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Shrimps of the genus Thor Kingsley, 1878 (Caridea, Thoridae): description of a new species using integrative data, remarks on Thor manningi Chace, 1972, and a world identification key

Abstract

Marine shrimps of the genus Thor Kingsley, 1878 are distributed in the eastern and western Atlantic, eastern Pacific, and Indo-West Pacific. Thor manningi Chace, 1972 was originally described from Antigua and since then has been recorded from other Atlantic localities, including the Caribbean Sea, Bermuda, USA, Brazil, and Ascension Island. Specimens previously identified as T. manningi from Panama and Brazil were analyzed using a combination of morphological and molecular approaches. The analyses yielded a new species from the Atlantic coast of Panama, herein described as Thor paulae sp. nov. Moreover, we provide additional morphological observations on T. manningi, mainly regarding mouthparts and pereopods. The new species is morphologically similar to the Pacific Thor cocoensis Wicksten and Vargas, 2001 and Thor marguitae Bruce, 1978. However, it can be separated from them by the carpus of the second pereopod, rostral dorsal dentition, and chela of the first pereopod, respectively. The two species studied here can be easily distinguished by the supraorbital prominence in T. manningi (versus absent in the new species), and the pterygostomial margin rounded and unarmed in T. manningi (versus angular, with tooth in the new species). Thor manningi is morphologically closer to the western Atlantic Thor dobkini Chace, 1972 and Thor floridanus Kingsley, 1878, but can be separated from both by the merus of the first pereopod (T. dobkini) and dactylus of fourth and fifth pereopods (T. floridanus, but with the possibility of overlap). We provide a comparative table with morphological characters of all 17 valid species of Thor, as well as a worldwide identification key to the genus.

Keywords:
Atlantic Ocean; Cytochrome Oxidase subunit I; Decapoda; Panama; 16S mtDNA

INTRODUCTION

The small-sized (< 1 cm in total length) shrimps of the genus ThorKingsley, 1878Kingsley, J.S. 1878. Notes on the North American Caridea in the Museum of the Peabody Academy of Science at Salem, Mass. Proceedings of the Academy of Natural Sciences of Philadelphia, 1878: 89-98. have a wide diversity of lifestyles and sexual systems, including some species being symbiotic with anemones or corals and others living in association with seaweed or seagrass (Bauer, 1986Bauer, R.T. 1986. Sex change and life history pattern in the shrimp Thor manningi (Decapoda: Caridea): a novel case of partial protandric hermaphroditism. Biological Bulletin, 170: 11-31.; Chace, 1997Chace, F.A. Jr. 1997. The caridean shrimps (Crustacea: Decapoda) of the Albatross Philippine expedition, 1907-1910, Part 7: Families Atyidae, Eugonatonotidae, Rhynchocinetidae, Bathypalaemonellidae, Processidae, and Hippolytidae. Smithsonian Contributions to Zoology, 587: 1-106. ; Khan et al., 2004Khan, R.N.; Becker, J.H.; Crowther, A.L. and Lawn, I.D. 2004. Spatial distribution of symbiotic shrimps (Periclimenes holthuisi, P. brevicarpalis, Thor amboinensis) on the sea anemone Stichodactyla haddoni. Journal of the Marine Biological Association of the United Kingdom, 84: 201-203.). Thor includes 16 valid species (De Grave and Fransen, 2011De Grave, S. and Fransen, C.H.J.M. 2011. Carideorum catalogus: the recent species of the dendrobranchiate, stenopodidean, procarididean and caridean shrimps (Crustacea: Decapoda). Zoologische Mededelingen, 89: 195-589. ; Xu and Li, 2014Xu, P. and Li, X.Z. 2014. A new species of the hippolytid shrimp genus Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea) from Hainan Island, China. Zootaxa, 3795: 394-400.; 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.; Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.; WoRMS, 2022WoRMS 2022. Thor Kingsley, 1878. Accessed at: Accessed at: https://www.marinespecies.org/aphia.php?p=taxdetails&id=106995 . Accessed on 15 february 2022.
https://www.marinespecies.org/aphia.php?...
): four in the western Atlantic, three in the eastern Pacific, eight in the northwestern Pacific and Indo-West Pacific, and one with circumtropical distribution. Some species are known only from the type locality, such as Thor spinipesBruce, 1983Bruce, A.J. 1983. Thor spinipes sp. nov., a new hippolytid shrimp from the Cobourg Peninsula, northern Australia. The Beagle, Records of the Northern Territory Museum of Arts and Sciences, 1: 1-10. (Australia, Northern Territory) and Thor singularisXu and Li, 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165. (China, Hainan Island). In opposition, Thor amboinensis (de Man, 1888De Man, J.G. 1887-1888. Bericht über die von Herrn Dr. J. Brock im indischen Archipel Gesammelten Decapoden und Stomatopoden. Archiv für Naturgeschichte, 53: 215-600. [in de Man, 1887-1888De Man, J.G. 1887-1888. Bericht über die von Herrn Dr. J. Brock im indischen Archipel Gesammelten Decapoden und Stomatopoden. Archiv für Naturgeschichte, 53: 215-600.]) and Thor manningiChace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179., are widely distributed.

Titus et al. (2018Titus, B.M.; Daly, M.; Hamilton, N.; Berumen, M.L. and Baeza, J.A. 2018. Global species delimitation and phylogeography of the circumtropical ‘sexy shrimp’ Thor amboinensis reveals a cryptic species complex and secondary contact in the Indo-West Pacific. Journal of Biogeography, 45: 1275-1287.) performed a molecular analysis of the circumtropical T. amboinensis and revealed the existence of at least five cryptic lineages: four in the Indo-West Pacific and one in the Western Atlantic. The latter lineage was recently described as Thor dicaprioAnker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.; and the undescribed Indo-West Pacific species within that complex are treated herein as T. amboinensis.

Thor manningi was initially described from Antigua and new records have extended its distribution to other Caribbean localities, Bermuda, the eastern coast of the USA, Brazil (seamounts of the North Brazilian Chain, Fernando de Noronha, Ceará to São Paulo), and Ascension Island (Central Atlantic) (Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.; Manning and Chace, 1990Manning, R.B. and Chace, F.A. Jr. 1990. Decapod and stomatopod crustaceans from Ascension Island, south Atlantic Ocean. Smithsonian Contributions to Zoology, 503: 1-91.; Christoffersen, 1998Christoffersen, M.L. 1998. Malacostraca. Eucarida. Caridea. Crangonoidea and Alpheoidea (Except Glyphocrangonidae and Crangonidae). p. 351-372. In: P.S. Young (ed), Catalogue of Crustacea of Brazil. Rio de Janeiro, Museu Nacional. (Série Livros, 6); Coelho Filho, 2006Coelho Filho, P.A. 2006. Checklist of the decapods (Crustacea) from the outer continental shelf and seamounts from Northeast of Brazil-REVIZEE Program (NE III). Zootaxa, 1184: 1-27.). The occurrence of T. manningi in Brazil was probably based on the identification key proposed by Chace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.), which was based on the analysis of specimens from the Caribbean Sea. In fact, a few morphological accounts (and figures) from Brazilian material of T. manningi have been provided by Almeida et al. (2008Almeida, A.O.; Bezerra, L.E.; Souza-Filho, J.F.; Almeida, S.M.; Albuquerque, D.L. and Coelho, P.A. 2008. Decapod and stomatopod crustaceans from Santo Aleixo Island, state of Pernambuco, Brazil. Nauplius, 16: 23-41.) based on material from Pernambuco, and the DNA sequences from São Paulo were made available by Terossi et al. (2017Terossi, M.; De Grave, S. and Mantelatto, F.L. 2017. Global biogeography, cryptic species and systematic issues in the shrimp genus Hippolyte Leach 1814 (Decapoda: Caridea: Hippolytidae) by multimarker analyses. Scientific Reports, 7: 6697. ; 2018Terossi, M.; Almeida, A.O.; Buranelli, R.C.; Castilho, A.L.; Costa, R.C.; Zara, F.J. and Mantelatto, F.L. 2018. Checklist of decapods (Crustacea) from the coast of the São Paulo state (Brazil) supported by integrative molecular and morphological data: I. Infraorder Caridea: families Hippolytidae, Lysmatidae, Ogyrididae, Processidae and Thoridae. Zootaxa, 4370: 76-94. ).

The taxonomy of this genus has not been completely clarified due to the morphological similarity among species, which hinders species identification, especially when they occur in the same region (Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.). This author reported difficulty in finding distinctive morphological characters among some species due to the occurrence of protandry. The sexual system of the four species reported from the western Atlantic has already been studied. Two species have been confirmed as gonochoric by Bauer and VanHoy (1996Bauer, R.T. and VanHoy, R. 1996. Variation in sexual systems (protandry, gonochorism) and reproductive biology among three species of the shrimp genus Thor (Decapoda: Caridea). Bulletin of Marine Science, 59: 53-73.), i.e., Thor dobkiniChace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179. and Thor floridanusKingsley, 1878Kingsley, J.S. 1878. Notes on the North American Caridea in the Museum of the Peabody Academy of Science at Salem, Mass. Proceedings of the Academy of Natural Sciences of Philadelphia, 1878: 89-98.. Simple protandry has been reported in T. dicaprio (see Baeza and Piantoni, 2010Baeza, J.A. and Piantoni, C. 2010. Sexual system, sex ratio, and group living in the shrimp Thor amboinensis (De Man): relevance to resource-monopolization and sex-allocation theories. Biological Bulletin, 219: 151-65. as T. amboinensis) and protandry with primary males (half the population does not change to female) in T. manningi (see Bauer, 1986Bauer, R.T. 1986. Sex change and life history pattern in the shrimp Thor manningi (Decapoda: Caridea): a novel case of partial protandric hermaphroditism. Biological Bulletin, 170: 11-31.).

This taxonomic context led us to analyze specimens previously identified as T. manningi from Panama and Brazil, using a combination of morphological and molecular data, as well as the morphology of the holotype from Antigua. Our findings result in the discovery of a new species of Thor from the Atlantic coast of Panama. In this study, we provide the description of the new species as well as additional morphological observations on T. manningi, including illustration of their mouthparts. Both species were morphologically compared with congeners, and a world identification key for the genus is also provided.

MATERIALS AND METHODS

The specimens analyzed are deposited in the following collections: Coleção de Crustáceos do Departamento de Biologia da Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto da Universidade de São Paulo, Brazil (CCDB); Coleção de Crustáceos do Departamento de Zoologia da Universidade Federal do Rio Grande do Sul, Brazil (DZ/UFRGS); Florida Museum of Natural History, USA (UF); Instituto de Ciências do Mar, Universidade Federal do Ceará, Brazil (LABOMAR); Laboratório de Invertebrados Marinhos do Ceará, Universidade Federal do Ceará, Brazil (LIMCE-UFC); National Museum of Natural History, Smithsonian Institution, USA (USNM).

Morphological data

Males were identified by the presence of the appendix masculina on the endopod of the second pair of pleopods and/or presence of the prehensile third pereopod, whereas females were identified by the presence of embryos or associated breeding material on their pleon, or by the absence of male diagnostic characters (Bauer, 1986Bauer, R.T. 1986. Sex change and life history pattern in the shrimp Thor manningi (Decapoda: Caridea): a novel case of partial protandric hermaphroditism. Biological Bulletin, 170: 11-31.). Mouthparts were dissected from specimens from samples CCDB 2593 (T. manningi), UF 44393, and UF 44518 (new species). Measurements and observations were performed with a Nikon SMZ800 stereomicroscope. The following measurements were taken: carapace length, length of the fifth and sixth pleonal segment, length, and proximal width of the telson, length of the endopod and exopod of the telson, length and greatest width of the scaphocerite, total length of the three articles of the third maxilliped, length from the articles of the first to the fifth pereopod (basis, ischium, merus, carpus, propodus, and dactylus, including the carpus articles of the second pereopod). Spiniform setae on the distal region of the flexor margin of the fifth pereopod were not counted since some specimens presented tufts of simple setae, making it impossible to see the structures. The illustrations of the morphology and the mouthparts were made, respectively, with the aid of a Nikon SMZ800 stereomicroscope and Olympus CX31 microscope equipped with a camera lucida, later vectorized into the Adobe Illustrator® CS6. Abbreviations are: CL, carapace length; coll.(s), collector (s).

