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ArticleBiota Neotrop. 23 (2) 2023https://doi.org/10.1590/1676-0611-BN-2022-1454   copy

March or Die: road-killed herpetofauna along BR-040 highway, an ancient road on the Atlantic Forest from Southeastern Brazil

Marche ou Morra: herpetofauna atropelada ao longo da rodovia BR-040, uma antiga estrada na Mata Atlântica do Sudeste do Brasil

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

The construction of highways is responsible for access to previously protected areas, resulting in changes in landscape and dynamics of the animal populations that live in these areas. These enterprises are the major responsible for the mortality of wild animals, surpassing hunting and even the trafficking of animals. The objective of this study was to make a list that reflects the diversity of amphibians and reptile’s road-killed along the BR-040, a highway that crosses the threaten lowland Atlantic Forest in Southeastern region of Brazil, including the use of microhabitats, lifestyle, activity pattern, reproductive cycles, and possible rare or endangered species. The study area consists of 180,4 km of highways. Monitoring began in 2006 and continues to the present day. A total of 1,410 individuals from 60 species were recorded in this study. The reptiles were more frequent in number of individuals and species. The commonest species recorded were Crotalus durissus and Dipsas mikanii. We have registered a single endangered species: Ranacephala hogei. The highest rates of road-kill were recorded during the wet season. Road-kills of fauna is a major threat to species, studies are of great importance to define plans that seek to mitigate the effects generated by these enterprises.

Keywords
Animal-vehicle collision; Roads; Road-kill mitigation; Road ecology; Reptiles; Amphibians

Resumo

A construção de rodovias é responsável pelo acesso a áreas anteriormente protegidas, resultando em alterações na paisagem e na dinâmica das populações animais que vivem nessas áreas. Esses empreendimentos são os maiores responsáveis pela mortalidade de animais silvestres, superando a caça e até mesmo o tráfico de animais. O objetivo deste estudo foi realizar uma lista que reflita a diversidade de anfíbios e répteis atropelados ao longo da BR-040, uma rodovia que atravessa a ameaçada Mata Atlântica na região Sudeste do Brasil, incluindo o uso de microhabitats, estilo de vida, padrão de atividade, ciclos reprodutivos, e possíveis espécies raras ou ameaçadas. A área de estudo é constituída por 180,4 km de rodovias. O monitoramento começou em 2006 e segue até os dias atuais. Ao todo 1.410 indivíduos de 60 espécies foram registrados nesse estudo. Os répteis foram mais frequentes, em número de indivíduos e espécies. As espécies mais comumente registradas foram Crotalus durissus e Dipsas mikanii. Registramos uma espécie ameaçada de extinção: Ranacephala hogei. A maior taxa de atropelamento foi registrada durante a estação chuvosa. O atropelamento de fauna é uma grande ameaça as espécies, sendo de grande importância estudos para definição de planos que busquem mitigar os efeitos gerados por esses empreendimentos.

Palavras-chave
Colisão animal-veículo; Rodovias; Mitigação de atropelamentos; Ecologia de estradas; Répteis; Anfíbios

Introduction

As a rule, roads make a major contribution to the high levels of biodiversity loss around the world (Coffin, 2007COFFIN, A.W. 2007. From roadkill to road ecology: a review of the ecological effects of roads. Journal of Transport Geography. v.15, p.396–406.; Jochimsen et al., 2014JOCHIMSEN, D.M., PETERSON, C.R. & HARMON, L.J. 2014. Influence of ecology and landscape on snake road mortality in a sagebrush-steppe ecosystem. Animal Conservation.; Van der Ree et al., 2015VAN DER REE, R., GRILO, C. & SMITH, D.J. 2015. Handbook of road ecology. Wiley, Chichester.), being road-kills one of the main causes of direct death of wild vertebrate species, overcoming the impacts generated by hunting and mortality rates from natural causes (Seiler & Helldin, 2006SEILER, A. & HELLDIN, J. 2006. Mortality in Wildlife due to transportation. In: Davenport, J; Davenport, J.L. (eds). The Ecology of transportation: managing mobility for the environments. Ireland: University College Cork p.165–190.; Valadão et al., 2018VALADÃO, R.M.; BASTOS, L.F. & CASTRO, C.P. 2018. Atropelamento de vertebrados silvestres em quatro rodovias no Cerrado, Mato Grosso, Brasil. Multi-science, 1(12):62–74. https://doi.org/10.33837/msj.v1i12.447
https://doi.org/10.33837/msj.v1i12.447... ; Hill et al., 2019HILL, J., DEVAULT, T.L. & BELANT, J.L. 2019. Cause-specific mortality of the world’s terrestrial vertebrates. Global Ecology and Biogeography, 28:680–689.). Every second 15 wild animals die on Brazilian roads, and these numbers can reach 1.3 million per day and exceed 475 million per year with extrapolated data (CBEEE, 2022CENTRO BRASILEIRO DE ESTUDOS EM ECOLOGIA DE ESTRADAS (CBEE). 2022. https://ecoestradas.com.br/ (last acces in 09/05/2022).
https://ecoestradas.com.br/... ). However, the actual number may be even higher, since several deaths are not recorded and road impacts go beyond collisions between wild animals and vehicles (Casella et al., 2006CASELLA, J., CÁCERES, N.C. & PARANHOS-FILHO, A.C. 2006. Uso de sensoriamento remoto e análise espacial na interpretação de atropelamentos de fauna entre Campo Grande e Aquiduana, MS. Anais 1º Simpósio de Geotecnologias no Pantanal, Embrapa.; Van der Ree et al., 2015VAN DER REE, R., GRILO, C. & SMITH, D.J. 2015. Handbook of road ecology. Wiley, Chichester.; Boyle et al., 2019BOYLE, S.P., DILLON, R., LITZUGUS, J.D. & LESBARRÈRES, D. 2019. Desiccation of Herpetofauna on roadway exclusion fencing. The Canadian Field-Naturalist, p.41–47.).

Due to the great urgency and growth of the road network around the world, road-kills and other direct and indirect road impacts have received attention in many studies (Bager & Rosa, 2010BAGER, A. & ROSA, C.A. 2010. Priority ranking of roads sites for mitigating wildlife roadkill. BiotaNeotropica, 10(4):149–153. https://doi.org/10.1590/S1676-06032010000400020
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https://doi.org/10.1590/S1676-0603201000... ; Vélez, 2014VÉLEZ, D.C.A. 2014. Adiciones al atropellamiento vehicular de mamíferos en la vía de El Escobero, Envigado (Antioquia), Colombia. Revista EIA, (22):147–153.; Shannon et al., 2016SHANNON, G., MCKENNA, M.F., ANGELONI, L.M., CROOKS, K.R., FRISTRUP, K.M., BROWN, E., WARNER, K.A., NELSON, M.D., WHITE, C., BRIGGS, J., MCFARLAND, S. & WITTEMYER, G. 2016. A synthesis of two decades of research documenting the effects of noise on wildlife. Biol. Rev., 91:982–1005.). To complicate matters, roads potentially reduce the size of natural populations, affecting their long-term persistence (Fahrig et al., 2003FAHRIG, L. 2003. Effects of Habitat fragmentation on Biodiversity. Annual Review of Ecology, Evolution and Systematics. 34:487–515. https://www.jstor.org/stable/30033784
https://www.jstor.org/stable/30033784... ; Bueno et al., 2013BUENO, C., FAUSTINO, M.T. & FREITAS, S.R. 2013. Influence of landscape characteristics on capybara road-kill on highway. Oecologia Aust 17:130–137.; Gonçalves et al., 2018GONÇALVES, L.O., ALVARES, D.J., TEIXEIRA, F.Z., SCHUCK, G., COELHO, I.P., ESPERANDIO, I.B., ANZA, J., BEDUSCHI, J., BASTAZINI, V.A.G. & KINDEL, A. 2018. Reptile road-kills in Southern Brazil: composition, hot moments and hot spots. Science of the total environment, 615:1438–1445.), by separating habitats by reducing their size, configuration and quality (McKinney, 2002MCKINNEY, M.L. 2002. Urbanization, biodiversity, and conservation. Bioscience 52, p.883–890.; Fahrig, 2003FAHRIG, L. 2003. Effects of Habitat fragmentation on Biodiversity. Annual Review of Ecology, Evolution and Systematics. 34:487–515. https://www.jstor.org/stable/30033784
https://www.jstor.org/stable/30033784... ; McKinney, 2006MCKINNEY, M.L. 2006. Urbanization as a major cause of biotic homogenization. Biological Conservation 127, p.247–260.; Maynard et al., 2016MAYNARD, R.J., AALL, N.C., SAENZ, D., HAMILTON, P.S. & KWIATKOWSKI, M.A. 2016. Road-edge effects on herpetofauna in lowland Amazonian rainforest. Tropical Conservation Science. v. 9, p.251–277.), acting as barriers to dispersion (Parris & Schneider, 2008PARRIS, K.M. & SCHNEIDER, A. 2008. Impacts of traffic noise and traffic volume on birds of Roadside habitats. Ecology and Society, 14(1):29. https://www.jstor.org/stable/26268029
https://www.jstor.org/stable/26268029... , Ware et al., 2015WARE, H.E., MCCLURE, C.J.W., CARLISLE, J.D. & BARBER, J.R. 2015. A phantom road experimente reveals traffic noise is na invisible source of habitat degradation. Proceedings of the National Academy of Sciences. 112(39):12105–12109. https://doi.org/10.1073/pnas.1504710112
https://doi.org/10.1073/pnas.1504710112... ), limiting gene flow (Ascensão et al., 2017ASCENSÃO, F., LUCAS, P.S., COSTA, A. & BAGER, A. 2017. The effect of roads on edge permeability and movement patterns for small mammals: a case study with Montane Akodont. Landescape Ecol. 32(4).). Additionally, roads affect individual survival, and provide humans with easy access to previously difficult-to-reach areas, thereby increasing the negative pressure on wildlife (Laurance et al., 2009LAURANCE, W.F., GOOSEM, M. & LAURANCE, S.G. 2009. Impacts of roads and linear clearings on tropical forests. Trends in ecology & evolution, 24(12):659–669.).

