DOCSLIB.ORG

Ecological and Phylogenetic Influences on Maxillary Dentition in Snakes

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ecological and Phylogenetic Influences on Maxillary Dentition in Snakes View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Cadernos Espinosanos (E-Journal) Phyllomedusa 9(2):121-131, 2010 © 2010 Departamento de Ciências Biológicas - ESALQ - USP ISSN 1519-1397 Ecological and phylogenetic influences on maxillary dentition in snakes Andrew Knox and Kate Jackson Department of Biology, Whitman College, Walla Walla, Washington 99362, USA. E‑mail: [email protected]. Abstract Ecological and phylogenetic influences on maxillary dentition in snakes. The maxillary dentition of snakes was used as a system with which to investigate the relative importance of the interacting forces of ecological selective pressures and phylogenetic constraints in determining morphology. The maxillary morphology of three groups of snakes having different diets, with each group comprising two distinct lineages—boids and colubroids— was examined. Our results suggest that dietary selective pressures may be more significant than phylogenetic history in shaping maxillary morphology. Keywords: Serpentes, dentition, diet, ecology, evolution, morphology. Resumo Influências ecológicas e filogenéticas sobre a dentição maxilar das serpentes. Usamos a dentição maxilar das serpentes como um sistema para investigar a importância relativa das pressões seletivas ecológicas e das restrições filogenéticas na determinação da morfologia. Examinamos a morfologia maxilar de três grupos de serpentes com diferentes dietas, com cada grupo compreendendo duas linhagens distintas—Boidae e Colubroidea. Nossos resultados sugerem que as pressões seletivas relacionadas à dieta podem ser mais significativas que a história filogenética na conformação da morfologia maxilar. Keywords: Serpentes, dentição, dieta, ecologia, evolução, morfologia. Introduction and that dentitional morphology would be correlated with the type of prey favored by Morphology is controlled by the interaction different species. Phylogeny constrains the of phylogeny and selective pressure (Losos and “starting point” from which the morphology of a Miles 1994). We hypothesized that in the case of structure deviates in response to various selective snake maxillary dentition, form follows function, pressures (i.e., natural selection). Therefore, we reasoned that the relative strength of selective pressures could be tested by examining the extent to which maxillary dentition in a species deviated Received 14 September 2010. Accepted 20 November 2010. from the plesiomorphic condition of the lineage. Distributed December 2010. Our goal was to test the impact of selective Phyllomedusa - 9(2), December 2010 121 Knox and Jackson pressures attributable to different types of prey have few, small teeth thought to facilitate by observing the variation in the maxillary regurgitation of the egg shell after its contents dentition in snakes. have been consumed (Savitzky 1983). In contrast, Alethinophidian snakes have teeth on four or snakes that prey on soft‑shelled eggs have broad, five bones—the palatine, pterygoid, dentary, bladelike teeth to slice open the eggs for digestion maxilla, and sometimes, a premaxilla. However, (Broadley 1979). Based on these studies many snakes have evolved specific dentitional documenting dentitional specializations in patterns that affect their function. Because snakes, a comprehensive study can be undertaken maxillary morphology is highly variable, it is an to describe taxonomic and ecological patterns. important taxonomic character; the dentition has Comparison of the morphological variation been used as a character trait for describing and of ophidian maxillae with the dietary habits of identifying snake taxa for more than a century snakes may lead to a better understanding of the (e.g., Boulenger 1896) and is still used today selective pressures acting on the morphology of (e.g., Chippaux 2006). Because ophidian maxillary the maxilla. An ecomorphological perspective morphology varies interspecifically, it is useful allows us to explore whether diverse prey for identifying and describing snakes, along with availability might have driven rapid evolution other features, such as scales, hemipenal from a generalized plesiomorphic condition in morphology, and mo lecular characters. We used the colubroid ancestor. If so, then we should a