The identification key was based on, and modified from, a previous proposal: Chace (1997Chace, F.A. Jr. 1997. The caridean shrimps (Crustacea: Decapoda) of the Albatross Philippine expedition, 1907-1910, Part 7: Families Atyidae, Eugonatonotidae, Rhynchocinetidae, Bathypalaemonellidae, Processidae, and Hippolytidae. Smithsonian Contributions to Zoology, 587: 1-106. ), a worldwide key with 10 species; Komai et al. (2015Komai, T.; Okuno, J. & Minemizu, R. 2015. New records of two species of the coral reef shrimp genus Thor Kingsley 1878 (Crustacea: Decapoda: Thoridae) from the Ryukyu Islands, Japan. Zootaxa, 4013: 399-412.), an Indo-West Pacific key with nine species; and on all original descriptions from the 17 valid Thor species (present study).

Genetic data

Total genomic DNA was extracted from the muscle tissue of the pleon of the specimens, using the Qiagen Extraction Kit, following the manufacturer's recommendation. A region of ~600 base pairs (bp) of the 16S mtDNA (16S) and ∼700 bp of the Cytochrome Oxidase subunit I (COI) genes were amplified from the extracted DNA through a polymerase chain reaction (PCR), using specific primers: 1472 (5´-AGATAGAAACCAACCTGG-3´) / 16SL2 (5´-GCCTGTTTATCAAAAACAT-3´) (Schubart et al., 2000Schubart, C.D.; Neigel, J.E. and Felder, D.L. 2000. Use of the mitochondrial 16S rRNA gene for phylogenetic and population studies of Crustacea. Crustacean Issues, 12: 817-830.; 2002Schubart, C.D.; Cuesta, J.A. and Felder, D.L. 2002. Glyptograpsidae, a new brachyuran family from Central America: larval and adult morphology, and a molecular phylogeny of the Grapsoidea. Journal of Crustacean Biology, 22: 28-44.) for the 16S; and COL6b (5´-ACAAATCATAAAGATATYGG-3´) / COH6 (5´-TADACTTCDGGRTGDCCAAARAAYCA-3) (Schubart and Huber, 2006Schubart, C.D. and Huber, M.G.J. 2006. Genetic comparisons of German populations of the stone crayfish, Austropotamobius torrentium (Crustacea: Astacidae). Bulletin Français de la Pêche et de la Pisciculture, 380-381: 1019-1028.) for the COI. PCR products were purified with ExoSAP-IT Kit, following the manufacturer's recommendation, and sequenced by ACTGENE (Análises Moleculares LTDA). All the sequences were confirmed by sequencing both strands, and the consensus sequence was obtained in the software Bioedit 7.0.5 (Hall, 2005Hall, T.A. 2005. BioEdit 7.0.5. North Carolina State University, Department of Microbiology. Available at Available at https://bioedit.software.informer.com/7.0/ . Accessed on 15 June 2021.
https://bioedit.software.informer.com/7....
). The non-specific readings were corrected manually, when necessary.

Sequences of five specimens of T. manningi were obtained from three locations: one from Panama, two from Brazil (São Paulo and Pernambuco), and three specimens of the new species from Panama. We also included T. manningi sequences obtained from GenBank from São Paulo and Puerto Rico.

Available sequences from other species of Thor (T. amboinensis complex and Thor hainanensisXu and Li, 2014Xu, P. and Li, X.Z. 2014. A new species of the hippolytid shrimp genus Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea) from Hainan Island, China. Zootaxa, 3795: 394-400.) and the outgroup composed of Thinora maldivensisBorradaile, 1915Borradaile, L.A. 1915. Notes on Carides. Annals and Magazine of Natural History, 15: 205-213. were retrieved from Genbank. This latter species was chosen for its morphological and phylogenetic proximity to Thor (see De Grave et al., 2014De Grave, S.; Li, C.P.; Tsang, L.M.; Chu, K.H. and Chan, T.Y. 2014. Unweaving hippolytoid systematics (Crustacea, Decapoda, Hippolytidae): resurrection of several families. Zoologica Scripta, 43: 496-507. and Komai et al., 2015Komai, T.; Okuno, J. & Minemizu, R. 2015. New records of two species of the coral reef shrimp genus Thor Kingsley 1878 (Crustacea: Decapoda: Thoridae) from the Ryukyu Islands, Japan. Zootaxa, 4013: 399-412.), although there was only one sequence available for the 16S; and Eualus cranchii (Leach, 1817Leach, W.E. 1815-1875. Malacostraca Podophthalmata Britanniae; or descriptions of such British species of the Linnean genus Cancer as have their eyes elevated on footstalks. London, J. Sowerby, 124p. [in Leach, 1815-1875Leach, W.E. 1815-1875. Malacostraca Podophthalmata Britanniae; or descriptions of such British species of the Linnean genus Cancer as have their eyes elevated on footstalks. London, J. Sowerby, 124p.]) that was selected because it belongs to the same family (De Grave et al., 2014De Grave, S.; Li, C.P.; Tsang, L.M.; Chu, K.H. and Chan, T.Y. 2014. Unweaving hippolytoid systematics (Crustacea, Decapoda, Hippolytidae): resurrection of several families. Zoologica Scripta, 43: 496-507., as Thoralus cranchii).

The final sequences were aligned by the MUSCLE method (Edgar, 2004Edgar, R.C. 2004. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Research, 32: 1792-1797. ), implemented in the Cyberinfrastructure for Phylogenetic Research (CIPRES) platform (Miller et al., 2010Miller, M.A.; Pfeiffer, W. and Scheartz, T. 2010. Creating the CIPRES Science Gateway for inference of large phylogenetic trees. p. 1-8. In: Proceedings of the Gateway Computing Environments Workshop (GCE), New Orleans, Louisiana, USA.). For each gene, genetic distance matrices and phylogenetic trees were generated separately by the methods of Maximum Likelihood (ML) and Bayesian Inference (BI). The best substitution model was defined by the software JModelTest 2 (Darriba et al., 2012Darriba, D.; Taboada, G.L.; Doallo, R. and Posada, D. 2012. jModelTest 2: more models, new heuristics and parallel computing. Nature Methods, 9: 772.) implemented on the CIPRES platform, using the Bayesian Information Criterion.

ML was performed with RAxML (Stamatakis, 2014Stamatakis, A. 2014. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics, 30: 1312-1313.), implemented on the CIPRES platform with the standard GTR model. The topology consistency was measured by the bootstrap method and the ML trees were viewed and edited in Mega 7 (Kumar et al., 2016Kumar, S.; Stecher, G. and Tamura, K. 2016. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution, 33: 1870-1874.). Only support values above 90 % are shown.

BI was carried out in the MrBayes 3.2.6 (Ronquist et al., 2012Ronquist, F.; Teslenko, M.; Van Der Mark, P.; Ayres, D.L.; Darling, A.; Höhna, S.; Larget, B.; Liu, L.; Suchard, M.A. and Huelsenbeck, J.P. 2012. MrBayes 3.2: efficient Bayesian phylogenetic inference and model choice across a large model space. Systematic Biology, 61: 539-542.) implemented on the CIPRES platform. The data from the obtained substitution model were analyzed in Tracer v1.6. (Rambaut et al., 2018Rambaut, A.; Drummond, A.J.; Xie, D.; Baele, G. and Suchard, M.A. 2018. Posterior summarisation in Bayesian phylogenetics using Tracer 1.7. Systematic Biology, 67: 901-904.). The first 15 % of the parameters and trees was discarded as burn-in. The final tree was generated, using the software Tree Annotator 1.8.4 (Drummond et al., 2012Drummond, A.J.; Suchard, M.A.; Xie, D. and Rambaut, A. 2012. Bayesian phylogenetics with BEAUti and the BEAST 1.7. Molecular Biology and Evolution, 29: 1969-1973. ). The tree was viewed and edited in the software Fig Tree 1.4.4 (http://tree.bio.ed.ac.uk/software/figtree/). Only support values of posterior probabilities above 0.90 are shown.

The genetic distance matrices were calculated for each gene by pairwise comparisons between sequences, using the p-distance with the software MEGA (Kumar et al., 2016Kumar, S.; Stecher, G. and Tamura, K. 2016. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution, 33: 1870-1874.).

RESULTS

Systematics

Family Thoridae Kingsley, 1879Kingsley, J.S. 1879. List of the North American Crustacea belonging to the suborder Caridea. Bulletin of the Essex Institute, 10: 53-71.

Genus Thor Kingsley, 1878Kingsley, J.S. 1878. Notes on the North American Caridea in the Museum of the Peabody Academy of Science at Salem, Mass. Proceedings of the Academy of Natural Sciences of Philadelphia, 1878: 89-98.

Thor paulae sp. nov.

(Figs. 1, 2)

Figure 1.
Thor paulae sp. nov. Panama, Bocas del Toro. Holotype, female (UF 60011). A, Carapace and cephalic appendages, left lateral view; B, rostrum, left lateral view; C, left antennule, dorsal view; D, left antennule, ventral view; E, left antenna, ventral view; F, pleon, left lateral view; G, left first pereopod, lateral view; H, left second pereopod, lateral view; I, left third pereopod, lateral view; J, left fourth pereopod, lateral view; K, left fifth pereopod, lateral view; L, telson and uropods, dorsal view. Scale bars: A, F-K: 0.83 mm; B: 1.0 mm; C-E: 0.625 mm; L: 0.25 mm.

Figure 2.
Thor paulae sp. nov. Panama, Bocas del Toro. Paratypes, females (A, B, D, E - UF 44393; C, F, G - UF 44518). A, Right mandible, ventral view; B, right maxillule, ventral view; C, left maxilla, ventral view; D, left first maxilliped, ventral view; E, left second maxilliped, ventral view; F, detail of the third maxilliped with papillose seta, ventral view; G, left third maxilliped, ventral view. Scale bars: A-E, G: 0.25 mm; F: 0.06 mm.

Zoobank: urn:lsid:zoobank.org:pub:E6AC08C7-EE6E-4EBB-B6BD-F1B2250C8255

Type material. Panama: Holotype, ovigerous female (CL 2.7 mm), UF 60011, Panama, Bocas del Toro, Seagal (09°17’20.4”N 82°17’45.6”W), colls. M. Leray, F. Michonneau and R. Lasley, 27 May 2016. Paratypes: 1 male with appendix masculina and 8 females (6 ovigerous and 2 non-ovigerous adults, CL 2.2-2.7 mm), UF 44518 (photo available, one dissected specimen), same data as holotype; 1 male with appendix masculina (CL 1.9 mm), UF 44289, Panama, Bocas del Toro, Ponsak (09°17’38.4”N 82°19’55.2”W), colls. M. Leray, F. Michonneau and R. Lasley, 13 May 2016; 7 females (5 ovigerous and 2 non-ovigerous adults, CL 2.0-2.5 mm), UF 44393 (photo available, one dissected specimen), Panama, Bocas del Toro, Punta STRI (Smithsonian Tropical Research Institute's) (09°20’56.4”N 82°15’46.8”W), colls. M. Leray, F. Michonneau and R. Lasley, 09 May 2016.

Etymology. The new species is named in honor of our great friend, Dra. Paula Beatriz de Araujo (Federal University of Rio Grande do Sul, Brazil), who has devoted her career to the study of biology, ecology, and systematics of crustaceans.

Diagnosis. Supraorbital tooth vestigial or absent. Pterygostomial margin angular, with one tooth. Telson with 3 pairs of dorsolateral spiniform setae; posterior margin with 3 pairs of simple setae. Merus of first pereopod with 1 or 2, rarely 3 or 4, spiniform setae on flexor proximal region. Dactylus of fourth and fifth pereopods with 2 or 3, rarely 1 or 4, spiniform setae on flexor margin.

Description. Rostrum (Fig. 1A, B) slightly descending, falling short of distal margin of first article of antennular peduncle to reaching distal margin of second article; dorsal margin armed with 4-5 teeth, posteriormost tooth located at about rostral base; ventral margin with minute subapical tooth, rarely 2 teeth or toothless. Supraorbital tooth vestigial or absent. Antennal tooth present, acute. Pterygostomial margin angular, with 1 tooth.

Pleurae (Fig. 1F) of pleonal segments 1-3 rounded posteroventrally; pleurae of pleonal segments 4-6 acute posteroventrally. Sixth segment 1.6 times as long as fifth; telson 1.1 times as long as sixth segment. Telson (Fig. 1L) 2.5 times longer than proximal width, with 3 pairs of dorsolateral spiniform setae and posterior margin with 3 pairs of simple setae, intermediate pair longest and outer shortest.