Nonetheless, wildlife road-kill’s do not occur randomly (Sosa & Schalk, 2016SOSA, R. & SCHALK, C.M. 2016. Seasonal activity and species habitat guilds influence road-kill patterns of neotropical snake. Tropical Conservation Science. 9:1–12.; Filius et al., 2020FILIUS, J., HOEK, Y.V.D., JARRÍN-V, P. & HOOFT, P.V. 2020. Wildlife roadkill patterns in a fragmented landscape of the Western Amazon. Ecology and Evolution, 10(13):6623–6635. https://doi.org/10.1002/ece3.6394
https://doi.org/10.1002/ece3.6394... ). Several factors favor certain species to be road-killed more than others, such as biological characteristics (body size and diet; Barthelmess & Brooks, 2010BARTHELMESS, E. & BROOKS, M.S. 2010. The influence of body-size and diet on roadkill trends in mammals. Biodiversity and Conservation, 19(6):1611–1629. DOI:10.1007/s10531-010-9791-3
https://doi.org/10.1007/s10531-010-9791-... ), the characteristics of the landscape and the road itself (Bueno et al., 2013BUENO, C., FAUSTINO, M.T. & FREITAS, S.R. 2013. Influence of landscape characteristics on capybara road-kill on highway. Oecologia Aust 17:130–137., 2015BUENO, C., SOUSA, C.O.M. & FREITAS, S.R. 2015. Habitat or matrix: which is more relevant to predict road-kill of vertebrates? Brazilian J Biol 75:228–238.), as well as seasonal variations in temperature and rainfall (Bueno & Almeida, 2010BUENO, C. & ALMEIDA, P.J.A.L. 2010. Sazonalidade de atropelamentos e os padrões de movimentos em mamíferos na BR-040 (Rio de Janeiro-Juiz de fora). Revista Brasileira de Zoociências, 12(3):219–226.; Santana, 2012SANTANA, G.S. 2012. Fatores influentes sobre atropelamentos de vertebrados na região central do Rio Grande do Sul, Brasil. Neotropical Biology and Conservation, 7(1):26–40.; Santos & Carvalho, 2012SANTOS, S.M., CARVALHO, F. & MIRA, A. 2012. How long do the dead survive on the road? Carcass persistence probability and implications for road-kill monitoring surveys. PLoS One, 6(9):e25383.). The vehicular traffic, as well as the vehicles’ speed are also important determining characteristics that lead to the collision of vehicles with animals (Cunha et al., 2010CUNHA, H.F., MOREIRA, F.G.A. & SILVA, S.S. 2010. Roadkill of wild vertebrates along the GO-060 road between Goiânia and Iporá, Goiás State, Brazil. Acta Scientiarum Biological Sciences, 32(3):257–263. https://doi.org/10.4025/actascibiolsci.v32i3.4752
https://doi.org/10.4025/actascibiolsci.v... ; Lester, 2015LESTER, D. 2015. Effective Wildlife Roadkill Mitigation. Journal of Traffic and Transportation Engineering, 3:42–51. https://doi.org/10.17265/2328-2142/2015.01.005
https://doi.org/10.17265/2328-2142/2015.... ). Various taxonomic groups are affected distinctly by vehicle collisions around the world, including mammals (Grilo et al., 2020GRILO, C., KOROLEVA, E., ANDRÁŠIK, R., BÍL, M. & GONZÁLEZ‐SUÁREZ, M. 2020. Roadkill risk and population vulnerability in European birds and mammals. Frontiers in Ecology and the Environment, 18(6): 323–328. https://doi.org/10.1002/fee.2216
https://doi.org/10.1002/fee.2216... ; Hill et al., 2021HILL, J.E., DEVAULT, T.L. & BELANT, J.L. 2021. A review of ecological factors promoting road use by mammals. Mammal Review, 51(2):214–227. https://doi.org/10.1111/mam.12222
https://doi.org/10.1111/mam.12222... ; Navas-Suárez et al., 2022NAVAS-SUÁREZ, P.E., DIAZ-DELGADO, J., CAIAFFA, M.G., DA SILVA, M.C., YOGUI, D.R., ALVES, M.H., CEREDA, J.F., DASILVA, M.P., CREMER, M.J., ASCENSÃO, F., LORIGADOS, C.A.B., MEDICI, E.P., DESBIEZ, A.L.J. & CATÃO-DIAS, J.L. 2022. Characterization of Traumatic Injuries Due to Motor Vehicle Collisions in Neotropical Wild Mammals, Journal of Comparative Pathology, 197:1–18. https://doi.org/10.1016/j.jcpa.2022.06.003
https://doi.org/10.1016/j.jcpa.2022.06.0... ), birds (Bujoczek et al., 2011BUJOCZEK, M., CIACH, M. & YOSEF, R., 2011. Road-kills affect avian population quality. Biological Conservation, 144(3), p.1036–1039.; Rosa & Bager, 2015ROSA, C.A. & BAGER, A. 2015. Seasonality and habitat types affect roadkills of neotropical birds. Journal of Environmental Management. 97:1–5. Grilo et al., 2020GRILO, C., KOROLEVA, E., ANDRÁŠIK, R., BÍL, M. & GONZÁLEZ‐SUÁREZ, M. 2020. Roadkill risk and population vulnerability in European birds and mammals. Frontiers in Ecology and the Environment, 18(6): 323–328. https://doi.org/10.1002/fee.2216
https://doi.org/10.1002/fee.2216... ; Medrano-Vizcaíno et al., 2022MEDRANO-VIZCAÍNO, P., BRITO-ZAPATA, D., RUEDA, A., GARCÍA-CARRASCO, J.M., MEDINA, D., AGUILAR, J., ACOSTA, N. & GONZALEZ-SUAREZ, M. 2022. First national assessment of wildlife mortality in Ecuador: an effort from citizens and academia to collect roadkill data at country scale. Authorea Preprints.), reptiles (Aresco, 2005ARESCO, M.J. 2005. The effect of sex-specific terrestrial movements and roads on the sex ratio of freshwater turtles. Biological Conservation 123:37–44.; Shepard et al., 2008aSHEPARD, D.B., KUHNS, A.R., DRESLIK, M.J. & PHILIPS, C.A. 2008. Roads as barriers to animal movement in fragmented landscapes. Animal conservation, 11:288–296.; Hallisey et al., 2022HALLISEY, N., BUCHANAN, S.W., GERBER, B.D., CORCORAN, L.S. & KARRAKER, N.E. 2022. Estimating Road Mortality Hotspots While Accounting for Imperfect Detection: A Case Study with Amphibians and Reptiles. Land, 11(5):739. https://doi.org/10.3390/land11050739
https://doi.org/10.3390/land11050739... ), amphibians (Fahrig et al., 2003FAHRIG, L. 2003. Effects of Habitat fragmentation on Biodiversity. Annual Review of Ecology, Evolution and Systematics. 34:487–515. https://www.jstor.org/stable/30033784
https://www.jstor.org/stable/30033784... ; Hels & Buchwald, 2001HELS, T. & BUCHWALD, E. 2001. The effect of road kills on amphibian populations. Biol. Conserv. 99, p.331–340.; Glista et al., 2008GLISTA, D.J., DEVAULT, T.L. & DEWOODY, J.A. 2008. Vertebrate road mortality predominantly impacts amphibians. Herpetological Conservation and Biology 3:77–87.; Hallisey et al., 2022HALLISEY, N., BUCHANAN, S.W., GERBER, B.D., CORCORAN, L.S. & KARRAKER, N.E. 2022. Estimating Road Mortality Hotspots While Accounting for Imperfect Detection: A Case Study with Amphibians and Reptiles. Land, 11(5):739. https://doi.org/10.3390/land11050739
https://doi.org/10.3390/land11050739... ) and invertebrates (Seibert & Conover, 1991SEIBERT, H. & J.H. CONOVER. 1991. Mortality of vertebrates and invertebrates on an Athens County, Ohio, Highway. Ohio Journal of Science 91:163–166.; McKenna et al., 2001MCKENNA, D.D., MCKENNA, K.M., MALCOM, S.B. & BEBENBAUM, M.R. 2001. Mortality of Lepidoptera along roadways in central Illinois. Journal-lepidopterists society, 55(2):63–68.). Ectotherms (amphibians and reptiles), despite being underrepresented in the literature on road ecology (Guns et al., 2011GUNS, K.E., MOUNTRAKIS, G. & QUACKENBUSH, L.J. 2011. Spatial wildlife vehicle collision models: a review of current work and its application to transportation mitigation projections. Journal Environment Manag. v.92, p.1074–1082.; Popp & Boyle, 2017POPP, J.N. & BOYLE, S.P. 2017. Railroad ecology: underrepresented in science? Basic and Applied Ecology. v. 19, p.84–93.), had a higher probability to be road-killed (D’Amico et al., 2015D’AMICO, M., ROMÁN, J., REYES, L. & REVILLA, E. 2015. Vertebrate road-kill patterns in Mediterranean habits: who, when and where. Biological Conservation 191, p.234–242.). This is probably because their metabolism causes slowness in amphibians (Hels & Buchwald, 2001HELS, T. & BUCHWALD, E. 2001. The effect of road kills on amphibian populations. Biol. Conserv. 99, p.331–340.; Puky, 2005PUKY, M., 2005. Amphibian road kills: a global perspective. In: Irwin, C.L., Garrett, P., McDermott, K.P. (Eds.), Proceedings of the 2005 International Conference on Ecology and Transportation (ICOET). Center for Transportation and the Environment, North Carolina State University (USA), p.325–338.), the behavioral freezing responses to threats (Andrews et al., 2005ANDREWS, K.M. & GIBBONS, J. W. 2005. How do highways influence snake movement? Behavioral responses to roads and vehicles. Copeia, 4, 772 –782.; Lima et al. 2015LIMA, S.L., BLACKWELL, B.F., DEVAULT, T.L. & FERNÁNDEZ‐JURICIC, E. 2015. Animal reactions to oncoming vehicles: a conceptual review. Biological Reviews, 90(1):60–76.) and, mainly, due to characteristic basking behavior for reptile’s thermoregulation (Ashley & Robinson, 1996ASHLEY, E.P. & ROBINSON, J.T. 1996. Road mortality of amphibians, reptiles and other wildlife on the Long Point Causeway, Lake Erie, Canadian. Can. Field Nat. 110, p.404–412.; Tanner & Perry, 2007TANNER, D. & PERRY, J. 2007. Road effects on abundance and fitness of Galápagos lava lizards (Microlophus albemarlensis). J. Environ. Manag. 85:270–278.; Jochimsen et al. 2014JOCHIMSEN, D.M., PETERSON, C.R. & HARMON, L.J. 2014. Influence of ecology and landscape on snake road mortality in a sagebrush-steppe ecosystem. Animal Conservation.; Andrews et al. 2015ANDREWS, K.M., LANGEN, T.A. & STRUIJK, R.P.J.H. 2015. Reptiles: overlooked but often at risk from roads. Road Ecology, p.271–280.; D’Amico et al. 2015D’AMICO, M., ROMÁN, J., REYES, L. & REVILLA, E. 2015. Vertebrate road-kill patterns in Mediterranean habits: who, when and where. Biological Conservation 191, p.234–242.; Schalk & Saenz, 2016SCHALK, C.M. & SAENZ, D. 2016. Environmental drivers of anuran calling phenology in a seasonal neotropical ecosystem. Austral ecology. v. 4, p.16–27.). In addition, there are other more intricate reasons, as such the cultural aversion to reptilian Bauplan in the Western civilization, mostly in the case of snakes and other limbless Squamata (Davey, 1994DAVEY, G.C.L. 1994. Self-reported fears to common indigenous animals in an adult UK population: the role of disgust sensitivity. Br J Psychol. 85(4):541–554.; Fernandes-Ferreira et al., 2011FERNANDES-FERREIRA, H., CRUZ, R., BORGES-NOJOSA, D.M. & ALVES, R.R.N. 2011. Crenças associadas a serpentes no Estado do Ceará, Nordeste do Brasil. Sitientibus. 11:153–163.; Ceríaco, 2012CERÍACO, L.M.P. 2012. Human attitudes towards herpetofauna: the influence of folklore and negative values on the conservation of amphibians and reptiles in Portugal. J Ethnobiol Ethnomed. 8:1–12.; Castilla et al., 2020CASTILLA, M.C., CAMPOS, C., COLANTONIO, S. & DÍAZ, M. 2020. Perceptions and atitudes of the local people towards bats in the surroundings of the Escaba dam (Tucumán, Argentina). Ethnobiol Conserv. 9:1–14. ; Silva et al., 2021SILVA, M.X.G., BRAGA-PEREIRA, F., SILVA, M.C., OLIVEIRA, J.V., LOPES, S.F. & ALVES, R.R.N. 2021. What are the factors influencing the aversion of students towards reptiles? Journal of Ethnobiology and Ethnomedicine. 17:35.). Amphibians and reptiles are vulnerable to road-kills when they travel on roads that cross their area of origin, or when they are attracted by the resources available in the area surrounding road edges, often because they are not seen by drivers (Laurance et al., 2009LAURANCE, W.F., GOOSEM, M. & LAURANCE, S.G. 2009. Impacts of roads and linear clearings on tropical forests. Trends in ecology & evolution, 24(12):659–669.; Bueno & Almeida, 2010BUENO, C. & ALMEIDA, P.J.A.L. 2010. Sazonalidade de atropelamentos e os padrões de movimentos em mamíferos na BR-040 (Rio de Janeiro-Juiz de fora). Revista Brasileira de Zoociências, 12(3):219–226.; Carvalho et al., 2015CARVALHO, C.F., CUSTÓDIO, A.E.I. & JÚNIOR, O.M. 2015. Wild vertebrates’ roadkill aggregations on the BR-050 Highway, State of Minas Gerais, Brazil. Bioscience Journal, 31(3):951–959.). Sometimes, however, when stigmatized animals are in sight of drivers on the road, some swerve the vehicle ever so slightly to run over them or simply do not try to swerve the vehicle to avoid hitting them (Ashley et al., 2007; Beckmann & Shine, 2012BECKMANN, C. & SHINE, R. 2012. Do drivers intentionally target wildlife on roads? Austral Ecology, 37(5):629–632.; Mesquita et al., 2014; Secco et al., 2014SECCO, H., RATTON, P., CASTRO, E., LUCAS, P. & BAGER, A. 2014. Intentional snake road-kill: a case study using fake snakes on a Brazilian road Introduction. Tropical Conservation Science, 7:561–571.; Assis et al., 2020ASSIS, J.R., CARVALHO-ROEL, C.F., IANNINI-CUSTÓDIO, A.E., PEREIRA, W.G & VELOSO, A.C. 2020. Snakes’ roadkill on highways in the Cerrado biome: an intentional conduct? Studies on Neotropical Fauna and Environment, v. online, p.1–8.).

