In honor of conservation of the Brazilian Atlantic Forest: description of two new damselflies of the genus <i><i>Forcepsioneura</i></i> discovered in private protected areas (Odonata: Coenagrionidae)

Pinto, Ângelo Parise; Kompier, Tom

doi:10.3897/zoologia.35.e21351

ABSTRACT

Two new Brazilian Protoneurinae damselflies, Forcepsioneura regua sp. nov. (holotype male deposited in DZRJ: Brazil, Rio de Janeiro State, Cachoeiras de Macacu municipality, RPPN Reserva Ecológica de Guapiaçu) and Forcepsioneura serrabonita sp. nov. (holotype male deposited in DZRJ: Brazil, Bahia State, Camacan municipality, RPPNs Serra Bonita) , are described, illustrated and diagnosed based on males and females. The bluish and smaller F. regua sp. nov. has been confused with at least three previously described species, being very similar to the type species of Forcepsioneura, F. garrisoni Lencioni, 1999, but lacking a defined tubercle-like process on the posterolateral margin of the median lobe of the prothorax in both sexes, which allows it to be distinguished from all other known species. The shape of the cercus of the male of F. serrabonita sp. nov. is similar to that of F. grossiorum Machado, 2001 and F. lucia Machado, 2000, two species with very short ventrobasal process. However, it differs from them mainly by the mediobasal process of the cercus, which is rounded in dorsal view and almost not visible in lateral view. The taxonomic status of Forcepsioneura is discussed and a comparison with the other species of the genus is provided. Based on size, habitat and coloration, Forcepsioneura can be informally divided into two groups: (1) large, orange-black and montane species, including F. grossiorum, F. itatiaiae (Santos, 1970), F. lucia and F. serrabonita sp. nov.; (2) small, bluish and lowland species, including F. garrisoni, F. haerteli Machado, 2001, F. regua sp. nov. and F. sancta (Hagen in Selys, 1860). Our findings highlight the urgency in directing collecting efforts to unexplored areas, as well as the importance of private preserves that harbor the type localities as guardians of the threatened and diverse Atlantic Forest diversity. Together these two localities surveyed account for more than 210 species of odonates, representing almost 24% of the number of Brazilian species. Brazil has the greatest number of known species of odonates in the world. This study shows that further research is required in order to fully understand the diversity of Forcepsioneura.

KEY WORDS:
Amazoneura; dragonfly; damselfly; Protoneurinae; Southeastern Brazil; taxonomy

INTRODUCTION

“…forest cover must be important for adults of the majority of neotropical Odonata. Every effort should be made to preserve forests and forest wetlands in this most biodiverse region of the Earth” (Paulson 2006Paulson DR (2006). The importance of forests to neotropical dragonflies. In: Rivera AC (Ed) Forests and dragonflies: fourth WDA International Symposium of Odonatology, Pontevedra (Spain), July 2005. Pensoft, Sofia , 79-101.: 97).

The quotation above illustrates the relevance of forests for the conservation of the insects of the order Odonata, popularly known as dragonflies and damselflies. Life on Earth is facing the sixth mass extinction in the planet’s geological history (Barnosky et al. 2011Barnosky AD, Matzke N, Tomiya S, Wogan GO, Swartz B, Quental TB, Marshall C, McGuire JL, Lindsey EL, Maguire KC, Mersey B, Ferrer EA (2011) Has the Earth’s sixth mass extinction already arrived? Nature 471(7336): 51-57. https://doi.org/10.1038/nature09678
https://doi.org/10.1038/nature09678... ). Distinct from the past, when natural processes caused extinctions, for example, the meteorite impact that ended the era of the giant ‘reptiles’ and caused the last big extinction event in the Cretaceous Period (Jablonski 2001Jablonski D (2001) Lessons from the past: evolutionary impacts of mass extinctions. Proceedings of the National Academy of Sciences 98(10): 5393-5398. https://doi.org/10.1073/pnas.101092598
https://doi.org/10.1073/pnas.101092598... , Barnosky et al. 2011Barnosky AD, Matzke N, Tomiya S, Wogan GO, Swartz B, Quental TB, Marshall C, McGuire JL, Lindsey EL, Maguire KC, Mersey B, Ferrer EA (2011) Has the Earth’s sixth mass extinction already arrived? Nature 471(7336): 51-57. https://doi.org/10.1038/nature09678
https://doi.org/10.1038/nature09678... ), the current high rate of biodiversity loss mostly results from human activities. This has led to this epoch being baptized as the Anthropocene (e.g., Crutzen and Stoermer 2000Crutzen PJ, Stoermer EF (2000) The “Anthropocene”. Global Change Newsletter 41: 17-18. http://www.igbp.net/download/18.316f18321323470177580001401/1376383088452/NL41.pdf
http://www.igbp.net/download/18.316f1832... ). As a consequence of the high demand for energy, crop production, and encroachment on natural habitats by urbanization, ecosystems are under strong pressure, causing what has been coined of Biodiversity Crisis (e.g., Singh 2002Singh JS (2002) The biodiversity crisis: a multifaceted review. Current Science 82(6): 638-647. http://www.jstor.org/stable/24106689
http://www.jstor.org/stable/24106689... ).

Amongst the severely threatened areas of the biosphere, the Atlantic Forest (AF) is recognized as an area of immense species diversity and, for some groups of plants, such as Bromeliaceae, the richest one (Martinelli et al. 2008Martinelli G, Vieira CM, Gonzalez M, Leitman P, Piratininga A, da Costa AF, Forzza RC (2008) Bromeliaceae da Mata Atlântica brasileira: lista de espécies, distribuição e conservação. Rodriguésia 59(1): 209-258. http://www.jstor.org/stable/23499386
http://www.jstor.org/stable/23499386... ). Originally, the very complex and heterogeneous AF encompassed about 1,500,000 km², mainly along the Brazilian Atlantic Coast (including also small areas in Paraguay and Argentina), and it is estimated that now has been reduced to less than 12% (Ribeiro et al. 2009Ribeiro MC, Metzger JP, Martensen AC, Ponzoni FJ, Hirota MM (2009) The Brazilian Atlantic Forest: How much is left, and how is the remaining forest distributed? Implications for conservation. Biological Conservation 142(6): 1141-1153. https://doi.org/10.1016/j.biocon.2009.02.021
https://doi.org/10.1016/j.biocon.2009.02... ). The domain, most often referred to as a biome, is composed by herbaceous-arbustive restinga vegetation at sea level, trade off by pluvial forests with tall canopies in the lowland, up to highland fields known as Campos Rupestres of the Southeastern Brazilian Páramos (Safford 1999Safford HD (1999) Brazilian Páramos I. An introduction to the physical environment and vegetation of the campos de altitude. Journal of Biogeography 26(4): 693-712. https://doi.org/10.1046/j.1365-2699.1999.00313.x
https://doi.org/10.1046/j.1365-2699.1999... , Ribeiro et al. 2009Ribeiro MC, Metzger JP, Martensen AC, Ponzoni FJ, Hirota MM (2009) The Brazilian Atlantic Forest: How much is left, and how is the remaining forest distributed? Implications for conservation. Biological Conservation 142(6): 1141-1153. https://doi.org/10.1016/j.biocon.2009.02.021
https://doi.org/10.1016/j.biocon.2009.02... ). Due to its high levels of biodiversity, endemism, and anthropic pressures, it is considered one of 34 hotspots for conservation (Myers et al. 2000Myers N, Mittermeier RA, Mittermeier CG, Da Fonseca GA, Kent J (2000) Biodiversity hotspots for conservation priorities. Nature 403(6772): 853-858. https://doi.org/10.1038/35002501
https://doi.org/10.1038/35002501... , Mittermeier et al. 2011Mittermeier RA, Turner WR, Larsen FW, Brooks TM, Gascon C (2011) Global biodiversity conservation: the critical role of hotspots. In: Zachos F, Habel J (Eds) Biodiversity Hotspots. Springer, Berlin, Heidelberg, 3-22. https://doi.org/10.1007/978-3-642-20992-5_1
https://doi.org/10.1007/978-3-642-20992-... ), even the hottest (Laurance 2009Laurance WF (2009) Conserving the hottest of the hotspots. Biological Conservation 142(6): 1137. https://doi.org/10.1016/j.biocon.2008.10.011
https://doi.org/10.1016/j.biocon.2008.10... ). Its area corresponds to the Parana biogeographical dominion sensu Morrone (2014Morrone JJ (2014) Biogeographical regionalisation of the Neotropical region. Zootaxa 3782(1): 1-110. https://doi.org/10.11646/zootaxa.3782.1.1
https://doi.org/10.11646/zootaxa.3782.1.... ). As far as Odonates are concerned, the AF holds about 50% of the 878 known Brazilian species (data based on Pinto 2017Pinto AP (2017) Odonata. In: Boeger WA, Zaher H, Rafael JA, Valim MP. Taxonomic Catalog of the Brazilian Fauna. PNUD. http://fauna.jbrj.gov.br/fauna/faunadobrasil/171 [Accessed: 26/09/2017]
http://fauna.jbrj.gov.br/fauna/faunadobr... ). However, its original cover corresponds to the most densely populated part of the country, and encompasses, for instance, huge metropolitan areas such as the megacities of São Paulo and Rio de Janeiro, that are among the thirty largest urban centers of the world (UN 2015UN (2015) World Urbanization Prospects: The 2014 Revision. United Nations (UN), Department of Economic and Social Affairs PD, New York, 493 pp.). The species of ForcepsioneuraLencioni, 1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... inhabit this threatened domain. The genus includes small Protoneurinae damselflies that, with the exception of specimens identified as F. sancta (Hagen in Selys, 1860) from the Cerrado domain of the Brazilian central plateau (see records in Pessacq et al. 2012Pessacq P, Santos TC, Costa JM (2012) Checklist and updated distribution of Protoneuridae from Brazil. International Journal of Odonatology 15(2): 59-73. https://doi.org/10.1080/13887890.2012.672158
https://doi.org/10.1080/13887890.2012.67... ), are restricted to the AF.