Cornea generally wider and slightly shorter than eyestalk. First article of antennular peduncle with tooth on median region of ventral margin (Fig. 1D); acute stylocerite of variable length from reaching distal margin of first article of antennular peduncle to distal margin of second article of antennular peduncle (Fig. 1C); stylocerite with tooth on proximal dorsolateral margin; second article of antennular peduncle with tooth on lateral margin with variable length from reaching half to slightly exceeding distal margin of third article of antennular peduncle; third article of antennular peduncle with triangular plate articulated on dorsodistal margin; inner flagellum overreaching outer flagellum; inner flagellum slender and elongate; outer flagellum stout, with dense row of aesthetascs (Fig. 1A). Antennal basicerite with 2 ventral teeth; carpocerite variable in length, not reaching or slightly exceeding half-length of scaphocerite; scaphocerite 2.5 times longer than median width, overreaching distal margin of third article of antennular peduncle, with tooth on lateral distal margin (Fig. 1E); antennal flagellum long, filiform, articulated slightly broader at base than tip.

Mandible asymmetrical (Fig. 2A), molar process with serrated surface, incisor process with 5 teeth, palp absent. Maxillule (Fig. 2B) with distally truncated and undivided endopod, with distal simple seta; endite with upper lacinia broad, with somewhat acute distomedial angle, with numerous plumose setae and 11 spiniform setae; lower lacinia slender, with numerous plumose setae distally. Maxilla (Fig. 2C) with coxal endite distally truncated and bilobed basal endite slightly rounded, numerous plumose setae on both endites; short endopod, distally slender, with plumose setae; exopod (scaphognathite) well-developed, rounded, truncated terminal margin, with numerous plumose setae.

First maxilliped (Fig. 2D) with coxal and basal endites similar in length, covered by numerous plumose setae; both endites with distal margin slightly rounded; undivided endopod, with plumose setae; exopod well developed and undivided, with some plumose setae on proximal region and numerous plumose setae on distal region; proximal and distal lobes of large epipod similar in width. Second maxilliped (Fig. 2E) with protopodite with plumose setae; endopod with 4 articles, merus 3.1 times as long as dactylus, carpus 3 times as long as dactylus, propodus 10 times as long as dactylus, propodus and dactylus with numerous plumose setae; long, slender, undivided exopod, some plumose setae on proximal region and numerous plumose setae on distal region. Third maxilliped (Fig. 2G) overreaching antennular peduncle; antepenultimate article 0.9 times as long as ultimate article, with some plumose setae, distal region unarmed or with 1 papillose seta (Fig. 2F) and 0 or 1 spiniform seta, with variable positions; penultimate article 0.3 times as long as ultimate article, with some simple and plumose setae; ultimate article with many simple and plumose setae, tip with 7 or 8 spiniform setae; exopod not reaching distal margin of antepenultimate article, with tuft of plumose setae on tip.

Pereopods without epipods. First pereopod (Fig. 1G) of variable length, not reaching or exceeding half-length of scaphocerite; ischium, merus, carpus, and propodus 2.0, 3.2, 2.8, 3.9 times as long as basis, respectively; ischium with 1 spiniform seta on distal flexor region; merus with 1 or 2, rarely 3 or 4, spiniform setae on flexor proximal region; chela slender, fingers 0.6 times as long as palm, both with short setae on cutting edge and tufts of setae on lateral edge. Second pereopod (Fig. 1H) with ischium, merus, carpus, and propodus 4.3, 4.6, 7.2, 2.6 times as long as basis, respectively; ischium with 2 simple and long setae on proximal flexor region; carpus subdivided into 6 articles, length ratio of carpal articles from proximal to distal 2:1:4:3:2.5:3; chela slender, fingers 0.7 times as long as palm, both with tufts of setae on lateral margin. Third pereopod (Fig. 1I) with ischium, merus, carpus, and propodus 2.2, 4.3, 2.1, 5.1 times as long as basis, respectively; merus with 1 to 3 lateral spiniform seta on distal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 7 to 16 spiniform setae, distal setae paired; male specimen (UF 44289) with tuft of setae on distal region of flexor margin; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3, rarely 4, spiniform setae on flexor margin. Fourth pereopod (Fig. 1J) with ischium, merus, carpus, and propodus 2.3, 4.9, 2.5, 5.7 times as long as basis, respectively; merus with 1 spiniform seta on distal region, tuft of setae on distal dorsal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 8 to 12 spiniform setae, distal setae paired; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3 spiniform setae on flexor margin. Fifth pereopod (Fig. 1K) with ischium, merus, carpus, and propodus 2.2, 4.2, 2.2, 5.4 times as long as basis, respectively; merus unarmed (rarely) or with 1 spiniform seta on distal region, tuft of setae on distal dorsal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 8 to 15 spiniform setae, distal setae paired, some specimens with tuft of simple setae on distal region of flexor margin; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3, rarely 1, spiniform setae on flexor margin.

Exopod of uropod 1.1 times as long as endopod (Fig. 1L); exopod with distolateral tooth and spiniform setae between distolateral tooth and margin of blade.

Type locality. Panama, Bocas del Toro, Isla Cristóbal, NW side, “Seagal”.

Distribution. Western Atlantic - Panama (this study).

Variations. One male paratype (UF 44289, 1.9 mm CL) presented a tuft of setae on the distal region of the flexor margin of the propodus of the third pereopod. This tuft was absent in the other male paratype examined (UF 44518, 2.2 mm CL).

Thor manningi Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.

(Fig. 3)

Figure 3.
Thor manningiChace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.. Brazil, São Paulo. Female (CCDB 2593). A, Right mandible, ventral view; B, right maxillule, ventral view; C, left maxilla, ventral view; D, left first maxilliped, ventral view; E, left second maxilliped, ventral view; F, left third maxilliped, ventral view. Scale bars: 0.25 mm.

Thor manningiChace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: 130, 137, figs. 59-61; Birkeland et al., 1976Birkeland, C.; Reimer, A.A. and Young, J.R. 1976. Survey of marine communities in Panama and experiments with oil. Report EPA-600/3-76-028. Narrangasett, Environmental Research Laboratory, 177p.: 138; Heck and Wetstone, 1977Heck, K.L. Jr and Wetstone, G.S. 1977. Habitat complexity and invertebrate species richness and abundance in tropical seagrass meadows. Journal of Biogeography, 4: 135-142. : 138; Carvacho, 1979Carvacho, A. 1979. Les crevettes carides de la mangrove guadeloupéenne. Bulletin du Museum National d'Histoire Naturelle, Section A, Zoologie Biologie et Ecologie, 1: 445-470.: 464; Gore, 1981Gore, R.H. 1981. Three new shrimps, and some interesting new records of decapod Crustacea from a deep-water coral reef in the Florida Keys. Proceedings of the Biological Society of Washington, 94: 135-162.: 138, 152; Markham and McDermott, 1980Markham, J.C. and McDermott, J.J. 1980. A tabulation of the Crustacea Decapoda of Bermuda. Proceedings of the Biological Society of Washington, 93: 1266-1276.: 1270; Carvacho, 1982Carvacho, A. 1982. Sur une petite collection de crevettes de la Martinique. Caribbean Journal of Science, 17: 15-20.: 18; Cubit and Williams, 1983Cubit, J. and Williams, S. 1983. The invertebrates of Galeta Reef (Caribbean Panama): A species list and bibliography. Atoll Research Bulletin, 269: 1-45. : 25; Williams, 1984Williams, A.B. 1984. Shrimps, lobsters, and crabs of the Atlantic coast of the eastern United States, Maine to Florida. Washington D.C., Smithsonian Institution Press, 550p.: 134, 137, fig. 96; Bauer, 1985Bauer, R.T. 1985. Diel and seasonal variation in species composition and abundance of caridean shrimps (Crustacea, Decapoda) from seagrass meadows on the north coast of Puerto Rico. Bulletin of Marine Science, 36: 150-162.: 150, 152-158; Bauer, 1986Bauer, R.T. 1986. Sex change and life history pattern in the shrimp Thor manningi (Decapoda: Caridea): a novel case of partial protandric hermaphroditism. Biological Bulletin, 170: 11-31.: 11-13, 15, 19, 23, 25, 27-29, figs. 1, 8, 9, 12; Martínez Iglesias, 1986Martínez Iglesias, I.C. 1986. Los crustáceos decápodos del Golfo de Batabanó. Caridea y Penaeidea. Poeyana, 321: 1-37.: 5, 18, 19, fig. 9B; Young, 1986Young, P.S. 1986. Análise qualitativa e quantitativa da fauna associada a corais hermatípicos (Coelenterata: Scleractinia) nos recifes de João Pessoa, PB. Revista Brasileira de Biologia, 46: 99-126.: 112; Manning and Chace, 1990Manning, R.B. and Chace, F.A. Jr. 1990. Decapod and stomatopod crustaceans from Ascension Island, south Atlantic Ocean. Smithsonian Contributions to Zoology, 503: 1-91.: 24; Markham et al., 1990Markham, J.C.; Donath-Hernandez, F.E.; Villalobos-Hiriart, J.L. and Diaz-Barriga, A.C. 1990. Notes on the shallow-water marine Crustacea of the Caribbean coast of Quintana Roo, Mexico. Anales del Instituto de Biología Universidad Nacional Autónoma de México, 61: 405-446.: 423; Bauer and VanHoy, 1996Bauer, R.T. and VanHoy, R. 1996. Variation in sexual systems (protandry, gonochorism) and reproductive biology among three species of the shrimp genus Thor (Decapoda: Caridea). Bulletin of Marine Science, 59: 53-73.: 53-56, 61-71; Duarte and Nalesso, 1996Duarte, L.F.L. and Nalesso, R.C. 1996. The sponge Zygomycale parishii (Bowerbank) and its endobiotic fauna. Estuarine, Coastal and Shelf Science, 42: 139-151.: 143, 148; Hernández-Aguilera et al., 1996Hernández-Aguilera, J.L.; Toral-Almazán, R.E. and Ruiz-Nuño, J.A. 1996. Especies catalogadas de crustáceos estomatópodos y decápodos para el Golfo de México, Río Bravo, Tamps. A Progreso, Yuc. Conabio, Dirección de Oceanografia, Secretaría de Marina, México, 132p.: 41; Christoffersen, 1998Christoffersen, M.L. 1998. Malacostraca. Eucarida. Caridea. Crangonoidea and Alpheoidea (Except Glyphocrangonidae and Crangonidae). p. 351-372. In: P.S. Young (ed), Catalogue of Crustacea of Brazil. Rio de Janeiro, Museu Nacional. (Série Livros, 6): 353; Álvarez et al., 1999Álvarez, F.; Villalobos, J.L.; Rojas, Y. and Robles, R. 1999. Listas y comentarios sobre los crustáceos decápodos de Veracruz, Mexico. Anales del Instituto de Biologia Universidad Nacional Autónoma de México, Série Zoologia, 70: 1-27.: 7; Morgado and Tanaka, 2001Morgado, E.H. and Tanaka, M.O. 2001. The macrofauna associated with the bryozoan Schizoporella errata (Walters) in southeastern Brazil. Scientia Marina, 65: 173-181.: 177; Wicksten, 2005Wicksten, M.K. 2005. 4. Hippolytid shrimps. p. 98-118. In: J.L. Hernández-Aguilera, J.A. Ruiz-Nuño, R.E. Toral-Almazán and V. Arenas-Fuentes (eds), Camarones, Langostas y Cangrejos de la Costa Este de México. México, DF, Econatura-CONABIO.: 100, 107, fig. 7; Coelho Filho, 2006Coelho Filho, P.A. 2006. Checklist of the decapods (Crustacea) from the outer continental shelf and seamounts from Northeast of Brazil-REVIZEE Program (NE III). Zootaxa, 1184: 1-27.: 10; De Grave et al., 2006De Grave, S.; Livingston, D. and Speight, M.R. 2006. Diel variation in sea grass dwelling shrimp: when to sample at night? Journal of the Marine Biological Association of the United Kingdom, 86: 1421-1422.: 5363.2; Almeida et al., 2008Almeida, A.O.; Bezerra, L.E.; Souza-Filho, J.F.; Almeida, S.M.; Albuquerque, D.L. and Coelho, P.A. 2008. Decapod and stomatopod crustaceans from Santo Aleixo Island, state of Pernambuco, Brazil. Nauplius, 16: 23-41.: 23, 28, 38, figs. 2-3; Felder et al., 2009Felder, D.L.; Álvarez, F.; Goy, J.W. and Lemaitre, R. 2009. Decapoda (Crustacea) of the Gulf of Mexico, with comments on the Amphionidacea. p. 1019-1104. In: D.L. Felder and D.K. Camp (eds), Gulf of Mexico Origin, Waters, and Biota, Vol. 1, Biodiversity. Texas, Texas A&M University Press.: 1059; Amaral et al., 2010Amaral, A.C.Z.; Migotto, A.E.; Turra, A. and Schaeffer-Novelli, Y. 2010. Araçá: biodiversidade, impactos e ameaças. Biota Neotropica, 10: 219-264. : 249; De Grave and Fransen, 2011De Grave, S. and Fransen, C.H.J.M. 2011. Carideorum catalogus: the recent species of the dendrobranchiate, stenopodidean, procarididean and caridean shrimps (Crustacea: Decapoda). Zoologische Mededelingen, 89: 195-589. : 434; Almeida et al., 2012Almeida, A.O.; Boehs, G.; Araújo-Silva, C.L. and Bezerra, L.E.A. 2012. Shallow-water caridean shrimps from southern Bahia, Brazil, including the first record of Synalpheus ul (Ríos & Duffy, 2007) (Alpheidae) in the southwestern Atlantic Ocean. Zootaxa, 3347: 1-35.: 2, 24, 26, 28, 35, app. II; De Grave and Anker, 2017De Grave, S. and Anker, A. 2017. An annotated checklist of marine caridean and stenopodidean shrimps (Malacostraca: Decapoda) of the Caribbean coast of Panama. Nauplius, 25: e2017015. DOI:10.1590/2358-2936e2017015.
https://doi.org/10.1590/2358-2936e201701...
: 33; Tavares et al., 2017Tavares, M.; Carvalho, L. and Mendonça, J.B. Jr. 2017. Towards a review of the decapod crustacea from the remote oceanic archipelago of Trindade and Martin Vaz, south Atlantic Ocean: new records and notes on ecology and zoogeography. Papéis Avulsos de Zoologia, 57: 157-176.: 157, 162, 107-172, fig. 4C; Terossi et al., 2017Terossi, M.; De Grave, S. and Mantelatto, F.L. 2017. Global biogeography, cryptic species and systematic issues in the shrimp genus Hippolyte Leach 1814 (Decapoda: Caridea: Hippolytidae) by multimarker analyses. Scientific Reports, 7: 6697. : fig. 2, tab. S1; Mariño et al., 2018Mariño, J.; Mendoza, M.D. and López-Sánchez, B. 2018. Composition and abundance of decapod crustaceans in mixed seagrass meadows in the Paraguana Peninsula, Venezuela. Iheringia. Série Zoologia, 108: e2018004.: 4-6; Terossi et al., 2018Terossi, M.; Almeida, A.O.; Buranelli, R.C.; Castilho, A.L.; Costa, R.C.; Zara, F.J. and Mantelatto, F.L. 2018. Checklist of decapods (Crustacea) from the coast of the São Paulo state (Brazil) supported by integrative molecular and morphological data: I. Infraorder Caridea: families Hippolytidae, Lysmatidae, Ogyrididae, Processidae and Thoridae. Zootaxa, 4370: 76-94. : 79, 87, fig. 2; Romero-Rodríguez and Álvarez, 2020Romero-Rodríguez, J. and Álvarez, F. 2020. Bopyrinella hadrocoxalis sp. nov. and Loki circumsaltanus Markham (Isopoda: Bopyridae) parasitizing shrimps of the genus Thor (Decapoda: Thoridae) in Mexican waters. Zootaxa, 4808: 560-570. : 560, 561, 563, 565, 567, 568, fig. 1A.

