fbpx
Wikipedia

Testudo (genus)

January 01, 1970

Testudo, the Mediterranean tortoises, are a genus of tortoises found in North Africa, Western Asia, and Europe. Several species are under threat in the wild, mainly from habitat destruction.

Testudo
Temporal range: Miocene–Present
Four tortoises of the genus Testudo.
Clockwise from left:
Testudo graeca ibera
Testudo hermanni boettgeri
Testudo hermanni hermanni
Testudo marginata sarda.
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Order: Testudines
Suborder: Cryptodira
Superfamily: Testudinoidea
Family: Testudinidae
Genus: Testudo
Linnaeus, 1758
Type species
Testudo graeca
Synonyms
  • Furculachelys Highfield, 1990[1]
  • Chersus Gmira, 1993
and see text.

Background edit

They are small tortoises, ranging in length from 7.0 to 35 cm and in weight from 0.7 to 7.0 kg.

Systematics edit

 
Distribution map of the tortoise species of the genus Testudo; overlaps and subspecies are shown

The systematics and taxonomy of Testudo is notoriously problematic. Highfield and Martin commented:

Synonymies on Testudo are notoriously difficult to compile with any degree of accuracy. The status of species referred has undergone a great many changes, each change introducing an additional level of complexity and making bibliographic research on the taxa extremely difficult. Most early and not a few later checklists contain a very high proportion of entirely spurious entries, and a considerable number of described species are now considered invalid – either because they are homonyms, non-binomial or for some other reason.[2]

Since then, DNA sequence data have increasingly been used in systematics, but in Testudines (turtles and tortoises), its usefulness is limited: In some of these, at least mtDNA is known to evolve more slowly in these than in most other animals.[3] Paleobiogeographical considerations suggest the rate of evolution of the mitochondrial 12S rRNA gene is 1.0-1.6% per million years for the last dozen million years or so in the present genus[4] and ntDNA evolution rate has been shown to vary strongly even between different population of T. hermanni;[5] this restricts sequence choice for molecular systematics and makes the use of molecular clocks questionable.

The following extant species in the following subgenera are placed here:

  • Genus Testudo
    • Subgenus Agrionemys
      • Russian tortoise or Horsfield's tortoise, T. horsfieldii[1]
        • Subspecies:
          • Central Asian tortoise, T. horsfieldii horsfieldii
          • Fergana Valley steppe tortoise, T. horsfieldii bogdanovi
          • Kazakhstan steppe tortoise, T. horsfieldii kazakhstanica
          • Turkmenistan steppe tortoise, T. horsfieldii kuznetzovi
          • Kopet-Dag steppe tortoise, T. horsfieldii rustamovi
    • Subgenus Chersine
      • Hermann's tortoise, T. hermanni[1]
        • Subspecies:
          • Eastern Hermann's tortoise, T. hermanni boettgeri[1]
          • Western Hermann's tortoise, T. hermanni hermanni[1]
    • Subgenus Testudo
      • Spur-thighed tortoise, Greek tortoise or common tortoise, T. graeca[1]
        • Subspecies:
          • Mediterranean spur-thighed tortoise, T. graeca graeca[1]
          • Araxes tortoise, T. graeca armeniaca[1]
          • Buxton's tortoise, T. graeca buxtoni[1]
          • Cyrenaican spur-thighed tortoise, T. graeca cyrenaica[1]
          • Asia Minor tortoise, T. graeca ibera[1]
          • Morocco tortoise, T. graeca marokkensis[1]
          • Nabeul tortoise, T. graeca nabeulensis[1]
          • Souss Valley tortoise, T. graeca soussensis[1]
          • Mesopotamian tortoise, T. graeca terrestris[1]
          • Iranian tortoise, T. graeca zarudnyi[1]
      • Egyptian tortoise or Kleinmann's tortoise, T. kleinmanni[1]
      • Marginated tortoise, T. marginata[1]


The first two are more distinct and ancient lineages than the closely related latter three species. Arguably, T. horsfieldii belongs in a new genus (Agrionemys) on the basis of the shape of its carapace and plastron,[6] and its distinctness is supported by DNA sequence analysis.[7] Likewise, a separate genus Eurotestudo has recently been proposed for T. hermanni; these three lineages were distinct by the Late Miocene as evidenced by the fossil record.[8] Whether these splits will eventually be accepted remains to be seen. The genus Chersus has been proposed to unite the Egyptian and marginated tortoises which have certain DNA sequence similarities,[4] but their ranges are (and apparently always were) separated by their closest relative T. graeca and the open sea and thus, chance convergent haplotype sorting would better explain the biogeographical discrepancy.