Protoneuridae s.l., as defined by Tillyard (1917Tillyard RJ (1917) The biology of dragonflies (Odonata or Paraneuroptera). Cambridge, University Press, 386 pp.), comprises what Tillyard and Fraser (1938Tillyard RJ, Fraser FC (1938) A reclassification of the order Odonata. Australian Zoologist 9: 125-169.: 164) formerly recognized as two parallel series of damselflies with reduced wing venation: the first series encompassing a small homogenous group of genera from the New World, and a second, clearly heterogeneous series from the Old World. Since Tillyard and Fraser (1938Tillyard RJ, Fraser FC (1938) A reclassification of the order Odonata. Australian Zoologist 9: 125-169.), more genera and species have been added to this unnatural assembly, contributing for its original concept representing a polyphyletic group (see Pessacq 2008Pessacq P (2008) Phylogeny of Neotropical Protoneuridae (Odonata: Zygoptera) and a preliminary study of their relationship with related families. Systematic Entomology 33(3): 511-528. https://doi.org/10.1111/j.1365-3113.2007.00414.x
https://doi.org/10.1111/j.1365-3113.2007... , Dijkstra et al. 2014Dijkstra K-DB, Kalkman VJ, Dow RA, Stokvis FR, van Tol J (2014) Redefining the damselfly families: the first comprehensive molecular phylogeny of Zygoptera (Odonata). Systematic Entomology 39(1): 68-96. https://doi.org/10.1111/syen.12035
https://doi.org/10.1111/syen.12035... ). However, the almost exclusively Neotropical representatives from the New World series (Protoneurinae sensu Bridges 1994Bridges CA (1994) Catalogue of the Family-Group, Genus-Group and Species-Group Names of the Odonata of the World (3rd end). Privately published, Urbana, Illinois, 905 pp. https://doi.org/10.5962/bhl.title.15291
https://doi.org/10.5962/bhl.title.15291... : IV.7), containing the type genus Protoneura Selys in Sagra, 1857, and fifteen other genera, were recovered as monophyletic, nested within Coenagrionidae in several analyses (Rehn 2003Rehn AC (2003) Phylogenetic analysis of higher-level relationships of Odonata. Systematic Entomology 28(2): 181-240. https://doi.org/10.1046/j.1365-3113.2003.00210.x
https://doi.org/10.1046/j.1365-3113.2003... , O’Grady and May 2003O’Grady EW, May ML (2003) A phylogenetic reassessment of the subfamilies of Coenagrionidae (Odonata: Zygoptera). Journal of Natural History 37(23): 2807-2834. https://doi.org/10.1080/0022293021000007453
https://doi.org/10.1080/0022293021000007... , Bybee et al. 2008Bybee SM, Ogden TH, Branham MA, Whiting MF (2008) Molecules, morphology and fossils: a comprehensive approach to odonate phylogeny and the evolution of the odonate wing. Cladistics 24(4): 477-514. https://doi.org/10.1111/j.1096-0031.2007.00191.x
https://doi.org/10.1111/j.1096-0031.2007... , Pessacq 2008Pessacq P (2008) Phylogeny of Neotropical Protoneuridae (Odonata: Zygoptera) and a preliminary study of their relationship with related families. Systematic Entomology 33(3): 511-528. https://doi.org/10.1111/j.1365-3113.2007.00414.x
https://doi.org/10.1111/j.1365-3113.2007... , Dijkstra et al. 2014Dijkstra K-DB, Kalkman VJ, Dow RA, Stokvis FR, van Tol J (2014) Redefining the damselfly families: the first comprehensive molecular phylogeny of Zygoptera (Odonata). Systematic Entomology 39(1): 68-96. https://doi.org/10.1111/syen.12035
https://doi.org/10.1111/syen.12035... ). Restraining true protoneurids to its Western Hemisphere members is an old hypothesis (see Watson 1992Watson JAL (1992) The subfamilies of Protoneuridae (Zygoptera). Odonatologica 21(2): 195-201. http://natuurtijdschriften.nl/download?type=document;docid=591986
http://natuurtijdschriften.nl/download?t... ), but even its monophyly is not free from controversy (see Pimenta et al. 2015Pimenta AL, Pinto AP, Takiya DM (2015) A first look at the phylogenetic relationships of Forcepsioneura and related genera (Coenagrionidae: Protoneurinae). ICO 2015 - International Congress of Odonatology. WDA, Argentina, 15-20.). However, considering that the monophyly of the New World protoneurids is demonstrated as highly supported, its familial status is justified, with other monophyletic groups of genera in Coenagrionidae s.l. each receiving similar level. It is contrary to recent proposals to decrease the rank level of both Pseudostigmatidae (Ingley et al. 2012Ingley SJ, Bybee SM, Tennessen KJ, Whiting MF, Branham MA (2012) Life on the fly: phylogenetics and evolution of the helicopter damselflies (Odonata, Pseudostigmatidae). Zoologica Scripta 41(6): 637-650. https://doi.org/10.1111/j.1463-6409.2012.00555.x
https://doi.org/10.1111/j.1463-6409.2012... ) and Protoneuridae (Dijkstra et al. 2014Dijkstra K-DB, Kalkman VJ, Dow RA, Stokvis FR, van Tol J (2014) Redefining the damselfly families: the first comprehensive molecular phylogeny of Zygoptera (Odonata). Systematic Entomology 39(1): 68-96. https://doi.org/10.1111/syen.12035
https://doi.org/10.1111/syen.12035... ) due to these being phylogenetically nested within Coenagrionidae s.l.

South American protoneurids are mostly small sized odonates living near or within forested areas. They are generally weak fliers, frequenting shaded areas near the shoreline of large freshwater bodies and numerous running water environments. Because of very thin general aspect and disruptive colors, protoneurids are difficult to be found in the field, being often overlooked by regular collectors.

Today’s Brazilian fauna counts with 70 species of Protoneurinae in 12 genera (Pessacq et al. 2012Pessacq P, Santos TC, Costa JM (2012) Checklist and updated distribution of Protoneuridae from Brazil. International Journal of Odonatology 15(2): 59-73. https://doi.org/10.1080/13887890.2012.672158
https://doi.org/10.1080/13887890.2012.67... , Pinto 2017Pinto AP (2017) Odonata. In: Boeger WA, Zaher H, Rafael JA, Valim MP. Taxonomic Catalog of the Brazilian Fauna. PNUD. http://fauna.jbrj.gov.br/fauna/faunadobrasil/171 [Accessed: 26/09/2017]
http://fauna.jbrj.gov.br/fauna/faunadobr... ), including the endemic Forcepsioneura. This genus was described to include Phasmoneura ciganae Santos, 1970 and its type species Forcepsioneura garrisoniLencioni, 1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... (Lencioni 1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... ). Independently, Angelo B.M. Machado in the same year proposed P. ciganae as a junior synonym of Phasmoneura sancta Hagen in Selys, 1860 (Machado 1999Machado ABM (1999) Studies on neotropical Protoneuridae 9. Phasmoneura ciganae Santos, conspecific with Phasmoneura sancta (Hagen) comb. nov. (Zygoptera). Notulae Odonatologica 5(3): 37-38. http://natuurtijdschriften.nl/record/593639
http://natuurtijdschriften.nl/record/593... ). Indeed, Machado, in a series of seminal works (“Studies on Neotropical Protoneuridae”), was the first author to suggest that P. sancta would need to be transferred to its own genus (see Machado 1985Machado ABM (1985) Studies on neotropical Protoneuridae. 5. Redescription of the type of Phasmoneura ephippigera (Selys, 1886) (Zygoptera). Odonatologica 14(4): 363-368. http://natuurtijdschriften.nl/record/591723
http://natuurtijdschriften.nl/record/591... ) and he (Machado 2000Machado ABM (2000) Studies on neotropical Protoneuridae. 10. Forcepcioneura lucia sp. nov. from the Parque Estadual Rola Moça, Minas Gerais, Brazil (Odonata, Zygoptera). Boletim Museu de Biologia Mello Leitão, Nova Série 11/12: 127-134. http://www.boletimmbml.net/pdf/11_07.pdf
http://www.boletimmbml.net/pdf/11_07.pdf... , 2001Machado ABM (2001) Studies on neotropical Protoneuridae. 11. Two new species of Forcepsioneura Lencioni (Odonata-Zygoptera) with a key to the males of the genus. Revista Brasileira de Zoologia 18(3): 845-854. https://doi.org/10.1590/S0101-81752001000300021
https://doi.org/10.1590/S0101-8175200100... , 2005Machado ABM (2005) Forcepsioneura grossiorum spec. nov. from Brazil (Zygoptera: Protoneuridae) [Studies on neotropical Protoneuridae, 17.]. Odonatologica 34(2): 169-172. http://natuurtijdschriften.nl/record/592511
http://natuurtijdschriften.nl/record/592... ) described half of the six currently valid species of Forcepsioneura.

Forcepsioneura belongs to a poorly-supported monophyletic group of six genera, along with AmazoneuraMachado, 2004Machado ABM (2004) Studies on Neotropical Protoneuridae. 15. Amazoneura gen. nov. with description of A. juruaensis sp. nov. (Odonata: Zygoptera). Revista Brasileira de Zoologia 21(2): 333-336. https://doi.org/10.1590/S0101-81752004000200029
https://doi.org/10.1590/S0101-8175200400... , Lamproneura De Marmels, 2003, Roppaneura Santos, 1966, Phasmoneura Williamson, 1916, and Psaironeura Williamson, 1915 (Pessacq 2008Pessacq P (2008) Phylogeny of Neotropical Protoneuridae (Odonata: Zygoptera) and a preliminary study of their relationship with related families. Systematic Entomology 33(3): 511-528. https://doi.org/10.1111/j.1365-3113.2007.00414.x
https://doi.org/10.1111/j.1365-3113.2007... ), i.e., the Roppaneura clade. All of them have cubitus anterior (CuA) and cubitus posterior plus anal anterior (CuP&AA) veins indistinct (except in Lamproneura), antennifer non-carinated dorsally, and male cercus with ventrobasal process and genital ligula with long recurved lateral lobes (Pessacq 2008Pessacq P (2008) Phylogeny of Neotropical Protoneuridae (Odonata: Zygoptera) and a preliminary study of their relationship with related families. Systematic Entomology 33(3): 511-528. https://doi.org/10.1111/j.1365-3113.2007.00414.x
https://doi.org/10.1111/j.1365-3113.2007... ). The monophyly of this group, as well as that of other formerly erected taxa in Protoneurinae, is uncertain and currently under investigation (Pimenta et al. 2015Pimenta AL, Pinto AP, Takiya DM (2015) A first look at the phylogenetic relationships of Forcepsioneura and related genera (Coenagrionidae: Protoneurinae). ICO 2015 - International Congress of Odonatology. WDA, Argentina, 15-20.).

From the six species currently recognized in Forcepsioneura, only F. sancta was described a long time ago. Most species were discovered recently, thanks to field-works in poor explored areas, and undescribed species are often reported in the literature (e.g., Kompier 2015Kompier T (2015). A guide to the dragonflies and damselflies of the Serra dos Orgaos [sic] South-easthern Brazil. Brussels, REGUA Publications, 379 pp.). At least five undescribed species of Forcepsioneura, all from the Brazilian Atlantic Forest, were detected by the first author.

In recognition of conservation efforts to protect AF remnants, we describe here two previously unknown damselflies of “Protoneuridae s.s.” (Coenagrionidae: Protoneurinae) recently collected in the states of Bahia and Rio de Janeiro, Brazil. These new damselflies were discovered in protected areas maintained thanks to private associations. The Brazilian AF is one of the most threatened biotic domains of the biosphere, and given its fragmentation and fragility, all conservation actions, including private sector initiatives, must be applauded for their contribution to both the scientific community and society in general.

