fbpx
Wikipedia

Basal (phylogenetics)

January 26, 2023

In phylogenetics, basal is the direction of the base (or root) of a rooted phylogenetic tree or cladogram. The term may be more strictly applied only to nodes adjacent to the root, or more loosely applied to nodes regarded as being close to the root. Note that extant taxa that lie on branches connecting directly to the root are not more closely related to the root than any other extant taxa.[1][2][3]

While there must always be two or more equally "basal" clades sprouting from the root of every cladogram, those clades may differ widely in taxonomic rank,[n 1] species diversity, or both.[n 2] If C is a basal clade within D that has the lowest rank of all basal clades within D,[n 3] C may be described as the basal taxon of that rank within D.[n 4] The concept of a 'key innovation' implies some degree of correlation between evolutionary innovation and diversification.[4][5][6][n 5] However, such a correlation does not make a given case predicable, so ancestral characters should not be imputed to the members of a less species-rich basal clade without additional evidence.[1][2][7][8][n 6]

In general, clade A is more basal than clade B if B is a subgroup of the sister group of A or of A itself.[n 7] Within large groups, "basal" may be used loosely to mean 'closer to the root than the great majority of', and in this context terminology such as "very basal" may arise. A 'core clade' is a clade representing all but the basal clade(s) of lowest rank within a larger clade; e.g., core eudicots. Of course, no extant taxon is closer to the root than any other, by definition.

Usage

A basal group in the stricter sense forms a sister group to the rest of the larger clade,[citation needed] as in the following case:

Root 

 Basal clade #1

 Non-basal clade #1

 Non-basal clade #2  

 Non-basal clade #3

Basal clade #2

While it is easy to identify a basal clade in such a cladogram, the appropriateness of such an identification is dependent on the accuracy and completeness of the diagram. It is often assumed in this example that the terminal branches of the cladogram depict all the extant taxa of a given rank within the clade; this is one reason the term basal is highly deceptive, as the lack of additional species in one clade is taken as evidence of morphological affinity with ancestral taxa. Additionally, this qualification does not ensure that the diversity of extinct taxa (which may be poorly known) is represented.[citation needed]

In phylogenetics, the term basal cannot be objectively applied to clades of organisms, but tends to be applied selectively and more controversially to groups or lineages[n 8] thought to possess ancestral characters, or to such presumed ancestral traits themselves. In describing characters, "ancestral" or "plesiomorphic" are preferred to "basal" or "primitive", the latter of which may carry false connotations of inferiority or a lack of complexity.[1] The terms ''deep-branching'' or ''early-branching'' are similar in meaning, and equally may misrepresent extant taxa that lie on branches connecting directly to the root node as having more ancestral character states.[1][2]

Despite the ubiquity of the usage of basal, systematists try to avoid its usage because its application to extant groups is unnecessary and misleading.[3] The term is more often applied when one branch (the one deemed "basal") is less diverse than another branch (this being the situation in which one would expect to find a basal taxon of lower minimum rank). The term may be equivocal in that it also refers to the direction of the root of the tree, which represents a hypothetical ancestor; this consequently may inaccurately imply that the sister group of a more species-rich clade displays ancestral features.[8] An extant basal group may or may not resemble the last common ancestor of a larger clade to a greater degree than other groups, and is separated from that ancestor by the same amount of time as all other extant groups. However, there are cases where the unusually small size of a sister group does indeed correlate with an unusual number of ancestral traits, as in Amborella (see below). This is likely a source of the mis-use of the term. Other famous examples of this phenomenon are the oviparous reproduction and nipple-less lactation of monotremes, a clade of mammals[11] with just five species, and the archaic anatomy of the tuatara,[12] a basal clade of lepidosaurian with a single species.

Examples

Flowering plants

 
Amborella trichopoda, the most basal extant angiosperm

The flowering plant family Amborellaceae, restricted to New Caledonia in the southwestern Pacific,[n 9] is a basal clade of extant angiosperms,[13] consisting of the most species, genus, family and order within the group that are sister to all other angiosperms (out of a total of about 250,000 angiosperm species). The traits of Amborella trichopoda are regarded as providing significant insight into the evolution of flowering plants; for example, it has "the most primitive wood (consisting only of tracheids), of any living angiosperm" as well as "simple, separate flower parts of indefinite numbers, and unsealed carpels".[14] However, those traits are a mix of archaic and apomorphic (derived) features that have only been sorted out via comparison with other angiosperms and their positions within the phylogenetic tree (the fossil record could potentially also be helpful in this respect, but is absent in this case).[14] The cladogram below is based on Ramírez-Barahona et al. (2020),[15] with species counts taken from the source indicated.