Conversely, the Greek tortoise is widespread and highly diverse. In this and other species, a high number of subspecies has been described, but not all generally accepted, and several (such as the "Negev tortoise" and the "dwarf marginated tortoise") are now considered to be local morphs. Some, such as the Tunisian tortoise, have even been separated as a separate genus Furculachelys, but this is not supported by more recent studies.[9]

Mating edit

Testudo spp. are promiscuous creatures and they follow a polyandrous mating system.[10] Mating involves a courtship ritual of mechanical, olfactory and auditory displays elicited from the male to coerce a female into accepting copulation.[11] Courtship displays are very energetically costly for males, especially because females tend to run away from courting males.[12] The male will chase her, exerting more energy and elaborate displays of ramming and biting. Females are able to judge a male's genetic quality through these displays; only healthy males are able to perform costly courting rituals, suggesting endurance rivalry.[11] These are considered honest signals that are then used to influence pre- and post-copulatory choice, as females are the choosy sex.[10]

Female mate choice offers no direct benefits (such as access to food or territory or parental care).[13] There are, however, indirect benefits of mating with multiple males. Engaging in a polyandrous mating system offers a female guaranteed fertilization, higher offspring diversity and sperm competition to ensure that eggs are fertilized by a high quality male. This is in respect to the "good genes" hypothesis that females receive indirect benefits through her offspring by mating with a quality male, "a male's contribution to a female's fitness is restricted to [his] genes" (Cutuli, G. et al., 2014).

Mating order has no influence on paternity of a clutch so a female's inclination to mate with multiple males and her ability to store sperm allows for sperm competition and suggests cryptic female choice.[14] However, some species do show size-assortative, T. marginata, for example, where large males breed with large females and small males breed with small females.[11] Other species form hierarchies; during male-to-male competition the more aggressive male is considered alpha.[10] Alpha males are more aggressive with their courting as well and have higher mounting success rate than beta males.

A female's reproductive tract contains sperm storage tubules and she is capable of storing sperm for up to four years.[15] This sperm remains viable and when she goes a breeding season without encountering a male she is able to fertilize her eggs with the stored sperm. Storing sperm can also result in multiple paternity clutches; It is quite common among Testudo spp. females to lay a clutch that has been sired by multiple males. And females can lay one to four clutches a breeding season. Sexual dimorphism, promiscuity, long term sperm storage and elaborate courting rituals are factors that effect mate preference, sperm competition and cryptic female choice in genus Testudo.[10]