MATERIAL AND METHODS

Specimens examined are deposited in the following collections. Acronyms, wherever possible, based on the updated version of Arnett et al. (1993Arnett Jr RH, Samuelson GA, Nishida GM (1993) The Insect and Spider Collections of the World (2nd end). Sandhill Crane Press, Gainesville, 310 pp.) by Evenhuis (2016Evenhuis NL (2016) Abbreviations for insect and spider collections of the world. http://hbs.bishopmuseum.org/codens/codens-inst.html [Accessed: 30/11/2016]
http://hbs.bishopmuseum.org/codens/coden... ): DZRJ - Coleção Entomológica “Prof. José Alfredo Pinheiro Dutra”, Departamento de Zoologia, Instituto de Biologia, Universidade Federal do Rio do Janeiro, Rio de Janeiro, RJ, Brazil; DZUP - Coleção Entomológica “Pe. Jesus Santiago Moure”, Departamento de Zoologia, Setor de Ciências Biológicas, Universidade Federal do Paraná, Curitiba, PR, Brazil; MNRJ - Museu Nacional, Universidade Federal do Rio de Janeiro, Rio de Janeiro, RJ, Brazil; MZSP - Museu de Zoologia, Universidade de São Paulo, SP, Brazil; RWG - Rosser W. Garrison Collection, Sacramento, CA, USA; USNM - National Museum of Natural History, Washington, DC, USA.

General morphology terms follow Pessacq (2008Pessacq P (2008) Phylogeny of Neotropical Protoneuridae (Odonata: Zygoptera) and a preliminary study of their relationship with related families. Systematic Entomology 33(3): 511-528. https://doi.org/10.1111/j.1365-3113.2007.00414.x
https://doi.org/10.1111/j.1365-3113.2007... ) and Garrison et al. (2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.); wing venation is based on the system of Riek and Kukalová-Peck (1984Riek EF, Kukalová-Peck J (1984) A new interpretation of dragonfly wing venation based upon early Carboniferous fossils from Argentina (Insecta: Odonatoidea) and basic character states in pterygote wings. Canadian Journal of Zoology 62: 1150-1166. https://doi.org/10.1139/z84-166
https://doi.org/10.1139/z84-166... ), with additions summarized by Fleck et al. (2003Fleck G, Bechly G, Martínez-Delclòs X, Jarzembowski E, Coram R, Nel A (2003) Phylogeny and classification of the Stenophlebioptera (Odonata: Epiproctophora). Annales de la Société Entomologique de France, Nouvelle Série 39: 55-93. https://doi.org/10.1080/00379271.2003.10697363
https://doi.org/10.1080/00379271.2003.10... ) and Garrison et al. (2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.). The terminology proposed by De Marmels (2002De Marmels J (2002) A study of Chromagrion Needham, 1903, Hesperagrion Calvert, 1902, and Zoniagrion Kennedy, 1917: three monotypic North American damselfly genera with uncertain generic relationships (Zygoptera: Coenagrionidae). Odonatologica 31(2): 139-150. http://natuurtijdschriften.nl/record/592391
http://natuurtijdschriften.nl/record/592... ) was implemented for the description of the structures of the apical segment of the genital ligula, which we believe corresponds to the second segment following Pfau (1971Pfau HK (1971) Struktur und Funktion des sekundären Kopulations apparates der Odonaten (Insecta, Palaeoptera), ihre Wandlung in der Stammesgeschichte und Bedeutung für die adaptive Entfaltung der Ordnung. Zeitschrift für Morphologie und Ökologie der Tiere 70: 281-371. https://doi.org/10.1007/BF00304097
https://doi.org/10.1007/BF00304097... ), while terminology for the ovipositor was based on Matushkina (2004Matushkina NA (2004) Comparative morphology of ovipositor in some damselflies (Odonata, Zygoptera). Vestnik Zoologii 38(3): 53-66.). The genital ligula was extruded using a hook-shaped pin after applying a few drops of 10% ammonia solution on the venter of the second and third abdominal segments (S2-3). In the few instances when genital ligula was fully extracted it was later transferred to a microvial with glycerin and stored with the respective specimen.

All measurements (in mm) and illustrations were made with the aid of a stereomicroscope equipped with a camera lucida. Specimens were photographed with a Leica MZ16 stereomicroscope equipped with a Leica DFC420 camera, and source images combined using Auto-montage software by The Synoptic Group^©.

The following abbreviations were used in the text: a.s.l. = above sea level; Ax = antenodal crossveins; Fw = fore wing; GL = genital ligula; Hw = hind wing; MBP = mediobasal process; Px = postnodal crossveins; Pt = pterostigma; S1-10 = abdominal segments; L1-2 = segments of genital ligula; VBP = ventrobasal process.

TAXONOMY

Forcepsioneura regua sp. nov.

http://zoobank.org/389F29AC-9E25-4154-80ED-C92FAFE9801C

Figs 1-6, 17-20, 24-28, 31-32, 35, 37

Forcepsioneura garrisoni nec Lencioni, 1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... : - Costa and Oldrini (2005Costa JM, Oldrini BB (2005) Odonatas da Marambaia. In: Menezes LFT, Peixoto AL, Araujo DSD (Eds) História Natural da Marambaia. Editora da Universidade Rural, Seropédica, 195-230.: 200, 208, key, misidentification of specimens from Rio de Janeiro State, Ilha da Marambaia island); - Anjos-Santos and Costa (2006Anjos-Santos D, Costa J (2006) A revised checklist of Odonata (Insecta) from Marambaia, Rio de Janeiro, Brazil with eight new records. Zootaxa 1300: 37-50.: 41, misidentification based on Costa and Oldrini 2005Costa JM, Oldrini BB (2005) Odonatas da Marambaia. In: Menezes LFT, Peixoto AL, Araujo DSD (Eds) História Natural da Marambaia. Editora da Universidade Rural, Seropédica, 195-230.).

Forcepsioneura haerteli nec Machado, 2001Machado ABM (2001) Studies on neotropical Protoneuridae. 11. Two new species of Forcepsioneura Lencioni (Odonata-Zygoptera) with a key to the males of the genus. Revista Brasileira de Zoologia 18(3): 845-854. https://doi.org/10.1590/S0101-81752001000300021
https://doi.org/10.1590/S0101-8175200100... : - Pessacq et al. (2012Pessacq P, Santos TC, Costa JM (2012) Checklist and updated distribution of Protoneuridae from Brazil. International Journal of Odonatology 15(2): 59-73. https://doi.org/10.1080/13887890.2012.672158
https://doi.org/10.1080/13887890.2012.67... : 6, misidentification of a male from Rio de Janeiro State, Cachoeiras de Macacu, Japuíba, Santana River).

Forcepsioneura sp.: - Garrison et al. (2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.: 358-360, 479, figs 2380, 2383, 2386, 2389, illustrations of wings, middle and posterior lobes of prothorax in laterodorsal view, and caudal appendages in lateral and dorsolateral views of a male from Ilha da Marambaia island, Rio de Janeiro State, Brazil); - Kompier (2015Kompier T (2015). A guide to the dragonflies and damselflies of the Serra dos Orgaos [sic] South-easthern Brazil. Brussels, REGUA Publications, 379 pp.): 112-113, photos of male and female habitus on the field from the type locality, characterization, comparison with Epipleoneura venezuelensis, F. lucia, and F. sancta, notes on habitat and behavior).

Diagnosis. Small, dorsally metallic greenish-blue, lateroventrally light blue and yellowish striped protoneurid; frons angulated; rear of head pale; CuP&AA indistinct; Ax space 1 as long as Ax space 3; GL with long inner fold and distal lateral lobe prolonged into a flagellum; cercus forcipate with mediobasal (MBP) and ventrobasal (VBP) processes, except for ill-defined prothoracic tubercle-like process, all characters agreeing with the definition of Forcepsioneura as recently diagnosed (Machado 2009Machado ABM (2008) [2009] Studies on neotropical Protoneuridae. 21. The status of Amazoneura Machado, 2004 (Odonata: Protoneuridae). Lundiana 9 (1): 53-56. http://www.icb.ufmg.br/lundiana/full/vol912008/05.pdf
http://www.icb.ufmg.br/lundiana/full/vol... , Garrison et al. 2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.).

The comparatively longer VBP, longer than 0.53 of total cercus length (dorsal branch) in lateral view, allows separation of males of F. regua sp. nov. from species of the orange-black group (VBP ≤ 0.40 of cercus length in F. grossiorum, F. lucia, and F. serrabonita sp. nov.); anteromesal margin of MBP acute in dorsal view (Fig. 25) separates it from F. sancta (largely rounded in dorsal view; sensu Machado 2001Machado ABM (2001) Studies on neotropical Protoneuridae. 11. Two new species of Forcepsioneura Lencioni (Odonata-Zygoptera) with a key to the males of the genus. Revista Brasileira de Zoologia 18(3): 845-854. https://doi.org/10.1590/S0101-81752001000300021
https://doi.org/10.1590/S0101-8175200100... ); apex of VBP acute and MBP not visible in lateral view (Figs 5, 24) from F. itatiaiae (apex of VBP truncated and MBP visible in lateral view); VBP shorter, not reaching ventral margin of S10 in lateral view, and apex strongly curved internally (Figs 5, 24-26) from F. haerteli (which has a longer VBP at level of S10, and apex slightly curved internally).

Based on its general color and size, F. regua sp. nov. is most similar to F. garrisoni. Indeed, these two species are remarkably similar due to the blue stripes on thorax (light blue group). The short MP vein, which reaches distally at most 0.5 of the length of cell distal to the vein descending from subnodus, and the fin-shaped plate of MBP with an acute and strongly anteriorly directed apex in laterodorsal view are unique to these two species and separate them from all other known species in the genus. The short VBP, not reaching ventral margin of S10 ventrally, and posterolateral margin of median lobe of prothorax lacking a defined tubercle-like process distinguish F. regua sp. nov. from F. garrisoni (VBP long, ventrally reaching the ventral margin of S10, and posterolateral margin of median lobe of prothorax with a strongly defined conical tubercle-like projection). The ill-defined process on prothorax is unique for F. regua sp. nov. (Figs 1-3, 17, 27-28).

Figures 1-6
Forcepsioneura regua sp. nov., holotype male (Brazil. RJ: Cachoeiras de Macacu, DZRJ 2071): (1-2) head in dorsal (1) and ventral (2) views; (3) prothorax in lateral view; (4-6) caudal appendages in dorsal (4), lateral (5) and dorsolateral (6) views. Scale bars = 1 mm.

Figures 7-12
Forcepsioneura serrabonita sp. nov., holotype male (Brazil. BA: Camacan, DZRJ 0050): (7-8) head in dorsal (7) and ventral (8) views; (9) prothorax in dorsolateral view; (10-12) caudal appendages in dorsal (10), lateral (11) and dorsolateral (12) views. Scale bars = 1 mm.

Figures 13-20
Prothorax and genital ligula of males of Forcepsioneura: (13-16) F. serrabonita sp. nov., holotype (Brazil. BA: Camacan, DZRJ 0050); (17-20) F. regua sp. nov., (17) holotype (Brazil. RJ: Cachoeiras de Macacu, DZRJ 2071), remainder from paratype of same locality; (13, 17) prothorax in dorsal view; (14-16, 18-20) genital ligula in ventral (14, 18) and lateral (15-16, 19-20) views. Scale bars = 0.5 mm.

