Interpopulational genetic diversity in the medically important scorpion <i>Tityus obscurus</i> (Scorpiones: Buthidae) from northeastern Brazilian Amazonia

PARDAL, Pedro Pereira de Oliveira; COELHO, Johne Souza; SILVA, Joaquim Martins da; ALMEIDA, Bruno Rafael Ribeiro; CHALKIDIS, Hipócrates Menezes; BORGES, Adolfo; ISHIKAWA, Edna Aoba Yassui; DINIZ, Cristovam Guerreiro; SANTOS-NETO, Guilherme da Cruz; MELO, Mauro André Damasceno de

doi:10.1590/1809-4392202202441

ABSTRACT

Scorpion envenoming is considered a public health problem in Brazil. A recent study described a variation in the clinical outcome of envenoming by Tityus obscurus in two populations separated by 850 km in the northeastern Amazon region. Our aim was to evaluate whether such clinical and toxinological variations are associated with underlying differences in genetic diversity between these two T. obscurus populations. We obtained DNA from five individuals of each population, in the municipalities of Belém and Santarém, located east and west of the state of Pará, Brazil, respectively. Gene regions encoding mitochondrial DNA (mtDNA) markers cytochrome oxidase subunit I (COI) and ribosomal 16S RNA (16S) were amplified and sequenced. Phylogenetic analyses were performed using maximum likelihood (ML) and Bayesian inferences (BA) for both molecular data (COI and 16S). The sampled T. obscurus populations corresponded to two distinct mtDNA lineages (genetic distance COI_K2 P = 0.08 to 0.13; 16S_K2 P = 0.10 to 0.11) with no shared mutations between groups and well supported by ML and BA inferences. Based on the divergence values found between eastern and western populations (COI, 0.07 to 0.12; 16S, 0.10), our study confirms the genetic heterogeneity of T. obscurus populations within the state of Pará, which correlates with observed venom and clinical differences, and reinforces the need for mapping the distribution of haplotypes throughout the geographic range of T. obscurus, to aid in future epidemiological, toxinological, and evolutionary studies.

KEYWORDS:
mitochondrial DNA; phylogenetic analyses; cytochrome oxidase subunit I; 16S RNA

RESUMO

O envenenamento por escorpiões é considerado um problema de saúde pública no Brasil. Um estudo recente descreve a variação do quadro clínico de envenenamento por Tityus obscurus em duas populações separadas por uma distância de 850 km no nordeste da Amazônia. O objetivo deste estudo foi avaliar se tais variações clínicas e toxicológicas estão associadas a diferenças subjacentes na diversidade genética entre essas duas populações de T. obscurus. Obtivemos DNA de cinco indivíduos de cada população nos municípios de Belém e Santarém, localizados a leste e oeste do estado do Pará, Brasil, respectivamente. Regiões gênicas que codificam marcadores de DNA mitocondrial (mtDNA) citocromo oxidase subunidade I (COI) e RNA ribossômico 16S (16S) foram amplificadas e sequenciadas. As análises filogenéticas foram realizadas por máxima verossimilhança (ML) e inferência Bayesiana (BA) para ambos os dados moleculares (COI e 16S). As populações de T. obscurus amostradas corresponderam a duas linhagens distintas de mtDNA (distância genética COI_K2 P = 0,08 a 0,13; 16S_K2 P = 0,10 a 0,11) sem mutações compartilhadas entre os grupos, e bem corroboradas por inferências ML e BA. Com base nos valores de divergência encontrados entre as populações oriental e ocidental (COI, 0,07 a 0,12; 16S, 0,10), nosso estudo confirma a heterogeneidade genética das populações de T. obscurus no estado do Pará. Os resultados são congruentes com as diferenças observadas no quadro clínico dos acidentes e toxicidade do veneno, e reforçam a necessidade de mapear a distribuição de haplótipos em toda a distribuição geográfica de T. obscurus, para auxiliar em futuros estudos epidemiológicos, toxinológicos e evolutivos.

PALAVRAS-CHAVE:
DNA mitocondrial; analise filogenética; citocromo oxidase subunidade I; RNA 16S

INTRODUCTION

Up to January 2021, 2433 known scorpion species have been reported worldwide (Dupré 2021Dupré, G. 2021. Checklist of scorpions’ taxa 1758-2020. Arachnides, 100: 1-112.). In Brazil, the scorpion diversity is high, with about 131 known species belonging to 23 genera and four families: Bothriuridae, Buthidae, Chactidae and Hormuridae (Lourenço 2002Lourenço, W.R. 2002. Scorpions of Brazil. Les editions de l’If Paris, Paris, 320p.; 2017Lourenço, W.R. 2017. Description of a new species of Opisthacanthus Peters (Scorpiones: Hormuridae) from Suriname/Brazil border with some biogeographic considerations. Acta Biológica Paranaense, 46: 9-22. ). The genus Tityus represents the most widely spread buthid group, responsible for the majority of severe and fatal scorpion envenoming cases in South America (Chippaux and Goyffon 2008Chippaux, J.P.; Goyffon, M. 2008. Epidemiology of scorpionism: a global appraisal. Acta Tropica, 107: 71-79. ; Borges et al. 2021Borges, A.; Graham, M.R.; Cândido, D.M.; Pardal, P.P.O. 2021. Amazonian scorpions and scorpionism: integrating toxinological, clinical, and phylogenetic data to combat a human health crisis in the world’s most diverse rainfores. Journal of Venomous Animals and Toxins including Tropical Diseases, 29: e20210028.).