collection of snake maxillae originally assembled observe a strong correlation between different for taxonomic studies to investigate the rela‑ types of maxillary dentition in snakes and their tionship between dentitional morphology and preferred type of prey. diet in a diversity of snakes. To test the role of phylogenetic constraints in Several studies have demonstrated apparent shaping morphology, we examined representatives correlations between specific types of prey and of two lineages of snakes—the boids and the the maxillary morphology of species of snakes colubroids (excluding taxa with highly specialized (e.g., Savitzky 1981, Vaeth et al. 1985, Jackson maxillary dentition for the injection of venom). et al. 1999, Jackson and Fritts 2004). For example, We recognize that this combination is far from Savitzky (1981) addressed dentitional specializa‑ ideal because Boidae comprises about 43 species, tion for a specific prey type; he hypothesized whereas Colubroidea contains some 2300 species that the occurrence of hinged teeth in some snake (Jackson 2007). The colubroids in our study are genera is associated with durophagy, and is an a diverse assemblage belonging to the para‑ adaptation that prevents the teeth from breaking phyletic group traditionally referred to as when it comes in contact with hard‑bodied prey. “Colubridae.” However, the two lineages are Other studies (Savitzky 1983, Cundall and Irish reciprocally monophyletic and distantly related; 1989, Greene 1989, Jackson and Fritts 2004) nonetheless, many taxa from each lineage fill elaborated this hypothesis to include other similar ecological niches. Potentially, analysis of morphological modifications, such as the the differences between boids and colubrids that presence of a large diastema in the maxillary share the same niche may provide insight into dentition and an arched maxillary bone for the the operative selective pressures and the ways in purpose of encircling the hard‑bodied prey as the which these pressures interact with phylogenetic snake bites it. Substantially lengthened teeth constraints. It is important to note fundamental were reported in predators that prey on soft items differences in the dentitional patterns of colubrids such as slugs (Zweifel 1954), and piscivorous and boids—colubrids have a posterior fang, snakes typically have numerous, sharp, sometimes enlarged and/or grooved, which often posteriorly curved teeth (Savitzky 1983). Snakes conducts venom, whereas boids lack a posterior that are specialized for calcareous egg‑eating fang but usually have enlarged anterior teeth. Phyllomedusa - 9(2), December 2010 122 Ecological and phylogenetic influences on maxillary dentition in snakes These are phylogenetically determined morpho‑ thon), Pituophis catenifer deserticola (Bull logies that may be modified by selective Snake), Lamprophis lineatus (Striped House pressures. Thus, we are interested in determining Snake), Psammophylax rhombeatus (Rhombic whether the maxillae of boids more strongly Skaapsteker), and Calabaria reinhardtii (African resemble those of other boids or is their maxillary Burrowing Python). Systematic and ecological morphology more similar to that of colubroids information appears in Table 1 and maxillae are that fill similar dietary niches. illustrated in Figure 1. Despite the fact that these species eat mammals, Materials and Methods their respective ranges of prey are at times diverse and may include other types of prey or have We compiled dietary information from the “generalist” qualities. Python sebae preys on literature for 45 species of snakes. We chose antelope and other large mammals. Lamprophis snakes that specialized on particular prey to lineatus is a generalist that feeds primarily on investigate explicit selective pressure. A total of rodents. Liasis mackloti is a semi‑aquatic generalist 45 colubroid and boid snake maxillae was pho‑ that consumes small mammals and some reptiles. tographed; snakes from Africa and South America Calabaria reinhardtii is fossorial and feeds on were most numerous. Species were grouped rodents by suffocating them. Pituophis catenifer according to their dietary preferences before eats small mammals and bird eggs, and their maxillae were examined. We focused on Psammophylax rhombeatus consumes mostly three dietary groupings—viz., species pre ferring mammals, in addition to lizards and amphibians. (1) mammalian, (2) aquatic, or (3) arboreal prey. Only one of these