References edit

  1. ^ a b c d e f g h i j k l m n o p q r Rhodin, Anders G.J.; Inverson, John B.; Roger, Bour; Fritz, Uwe; Georges, Arthur; Shaffer, H. Bradley; van Dijk, Peter Paul (August 3, 2017). "Turtles of the world, 2017 update: Annotated checklist and atlas of taxonomy, synonymy, distribution, and conservation status(8th Ed.)" (PDF). Chelonian Research Monographs. 7. ISBN 978-1-5323-5026-9. Retrieved October 4, 2019.
  2. ^ Highfield, A. C. & Martin, J. (1989). "A revision of the Testudines of North Africa, Asia, and Europe. Genus: Testudo". Journal of Chelonian Herpetology. 1 (1): 1–12.
  3. ^ Avise, J. C.; Bowen, B. W.; Lamb, T.; Meylan, A. B.; Bermingham, E. (1992). "Mitochondrial DNA evolution at a turtle's pace: Evidence for low genetic variability and reduced microevolutionary rate in the Testudines". Molecular Biology and Evolution. 9 (3): 457–473. doi:10.1093/oxfordjournals.molbev.a040735. PMID 1584014.
  4. ^ a b Van Der Kuyl, Antoinette C.; Ph. Ballasina, Donato L.; Dekker, John T.; Maas, Jolanda; Willemsen, Ronald E.; Goudsmit, Jaap (2002). "Phylogenetic Relationships among the Species of the Genus Testudo (Testudines: Testudinidae) Inferred from Mitochondrial 12S rRNA Gene Sequences". Molecular Phylogenetics and Evolution. 22 (2): 174–183. doi:10.1006/mpev.2001.1052. PMID 11820839.
  5. ^ Fritz, Uwe; Auer, Markus; Bertolero, Albert; Cheylan, Marc; Fattizzo, Tiziano; Hundsdorfer, Anna K.; Martin Sampayo, Marcos; Pretus, Joan L.; Široky, Pavel; Wink, Michael (2006). "A rangewide phylogeography of Hermann's tortoise, Testudo hermanni (Reptilia: Testudines: Testudinidae): Implications for taxonomy". Zoologica Scripta. 35 (5): 531–543. doi:10.1111/j.1463-6409.2006.00242.x. S2CID 86110728.
  6. ^ Khozatsky, L.I. & Mlynarski, M. (1966): Agrionemys - nouveau genre de tortues terrestres (Testudinidae) ["Agrionemys - a new genus of tortoises"]. [Article in French[verification needed]] Bulletin de l'Académie Polonaise des Sciences II - Série des Sciences Biologiques 2: 123-125.
  7. ^ Fritz, Uwe; Široký, Pavel; Kami, Hajigholi; Wink, Michael (2005). "Environmentally caused dwarfism or a valid species—Is Testudo weissingeri Bour, 1996 a distinct evolutionary lineage? New evidence from mitochondrial and nuclear genomic markers". Molecular Phylogenetics and Evolution. 37 (2): 389–401. doi:10.1016/j.ympev.2005.03.007. PMID 16223676.
  8. ^ De Lapparent De Broin, France; Bour, Roger; Parham, James F.; Perälä, Jarmo (2006). "Eurotestudo, a new genus for the species Testudo hermanni Gmelin, 1789 (Chelonii, Testudinidae)". Comptes Rendus Palevol. 5 (6): 803–811. Bibcode:2006CRPal...5..803D. doi:10.1016/j.crpv.2006.03.002.
  9. ^ Van Der Kuyl, Antoinette C.; Ballasina, Donato LP; Zorgdrager, Fokla (2005). "Mitochondrial haplotype diversity in the tortoise species Testudo graeca from North Africa and the Middle East". BMC Evolutionary Biology. 5: 29. doi:10.1186/1471-2148-5-29. PMC 1097724. PMID 15836787.
  10. ^ a b c d Cutuli, Giulia; Cannicci, Stefano; Vannini, Marco; Fratini, Sara (2014). "Influence of male courtship intensity and male-male competition on paternity distribution in Hermann's tortoise, Testudo hermanni hermanni (Chelonia: Testudinidae)". Biological Journal of the Linnean Society. 111 (3): 656–667. doi:10.1111/bij.12243. hdl:2158/844715.
  11. ^ a b c Sacchi, Roberto; Galeotti, Paolo; Fasola, Mauro; Ballasina, Donato (2003). "Vocalizations and courtship intensity correlate with mounting success in marginated tortoises Testudo marginata". Behavioral Ecology and Sociobiology. 55: 95–102. doi:10.1007/s00265-003-0685-1. S2CID 9968063.
  12. ^ Galeotti, Paolo; Sacchi, Roberto; Rosa, Daniele Pellitteri; Fasola, Mauro (2005). "Female preference for fast-rate, high-pitched calls in Hermann's tortoises Testudo hermanni". Behavioral Ecology. 16: 301–308. doi:10.1093/beheco/arh165.
  13. ^ Cutuli, Giulia; Cannicci, Stefano; Vannini, Marco; Fratini, Sara (2013). "Influence of mating order on courtship displays and stored sperm utilization in Hermann's tortoises (Testudo hermanni hermanni)". Behavioral Ecology and Sociobiology. 67 (2): 273–281. doi:10.1007/s00265-012-1447-8. hdl:2158/774769. S2CID 15308304.
  14. ^ Johnston, Emily E.; Rand, Matthew S.; Zweifel, Stephan G. (2006). "Detection of multiple paternity and sperm storage in a captive colony of the central Asian tortoise, Testudo horsfieldii". Canadian Journal of Zoology. 84 (4): 520–526. doi:10.1139/Z06-023.
  15. ^ Roques, S.; Díaz-Paniagua, C.; Andreu, A. C. (2004). "Microsatellite markers reveal multiple paternity and sperm storage in the Mediterranean spur-thighed tortoise, Testudo graeca". Canadian Journal of Zoology. 82: 153–159. doi:10.1139/Z03-228.