In 2021, a total of 149,677 scorpion envenoming cases were registered in Brazil, with 228 accidents leading to death, of which 71 were reported from the Amazon region (Brasil 2022Brasil. 2022. Acidentes por animais peçonhentos - Notificações registradas no Sistema de Informação de Agravos de notificação. Ministério da Saúde/ Data-SUS. Brasilia. ( (http://tabnet.datasus.gov.br/cgi/tabcgi.exe?sinannet/cnv/animaisbr.def ). Accessed on 20 Mar 2022.
http://tabnet.datasus.gov.br/cgi/tabcgi.... ). Scorpionism is considered a health problem in Brazil associated with poverty and the lack of access to effective antivenoms in remote regions, together with the ability of some medically significant species to invade urban areas, being children and the elderly the most vulnerable groups (Chippaux and Goyffon 2008Chippaux, J.P.; Goyffon, M. 2008. Epidemiology of scorpionism: a global appraisal. Acta Tropica, 107: 71-79. ; Amado et al. 2021Amado, T.F.; Moura, T.A.; Riul, P.; Lira, A.F.A.; Badillo-Montaño, R.; Martinez, P.A. 2021. Vulnerable areas to accidents with scorpions in Brazil. Tropical Medicine & International Health, 26: 591-601.).

Tityus obscurus, Gervais 1843 is an 8 to 10 cm-long, dark scorpion frequently associated with envenomings in the Brazilian Amazon region, especially in the states of Pará and Amapá (Lourenço and Leguin 2008Lourenço, W.R.; Leguin, E.A. 2008.The true identity of Scorpio (Atreus) obscurus Gervais, 1843 (Scorpiones, Buthidae). Euscorpius, 75: 1-9. ). The species is widely distributed in South America, from French Guiana to northern Brazil (states of Pará and Amapá) (Lourenço et al. 2019Lourenço, W.R.; Rossi, A.; Wilmé, L. 2019. Further clarifications on species of Tityus C. L. Koch, 1836, subgenus Atreus Gervais, 1843 (Scorpiones: Buthidae), from Amazonia, with the description of a new species. Rivista Aracnologica Italiana, 21: 11-25.; Martins et al. 2021Martins, J.G.; Santos, G.C.; Procópio, R.E.L.; Arantes, E.C.; Bordon, K.C.F. 2021. Scorpion species of medical importance in the Brazilian Amazon: a review to identify knowledge gaps. Journal of Venomous Animals and Toxins including Tropical Diseases , 20: e20210012. ). The type and magnitude of clinical manifestations associated with scorpion envenoming are related, among other factors, to the amount of venom injected and inflammatory mediators released thereof (Abroug et al. 2020Abroug, F.; Ouanes-Besbes, L.; Tilouche, N.; Elatrous, S. 2020. Scorpion envenomation: state of the art. Intensive Care Medicine, 46: 401-410.). Current classification of envenoming severity includes three groups of cases: mild, moderate and severe (Brasil 2001Brasil. 2001. Manual de diagnóstico e tratamento de acidentes por animais peçonhentos. Ministério da Saúde/Fundação Nacional de Saúde. Brasília. ( (https://www.icict.fiocruz.br/sites/www.icict.fiocruz.br/files/Manual-de-Diagnostico-e-Tratamento-de-Acidentes-por-Animais-Pe--onhentos.pdf ). Accessed on 20 May 2022.
https://www.icict.fiocruz.br/sites/www.i... ). A recent study involving scorpion envenoming cases by two populations of T. obscurus from eastern and western Pará showed that clinical manifestations and severity differed significantly between these areas, suggesting an underlying geographical variation in T. obscurus venom toxicity and composition across Pará (Pardal et al. 2014Pardal, P.P.O.; Ishikawa, E.A.; Vieira, J.L.; Coelho, J.S.; Dórea, R.C.; Abati, P.A.; et al. 2014. Clinical aspects of envenomation caused by Tityus obscurus (Gervais, 1843) in two distinct regions of Pará state, Brazilian Amazon basin: a prospective case series. Journal of Venomous Animals and Toxins including Tropical Diseases , 20: 3. doi:10.1186/1678-9199-20-3.
https://doi.org/10.1186/1678-9199-20-3... ; Torrez et al. 2015Torrez, P.P.Q.; Quiroga, M.M.M.; Abati, P.A.M.; Mascheretti, M.; Costa, W.S.; Campos, L.P.; et al. 2015. Acute cerebellar dysfunction with neuromuscular manifestations after scorpionism presumably caused by Tityus obscurus in Santarém, Pará/Brazil. Toxicon, 96: 68-73. ). Further investigation of these variations between T. obscurus populations should ideally be based on the evaluation of their genetic divergence, to explore the existence of a putative T. obscurus species complex, as has been suggested previously based on morphological evidence (Lourenço et al. 2019Lourenço, W.R.; Rossi, A.; Wilmé, L. 2019. Further clarifications on species of Tityus C. L. Koch, 1836, subgenus Atreus Gervais, 1843 (Scorpiones: Buthidae), from Amazonia, with the description of a new species. Rivista Aracnologica Italiana, 21: 11-25.). Other species complexes have been described for similarly amply distributed scorpions, such as the Australian Urodacus yaschenko (Luna-Ramirez et al. 2017Luna-Ramirez, K.; Miller, A.D.; Rašić, G. 2017. Genetic and morphological analyses indicate that the Australian endemic scorpion Urodacus yaschenkoi (Scorpiones: Urodacidae) is a species complex. Peer Journal, 5: e2759. ) and the Afro-Mediterranean Buthus occitanus (Klesser et al. 2021Klesser, R.; Husemann, M.; Schmitt, T.; Sousa, P.; Moussi, A.; Habel, J.C. 2021. Molecular biogeography of the Mediterranean Buthus species complex (Scorpiones: Buthidae) at its southern Palaearctic margin. Biological Journal of the Linnean Society, 133: 166-178.). Significantly, variation in scorpion venom composition has been shown to generally increase with geographical distance in the case of amply distributed scorpion species in the African genera Parabuthus, Uroplectes and Opistophthalmus (Schaffrath et al. 2018Schaffrath, S.; Prendini, L.; Predel, R. 2018. Intraspecific venom variation in southern African scorpion species of the genera Parabuthus, Uroplectes and Opistophthalmus (Scorpiones: Buthidae, Scorpionidae). Toxicon, 144: 83-90. ). A study to evaluate genetic variability of toxinologically divergent populations of Amazonian scorpions of medical importance, such as T. obscurus, would clearly benefit the understanding of their public health importance as risk maps could be defined using a multidisciplinary approach.