There is global concern about the road-kill threats in animal conservation (Freitas, 2015FREITAS, S.R., OLIVEIRA, A.N., CIOCHETI, G., VIERA, M.V. & MATOS, D.M.S. 2015. How landscape features influence road-kill of three species of mammals in the brazilian savanna? Oecologia Australis, 18:35–45.; Adárraga-Caballero & Gutiérrez-Moreno, 2019ADÁRRAGA-CABALLERO, M.A. GUTIÉRREZ-MORENO, L.C. 2019. Mortalidad de vertebrados silvestres em la carretera trocal del Caribe, Magdalena, Colombia, Biota Colombiana, 20(1):106–119.; Jarvis et al., 2019JARVIS, L.E., HARTUP, M. & PETROVAN, S.O. 2019. Road mitigation using tunnels and fences promotes site connectivity and population expansion for a protected amphibian. European Journal of wildlife research, 65(27):1–11., Grilo et al., 2021GRILO, C., BORDA-DE-ÁGUA, L., BEJA, P., GOOLSBY, E., SOANES, K., ROUX, A.L., KOROLEVA, E., FERREIRA, F.Z., GAGNÉ, S.A., WANG, Y. & GONZÁLEZ-SUÁREZ, M. 2021. Conservation threats from roadkill in the global road network. Global Ecol. Biogeogr. 30, p.2200–2210.). Although road ecology is a recent topic of interest in temperate and tropical regions (Rosa & Bager, 2013ROSA, C.A. & BAGER, A. 2013. Review of factors underlying the mechanisms and effects of roads on vertebrates. Oecologia Australis. 1:6–19.; Pereira et al., 2017PEREIRA, A.N., CALABUIG, C. & WACHLEVSKI. 2017. Less impact or simply neglected? Anuran mortality on roads in the Brazilian semiarid zone. Journal of Arid Environments.), especially in the New World, the visibility of this theme has increased rapidly with the public becoming aware of its relevance to the protections of wild animal populations (Attademo et al., 2011ATTADEMO, A.M., PELTZER, P.M., LAJMANOVICH, R.C., ELBERG, G., JUNGES, C., SNACHEZ, L.C. & BASSO, A. 2011. Wildlife vertebrate mortality in roads from Santa Fé Province, Argentina. Revista Mexicana de Biodiversidade 82, p.915–925.). Nevertheless, there is still a paucity of accurate information on the spatial and temporal distribution of road-kill’s. Understanding the dynamics of wildlife-vehicle collisions allows us to find alternative solutions to increase safety on the roads, reduce the impacts on humans and wildlife, reduce costs, and invest in mitigation measures aimed at conservation of biodiversity (Forman, 1998FORMAN, R.T.T. 1998. Road Ecology: a solution for the giant embracing us. Landscape Ecology, 13(4):3–5.; Czech et al., 2000CZECH, B., KRAUSMAN, P.R. & DEVERS, P.K. 2000. Economic associations among causes of species endangerment in the United States. BioScience 50, p.593–601.; Rytwinski et al., 2016RYTWINSKI, T., SOANES, K., JAEGER, J.A., FAHRIG, L., FINDLAY, C.S., HOULAHAN, & VAN DER GRIFT, E.A. 2016. How effective is road mitigation at reducing road-kill? A meta-analysis. PLoS one, 11(11):e0166941.; Abra et al., 2019ABRA, F.D., GRANZIERA, B.M., HUIJSER, M.P., FERRAZ, K.M.P.M.D.B., HADDAD, C.M. & PAOLINO, R.M. 2019. Pay or prevent? Human safety, costs to society and legal perspectives on animal-vehicle collisions in São Paulo state, Brazil. Plos One, 14(4):e0215152. 10.1371/journal.pone.0215152.
https://doi.org/10.1371/journal.pone.021... ; Ascensão et al., 2021ASCENSÃO, F., YOGUI, D.R., ALVES, M.H., ALVES, A.C., ABRA, F. & DESBIEZ, A.L.J. 2021. Preventing wildlife roadkill can offset mitigation investments in short-medium term. Biological Conservation, 253. 10.1016/j.biocon.2020.108902
https://doi.org/10.1016/j.biocon.2020.10... ; Silva et al., 2021SILVA, M.X.G., BRAGA-PEREIRA, F., SILVA, M.C., OLIVEIRA, J.V., LOPES, S.F. & ALVES, R.R.N. 2021. What are the factors influencing the aversion of students towards reptiles? Journal of Ethnobiology and Ethnomedicine. 17:35.). The objective of this study was to make a list of the diversity of amphibians and reptiles’ road-killed along the BR-040, a highway that crosses the threaten Atlantic Forest in the Southeastern region of Brazil, including information on the use of microhabitats, lifestyle, activity pattern, reproductive cycles, and possibly rare or endangered species.

Material and Methods

1. Study area and source of data

The database used in the study come from the monitoring of the fauna road-killed along a 180 km stretch on the BR-040 (from km 125.2 in the municipality of Duque de Caxias, state of Rio de Janeiro to km 773.5 in the municipality of Juiz de Fora, state of Minas Gerais) (Figure 1). The project “Caminhos da Fauna” (free translation, Wildlife Pathways) started in 2006, is still in progress, and comprises the pioneering study in the monitoring of road-killed animals in the state of Rio de Janeiro. In the present study, we analyzed the records from April 2006 to June 2022, comprising both the specimens discarded after identification at the lowest taxonomic level possible and those preserved for scientific purposes and deposited in the Amphibians and Reptiles collections of the Museu Nacional, Universidade Federal do Rio de Janeiro (MNRJ). These specimens comprise an important source of data in the amphibians and reptiles collections. The list of deposited specimens is in the appendix and the institutional abbreviation followed is as detailed in Sabaj (2020)SABAJ, M.H. 2020. Codes for Natural History Collections in Ichthyology and Herpetology. Copeia 108, No. 2, 593–669. https://doi.org/10.1643/ASIHCODONS2020
https://doi.org/10.1643/ASIHCODONS2020... .

Figure 1.
Land cover map for the selected area of surroundings from the BR-040 highway stretches where road-kill were recorded, from km 125.2 in the municipality of Duque de Caxias (red star), state of Rio de Janeiro, to the Km 773.5 in the municipality of Juiz de Fora (red triangle), state of Minas Gerais.