 Angiosperms 

Amborellales (1 species)[16]

Nymphaeales (about 90 species)[17]

Austrobaileyales (about 95 species)[17]

Magnoliids (about 9,000 species)[16]

Chloranthales (about 80 species)[17]

Monocots (about 70,000 species)[16]

Ceratophyllales (about 6 species)[16]

Eudicots (about 175,000 species)[16]

Great apes

Within the great apes, gorillas (eastern and western) are a sister group to chimpanzees, bonobos and humans. These five species form a clade, the subfamily Homininae (African apes), of which Gorilla has been termed the basal genus. However, if the analysis is not restricted to genera, the Homo plus Pan clade is also basal.

 
The phylogenetic tree of marsupials derived from retroposon data shows the basal position of South American Didelphimorphia within Marsupialia, and the basal position of South American Dromiciops within otherwise Australasian Australidelphia.[18]
 
Relationship of biogeography and phylogeny of bat superfamily Noctilionoidea inferred from nuclear DNA sequence data, showing the basal position of the Malagasy family Myzopodidae. Locations with only fossil members are indicated by red stars.
 Homininae 

Humans (Homo sapiens)

Bonobos (Pan paniscus)

Common chimpanzees (Pan troglodytes)

Eastern gorillas (Gorilla beringei)

Western gorillas (Gorilla gorilla)

Moreover, orangutans are a sister group to Homininae and are the basal genus in the great ape family Hominidae as a whole.

 Hominidae 
 Ponginae 

Orangutans (Pongo spp.)

 Homininae 

Humans (Homo sapiens)

Chimpanzees (Pan spp.)

Gorillas (Gorilla spp.)

Subfamilies Homininae and Ponginae are both basal within Hominidae, but given that there are no nonbasal subfamilies in the cladogram it is unlikely the term would be applied to either. In general, a statement to the effect that one group (e.g., orangutans) is basal, or branches off first, within another group (e.g., Hominidae) may not make sense unless the appropriate taxonomic level(s) (genus, in this case) is specified. If that level cannot be specified (i.e., if the clade in question is unranked) a more detailed description of the relevant sister groups may be needed. As can be seen, the term is not reflective of ancestral states or proximity to the common ancestor of extant species.

In this example, orangutans differ from the other genera in their Asian range. This fact plus their basal status provides a hint that the most recent common ancestor of extant great apes may have been Eurasian (see below), a suggestion that is consistent with other evidence.[19] (Of course, lesser apes are entirely Asiatic.) However, orangutans also differ from African apes in their more highly arboreal lifestyle, a trait generally viewed as ancestral among the apes.[20][21]

Relevance to biogeographic history

Given that the deepest phylogenetic split in a group is likely to have occurred early in its history, identification of the most basal subclade(s) in a widely dispersed taxon or clade can provide valuable insight into its region of origin; however, the lack of additional species in a clade is not evidence that it carries the ancestral state for most traits. Most deceptively, people often believe that the direction of migration away from the area of origin can also be inferred (as in the Amaurobioides and Noctilionoidea cases below). As with all other traits, the phylogeographic location of one clade that connects to the root does not provide information about the ancestral state. Examples where such unjustified inferences may have been made include:

  • Spiders of the genus Amaurobioides are present in South Africa, Australia, New Zealand and Chile.[22][23] The most basal clade is South African; DNA sequence evidence indicates that after their South American ancestors reached South Africa, they dispersed eastward all the way back to South America over an interval of about 8 million years.[23]
  • Iguanid lizards (sensu lato) are distributed throughout the Americas, on Madagascar, and on Fiji and Tonga in the western South Pacific. The Malagasy forms (Opluridae) were previously thought to be basal, with an estimated divergence date from the others of ~162 million years, not long before the time of Madagascar's separation from Africa.[24] This suggested that iguanids once had a widespread Gondwanan distribution; after the Malagasy and New World representatives were separated by vicariance, less isolated Old World iguanids became extinct through competition with other lizard groups (e.g., agamids). In contrast, western Pacific iguanids are nested deeply within American iguanids,[25] having apparently colonized their isolated range after an epic 10,000 km rafting event.[26][27] However, a 2022 study found oplurids to be closely allied with the American iguanians Leiosauridae, having only diverged 60 million years ago following a likely rafting event of their own.[28] Due to this, neither of the Old World "iguanids" are thought to represent basal lineages.
  • Coral snakes comprise about 16 species in Asia and over 65 species in the Americas. However, none of the American clades are basal, implying that the group's ancestry was in the Old World.[29]
  • Extant australidelphian marsupials constitute about 240 species in Australasia and one species (the monito del monte) in South America. The fact that the monito del monte occupies a basal position (the most basal species, genus, family and order) in the superorder Australidelphia is an important clue that its origin was in South America. This conclusion is consistent with the fact that the South American order Didelphimorphia is basal within infraclass Marsupialia; i.e., extant marsupials as a whole also appear to have originated in South America.[18][n 10][n 11][n 12]
  • While the bat superfamily Noctilionoidea has over 200 species in the Neotropics, two in New Zealand, and two in Madagascar, the basal position of the Malagasy family[36] suggests, in combination with the fossil record and the next-most-basal placement of the New Zealand family, that the superfamily originated in Africa and then migrated eastward to South America, proliferating there but surviving in the Old World only in refugia.[37]
  • The genus Urocyon (gray and island foxes) is basal in the canine subfamily,[38] suggesting a North American origin of the nearly worldwide group. This is consistent with fossil evidence indicating a North American origin for the canid family as a whole (the other two canid subfamilies, the extinct Borophaginae[39] and Hesperocyoninae,[40] the latter being basal in Canidae, were both endemic to North America).

Notes

  1. ^ Meaning the lowest taxonomic ranks of the respective clades; the highest ranks should be the same (assuming they are ranked).
  2. ^ See the Amborella example, in which one basal clade is a single extant species (that is also the sole living representative of an order, Amborellales). Meanwhile, the other (unranked) sister basal clade has about 250,000 species.
  3. ^ For example, C might be a genus and the other basal clade(s) might have the higher ranks of subfamily or family.
  4. ^ In the great apes example, Gorilla is the basal genus of subfamily Homininae, while Pongo is the basal genus of family Hominidae. The two basal clades of the latter both have the highest rank of subfamily, i.e. Homininae and Ponginae.
  5. ^ Greater diversification of a clade may also be associated with colonization of a new land mass, especially if larger or less competitive than the ancestral land mass; see the coral snake, marsupial and noctilionoid bat examples.
  6. ^ For example, the giant panda represents the most basal extant species, genus and subfamily within Ursidae,[9] but its specializations for a bamboo diet are not ancestral ursid characters.[10]
  7. ^ That is, in the diagram below, both basal clades #1 and #2 are more basal than non-basal clade #1, which in turn is more basal than non-basal clades #2 and #3.
  8. ^ Since a lineage is a linear chain of descent, all lineages within a clade can be traced back not only to the root, but to the origin of life. Thus, from a phylogenetic standpoint, the notion of a lineage being basal is nonsensical. However, in genetics, basal lineage refers to a lineage connecting a common ancestor with a single variant allele to a branch ancestor with two descendant variants.
  9. ^ New Caledonia is viewed as a refugium; i.e., in this case the geographic location of the basal clade is not thought to provide evidence for the locale in which angiosperms originated.
  10. ^ These conclusions have been supported by the finding of Eocene fossil remains of the microbiotherian Woodburnodon casei in Antarctica,[30] which is presumed to have served as a way station on the migration route to Australia before the final breakup of Gondwana.
  11. ^ Similarly, among australobatrachian frogs, the South American family Calyptocephalellidae, with 5 extant species (living in the same Valdivian forest as the monito del monte), is basal to the Australasian families Limnodynastidae and Myobatrachidae,[31] with about 120 extant species, suggesting a South American origin for the group.[32] This is consistent with the finding of a fossil from the South American family in Antarctica.[33]
  12. ^ Ratites may have similarly traveled overland from South America to colonize Australia;[34] a fossil ratite is known from Antarctica,[35] and South American rheas are more basal within the group than Australo-Pacific ratites.[34]