taxa has enlarged posterior Maxillae were stored in a 75% ethanol dentition—Psammophylax rhombeatus, which solution. All African specimens had been has grooved posterior fangs. None of the maxillae sputter‑coated with a gold/palladium mixture for is curved or contains diastemata. Python sebae, scanning electron microscopy as part of another Pituophis. catenifer, Lamprophis lineatus, and study. Maxillae were secured to a contrasting Liasis mackloti share many dentitional color of construction paper with double‑sided characteristics, including moderate intertooth tape to photograph them. The camera was mounted spacing, the absence of striations, and anterior to a photocopy stand and the photographed with and posterior teeth that are angled posteriorly at an Olympus Evolt E‑510 Digital SLR camera
Load more

Recommended publications
  • Reproductive Behavior and Development in Spilotes Sulphureus (Serpentes: Colubridae) from Ecuador
    Phyllomedusa 17(1):113–126, 2018 © 2018 Universidade de São Paulo - ESALQ ISSN 1519-1397 (print) / ISSN 2316-9079 (online) doi: http://dx.doi.org/10.11606/issn.2316- 9079.v17i1p113-126 Reproductive behavior and development in Spilotes sulphureus (Serpentes: Colubridae) from Ecuador Jorge H. Valencia1 and Katty Garzon-Tello1,2 1 Fundación Herpetológica Gustavo Orcés, Av. Amazonas 3008 y Rumipamba, Casilla 1703448, Quito, Ecuador. E-mail: [email protected]. 2 Vivarium de Quito, Av. Amazonas 3008 y Rumipamba, Casilla 1703448, Quito, Ecuador. E-mail: [email protected]. Abstract Reproductive behavior and development in Spilotes sulphureus (Serpentes: Colu bridae) from Ecuador. The Birdsnake Spilotes sulphureus is a large-sized species that occurs from the Amazon region to the Atlantic forest of South America. Despite the wide distribution little is known about its natural history. Here we report, for the frst time, reproductive behavior displayed by this species observed in a pair of Ecuadorian specimens in captivity. A ritualized pre-copulatory behavior followed a colubrine pattern similar to the congeneric species Spilotes pullatus. The repertoire included chin-rubbing, continuous tongue ficking, head raising, body jerking, cloacal gaping, and partial mounting. Oviposition occurred 86–98 days after of the frst copulation. Females lay clutches of 7–14 eggs. Juvenile coloration is remarkably different from adults. Newborns have a dorsum with transverse brown or gray bands, and white or pale gray interspaces; young of 1–2 years have green bands and yellow-green interspaces; adults have dark green bands. Ontogenetic color changes are presumably associated with antipredator strategies, change in size, vulnerability or habitat and microhabitat selection.
    [Show full text]
  • Freshwater Fishes
    WESTERN CAPE PROVINCE state oF BIODIVERSITY 2007 TABLE OF CONTENTS Chapter 1 Introduction 2 Chapter 2 Methods 17 Chapter 3 Freshwater fishes 18 Chapter 4 Amphibians 36 Chapter 5 Reptiles 55 Chapter 6 Mammals 75 Chapter 7 Avifauna 89 Chapter 8 Flora & Vegetation 112 Chapter 9 Land and Protected Areas 139 Chapter 10 Status of River Health 159 Cover page photographs by Andrew Turner (CapeNature), Roger Bills (SAIAB) & Wicus Leeuwner. ISBN 978-0-620-39289-1 SCIENTIFIC SERVICES 2 Western Cape Province State of Biodiversity 2007 CHAPTER 1 INTRODUCTION Andrew Turner [email protected] 1 “We live at a historic moment, a time in which the world’s biological diversity is being rapidly destroyed. The present geological period has more species than any other, yet the current rate of extinction of species is greater now than at any time in the past. Ecosystems and communities are being degraded and destroyed, and species are being driven to extinction. The species that persist are losing genetic variation as the number of individuals in populations shrinks, unique populations and subspecies are destroyed, and remaining populations become increasingly isolated from one another. The cause of this loss of biological diversity at all levels is the range of human activity that alters and destroys natural habitats to suit human needs.” (Primack, 2002). CapeNature launched its State of Biodiversity Programme (SoBP) to assess and monitor the state of biodiversity in the Western Cape in 1999. This programme delivered its first report in 2002 and these reports are updated every five years. The current report (2007) reports on the changes to the state of vertebrate biodiversity and land under conservation usage.