The area of study crosses the Biodiversity Corridor of the Serra do Mar National Park, whose main native vegetation cover is composed of tropical rain forest (Veloso et al., 1991VELOSO, H.P., RANGEL-FILHO, A.L.R. & LIMA, J.C.A. 1991. Classificação da vegetação brasileira, adaptada a um sistema universal. Ibge.). The topography varies from the lowlands in the municipality of Duque de Caxias (22°90’46"S, 43°18'43"W; 19 m above sea level, hereafter asl), through the mountain range (about 1,000 m asl) near the municipality of Petrópolis (22°30'18"S, 43°10'44"W; 838 m asl), up to the municipality of Juiz de Fora (21°41'20"S, 43°20'40"W; 715 m asl) (Figure 2). Since 1996, the BR-040 stretch from Rio de Janeiro to Juiz de Fora has been under the authority of a private company, CONCER. The mean traffic volume on this road is 37,000 vehicles/day (CONCER, 2020CONCER, 2020. Accessed in 23/11/2022, avaible in: https://www.concer.com.br/
https://www.concer.com.br/... ). Within this entire range, the road has 2 paved lanes in each direction, and for the stretch crossing the mountain range, the 2-lanes going up and the 2-lanes going down run separately.

Figure 2.
Elevation map for the selected area of surroundings from the BR-040 highway stretches where road-kill were recorded, from km 125.2 in the municipality of Duque de Caxias (red star), state of Rio de Janeiro, to the Km 773.5 in the municipality of Juiz de Fora (red triangle), state of Minas Gerais.

2. Sampling design

The collection protocol is based on standard forms and techniques developed for the project Caminhos da Fauna, which includes taking pictures, removing carcasses, storing them in freezers, and recording their location, date and time of collection. The project has promoted the installation of three freezers located at the 104 km, 45 km and 816 km marks of BR-040 highway to provide a better preservation of the collected carcasses. Twice a month, the carcasses accumulated in the freezers were taken to the laboratory, at Veiga de Almeida University, in the municipality of Rio de Janeiro. After that, the specimens were donated to MNRJ, where they were defrosted, weighted and measured (in the case of slightly damaged animals) and sampled for genetic material (muscle tissue was taken from most of reptiles specimens and for selected amphibians specimens). Carcass collections are carried out in partnership with the CONCER concessionaire throughout the week for 24 hours. The monitoring speed is 50 km/h which allows a best visualization of the road-killed animals (small reptiles and amphibians) along the entire highway. The data were converted to road-kill rate (number of individuals/km/day). For each record, a field form is filled out with: mileage, direction, location on the road, sex, taxonomic group of the road-killed animal, local speed limit, weather for the day of collection, presence of water nearby, surrounding vegetation, in addition all occurrences were georeferenced and made available in decimal degrees decimals. Unidentified species at least at gender level were not considered for further analyses.

Carcass collections are included in the SISBIO License Number: 30727-9. The animal carcasses used in this study meet and are in accordance with operation license No. 1187/2013 and authorization for capture, collection and transport of biological material - Abio (1st Renewal and 3rd Rectifier) 514/2014.

3. Species identification

The collected carcasses were identified by experts at the lowest taxonomic level possible using the relevant taxonomic literature, as well as by means of direct comparison with the specimens from the MNRJ collections of Amphibians and Reptiles. After identification, they are fixed in formalin solution and preserved in ethanol 70ºGL and incorporated to the respective collection. The photographs aided in the taxonomic identification, but they were not considered alone for the species identification. Data regarding activity patterns, foraging, microhabitat selection and reproductive cycles were based on the available literature for each taxonomic group (e.g.,Haddad et al., 2013HADDAD, C.F.B., TOLEDO, L.F., PRADO, C.P.A., LOEBMANN, D., GASPARINI, J.L. & SAZIMA, I. 2013. Guia dos anfíbios da Mata Atlântica: Diversidade e Biologia. Anolis, São Paulo.; Marques et al., 2019MARQUES, O.A.V, ETEROVIC, A. & SAZIMA, I. 2019. Serpentes da Mata Atlântica: guia ilustrado para as regiões costeiras do Brasil. Ponto A, pp. 319.) and are summarized in Tables 12, indicating the specific source of each natural history information.

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Table 1.
Complete list of road-killed amphibians on highway BR-040. Abbreviations: N = Sample number; No = Nocturnal; Di = Diurnal; Arb = Arboreal; Cry = Cryptozoic; Ter = Terrestrial; Art = Arthropods; Mol = Mollusks; Anu = Anura; S = Small; M = Medium; L = Large; REP. MODE = Reproductive Mode; LC = Least Concern; DD = Data Deficient; REP. MODE: (1) Direct development of terrestrial eggs; (2) Eggs and exotrophic tadpoles in still or running water; (3) Eggs on wet rocks, rock crevices, exotrophic semi-terrestrial tadpoles; (4) Eggs and exotrophic tadpoles in still water or eggs and early larval stages in natural or constructed basin; (5) Eggs and exotrophic tadpoles in running water or eggs and early larval stages in natural or constructed basin; (6) Eggs and exotrophic tadpoles in still water; (7) Foam nest with eggs and early larval stages in underground constructed chamber; (8) Foam nest floating on still water; HABITS: (1) Forest floor; (2) Swamp or pond; (3) Rock wall; (4) River or stream backwaters.
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Table 2.
Complete list of road-killed reptiles on highway BR-040. Abbreviations: N = Sample number; No = Nocturnal; D = Diurnal; A = Arboreal; C = Cryptozoic; T = Terrestrial; Fo = Fossorial; Aq = Aquatic; Sa = Saxicola; M = Mammals; B = Birds; Ar = Arthropods; Mol = Mollusks; An = Anura; F = Fish; L = Lizard; E = Earthworm; Sn = Snake; G = Generalist; PMa = Plant material; Sm = Small; M = Medium; L = Large; REP. MODE = Reproductive Mode; S = Seasonal; C = Continuous; Bo = Both; V = Viviparous; O = Oviparous; D = Dry; R = Rainy LC = Least Concern; DD = Data Deficient; CR = Critically Endangered.

Results

We recorded 1,411 road-killed individuals, being 934 reptiles (66.19%) of 45 species and 478 amphibians (33.81%) of 15 species (Figures 310). However, due to the poor morphological condition of some specimens, it was not possible to identify them to the level of species. In these cases, specimens were identified up to the generic level (records for 41 reptiles and 46 amphibians) or remained without identification (17 amphibians and 12 reptiles) (Tables 12).

Figure 3.
Road-kill species registered in the monitored stretch. A – Boana faber, municipality of Bandeira, state of Minas Gerais, Brazil; B – Dendropsophus elegans, municipality of Bandeira, state of Minas Gerais, Brazil; and C – Haddadus binotatus, municipality of Bandeira, state of Minas Gerais, Brazil. Photos by Teles, A.
Figure 4.
Road-kill species registered in the monitored stretch. A – Bothrops jararaca, municipality of Bandeira, state of Minas Gerais, Brazil; B – Dipsas mikanii, Serra do Caraça, state of Minas Gerais; and C – Brazil Chironius bicarinatus, Serra do Caraça, state of Minas Gerais, Brazil. Photos by Soares, M.
Figure 5.
Road-kill species registered in the monitored stretch. A – Philodryas olfersii, Serra do Mendanha, state of Rio de Janeiro, Brazil; B – Xenodon neuwiedii, municipality of Rio de Janeiro, state of Rio de Janeiro, Brazil; and C – Elapomorphus quinquelineatus, municipality of Simão Pereira, state of Minas Gerais, Brazil. Photos by Soares, M (A – B) and Silva, F (C).
Figure 6.
Road-kill species registered in the monitored stretch. A – Erythrolamprus miliaris, Serra do Caraça, state of Minas Gerais, Brazil; B – Atractus zebrinus, Serra do Caraça, state of Minas Gerais, Brazil; and C – Pseudablades patagoniensis, state of Rio de Janeiro, Brazil. Photos by Silva, F (A) and Ferreira-Cunha, L (B – C).
Figure 7.
Road-kill species registered in the monitored stretch. A – Bokermannohyla circumdata, Serra do Caraça, state of Minas Gerais, Brazil; B – Boana semilineata, Simão Pereira, state of Minas Gerais, Brazil; and C – Ischnocnema guentheri, Parque Nacional da Serra dos Órgãos, state of Rio de Janeiro, Brazil. Photos by Soares, M (A) and Silva, F (B – C).
Figure 8.
Road-kill species registered in the monitored stretch. A – Rhinella ornata, Serra do Caraça, state of Minas Gerais, Brazil; B – Trachycephalus mesophaeus, Serra do Caraça, state of Minas Gerais, Brazil; and C – Thoropa miliaris, Rebio do Tinguá, state of Rio de Janeiro, Brazil. Photos by Silva, F (A) and Ferreira-Cunha, L (B – C).
Figure 9.
Road-kill species registered in the monitored stretch. A – Aspronema dorsivittata, Serra do Caraça, state of Minas Gerais, Brazil; B – Salvator merianae, municipality of Rio de Janeiro, state of Rio de Janeiro, Brazil; and C – Tropidurus torquatus, Serra do Caraça, state of Minas Gerais, Brazil. Photos by Andrade-Jr, A (A), Ferreira-Cunha, L (B) and Carvalho, B (C).
Figure 10.
Road-kill species registered in the monitored stretch. A – Phrynops geoffroanus, municipality of Paracatu, state of Minas Gerais, Brazil; and B – Mesoclemmys hogei, municipality of Faria Lemos, state of Minas Gerais, Brazil. Photos by Silva, F (A) and Carrara, R (B).

Considering only road-killed reptiles, Serpentes was the most recorded group, corresponding to 72.91% (N = 681) of the entire sampling, followed by lizards with 24.19% (N = 226), Amphisbaenia 0.96% (N = 9), Testudines 0.42% (N = 4), and Crocodylia 0.32% (N = 3); without identification 1.20% (N = 12).

The most representative of the snakes (N = 681) were the Rattlesnake, Crotalus durissus Linnaeus, 1758 corresponding to 19.23% (N = 130) followed by the Neuwied’s Tree Snake, Dipsas neuwiedi (Ihering, 1911) (11.45%; N = 78), and the Lancehead, Bothrops jararaca (Wied-Neuwied, 1824) (7.48%; N = 51). These three species together correspond to 38.16% of the sample for the snakes group.

The most commonly found lizards were the White Tegu, Salvator merianae Duméril & Bibron, 1839 (45.13%; N = 102) and the Amazon Lava Lizard, Tropidurus torquatus (Wied-Neuwied, 1820) (32.30%; N = 73). Together, these two species correspond to 77.43% of the sample for lizards.