References

  1. ^ a b c d Smith, Stacey (2016-09-19). "For the love of trees: The ancestors are not among us". For the love of trees. Retrieved 2022-03-07.
  2. ^ a b c Crisp, Michael D.; Cook, Lyn G (2005). "Do early branching lineages signify ancestral traits?". Trends in Ecology & Evolution. 20 (3): 122–128. doi:10.1111/j.0307-6970.2004.00262.x. PMID 16701355. S2CID 82371239.
  3. ^ a b Krell, Frank-T; Cranston, Peter S. (2004). "Which side of the tree is more basal?". Systematic Entomology. 29 (3): 279–281. doi:10.1016/j.tree.2004.11.010. PMID 16701355. S2CID 12285373.
  4. ^ Heard, S.B.; Hauser, D.L. (1995). "Key evolutionary innovations and their ecological mechanisms". Historical Biology. 10 (2): 151–173. doi:10.1080/10292389509380518.
  5. ^ Engel, M.S.; Grimaldi, D.A. (2004). "New light shed on the oldest insect". Nature. 427 (6975): 627–630. Bibcode:2004Natur.427..627E. doi:10.1038/nature02291. PMID 14961119. S2CID 4431205.
  6. ^ Fernández‐Mazuecos, M.; Blanco‐Pastor, J.L.; Juan, A.; Carnicero, P.; Forrest, A.; Alarcón, M.; Vargas, P.; Glover, B.J. (2019). "Macroevolutionary dynamics of nectar spurs, a key evolutionary innovation". New Phytologist. 222 (2): 1123–1138. doi:10.1111/nph.15654. hdl:10045/89954. PMID 30570752. S2CID 58567195.
  7. ^ Baum, D. A. (4 November 2013). "Phylogenetics and the History of Life". The Princeton Guide to Evolution. Princeton University Press. p. 57. ISBN 978-1-4008-4806-5. OCLC 861200134.
  8. ^ a b Jenner, Ronald A (2006). "Unburdening evo-devo: ancestral attractions, model organisms, and basal baloney". Development Genes and Evolution. 216 (7–8): 385–394. doi:10.1007/s00427-006-0084-5. PMID 16733736. S2CID 23140594.
  9. ^ Krause, J.; Unger, T.; Noçon, A.; Malaspinas, A.; Kolokotronis, S.; Stiller, M.; Soibelzon, L.; Spriggs, H.; Dear, P. H.; Briggs, A. W.; Bray, S. C. E.; O'Brien, S. J.; Rabeder, G.; Matheus, P.; Cooper, A.; Slatkin, M.; Pääbo, S.; Hofreiter, M. (2008). "Mitochondrial genomes reveal an explosive radiation of extinct and extant bears near the Miocene-Pliocene boundary". BMC Evolutionary Biology. 8 (220): 220. doi:10.1186/1471-2148-8-220. PMC 2518930. PMID 18662376.
  10. ^ McLellan, Bruce; Reiner, David C. (1994). "A Review of Bear Evolution". Bears: Their Biology and Management. 9 (1): 85–96. doi:10.2307/3872687. JSTOR 3872687.
  11. ^ Van Rheede, Teun (2005). "The Platypus Is in Its Place: Nuclear Genes and Indels Confirm the Sister Group Relation of Monotremes and Therians". Molecular Biology and Evolution. 23 (3): 587–597. doi:10.1093/molbev/msj064. PMID 16291999.
  12. ^ Herrera-Flores, J. A.; Stubbs, T. L.; Benton, M. J.; Ruta, M. (2017). "Macroevolutionary patterns in Rhynchocephalia: is the tuatara (Sphenodon punctatus) a living fossil?". Palaeontology. 60 (3): 319–328. doi:10.1111/pala.12284.
  13. ^ Li, H.-T.; Yi, T.-S.; Gao, L.-M.; Ma, P.-F.; Zhang, T.; Yang, J.-B.; Gitzendanner, M.A.; Fritsch, P.W.; Cai, J.; Luo, Y.; Wang, H.; van der Bank, M.; Zhang, S.-D.; Wang, Q.-F.; Wang, J.; Zhang, Z.-R.; Fu, C.-N.; Yang, J.; Hollingsworth, P.M.; Chase, M.W.; Soltis, D.E.; Soltis, P.S.; Li, D.-Z. (2019). "Origin of angiosperms and the puzzle of the Jurassic gap". Nature Plants. 5 (5): 461–470. doi:10.1038/s41477-019-0421-0. PMID 31061536. S2CID 146118264.
  14. ^ a b Essig, F. B. (2014-07-01). "What's so primitive about Amborella?". Botany Professor. Retrieved 2014-10-04.
  15. ^ Ramírez-Barahona, S.; Sauquet, H.; Magallón, S. (2020). "The delayed and geographically heterogeneous diversification of flowering plant families". Nature Ecology & Evolution. 4 (9): 1232–1238. doi:10.1038/s41559-020-1241-3. PMID 32632260. S2CID 220375828.