    [Show full text]
  • De Los Reptiles Del Yasuní
    guía dinámica de los reptiles del yasuní omar torres coordinador editorial Lista de especies Número de especies: 113 Amphisbaenia Amphisbaenidae Amphisbaena bassleri, Culebras ciegas Squamata: Serpentes Boidae Boa constrictor, Boas matacaballo Corallus hortulanus, Boas de los jardines Epicrates cenchria, Boas arcoiris Eunectes murinus, Anacondas Colubridae: Dipsadinae Atractus major, Culebras tierreras cafés Atractus collaris, Culebras tierreras de collares Atractus elaps, Falsas corales tierreras Atractus occipitoalbus, Culebras tierreras grises Atractus snethlageae, Culebras tierreras Clelia clelia, Chontas Dipsas catesbyi, Culebras caracoleras de Catesby Dipsas indica, Culebras caracoleras neotropicales Drepanoides anomalus, Culebras hoz Erythrolamprus reginae, Culebras terrestres reales Erythrolamprus typhlus, Culebras terrestres ciegas Erythrolamprus guentheri, Falsas corales de nuca rosa Helicops angulatus, Culebras de agua anguladas Helicops pastazae, Culebras de agua de Pastaza Helicops leopardinus, Culebras de agua leopardo Helicops petersi, Culebras de agua de Peters Hydrops triangularis, Culebras de agua triángulo Hydrops martii, Culebras de agua amazónicas Imantodes lentiferus, Cordoncillos del Amazonas Imantodes cenchoa, Cordoncillos comunes Leptodeira annulata, Serpientes ojos de gato anilladas Oxyrhopus petolarius, Falsas corales amazónicas Oxyrhopus melanogenys, Falsas corales oscuras Oxyrhopus vanidicus, Falsas corales Philodryas argentea, Serpientes liana verdes de banda plateada Philodryas viridissima, Serpientes corredoras
    [Show full text]
  • Germination and Seedling Establishment of Spiny Hopsage (Grayia Spinosa [Hook.] Moq.)
    AN ABSTRACT OF THE THESIS OF Nancy L. Shaw for the degree of Doctor of Philosophy in Crop and Soil Sciences presented on March 19, 1992 Title: Germination and Seedling Establishment of Spiny Hopsage (Grayia Spinosa [Hook.] Moq.) Abstract approved:_Redactedfor Privacy von r. ULdUe Reestablishment of spiny hopsage(Grayia spinosa [Hook.] Moq.) where depleted or lost on shrub steppe sites can improve forage, plant cover, and soil stabilization. The objectives of this study were to: 1) determine direct-seeding requirements; 2) develop optimum germination pretreatments; and 3) examine dormancy mechanisms in spiny hopsage fruits and seeds. The effects of seed source, planting date,and site preparation method onseed germination and seedling establishment (SE) were examined at Birds of Prey and Reynolds Creek in southwestern Idaho. Three seed sources were planted on rough or compact seedbeds on 4 dates in 1986-87 and 3 dates in 1987-88. Exposure to cool-moist environments improved spring SE from early fall (EF) and late fall (LF) plantings. Few seedlings emerged from early (ESp) or late spring (LSp) plantings. SE was low at: 1 site in 1986-87 and atboth sites in 1987-88, probably due to lack of precipitation. For the successful 1986-87 planting, seedling density was greater on rough compared to compact seedbeds in April andMay, possiblydue to improved microclimate conditions. Growth rate varied among seed sources, but seedlings developed a deep taproot (mean length 266 mm) with few lateral roots the first season. Seeds were planted on 3 dates in 1986-87 and 1987-88, andnylon bags containing seeds were planted on 4 dates each year to study microenvironment effects on germination (G), germination rate (GR), and SE.