Figures 21-26
Caudal appendages of males of Forcepsioneura: (21-23) F. serrabonita sp. nov., holotype (Brazil. BA: Camacan, DZRJ 0050); (24-26) F. regua sp. nov., holotype (Brazil. RJ: Cachoeiras de Macacu, DZRJ 2071); (21, 24) lateral view; (22, 25) dorsal view; (23, 26) posterior view. Scale bars = 1 mm.

Figures 27-30
Head and prothorax in dorsal view of females of Forcepsioneura: (27-28) F. regua sp. nov., paratype (Brazil. RJ: Cachoeiras de Macacu, DZRJ 2071); (29-30) F. serrabonita sp. nov., paratype (Brazil. BA: Camacan, MNRJ ODO-0001). Scale bars = 1 mm.

Despite the fact that the blue coloration and the ill-defined process on the prothorax of F. regua sp. nov. appear to be unique to females of this species, females of other Forcepsioneura are poorly known. Consequently, females should be identified through comparison with descriptions, figures, and their association with males.

Description of the male holotype. Head (Figs 1-2): Labium, visible parts of maxilla and mandibles (except apex) ivory yellow. Genae yellowish, darkening gradually posteriorly. Labrum dark brown to black with ventral 0.25 yellowish-orange, extended to 0.50 mesally, areas close to clypeolabral suture paler. Anteclypeus with lateral and mesal membranous ventral part yellowish, remainder part forming a rectangular black plate, postclypeus shining black. Antefrons, postfrons and remainder of epicranium black with shining bluish metallic reflections after postfrontal suture over postocular area. Antenna, antennifer and scape black, posterior surface of pedicel light brown, all parts with laterofrontal surface and distal apex of scape ivory yellow; flagellum lost. Posterior region of the cranium (“postgena” plus “occiput”) ivory yellow, 0.33 dorsal brownish-black.

Thorax (Figs 1-3, 17): Prothorax dorsally black, gradually lightening ventrally to brown laterally, ventral 0.3 of pleural sclerites yellow, notum with a ventrolateral whitish-blue stripe; anterior margin of anterior lobe black mesally, yellow laterally, posterolateral margin of median lobe with a very weak projection resembling the tubercle-like process observed in other Forcepsioneura (Figs 3, 17); posterior lobe asymmetrically convex, narrower than median lobe in dorsal view, right half slightly deformed (Fig. 17); sternellum (furcasternum sensu Asahina 1954Asahina S (1954) A morphological study of a relic dragonfly Epiophlebia superstes Selys (Odonata, Anisozygoptera).The Japan Society for Promotion of Science, Tokyo, 153 pp.) almost entirely black. Synthorax (Fig. 35) dorsally dark, gradually lightening ventrally; mesepisternum from mesostigmal region to antealar sinus dark brown to black with bluish metallic reflections, with a brown stripe occupying 0.33 of width running longitudinally to mesopleural suture; mesepimeron and metepisternum brown with irregular darker areas and a wide light blue longitudinal stripe running from posterolateral angle of mesinfraepisternum to antealar processes, occupying at maximum 0.33 of mesepimeron to 0.80 of metepisternum width, a mesal dark dot at level of intersegmental suture; metepimeron ivory yellow with a small brown area close to metapleural suture posteriorly; metapostepimeron ivory yellow with a black spot at lateroventral angle. Legs ivory yellow with irregular dark brown to black areas in the articulations of femur-tibia and tarsal segments, dorsal surface of femora, tibiae and apex of pretarsal claws (pretarsus); spurs black, except scale-like ivory yellow two proximal femoral spurs and tibial comb of prothoracic leg; anteroventral surface of femora armed with long and robust spurs, three in pro-, four in meso- and metathoracic femora, posteroventral surface with shorter and thinner spurs, 5 in pro-, 5-6 in meso- and 6-8 in metathoracic femora; anteroventral surface of tibiae armed with 9-10 spurs in pro- (4-5 of tibial comb), 5-6 in meso-, 6 metathoracic, length similar to intervening spaces; pretarsal claws with distinct acute supplementary inferior tooth at ca 0.50 of their length in all legs.

Wings (Fig. 35): Membrane hyaline; venation dark brown to black; Pt black, quadrangular; MP reaches anal margin at the vein descending from subnodus or very slightly distal, covering 2 cells in all wings; Px in Fw 11; Hw 9; RP2 originating at Px 5 in Fw, at Px 4 in Hw.

Abdomen (Figs 4-6, 18-20, 24-26, 35): S1-10 tergites dark brown to black dorsally, light brown to ivory yellow lateroventrally, darker in S8-10, with a very thin line along dorsal carina on S1-8; sternites similar in color to adjacent areas of tergites, yellow ivory in S1, remainder segments yellow to light brown with irregular dark areas, S9 dark brown; pale longitudinal stripe occupying ventral 0.5 of tergites S1-6 laterally, gradually narrowing to ca 0.2 in S8, a narrow line in S9 and ill-defined areas in S10; S3-7 with a narrow anterior pale ring ≤0.1 of segment total length, separated dorsally in S3; S1-7 cylindrical, S8-10 distinctly wider than previous segments, S7 width 0.6 of posterior part of S8 width; posterior margin of S10 with a shallow and wide concavity. Secondary genitalia (Figs 18-20) typical of Coenagrionoidea, anterior lamina with a deep and acute incision, anterior hamule quadrangular, with anteroventral angle acutely projected, posterior hamule almost entirely internalized with a curved thumb-shape; VS longer than wide, maximum width 0.3 of total length in ventral view. Genital ligula (as in Figs 18-20; based on paratype) with L1 smooth, without any kind of special setae; L2 with posterolateral portion of flexure projected distally beyond median region, making its margin concave in ectal view; distal margin of L2 (tip of ligula) with a mesal concavity (Fig. 18), lateral margins prolonged into two curved long flagella, in ectal view basally almost perpendicular, afterwards twisted (Figs 18-20); internal fold proximal to flexure, long with ca 0.4 of L2 total length in lateral view; no sclerotized tubercle at flexure. Epiproct reduced to a membranous-like plate. Cercus (Figs 4-6, 24-26) brown to dark brown, apex of cercus, ventrobasal and mediobasal processes black; cercus in lateral view slightly directed obliquely dorsad, gradually tapering distally; ventrobasal process perpendicular to dorsal branch, length ca 0.66 of cercus, apex stoutly rounded, at distal 0.2 distinctly curved posteriorly, distal edge at 0.7 from distance of ventrobasal process base to margin of S10; mediobasal process not visible in lateral view (Figs 5, 24); tip of cercus blunt; in dorsal view forcipate, proximally wide, slender distally; lateral margin almost straight, internal margin very slightly curved, apexes converging (Figs 4, 25); mediobasal process as a very acute fin-shaped plate, apex strongly directed anteriorly, positioned at basal 0.2 (Fig. 25); in posterior view directed ventrally obliquely and projected from a dilated area of cercus; apex of ventrobasal process broadly acute and abruptly curved in posterior view (Fig. 26). Paraproct orange-yellow, plate-like.

Measurements (mm). Total length (incl. caudal appendages) 33.5; abdomen length (excluding caudal appendages) 28.8; head maximum width 2.9; Fw length 18.5; Hw length 17.4; Fw maximum width 3.3, Hw maximum width 3.3; Pt length 0.47 in Fw, 0.49 in Hw; length of metathoracic femur 1.6; metathoracic tibia 1.7; length of S9+10 in lateral view 1.1; length of cercus (dorsal branch) in lateral view 0.45; length of ventrobasal process in lateral view 0.29.

Female paratype. Similar to holotype but paler, differences described below.

Head (Fig. 27): Labrum greenish-brown to light brown with ventral 0.25 yellowish, extended mesally to 0.50. Antefrons with mesal pale rounded spot. Posterior region of the cranium (“postgena” plus “occiput”) ivory yellow, dorsal 0.20 brownish-black.

Thorax (Figs 27-28): Mesal projection of posterior lobe of prothorax with a small concavity divided into two lobes (Fig. 28). Anteroventral surface of femora armed with long and robust spurs, 3 in pro-, 4 in meso- and metathoracic femora, right metafemur with 7 supernumerary spurs, posteroventral surface with shorter and thinner spurs, 5 in pro-, 6 in meso- and metathoracic femora; anteroventral surface of tibiae armed with 5 spurs in meso-, 6 in metathoracic tibiae, length similar to intervening spaces (spurs not visible on the single preserved prothoracic leg). Wings: Pt brown, quadrangular but more rounded than in male; MP reaches anal margin at vein descending from subnodus in Fw and very slightly distal in Hw; Px in Fw 9-10; Hw 11.

Abdomen (Figs 31-32): Tergites of S1-10 dark brown to black dorsally, light brown to ivory yellow lateroventrally, distinctly darker in S8-10; tergites with a very thin pale line along the dorsal carina on S1-8; sternites similar in color to adjacent areas of tergites except 0.5 posterior of S8 dark brown with a transverse posterior yellow stripe contiguous to and with similar width of yellow posterior field of tergite. Ovipositor (Fig. 32) distally reaching level of cercus in lateral view, dark brown, lightening distally, dorsal lobe of third valve (gonoplac of S9) yellow, ventral surface smooth; stylus dark brown, tip yellow. Cercus, epiproct and paraproct dark brown to black.

Figures 31-34
Abdominal segments seven to ten (S7-10) of females of Forcepsioneura: (31-32) F. regua sp. nov., paratype (Brazil. RJ: Cachoeiras de Macacu, DZRJ); (33-34) F. serrabonita sp. nov., paratype (Brazil. BA: Camacan, MNRJ ODO-0001). Scale bars for = 1 mm.

Measurements (mm). Total length (incl. caudal appendages) 35.2; abdomen length (excluding caudal appendages) 30.5; head maximum width 2.9; Fw length 21.2; Hw length 20.2; Fw maximum width 3.7; Hw maximum width 3.8; Pt length 0.53 in Fw; 0.54 in Hw; length of metathoracic femur 2.0; metathoracic tibia 2.2; length of S9+10 in lateral view 1.0; total length of cercus in lateral view 0.28.

Variation in male paratypes. The nine other males are very similar to holotype except for minor differences described below.

Head: Antefrons ivory yellow with a mesal ill-defined brown line; occipital bar with a yellow spot. Flagellum dark brown. Thorax: Prothorax paler with whitish-blue ventrolateral stripe faint; posterior lobe truncated or with small median concavity. Light blue longitudinal stripe on synthorax occupying at maximum 0.5 of mesepimeron width to almost entire metepisternum. Long and robust spurs on anteroventral surface of femora 3-4 in pro-, 4 in meso- and 4-5 in meta-, posteroventral surface with shorter and thinner spurs, 3-5 in pro-, 4-6 in meso- and 5-8 in metathoracic femora; anteroventral surface of tibiae armed with 9-11 spurs in pro- (4-5 of tibial comb), 5-6 in meso-, 5-6 in metathorax.