  16. ^ a b c d e Palmer, J.D.; Soltis, D.E.; Chase, M.W. (2004). "The plant tree of life: an overview and some points of view". American Journal of Botany. 91 (10): 1437–1445. doi:10.3732/ajb.91.10.1437. PMID 21652302.
  17. ^ a b c Christenhusz, M. J. M.; Byng, J. W. (2016). "The number of known plants species in the world and its annual increase". Phytotaxa. 261 (3): 201–217. doi:10.11646/phytotaxa.261.3.1.
  18. ^ a b Nilsson, M. A.; Churakov, G.; Sommer, M.; Van Tran, N.; Zemann, A.; Brosius, J.; Schmitz, J. (2010-07-27). Penny, David (ed.). "Tracking Marsupial Evolution Using Archaic Genomic Retroposon Insertions". PLOS Biology. 8 (7): e1000436. doi:10.1371/journal.pbio.1000436. PMC 2910653. PMID 20668664.
  19. ^ Moya-Sola, S.; Alba, D. M.; Almecija, S.; Casanovas-Vilar, I.; Kohler, M.; De Esteban-Trivigno, S.; Robles, J. M.; Galindo, J.; Fortuny, J. (2009-06-16). "A unique Middle Miocene European hominoid and the origins of the great ape and human clade". PNAS. 106 (24): 9601–9606. Bibcode:2009PNAS..106.9601M. doi:10.1073/pnas.0811730106. PMC 2701031. PMID 19487676..
  20. ^ MaClatchy, L.; Gebo, D.; Kityo, R.; Pilbeam, D. (2000). "Postcranial functional morphology of Morotopithecus bishopi, with implications for the evolution of modern ape locomotion". Journal of Human Evolution. 39 (2): 159–183. doi:10.1006/jhev.2000.0407. PMID 10968927.
  21. ^ Thorpe, S. K. S.; Crompton, R. H. (2006). "Orangutan positional behavior and the nature of arboreal locomotion in Hominoidea". American Journal of Physical Anthropology. 131 (3): 384–401. doi:10.1002/ajpa.20422. PMID 16617429.
  22. ^ Kukso, F. (2016-11-08). "Seafaring Spiders Made It around the World—in 8 Million Years". Scientific American. Retrieved 2016-11-10.
  23. ^ a b Kuntner, M.; Ceccarelli, F. S.; Opell, B. D.; Haddad, C. R.; Raven, Robert J.; Soto, E. M.; Ramírez, M. J. (2016-10-12). "Around the World in Eight Million Years: Historical Biogeography and Evolution of the Spray Zone Spider Amaurobioides (Araneae: Anyphaenidae)". PLOS ONE. 11 (10): e0163740. Bibcode:2016PLoSO..1163740C. doi:10.1371/journal.pone.0163740. PMC 5061358. PMID 27732621.
  24. ^ Okajima, Y.; Kumazawa, Y. (2009-07-15). "Mitogenomic perspectives into iguanid phylogeny and biogeography: Gondwanan vicariance for the origin of Madagascan oplurines". Gene. 441 (1–2): 28–35. doi:10.1016/j.gene.2008.06.011. PMID 18598742.
  25. ^ Schulte, J. A.; Valladares, J. P.; Larson, A. (September 2003). "Phylogenetic Relationships Within Iguanidae Inferred Using Molecular and Morphological Data and a Phylogenetic Taxonomy of Iguanian Lizards". Herpetologica. 59 (3): 399–419. doi:10.1655/02-48. S2CID 56054202.
  26. ^ Gibbons, J. R. H. (1981-07-31). "The Biogeography of Brachylophus (Iguanidae) including the Description of a New Species, B. vitiensis, from Fiji". Journal of Herpetology. 15 (3): 255–273. doi:10.2307/1563429. JSTOR 1563429.
  27. ^ Keogh, J. S.; Edwards, D. L; Fisher, R. N; Harlow, P. S (2008). "Molecular and morphological analysis of the critically endangered Fijian iguanas reveals cryptic diversity and a complex biogeographic history". Philosophical Transactions of the Royal Society B: Biological Sciences. 363 (1508): 3413–3426. doi:10.1098/rstb.2008.0120. PMC 2607380. PMID 18782726.
  28. ^ Welt, Rachel S.; Raxworthy, Christopher J. (2022-02-01). "Dispersal, not vicariance, explains the biogeographic origin of iguanas on Madagascar". Molecular Phylogenetics and Evolution. 167: 107345. doi:10.1016/j.ympev.2021.107345. ISSN 1055-7903. PMID 34748875. S2CID 243821392.
  29. ^ Slowinski, J. B.; Boundy, J.; Lawson, R. (June 2001). "The Phylogenetic Relationships of Asian Coral Snakes (Elapidae: Calliophis and Maticora) Based on Morphological and Molecular Characters". Herpetologica. 57 (2): 233–245. JSTOR 3893186.