Though mtDNA markers have been used previously in systematic studies of scorpions (Gantenbein et al. 2001Gantenbein, B.; Fet, V.; Barker, M.D. 2001. Mitochondrial DNA reveals a deep, divergent phylogeny in Centruroides exilicauda (Wood, 1863) (Scorpiones: Buthidae). In: Fet, V.; Selden, P.A. (Ed.). Scorpions. In Memoriam Gary A. Polis. The British Arachnological Society, Burnham Beeches, p.235-244.; Borges et al. 2010Borges, A.; Bermingham, E.; Herrera, N.; Alfonzo, M.J.; Sanjur, O.I. 2010. Molecular systematics of the neotropical scorpion genus Tityus (Buthidae): the historical biogeography and venom antigenic diversity of toxic Venezuelan species. Toxicon, 55: 436-54. ; Ojanguren-Affilastro et al. 2017Ojanguren-Affilastro, A.A.; Adilardi, R.S.; Cajade, R.; Ramirez, M.J.; Ceccarelli, F.S.; Mola, L.M. 2017. Multiple approaches to understanding the taxonomic status of an enigmatic new scorpion species of the genus Tityus (Buthidae) from the biogeographic island of Paraje Tres Cerros (Argentina). PLoS ONE, 12: e0181337. ), their potential for elucidating genetic diversity in Amazonian scorpion species still remains unclear, particularly in the case of Tityus species associated with severe/lethal cases (Borges et al. 2021). Therefore, this study was designed as the first attempt to evaluate the genetic diversity among medically significant T. obscurus populations inhabiting Pará state, Brazil, and relationship with the regional clinical and toxinological variations observed in previous studies.

MATERIAL AND METHODS

Study Area

Samples (n = 5 individuals per site) were collected in two different sites located in the state of Pará, Brazil: two females, one male and two juveniles from Belém (01°27’21”S, 48°30’14”W), and five males from Santarém (2º24’52”S, 54º42’36”W). Both sites are 850 km apart from each other and are separated by the Xingu and Tocantins rivers (Figure 1).

Figure 1
Location of Pará state in Brazil (small map), and outline of Pará state showing the location of the two sampling sites: municipality of Santarém (west) and municipality of Belém (east) where Tityus obscurus were collected. This figure is in color in the electronic version.

Species identification

All individuals were identified as T. obscurus at the Laboratory of Medical Entomology and Venomous Arthropods at the Nucleus Tropical Medicine of Federal University of Pará (LEMAP/NMT/UFPA), based on their morphological characteristics (Lourenço 2002Lourenço, W.R. 2002. Scorpions of Brazil. Les editions de l’If Paris, Paris, 320p.; Lourenço and Leguin 2008). To confirm their identity further, samples were sent to Instituto Butantan (São Paulo), where their classification as Tityus obscurus was assertained based on current taxonomic keys (Lourenço and Leguin 2008) (Figure 2). All samples were preserved in 70% ethanol, and are deposited at the UFPA Arachnological Collection, with the numbers 381, 359, 360, 362, 391 LEMAP/NMT/UFPA (eastern scorpions) and 393, 364, 377, 378 and 379 LEMAP/NMT/UFPA (western scorpions).

Figure 2
Tityus obscurus collected from the eastern population (A - male; B - female) and the western population (C - male; D - female) in Pará state, Brazil. This figure is in color in the electronic version.

This study was conducted in strict accordance with the ethical recommendations for the use and management of animals in research, and was approved by the ethics committee on research involving human beings (medical ethics committee) of the Nucleus of Tropical Medicine at Universidade Federal do Pará-UFPA (license # 038/2007) and by the Brazilian Environmental Institute (Instituto Brasileiro do Meio Ambiente e dos Recursos Naturais Renováveis - IBAMA) (SISBIO license # 11727-2).