Abdomen: Paraproct orange-yellow to dark brown.

Measurements (mm, n = 5). Total length (incl. caudal appendages) 31.7-35.9; abdomen length (excluding caudal appendages) 27.0-30.8; head maximum width 2.8-3.0; Fw length 17.3-19.2; Hw length 16.5-18.0; Fw maximum width 3.0-3.5; Hw maximum width 2.9-3.3; Pt length 0.44-0.58 in Fw; 0.46-0.58 in Hw; length of metathoracic femur 1.7-1.9; metathoracic tibia 1.9-2.1; length of S9+10 in lateral view 1.1-1.3; length of cercus (dorsal branch) in lateral view 0.42-0.60; length of ventrobasal process in lateral view 0.30-0.36.

Larva. Unknown.

Material examined (10 males, 2 females). Holotype male and paratype female (in tandem), BRAZIL. Rio de Janeiro State: Cachoeiras de Macacu municipality, Reserva Ecológica de Guapiaçu (REGUA), forest fragment (22°28’08”S, 42°45’39”W, 42 m a.s.l.), 27.VII.2012, T.M.F. Kompier leg. (DZRJ 2071); 1 male paratype, same data but pond with macrophytes (22°27’10”S, 42°46’13”W, 34 m a.s.l.), 03.XII.2009, A.L. Carvalho & Disciplina Técnicas de Coleta PPGZoo/UFRJ leg. (DZRJ 315, DNA voucher ENT3609); 1 male paratype, same data but stream at small wetland (22°25’51”S, 42°45’39”W, 75 m a.s.l.), 02.III.2013, T.M.F. Kompier leg. (DZRJ 326); 2 male paratypes, same data but 22°28’04”S, 42°45’32”W, 70 m a.s.l., 13.I.2014, (DZRJ 2251, DNA voucher ENT2854; DZRJ 2252, DNA voucher ENT3608); 1 male paratype, same municipality but [District of] Japuíba [22°33’46”S, 42°41’30”W, 26 m a.s.l.], Rio Santana (sic, Rio Macacu?), 08.V.1983, J.M. Costa leg. (MNRJ ODO-0011, DNA voucher ENT2368); 2 male paratypes, Mangaratiba municipality, Ilha de Marambaia, Gruta da Santa (23°03’35”S, 43°57’56”W, 100 m a.s.l.), 02.XII.2000, R.W. Garrison leg. (RWG, DNA voucher ENT3016; DZUP 498845); 1 male and 1 female paratypes, same data but 04.XII.2000 (RWG); 1 male paratype, same data but temporary pool close to areal (MNRJ-ODO 0208, DNA voucher ENT3607). Specimens in DZRJ collected under ICMBIO/SISBIO license numbers 25034-1, 25034-2, and 25034-3.

Biological and ecological data. Males were observed at seeps from peaty substrate at the forest edge and on very shallow, small streams with abundant leaf litter and limited flow. Even though observations were made on sunny days, they seem to avoid direct sunlight, perching suspended from the tips of leaves and grasses, or on the leaf litter. Streams were either partially or fully covered by trees and bushes. Females were observed in the same habitat. Both males and females were seen flying very slowly, and appeared to float in the air. Copulation lasted up to 10 minutes. Females were observed ovipositing unattended on a muddy substrate. Their habitat was shared with Heteragrion aurantiacum Selys, 1862, H. consors Hagen in Selys, 1862 and Acanthagrion gracile (Rambur, 1842), species that are tolerant to disturbed habitats in typical southeastern Brazilian Atlantic Forest.

Etymology. Noun in apposition in reference to the acronym of the type locality, Reserva Ecológica de Guapiaçu (REGUA), a private reserve maintained for conservation, scientific research and environmental education.

Remarks. This species has been known to specialists for at least eighteen years (e.g., Garrison 2000Garrison RW (2000) Brazil 2000, or living it up (and collecting) in Rio. Argia 13(1): 12-15.). Some specimens of the type series of F. regua sp. nov. had been previously determined as F. garrisoni, F. haerteli or F. sancta by distinct specialists. For example, Costa and Oldrini (2005Costa JM, Oldrini BB (2005) Odonatas da Marambaia. In: Menezes LFT, Peixoto AL, Araujo DSD (Eds) História Natural da Marambaia. Editora da Universidade Rural, Seropédica, 195-230.) cited this species as F. garrisoni from Ilha da Marambaia island in Rio de Janeiro, and provided an illustration of the cercus in laterointernal view (their fig. 30). Even though that illustration agrees with F. garrisoni, we think that it was modified from the original description of that species. We believe this because other illustrations in that paper were clearly extracted from previous works, and reproduced with minor modifications. Individuals of the population from Ilha da Marambaia island are distinctly larger than those from the type locality in REGUA.

Forcepsioneura serrabonita sp. nov.

http://zoobank.org/9D6A447E-4F57-4DF3-AA37-BB59DA7F7829

Figs 7-12, 13-16, 21-23, 29-30, 33-34, 36, 38

Diagnosis. A medium, dorsally black and lateroventrally yellowish protoneurid species; frons angulated; rear of head pale; posterolateral margin of median lobe of prothorax with well-defined tubercle-like process; CuP&AA indistinct; Ax space 1 as long as Ax space 3; GL with long inner fold and distal lateral lobe prolonged into a flagellum; cercus forcipate with mediobasal (MBP) and ventrobasal process (VBP), all characters agreeing with the definition of Forcepsioneura as recently diagnosed (Machado 2009Machado ABM (2008) [2009] Studies on neotropical Protoneuridae. 21. The status of Amazoneura Machado, 2004 (Odonata: Protoneuridae). Lundiana 9 (1): 53-56. http://www.icb.ufmg.br/lundiana/full/vol912008/05.pdf
http://www.icb.ufmg.br/lundiana/full/vol... , Garrison et al. 2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.).

Based on general color and shape of male cercus, F. serrabonita sp. nov. resembles F. grossiorum and F. lucia. Males of this orange-black group of large species with robust cercus have a short VBP (as long as ≤ 0.40 of dorsal branch of cercus in lateral view), while it is longer (as long as ≥ 0.55 of dorsal branch) in F. garrisoni, F. haerteli, F. itatiaiae, F. regua sp. nov. and F. sancta. Forcepsioneura serrabonita sp. nov. is distinguished from the first two species by having posterior lobe of prothorax regularly rounded (Figs 9, 13; sinuous in F. grossiorum); Pt quadrangular, ratio between costal length and proximal length 0.54 in F. serrabonita sp. nov., being similar in size to F. lucia (ratio ≅ 0.6), but rectangular and distinctly longer in F. grossiorum (ratio = 0.8); cercus slender, with anteromesal margin of MBP process rounded in dorsal view (Figs 10, 22; acute in both F. grossiorum and F. lucia), MBP almost not visible in lateral view (Figs 11, 21; clearly visible in F. grossiorum and F. lucia).

In view of the large size of specimens of F. serrabonita sp. nov., they can be confused with F. itatiaiae, from which, in addition to the shorter VBP mentioned above, it can be separated by the shape of the male cercus with strongly cylindrical VBP (Figs 11, 21; blade-like and truncated apex in F. itatiaiae), MBP largely rounded dorsally and almost not visible in lateral view (Figs 10-11, 21-22; angulated plate as an axe with concave blade dorsally, and clearly visible in lateral view in F. itatiaiae).

Additionally, the distinctive shape of the GL (Figs 14-16), with a large and upright internal fold (obliquely toward anteriorly in the other species), will separate F. serrabonita sp. nov. from all species for which the GL has been described.

Females of several Forcepsioneura species are poorly known, which hampers a useful diagnosis. Putative females should be identified by comparison with descriptions, figures and association with males.

Description of male holotype. Head (Figs 7-8): Labium, visible parts of maxillae and mandibles (except apex) ivory yellow (Fig. 8). Genae yellowish, darkening gradually posteriorly. Labrum orange-brown (possibly light orange in life) with two lateral and one mesal rounded dark brown spots from clypeolabral suture to 0.5 ventral, pale areas among them darkened. Anteclypeus with lateral and mesal membranous ventral part yellowish, remainder part forming a semicircular dark brown plate, postclypeus almost entirely shining dark brown with ill-defined orange-brown spots. Antefrons dark brown with ill-defined pale areas, postfrons and remainder of epicranium opaque black with a weak copper luster. Antenna, antennifer and scape black, posterior surface of pedicel light dark brown, all parts with laterofrontal surface and distal apex of antennifer and scape ivory yellow; flagellum lost. Posterior region of the cranium (“postgena” plus “occiput”) pale brown (Fig. 7), probably light ivory yellow.

Thorax (Figs 9, 36): Prothorax dorsally black, gradually lightening ventrally to yellow at pleural sclerites; anterior margin of anterior lobe ivory yellow; posterolateral margin of median lobe with well-defined tubercle-like process; posterior lobe rounded convex, narrower than median (Figs 9, 13); sternellum (furcasternum sensu Asahina 1954Asahina S (1954) A morphological study of a relic dragonfly Epiophlebia superstes Selys (Odonata, Anisozygoptera).The Japan Society for Promotion of Science, Tokyo, 153 pp.) almost entirely black. Synthorax (Fig. 36) dorsally dark, gradually lightening ventrally; mesepisternum from mesostigmal region to antealar sinus entirely dark brown to black with greenish-copper metallic reflections, except light brown line running longitudinal to mesopleural suture; mesepimeron dorsally light brown, narrowed ventrally by an ivory yellow stripe occupying 0.4 of the lateroventral apex of the sclerite, over mesinfraepisternum it occupies 0.5 ventral; remainder of synthorax ivory yellow, except poorly defined light brown stripe with about 0.3 of width along metapleural suture ending at spiracle level and a small black spot at ventro-distal apex of metapostepimeron. Legs ivory yellow with irregular dark brown to black areas in articulation femur-tibia, dorsal surface of metathoracic femur and apex of pretarsal claws (pretarsus); spurs black except scale-like ivory yellow proximal femoral spurs and tibial comb of prothoracic leg; anteroventral surface of femora armed with long and robust spurs, 5 in pro- and mesothoracic and 6 in metathoracic femora, posteroventral surface with shorter and thinner spurs, 3 in pro- and mesothoracic femora to 6 in metathoracic femur; anteroventral surface of tibiae armed with 9 spurs in pro- (4 of tibial comb), 7 in meso-, 6-7 in metathoracic tibiae, usually longer than intervening spaces; pretarsal claws with distinct acute supplementary inferior tooth at ca 0.50 of their length in all legs.

Figures 35-40
Habitus and habitat of species of Forcepsioneura: (35) F. regua sp. nov., holotype (Brazil. RJ: Cachoeiras de Macacu, DZRJ 2071); (36) F. serrabonita sp. nov., holotype (Brazil. BA: Camacan, DZRJ 0050), (37) F. regua sp. nov., live individual at type locality at Reserva Ecológica de Guapiaçu (REGUA); (38) overview of type locality at RPPN Serra Bonita; (39) shallow muddy and slow stream at Itatiaia National Park, typical habitat of small light blue species; (40) seepage covered by hornworts at Três Picos State Park, typical habitat of large orange-black species. Scale bars = 1 mm. Photos: (37) TMFK; (38) RA Carvalho; (39-40) APP.