  30. ^ Goin, F. J.; Zimicz, N.; Reguero, M. A.; Santillana, S. N.; Marenssi, S. A.; Moly, J. J. (2007). "New marsupial (Mammalia) from the Eocene of Antarctica, and the origins and affinities of the Microbiotheria". Revista de la Asociación Geológica Argentina. 62 (4): 597–603. Retrieved 2016-07-17.
  31. ^ Pyron, R.A.; Wiens, J.J. (2011). "A large-scale phylogeny of Amphibia including over 2800 species, and a revised classification of extant frogs, salamanders, and caecilians". Molecular Phylogenetics and Evolution. 61 (2): 543–583. doi:10.1016/j.ympev.2011.06.012. PMID 21723399.
  32. ^ Feng, Y.-J.; Blackburn, D.C.; Liang, D.; Hillis, D.M.; Wake, D.B.; Cannatella, D.C.; Zhang, P. (2017). "Phylogenomics reveals rapid, simultaneous diversification of three major clades of Gondwanan frogs at the Cretaceous–Paleogene boundary". Proceedings of the National Academy of Sciences. 114 (29): E5864–E5870. Bibcode:2017PNAS..114E5864F. doi:10.1073/pnas.1704632114. PMC 5530686. PMID 28673970.
  33. ^ Mörs, T.; Reguero, M.; Vasilyan, D. (2020). "First fossil frog from Antarctica: implications for Eocene high latitude climate conditions and Gondwanan cosmopolitanism of Australobatrachia". Scientific Reports. 10 (1): 5051. Bibcode:2020NatSR..10.5051M. doi:10.1038/s41598-020-61973-5. PMC 7181706. PMID 32327670.
  34. ^ a b Yonezawa, T.; Segawa, T.; Mori, H.; Campos, P. F.; Hongoh, Y.; Endo, H.; Akiyoshi, A.; Kohno, N.; Nishida, S.; Wu, J.; Jin, H.; Adachi, J.; Kishino, H.; Kurokawa, K.; Nogi, Y.; Tanabe, H.; Mukoyama, H.; Yoshida, K.; Rasoamiaramanana, A.; Yamagishi, S.; Hayashi, Y.; Yoshida, A.; Koike, H.; Akishinonomiya, F.; Willerslev, E.; Hasegawa, M. (2016-12-15). "Phylogenomics and Morphology of Extinct Paleognaths Reveal the Origin and Evolution of the Ratites". Current Biology. 27 (1): 68–77. doi:10.1016/j.cub.2016.10.029. PMID 27989673.
  35. ^ Tambussi, C.P.; Noriega, J.I.; Gazdzicki, A.; Tatur, A.; Reguero, M.A.; Vizcaino, S.F. (1994). (PDF). Polish Polar Research. 15 (1–2): 15–20. Archived from the original (PDF) on 2019-12-28. Retrieved 28 December 2019.
  36. ^ Teeling, E. C.; Springer, M.; Madsen, O.; Bates, P.; O'Brien, S.; Murphy, W. (2005-01-28). "A Molecular Phylogeny for Bats Illuminates Biogeography and the Fossil Record". Science. 307 (5709): 580–584. Bibcode:2005Sci...307..580T. doi:10.1126/science.1105113. PMID 15681385. S2CID 25912333.
  37. ^ Gunnell, G. F.; Simmons, N. B.; Seiffert, E. R. (2014-02-04). "New Myzopodidae (Chiroptera) from the Late Paleogene of Egypt: Emended Family Diagnosis and Biogeographic Origins of Noctilionoidea". PLoS ONE. 9 (2): e86712. Bibcode:2014PLoSO...986712G. doi:10.1371/journal.pone.0086712. PMC 3913578. PMID 24504061.
  38. ^ Lindblad-Toh, K.; Wade, C.M.; Mikkelsen, T.S.; Karlsson, E.K.; Jaffe, D.B.; Kamal, M.; Clamp, M.; Chang, J.L.; Kulbokas, E.J.; Zody, M.C.; Mauceli, E.; Xie, X.; Breen, M.; Wayne, R.K.; Ostrander, E.A.; Ponting, C.P.; Galibert, F.; Smith, D.R.; Dejong, P.J.; Kirkness, E.; Alvarez, P.; Biagi, T.; Brockman, W.; Butler, J.; Chin, C.-W.; Cook, A.; Cuff, J.; Daly, M.J.; Decaprio, D.; et al. (2005). "Genome sequence, comparative analysis and haplotype structure of the domestic dog". Nature. 438 (7069): 803–819. Bibcode:2005Natur.438..803L. doi:10.1038/nature04338. PMID 16341006.
  39. ^ Wang, Xiaoming; Tedford, Richard; Taylor, Beryl (1999-11-17). "Phylogenetic systematics of the Borophaginae (Carnivora, Canidae)". Bulletin of the American Museum of Natural History. 243. hdl:2246/1588.
  40. ^ Wang, X.; Tedford, R.H. (2008). Dogs, Their Fossil Relatives and Evolutionary History. Columbia University Press. pp. 23–31. ISBN 978-0-231-13528-3.