External links edit

  • Tortoise Trust Web - Basic care of Mediterranean tortoises.
  • James F. Parham; J. Robert Macey; Theodore J. Papenfuss; Chris R. Feldman; Oguz Türkozan; Rosa Polymeni; JeVrey Boore (2005). "The phylogeny of Mediterranean tortoises and their close relatives based on complete mitochondrial genome sequences from museum specimens" (PDF). {{cite journal}}: Cite journal requires |journal= (help)

January 01, 1970
testudo, genus, testudo, mediterranean, tortoises, genus, tortoises, found, north, africa, western, asia, europe, several, species, under, threat, wild, mainly, from, habitat, destruction, testudotemporal, range, miocene, present, preꞒ, four, tortoises, genus,. Testudo the Mediterranean tortoises are a genus of tortoises found in North Africa Western Asia and Europe Several species are under threat in the wild mainly from habitat destruction TestudoTemporal range Miocene Present PreꞒ Ꞓ O S D C P T J K Pg N Four tortoises of the genus Testudo Clockwise from left Testudo graeca iberaTestudo hermanni boettgeriTestudo hermanni hermanniTestudo marginata sarda Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Class Reptilia Order Testudines Suborder Cryptodira Superfamily Testudinoidea Family Testudinidae Genus TestudoLinnaeus 1758 Type species Testudo graecaLinnaeus 1758 Synonyms Furculachelys Highfield 1990 1 Chersus Gmira 1993 and see text Contents 1 Background 2 Systematics 3 Mating 4 References 5 External linksBackground editThey are small tortoises ranging in length from 7 0 to 35 cm and in weight from 0 7 to 7 0 kg Systematics edit nbsp Distribution map of the tortoise species of the genus Testudo overlaps and subspecies are shown The systematics and taxonomy of Testudo is notoriously problematic Highfield and Martin commented Synonymies on Testudo are notoriously difficult to compile with any degree of accuracy The status of species referred has undergone a great many changes each change introducing an additional level of complexity and making bibliographic research on the taxa extremely difficult Most early and not a few later checklists contain a very high proportion of entirely spurious entries and a considerable number of described species are now considered invalid either because they are homonyms non binomial or for some other reason 2 Since then DNA sequence data have increasingly been used in systematics but in Testudines turtles and tortoises its usefulness is limited In some of these at least mtDNA is known to evolve more slowly in these than in most other animals 3 Paleobiogeographical considerations suggest the rate of evolution of the mitochondrial 12S rRNA gene is 1 0 1 6 per million years for the last dozen million years or so in the present genus 4 and ntDNA evolution rate has been shown to vary strongly even between different population of T hermanni 5 this restricts sequence choice for molecular systematics and makes the use of molecular clocks questionable The following extant species in the following subgenera are placed here Genus Testudo Subgenus Agrionemys Russian tortoise or Horsfield s tortoise T horsfieldii 1 Subspecies Central Asian tortoise T horsfieldii horsfieldii Fergana Valley steppe tortoise T horsfieldii bogdanovi Kazakhstan steppe tortoise T horsfieldii kazakhstanica Turkmenistan steppe tortoise T horsfieldii kuznetzovi Kopet Dag steppe tortoise T horsfieldii rustamovi Subgenus Chersine Hermann s tortoise T hermanni 1 Subspecies Eastern Hermann s tortoise T hermanni boettgeri 1 Western Hermann s tortoise T hermanni hermanni 1 Subgenus Testudo Spur thighed tortoise Greek tortoise or common tortoise T graeca 1 Subspecies Mediterranean spur thighed tortoise T graeca graeca 1 Araxes tortoise T graeca armeniaca 1 Buxton s tortoise T graeca buxtoni 1 Cyrenaican spur thighed tortoise T graeca cyrenaica 1 Asia Minor tortoise T graeca ibera 1 Morocco tortoise T graeca marokkensis 1 Nabeul tortoise T graeca nabeulensis 1 Souss Valley tortoise T graeca soussensis 1 Mesopotamian tortoise T graeca terrestris 1 Iranian tortoise T graeca zarudnyi 1 Egyptian tortoise or Kleinmann s tortoise T kleinmanni 1 Marginated tortoise T marginata 1 The first two are more distinct and ancient lineages than the closely related latter three species Arguably T