Wings (Fig. 36): Membrane hyaline; venation dark brown to black; Pt brown, with a narrow internal pale line surrounding the enclosing veins, quadrangular. MP reaches anal margin slightly distal of vein descending from subnodus, covering 2 cells in FW, distal to vein descending from subnodus covering ca 0.5 of a third cell in HW. Px in Fw 12; Hw 11; RP2 originating at or slightly distal to Px 5 in Fw, at or slightly proximal to Px 4 in Hw.

Abdomen (Figs 10-12, 14-16, 21-23, 36): Tergites of S1-10 dark brown to black dorsally, yellow ivory lateroventrally, darker in S8-10; sternites similar in color to adjacent areas of tergite, yellow ivory in S1, remainder segments light yellow to orange-yellow with irregular dark areas; pale longitudinal stripe occupying 0.5 ventral of S1-2 tergites laterally, gradually narrowing to ca 0.3 in S8, S9 with two ill-defined small pale spots, one close to posterior field of S8 and other close to posterior carina, S10 almost entirely black; S3-7 with an narrow anterior pale ring ≤0.1 of total segment length, dorsally separated by a thin line; S1-7 cylindrical, S8-10 distinctly wider than previous segments, S7-8 slightly smashed preventing an accurate measurement of abdominal width in these segments; posterior margin of S10 with a shallow and wide concavity. Secondary genitalia (Figs 14-16) typical of Coenagrionoidea, anterior lamina with a deep and acute incision, anterior hamule quadrangular, with anteroventral angle acutely projected, posterior hamule almost entirely internalized with a curved thumb-shape; VS longer than wide, maximum width 0.4 of total length in ventral view. Genital ligula (as in Figs 14-16) rectangular in ectal view; L1 smooth, without any kind of special setae; L2 with posterolateral portion of flexure projected distally beyond median region, mesally slightly projected in ectal view, in lateral view this projection similar to terminal fold (Fig. 15); distal margin of L2 (tip of ligula) almost straight in ectal view; distal lateral lobe prolonged into a gradually thinner, twisted, flagellum; internal fold proximal to flexure, upright, large, ca 0.4 of L2 total length in lateral view (Fig. 16); no sclerotized tubercle at level of flexure. Epiproct reduced to a membranous-like plate. Cercus (Figs 10-12, 21-23) ivory yellow, with apex, ventrobasal (VBP) and mediobasal (MBP) processes dark brown to black; in lateral view strongly directed obliquely dorsad; VBP in opposite direction, short, apex rounded, distal edge at half distance from ventral margin of S10; MBP visible as a rounded tubercle between cercus and VBP; tip of cercus blunt; in dorsal view forcipate, proximally wide, slender distally, lateral margin gently curved, internal margin slightly more curved, apices converging (Figs 10, 22); MBP as a rounded plate, positioned at 0.33 basal; in posterior view obliquely directed ventrally and projected from a dilated area of cercus; apex of VBP process acute and slightly curved in posterior view (Fig. 23). Paraproct orange-yellow, plate-like.

Measurements (mm). Total length (incl. caudal appendages) 38.7; abdomen length (excluding caudal appendages) 33.0; head maximum width 3.4; Fw length 21.8; Hw length 20.3; Fw maximum width 3.8, 3.7 in Hw; Pt length 0.54 in Fw, 0.58 in Hw; length of metathoracic femur 2.0; metathoracic tibia 2.1; length of S9+10 in lateral view 1.46; total length of cercus (dorsal branch) in lateral view 0.88; length of ventrobasal process in lateral view 0.36.

Female paratype. Similar to holotype. The only differences are described below.

Head (Figs 29-30): Labrum light orange with two lateral and a mesal rounded dark brown spots from clypeolabral suture to 0.5 ventral. Anteclypeus yellowish. Antefrons ivory yellow. Scape articulation and posterior surface of pedicel ivory yellow. Posterior region of the cranium (“postgena” plus “occiput”) yellowish, brownish dorsally close to foramen

Thorax (Figs 30, 36): Leg spurs black; anteroventral surface of femora armed with long and robust spurs, 5 in pro-, 4 in meso- and metathoracic femora, posteroventral surface with shorter and thinner spurs, 3 in pro-, 4 in meso- and 6 in metathoracic femora; anteroventral surface of tibiae armed with 10 spurs in pro- (5 of tibial comb), 6 in meso- and metathoracic tibiae, usually longer than intervening spaces.

Wings: MP reaches anal margin slightly distal of the vein descending from subnodus, covering 2 cells and ca 0.25 of a third cell in FW and 0.5 in HW. Px in Fw 13; Hw 11; RP2 originating at or slightly proximal to Px 6 in Fw, at Px 4 in Hw.

Abdomen (Figs 33-34): Coloration very similar to that of male holotype except for the yellow ivory posterior field of S8 and dorsal longitudinal stripe on S9-10, forming an irregular T-spot dorsally on S9. Sternites light yellow to orange-yellow. Ovipositor (Fig. 34) reaching distally level of cercus in lateral view, yellowish-orange, dorsal lobe of third valve (gonoplac of S9) slightly paler, ventral surface smooth; stylus dark brown, tip yellow. Cercus, epiproct and paraproct dark brown to black (Figs 33-34).

Measurements (mm). Total length (incl. caudal appendages) 37.3; abdomen length (excluding caudal appendages) 31.0; head maximum width 3.1; Fw length 21.2; Hw length 19.8; Fw maximum width 3.8; Hw maximum width 3.9; Pt length in Fw 0.54; Pt length in Hw 0.59; length of metathoracic femur 2.2; metathoracic tibia 2.4; length of S9+10 in lateral view 1.0; total length of cercus (dorsal branch) in lateral view 0.32.

Variation in male paratypes. The four other specimens (excluding the teneral one) are very similar to holotype, minor differences are described below.

Head: Labrum brownish to black. Postclypeus shining dark or with ill-defined mesal orange-brown spot. Frons and remainder of epicranium opaque black with a weak copper luster. Antennal flagellum brown to black. Posterior region of cranium (“postgena” plus “occiput”) ivory yellow.

Thorax: Anteroventral surface of femora armed with long and robust spurs, 5 in pro-, 3-4 in meso- and 5 in metathoracic femora, posteroventral surface with shorter and thinner spurs, 3 in pro-, 4-5 in meso-, 5-6 in metathoracic femora; anteroventral surface of tibiae armed with 9-10 spurs in pro- (4-5 of tibial comb), 5-6 in meso-, 5-6 in metathoracic tibiae.

Wings: MP reaches anal margin at or slightly distally to vein descending from subnodus, covering from 0.33 to 0.5 of a third cell in HW. Px in Fw 12-15; Hw 10-13; RP2 originating between Px 5-6 in Fw.

Measurements (mm). Total length (incl. caudal appendages) 37.5-40.5; abdomen length (excluding caudal appendages) 31.7-33.7; head maximum width 2.9-3.3; Fw length 20.3-22.3; Hw length 19.5-21.3; Fw maximum width 3.5-3.8; Hw maximum width 3.7-3.8; Pt length 0.56-0.60 in Fw; 0.58-0.64 in Hw; length of metathoracic femur 1.9-2.1; metathoracic tibia 2.1-2.2; length of S9+10 in lateral view 1.3-1.4; total length of cercus (dorsal branch) in lateral view 0.74-0.86; length of ventrobasal process in lateral view 0.12-0.22.

Larva. Unknown.

Material examined (6 males, 1 female). Holotype male, BRAZIL. Bahia State: Camacan municipality, Reserva Particular do Patrimônio Natural (RPPN) Serra Bonita, collecting point “Alojamento” (BA 2012-001; 15°23’16”S, 39°33’58”W, 810 m a.s.l.), 27-29.II.2012, R.A. Carvalho leg. (DZRJ 0050); 1 male paratype, same data but first trickle on road beyond managers house (15°23’19”S, 39°33’57”W, 710 m a.s.l. [822 m]), 5.I.2013, C.M. Flint & O.S. Flint Jr. leg. (USNM); 2 male paratypes, same data but quarry, 20.II.2015 (USNM; MZSP ODO-492, DNA voucher ENT2857); 1 male paratype, same data but 26.II.2015 (USNM); 1 female paratype, same data but spring near telecommunication towers (15°23’02”S, 39°34’19”W; 850 m a.s.l. [880 m]), 25.XII.2013, T.W. Donnelly leg. (MNRJ ODO-0001; ex-TWD collection). Additional specimen (excluded from type series). 1 male (teneral), same data as holotype but trickles at upper water tank (15°23’03”, 39°34’19”W, 890 m a.s.l.), 23.XII.2012, C.M. Flint & O.S. Flint, Jr. leg. (USNM).

Etymology. Noun in apposition in reference to the type locality in the complex of RPPNs Serra Bonita, in honor of this protected area and its managers, who have taken positive steps towards the preservation of Atlantic Forest remnants in the southern portion of the biodiversity-rich state of Bahia.

Biological and ecological data. Expected to be a submontane forest species, most likely occurring at seepages similar to the mesohabitat occupied by the large montane species from southeastern Brazil (e.g., F. itatiaiae and F. cf. lucia). The larvae possibly are madicolous and should inhabit shallow streams running over rocky substrates covered by ferns and hornworts/liverworts forming small waterfalls (Fig. 40). Though we have not observed adult behavior in the field it is plausible to assume that F. serrabonita sp. nov. is a forest damselfly like most Forcepsioneura.

DISCUSSION

The “Reserva Particular do Patrimônio Natural Serra Bonita” (RPPN, Private Reserve of Natural Heritage) is a complex of protected areas that started from a small fragment bought in the 1990s. Now it covers about 7,500 ha between 300 and 1,080 m above sea level of primary and secondary forests maintained by Instituto Uiraçu (Becker 2017Becker V (2017) The story of the SBR by Vitor Osmar Becker, PhD. https://www.serrabonita.org/the-story-of-the-serra-bonita [Accessed: 30/09/2017]
https://www.serrabonita.org/the-story-of... ). This complex is located in one of most biodiverse regions of the threatened Atlantic Forest, representing unique fragments with high levels of biodiversity and endemism on montane formations in southern Bahia. Although Serra Bonita remains undersampled, studies have shown that it includes at least 810 species of vascular plants, mostly flowering plants (Amorim et al. 2009Amorim AM, Jardim JG, Lopes MMM, Fiaschi P, Borges RAX, Perdiz RDO, Thomas WW (2009) Angiosperms of montane forest areas in southern Bahia, Brazil. Biota Neotropica 9(3): 1-36. https://doi.org/10.1590/S1676-06032009000300028
https://doi.org/10.1590/S1676-0603200900... , Matos et al. 2010Matos F, Amorim AM, Labiak PH (2010) The ferns and lycophytes of a montane tropical forest in Southern Bahia, Brazil. Journal of the Botanical Research Institute of Texas 4(1): 333-346. http://www.jstor.org/stable/41972015.
http://www.jstor.org/stable/41972015... ), 80 of amphibians (Dias et al. 2014Dias IR, Medeiros TT, Nova MFV, Solé M (2014) Amphibians of Serra Bonita, southern Bahia: a new hotpoint within Brazil’s Atlantic Forest hotspot. ZooKeys 449: 105-130. https://doi.org/10.3897/zookeys.449.7494
https://doi.org/10.3897/zookeys.449.7494... ) and a huge number of moths, estimated between five and six thousand species (V. Becker pers. comm.). The species-rich longhorn beetles (Cerambycidae), however, have only been recorded in few numbers, currently only 51 species (Martins and Galileo 2010Martins UR, Galileo MHM (2010) Cerambycidae (Coleoptera) da Serra Bonita. Papéis Avulsos de Zoologia 50: 435-443.). In comparison, a preliminary checklist of dragonflies elaborated in collaboration by a few odonatologists already includes almost 90 species.