Figure 4.
Maximum Likelihood phylogenetic trees based on 16S mt (A) and Cytochrome Oxidase subunit I (B) genes. Numbers on branches represent bootstraps/posterior probabilities (Maximum Likelihood/Bayesian Inference), numbers < 90 % /0.90 are not shown. Colors correspond to localities in the map (C). Localities - Atl: Atlantic; PE: Pernambuco; RS: Red Sea; SP: São Paulo. Collections - CCDB: Coleção de Crustáceos do Departamento de Biologia, Faculdade de Filosofia Ciências e Letras de Ribeirão Preto, Brazil; DZ/UFRGS: Coleção de Crustáceos do Departamento de Zoologia, Universidade Federal do Rio Grande do Sul, Brazil; UF: Florida Museum of Natural History, USA. References - A: Bracken et al. (2009Bracken, H.D.; De Grave, S. and Felder, D.L. 2009. Phylogeny of the infraorder Caridea based on mitochondrial and nuclear genes (Crustacea: Decapoda). Crustacean Issues, 18: 281-305. as Thoralus cranchii); B: De Grave et al. (2014De Grave, S.; Li, C.P.; Tsang, L.M.; Chu, K.H. and Chan, T.Y. 2014. Unweaving hippolytoid systematics (Crustacea, Decapoda, Hippolytidae): resurrection of several families. Zoologica Scripta, 43: 496-507.); C: Fiedler et al. (2010Fiedler, G.C.; Rhyne, A.L.; Segawa, R.; Aotsuka, T. and Schizas, N.V. 2010. The evolution of euhermaphroditism in caridean shrimps: a molecular perspective of sexual systems and systematics. BMC Ecology and Evolution, 10: 297. as Thor cf. manningi); D: present study; E: Terossi et al. (2018Terossi, M.; Almeida, A.O.; Buranelli, R.C.; Castilho, A.L.; Costa, R.C.; Zara, F.J. and Mantelatto, F.L. 2018. Checklist of decapods (Crustacea) from the coast of the São Paulo state (Brazil) supported by integrative molecular and morphological data: I. Infraorder Caridea: families Hippolytidae, Lysmatidae, Ogyrididae, Processidae and Thoridae. Zootaxa, 4370: 76-94. ); F: D.K.G. Lundin (unpublished data); G: Terossi et al. (2017Terossi, M.; De Grave, S. and Mantelatto, F.L. 2017. Global biogeography, cryptic species and systematic issues in the shrimp genus Hippolyte Leach 1814 (Decapoda: Caridea: Hippolytidae) by multimarker analyses. Scientific Reports, 7: 6697. ); H: Titus et al. (2018Titus, B.M.; Daly, M.; Hamilton, N.; Berumen, M.L. and Baeza, J.A. 2018. Global species delimitation and phylogeography of the circumtropical ‘sexy shrimp’ Thor amboinensis reveals a cryptic species complex and secondary contact in the Indo-West Pacific. Journal of Biogeography, 45: 1275-1287.); I: Madhavan et al. (2019Madhavan, M.; Purushothaman, P.; Akash, S.; Bharathi, S.; Jose, S.; Dhinakaran, A.; Ravi, C.; Kumar, T. and Lal, K. 2019. New record of Thor hainanensis Xu & Li, 2014 and taxonomical remarks on Lysmata ternatensis de Man, 1902 (Decapoda: Thoridae & Lysmatidae) from the Lakshadweep Islands, India. Zootaxa, 4624: 351-364. ). Bold represents species analyzed in this study. * Represent nodes in the clades not recovered by one of the analyzes (inconsistencies).

Thor floridanus - (?) Fausto-Filho, 1970Fausto-Filho, J. 1970. Quarta contribuição ao inventário dos crustáceos decápodos marinhos do nordeste brasileiro. Arquivos de Ciências do Mar, 10: 55-60.: 56; (?) Coelho and Ramos, 1972Coelho, P.A. and Ramos, M.A. 1972. A constituição e a distribuição da fauna de decápodos do litoral leste da América do Sul entre as latitudes de 5ºN e 39ºS. Trabalhos Instituto Oceanográfico Universidade Federal De Pernambuco, 13: 133-236.: 152; (?) Heck, 1977Heck, K.L. Jr. 1977. Comparative species richness, composition and abundance of invertebrates in Caribbean seagrass (Thalassa testudinum) meadows (Panama). Marine Biology, 41: 335-348.: 338; (?) Heck, 1979Heck, K.L. Jr. 1979. Some determinants of the composition and abundance of motile macroinvertebrate species in tropical and temperate turtlegrass (Thalassia testudinum) meadows. Journal of Biogeography, 6: 183-200. : 199; (?) Christoffersen, 1998Christoffersen, M.L. 1998. Malacostraca. Eucarida. Caridea. Crangonoidea and Alpheoidea (Except Glyphocrangonidae and Crangonidae). p. 351-372. In: P.S. Young (ed), Catalogue of Crustacea of Brazil. Rio de Janeiro, Museu Nacional. (Série Livros, 6): 353.

Thor c. manningi - Rodríguez, 1980Rodríguez, G. 1980. Los Crustáceos Decápodos de Venezuela. Caracas, Instituto Venezuelano de Investigaciones Científicas, 494p.: 170, 171, fig. 49.

Thornanningi - Young, 1986Young, P.S. 1986. Análise qualitativa e quantitativa da fauna associada a corais hermatípicos (Coelenterata: Scleractinia) nos recifes de João Pessoa, PB. Revista Brasileira de Biologia, 46: 99-126.: 103 (misspelled).

Thor cf. manningi - Fiedler et al., 2010Fiedler, G.C.; Rhyne, A.L.; Segawa, R.; Aotsuka, T. and Schizas, N.V. 2010. The evolution of euhermaphroditism in caridean shrimps: a molecular perspective of sexual systems and systematics. BMC Ecology and Evolution, 10: 297. : 5, fig. 1.

Material examined. Antigua and Barbuda: Male, holotype (prehensile, CL 1.3 mm), USNM 135393, English Harbour, Antigua, from bottom of yacht anchored for several months, coll. D.V. Nicholson, Smithsonian-Bredin Expedition Sta 82-56, 04 April 1956. Panama: 1 ovigerous female (CL 2.5 mm), UF 44457 (photo available), Bocas del Toro (09°13'58.8''N 82°06'43.2''W), colls. M. Leray, F. Michonneau and R. Lasley, 24 May 2016; 1 ovigerous female (CL 1.93 mm), CCDB 6407, Bocas del Toro (09°19.805’N 82°15.087’W), colls. F. Mantelatto et al., 02 August 2011. Brazil: Ceará - 2 males (1 prehensile and 1 male with appendix masculina, CL 1.4-1.6 mm), LIMCE-UFC 300, Trairí, Mundaú, colls. PROBIO team, 14 March 2003; 1 ovigerous female (CL 2.0 mm), LIMCE-UFC 320, Paracuru, coll. P.P.G. Pachelle, 23 September 2010; 1 male (prehensile) and 4 females (3 ovigerous) (CL 1.2-2.6 mm), LABOMAR 732, São Gonçalo do Amarante, Terminal Portuário do Pecém, coll. PROCAD team, 29 January 2010. Pernambuco - 1 ovigerous female and 1 male with appendix masculina (CL 0.9-1.9 mm), DZ/UFRGS 6849, Cabo de Santo Agostinho, Praia de Suape, colls. G.L. Bochini, A.O. Almeida and G.O. Soledade, 26 May 2017; 2 males (1 prehensile and 1 with appendix masculina, CL 1.1-1.3 mm), DZ/UFRGS 6850, same location and colls., 26 June 2017; 1 female (CL 1.8 mm), DZ/UFRGS 6851, same location and colls., 23 August 2017; 1 female with breeding dress (CL 1.9 mm), DZ/UFRGS 6852, same location and colls., 28 August 2017; 2 ovigerous females (CL 2.0-2.1 mm), DZ/UFRGS 6853, same location and colls., 29 March 2018; 2 females (CL 2.2-2.4 mm), DZ/UFRGS 6832, same location and colls., 21 March 2019; 2 females (CL 1.8-2.2 mm), DZ/UFRGS 6833, same location and colls., 21 March 2019; 1 male with appendix masculina (CL 1.3 mm), DZ/UFRGS 6854, Cabo de Santo Agostinho, Praia do Paraíso, 08°21’29.9”S 34°57’00.9”W, colls. G.L. Bochini, A.O. Almeida and G.O. Soledade, 26 April 2017. São Paulo - 1 male with appendix masculina and 5 females (3 ovigerous) (CL 1.1-2.7 mm, one dissected specimen), CCDB 2593, Ubatuba, Praia Itaguá (23°26’59”S 045°01’49”W), coll. F.L. Mantelatto, 17 September 2008; 1 ovigerous female (CL 2.2 mm), CCDB 1850, Ubatuba, Praia Itaguá (23°26’59”S 045°01’49”W), colls. F.L. Mantelatto, I.C. Leone and R.C. Buranelli, 16 September 2010; 3 males with appendix masculina and 4 females (3 ovigerous and 1 with breeding dress) (CL 1.8-2.1 mm), CCDB 2737, Ubatuba, Praia Itaguá (23°26’59”S 045°01’49”W), colls. F.L. Mantelatto, R. Robles, M. Terossi, I.C. Leone and N.M. Grilli, 22 February 2011; 1 male with appendix masculina (CL 2.5 mm), CCDB 3840, Ilhabela, Praia do Engenho d'Água, colls. F.L. Mantelatto and E.C. Mossolin, 12 July 2006.