horsfieldii belongs in a new genus Agrionemys on the basis of the shape of its carapace and plastron 6 and its distinctness is supported by DNA sequence analysis 7 Likewise a separate genus Eurotestudo has recently been proposed for T hermanni these three lineages were distinct by the Late Miocene as evidenced by the fossil record 8 Whether these splits will eventually be accepted remains to be seen The genus Chersus has been proposed to unite the Egyptian and marginated tortoises which have certain DNA sequence similarities 4 but their ranges are and apparently always were separated by their closest relative T graeca and the open sea and thus chance convergent haplotype sorting would better explain the biogeographical discrepancy Conversely the Greek tortoise is widespread and highly diverse In this and other species a high number of subspecies has been described but not all generally accepted and several such as the Negev tortoise and the dwarf marginated tortoise are now considered to be local morphs Some such as the Tunisian tortoise have even been separated as a separate genus Furculachelys but this is not supported by more recent studies 9 Mating editTestudo spp are promiscuous creatures and they follow a polyandrous mating system 10 Mating involves a courtship ritual of mechanical olfactory and auditory displays elicited from the male to coerce a female into accepting copulation 11 Courtship displays are very energetically costly for males especially because females tend to run away from courting males 12 The male will chase her exerting more energy and elaborate displays of ramming and biting Females are able to judge a male s genetic quality through these displays only healthy males are able to perform costly courting rituals suggesting endurance rivalry 11 These are considered honest signals that are then used to influence pre and post copulatory choice as females are the choosy sex 10 Female mate choice offers no direct benefits such as access to food or territory or parental care 13 There are however indirect benefits of mating with multiple males Engaging in a polyandrous mating system offers a female guaranteed fertilization higher offspring diversity and sperm competition to ensure that eggs are fertilized by a high quality male This is in respect to the good genes hypothesis that females receive indirect benefits through her offspring by mating with a quality male a male s contribution to a female s fitness is restricted to his genes Cutuli G et al 2014 Mating order has no influence on paternity of a clutch so a female s inclination to mate with multiple males and her ability to store sperm allows for sperm competition and suggests cryptic female choice 14 However some species do show size assortative T marginata for example where large males breed with large females and small males breed with small females 11 Other species form hierarchies during male to male competition the more aggressive male is considered alpha 10 Alpha males are more aggressive with their courting as well and have higher mounting success rate than beta males A female s reproductive tract contains sperm storage tubules and she is capable of storing sperm for up to four years 15 This sperm remains viable and when she goes a breeding season without encountering a male she is able to fertilize her eggs with the stored sperm Storing sperm can also result in multiple paternity clutches It is quite common among Testudo spp females to lay a clutch that has been sired by multiple males And females can lay one to four clutches a breeding season Sexual dimorphism promiscuity long term sperm storage and elaborate courting rituals are factors that effect mate preference sperm competition and cryptic female choice in genus Testudo 10 References edit a b c d e f g h i j k l m n o p q r Rhodin Anders G J Inverson John B Roger Bour Fritz Uwe Georges Arthur Shaffer H Bradley van Dijk Peter Paul August 3 2017 Turtles of the world 2017 update Annotated checklist and atlas of taxonomy synonymy distribution and conservation status 8th Ed PDF Chelonian Research Monographs 7 ISBN 978 1 5323 5026 9 Retrieved October 4 2019 Highfield A C amp Martin J 1989 A revision of the Testudines of North Africa Asia and Europe Genus Testudo Journal