The most frequently road-killed species of amphibians’ was the Butter Frog, Leptodactylus latrans (Steffen, 1815) (N = 168; 35.14%), followed by the Yellow Cururu Toad, Rhinella icterica (Spix, 1824) (N = 157; 32.84%), and Military River Frog, Thoropa miliaris (Spix, 1824) (N = 21; 4.39%). These three species together correspond to 72.37% of the amphibian sample.

During the more than 15 years of sampling (2006 to 2022), the year with the highest number of records was 2014, with 462 road-kills of wildlife (32.77%), followed by 2015 (N = 301; 21.35%) and 2016 (N = 195; 13.83%). In 2014, the highest rate of accidents occurred in the rainy season, in the months of October (N = 49; 10.60%), November (N = 48; 10.39%), December (N = 45; 9.74%), January (N = 76; 16.45%), February (N = 65; 14.07%) and March (N = 59; 12.77%). These six months together corresponded to 74.02% of the trampling of wildlife of the year sampled.

The road-kill rate for the stretch of highway studied was 0.04 road-kill’s per kilometer per month. It was possible to observe a higher number of road-kills in the stretches where the speed limit is higher. The three stretches with the highest incidence of road-kills have speed limits of 110 km/h (N = 698; 49.50), 70 km/h (N = 533; 37.80%), and 90 km/h (N = 145; 10.28%). The remaining road-kills (2.42%) occurred on stretches with speed limit between 30 and 60 km/h. The higher number of road-kills occurred on two-lane and one-lane stretches of the highway. Together, these stretches corresponded to 96.74% of all road-kills. The sections with three and four lanes had respectively 36 (2.55%) and 10 (0.71%) records of road-kills. The number of tracks showed that the stretches with 2 (N = 508; 36.03%) and 4 (N = 812; 57.59%) lanes were the most susceptible to trampling, together corresponding to 93.62% of the road-kill events.

Among the 60 species identified throughout the study, 52 species were classified as LC (Least Concern) for both red lists consulted. Five species were classified as LC for ICMBio (Instituto Chico Mendes de Conservação da Biodiversidade) and DD (Data Deficient) for IUCN (International Union for Conservation of Nature). Only one species was listed as CR (Critically Endangered, in both lists) and two species had no information (NE, Not Evaluated) for the IUCN list (LC in ICMBio list) (see Tables 1 and 2).

No difference in the impact of road-kills was observed between the patterns of activity reported for the group of reptiles: diurnal (N = 439; 47%), nocturnal (N = 403; 43.14%) and those active in both periods (N = 33; 3.53%). For snakes, we observed a higher number of road-kill on species that presented predominantly nocturnal activity (N = 403; 59.17%), species with diurnal activity recorded 28.92% (N = 197) while species active in both periods 4.84% (N = 33). For reptiles considered as a whole, the three lifestyles attributed to the most recorded animals were terrestrial (N = 495; 52.99%) followed by semi-arboreal (N = 276; 29.55%) and cryptozoic (N = 64; 6.85%), these three totaling 89.39% of the records. The other lifestyles: semi-aquatic (N = 25; 2.67%), saxicolous (N = 2; 0.21%), fossorial (N = 9; 0.96%), and arboreal (N = 4; 0.42%), together totaled 4.26% of the sample. For snakes we noticed the same pattern observed above, species with terrestrial (N = 293; 43.02%), semi-arboreal (N = 276; 40.52%) and cryptozoic (N = 40, 5.87%) lifestyles were the most affected by road-kill, totaling 89.41% of the records. Snakes that feed exclusively on mammals or that combine mammals and other taxonomic groups (i.e., generalist), were the most sampled (N = 282) corresponding to 41.40% of road-kill’s. Followed by snakes that feed exclusively on anurans or that combine anurans and other taxonomic groups (i.e., generalist; N = 155), corresponding to 22.76% of road-kill’s. Reptiles with seasonal reproduction (N = 777; 95.67%) were more road-killed than those with continuous reproduction throughout the year (N = 35; 4.33%). Animals with reproduction in the wet season had 545 records (67.45%), while in the dry season 228 records (28.22%). For reptiles, medium-sized individuals (500 < CRC < 1000 mm) were more commonly found on the highway (N = 403; 48.49%), followed by small animals (CRC < 500 mm) (N = 231; 27.79%) and finally large animals (CRC > 1000 mm) (N = 197; 23.70%). In a more directed view, for the snake’s group, we found the same pattern, the species most hit were the medium-sized ones (500 < CRC < 1000 mm) (N = 373; 60.85%), followed by the small ones (CRC < 500 mm) (N = 150; 24.47%) and large ones (CRC > 1000 mm) (N = 90; 14.68%).

For amphibians, the lifestyle attributed to the animals most hit was the terrestrial (N = 378; 92.42%), followed by arboreal (N = 26; 6.36%) and cryptozoic (N = 5; 1.22%) individuals. Regarding habitat, the two most frequently found groups were animals with habits strictly associated with swamp or pond (N = 216; 52.55%) or swamp or pond and river or stream backwaters (N = 169; 41.12%), together amounting to 93.7%. The other two habits, Forest floor (N = 5) and Rock wall (N = 21), together corresponded to 6.3% of the road-kills. Large individuals (CRC > 100 mm) were the most found (N = 193; 46.96%), followed by medium-sized (50 < CRC < 100 mm) (N = 186; 45.26%) and small-sized (CRC < 50 mm) (N = 32; 7.79%).

Discussion

Road ecology is a recent topic of interest in evolutionary biology, initiated in Brazil in the late 1980s (see Novelli et al., 1988NOVELLI, R., TAKASE, E. & CASTRO, V. 1988. Estudo das aves mortas por atropelamento em um trecho da Rodovia BR 471, entre os distritos da Quinta e Taim, Rio Grande do Sul. Revista Brasileira de Zoologia, 5(3):441–454.) with the objective of understanding the patterns and processes related to the interactions between the road network and the ecosystems, establishing effective mitigation measures for the negative effects of roads on wildlife (Huijser et al., 2009HUIJSER, M.P., DUFFIELD, J.W., CLEVENGER, A.P., AMENT, R.J. & MCGOWEN, P.T. 2009. Cost-benefit analyses of mitigation measures aimed at reducing collisions with large ungulates in the Unites States and Canada: a decision support tool. Ecology and Society, 14:15.; Rosa & Bager, 2013ROSA, C.A. & BAGER, A. 2013. Review of factors underlying the mechanisms and effects of roads on vertebrates. Oecologia Australis. 1:6–19.). However, these recent studies still show aggregations of trampling in Brazil and the World (Cáceres et al. 2012CÁCERES, N.C., CASELLA, J. & GOULART, C.S. 2012. Variação espacial e sazonal de atropelamentos de mamíferos no bioma cerrado, rodovia BR 262, sudoeste do Brasil. Mastozoología Neotropical, 19(1):21–33.; Teixeira et al., 2013TEIXEIRA, F.Z., COELHO, A.V.P., ESPERANDIO, I.B. & KINDEL, A. 2013. Vertebrate road mortality estimates: Effects of sampling methods and carcass removal. Biological Conservation, 157:317–323.; Carvalho-Roel et al., 2019CARVALHO-ROEL, C.F., IANNINI-CUSTÓDIO, A.E. & JÚNIOR, O.M. 2019. Do roadkill aggregations of wild and domestic mammals overlap? Rev. Biol. Trop. 67(1):47–60.; Miranda et al., 2020MIRANDA, J.E.S., MELO, F.R. & UMETSU, R.K. 2020. Are roadkill hotspot in the Cerrado equal among groups of vertebrates? Environmental Management. 65:565–573.; Spanowicz et al., 2020SPANOWICZ, A.G., TEIXEIRA, F.Z. & JAEGER, J.A.G. 2020. An adaptive plan for prioritizing road sections for fencing to reduce animal mortality. Conservation Biology n/a.; Ascensão et al., 2021ASCENSÃO, F., YOGUI, D.R., ALVES, M.H., ALVES, A.C., ABRA, F. & DESBIEZ, A.L.J. 2021. Preventing wildlife roadkill can offset mitigation investments in short-medium term. Biological Conservation, 253. 10.1016/j.biocon.2020.108902
https://doi.org/10.1016/j.biocon.2020.10... ). In the present study we observed an increase in the number of road-killed during the rainy season, which indicates a seasonal pattern of trampling, as observed in other studies (Bencke & Bencke, 1999BENCKE, G.A. & C. S.C. BENCKE. 1999. The potential importance of road deaths as cause of mortality for large forest owls in southern Brasil. Cotinga, Bedfordshire 11:79–80.; Seibert & Conover, 1991SEIBERT, H. & J.H. CONOVER. 1991. Mortality of vertebrates and invertebrates on an Athens County, Ohio, Highway. Ohio Journal of Science 91:163–166.; Machado et al., 2015MACHADO, F.S., FONTES, M.A., MOURA, A.S., MENDES, P.B. & ROMÃO, B.D.S. 2015. Roadkill on vertebrates in Brazil: seasonal variation and road type comparison. North-Western Journal of Zoology, 11(2):247–252.; Garriga et al., 2017GARRIGA, N., FRANCH, M., SANTOS, X., MONTORI, A. & LLORENTE, G.A. 2017. Seasonal variation in vertebrate traffic casualties and its implications for mitigation measures. Landscape and Urban Planning, 157. 36–44. DOI: 10.1016/j.landurbplan.2016.05.029
https://doi.org/10.1016/j.landurbplan.20... ). This period is usually associated with the reproductive season of many groups (e.g., amphibians and reptiles) (Toledo et al., 2003TOLEDO, L.F., ZINA, J. & HADDAD, C.F.B. 2003. Distribuição espacial e temporal de uma comunidade de anfíbios do Município de Rio Claro, São Paulo, Brazil. Holos Environmental, 3(2):136–149.; Jochimsen, 2005JOCHIMSEN, D.M. 2005. Factors influencing the road mortality of snakes on the upper snake river plain, Idaho. Wildlife impacts and conservations Solutions. Chapter 8:351–365.; Zina et al., 2007ZINA, J., ENNSER, J., PINHEIRO, S.C.P., HADDAD, C.F.B. & TOLEDO, L.F. 2007. Taxocenose de anuros de uma mata semidecídua do interior do Estado de São Paulo e comparações com outras taxocenoses do Estado, sudeste do Brasil. Biota Neotropica, 7:1–9.; Shepard et al., 2008aSHEPARD, D.B., KUHNS, A.R., DRESLIK, M.J. & PHILIPS, C.A. 2008. Roads as barriers to animal movement in fragmented landscapes. Animal conservation, 11:288–296.) and the increased availability of food at foraging sites. These factors stimulate the greater movement of animals, thus increasing the chance of trampling of the fauna (Forman & Alexander, 1998FORMAN, R.T.T. & ALEXANDER, E. 1998. Roads and their major ecological effects. Annual Review of Ecology and Systematic 29, p.207–231.; Smith & Dodd, 2003SMITH, L.L. & DODD, C.K. 2003. Wildlife mortality on U.S. highway 441 across Paynes Prairie, Alachua County, Florida. Florida Scientist 66:128–140.; Jochimsen, 2005JOCHIMSEN, D.M. 2005. Factors influencing the road mortality of snakes on the upper snake river plain, Idaho. Wildlife impacts and conservations Solutions. Chapter 8:351–365.; Pinowski, 2005PINOWSKI, J. 2005. Roadkills of vertebrates in Venezuela. Revista Brasileira de Zoología 22(1):191–196.).