Additions to original description provided byChace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.). Telson 3 times longer than proximal width, with 3-6 pairs of dorsolateral spiniform setae (frequently 3 or 4 pairs). Acute stylocerite of variable length from reaching distal margin of second article of antennular peduncle to slightly exceeding distal margin of third article of antennular peduncle; inner flagellum overreaching outer flagellum; inner flagellum slender and elongate; outer flagellum stout, with dense row of aesthetascs. Antennal basicerite with two ventral teeth; carpocerite variable in length, reaching or slightly exceeding half-length of scaphocerite; antennal flagellum long, filiform, articulated slightly broader at base than tip.

Mandible asymmetrical (Fig. 3A), molar process with serrated surface, incisor process with 5-6 teeth, palp absent. Maxillule (Fig. 3B) with distally truncated and undivided endopod, with distal simple seta; endite with upper lacinia broad, with somewhat acute distomedial angle, with numerous plumose setae and 9 spiniform setae; lower lacinia slender, with numerous plumose setae distally. Maxilla (Fig. 3C) with coxal endite distally truncated and bilobed basal endite slightly rounded, numerous plumose setae on both endites; short endopod, distally slender, free of setae; exopod (scaphognathite) well developed, rounded, slender terminal margin, with numerous plumose setae.

First maxilliped (Fig. 3D) with coxal and basal endites similar in length, covered by numerous plumose setae; distal margin of coxal endite slightly rounded; distal margin of basal endite slightly concave on median region and rounded on tips; undivided endopod, slightly more slender distally, with some plumose setae on proximal region; exopod well developed and undivided, with some plumose setae on proximal region and numerous plumose setae on distal region; proximal and distal lobes of large epipod similar in width. Second maxilliped (Fig. 3E) with protopodite with plumose setae; endopod with 4 articles, merus 5 times as long as dactylus, carpus 3 times as long as dactylus, propodus 12 times as long as dactylus, propodus and dactylus with numerous plumose setae; long, slender, undivided exopod, some plumose setae on proximal region and numerous plumose setae on distal region; podobranch on epipod. Third maxilliped (Fig. 3F) overreaching antennular peduncle; antepenultimate article 0.9 times as long as ultimate article, proximal region with some plumose setae, distal region unarmed or with 1 papillose seta and 0, 1, 2, or 3 spiniform setae, with variable positions; penultimate article 0.3 times as long as ultimate article, with some simple and plumose setae; ultimate article with many simple and plumose setae, tip with 7 or 8 spiniform setae; exopod not reaching distal margin of antepenultimate article, with tuft of plumose setae on tip.

Pereopods without epipods. First pereopod of variable length, not reaching or exceeding half-length of scaphocerite; ischium with 1 or 2 spiniform setae on distal flexor region; merus with 1 or 2, rarely 3, spiniform setae on flexor proximal region; chela slender, fingers 0.6 times as long as palm, both with short setae on cutting edge and tufts of setae on lateral margin. Second pereopod, ischium with 2 or 3 simple and long setae on proximal flexor region; carpus subdivided into 6 articles, length ratio of carpal articles from proximal to distal 2:2:4:2.5:1:2; chela slender, fingers 0.8 times as long as palm, both with tufts of setae on lateral margin. Third pereopod, merus with 1 to 4 lateral spiniform setae on distal region, rarely unarmed or with 5 or 6 spiniform setae, tuft of setae on distal dorsal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 8 to 13 spiniform setae, distal setae paired; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3 spiniform setae on flexor margin in non-prehensile pereopod (females and non-functional males); absence or presence of 1 spiniform seta on prehensile pereopod (functional males). Fourth pereopod, merus with 1 to 3 spiniform setae on distal region, rarely 4, tuft setae on distal dorsal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 8 to 12 spiniform setae, distal setae paired; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3, rarely 1 or 4, spiniform setae on flexor margin. Fifth pereopod, merus unarmed or with 1 spiniform seta on distal region, tuft of setae on distal dorsal region; carpus with tip of dorsal region projected anteriorly; flexor region of propodus with 8 to 12 spiniform setae, distal setae paired, some specimens with tuft of simple setae on distal region of flexor margin; dactylus 0.2 times as long as propodus, distally biunguiculate with 2 or 3, rarely 1 or 4, spiniform setae on flexor margin.

Type locality. Antigua and Barbuda, Antigua, English Harbour.

Distribution. Western Atlantic - USA (North Carolina, Florida), Bermuda, Mexico (Veracruz, Yucatán, Campeche, Quintana Roo), Cuba, Puerto Rico, British Virgin Islands, Anguilla, Saint Kitts and Nevis, Antigua and Barbuda, Guadeloupe, Dominica, Martinique, Saint Lucia, Grenada, Trinidad and Tobago, Curaçao, Honduras, Panama, Venezuela, Brazil (Seamounts of North Chain, Fernando de Noronha, Trindade Island, Ceará, Rio Grande do Norte, Paraíba, Pernambuco, Bahia, São Paulo). Central Atlantic - Ascension Island (Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.; Birkeland et al., 1976Birkeland, C.; Reimer, A.A. and Young, J.R. 1976. Survey of marine communities in Panama and experiments with oil. Report EPA-600/3-76-028. Narrangasett, Environmental Research Laboratory, 177p.; Markham and McDermott, 1980Markham, J.C. and McDermott, J.J. 1980. A tabulation of the Crustacea Decapoda of Bermuda. Proceedings of the Biological Society of Washington, 93: 1266-1276.; Rodríguez, 1980Rodríguez, G. 1980. Los Crustáceos Decápodos de Venezuela. Caracas, Instituto Venezuelano de Investigaciones Científicas, 494p.; Gore, 1981Gore, R.H. 1981. Three new shrimps, and some interesting new records of decapod Crustacea from a deep-water coral reef in the Florida Keys. Proceedings of the Biological Society of Washington, 94: 135-162.; Carvacho, 1982Carvacho, A. 1982. Sur une petite collection de crevettes de la Martinique. Caribbean Journal of Science, 17: 15-20.; Martínez Iglesias, 1986Martínez Iglesias, I.C. 1986. Los crustáceos decápodos del Golfo de Batabanó. Caridea y Penaeidea. Poeyana, 321: 1-37.; Young, 1986Young, P.S. 1986. Análise qualitativa e quantitativa da fauna associada a corais hermatípicos (Coelenterata: Scleractinia) nos recifes de João Pessoa, PB. Revista Brasileira de Biologia, 46: 99-126.; Manning and Chace, 1990Manning, R.B. and Chace, F.A. Jr. 1990. Decapod and stomatopod crustaceans from Ascension Island, south Atlantic Ocean. Smithsonian Contributions to Zoology, 503: 1-91.; Markham et al., 1990Markham, J.C.; Donath-Hernandez, F.E.; Villalobos-Hiriart, J.L. and Diaz-Barriga, A.C. 1990. Notes on the shallow-water marine Crustacea of the Caribbean coast of Quintana Roo, Mexico. Anales del Instituto de Biología Universidad Nacional Autónoma de México, 61: 405-446.; Duarte and Nalesso, 1996Duarte, L.F.L. and Nalesso, R.C. 1996. The sponge Zygomycale parishii (Bowerbank) and its endobiotic fauna. Estuarine, Coastal and Shelf Science, 42: 139-151.; Hernández-Aguilera et al., 1996Hernández-Aguilera, J.L.; Toral-Almazán, R.E. and Ruiz-Nuño, J.A. 1996. Especies catalogadas de crustáceos estomatópodos y decápodos para el Golfo de México, Río Bravo, Tamps. A Progreso, Yuc. Conabio, Dirección de Oceanografia, Secretaría de Marina, México, 132p.; Álvarez et al., 1999Álvarez, F.; Villalobos, J.L.; Rojas, Y. and Robles, R. 1999. Listas y comentarios sobre los crustáceos decápodos de Veracruz, Mexico. Anales del Instituto de Biologia Universidad Nacional Autónoma de México, Série Zoologia, 70: 1-27.; Coelho Filho, 2006Coelho Filho, P.A. 2006. Checklist of the decapods (Crustacea) from the outer continental shelf and seamounts from Northeast of Brazil-REVIZEE Program (NE III). Zootaxa, 1184: 1-27.; De Grave et al., 2006De Grave, S.; Livingston, D. and Speight, M.R. 2006. Diel variation in sea grass dwelling shrimp: when to sample at night? Journal of the Marine Biological Association of the United Kingdom, 86: 1421-1422.; Almeida et al., 2008Almeida, A.O.; Bezerra, L.E.; Souza-Filho, J.F.; Almeida, S.M.; Albuquerque, D.L. and Coelho, P.A. 2008. Decapod and stomatopod crustaceans from Santo Aleixo Island, state of Pernambuco, Brazil. Nauplius, 16: 23-41.; 2012Almeida, A.O.; Boehs, G.; Araújo-Silva, C.L. and Bezerra, L.E.A. 2012. Shallow-water caridean shrimps from southern Bahia, Brazil, including the first record of Synalpheus ul (Ríos & Duffy, 2007) (Alpheidae) in the southwestern Atlantic Ocean. Zootaxa, 3347: 1-35.; Fielder et al., 2010Fiedler, G.C.; Rhyne, A.L.; Segawa, R.; Aotsuka, T. and Schizas, N.V. 2010. The evolution of euhermaphroditism in caridean shrimps: a molecular perspective of sexual systems and systematics. BMC Ecology and Evolution, 10: 297. ; Tavares et al., 2017Tavares, M.; Carvalho, L. and Mendonça, J.B. Jr. 2017. Towards a review of the decapod crustacea from the remote oceanic archipelago of Trindade and Martin Vaz, south Atlantic Ocean: new records and notes on ecology and zoogeography. Papéis Avulsos de Zoologia, 57: 157-176.). Although Chace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.) reported T. manningi from the Pacific coast of Mexico (Islas Tres Marias), those specimens were Thor algicolaWicksten, 1987Wicksten, M.K. 1987. A new species of hippolytid shrimp from the west coast of Mexico. Bulletin of the Southern California Academy of Sciences, 86: 27-33. (see Wicksten, 1987Wicksten, M.K. 1987. A new species of hippolytid shrimp from the west coast of Mexico. Bulletin of the Southern California Academy of Sciences, 86: 27-33.).

Variations. The variations in the length of structures or number of spiniform setae of the pereopods did not show any relation with geographic distribution. The number of spiniform setae on the distal region of the merus of the third and fourth pereopods and on the telson dorsolateral surface may vary on each side of the body of the same specimen.

Genetic data

Final matrices with 520 bp (16S) and 570 bp (COI) were used in the analyses. The best-fitting substitution model for the 16S was TPM3uf + G, with nucleotide frequencies of A = 0.3623, C = 0.1030, G = 0.1797, and T = 0.3550, and gamma distribution = 0.3070. For COI, the best-fitting substitution model was TPM1uf + G, with nucleotide frequencies of A = 0.2894, C = 0.1585, G = 0.1535, and T = 0.3986, and gamma distribution = 0.2240.

We obtained almost the same topology for the phylogeny using the ML and BI analyses. Thus, we selected the ML tree as the basis for discussions, showing bootstrap supporting values, but also including posterior probabilities (expressed as a percentage) for BI analyses (Fig. 4). Both trees recovered T. manningi and T. paulae sp. nov. as two separate lineages with high support values. The T. manningi clade included specimens from Brazil (Pernambuco and São Paulo), Panama, and Puerto Rico; and T. paulae sp. nov. included only specimens from Panama. For the 16S gene, T. manningi and T. paulae sp. nov. were recovered as sister group (Fig. 4A), whereas for COI gene, T. paulae sp. nov. was included in a clade with specimens from T. amboinensis complex and T. hainanensis, being T. manningi sister group of this huge clade (Fig. 4B).

