Two hypotheses about the relationships of the major groups of snakes. Left: tree based on nuclear genes, showing Acrochordidae and Xenodermidae as successive outgroups to core Colubroidea Right: tree based on mitochondrial genes, showing a sister relationship between Acrochordidae and Xenodermidae From Oguiura et al. 2009 |
Study
|
Acrochordid-Xenodermid Relationship
|
Support
|
How many species?
|
What data were used?
|
X&A
|
-
|
-
|
Morphology
|
|
X+A
|
8%
|
37
|
ND4
|
|
X+A
|
98%
|
98
|
4
mitochondrial genes
|
|
A,X
|
not reported
|
25
|
7
nuclear genes
|
|
A,X
|
>95%
|
50
|
20
nuclear genes
|
|
A,X*
|
100%
|
30
|
12
nuclear genes
|
|
A,X
|
94%
|
131
|
2
mitochondrial genes + 1 nuclear gene
|
|
A,X
|
97-100%
|
761
|
3
mitochondrial genes + 2 nuclear genes
|
|
X,A
|
95-100%
|
141
extant +
51 extinct |
610
morphological characters
|
|
A,X
|
100%
|
161
|
44
nuclear genes
|
|
X+A
|
95%
|
4,161
|
5
mitochondrial genes + 7 nuclear genes
|
|
A,X*
|
99%
|
32
|
333
nuclear loci
with 100% coverage |
|
A,X
|
91%
|
4,162
|
5
mitochondrial genes + 47 nuclear genes
|
related to colubroids than xenodermids; X,A means that xenodermids are more distant
*Relationships differed depending on which methods were used
Arafura Filesnake (Acrochordus arafurae) |
Dragonsnake (Xenodermus javanicus) |
Bearded Snake (Fimbrios klossi) |
Parafimbrios lao From Teynié et al. 2015 |
Amami Odd-scaled Snake (Achalinus werneri) |
Stoliczkia borneensis |
and avian W chromosomes also have these repeats. Cell biologists think that these repeats function to inactivate all the genes on the W chromosome except for those that determine sex3. Both mammalian X chromosomes and snake W chromosomes become very dense in body cells, so that none of the genes on them can be expressed. They only decondense and plays their brief, female-determining roles, in maturing eggs that are destined to become females. Unlike in mammals, the sex chromosomes of snakes span the gamut from completely identical to markedly differentiated, allowing biologists to study the evolution of chromosomal sex determination. The new study showed that female dragonsnakes have two different-looking sex chromosomes, with many Bkm repeats in the W, whereas the two Z sex chromosomes of male dragonsnakes look similar and lacked Bkm repeats, bolstering the relationship between xenodermids and other colubroids and diminishing the relationship between xenodermids and filesnakes.
The other major finding of the new study is the documentation that at least part of the sex chromosomes are homologous across all families of caenophidian snakes, suggesting that snake sex chromosomes emerged in the common ancestor of Caenophidia some 60-80 million years ago. One gene that is only on the Z chromosome in all caenophidians, including dragonsnakes, is also found on the W chromosome in filesnakes. The Z-chromosome-specific genes in caenophidians were on both the Z and W chromosomes in boas, pythons, and sunbeam snakes (Xenopeltidae), as well as in bearded dragons and anoles. Other toxicoferan lizards with ZW sex chromosomes, including chameleons and monitor lizards, seem to have evolved them independently.
1 A recent article in the journal Herpetological Review pointed out that the grammatical rules for structuring family and subfamily names from genus names have recently been incorrectly applied in two cases involving snakes which concern this article: 1) Xenodermatidae/inae for the family/subfamily containing Xenodermus, the root of which is "dermus", a masculine noun with which the masculine specific epithet javanicus is correctly coupled (not the neuter javanicum; in contrast think of the neuter Heloderma horridum in family Helodermatidae). The correct family or subfamily name is thus Xenodermidae/inae. 2) Pareatidae or Pareatinae for the family containing Pareas, which is also masculine, making the correct family/subfamily name Pareidae/inae.↩
2 Don't confuse this snake genus (Stoliczkia) with a genus of extinct ammonite (Stoliczkaia), both named for Czech biologist Ferdinand Stoliczka. The extra "a" was added to the original spelling of the snake genus by Boulenger in 1899, probably by accident, and this genus is still widely misspelled today (e.g., on GenBank and on Wikipedia before I fixed it while writing this article).↩
3 It's also thought that "GATA" is a particularly potent regulatory sequence, with the power to turn nearby genes on and off. In a way, the sex genes have essentially 'hijacked' the W chromosome, turning off all its other genes, and simultaneously creating a concentrated source of mutation-causing elements. Chromosomal sex determination may therefore constitute a unique and potentially very powerful genotypic mechanism for abruptly enhancing evolutionary rates, which might have contributed to the explosive radiations of species in clades with chromosomal sex determination, such as mammals, birds, squamates, and certain groups of insects.↩
Boulenger, G. A. 1899. Description of three new reptiles and a new batrachian from Mt. Kina Balu, North Borneo. Annals and Magazine of Natural History 7:451-453 <link>