For instance, some studies point to ectotherms (amphibians and reptiles) as the largest victims of road-kills in wet areas (Ashley & Robinson, 1996ASHLEY, E.P. & ROBINSON, J.T. 1996. Road mortality of amphibians, reptiles and other wildlife on the Long Point Causeway, Lake Erie, Canadian. Can. Field Nat. 110, p.404–412.; Glista et al., 2008GLISTA, D.J., DEVAULT, T.L. & DEWOODY, J.A. 2008. Vertebrate road mortality predominantly impacts amphibians. Herpetological Conservation and Biology 3:77–87.; Shepard et al., 2008bSHEPARD, D.B., DRESLIK, M.J., JELLENAND, B.C. & PHILLIPS, C.A. 2008. Reptile Road mortality around an oasis in the Illinois corn desert with emphasis on the endangered Eastern Massasauga. Copeia 2008:350–359.) because they are strongly influenced by environmental conditions in terms of humidity and temperature (Zug et al., 2001ZUG, G.R., L.J. VITT, & J.P. CALDWELL. 2001. Herpetology: An introductory biology of amphibians and reptiles. Academic Press, California, 630 pp.). This pattern can be observed here, for both groups, where the trampling peak occurred during the rainy season (hot moments), coinciding with the time of greatest activity for foraging and reproduction. Due to aspects intrinsic to each species (e.g., biological cycle, population density, speed of movement and use of surrounding areas close to highways) (Steen & Gibbs, 2004STEEN, D.A. & GIBBS, J.P. 2004. Effects of roads on the structure of freshwater turtle populations. Biological Conservation 18:1143–1148.; Aresco, 2005ARESCO, M.J. 2005. The effect of sex-specific terrestrial movements and roads on the sex ratio of freshwater turtles. Biological Conservation 123:37–44.) monitoring protocols should be established targeting the study area and taxonomic group of interest (Glista et al., 2008GLISTA, D.J., DEVAULT, T.L. & DEWOODY, J.A. 2008. Vertebrate road mortality predominantly impacts amphibians. Herpetological Conservation and Biology 3:77–87.; Attademo et al., 2011ATTADEMO, A.M., PELTZER, P.M., LAJMANOVICH, R.C., ELBERG, G., JUNGES, C., SNACHEZ, L.C. & BASSO, A. 2011. Wildlife vertebrate mortality in roads from Santa Fé Province, Argentina. Revista Mexicana de Biodiversidade 82, p.915–925.).

As a rule, road-kills are concentrated in a few species of the faunal elements in a given region, usually species presenting generalist habits (non-specialized diet and microhabitats), relatively abundant population density, with high mobility and that use the highways (primarily or secondarily) as a source of resources (e.g., food intake and/or thermoregulation opportunity) (Forman et al., 2003FORMAN, R.T.T., SPERLING, D., BISSONETTE, J.A., CLEVENGER, A.P., CUTSHALL, C.D., DALE, V.H., FAHRIG, L., FRANCE, R., GOLDMAN, C.R., HEANUE K, JONES, J.A., SWANSON, F.J., TURRENTINE, T. & WINTER, T.C. 2003. Road ecology: science and solutions. Island Press, Washington, DC, USA., Secco et al., 2014SECCO, H., RATTON, P., CASTRO, E., LUCAS, P. & BAGER, A. 2014. Intentional snake road-kill: a case study using fake snakes on a Brazilian road Introduction. Tropical Conservation Science, 7:561–571.). Not surprising, the group most affected by trampling in our study were reptiles, especially snakes. We raised four, not mutually exclusive, possibilities that could contribute to this high rate, as such: (i) use of the road to maximize thermoregulatory behavior at night and in cold days (Sullivan, 1981SULLIVAN, B.K. 1981. Observed differences in body temperature and associated behavior of four snake species. Journal of Herpetology, 15(2):245–246.; Mccardle & Fontenot, 2016MCCARDLE, L.D. & FONTENOT, C.L. 2016. The influence of thermal biology on road mortality risk in snakes. Journal of Thermal Biology, 56:39–49.; Gonçalves et al., 2018GONÇALVES, L.O., ALVARES, D.J., TEIXEIRA, F.Z., SCHUCK, G., COELHO, I.P., ESPERANDIO, I.B., ANZA, J., BEDUSCHI, J., BASTAZINI, V.A.G. & KINDEL, A. 2018. Reptile road-kills in Southern Brazil: composition, hot moments and hot spots. Science of the total environment, 615:1438–1445.); (ii) motionlessness as a defensive tactic used by some species (Andrews & Gibbons, 2005ANDREWS, K.M. & GIBBONS, J. W. 2005. How do highways influence snake movement? Behavioral responses to roads and vehicles. Copeia, 4, 772 –782.); (iii) intentional road-killing predominantly of snakes by cultural motivation (Secco et al., 2014SECCO, H., RATTON, P., CASTRO, E., LUCAS, P. & BAGER, A. 2014. Intentional snake road-kill: a case study using fake snakes on a Brazilian road Introduction. Tropical Conservation Science, 7:561–571.; Assis et al., 2020ASSIS, J.R., CARVALHO-ROEL, C.F., IANNINI-CUSTÓDIO, A.E., PEREIRA, W.G & VELOSO, A.C. 2020. Snakes’ roadkill on highways in the Cerrado biome: an intentional conduct? Studies on Neotropical Fauna and Environment, v. online, p.1–8.); and (iv) the scavenging behavior of some species that are attracted to carcasses on highways (Schwartz et al., 2018SCHWARTZ, A.L.W., WILLIAMS, H.F., CHADWICK, E., THOMAS, R.J. & PERKINS, S.E. 2018. Roadkill scavenging behaviour in an urban environment. Journal of Urban Ecology, 4:1–7.; Muszynska et al. 2022MUSZYNSKA, A., MATUSZEWSKA, M., SMUTYLO, M. & BORCZYK, B. 2022. One death follows another: scavenging and road mortality in the grass snake, Natrix natrix (Serpentes: Colubridae). Herpetology Notes, 15:295–296.).

The high number of road-killed Crotalus durissus species (N = 128) and Salvator merianae (N = 102) can be explained by the fact that they are species commonly found and adapted to open and anthropized areas, such as residential and commercial regions along roadsides. On the other hand, as in several other studies carried out in Brazil (Coelho et al., 2008COELHO, I.P., KINDEL, A. & COELHO, A.V.P. 2008. Roadkills of vertebrate species on two highways through the Atlantic Forest Biosphere Reserve, Southern Brazil. European Journal of Wildlife Research, 54:689–699.; Kunz & Ghizoni-Jr, 2009KUNZ, T.S. & GHIZONI-JR, I.R. 2009. Serpentes encontradas mortas em rodovias do estado de Santa Catarina, Brasil. Biotemas, 22(2):91–103.; Turci & Bernarde, 2009TURCI, L.C.B. & BERNARDE, P.S. 2009. Vertebrados atropelados na rodovia Estadual 383 em Rondônia, Brasil. Biotemas, 22(1):121–127.; Abra et al., 2019ABRA, F.D., GRANZIERA, B.M., HUIJSER, M.P., FERRAZ, K.M.P.M.D.B., HADDAD, C.M. & PAOLINO, R.M. 2019. Pay or prevent? Human safety, costs to society and legal perspectives on animal-vehicle collisions in São Paulo state, Brazil. Plos One, 14(4):e0215152. 10.1371/journal.pone.0215152.
https://doi.org/10.1371/journal.pone.021... ; Ascensão et al., 2021ASCENSÃO, F., YOGUI, D.R., ALVES, M.H., ALVES, A.C., ABRA, F. & DESBIEZ, A.L.J. 2021. Preventing wildlife roadkill can offset mitigation investments in short-medium term. Biological Conservation, 253. 10.1016/j.biocon.2020.108902
https://doi.org/10.1016/j.biocon.2020.10... ) larger animals were more represented in our records of road-kills and this effect can be explained by the monitoring speed (50 km/h) and the means of transport used for monitoring (car assistance), a general standard used in our collection methodology and in several other studies (Enge & Wood, 2002ENGE, K.M. & WOOD, K.N. 2002. A pedestrian road Survey of an upland snake community in Florida. Southeastern naturalist, 1(4):365–380.; Taylor & Goldingay, 2004TAYLOR, B.D. & GOLDINGAY, R.L. 2004. Wildlife road-kills on three major roads in north-eastern New South Wales. Wildlife Research, Collingwood, 31:83–91.; Coleman et al., 2008COLEMAN, J.L., FORD, N.B. & HERRIMAN, K. 2008. A road survey of Amphibians and Reptiles in a Bottomland Hardwood Forest. Southeastern naturalist, 7(2):339–348.; Delgado et al., 2019DELGADO, J.D., HUMIA, J.D., PEREIRAS, A.R., ROSAL, A., DEL VALLE PALENZUELA, M., MORELLI, F., NATALIA L., HERNÁNDEZ, A. & SÁNCHEZ, J.R. 2019. The spatial distribution of animal casualties within a road corridor: Implications for roadkill monitoring in the southern Iberian rangelands. Transportation Research Part D: Transport and Environment, 67:119–130. https://doi.org/10.1016/j.trd.2018.11.017
https://doi.org/10.1016/j.trd.2018.11.01... ). These choices likely result in lower detection of small animals as reported in other studies that used bicycles and/or lower speed during monitoring (Pracucci et al., 2012PRACUCCI, A., ROSA, C.A. & BAGER, A. 2012. Variação sazonal da fauna selvagem atropelada na rodovia MG234, sul de Minas Gerais-Brasil. Biotemas, 25(1):73–79.; Rosa et al., 2012ROSA, C.A., CARDOSO, T.R., TEIXEIRA, F.Z. & BAGER, A. 2012. Atropelamento de fauna selvagem: Amostragem e análise de dados em ecologia de estrada. In: A. Bager (Ed.), Ecologia de Estradas – Tendências e Pesquisas. pp. 79–98.; Pinheiro & Turci, 2013PINHEIRO, B.F. & TURCI, L.C.B. 2013. Vertebrados atropelados na estrada da Variante (BR-307), Cruzeiro do Sul, Acre, Brasil. Natureza Online, 11(2):68–78.; Santos et al., 2016SANTOS R.A.L., SANTOS S.M., SANTOS-REIS M., FIGUEREDO, A.P., BAGER, A., AGUIAR, L.M.S. & ASCENSÃO, F. 2016. Carcass persistence and detectability: reducing the uncertainty surrounding wildlife-vehicle collision surveys. PLoS ONE, 11(11).; Wang et al., 2022WANG, Y., YANG, Y., HAN, Y., SHI, G., ZHANG, L., WANG, Z., CAO, G., ZHOU, H., KONG, Y., PIAO, Z. & MERROW, J. 2022. Temporal patterns and factors influencing vertebrate roadkill in China. Transportation Research Interdisciplinary Perspectives, 15.), indicating that monitoring carried out with the help of cars can generate biased results for large animals.