DNA extraction, amplification and sequencing

DNA was extracted from tissue obtained from the pedipalps of each sampled specimen using Qiagen Kit (GENTRA® - Generation^® Capture Column™ Kit) according to the manufacturer’s recommendations. Fragments of mtDNA were amplified using primers 16SF (5’- CGATTTGAACTCAGATCA-3’ designed by Gantenbein et al. 1999Gantenbein, B.; Fet, V.; Largiader, C.R.; Scholl, A. 1999. First DNA phylogeny of Euscorpius Thorell, 1876 (Scorpiones, Euscorpiidae) and its bearing on taxonomy and biogeography of this genus. Biogeographica, 75: 49-65.) and LR-J-12887 (5’-GTGCAAAGGTAGCATAATCA-3’; Simon et al. 1994Simon, C.; Frati, F.; Beckenbach, A.; Crespi, B.; Liu, H.; Flook, P. 1994. Evolution, weighting, and phylogenetic utility of mitochondrial gene sequences and a compilation of conserved polymerase chain reaction primers. Annals of the Entomological Society of America, 87: 651-701.) for the 16S rRNA gene. For COI amplification the following primers were used: C1-J-2183 (5’-CAACATTTATTTTGATTTTTTGG-3’; Simon et al. 1994) and COIKG-R2 (5’- GATATTAATCCTAAAAAATGTTGAGG-3’; Tanaka et al. 2001Tanaka, H.; Roubik, D.W.; Kato, M.; Liew, F.; Gunsalam, G. 2001. Phylogenetic position of Apis nuluensis on northern Borneo and phylogeography of A. cercana as inferred from mitochondrial DNA sequences. Insectes Sociaux, 48: 44-51.). All primers were synthesized by Operon Technologies (USA).

PCR conditions for 16S consisted of an initial denaturation step at 94°C for 5 min; 30 cycles of 45 sec at 94°C, 45 sec at 48°C and 45 sec at 72°C, followed by a final extension at 72°C for 10 min. COI amplification was performed with the following amplification cycles: denaturation at 94 ⁰C for 5 min; four cycles of denaturing at 94 ⁰C for 30 s, annealing at 48 ⁰C for 30 s, and extension at 72 ⁰C for 1 min; 29 cycles of denaturation at 94 ⁰C for 30 s, annealing at 52 ⁰C for 30 s, extension at 72 ⁰C for 1 min; a final extension at 72 ⁰C for 5 min (Borges et al. 2010Borges, A.; Bermingham, E.; Herrera, N.; Alfonzo, M.J.; Sanjur, O.I. 2010. Molecular systematics of the neotropical scorpion genus Tityus (Buthidae): the historical biogeography and venom antigenic diversity of toxic Venezuelan species. Toxicon, 55: 436-54. ).

Amplified PCR products were purified using ExoSAP-IT^® (Amersham Pharmacia Biotech. Inc., Piscataway, NJ, USA). Sequencing was performed on a MegaBace 750 automated sequencing platform using BigDye Terminator v3.1 Cycle Sequencing Kit according to the manufacturer’s protocols.

Sequence alignment and edition of COI and 16S fragments were performed with BioEdit 7 (Hall 1999Hall, T.A. 1999. BioEdit: A user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symposium Series, 41: 95-98.) and ClustalX 1,82 (Thompson et al. 1997Thompson, J.D.; Gibson, T.J.; Plewniak, F.; Jeanmougin, F.; Higgins, D.G. 1997. The CLUSTAL_X windows interface: flexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Research, 25: 4876-4882. ). Nucleotide sequences obtained in this study were deposited in GenBank under accession numbers JX196960 - JX196969. The species Centruroides vittatus (Say, 1821) (GenBank sequences COI - EU404118.1; 16S - EU499946.1) was used as outgroup. GenBank sequences of T. obscurus Morona (COI - MF466178.1), T. asthenes (COI - MF466177.1), T. perijanensis (COI - AY586787.1; 16S - AY586754.1) and T. clathratus (COI - KY982266.1; 16S - KY981980.1) were used to improve the robustness of the phylogenetic arrangement. A saturation test was performed using the software DAMBE 4.2.13 (Xia and Xie 2001Xia, X.; Xie, Z. 2001.DAMBE: software package for data analysis in molecular biology and evolution. Journal of Heredity, 92: 371-373.). Haplotype and nucleotide diversity were identified by DnaSP 4.0 (Rozas et al. 2003Rozas, J.; Sánchez-DelBarrio, J.C.; Messeguer, X.; Rozas, R. 2003. DnaSP, DNA polymorphism analyses by the coalescent and other methods. Bioinformatics, 19: 2496-2497.) and levels of genetic distance (Kimura Two-Parameters - K2P and P distances) were estimated by the software MEGA 6.0.6 (Tamura et al. 2013Tamura, K.; Stecher, G.; Peterson, D.; Filipski, A.; Kumar, S. 2013. MEGA6: Molecular Evolutionary Genetics Analysis version 6.0. Molecular Biology and Evolution, 30: 2725-2729. ).

Phylogenetic analyses were performed with PhyML 3.1 (Guindon and Gascuel 2003Guindon, S.; Gascuel, O. 2003. A simple, fast, and accurate algorithm to estimate large phylogenies by maximum likelihood.Systematic Biology, 52: 696-704. ) for the maximum likelihood (ML) method, and MrBayes 3.2 (Ronquist et al. 2012Ronquist, F.; Teslenko, M.; Van der Mark, P.; Ayres, D.L.; Darling, A.; Höhna, S.; et al. 2012. MrBayes 3.2: efficient Bayesian phylogenetic inference and model choice across a large model space. Systematic Biology, 61: 539-542. ) for a Bayesian analysis (BA). The ML analysis was performed using 1000 bootstrap replicates, and using frequencies, gamma shape and transition/transversion rates set by user according to the parameters of the Akaike Information Criterion correction (AICc). For the Bayesian analysis, Monte Carlo Markov Chains were used with a parameter of 10⁶ generations, the initial heated chain set to 0.2 and a burn-in of 3000, determined by preliminary runs. The software MODELTEST 3.07 (Posada and Crandall 1998Posada, D.; Crandall, K.A. 1998. MODELTEST: testing the model of DNA substitution. Bioinformatics, 14: 817-818. ) was used for choosing the best mutation model applied in ML and BA analyses, using the AICc criterion and Bayesian Information Criterion (BIC), respectively. The best choice of model was the Hasegawa-Kishino-Yano, HKY (Hasegawa et al. 1985Hasegawa, M.; Kishino, H.; Yano, T. 1985. Dating of the human-ape splitting by a molecular clock of mitochondrial DNA. Journal of Molecular Evolution, 22: 160-174.) for ML and for BA. A haplotype network was performed with Haploviewer (Salzburger et al. 2011Salzburger, W.; Ewing, G.B.; Von Haeseler, A. 2011. The performance of phylogenetic algorithms in estimating haplotype genealogies with migration. Molecular Ecology, 20: 1952-1963.), in order to establish the relationship between the different haplotypes, taking into account only variable sites using parsimony algorithms.