External links

January 26, 2023
basal, phylogenetics, phylogenetics, basal, direction, base, root, rooted, phylogenetic, tree, cladogram, term, more, strictly, applied, only, nodes, adjacent, root, more, loosely, applied, nodes, regarded, being, close, root, note, that, extant, taxa, that, b. In phylogenetics basal is the direction of the base or root of a rooted phylogenetic tree or cladogram The term may be more strictly applied only to nodes adjacent to the root or more loosely applied to nodes regarded as being close to the root Note that extant taxa that lie on branches connecting directly to the root are not more closely related to the root than any other extant taxa 1 2 3 While there must always be two or more equally basal clades sprouting from the root of every cladogram those clades may differ widely in taxonomic rank n 1 species diversity or both n 2 If C is a basal clade within D that has the lowest rank of all basal clades within D n 3 C may be described as the basal taxon of that rank within D n 4 The concept of a key innovation implies some degree of correlation between evolutionary innovation and diversification 4 5 6 n 5 However such a correlation does not make a given case predicable so ancestral characters should not be imputed to the members of a less species rich basal clade without additional evidence 1 2 7 8 n 6 In general clade A is more basal than clade B if B is a subgroup of the sister group of A or of A itself n 7 Within large groups basal may be used loosely to mean closer to the root than the great majority of and in this context terminology such as very basal may arise A core clade is a clade representing all but the basal clade s of lowest rank within a larger clade e g core eudicots Of course no extant taxon is closer to the root than any other by definition Contents 1 Usage 2 Examples 2 1 Flowering plants 2 2 Great apes 3 Relevance to biogeographic history 4 Notes 5 References 6 External linksUsage EditA basal group in the stricter sense forms a sister group to the rest of the larger clade citation needed as in the following case Root Basal clade 1 Non basal clade 1 Non basal clade 2 Non basal clade 3 Basal clade 2While it is easy to identify a basal clade in such a cladogram the appropriateness of such an identification is dependent on the accuracy and completeness of the diagram It is often assumed in this example that the terminal branches of the cladogram depict all the extant taxa of a given rank within the clade this is one reason the term basal is highly deceptive as the lack of additional species in one clade is taken as evidence of morphological affinity with ancestral taxa Additionally this qualification does not ensure that the diversity of extinct taxa which may be poorly known is represented citation needed In phylogenetics the term basal cannot be objectively applied to clades of organisms but tends to be applied selectively and more controversially to groups or lineages n 8 thought to possess ancestral characters or to such presumed ancestral traits themselves In describing characters ancestral or plesiomorphic are preferred to basal or primitive the latter of which may carry false connotations of inferiority or a lack of complexity 1 The terms deep branching or early branching are similar in meaning and equally may misrepresent extant taxa that lie on branches connecting directly to the root node as having more ancestral character states 1 2 Despite the ubiquity of the usage of basal systematists try to avoid its usage because its application to extant groups is unnecessary and misleading 3 The term is more often applied when one branch the one deemed basal is less diverse than another branch this being the situation in which one would expect to find a basal taxon of lower minimum rank The term may be equivocal in that it also refers to the direction of the root of the tree which represents a hypothetical ancestor this consequently may inaccurately