The genetic distance analysis corroborated the phylogenetic reconstruction results. The intraspecific variation of both genes was null for T. manningi and T. paulae sp. nov. In contrast, the values of interspecific variation between these two species were high (16S: 20 %, COI: 23 %). Such values are similar or even higher when these species are compared to different lineages of the T. amboinensis complex (T. manningi - 16S: 18-19 %, COI: 13-17 %; T. paulae sp. nov. - 16S: 20-22, COI: 14-15 %) and T. hainanensis (T. manningi - COI: 22 %; T. paulae sp. nov. - COI: 22 %).

DISCUSSION

This study describes a new species from Panama Atlantic coast (previously identified as T. manningi) and provides remarks on T. manningi, including material from Brazil. The phylogenetic analysis (ML and BI) separating two distinct clades with high support values for both analyzed genes, the presence of a supraorbital prominence in T. manningi (versus absent or vestigial in the new species), and the pterygostomial margin rounded and unarmed in T. manningi (versus angular with one tooth in the new species) showed that these species are clearly separated, based on molecular and morphological data. Moreover, the proximal tooth on the dorsolateral margin of the stylocerite is more developed in the new species than in T. manningi.

Thor paulae sp. nov. is the seventeenth species described for the genus (Tab. 1). The new species can be separated from the other four Atlantic species. The new species differs from T. dobkini, T. floridanus, and T. manningi by the absence or presence of a vestigial supraorbital tooth (versus presence of a prominence in the other three species) and by the pterygostomial margin angular with one tooth (versus rounded and unarmed in the other three species) (see Fig. 1A, and Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179., figs. 57a, 58a, 59a, 60a). Otherwise, T. paulae sp. nov. shares these characters (supraorbital tooth absent and pterygostomial margin angular with one tooth) with T. dicaprio (see Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.). However, T. paulae sp. nov. differs from the latter species in morphology (3 dorsolateral setae on telson versus 4 in T. dicaprio; Fig. 1I; Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517., fig. 1D), by genetics (Fig. 4; 22 % for COI), and by coloration since the new species does not have the “sexy shrimp pattern” as T. dicaprio and other lineages of the T. amboinensis complex (see Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.; photos of T. paulae sp. nov. are available at http://specifyportal.flmnh.ufl.edu/iz/, UF 44518 and UF 44393).

Table 1.
Species of the genus ThorKingsley, 1878Kingsley, J.S. 1878. Notes on the North American Caridea in the Museum of the Peabody Academy of Science at Salem, Mass. Proceedings of the Academy of Natural Sciences of Philadelphia, 1878: 89-98., distribution (underlined type locality) and comparison of some morphological characters.

Thor paulae sp. nov. is morphologically similar to the Pacific Thor cocoensisWicksten and Vargas, 2001Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144. and Thor marguitaeBruce, 1978Bruce, A.J. 1978. Thor marguitae sp. nov., a new hippolytid shrimp from Heron Island, Australia. Crustaceana, 35: 159-169. (Tab. 1) regarding the following characters (Bruce, 1978Bruce, A.J. 1978. Thor marguitae sp. nov., a new hippolytid shrimp from Heron Island, Australia. Crustaceana, 35: 159-169.; Wicksten and Vargas, 2001Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144.; this study): supraorbital tooth absent or vestigial, pterygostomial margin angular, telson bearing 3 pairs of dorsolateral spiniform setae (sometimes 4 in T. cocoensis) and 3 pairs of setae on posterior margin, antennular stylocerite with a proximal tooth on dorsolateral margin, pereopods without epipod, and merus of the first pereopod with some spiniform setae on the flexor proximal region (not described for T. cocoensis by Wicksten and Vargas, 2001Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144., but illustrated in their fig. 4A). Nonetheless, the new species can be distinguished from T. cocoensis by the third carpal article of the second pereopod being longest (versus sixth carpal article the longest in T. cocoensis) and by the rostrum dorsal dentition (4 to 5 in T. paulae sp. nov. versus 1 to 2 in T. cocoensis) (Wicksten and Vargas, 2001Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144.; this study). The new species can be separated from T. marguitae by the chela of the first pereopod not tapering or strongly compressed (versus tapering and clearly compressed in T. marguitae) (Bruce, 1978Bruce, A.J. 1978. Thor marguitae sp. nov., a new hippolytid shrimp from Heron Island, Australia. Crustaceana, 35: 159-169.; this study).

The new species is currently restricted to Bocas del Toro, Panama. One of us (FLM) has collected some individuals previously identified as Thor sp. in the STRI vicinities during a taxonomic field activity in August 2011. The material was deposited in the Zoological Collection of the University of Louisiana, Lafayette (ULLZ) and recently moved to USNM. The identity of this material should be checked in the future since we were not able to do so at the moment due to pandemic restrictions. With the new species, four species of Thor have been reported from the Panama Atlantic coast: T. dicaprio, T. floridanus, T. manningi, and T. paulae sp. nov. (De Grave and Anker, 2017De Grave, S. and Anker, A. 2017. An annotated checklist of marine caridean and stenopodidean shrimps (Malacostraca: Decapoda) of the Caribbean coast of Panama. Nauplius, 25: e2017015. DOI:10.1590/2358-2936e2017015.
https://doi.org/10.1590/2358-2936e201701...
; Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.; this study). However, the records of T. floridanus by Heck (1977Heck, K.L. Jr. 1977. Comparative species richness, composition and abundance of invertebrates in Caribbean seagrass (Thalassa testudinum) meadows (Panama). Marine Biology, 41: 335-348.; 1979Heck, K.L. Jr. 1979. Some determinants of the composition and abundance of motile macroinvertebrate species in tropical and temperate turtlegrass (Thalassia testudinum) meadows. Journal of Biogeography, 6: 183-200. ) could actually refer to T. manningi (see De Grave and Anker, 2017De Grave, S. and Anker, A. 2017. An annotated checklist of marine caridean and stenopodidean shrimps (Malacostraca: Decapoda) of the Caribbean coast of Panama. Nauplius, 25: e2017015. DOI:10.1590/2358-2936e2017015.
https://doi.org/10.1590/2358-2936e201701...
). Our molecular analysis has confirmed the occurrence of at least three species on the Panama Atlantic coast: T. dicaprio, T. manningi, and T. paulae sp. nov. (Fig. 4).

As the new species material has been previously identified as T. manningi, we analyzed specimens of T. manningi from Antigua and Barbuda (holotype), Panama, and Brazil, and added more detail to the original description provided by Chace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.), mainly regarding mouthparts and pereopods. We provide below some comparative observations on this species: the Atlantic T. dobkini, T. manningi, and T. floridanus differ from all other species of the genus by having a small supraorbital prominence; four species have a strong supraorbital tooth (see Tab. 1) and a supraorbital prominence or tooth is absent in the remaining ten species (Tab. 1).

Thor manningi can be separated from T. dobkini by the distal half of flexor margin of merus of first pereopod unarmed (versus armed with 1 or 2 setae in T. dobkini) (Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.). Chace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.) mentioned spines (= spiniform setae) on the proximal half of the flexor margin of the merus of the first pereopod in some specimens of T. manningi and T. floridanus. These setae were also observed in T. manningi.

Chace (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.) mentioned that T. manningi could be separated from T. floridanus based on the number of spinules (= spiniform setae) on the dactylus of the fourth and fifth pereopods (3, sometimes 2 or 4, in T. manningi versus and 4 or 5, rarely 3 or 6, in T. floridanus). However, such characters must be analyzed with caution, considering the possibility of overlap. In this study, only a large female of T. manningi was found with 4 spiniform setae on the dactylus of the fourth and fifth pereopods, which agrees with Chace’s (1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.) report that this condition was rare in the species. Specimens from Brazil have been included in the analysis of T. manningi, expanding the knowledge on the variation of some characters. Analyzing more specimens of T. floridanus is recommended in order to find characters for more precise separation between these closely related species.

Finally, this study included all species with available sequences in a phylogenetic analysis (i.e., only five of the 17 described species), which is not enough to recover and discuss the phylogeny of the genus. Despite this unfavorable scenario, two considerations can be made: T. amboinensis complex is not monophyletic and the hypothesis proposed by Anker and Baeza (2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.) that T. hainanensis “possibly representing one of the clades in Titus et al. (2018Titus, B.M.; Daly, M.; Hamilton, N.; Berumen, M.L. and Baeza, J.A. 2018. Global species delimitation and phylogeography of the circumtropical ‘sexy shrimp’ Thor amboinensis reveals a cryptic species complex and secondary contact in the Indo-West Pacific. Journal of Biogeography, 45: 1275-1287.)” is refuted because here we included the five clades of Titus et al. (2018Titus, B.M.; Daly, M.; Hamilton, N.; Berumen, M.L. and Baeza, J.A. 2018. Global species delimitation and phylogeography of the circumtropical ‘sexy shrimp’ Thor amboinensis reveals a cryptic species complex and secondary contact in the Indo-West Pacific. Journal of Biogeography, 45: 1275-1287.) and T. hainanensis is clearly separate from them. More studies on the phylogenetic relationships of this genus need to be conducted.

Identification key to Thor species worldwide

Remarks on the proposed key: Xu and Li (2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.) mentioned an indistinct tooth on the proximal dorsolateral margin of the stylocerite of T. leptochelus (as Thinora leptochelusXu and Li, 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.) while Komai et al. (2015Komai, T.; Okuno, J. & Minemizu, R. 2015. New records of two species of the coral reef shrimp genus Thor Kingsley 1878 (Crustacea: Decapoda: Thoridae) from the Ryukyu Islands, Japan. Zootaxa, 4013: 399-412.) reported no trace of this tooth; Anker and Baeza (2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.), when describing T. dicaprio, did not report morphological differences between the species and other T. amboinensis lineages, instead only genetics, geography and coloration.

1a. Strong supraorbital tooth present (see Bruce, 1983Bruce, A.J. 1983. Thor spinipes sp. nov., a new hippolytid shrimp from the Cobourg Peninsula, northern Australia. The Beagle, Records of the Northern Territory Museum of Arts and Sciences, 1: 1-10.: fig. 2A-C) ……………...………… 2

1b. Supraorbital tooth reduced to prominence (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 59a) or absent (Fig. 1A) ………………………………………………………………….…………………………….. 5

2a. Posterior margin of telson bearing acute median tooth (see Wicksten, 1996Wicksten, M.K. 1996. A new species of hippolytid shrimp from Rocas Alijos. p. 295-298. In: R.W. Schmieder (ed), Rocas Alijos. Monographiae Biologicae, vol 75. Dordrecht, Springer.: fig. 1O) ….. 3

2b. Posterior margin of telson without acute median tooth (Fig. 1I) …………………………………………………………………………………....…….…….. 4

3a. Posterior margin of telson with 2 pairs of simple setae laterally and 2 pairs of plumose setae centrally (see Bruce, 1976Bruce, A.J. 1976. A report on a small collection of shrimps from the Kenya National Marine Parks at Malindi, with notes on selected species. Zoologische Verhandelingen, 145: 1-72.: fig. 20A) ....….…………………….………..….. T. spinosus

3b. Posterior margin of telson with 2-3 pairs of simple setae (see Wicksten, 1996Wicksten, M.K. 1996. A new species of hippolytid shrimp from Rocas Alijos. p. 295-298. In: R.W. Schmieder (ed), Rocas Alijos. Monographiae Biologicae, vol 75. Dordrecht, Springer.: fig. 1O) …………………………………….………………………………………...……… T. cordelli

4a. Stylocerite with distinct tooth on proximal dorsolateral margin (Fig. 1C) …...…………. ……………………………………………………………………………………… T. spinipes

4b. Stylocerite with indistinct tooth or without tooth on proximal dorsolateral margin (see Xu and Li, 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.: fig. 7D) ………………………………………………………..… T. leptochelus

5a. Pterygostomial margin angular (Fig. 1A) ……………….....……...…...………………… 6

5b. Pterygostomial margin rounded (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 59a) ..……….......…………….. 12

6a. First pereopod with epipod (see Xu and Li, 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.: fig. 35E) .….…………...……………. 7

6b. First pereopod without epipod …….……...………………….…………...……………… 8

7a. Second pereopod with epipod (see Xu and Li, 2015Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.: fig. 35F) ….................... T. singularis

7b. Second pereopod without epipod …….......................................................... T. hainanensis

8a. First pereopod with chela tapering and clearly compressed (see Bruce, 1978Bruce, A.J. 1978. Thor marguitae sp. nov., a new hippolytid shrimp from Heron Island, Australia. Crustaceana, 35: 159-169.: fig. 4A)………..………………………………………………………………….…...T. marguitae

8b. First pereopod with chela not tapering or strongly compressed (Fig. 1G) ………………. 9

9a. Second pereopod with sixth carpal article longest (see Wicksten and Vargas, 2001Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144.: fig. 4B) ………………………………………………………………………..……. T. cocoensis

9b. Second pereopod with third carpal article longest (Fig. 1H) …………………..………. 10

10a. Telson with 3 pairs of dorsolateral spiniform setae (Fig. 1I); absence of “sexy shrimp pattern” coloration ……………………..…………………………………... T. paulae sp. nov.