of Chelonian Herpetology 1 1 1 12 Avise J C Bowen B W Lamb T Meylan A B Bermingham E 1992 Mitochondrial DNA evolution at a turtle s pace Evidence for low genetic variability and reduced microevolutionary rate in the Testudines Molecular Biology and Evolution 9 3 457 473 doi 10 1093 oxfordjournals molbev a040735 PMID 1584014 a b Van Der Kuyl Antoinette C Ph Ballasina Donato L Dekker John T Maas Jolanda Willemsen Ronald E Goudsmit Jaap 2002 Phylogenetic Relationships among the Species of the Genus Testudo Testudines Testudinidae Inferred from Mitochondrial 12S rRNA Gene Sequences Molecular Phylogenetics and Evolution 22 2 174 183 doi 10 1006 mpev 2001 1052 PMID 11820839 Fritz Uwe Auer Markus Bertolero Albert Cheylan Marc Fattizzo Tiziano Hundsdorfer Anna K Martin Sampayo Marcos Pretus Joan L Siroky Pavel Wink Michael 2006 A rangewide phylogeography of Hermann s tortoise Testudo hermanni Reptilia Testudines Testudinidae Implications for taxonomy Zoologica Scripta 35 5 531 543 doi 10 1111 j 1463 6409 2006 00242 x S2CID 86110728 Khozatsky L I amp Mlynarski M 1966 Agrionemys nouveau genre de tortues terrestres Testudinidae Agrionemys a new genus of tortoises Article in French verification needed Bulletin de l Academie Polonaise des Sciences II Serie des Sciences Biologiques 2 123 125 Fritz Uwe Siroky Pavel Kami Hajigholi Wink Michael 2005 Environmentally caused dwarfism or a valid species Is Testudo weissingeri Bour 1996 a distinct evolutionary lineage New evidence from mitochondrial and nuclear genomic markers Molecular Phylogenetics and Evolution 37 2 389 401 doi 10 1016 j ympev 2005 03 007 PMID 16223676 De Lapparent De Broin France Bour Roger Parham James F Perala Jarmo 2006 Eurotestudo a new genus for the species Testudo hermanni Gmelin 1789 Chelonii Testudinidae Comptes Rendus Palevol 5 6 803 811 Bibcode 2006CRPal 5 803D doi 10 1016 j crpv 2006 03 002 Van Der Kuyl Antoinette C Ballasina Donato LP Zorgdrager Fokla 2005 Mitochondrial haplotype diversity in the tortoise species Testudo graeca from North Africa and the Middle East BMC Evolutionary Biology 5 29 doi 10 1186 1471 2148 5 29 PMC 1097724 PMID 15836787 a b c d Cutuli Giulia Cannicci Stefano Vannini Marco Fratini Sara 2014 Influence of male courtship intensity and male male competition on paternity distribution in Hermann s tortoise Testudo hermanni hermanni Chelonia Testudinidae Biological Journal of the Linnean Society 111 3 656 667 doi 10 1111 bij 12243 hdl 2158 844715 a b c Sacchi Roberto Galeotti Paolo Fasola Mauro Ballasina Donato 2003 Vocalizations and courtship intensity correlate with mounting success in marginated tortoises Testudo marginata Behavioral Ecology and Sociobiology 55 95 102 doi 10 1007 s00265 003 0685 1 S2CID 9968063 Galeotti Paolo Sacchi Roberto Rosa Daniele Pellitteri Fasola Mauro 2005 Female preference for fast rate high pitched calls in Hermann s tortoises Testudo hermanni Behavioral Ecology 16 301 308 doi 10 1093 beheco arh165 Cutuli Giulia Cannicci Stefano Vannini Marco Fratini Sara 2013 Influence of mating order on courtship displays and stored sperm utilization in Hermann s tortoises Testudo hermanni hermanni Behavioral Ecology and Sociobiology 67 2 273 281 doi 10 1007 s00265 012 1447 8 hdl 2158 774769 S2CID 15308304 Johnston Emily E Rand Matthew S Zweifel Stephan G 2006 Detection of multiple paternity and sperm storage in a captive colony of the central Asian tortoise Testudo horsfieldii Canadian Journal of Zoology 84 4 520 526 doi 10 1139 Z06 023 Roques S Diaz Paniagua C Andreu A C 2004 Microsatellite markers reveal multiple paternity and sperm storage in the Mediterranean spur thighed tortoise Testudo graeca Canadian Journal of Zoology 82 153 159 doi 10 1139 Z03 228 External links editMediterranean tortoises Tortoise Trust Web Basic care of Mediterranean tortoises James F Parham J Robert Macey Theodore J Papenfuss Chris R Feldman Oguz Turkozan Rosa Polymeni JeVrey Boore 2005 The phylogeny of Mediterranean tortoises and their close relatives based on complete mitochondrial genome sequences from museum specimens PDF a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Retrieved from https en wikipedia org w index php title Testudo genus amp oldid 1193946224, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.