RESULTS

521-bp and 364-bp long fragments were obtained after partial sequencing of amplified COI and 16S genes, respectively, in the sampled populations of T. obscurus. Sample ToW5 from western Pará did not amplify for COI (Table 1). After analysis of the COI sequences, the western population exhibited four haplotypes, with two polymorphic sites and values of 0.8000 and 0.0019 for haplotype and nucleotide diversity, respectively. The eastern population presented five haplotypes, with 24 polymorphic sites and values of 1.000 and 0.0255 for haplotype and nucleotide diversity, respectively. After analysis of the 16S sequences, the western population presented four haplotypes, with three polymorphic sites and values of 0.7000 and 0.0033 for haplotype and nucleotide diversity, respectively. The eastern population exhibited five haplotypes, with five polymorphic sites and values of 1.000 and 0.0071 for haplotype and nucleotide diversity, respectively. No evidence of shared mutations was observed between eastern and western T. obscurus populations regarding these genes. The network based on COI and 16S genetic markers showed that the haplotypes are divided in two haplogroups, with no shared haplotypes, and separated by 38 and 34 mutations for COI and 16S sequences, respectively. H7 was the only 16S haplotype observed in two individuals from the western group (Figure 3).

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Table 1
K2P genetic distance between two populations of Tityus obscurus (T.o.) from the west and east of Pará state (Brazil) and Centruroides vittatus (C.v.) obtained from mitochondrial 16S (below the diagonal) and COI (above the diagonal) sequences. NA - non-amplified sample.

Figure 3
Haplotype network for the two populations of Tityus obscurus, performed for COI (A) and 16S (B) sequences obtained from the east and west of Pará state, Brazil.

The K2P distance matrix showed the existence of two groups, with COI values across individuals ranging from 0.00 to 0.04 within populations, and from 0.08 to 0.13 between the eastern and western groups (Table 1). Similarly, the K2P distance for 16S across individuals ranged from 0.00 to 0.01 observed within each population and from 0.10 to 0.11 between the eastern and western groups (Table 1). The P distance matrix exhibited COI values across individuals ranging from 0.01 to 0.04 inside populations and from 0.07 to 0.12 between the eastern and western groups, also equivalent to P distance for 16S across individuals varying from 0.00 to 0.03 inside populations and exhibiting 0.10 between the eastern and western groups (Table 2). Tree topologies obtained by maximum likelihood (ML) and Bayesian (BA) methods with COI and 16S mitochondrial fragments were similar, and clearly showed the existence of divergence between the eastern and western T. obscurus groups (Figure 4 and 5) forming two independent groups.

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Table 2
P genetic distance between two populations of Tityus obscurus (T.o.) from the west and east of Pará state (Brazil) and Centruroides vittatus (C.v.) obtained from mitochondrial 16S (below the diagonal) and COI (above the diagonal) sequences. NA - non-amplified sample.

Figure 4
Phylogenetic tree constructed through maximum likelihood (ML) for Tityus obscurus from the west (T. obscurus West 1 to 4) and east (T. obscurus East 1 to 5) of Pará state (Brazil) and sequences from T. obscurus and species from GenBank based on COI. Bayesian posterior probabilities and bootstrap percentages are shown above and below the branches, respectively.

Figure 5
Phylogenetic tree performed by maximum likelihood (ML) for Tityus obscurus from the west (T. obscurus West 1 to 4) and east (T. obscurus East 1 to 5) of Pará state (Brazil) and sequences from T. obscurus and species from GenBank based on 16S. Bayesian posterior probabilities and bootstrap percentages are shown above and below the branches, respectively.