Considering the presence of amphibians (mostly nocturnal animals) in the sample, it is believed that most of the road-kills occurred between 18:00 p.m. and 07:00 a.m. (Silva et al., 2007SILVA, M.O., OLIVEIRA, I.S., CARDOSO, M.W. & GRAF, V. 2007. Road Kills impact over the herpetofauna of Atlantic Forest (PR-340, Antonina, Paraná). Acta Biol. Par. 36(1-2):103–112.). This period is off-peak road traffic activity, which usually occurs in the beginning of the day and in the end of the afternoon, so that, even with this asynchronism with the peak moment on the highways, amphibians are greatly affected by trampling of wildlife, although they are still poorly sampled in studies on this topic (Glista et al., 2008GLISTA, D.J., DEVAULT, T.L. & DEWOODY, J.A. 2008. Vertebrate road mortality predominantly impacts amphibians. Herpetological Conservation and Biology 3:77–87.). Previous studies indicated that frogs of the genus Rhinella are among the amphibians most road-killed (Dornas et al., 2017DORNAS, R.A.P., KINDEL, A., BAGER, A. & FREITAS, S.R. 2017. Avaliação da mortalidade de vertebrados em rodovias no Brasil in: A. Bager (Ed.), Ecologia de estrada tendências e pesquisas. pp. 139–152.), result also observed in the present study: Rhinella spp. were the amphibian most road-killed with 203 register (42.47%). One possible explanation for the high rate of road-kills of individuals of this genus is that they are commonly found foraging around light poles (Coelho et al., 2012COELHO, I.P., TEIXEIRA, F.Z., COLOMBO, P., COELHO, A.V.P. & KINDEL, A. 2012. Anuran road-kills neighboring a peri-urban reserve in the Atlantic Forest, Brazil. Journal of Environmental Management, 112:17–26.; Bastos et al., 2019BASTOS, D.F.O., SOUZA, R.A.T., ZINA, J. & ROSA, C.A. 2019. Seasonal and spatial variation of road-killed vertebrates on BR-330, Southwest Bahia, Brazil. Oecologia Australis, 23(3):388–402.). In addition to that, Rhinella species are explosive breeders, that dislocate to breeding areas during the reproductive season (the rainy season) (e.g., Rhinella ornata, Dixo et al., 2009DIXO, M., METZGER, J.P., MORGANTE, J.S. & ZAMUDIO, K.R. 2009. Habitat fragmentation reduces genetic diversity and connectivity among toad populations in the Brazilian Atlantic Coastal Forest. Biological Conservation, 142(8):1560–1569.). Leptodactylus latrans is another very abundant species in records of road-kills, as it is a species frequently recorded in areas modified by humans (Bastos et al., 2019BASTOS, D.F.O., SOUZA, R.A.T., ZINA, J. & ROSA, C.A. 2019. Seasonal and spatial variation of road-killed vertebrates on BR-330, Southwest Bahia, Brazil. Oecologia Australis, 23(3):388–402.).

Another point to be discussed is that small vertebrates, such as frogs, are usually less visualized on highways than large animals, such as some representatives of the mammal group (Santos et al., 2016SANTOS R.A.L., SANTOS S.M., SANTOS-REIS M., FIGUEREDO, A.P., BAGER, A., AGUIAR, L.M.S. & ASCENSÃO, F. 2016. Carcass persistence and detectability: reducing the uncertainty surrounding wildlife-vehicle collision surveys. PLoS ONE, 11(11).; Filius et al., 2020FILIUS, J., HOEK, Y.V.D., JARRÍN-V, P. & HOOFT, P.V. 2020. Wildlife roadkill patterns in a fragmented landscape of the Western Amazon. Ecology and Evolution, 10(13):6623–6635. https://doi.org/10.1002/ece3.6394
https://doi.org/10.1002/ece3.6394... ), with this more than half of these small animals that road-killed easily go unnoticed in monitoring (Delgado et al., 2019DELGADO, J.D., HUMIA, J.D., PEREIRAS, A.R., ROSAL, A., DEL VALLE PALENZUELA, M., MORELLI, F., NATALIA L., HERNÁNDEZ, A. & SÁNCHEZ, J.R. 2019. The spatial distribution of animal casualties within a road corridor: Implications for roadkill monitoring in the southern Iberian rangelands. Transportation Research Part D: Transport and Environment, 67:119–130. https://doi.org/10.1016/j.trd.2018.11.017
https://doi.org/10.1016/j.trd.2018.11.01... ). Due to this fact, slower research methods employing bike or walking and with more than one agent are encouraged for better visualization of smaller animals as they can result in detectability up to 8.4 times greater than using a car (Medrano-Vizcaíno et al, 2022MEDRANO‐VIZCAÍNO, P., GRILO, C., SILVA PINTO, F.A., CARVALHO, W.D., MELINSKI, R.D., SCHULTZ, E.D. & GONZÁLEZ‐SUÁREZ, M. 2022. Roadkill patterns in Latin American birds and mammals. Global Ecology and Biogeography, Volume 31(9):1756:1783. https://doi.org/10.1111/geb.13557
https://doi.org/10.1111/geb.13557... ; Wang et al., 2022WANG, Y., YANG, Y., HAN, Y., SHI, G., ZHANG, L., WANG, Z., CAO, G., ZHOU, H., KONG, Y., PIAO, Z. & MERROW, J. 2022. Temporal patterns and factors influencing vertebrate roadkill in China. Transportation Research Interdisciplinary Perspectives, 15.). This may explain in parts the low number of road-kills recorded for the amphibian group in the present study when compared to the work performed by Filius et al. (2020)FILIUS, J., HOEK, Y.V.D., JARRÍN-V, P. & HOOFT, P.V. 2020. Wildlife roadkill patterns in a fragmented landscape of the Western Amazon. Ecology and Evolution, 10(13):6623–6635. https://doi.org/10.1002/ece3.6394
https://doi.org/10.1002/ece3.6394... , in which monitoring with bicycle and walking was carried out. Another two points that can help explain this low number of records for the amphibians are (i) smaller animals can more easily be thrown off the road and even get stuck in tires and (ii) the shorter persistence time of reptile and amphibian carcasses on highways, especially for smaller representatives (Santos et al., 2016SANTOS R.A.L., SANTOS S.M., SANTOS-REIS M., FIGUEREDO, A.P., BAGER, A., AGUIAR, L.M.S. & ASCENSÃO, F. 2016. Carcass persistence and detectability: reducing the uncertainty surrounding wildlife-vehicle collision surveys. PLoS ONE, 11(11).; Filius et al., 2020FILIUS, J., HOEK, Y.V.D., JARRÍN-V, P. & HOOFT, P.V. 2020. Wildlife roadkill patterns in a fragmented landscape of the Western Amazon. Ecology and Evolution, 10(13):6623–6635. https://doi.org/10.1002/ece3.6394
https://doi.org/10.1002/ece3.6394... ).