    [Show full text]
  • Eli Greenbaum, Ph.D
    ELI GREENBAUM, PH.D. Curriculum Vitae PRESENT ADDRESS University of Texas at El Paso Cell: (785) 393-3583 Dept. of Biological Sciences Office: (915) 747-5553 500 West University Ave. Lab: (915) 747-5645 El Paso, TX 79968* FAX: (915) 747-5808 *zip code 79902 for FEDEX deliveries E-mail: [email protected] WEBSITES Homepage: http://eligreenbaum.iss.utep.edu/default.htm Blog from 2014: http://greenbaum2014.at.utep.edu/category/fieldwork/2014-expedition/ Blog from 2013: http://greenbaum.at.utep.edu/index.php/2013-expedition ACADEMIC POSITIONS 2013–present. Associate Professor, Dept. of Biological Sciences, University of Texas at El Paso. 2008–2012. Assistant Professor, Dept. of Biological Sciences, University of Texas at El Paso. 2006–2008. Postdoctoral Research Fellow, Dept. of Biology, Villanova University, Villanova, PA. EDUCATION 2006. Ph.D. (Ecology and Evolutionary Biology). The University of Kansas, Lawrence. Oral exam: 4 November 2002. Dissertation title: Molecular systematics of New World microhyline frogs, with an emphasis on the Middle American genus Hypopachus. Dissertation defense: 25 January 2006 (defended with honors). Advisor: Dr. Linda Trueb. 1998. M.S. (Biology). University of Louisiana at Monroe, Monroe. Thesis title: Sexual differentiation in the spiny softshell turtle (Apalone spinifera). Advisor: Dr. John L. Carr. 1996. B.S. (Biological Sciences). Binghamton University, Binghamton, New York. 1992. High School Diploma. City Honors High School, Buffalo, New York. PENDING GRANTS 2014. Institute for Museum and Library Services, Museums for America Program, $150,000. Natural History Collection Stewardship for the 21st Century at the University of Texas at El Paso. PI. Resubmission. 2015. NSF Biodiversity: Discovery & Analysis Program.
    [Show full text]
  • Snakes: Cultural Beliefs and Practices Related to Snakebites in a Brazilian Rural Settlement Dídac S Fita1, Eraldo M Costa Neto2*, Alexandre Schiavetti3
    Fita et al. Journal of Ethnobiology and Ethnomedicine 2010, 6:13 http://www.ethnobiomed.com/content/6/1/13 JOURNAL OF ETHNOBIOLOGY AND ETHNOMEDICINE RESEARCH Open Access ’Offensive’ snakes: cultural beliefs and practices related to snakebites in a Brazilian rural settlement Dídac S Fita1, Eraldo M Costa Neto2*, Alexandre Schiavetti3 Abstract This paper records the meaning of the term ‘offense’ and the folk knowledge related to local beliefs and practices of folk medicine that prevent and treat snake bites, as well as the implications for the conservation of snakes in the county of Pedra Branca, Bahia State, Brazil. The data was recorded from September to November 2006 by means of open-ended interviews performed with 74 individuals of both genders, whose ages ranged from 4 to 89 years old. The results show that the local terms biting, stinging and pricking are synonymous and used as equivalent to offending. All these terms mean to attack. A total of 23 types of ‘snakes’ were recorded, based on their local names. Four of them are Viperidae, which were considered the most dangerous to humans, besides causing more aversion and fear in the population. In general, local people have strong negative behavior towards snakes, killing them whenever possible. Until the antivenom was present and available, the locals used only charms, prayers and homemade remedies to treat or protect themselves and others from snake bites. Nowadays, people do not pay attention to these things because, basically, the antivenom is now easily obtained at regional hospitals. It is under- stood that the ethnozoological knowledge, customs and popular practices of the Pedra Branca inhabitants result in a valuable cultural resource which should be considered in every discussion regarding public health, sanitation and practices of traditional medicine, as well as in faunistic studies and conservation strategies for local biological diversity.