10b. Telson with 4 pairs of dorsolateral spiniform setae; “sexy shrimp pattern” coloration (see Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.: figs. 1D, 2) …………………………………………………..….... 11

11a. With conspicuous red-white banding of the antennal flagella (see Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.: figs. 2-5); western Atlantic …………………………………….……...…… T. dicaprio

11b. Without red-white banding of the antennal flagella (see Anker and Baeza, 2021Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.: figs. 7-9); Indo-West Pacific, eastern Pacific and eastern Atlantic ............................... T. amboinensis

12a. Telson with 1 pair of barely visible lateral spiniform setae on distal 1/4 of length (see Holthuis, 1947Holthuis, L.B. 1947. The Decapoda of the Siboga Expedition. Part IX. The Hippolytidae and Rhynchocinetidae collected by the Siboga and Snellius expeditions with remarks on other species. Siboga Expedition, 39: 1-100.: fig. 5) ….………………….……………….....……….…….… T. intermedius

12b. Telson with 2-6 pairs of distinct dorsolateral spiniform setae (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 60d) ……………………………………………………………….........………………………… 13

13a. Stylocerite without tooth on proximal dorsolateral margin .…………………..…...…… …………………………………….………………………………………………. T. paschalis

13b. Stylocerite with tooth on proximal dorsolateral margin (Fig. 1C) …..………….…….. 14

14a. Merus of first pereopod armed with 1-2 spiniform setae on distal half of flexor margin (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 57n) ………….……………………………...………...……. T. dobkini

14b. Merus of first pereopod unarmed on distal half of flexor margin (Fig. 1G) ..…..…….. 15

15a. Second pereopod with sixth carpal article longest (see Wicksten, 1987Wicksten, M.K. 1987. A new species of hippolytid shrimp from the west coast of Mexico. Bulletin of the Southern California Academy of Sciences, 86: 27-33.: fig. 2E) .…..… …………….…………….………………………….…………….……………….... T. algicola

15b. Second pereopod with third carpal article longest (Fig. 1H) ……………….………… 16

16a. Fourth and fifth pereopods with dactylus usually armed with 2-3 setae on proximal flexor margin (rarely 1 or 4) (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 59v) ……….......…………… T. manningi

16b. Fourth and fifth pereopods with dactylus usually armed with 4-5 setae on proximal flexor margin (rarely 3 or 6) (see Chace, 1972Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.: fig. 58t) ………..….….. T. floridanus

ACKNOWLEDGEMENTS

The authors are indebted to the following foundations for support during the development of this project: Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) - Finance Code 001 for Master’s Scholarship to APLK; Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (Research Grant 421193/2018-2 to MT; 421963/2016-6 to AOA; PQ 304235/2019-9, 302253/2019-0 and 311340/2021-0 to AOA, FLM and MT, respectively); Fundação de Amparo à Pesquisa do Estado de São Paulo - FAPESP (Temáticos BIOTA 2010/50188-8 and INTERCRUSTA 2018/13685-5 to FLM). Thanks to Amanda Bemis (UF), Felipe Ribeiro (UFRGS), Gabriel Bochini (UFPE), Gustav Paulay (UF), Helena Mathews-Cascon (UFC), John Slapcinsky (UF), and Luis Ernesto Bezerra (LABOMAR/UFC) for loaning, transporting, or allowing the study of material. Special thanks are due to Amanda Windsor for analyzing the holotype of Thor manningi (USNM). Sampling in São Paulo was conducted in accordance with current applicable state and federal laws of Brazil, Permanent license to FLM for collection of Zoological Material no. 11777-1 MMA/IBAMA/SISBIO. Thanks to Fabrício Carvalho, Felipe Ribeiro, Gabriel Bochini, and Luiz Alexandre Campos for suggestions in an early version of this study and to anonymous reviewers for their suggestions to improve the quality of this manuscript during the review process .