DISCUSSION

The genetic divergence between the eastern and western T. obscurus populations in Pará state, Brazil, uncovered in this study offers further proof of the existence of a T. obscurus species complex in Amazonia. According to Almeida et al. (2017Almeida, B.R.R.; Milhomem-Paixão, S.S.R.; Noronha, R.C.R.; Nagamachi, C.Y.; Costa, M.J.R.D.; Pardal, P.P.O.; Coelho, J.S.; Pieczarka, J.S. 2017. Karyotype diversity and chromosomal organization of repetitive DNA in Tityus obscurus (Scorpiones, Buthidae). BMC Genetics, 18: 35. doi.org/10.1186/s12863-017-0494-6
https://doi.org/doi.org/10.1186/s12863-0... ), chromosomal diversity among T. obscurus populations inhabiting the region analyzed in our study may have contributed to their reproductive isolation. The extent of mtDNA divergence between the eastern and western T. obscurus lineages found by us exceeds estimates of interspecific divergence reported for other scorpion groups. In this sense, pairwise distances based on K2P for COI and 16S between the T. obscurus eastern and western groups (COI_K2P = 0.08 to 0.13; 16S_K2P = 0.10 to 0.11) are higher than those observed between species of the genus Mesobuthus (COI_K2P = 0.05 to 0.08) (Mirshamsi et al. 2010Mirshamsi, O.; Sari, A.; Elahi, E.; Hosseinie, S. 2010. Phylogenetic relationships of Mesobuthus eupeus (C.L. Koch, 1839) inferred from COI sequences (Scorpiones: Buthidae). Journal of Natural History, 44: 2851-2872. ), and similar to those observed in different species of the genus Euscorpius (16S_K2P = 0.04 to 0.12) (Soleglad and Fet 2003Soleglad, M.E.; Fet, V. 2003. High-level systematics and phylogeny of the extant scorpions (Scorpiones: Orthosterni). Euscorpius, 11: 1-56. ). The values of 16S pairwise distances (P distance) across different lineages of Centruroides exilicauda varyed from 0.01 to 0.15 (Gantenbein et al. 2001Gantenbein, B.; Fet, V.; Barker, M.D. 2001. Mitochondrial DNA reveals a deep, divergent phylogeny in Centruroides exilicauda (Wood, 1863) (Scorpiones: Buthidae). In: Fet, V.; Selden, P.A. (Ed.). Scorpions. In Memoriam Gary A. Polis. The British Arachnological Society, Burnham Beeches, p.235-244.), resembling our values for T. obscurus (16S_{P distance} = 0.10). The same was observed for different species of the genus Euscorpius, with 16S divergence varying from 0.04 to 0.12 (Soleglad and Fet 2003), similarly to our results. COI and 16S in both pairwise distances (K2P and P distance) between the eastern and western groups exhibited half of the divergence observed when compared to the far related Centruroides vittatus. This species was chosen as outgroup because Centruroides, together with Zabius, is paraphyletic with respect to Tityus (Esposito et al. 2018Esposito, L.A.; Yamaguti, H.Y.; Pinto-da-Rocha, R.; Prendini, L. 2018. Plucking with the plectrum: Phylogeny of the New World buthid scorpion subfamily Centruroidinae Kraus, 1955 (Scorpiones: Buthidae) reveals evolution of three pecten-sternite stridulation organs. Arthropod Systematics and Phylogeny, 76: 87-122.). Taken together, the above observations suggest the existence of a complex of species or subspecies related to T. obscurus, which deserves further research.

The mtDNA divergence observed between the regional lineages of T. obscurus, evidenced in our tree topologies and haplotype network may be a consequence of isolation by geographic or ecological barriers. The existence of 34 - 38 mutations (16S and COI, respectively) separating these groups without shared haplotypes supports this hypothesis. A priori, genetically differentiated populations of T. obscurus could have originated by vicariance, through the fragmentation of its ancestral distribution by barriers represented by the Xingu and Tocantins rivers, promoting geographic isolation and reducing gene flow between scorpion populations (Ceccarelli et al. 2017Ceccarelli, F.S.; Pizarro-Araya, J.; Ojanguren-Affilastro, A.A. 2017. Phylogeography and population structure of two Brachistosternus species (Scorpiones: Bothriuridae) from the Chilean coastal desert - the perils of coastal living. Biological Journal of the Linnean Society, 120: 75-89. ). The process of genetic differentiation in T. obscurus may also have been influenced by other biogeographic factors such as environmental heterogeneity and isolation by distance, (Santorelli et al. 2018Santorelli, S.; Magnusson, W.E.; Deus, C.P. 2018. Most species are not limited by an Amazonian River postulated to be a border between endemism areas. Scientific Reports, 8: 2294. doi.org/10.1038/s41598-018-20596-7
https://doi.org/doi.org/10.1038/s41598-0... ; Dambros et al. 2020Dambros, C.; Zuquim, G.; Moulatlet, G.M.; Costa F.R.C.; Tuomisto, H.; Ribas, C.C.; et al. 2020. The role of environmental filtering, geographic distance and dispersal barriers in shaping the turnover of plant and animal species in Amazonia.Biodiversity and Conservation, 29: 3609-3634.) since our two populations are separated by 850 km. Tityus obscurus is widely distributed throughout the Amazon region, and both populations analyzed in this study occupy several microhabitats, such as canopy in floodplain (igapó) forests, leaf sheaths of Arecaceae palms, and litter in terra firme forests (Martins et al. 2021Martins, J.G.; Santos, G.C.; Procópio, R.E.L.; Arantes, E.C.; Bordon, K.C.F. 2021. Scorpion species of medical importance in the Brazilian Amazon: a review to identify knowledge gaps. Journal of Venomous Animals and Toxins including Tropical Diseases , 20: e20210012. ). In Alter do Chão, municipality of Santarém (western population), the forest vegetation (especially floodplain forests) forms a mosaic with savannah areas, which is not observed in Belém (eastern population), increasing the environmental heterogeneity of this region (Magnusson et al. 2008Magnusson, W.E.; Lima, A.P.; Albernaz, A.L.K.M; Sanaiotti, T.M.; Guillaumet, J.L. 2008. Composição florística e cobertura vegetal das savanas na região de Alter do Chão, Santarém-PA. Brazilian Journal of Botany, 31: 165-177.). This habitat disruption limits the dispersal of scorpions adapted to forest environments (Lourenço 2002Lourenço, W.R. 2002. Scorpions of Brazil. Les editions de l’If Paris, Paris, 320p.). This mosaic pattern may reflect historical events, such as processes of contraction and expansion of the vegetation cover of the Amazon forest during climate changes in the last ice ages, which resulted in small forest fragments, for which it is suggested that a certain rate of speciation/extinction occurred (Rocha and Kaefer 2019Rocha, D.G.; Kaefer, I.L. 2019. What has become of the refugia hypothesis to explain biological diversity in Amazonia? Ecology and Evolution, 9: 4302-4309. ). This phenomenon contributed to the emergence of inter- and intrapopulational morphological variations in some Tityus species inthe Amazon (Lourenço 2018Lourenço, W.R. 2018. The evolution and distribution of noxious species of scorpions (Arachnida: Scorpiones). Journal of Venomous Animals and Toxins including Tropical Diseases, 24: 1-12.). These ecological and biogeographical factors, associated with the low vagility of scorpions (Lourenço 2015Lourenço W.R. 2015. Scorpion diversity and distribution; past and present patterns. In: Gopalakrishnakone, P.; Possani, L.F.; Schwartz, E.; Rodríguez de la Vega, R. (Ed.). Scorpion Venoms. Toxinology, v.4., Springer, Dordrecht, p.3-23. ), may have played an important role in the cryptic genetic differentiation of T. obscurus.