    [Show full text]
  • A Molecular Phylogeny of the Lamprophiidae Fitzinger (Serpentes, Caenophidia)
    Zootaxa 1945: 51–66 (2008) ISSN 1175-5326 (print edition) www.mapress.com/zootaxa/ ZOOTAXA Copyright © 2008 · Magnolia Press ISSN 1175-5334 (online edition) Dissecting the major African snake radiation: a molecular phylogeny of the Lamprophiidae Fitzinger (Serpentes, Caenophidia) NICOLAS VIDAL1,10, WILLIAM R. BRANCH2, OLIVIER S.G. PAUWELS3,4, S. BLAIR HEDGES5, DONALD G. BROADLEY6, MICHAEL WINK7, CORINNE CRUAUD8, ULRICH JOGER9 & ZOLTÁN TAMÁS NAGY3 1UMR 7138, Systématique, Evolution, Adaptation, Département Systématique et Evolution, C. P. 26, Muséum National d’Histoire Naturelle, 43 Rue Cuvier, Paris 75005, France. E-mail: [email protected] 2Bayworld, P.O. Box 13147, Humewood 6013, South Africa. E-mail: [email protected] 3 Royal Belgian Institute of Natural Sciences, Rue Vautier 29, B-1000 Brussels, Belgium. E-mail: [email protected], [email protected] 4Smithsonian Institution, Center for Conservation Education and Sustainability, B.P. 48, Gamba, Gabon. 5Department of Biology, 208 Mueller Laboratory, Pennsylvania State University, University Park, PA 16802-5301 USA. E-mail: [email protected] 6Biodiversity Foundation for Africa, P.O. Box FM 730, Bulawayo, Zimbabwe. E-mail: [email protected] 7 Institute of Pharmacy and Molecular Biotechnology, University of Heidelberg, INF 364, D-69120 Heidelberg, Germany. E-mail: [email protected] 8Centre national de séquençage, Genoscope, 2 rue Gaston-Crémieux, CP5706, 91057 Evry cedex, France. E-mail: www.genoscope.fr 9Staatliches Naturhistorisches Museum, Pockelsstr. 10, 38106 Braunschweig, Germany. E-mail: [email protected] 10Corresponding author Abstract The Elapoidea includes the Elapidae and a large (~60 genera, 280 sp.) and mostly African (including Madagascar) radia- tion termed Lamprophiidae by Vidal et al.
    [Show full text]
  • The Herpetofauna of the Cubango, Cuito, and Lower Cuando River Catchments of South-Eastern Angola
    Official journal website: Amphibian & Reptile Conservation amphibian-reptile-conservation.org 10(2) [Special Section]: 6–36 (e126). The herpetofauna of the Cubango, Cuito, and lower Cuando river catchments of south-eastern Angola 1,2,*Werner Conradie, 2Roger Bills, and 1,3William R. Branch 1Port Elizabeth Museum (Bayworld), P.O. Box 13147, Humewood 6013, SOUTH AFRICA 2South African Institute for Aquatic Bio- diversity, P/Bag 1015, Grahamstown 6140, SOUTH AFRICA 3Research Associate, Department of Zoology, P O Box 77000, Nelson Mandela Metropolitan University, Port Elizabeth 6031, SOUTH AFRICA Abstract.—Angola’s herpetofauna has been neglected for many years, but recent surveys have revealed unknown diversity and a consequent increase in the number of species recorded for the country. Most historical Angola surveys focused on the north-eastern and south-western parts of the country, with the south-east, now comprising the Kuando-Kubango Province, neglected. To address this gap a series of rapid biodiversity surveys of the upper Cubango-Okavango basin were conducted from 2012‒2015. This report presents the results of these surveys, together with a herpetological checklist of current and historical records for the Angolan drainage of the Cubango, Cuito, and Cuando Rivers. In summary 111 species are known from the region, comprising 38 snakes, 32 lizards, five chelonians, a single crocodile and 34 amphibians. The Cubango is the most western catchment and has the greatest herpetofaunal diversity (54 species). This is a reflection of both its easier access, and thus greatest number of historical records, and also the greater habitat and topographical diversity associated with the rocky headwaters.