Like Serra Bonita, also in Southeastern Brazil, the “RPPN Reserva Ecológica de Guapiaçu” originated from private efforts aiming to conserve the AF. This protected area shares a similar history with Serra Bonita, beginning in the 1990s. Originally it was a farm and slowly it became a conservation and restoration portion of the AF. The preserve was founded in the beginning of 2000 and was officially recognized as a RPPN at the state level in 2013, at 302 ha. In 2014 a smaller, 35 ha area was incorporated to it and baptized as REGUA II. Unofficially, the preserve is between 6,500 and 7,500 ha, and 49% to 80% of its area is estimated to be inserted within the Três Picos State Park (Pimentel and Olmos 2011Pimentel L, Olmos F (2011) The birds of Reserva Ecológica Guapiaçu (REGUA), Rio de Janeiro, Brazil. Cotinga 33: 8-24., Soares et al. 2011Soares A, Bizarro JM, Bastos CB, Tangerini N, Silva NA, da Silva AS, Silva GB (2011) Preliminary analysis of the diurnal Lepidoptera fauna of the Três Picos State Park, Rio de Janeiro, Brazil, with a note on Parides ascanius (Cramer, 1775). Tropical Lepidoptera Research 21(2): 66-79. http://troplep.org/TLR/21-2/Tropical-Lepidoptera-Research-21-2-2011-Soarez-et-al.pdf
http://troplep.org/TLR/21-2/Tropical-Lep... for distinct data). The latter is a protected area created by the government of the state of Rio de Janeiro in 2002 and further enlarged in 2009 (INEA 2013INEA (2013) Parque Estadual dos Três Picos: plano de manejo, resumo executivo. Instituto Estadual do Ambiente (INEA), Rio de Janeiro, 102 pp., RJ decrees 31,443, 41,990). With elevations from sea level to 2,000 m (Soares et al. 2011Soares A, Bizarro JM, Bastos CB, Tangerini N, Silva NA, da Silva AS, Silva GB (2011) Preliminary analysis of the diurnal Lepidoptera fauna of the Três Picos State Park, Rio de Janeiro, Brazil, with a note on Parides ascanius (Cramer, 1775). Tropical Lepidoptera Research 21(2): 66-79. http://troplep.org/TLR/21-2/Tropical-Lepidoptera-Research-21-2-2011-Soarez-et-al.pdf
http://troplep.org/TLR/21-2/Tropical-Lep... ), REGUA has a high diversity and is administrated in partnership with the public area of the Três Picos State Park. REGUA also integrates an important watershed for the metropolitan megacity of Rio de Janeiro (Rodríguez Osuna et al. 2014Rodríguez Osuna V, Börner J, Nehren U, Prado RB, Gaese H, Heinrich J (2014) Priority areas for watershed service conservation in the Guapi-Macacu region of Rio de Janeiro, Atlantic Forest, Brazil. Ecological Processes 3(16): 1-21. https://doi.org/10.1186/s13717-014-0016-7
https://doi.org/10.1186/s13717-014-0016-... ).

Recent studies highlight the relevance of REGUA. For example, 450 species of birds were recorded in REGUA and in neighboring areas (Pimentel and Olmos 2011Pimentel L, Olmos F (2011) The birds of Reserva Ecológica Guapiaçu (REGUA), Rio de Janeiro, Brazil. Cotinga 33: 8-24.). As far as we know, 59 species of mosquitoes (Silva et al. 2014Silva JS, Couri MS, Giupponi APL, Alencar J (2014) Mosquito fauna of the Guapiaçu Ecological Reserve, Cachoeiras de Macacu, Rio de Janeiro, Brazil, collected under the influence of different color CDC light traps. Journal of Vector Ecology 39(2): 384-394. https://doi.org/10.1111/jvec.12114
https://doi.org/10.1111/jvec.12114... ) and at least 570 species of butterflies (Soares et al. 2011Soares A, Bizarro JM, Bastos CB, Tangerini N, Silva NA, da Silva AS, Silva GB (2011) Preliminary analysis of the diurnal Lepidoptera fauna of the Três Picos State Park, Rio de Janeiro, Brazil, with a note on Parides ascanius (Cramer, 1775). Tropical Lepidoptera Research 21(2): 66-79. http://troplep.org/TLR/21-2/Tropical-Lepidoptera-Research-21-2-2011-Soarez-et-al.pdf
http://troplep.org/TLR/21-2/Tropical-Lep... ) have been found there. The most significant aspect of these two protected areas, REGUA and Três Picos State Park, is their status as the richest spots for dragonflies and damselflies in the world, with at least 204 species (see Kompier 2015Kompier T (2015). A guide to the dragonflies and damselflies of the Serra dos Orgaos [sic] South-easthern Brazil. Brussels, REGUA Publications, 379 pp.), surpassing Manu National Park in Madre de Dios province in Peru, the site previously known as the most diverse with 188 species (Paulson 2004Paulson DR (2004) Critical species of Odonata in the Neotropics. International Journal of Odonatology 7(2): 163-188. https://doi.org/10.1080/13887890.2004.9748208
https://doi.org/10.1080/13887890.2004.97... ; number of species updated by Paulson 2006Paulson DR (2006). The importance of forests to neotropical dragonflies. In: Rivera AC (Ed) Forests and dragonflies: fourth WDA International Symposium of Odonatology, Pontevedra (Spain), July 2005. Pensoft, Sofia , 79-101.).

These recent findings, including the two new species described here, bring to attention the urgency in directing collecting efforts at unexplored areas, and also the importance of private preserves that harbor the type localities of described species in the AF. Together, REGUA and Três Picos harbor over 210 species of Odonata, or about 24% of the known Brazilian dragonflies, and represent a major hotspot for the conservation of these insects. As highlighted by Corbet (2006Corbet P (2006). Forests as habitats for dragonflies (Odonata). In: Rivera AC (Ed.) Forests and dragonflies: Fourth WDA International Symposium of Odonatology, Pontevedra, Spain, July 2005. Pensoft, Sofia, 13-36.), dragonflies and damselflies depend on forests for survival and these insects are rapidly being deprived of their mesohabitats that allow their existence. Odonatologists should be alert to these processes and focus in knowledge production that promotes mitigation actions to conserve their populations. Charismatic groups of animals, such as insects of the order Odonata, can be used as flagship species for conservation (see Oertli 2008Oertli B (2008) The use of dragonflies in the assessment and monitoring of aquatic habitats. In: Córdoba-Aguilar A (Ed.) Dragonflies and Damselflies: Model organisms for ecological and evolutionary research. Oxford University Press, New York, 79-95. https://doi.org/10.1093/acprof:oso/9780199230693.003.0007
https://doi.org/10.1093/acprof:oso/97801... ). The high diversity observed in these areas can be used to foster awareness and empathy for the relevance of the conservation of these fragments of AF. Four species of Forcepsioneura (out of the eight described) occur in the state of Rio de Janeiro within the National Park of Itatiaia and REGUA and its neighboring areas represent the hotspot for this genus.

When Forcepsioneura was erected, Lencioni (1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... ) designated F. garrisoni as the type species, a poorly known species. Forcepsioneura garrisoni was only known from the male holotype, until recently when APP collected males in the states of Rio de Janeiro and Paraná that agree fairly well with the original description, and additional specimens from São Paulo, which are deposited in a private collection (F. Lencioni pers. comm.). Besides the type species, the genus also includes the shady forest species F. grossiorum, F. haerteli, F. itatiaiae, F. lucia, F. sancta and the two new species described here. Of these, F. grossiorum is known from a single male from Serra dos Órgãos and F. haerteli from two males collected in state of Santa Catarina, the southernmost known record for the genus. All these aspects help to make the generic limits (especially in relation to Amazoneura) uncertain because few are known about the included species (e.g., morphological variation, female morphology).

Erected for Amazonian species (Machado 2004Machado ABM (2004) Studies on Neotropical Protoneuridae. 15. Amazoneura gen. nov. with description of A. juruaensis sp. nov. (Odonata: Zygoptera). Revista Brasileira de Zoologia 21(2): 333-336. https://doi.org/10.1590/S0101-81752004000200029
https://doi.org/10.1590/S0101-8175200400... ), the poorly known Amazoneura can be distinguished from Forcepsioneura by eight characters as defined by Machado (2009Machado ABM (2008) [2009] Studies on neotropical Protoneuridae. 21. The status of Amazoneura Machado, 2004 (Odonata: Protoneuridae). Lundiana 9 (1): 53-56. http://www.icb.ufmg.br/lundiana/full/vol912008/05.pdf
http://www.icb.ufmg.br/lundiana/full/vol... ), even though he recognized they were weak to warrant generic delimitation. However, the rounded frons, dark markings on metepimeron and rear of head in Amazoneura and the strongly disjunct geographical distribution from Forcepsioneura were considered robust enough to support the separation between these two genera. The generic distinction between Amazoneura (Amazonia inhabitants) and Forcepsioneura (predominantly Atlantic Forest inhabitants) is still unsatisfactory (Machado 2009Machado ABM (2008) [2009] Studies on neotropical Protoneuridae. 21. The status of Amazoneura Machado, 2004 (Odonata: Protoneuridae). Lundiana 9 (1): 53-56. http://www.icb.ufmg.br/lundiana/full/vol912008/05.pdf
http://www.icb.ufmg.br/lundiana/full/vol... , Garrison et al. 2010Garrison RW, von Ellenrieder N, Louton JA (2010) Damselfly genera of the New World. An illustrated and annotated key to the Zygoptera. The John Hopkins University Press, Baltimore, 490 pp.). The inclusion of more species in Forcepsioneura and the discovery of undescribed species defy the original generic definition and make a revision necessary.