The genetic divergence observed at the molecular level correlates with the previous clinical findings reported by Pardal et al. (2014Pardal, P.P.O.; Ishikawa, E.A.; Vieira, J.L.; Coelho, J.S.; Dórea, R.C.; Abati, P.A.; et al. 2014. Clinical aspects of envenomation caused by Tityus obscurus (Gervais, 1843) in two distinct regions of Pará state, Brazilian Amazon basin: a prospective case series. Journal of Venomous Animals and Toxins including Tropical Diseases , 20: 3. doi:10.1186/1678-9199-20-3.
https://doi.org/10.1186/1678-9199-20-3... ). The symptom referred to by patients as “electric body shock” was reported as related to accidents with T. obscurus in northern Brazil and this clinical manifestation was associated to envenoming cases occurring solely in western Pará (Santarém). Symptoms such as myoclonus, difficulty in ambulation, and strong muscular contractions, are all totally absent in envenoming cases from eastern Pará (Belém), which suggests compositional and physio-pathological variations in the toxicity of T. obscurus venom from different areas of the Brazilian Amazon basin (Pardal et al. 2014; Borges et al. 2021Borges, A.; Graham, M.R.; Cândido, D.M.; Pardal, P.P.O. 2021. Amazonian scorpions and scorpionism: integrating toxinological, clinical, and phylogenetic data to combat a human health crisis in the world’s most diverse rainfores. Journal of Venomous Animals and Toxins including Tropical Diseases, 29: e20210028.). Similar cases of association between genetic differentiation and venom variation have been reported for other scorpion species (Abdel-Rahman et al. 2009Abdel-Rahman, M.A.; Omran, M.A.A.; Abdel-Nabi, I.M.; Ueda, H.; McVean, A. 2009. Intraspecific variation in the Egyptian scorpion Scorpio maurus palmatus venom collected from different biotopes. Toxicon, 53: 349-359.; Borges et al. 2020Borges, A.; Lomonte, B.; Ângulo, Y.; Patiño, H.A.; Pascale, J.M.; Otero, R.; et.al. 2020. Venom diversity in the Neotropical scorpion genus Tityus: Implications for antivenom design emerging from molecular and immunochemical analyses across endemic areas of scorpionism. Acta Tropica, 204: 105346. ). Once identified and mapped using genetic tools, knowledge of the distribution of these two groups could lead to more specific therapeutic interventions using region-specific strategies in future envenoming cases.

As suggested by Torrez et al. (2015Torrez, P.P.Q.; Quiroga, M.M.M.; Abati, P.A.M.; Mascheretti, M.; Costa, W.S.; Campos, L.P.; et al. 2015. Acute cerebellar dysfunction with neuromuscular manifestations after scorpionism presumably caused by Tityus obscurus in Santarém, Pará/Brazil. Toxicon, 96: 68-73. ), further characterization of the unique venom activity at the cerebellar level associated with western populations of T. obscurus is necessary, especially because the severity of this manifestation requires the use of benzodiazepines even after the antivenom administration. The antivenom produced in Brazil against Tityus serrulatus (Lutz & Melo, 1922), the species responsible for the most severe accidents in southeast Brazil, does not recognize the low molecular mass of the neurotoxic fraction of T. obscurus nor neutralizes significantly its hyaluronidase activity (Guerra-Duarte et al. 2019Guerra-Duarte, C.; Horta, C.C.R.; Oliveira-Mendes, B.B.R.; Magalhães, B.F.; Costal-Oliveira, F.; Stransky, S.; et al. 2019. Determination of hyaluronidase activity in Tityus spp. Scorpion venoms and its inhibition by Brazilian antivenoms. Toxicon, 167: 134-143. ). The synergistic action of low molecular mass neurotoxins (which alter the gating mechanism of various ion channels) and the connective-tissue degrading hyaluronidase activity are responsible for the systemic effects of Tityus venoms (Abroug et al. 2020Abroug, F.; Ouanes-Besbes, L.; Tilouche, N.; Elatrous, S. 2020. Scorpion envenomation: state of the art. Intensive Care Medicine, 46: 401-410.). The approach proposed here could be instrumental for evaluating the actual distribution of the medically important western T. obscurus population, and for estimating the overall genetic structure of the T. obscurus complex, which possibly underlies the existence of diversity gradients for venom toxic and immunogenic components. In this sense, the recent finding that Tityus cisandinus (Lourenço and Ythier 2017Lourenço, W.R.; Ythier E. 2017. Description of Tityus (Atreus) cisandinus sp. n. from Ecuadorian Amazonia, with comments on some related species (Scorpiones: Buthidae). Arachnida. Rivista Aracnologica Italiana , 15: 18-34.) from Amazonian Ecuador is genetically related to T. obscurus from Brazilian Amazonia, as its envenoming syndrome also includes neurological alterations (Román et al. 2018Román, JP.; García, F.; Medina, D.; Vásquez, M.; García, J.; Graham, MR ; Romero-Alvarez, D.; Pardal, PPO.; Ishikawa, EAY.; Borges, A. 2018. Scorpion envenoming in Morona Santiago, Amazonian Ecuador: molecular phylogenetics confirms involvement of the Tityus obscurus group. Acta Tropica, 178: 1-9.; Borges et al. 2021Borges, A.; Graham, M.R.; Cândido, D.M.; Pardal, P.P.O. 2021. Amazonian scorpions and scorpionism: integrating toxinological, clinical, and phylogenetic data to combat a human health crisis in the world’s most diverse rainfores. Journal of Venomous Animals and Toxins including Tropical Diseases, 29: e20210028.). This indicates that a combined approach using clinical, phylogenetic, and toxinological tools should prove rewarding in the study of Tityus diversity in the Amazon Basin.