REFERENCES

  • Almeida, A.O.; Bezerra, L.E.; Souza-Filho, J.F.; Almeida, S.M.; Albuquerque, D.L. and Coelho, P.A. 2008. Decapod and stomatopod crustaceans from Santo Aleixo Island, state of Pernambuco, Brazil. Nauplius, 16: 23-41.
  • Almeida, A.O.; Boehs, G.; Araújo-Silva, C.L. and Bezerra, L.E.A. 2012. Shallow-water caridean shrimps from southern Bahia, Brazil, including the first record of Synalpheus ul (Ríos & Duffy, 2007) (Alpheidae) in the southwestern Atlantic Ocean. Zootaxa, 3347: 1-35.
  • Álvarez, F.; Villalobos, J.L.; Rojas, Y. and Robles, R. 1999. Listas y comentarios sobre los crustáceos decápodos de Veracruz, Mexico. Anales del Instituto de Biologia Universidad Nacional Autónoma de México, Série Zoologia, 70: 1-27.
  • Amaral, A.C.Z.; Migotto, A.E.; Turra, A. and Schaeffer-Novelli, Y. 2010. Araçá: biodiversidade, impactos e ameaças. Biota Neotropica, 10: 219-264.
  • Anker, A. and Baeza, J.A. 2021. Thor dicaprio sp. nov., a new, conspicuously coloured shrimp from the tropical western Atlantic, with taxonomic remarks on the T. amboinensis (De Man, 1888) complex (Decapoda: Caridea: Thoridae). Zootaxa, 5039: 495-517.
  • Ayón-Parente, M.; Hermoso-Salazar, M.; Hendrickx, M.E.; Galván-Villa, C.M.; Ríos-Jara, E. and Bastida-Izaguirre, D. 2016. The caridean shrimps (Crustacea: Decapoda: Caridea: Alpheoidea, Palaemonoidea, and Processoidea) from Bahía Chamela, Mexico. Revista Mexicana de Biodiversidad, 87: 311-327.
  • Baeza, J.A. and Piantoni, C. 2010. Sexual system, sex ratio, and group living in the shrimp Thor amboinensis (De Man): relevance to resource-monopolization and sex-allocation theories. Biological Bulletin, 219: 151-65.
  • Bauer, R.T. 1985. Diel and seasonal variation in species composition and abundance of caridean shrimps (Crustacea, Decapoda) from seagrass meadows on the north coast of Puerto Rico. Bulletin of Marine Science, 36: 150-162.
  • Bauer, R.T. 1986. Sex change and life history pattern in the shrimp Thor manningi (Decapoda: Caridea): a novel case of partial protandric hermaphroditism. Biological Bulletin, 170: 11-31.
  • Bauer, R.T. and VanHoy, R. 1996. Variation in sexual systems (protandry, gonochorism) and reproductive biology among three species of the shrimp genus Thor (Decapoda: Caridea). Bulletin of Marine Science, 59: 53-73.
  • Birkeland, C.; Reimer, A.A. and Young, J.R. 1976. Survey of marine communities in Panama and experiments with oil. Report EPA-600/3-76-028. Narrangasett, Environmental Research Laboratory, 177p.
  • Boone, L. 1935. The Crustacea: Anomura, Macrura, Euphausiacea, Isopoda, Amphipoda and Echinodermata: Asteroidea and Echinoidea of the “Alva” world cruise, 1931, William K. Vanderbilt, commanding. Bulletin of the Vanderbilt Marine Museum, 6: 1-264.
  • Borradaile, L.A. 1915. Notes on Carides. Annals and Magazine of Natural History, 15: 205-213.
  • Bracken, H.D.; De Grave, S. and Felder, D.L. 2009. Phylogeny of the infraorder Caridea based on mitochondrial and nuclear genes (Crustacea: Decapoda). Crustacean Issues, 18: 281-305.
  • Bruce, A.J. 1976. A report on a small collection of shrimps from the Kenya National Marine Parks at Malindi, with notes on selected species. Zoologische Verhandelingen, 145: 1-72.
  • Bruce, A.J. 1978. Thor marguitae sp. nov., a new hippolytid shrimp from Heron Island, Australia. Crustaceana, 35: 159-169.
  • Bruce, A.J. 1983. Thor spinipes sp. nov., a new hippolytid shrimp from the Cobourg Peninsula, northern Australia. The Beagle, Records of the Northern Territory Museum of Arts and Sciences, 1: 1-10.
  • Carvacho, A. 1979. Les crevettes carides de la mangrove guadeloupéenne. Bulletin du Museum National d'Histoire Naturelle, Section A, Zoologie Biologie et Ecologie, 1: 445-470.
  • Carvacho, A. 1982. Sur une petite collection de crevettes de la Martinique. Caribbean Journal of Science, 17: 15-20.
  • Chace, F.A. Jr. 1972. The shrimps of the Smithsonian-Bredin Caribbean expeditions with a summary of the West Indian shallow-water species (Crustacea: Decapoda: Natantia). Smithsonian Contributions to Zoology, 98: 1-179.
  • Chace, F.A. Jr. 1997. The caridean shrimps (Crustacea: Decapoda) of the Albatross Philippine expedition, 1907-1910, Part 7: Families Atyidae, Eugonatonotidae, Rhynchocinetidae, Bathypalaemonellidae, Processidae, and Hippolytidae. Smithsonian Contributions to Zoology, 587: 1-106.
  • Christoffersen, M.L. 1998. Malacostraca. Eucarida. Caridea. Crangonoidea and Alpheoidea (Except Glyphocrangonidae and Crangonidae). p. 351-372. In: P.S. Young (ed), Catalogue of Crustacea of Brazil. Rio de Janeiro, Museu Nacional. (Série Livros, 6)
  • Coelho, P.A. and Ramos, M.A. 1972. A constituição e a distribuição da fauna de decápodos do litoral leste da América do Sul entre as latitudes de 5ºN e 39ºS. Trabalhos Instituto Oceanográfico Universidade Federal De Pernambuco, 13: 133-236.
  • Coelho Filho, P.A. 2006. Checklist of the decapods (Crustacea) from the outer continental shelf and seamounts from Northeast of Brazil-REVIZEE Program (NE III). Zootaxa, 1184: 1-27.
  • Cubit, J. and Williams, S. 1983. The invertebrates of Galeta Reef (Caribbean Panama): A species list and bibliography. Atoll Research Bulletin, 269: 1-45.
  • Darriba, D.; Taboada, G.L.; Doallo, R. and Posada, D. 2012. jModelTest 2: more models, new heuristics and parallel computing. Nature Methods, 9: 772.
  • De Grave, S. and Anker, A. 2017. An annotated checklist of marine caridean and stenopodidean shrimps (Malacostraca: Decapoda) of the Caribbean coast of Panama. Nauplius, 25: e2017015. DOI:10.1590/2358-2936e2017015.
    » https://doi.org/10.1590/2358-2936e2017015
  • De Grave, S. and Fransen, C.H.J.M. 2011. Carideorum catalogus: the recent species of the dendrobranchiate, stenopodidean, procarididean and caridean shrimps (Crustacea: Decapoda). Zoologische Mededelingen, 89: 195-589.
  • De Grave, S.; Livingston, D. and Speight, M.R. 2006. Diel variation in sea grass dwelling shrimp: when to sample at night? Journal of the Marine Biological Association of the United Kingdom, 86: 1421-1422.
  • De Grave, S.; Li, C.P.; Tsang, L.M.; Chu, K.H. and Chan, T.Y. 2014. Unweaving hippolytoid systematics (Crustacea, Decapoda, Hippolytidae): resurrection of several families. Zoologica Scripta, 43: 496-507.
  • De Man, J.G. 1887-1888. Bericht über die von Herrn Dr. J. Brock im indischen Archipel Gesammelten Decapoden und Stomatopoden. Archiv für Naturgeschichte, 53: 215-600.
  • Drummond, A.J.; Suchard, M.A.; Xie, D. and Rambaut, A. 2012. Bayesian phylogenetics with BEAUti and the BEAST 1.7. Molecular Biology and Evolution, 29: 1969-1973.
  • Duarte, L.F.L. and Nalesso, R.C. 1996. The sponge Zygomycale parishii (Bowerbank) and its endobiotic fauna. Estuarine, Coastal and Shelf Science, 42: 139-151.
  • Edgar, R.C. 2004. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Research, 32: 1792-1797.
  • Fausto-Filho, J. 1970. Quarta contribuição ao inventário dos crustáceos decápodos marinhos do nordeste brasileiro. Arquivos de Ciências do Mar, 10: 55-60.
  • Felder, D.L.; Álvarez, F.; Goy, J.W. and Lemaitre, R. 2009. Decapoda (Crustacea) of the Gulf of Mexico, with comments on the Amphionidacea. p. 1019-1104. In: D.L. Felder and D.K. Camp (eds), Gulf of Mexico Origin, Waters, and Biota, Vol. 1, Biodiversity. Texas, Texas A&M University Press.
  • Fiedler, G.C.; Rhyne, A.L.; Segawa, R.; Aotsuka, T. and Schizas, N.V. 2010. The evolution of euhermaphroditism in caridean shrimps: a molecular perspective of sexual systems and systematics. BMC Ecology and Evolution, 10: 297.
  • Gore, R.H. 1981. Three new shrimps, and some interesting new records of decapod Crustacea from a deep-water coral reef in the Florida Keys. Proceedings of the Biological Society of Washington, 94: 135-162.
  • Hall, T.A. 2005. BioEdit 7.0.5. North Carolina State University, Department of Microbiology. Available at Available at https://bioedit.software.informer.com/7.0/ Accessed on 15 June 2021.
    » https://bioedit.software.informer.com/7.0/
  • Heck, K.L. Jr. 1977. Comparative species richness, composition and abundance of invertebrates in Caribbean seagrass (Thalassa testudinum) meadows (Panama). Marine Biology, 41: 335-348.
  • Heck, K.L. Jr. 1979. Some determinants of the composition and abundance of motile macroinvertebrate species in tropical and temperate turtlegrass (Thalassia testudinum) meadows. Journal of Biogeography, 6: 183-200.
  • Heck, K.L. Jr and Wetstone, G.S. 1977. Habitat complexity and invertebrate species richness and abundance in tropical seagrass meadows. Journal of Biogeography, 4: 135-142.
  • Heller, C. 1861. Beiträge zur Crustaceen-Fauna des rothen Meeres. Zweiter Theil. Sitzungsberichte der mathematisch-naturwissenschaftlichen Classe der Kaiserlichen Akademie der Wissenschaften in Wien, 44: 241-295.
  • Hernández-Aguilera, J.L.; Toral-Almazán, R.E. and Ruiz-Nuño, J.A. 1996. Especies catalogadas de crustáceos estomatópodos y decápodos para el Golfo de México, Río Bravo, Tamps. A Progreso, Yuc. Conabio, Dirección de Oceanografia, Secretaría de Marina, México, 132p.
  • Holthuis, L.B. 1947. The Decapoda of the Siboga Expedition. Part IX. The Hippolytidae and Rhynchocinetidae collected by the Siboga and Snellius expeditions with remarks on other species. Siboga Expedition, 39: 1-100.
  • Khan, R.N.; Becker, J.H.; Crowther, A.L. and Lawn, I.D. 2004. Spatial distribution of symbiotic shrimps (Periclimenes holthuisi, P. brevicarpalis, Thor amboinensis) on the sea anemone Stichodactyla haddoni Journal of the Marine Biological Association of the United Kingdom, 84: 201-203.
  • Kingsley, J.S. 1878. Notes on the North American Caridea in the Museum of the Peabody Academy of Science at Salem, Mass. Proceedings of the Academy of Natural Sciences of Philadelphia, 1878: 89-98.
  • Kingsley, J.S. 1879. List of the North American Crustacea belonging to the suborder Caridea. Bulletin of the Essex Institute, 10: 53-71.
  • Komai, T.; Okuno, J. & Minemizu, R. 2015. New records of two species of the coral reef shrimp genus Thor Kingsley 1878 (Crustacea: Decapoda: Thoridae) from the Ryukyu Islands, Japan. Zootaxa, 4013: 399-412.
  • Kumar, S.; Stecher, G. and Tamura, K. 2016. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Molecular Biology and Evolution, 33: 1870-1874.
  • Leach, W.E. 1815-1875. Malacostraca Podophthalmata Britanniae; or descriptions of such British species of the Linnean genus Cancer as have their eyes elevated on footstalks. London, J. Sowerby, 124p.
  • Madhavan, M.; Purushothaman, P.; Akash, S.; Bharathi, S.; Jose, S.; Dhinakaran, A.; Ravi, C.; Kumar, T. and Lal, K. 2019. New record of Thor hainanensis Xu & Li, 2014 and taxonomical remarks on Lysmata ternatensis de Man, 1902 (Decapoda: Thoridae & Lysmatidae) from the Lakshadweep Islands, India. Zootaxa, 4624: 351-364.
  • Manning, R.B. and Chace, F.A. Jr. 1990. Decapod and stomatopod crustaceans from Ascension Island, south Atlantic Ocean. Smithsonian Contributions to Zoology, 503: 1-91.
  • Mariño, J.; Mendoza, M.D. and López-Sánchez, B. 2018. Composition and abundance of decapod crustaceans in mixed seagrass meadows in the Paraguana Peninsula, Venezuela. Iheringia. Série Zoologia, 108: e2018004.
  • Markham, J.C. and McDermott, J.J. 1980. A tabulation of the Crustacea Decapoda of Bermuda. Proceedings of the Biological Society of Washington, 93: 1266-1276.
  • Markham, J.C.; Donath-Hernandez, F.E.; Villalobos-Hiriart, J.L. and Diaz-Barriga, A.C. 1990. Notes on the shallow-water marine Crustacea of the Caribbean coast of Quintana Roo, Mexico. Anales del Instituto de Biología Universidad Nacional Autónoma de México, 61: 405-446.
  • Martínez Iglesias, I.C. 1986. Los crustáceos decápodos del Golfo de Batabanó. Caridea y Penaeidea. Poeyana, 321: 1-37.
  • Miller, M.A.; Pfeiffer, W. and Scheartz, T. 2010. Creating the CIPRES Science Gateway for inference of large phylogenetic trees. p. 1-8. In: Proceedings of the Gateway Computing Environments Workshop (GCE), New Orleans, Louisiana, USA.
  • Morgado, E.H. and Tanaka, M.O. 2001. The macrofauna associated with the bryozoan Schizoporella errata (Walters) in southeastern Brazil. Scientia Marina, 65: 173-181.
  • Rambaut, A.; Drummond, A.J.; Xie, D.; Baele, G. and Suchard, M.A. 2018. Posterior summarisation in Bayesian phylogenetics using Tracer 1.7. Systematic Biology, 67: 901-904.
  • Rodríguez, G. 1980. Los Crustáceos Decápodos de Venezuela. Caracas, Instituto Venezuelano de Investigaciones Científicas, 494p.
  • Romero-Rodríguez, J. and Álvarez, F. 2020. Bopyrinella hadrocoxalis sp. nov. and Loki circumsaltanus Markham (Isopoda: Bopyridae) parasitizing shrimps of the genus Thor (Decapoda: Thoridae) in Mexican waters. Zootaxa, 4808: 560-570.
  • Ronquist, F.; Teslenko, M.; Van Der Mark, P.; Ayres, D.L.; Darling, A.; Höhna, S.; Larget, B.; Liu, L.; Suchard, M.A. and Huelsenbeck, J.P. 2012. MrBayes 3.2: efficient Bayesian phylogenetic inference and model choice across a large model space. Systematic Biology, 61: 539-542.
  • Schubart, C.D. and Huber, M.G.J. 2006. Genetic comparisons of German populations of the stone crayfish, Austropotamobius torrentium (Crustacea: Astacidae). Bulletin Français de la Pêche et de la Pisciculture, 380-381: 1019-1028.
  • Schubart, C.D.; Cuesta, J.A. and Felder, D.L. 2002. Glyptograpsidae, a new brachyuran family from Central America: larval and adult morphology, and a molecular phylogeny of the Grapsoidea. Journal of Crustacean Biology, 22: 28-44.
  • Schubart, C.D.; Neigel, J.E. and Felder, D.L. 2000. Use of the mitochondrial 16S rRNA gene for phylogenetic and population studies of Crustacea. Crustacean Issues, 12: 817-830.
  • Stamatakis, A. 2014. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics, 30: 1312-1313.
  • Tavares, M.; Carvalho, L. and Mendonça, J.B. Jr. 2017. Towards a review of the decapod crustacea from the remote oceanic archipelago of Trindade and Martin Vaz, south Atlantic Ocean: new records and notes on ecology and zoogeography. Papéis Avulsos de Zoologia, 57: 157-176.
  • Terossi, M.; De Grave, S. and Mantelatto, F.L. 2017. Global biogeography, cryptic species and systematic issues in the shrimp genus Hippolyte Leach 1814 (Decapoda: Caridea: Hippolytidae) by multimarker analyses. Scientific Reports, 7: 6697.
  • Terossi, M.; Almeida, A.O.; Buranelli, R.C.; Castilho, A.L.; Costa, R.C.; Zara, F.J. and Mantelatto, F.L. 2018. Checklist of decapods (Crustacea) from the coast of the São Paulo state (Brazil) supported by integrative molecular and morphological data: I. Infraorder Caridea: families Hippolytidae, Lysmatidae, Ogyrididae, Processidae and Thoridae. Zootaxa, 4370: 76-94.
  • Titus, B.M.; Daly, M.; Hamilton, N.; Berumen, M.L. and Baeza, J.A. 2018. Global species delimitation and phylogeography of the circumtropical ‘sexy shrimp’ Thor amboinensis reveals a cryptic species complex and secondary contact in the Indo-West Pacific. Journal of Biogeography, 45: 1275-1287.
  • Wicksten, M.K. 1987. A new species of hippolytid shrimp from the west coast of Mexico. Bulletin of the Southern California Academy of Sciences, 86: 27-33.
  • Wicksten, M.K. 1996. A new species of hippolytid shrimp from Rocas Alijos. p. 295-298. In: R.W. Schmieder (ed), Rocas Alijos. Monographiae Biologicae, vol 75. Dordrecht, Springer.
  • Wicksten, M.K. 2005. 4. Hippolytid shrimps. p. 98-118. In: J.L. Hernández-Aguilera, J.A. Ruiz-Nuño, R.E. Toral-Almazán and V. Arenas-Fuentes (eds), Camarones, Langostas y Cangrejos de la Costa Este de México. México, DF, Econatura-CONABIO.
  • Wicksten, M.K. and Vargas, R. 2001. A new species of Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea: Hippolytidae) from the tropical eastern Pacific. Proceedings of the Biological Society of Washington, 114: 139-144.
  • Williams, A.B. 1984. Shrimps, lobsters, and crabs of the Atlantic coast of the eastern United States, Maine to Florida. Washington D.C., Smithsonian Institution Press, 550p.
  • WoRMS 2022. Thor Kingsley, 1878. Accessed at: Accessed at: https://www.marinespecies.org/aphia.php?p=taxdetails&id=106995 Accessed on 15 february 2022.
    » https://www.marinespecies.org/aphia.php?p=taxdetails&id=106995
  • Xu, P. and Li, X.Z. 2014. A new species of the hippolytid shrimp genus Thor Kingsley, 1878 (Crustacea: Decapoda: Caridea) from Hainan Island, China. Zootaxa, 3795: 394-400.
  • Xu, P. and Li, X.Z. 2015. Report on the Hippolytidae Bate (sensu lato) from China seas. Systematic Zoology, 40: 107-165.
  • Young, P.S. 1986. Análise qualitativa e quantitativa da fauna associada a corais hermatípicos (Coelenterata: Scleractinia) nos recifes de João Pessoa, PB. Revista Brasileira de Biologia, 46: 99-126.

Publication Dates

  • Publication in this collection
    17 Oct 2022
  • Date of issue
    2022

History

  • Received
    28 Nov 2021
  • Accepted
    24 Feb 2022
Sociedade Brasileira de Carcinologia Instituto de Biociências, UNESP, Campus Botucatu, Rua Professor Doutor Antônio Celso Wagner Zanin, 250 , Botucatu, SP, 18618-689 - Botucatu - SP - Brazil
E-mail: editor.nauplius@gmail.com