    [Show full text]
  • Nyika and Vwaza Reptiles & Amphibians Checklist
    LIST OF REPTILES AND AMPHIBIANS OF NYIKA NATIONAL PARK AND VWAZA MARSH WILDLIFE RESERVE This checklist of all reptile and amphibian species recorded from the Nyika National Park and immediate surrounds (both in Malawi and Zambia) and from the Vwaza Marsh Wildlife Reserve was compiled by Dr Donald Broadley of the Natural History Museum of Zimbabwe in Bulawayo, Zimbabwe, in November 2013. It is arranged in zoological order by scientific name; common names are given in brackets. The notes indicate where are the records are from. Endemic species (that is species only known from this area) are indicated by an E before the scientific name. Further details of names and the sources of the records are available on request from the Nyika Vwaza Trust Secretariat. REPTILES TORTOISES & TERRAPINS Family Pelomedusidae Pelusios rhodesianus (Variable Hinged Terrapin) Vwaza LIZARDS Family Agamidae Acanthocercus branchi (Branch's Tree Agama) Nyika Agama kirkii kirkii (Kirk's Rock Agama) Vwaza Agama armata (Eastern Spiny Agama) Nyika Family Chamaeleonidae Rhampholeon nchisiensis (Nchisi Pygmy Chameleon) Nyika Chamaeleo dilepis (Common Flap-necked Chameleon) Nyika(Nchenachena), Vwaza Trioceros goetzei nyikae (Nyika Whistling Chameleon) Nyika(Nchenachena) Trioceros incornutus (Ukinga Hornless Chameleon) Nyika Family Gekkonidae Lygodactylus angularis (Angle-throated Dwarf Gecko) Nyika Lygodactylus capensis (Cape Dwarf Gecko) Nyika(Nchenachena), Vwaza Hemidactylus mabouia (Tropical House Gecko) Nyika Family Scincidae Trachylepis varia (Variable Skink) Nyika,
    [Show full text]
  • A Single Specimen Reveals Multiple New Aspects of Diet and Distribution of Snakes
    Herpetology Notes, volume 14: 385-390 (2021) (published online on 15 February 2021) A Matryoshka of scales: a single specimen reveals multiple new aspects of diet and distribution of snakes Thaís B. Guedes1 Snakes comprise approximately 3,800 species et al., 2013). Much of what is known about the diet (Uetz and Hošek, 2020), all of which are carnivorous, of C. plumbea is based on the analysis of gut contents consuming an enormous variety of prey types captured of preserved specimens (Cunha and Nascimento, by active foraging or ambush methods (Greene, 1978; Gaiarsa et al., 2013), with two reports about 1997; Grundler 2020). Despite recent advances, prey ingestion position being head-first (Teixeira and detailed information on feeding ecology is still scarce, Vrcibradic, 2003; Drummond et al., 2010). particularly for many species of the rich snake fauna Here we report four interesting findings that came of the Neotropics (e.g., Marques and Sazima, 1997; from the examination of a single specimen of Clelia Hartmann and Marques, 2005; Gaiarsa et al., 2013; plumbea housed in a scientific collection: (1) two new Roberto and Souza, 2020). The frequency of prey items records of prey items for C. plumbea; (2) an unusual found in the stomachs of specimens collected or housed food item found in the stomach of the Yellow-bellied in scientific collections is low (e.g., Vitt and Vangilder, Puffing-snake (Spilotes sulphureus) eaten by the C. 1983; Marques and Sazima, 1997) and the observation plumbea; (3) the second record of C. plumbea in the of a predation event in the field is rare and unpredictable state of Maranhão; and (4) the second record of S.