CONCLUSIONS

The results obtained in the present study based on mitochondrial DNA correlate with previous findings, demonstrating clinical and toxinological heterogeneity between Amazonian T. obscurus populations. Our findings reinforce the need for mapping the distribution area of T. obscurus haplotypes in Pará, which should help the design of region-specific therapeutic tools to treat scorpionism in the area.

ACKNOWLEDGMENTS

We thank Dr. Denise Maria Cândido from Laboratório de Artrópodes at Instituto Butantan, São Paulo, for species identification and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the financial support (proc. # 455885/2014-1).

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CITE AS:

Pardal, P.P.O.; Coelho, J.S.; Silva, J.M.; Almeida, B.R.R.; Chalkidis, H.M.; Borges, A. et al. 2023. Interpopulational genetic diversity in the medically important scorpion Tityus obscurus (Scorpiones: Buthidae) from northeastern Brazilian Amazonia. Acta Amazonica 53: 215-222.

DATA AVAILABILITY

The nucleotide sequences obtained in this study were deposited in GeneBank under accession numbers JX196960 - JX196969, and can be accessed at https://www.ncbi.nlm.nih.gov/nucleotide/.

Edited by

ASSOCIATE EDITOR:

Izeni P. Farias

Publication Dates

Publication in this collection
09 Oct 2023
Date of issue
Jul-Sep 2023

History

Received
18 Aug 2022
Accepted
06 Apr 2023

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

[1] Abdel-Rahman, M.A.; Omran, M.A.A.; Abdel-Nabi, I.M.; Ueda, H.; McVean, A. 2009. Intraspecific variation in the Egyptian scorpion Scorpio maurus palmatus venom collected from different biotopes. Toxicon, 53: 349-359.

[2] Abroug, F.; Ouanes-Besbes, L.; Tilouche, N.; Elatrous, S. 2020. Scorpion envenomation: state of the art. Intensive Care Medicine, 46: 401-410.

[3] Almeida, B.R.R.; Milhomem-Paixão, S.S.R.; Noronha, R.C.R.; Nagamachi, C.Y.; Costa, M.J.R.D.; Pardal, P.P.O.; Coelho, J.S.; Pieczarka, J.S. 2017. Karyotype diversity and chromosomal organization of repetitive DNA in Tityus obscurus (Scorpiones, Buthidae). BMC Genetics, 18: 35. doi.org/10.1186/s12863-017-0494-6
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	T.o. East ToE1	T.o. East ToE2	T.o. East ToE3	T.o. East ToE4	T.o. East ToE5	T.o. West ToW1	T.o. West ToW2	T.o. West ToW3	T.o. West ToW4	T.o. West ToW5	C.v.
T. obscurus East ToE1	-------	0.00	0.00	0.00	0.00	0.13	0.11	0.13	0.08	NA	0.21
T. obscurus East ToE2	0.00	--------	0.00	0.00	0.00	0.13	0.11	0.13	0.08	NA	0.21
T. obscurus East ToE3	0.01	0.01	--------	0.00	0.00	0.13	0.11	0.13	0.08	NA	0.21
T. obscurus East ToE4	0.00	0.01	0.01	--------	0.00	0.13	0.11	0.13	0.08	NA	0.21
T. obscurus East ToE5	0.01	0.01	0.00	0.01	--------	0.13	0.11	0.13	0.08	NA	0.21
T. obscurus West ToW1	0.11	0.11	0.11	0.11	0.11	--------	0.02	0.01	0.04	NA	0.27
T. obscurus West ToW2	0.11	0.11	0.11	0.11	0.11	0.00	--------	0.02	0.03	NA	0.26
T. obscurus West ToW3	0.11	0.11	0.11	0.11	0.11	0.00	0.00	--------	0.04	NA	0.27
T. obscurus West ToW4	0.10	0.10	0.10	0.10	0.10	0.01	0.01	0.01	--------	NA	0.26
T. obscurus West ToW5	0.11	0.11	0.11	0.11	0.11	0.00	0.00	0.00	0.01	--------	NA
C. vittatus	0.27	0.27	0.27	0.27	0.28	0.30	0.30	0.31	0.30	0.30	--------

Brasil