The two species described here contribute at different levels to challenge the definition of Forcepsioneura. In F. serrabonita sp. nov. the posterolateral margin of the median lobe is projected into a well-defined tubercle-like process (Figs 9, 13, 30), but it is only poorly projected in F. regua sp. nov. (Figs 3, 17, 28; an exception already cited by Machado 2009Machado ABM (2008) [2009] Studies on neotropical Protoneuridae. 21. The status of Amazoneura Machado, 2004 (Odonata: Protoneuridae). Lundiana 9 (1): 53-56. http://www.icb.ufmg.br/lundiana/full/vol912008/05.pdf
http://www.icb.ufmg.br/lundiana/full/vol... ). The homology of these processes should be investigated in a phylogenetic context because similar projections are observed in a few other genera of Protoneurinae, including Psaironeura, a putative representative of the Roppaneura clade. The short VBP observed in F. serrabonita sp. nov. (Figs 11, 21, 23), though not as short as observed in Amazoneura or even in Roppaneura, somewhat links species of these genera and probably has a value for generic definition. In addition, F. lucia also has very short VBP on the cercus.

The strong separation between AF and Amazonian species, somewhat resembling a vicarious pattern, is questionable. There are records of F. sancta (a typical AF species) from the Cerrado domain of the central Brazilian plateau (Pessacq et al. 2012Pessacq P, Santos TC, Costa JM (2012) Checklist and updated distribution of Protoneuridae from Brazil. International Journal of Odonatology 15(2): 59-73. https://doi.org/10.1080/13887890.2012.672158
https://doi.org/10.1080/13887890.2012.67... ), and an unknown Forcepsioneura species was also mentioned from the extreme northern Atlantic Forest of state of Rio Grande do Norte (Irusta and Lencioni 2015Irusta JB, Lencioni FAA (2015) First record of Pseudostigmatidae (Insecta: Odonata) in the Northeast Region of Brazil. Check List 11(2): 1-3. https://doi.org/10.15560/11.2.1565
https://doi.org/10.15560/11.2.1565... ). Forested areas in northeastern Brazil have been recently shown to be harbor a mixture between the AF and Amazonian elements (see discussion in Takiya et al. 2016Takiya DM, Santos APM, Pinto AP, Henriques-Oliveira AL, Carvalho AL, Sampaio BHL, Mattos BC, Moreira FFF, Avelino-Capistrano F, Gonçalves IC, Cordeiro IRS, Câmara JT, Barbosa JF, Souza WRM, Rafael JA (2016) Aquatic insects from the Caatinga: checklist and diversity assessment from Ubajara (Ceará State) and Sete Cidades (Piauí State) National Parks, Northeast Brazil. Biodiversity Data Journal 4: 1-195. https://doi.org/10.3897/BDJ.4.e8354
https://doi.org/10.3897/BDJ.4.e8354... ). This puzzle can only be solved, and a more suitable classification proposed, through robust phylogenetic and population level analyses of the genera involved. Indeed, recent investigations using molecular data support the monophyly of Forcepsioneura (see Pimenta et al. 2015Pimenta AL, Pinto AP, Takiya DM (2015) A first look at the phylogenetic relationships of Forcepsioneura and related genera (Coenagrionidae: Protoneurinae). ICO 2015 - International Congress of Odonatology. WDA, Argentina, 15-20.).

Based on size, general coloration, shape of cercus and habitat, Forcepsioneura can be divided into two species groups: (1) includes F. garrisoni, F. haerteli, F. regua sp. nov. and F. sancta. Small, lowland species that present pale areas predominantly bluish-green, cercus slender with ventrobasal process comparatively long, and distribution almost restricted to coastal areas of the Atlantic Forest (F. sancta is an exception), some species even occupying strictly restinga formations, being associated with small shallow streams and muddy pools with slow running water (Fig. 39); (2) includes F. grossiorum, F. itatiaiae, F. lucia, and F. serrabonita sp. nov. Large, submontane to montane species, pale areas predominately greenish-orange, cercus robust with short ventrobasal process, associated with seepages or small streams to rocky shallow waterfalls (Fig. 40). These groups do not necessarily share common evolutionary histories; however provide a useful grouping to be investigated in phylogenetic analyses.

The light blue Forcepsioneura form a complex of strongly similar species including F. garrisoni, F. regua sp. nov. and an undescribed species from southern state of Bahia. Although nothing was mentioned about blue hues in the original description of F. garrisoni (see Lencioni 1999Lencioni FAA (1999) The genus Phasmoneura, with description of Forcepsioneura gen. nov. and two new species. Odonatologica 28(2): 127-137. http://natuurtijdschriften.nl/record/592273
http://natuurtijdschriften.nl/record/592... ), we suspect that is also blue. The males recently collected in Rio de Janeiro and Paraná by APP and which have been associated to this species are bluish. Analogous to other small Protoneurinae, such as species of Drepanoneuravon Ellenrieder & Garrison, 2008von Ellenrieder N, Garrison RW (2008) Drepanoneura gen. nov. for Epipleoneura letitia and Protoneura peruviensis, with descriptions of eight new Protoneuridae from South America (Odonata: Protoneuridae). Zootaxa 1842: 1-34., Epipleoneura Williamson, 1915, and Peristicta Hagen in Selys, 1860 (see von Ellenrieder and Garrison 2008von Ellenrieder N, Garrison RW (2008) Drepanoneura gen. nov. for Epipleoneura letitia and Protoneura peruviensis, with descriptions of eight new Protoneuridae from South America (Odonata: Protoneuridae). Zootaxa 1842: 1-34., Anjos-Santos and Pessacq 2013Anjos-Santos D, Pessacq P (2013) Peristicta guarellae sp. nov. from Brazil (Odonata: Protoneuridae). International Journal of Odonatology 16(4): 293-299. https://doi.org/10.1080/13887890.2013.845066
https://doi.org/10.1080/13887890.2013.84... , Pessacq 2014Pessacq P (2014). Synopsis of Epipleoneura (Zygoptera, Coenagrionidae, “Protoneuridae”), with emphasis on its Brazilian species. Zootaxa 3872(3): 201-234. https://doi.org/10.11646/zootaxa.3872.3.1
https://doi.org/10.11646/zootaxa.3872.3.... ), they are strongly similar, and due to their extreme similarity in external morphology and coloration, species identification is only possible through careful examination of the caudal appendages and genital ligula. Therefore, it is possible that this complex of bluish species is a set of cryptic species (remember that even specialists have failed to identify them as distinct entities). Cryptic species might also be involved in distinct populations of F. lucia. This species was originally described from Rola Moça State Park, part of the Serra do Espinhaço mountain range in the state of Minas Gerais. However, other populations have recently been identified in Serra da Mantiqueira and Serra do Mar mountain ranges in state of Rio de Janeiro (Serra do Mar populations are mentioned in Kompier 2015Kompier T (2015). A guide to the dragonflies and damselflies of the Serra dos Orgaos [sic] South-easthern Brazil. Brussels, REGUA Publications, 379 pp.) and a third one was found in the state of Espírito Santo. These populations might each represent undescribed species. An ongoing integrative taxonomy research on this group of damselflies has revealed a hidden diversity (Pimenta et al. 2015Pimenta AL, Pinto AP, Takiya DM (2015) A first look at the phylogenetic relationships of Forcepsioneura and related genera (Coenagrionidae: Protoneurinae). ICO 2015 - International Congress of Odonatology. WDA, Argentina, 15-20.) and possibly will enlighten key aspects for future investigations about species delimitation in Forcepsioneura.

Additionally, Anjos-Santos and Pessacq (2013Anjos-Santos D, Pessacq P (2013) Peristicta guarellae sp. nov. from Brazil (Odonata: Protoneuridae). International Journal of Odonatology 16(4): 293-299. https://doi.org/10.1080/13887890.2013.845066
https://doi.org/10.1080/13887890.2013.84... ) considered the mysterious Peristicta lizeriaNavás, 1920Navás L (1920) Insectos Sudamericanos (2ª serie). Anales de la Sociedad Científica Argentina XC: 44-51. http://biodiversitylibrary.org/page/34988004
http://biodiversitylibrary.org/page/3498... from the province of Buenos Aires, Argentina, as a potential junior synonym of any of the two southern representatives of Peristicta, i.e., P. aeneoviridis Calvert, 1909 and P. forceps Hagen in Selys, 1860. However, there are no characters supporting Navás’ (1920Navás L (1920) Insectos Sudamericanos (2ª serie). Anales de la Sociedad Científica Argentina XC: 44-51. http://biodiversitylibrary.org/page/34988004
http://biodiversitylibrary.org/page/3498... ) original combination. Generally, Longinos Navás’s descriptions of dragonflies are insufficient for identification, and confusing. Most species erected by him still await confirmation, but even considering his inaccuracies the illustration of the caudal appendages is strongly similar to species of the Roppaneura clade and not with that observed in Peristicta. Based on recent material collected in state of Rio Grande do Sul by APP, that likely represent two unknown species of Forcepsioneura, the possibility cannot be dismissed that P. lizeria actually belongs to the Roppaneura clade, representing a valid species either of Forcepsioneura, of Roppaneura or even of a new genus.

Finally, this paper is a first step towards an understanding of the diversity and morphology of this remarkable group of damselflies typical of the threatened Atlantic Forest domain. Studies on the morphological and spatial evolution of Forcepsioneura are being conducted.

ACKNOWLEDGMENTS

This paper was only possible due to the help of Thomas W. Donnelly, Oliver Flint Jr (USNAM), Rosser W. Garrison (CDFA), and Angelo B.M. Machado (UFMG), who lent us specimens. We also thank ICMBIO/SISBIO for collecting permits; APP is strongly indebted to Rachel A. Carvalho, a colleague and specialist in leafhoppers who collected one of the holotypes and has shared interesting material from her expeditions; the protected area managers and employees, Nicholas and Raquel Locke and Jorge Bizarro (REGUA) and Vitor Becker (Serra Bonita) for their support of scientific research as a way to promote biological conservation. This study was partially supported by the following postdoctoral grants to APP: Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq-PDJ proc. 157592/2015-4) and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES-PVE proc. A019/2013).

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Publication Notes

Available online:

June 29, 2018
Zoobank Register:

http://zoobank.org/2961994A-B275-4653-86DB-80B5952C0D42
Publisher:

© 2018 Sociedade Brasileira de Zoologia. Published by Pensoft Publishers at https://zoologia.pensoft.net

Edited by

Editorial responsibility:

Gabriel L.F. Mejdalani

Data availability

Data citations

Pinto AP (2017) Odonata. In: Boeger WA, Zaher H, Rafael JA, Valim MP. Taxonomic Catalog of the Brazilian Fauna. PNUD. http://fauna.jbrj.gov.br/fauna/faunadobrasil/171 [Accessed: 26/09/2017]

Publication Dates

Publication in this collection
16 July 2018
Date of issue
2018

History

Received
30 Sept 2017
Accepted
14 Nov 2017
Published
29 June 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Amorim AM, Jardim JG, Lopes MMM, Fiaschi P, Borges RAX, Perdiz RDO, Thomas WW (2009) Angiosperms of montane forest areas in southern Bahia, Brazil. Biota Neotropica 9(3): 1-36. https://doi.org/10.1590/S1676-06032009000300028
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