    [Show full text]
  • Investigations Into the Presence of Nidoviruses in Pythons Silvia Blahak1, Maria Jenckel2,3, Dirk Höper2, Martin Beer2, Bernd Hoffmann2 and Kore Schlottau2*
    Blahak et al. Virology Journal (2020) 17:6 https://doi.org/10.1186/s12985-020-1279-5 RESEARCH Open Access Investigations into the presence of nidoviruses in pythons Silvia Blahak1, Maria Jenckel2,3, Dirk Höper2, Martin Beer2, Bernd Hoffmann2 and Kore Schlottau2* Abstract Background: Pneumonia and stomatitis represent severe and often fatal diseases in different captive snakes. Apart from bacterial infections, paramyxo-, adeno-, reo- and arenaviruses cause these diseases. In 2014, new viruses emerged as the cause of pneumonia in pythons. In a few publications, nidoviruses have been reported in association with pneumonia in ball pythons and a tiger python. The viruses were found using new sequencing methods from the organ tissue of dead animals. Methods: Severe pneumonia and stomatitis resulted in a high mortality rate in a captive breeding collection of green tree pythons. Unbiased deep sequencing lead to the detection of nidoviral sequences. A developed RT-qPCR was used to confirm the metagenome results and to determine the importance of this virus. A total of 1554 different boid snakes, including animals suffering from respiratory diseases as well as healthy controls, were screened for nidoviruses. Furthermore, in addition to two full-length sequences, partial sequences were generated from different snake species. Results: The assembled full-length snake nidovirus genomes share only an overall genome sequence identity of less than 66.9% to other published snake nidoviruses and new partial sequences vary between 99.89 and 79.4%. Highest viral loads were detected in lung samples. The snake nidovirus was not only present in diseased animals, but also in snakes showing no typical clinical signs.
    [Show full text]
  • Ancestral Reconstruction of Diet and Fang Condition in the Lamprophiidae: Implications for the Evolution of Venom Systems in Snakes
    Journal of Herpetology, Vol. 55, No. 1, 1–10, 2021 Copyright 2021 Society for the Study of Amphibians and Reptiles Ancestral Reconstruction of Diet and Fang Condition in the Lamprophiidae: Implications for the Evolution of Venom Systems in Snakes 1,2 1 1 HIRAL NAIK, MIMMIE M. KGADITSE, AND GRAHAM J. ALEXANDER 1School of Animal, Plant and Environmental Sciences, University of the Witwatersrand, Johannesburg. PO Wits, 2050, Gauteng, South Africa ABSTRACT.—The Colubroidea includes all venomous and some nonvenomous snakes, many of which have extraordinary dental morphology and functional capabilities. It has been proposed that the ancestral condition of the Colubroidea is venomous with tubular fangs. The venom system includes the production of venomous secretions by labial glands in the mouth and usually includes fangs for effective delivery of venom. Despite significant research on the evolution of the venom system in snakes, limited research exists on the driving forces for different fang and dental morphology at a broader phylogenetic scale. We assessed the patterns of fang and dental condition in the Lamprophiidae, a speciose family of advanced snakes within the Colubroidea, and we related fang and dental condition to diet. The Lamprophiidae is the only snake family that includes front-fanged, rear-fanged, and fangless species. We produced an ancestral reconstruction for the family and investigated the pattern of diet and fangs within the clade. We concluded that the ancestral lamprophiid was most likely rear-fanged and that the shift in dental morphology was associated with changes in diet. This pattern indicates that fang loss, and probably venom loss, has occurred multiple times within the Lamprophiidae.
    [Show full text]