Gauthier, J. A., M. Kearney, J. A. Maisano, O. Rieppel, and A. D. B. Behlke. 2012. Assembling the squamate Tree of Life: perspectives from the phenotype and the fossil record. Bulletin of the Peabody Museum of Natural History 53:3-308 <link>
Jerdon, T. C. 1870. Notes on Indian Herpetology. Proceedings of the Asiatic Society of Bengal 1870:66-85 <link>
Jones, K., and L. Singh. 1985. Snakes and the evolution of sex chromosomes. Trends in Genetics 1:55-61 <link>
Lawson, R., J. B. Slowinski, B. I. Crother, and F. T. Burbrink. 2005. Phylogeny of the Colubroidea (Serpentes): new evidence from mitochondrial and nuclear genes. Molecular Phylogenetics and Evolution 37:581-601 <link>
Kelly, C. M. R., N. P. Barker, and M. H. Villet. 2003. Phylogenetics of advanced snakes (Caenophidia) based on four mitochondrial genes. Systematic Biology 52:439-459 <link>
Kraus, F., and W. M. Brown. 1998. Phylogenetic relationships of colubroid snakes based on mitochondrial DNA sequences. Zoological Journal of the Linnean Society 122:455-487 <link>
Oguiura, N., H. Ferrarezzi, and R. Batistic. 2009. Cytogenetics and molecular data in snakes: a phylogenetic approach. Cytogenetic and Genome Research 127:128-142 <link>
O’Meally, D., H. R. Patel, R. Stiglec, S. D. Sarre, A. Georges, J. A. M. Graves, and T. Ezaz. 2010. Non-homologous sex chromosomes of birds and snakes share repetitive sequences. Chromosome Research 18:787-800 <link>
Pokorna, M., and L. Kratochvíl. 2009. Phylogeny of sex‐determining mechanisms in squamate reptiles: are sex chromosomes an evolutionary trap? Zoological Journal of the Linnean Society 156:168-183 <link>
Pyron, R. A., F. T. Burbrink, G. R. Colli, A. N. M. de Oca, L. J. Vitt, C. A. Kuczynski, and J. J. Wiens. 2011. The phylogeny of advanced snakes (Colubroidea), with discovery of a new subfamily and comparison of support methods for likelihood trees. Molecular Phylogenetics and Evolution 58:329-342 <link>
Pyron, R. A., F. Burbrink, and J. J. Wiens. 2013. A phylogeny and revised classification of Squamata, including 4161 species of lizards and snakes. BMC Biology 13:53 <link>
Pyron, R. A., C. R. Hendry, V. M. Chou, E. M. Lemmon, A. R. Lemmon, and F. T. Burbrink. 2014. Effectiveness of phylogenomic data and coalescent species-tree methods for resolving difficult nodes in the phylogeny of advanced snakes (Serpentes: Caenophidia). Molecular Phylogenetics and Evolution 81:221-231 <link>
Rovatsos, M., M. Johnson Pokorná, and L. Kratochvíl. 2015. Differentiation of sex chromosomes and karyotype characterisation in the Dragonsnake Xenodermus javanicus (Squamata: Xenodermatidae). Cytogenetic and Genome Research 147:48-54 <link>
Savage, J. M. 2015. What are the correct family names for the taxa that include the snake genera Xenodermus, Pareas, and Calamaria? Herpetological Review 46:664-665 <link>
Sharma, G., and U. Nakhasi. 1980. Karyological studies on six species of Indian snakes (Colubridae: Reptilia). Cytobios 27:177-192 link>
Teynié, A., P. David, A. Lottier, M. D. Le, N. Visal, and T. Q. Nguyan. 2015. A new genus and species of xenodermatid snake (Squamata: Caenophidia: Xenodermatidae) from northern Lao People’s Democratic Republic. Zootaxa 3926:523-540 <link>
Vicoso, B., J. Emerson, Y. Zektser, S. Mahajan, and D. Bachtrog. 2013. Comparative sex chromosome genomics in snakes: differentiation, evolutionary strata, and lack of global dosage compensation. PLoS Biology 11:e1001643 <link>
Vidal, N., A. S. Delmas, P. David, C. Cruaud, A. Couloux, and S. B. Hedges. 2007. The phylogeny and classification of caenophidian snakes inferred from seven nuclear protein-coding genes. Comptes Rendus Biologies 330:182-187 <link>
Wang, G., S. He, S. Huang, M. He, and E. Zhao. 2009. The complete mitochondrial DNA sequence and the phylogenetic position of Achalinus meiguensis (Reptilia: Squamata). Chinese Science Bulletin 54:1713-1724 <link>
Wiens, J. J., C. A. Kuczynski, S. A. Smith, D. G. Mulcahy, J. W. Sites, T. M. Townsend, and T. W. Reeder. 2008. Branch lengths, support, and congruence: testing the phylogenomic approach with 20 nuclear loci in snakes. Systematic Biology 57:420-431 <link>
Wiens, J. J., C. R. Hutter, D. G. Mulcahy, B. P. Noonan, T. M. Townsend, J. W. Sites, and T. W. Reeder. 2012. Resolving the phylogeny of lizards and snakes (Squamata) with extensive sampling of genes and species. Biology Letters 8:1043-1046 <link>
Zaher, H., F. G. Grazziotin, J. E. Cadle, R. W. Murphy, J. C. Moura-Leite, and S. L. Bonatto. 2009. Molecular phylogeny of advanced snakes (Serpentes, Caenophidia) with an emphasis on South American Xenodontines: A revised classification and descriptions of new taxa. Papeis Avulsos de Zoologia (Sao Paulo) 49:115-153 <link>
Zheng, Y., and J. J. Wiens. 2016. Combining phylogenomic and supermatrix approaches, and a time-calibrated phylogeny for squamate reptiles (lizards and snakes) based on 52 genes and 4162 species. Molecular Phylogenetics and Evolution 94:537-547 <link>
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.