As proposed by Sosa & Schalk (2016)SOSA, R. & SCHALK, C.M. 2016. Seasonal activity and species habitat guilds influence road-kill patterns of neotropical snake. Tropical Conservation Science. 9:1–12., our results suggest that roads can act as a barrier to the dispersion of amphibians and reptiles, especially for fossorial and arboreal species (snakes) and small species (some amphibians and lizards), since the members of this guild are more unfeasible, either by the style of movement and the crossing time, or by the lack of connectivity between the forest areas on each side of the road. Despite the high number of species found in our study, we believe that this number may be underestimated. Due to two factors: (i) species that were not yet recorded in our dataset of road-killed animals, but are expected for the region (e.g., Dactyloa punctata; Hemidactylus mabouia; Gymnodactylus darwinii; Echinanthera cephalostriata), (ii) some species may have been thrown out of the track, or even, if they took refuge in the forest and later died outside the area of collection, in addition to the possibility that they served as a food source for carnivorous and scavenger animals (Rodrigues et al., 2002RODRIGUES, F.H.G., HASS, A., REZENDE, L.M., PEREIRA, C.S., FIGUEIREDO, C.F., LEITE, B.F. & FRANÇA, F.G.R. 2002. Impacto de rodovias sobre a fauna da Estação Ecológica de Água Emendadas, DF. In: III Congresso brasileiro de Unidades de Conservação, 1 p.585.; Bagatini, 2006BAGATINI, T. 2006. Evolução dos índices de atropelamento de vertebrados silvestres nas rodovias do entorno da Estação Ecológica Águas Emendadas, DF, Brasil, e eficácia de medidas mitigadoras. Dissertation Universidade de Brasília.; Silva et al., 2007SILVA, M.O., OLIVEIRA, I.S., CARDOSO, M.W. & GRAF, V. 2007. Road Kills impact over the herpetofauna of Atlantic Forest (PR-340, Antonina, Paraná). Acta Biol. Par. 36(1-2):103–112.; Pracucci et al., 2012PRACUCCI, A., ROSA, C.A. & BAGER, A. 2012. Variação sazonal da fauna selvagem atropelada na rodovia MG234, sul de Minas Gerais-Brasil. Biotemas, 25(1):73–79.; Ratton et al., 2014RATTON, P., SECCO, H. & ROSA, C.A. 2014. Carcass permanency time and its implications to the roadkill data. European Journal of Wildlife Research 5:1–4.; Machado et al., 2015MACHADO, F.S., FONTES, M.A., MOURA, A.S., MENDES, P.B. & ROMÃO, B.D.S. 2015. Roadkill on vertebrates in Brazil: seasonal variation and road type comparison. North-Western Journal of Zoology, 11(2):247–252.). In fact, the accumulation of carrion along the highways attracts animals, which consequently may be also road-killed (Muszynska et al. 2022MUSZYNSKA, A., MATUSZEWSKA, M., SMUTYLO, M. & BORCZYK, B. 2022. One death follows another: scavenging and road mortality in the grass snake, Natrix natrix (Serpentes: Colubridae). Herpetology Notes, 15:295–296.). The behavior of scavenging is quite reported for the group of mammals (Gonzáles-Suarez et al., 2018GONZÁLES-SUÁREZ, M., FERREIRA, F.Z. & GRILO, C. (2018) Spatial and species-level predictions of road mortality risk using trait data. Global Ecology and Biogeography 27:1093–1105.). Although the scavenging behavior is not commonly recorded among snakes, as theoretically they have the preference for live prey (Sazima & Strussmann, 1990SAZIMA, I. & STRÜSSMANN, C. 1990. Necrofagia em serpentes brasileiras: exemplos e previsões. Revista Brasileira de Biologia, 50(2):463–468.; Greene, 1997GREENE, H.W. (1997) Snakes: The Evolution of Mystery in Nature. Berkeley CA.), there are some records in the literature reinforcing such behavior in the group (see Sazima & Strussmann, 1990SAZIMA, I. & STRÜSSMANN, C. 1990. Necrofagia em serpentes brasileiras: exemplos e previsões. Revista Brasileira de Biologia, 50(2):463–468.; Lillywhite et al., 2002LILLYWHITE, H.B., SHEEHY, C.M. & MCCUE, M.D. 2002. Scavenging behaviors of Cottonmouth Snakes at Island Bird Rookeries. Herpetological Review, 33.; Gomes et al., 2017GOMES, D.F., GONZALEZ, R.C. & SILVA-SOARES, T. 2017. Erythrolamprus miliaris (Linnaeus, 1758) (Serpentes: Dipsadidae): report on an unusual event of necrophagy. Herpetology Notes, 10:417–419.; Marques et al., 2017MARQUES, O.A., COETI, R.Z., BRAGA, P.A. & SAZIMA, I. 2017: A rotten choice: feeding attempt by a coral snake (Micrurus frontalis) on a dead pitviper (Bothrops jararaca) that had swallowed a bulky rodent. Herpetology Notes 10:137–139.). In this way, some snakes can lead two stages in what we call “the cycle of road-kills”, constituting of two main steps: (i) as a source of food for scavengers animals (attracting other carnivorous animals like birds and mammals) and/or (ii) as carrion consumers of amphibians (e.g., Chironius spp.) or other vertebrates (e.g., Philodryas spp.) along the roads. Another very important point when we talk about road ecology is the rate of decomposition of carcasses along the roads and the difficulties generated by this factor. The estimate for the disappearance of carcasses in the snake group is that approximately 50% disappear within the first 8 to 24 hours (de Gregorio et al., 2011DEGREGORIO, B.A., HANCOCK, T.E., KURZ, D.J. & YUE, S. 2011. How quickly are road-killed snakes scavenged? Implications for underestimates of road mortality. Journal of the North Carolina Academy of Science 127(2):184–188.; Santos et al., 2016SANTOS R.A.L., SANTOS S.M., SANTOS-REIS M., FIGUEREDO, A.P., BAGER, A., AGUIAR, L.M.S. & ASCENSÃO, F. 2016. Carcass persistence and detectability: reducing the uncertainty surrounding wildlife-vehicle collision surveys. PLoS ONE, 11(11).; Cabrera-Casas et al., 2020CABRERA-CASAS L.X., ROBAYO-PALACIO L.M. & VARGAS-SALINAS F. 2020. Persistence of snake carcasses on roads and its potential effect on estimating roadkills in a megadiverse country. Amphibian & Reptile Conservation 14(1):163–173 (e230).), depending on traffic and time of year. We extrapolate that for most amphibians and other small reptiles (several lizards and small snakes), this rate should be even higher due to the smaller body size, directly affecting the number of recorded individuals. However, this is not the only problem caused by the decomposition of carcasses, another known issue is the difficulty for the identification of very damage specimens (Bastos et al., 2019BASTOS, D.F.O., SOUZA, R.A.T., ZINA, J. & ROSA, C.A. 2019. Seasonal and spatial variation of road-killed vertebrates on BR-330, Southwest Bahia, Brazil. Oecologia Australis, 23(3):388–402.). For this reason, 20 amphibians and 58 reptiles could not be identified to the specific level. In addition, some specimens have been identified only to the generic level, such as Tropidodryas sp. due to the fact that more than one species occurs sympatrically in the region in combination with lacking preservation of key characters for diagnosing between congeners.

About road-kill rates, most information available were also estimated for the entire vertebrate clade, not for specific taxonomic groups, or as the number or record per kilometer, which is affected by the duration of the study. In Brazil, vertebrate road-kill rates varied from 0.18 road-kills/km/month in Pantanal wetlands (Fischer, 1997FISCHER, W.A. 1997. Efeitos da BR-262 na mortalidade de vertebrados silvestres: síntese naturalística para a conservação da região do Pantanal, MS. Campo Grande:(Dissertação de Mestrado em Ecologia e Conservação). Universidade Federal de Mato Grosso do Sul. 44p.), 0.19 road-kills/km/month in stretches of Cerrado (Prada, 2004PRADA, C.S. 2004. Atropelamento de vertebrados silvestres em uma região fragmentada do nordeste do estado de São Paulo: quantificação do impacto e análise de fatores envolvidos. Masters Dissertation. Universidade Federal de São Carlos, São Paulo.), and 0.21 and 0.46 road-kills/km/month in two roads in the sandy and wet restinga (Coelho et al., 2008COELHO, I.P., KINDEL, A. & COELHO, A.V.P. 2008. Roadkills of vertebrate species on two highways through the Atlantic Forest Biosphere Reserve, Southern Brazil. European Journal of Wildlife Research, 54:689–699.), important remnants of Atlantic Forest in the south of Brazil. The rate found in the section analyzed by us (0.04 road-kill’s/km/month) can be considered high, since it is relative only to the herpetofauna and for a stretch of highway. Several concepts about the ecology of roads were not and still are not taken into account in the environmental licensing process (Machado et al., 2015MACHADO, F.S., FONTES, M.A., MOURA, A.S., MENDES, P.B. & ROMÃO, B.D.S. 2015. Roadkill on vertebrates in Brazil: seasonal variation and road type comparison. North-Western Journal of Zoology, 11(2):247–252.), causing the various ecological problems presented and discussed throughout the present study. Despite a myriad of mitigating measures to road-kills—such as the construction of ecological corridors, bridges, fences, and catwalks—are constantly encouraged to prevent animals from being road-killed when crossing the roads, some of these are criticized for their efficiency (e.g., isolated use of signs) and sometimes related to an increase in the rate of predation, hunting and trafficking of animals with economic interest (e.g., tunnels and underpasses) (Smith & Dodd, 2003SMITH, L.L. & DODD, C.K. 2003. Wildlife mortality on U.S. highway 441 across Paynes Prairie, Alachua County, Florida. Florida Scientist 66:128–140.).

Future Directions

The use of continuous fences and tunnel system for fauna (eco-passages or wildlife culverts) are currently the most recommended strategies for mitigate the impact of road-kills of amphibians and reptiles (Schmidt & Zumbach 2008SCHMIDT, B. & ZUMBACH, S. 2008. Amphibian Road mortality and how to prevent it: a review. In: Urban Herpetology, p. 157–167. MITCHELL, J.C., JUNG BROWN, R.E., BARTOLOMEW, B., Eds, Herpetological Conservation, St. Louis, Missouri.; Lesbarreres & Fahrig, 2012LESBARRERES, D. & FAHRIG, L. 2012. Measures to reduce population fragmentation by roads: what has worked and how do we know? Trends in Ecology and Evolution, 27(7).; Beebee, 2013BEEBEE T.J.C. 2013. Effects of Road Mortality and Mitigation Measures on Amphibian Populations. Conserv Biol.; Yue et al., 2019YUE, S., BONEBRAKE, T. & GIBSON, L. 2019. Informing Snake roadkill mitigation strategies in Taiwan using citizen science. The Journal of Wildlife Management. 83(1):80–88.) and can be used by other taxonomic groups, including invertebrates and small mammals.

Mitigation strategies focused on one taxonomic species or group need to be beneficial, or at least not bring negative effects, to other animals present in the study region (Jarvis et al., 2019JARVIS, L.E., HARTUP, M. & PETROVAN, S.O. 2019. Road mitigation using tunnels and fences promotes site connectivity and population expansion for a protected amphibian. European Journal of wildlife research, 65(27):1–11.). With this, to reduce the road-kills of amphibians and reptiles in the stretch analyzed by us we recommend, in addition to speed reducers, fauna-signaling plates and environmental education campaigns, the addition of continuous fences (no spaces for the animal to pass through it) and tunnels for fauna prioritizing the highest and well-preserved areas in order to mitigate damage to populations of more vulnerable and fragile species to automotive enterprises. We also recommend the preparation of further studies along the stretch aimed at detecting hotspots and the proposal of new strategies that help in conservation of local species.

Supplementary Material

The following online material is available for this article:

Appendix – List of specimens deposited in the Amphibians and Reptiles collections of the Museu Nacional, Universidade Federal do Rio de Janeiro (MNRJ).

Acknowledgments

We are grateful to CONCER for help with data collection. We are deeply indebted to Albedi Andrade-Jr., André Teles, Bárbara Carvalho, Fernanda Silva, Francielly Reis, Larissa Ferreira-Cunha, and Rodrigo Carrara for providing photographs of the species. This study was supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES; #2022-1001), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq; #307631/2021-4), and Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ; #E-26/202.737/2018).

Data Availability

The data used in our analysis is available at Zenodo Dataverse <https://doi.org/10.5281/zenodo.7459911>.

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Edited by

Associate Editor
Pedro Nunes

Publication Dates

  • Publication in this collection
    30 June 2023
  • Date of issue
    2023

History

  • Received
    19 Dec 2022
  • Accepted
    08 May 2023
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