imply that the sister group of a more species rich clade displays ancestral features 8 An extant basal group may or may not resemble the last common ancestor of a larger clade to a greater degree than other groups and is separated from that ancestor by the same amount of time as all other extant groups However there are cases where the unusually small size of a sister group does indeed correlate with an unusual number of ancestral traits as in Amborella see below This is likely a source of the mis use of the term Other famous examples of this phenomenon are the oviparous reproduction and nipple less lactation of monotremes a clade of mammals 11 with just five species and the archaic anatomy of the tuatara 12 a basal clade of lepidosaurian with a single species Examples EditFlowering plants Edit Amborella trichopoda the most basal extant angiosperm The flowering plant family Amborellaceae restricted to New Caledonia in the southwestern Pacific n 9 is a basal clade of extant angiosperms 13 consisting of the most species genus family and order within the group that are sister to all other angiosperms out of a total of about 250 000 angiosperm species The traits of Amborella trichopoda are regarded as providing significant insight into the evolution of flowering plants for example it has the most primitive wood consisting only of tracheids of any living angiosperm as well as simple separate flower parts of indefinite numbers and unsealed carpels 14 However those traits are a mix of archaic and apomorphic derived features that have only been sorted out via comparison with other angiosperms and their positions within the phylogenetic tree the fossil record could potentially also be helpful in this respect but is absent in this case 14 The cladogram below is based on Ramirez Barahona et al 2020 15 with species counts taken from the source indicated Angiosperms Amborellales 1 species 16 Nymphaeales about 90 species 17 Austrobaileyales about 95 species 17 Magnoliids about 9 000 species 16 Chloranthales about 80 species 17 Monocots about 70 000 species 16 Ceratophyllales about 6 species 16 Eudicots about 175 000 species 16 Basal angiosperms Great apes Edit This section includes a list of general references but it lacks sufficient corresponding inline citations Please help to improve this section by introducing more precise citations November 2021 Learn how and when to remove this template message Within the great apes gorillas eastern and western are a sister group to chimpanzees bonobos and humans These five species form a clade the subfamily Homininae African apes of which Gorilla has been termed the basal genus However if the analysis is not restricted to genera the Homo plus Pan clade is also basal The phylogenetic tree of marsupials derived from retroposon data shows the basal position of South American Didelphimorphia within Marsupialia and the basal position of South American Dromiciops within otherwise Australasian Australidelphia 18 Relationship of biogeography and phylogeny of bat superfamily Noctilionoidea inferred from nuclear DNA sequence data showing the basal position of the Malagasy family Myzopodidae Locations with only fossil members are indicated by red stars Homininae Humans Homo sapiens Bonobos Pan paniscus Common chimpanzees Pan troglodytes Eastern gorillas Gorilla beringei Western gorillas Gorilla gorilla Moreover orangutans are a sister group to Homininae and are the basal genus in the great ape family Hominidae as a whole Hominidae Ponginae Orangutans Pongo spp Homininae Humans Homo sapiens Chimpanzees Pan spp Gorillas Gorilla spp Subfamilies Homininae and Ponginae are both basal within Hominidae but given that there are no nonbasal subfamilies in the cladogram it is unlikely the term would be applied to either In general a statement to the effect that one group e g orangutans is basal or branches off first within another group e g Hominidae may not make sense unless the appropriate taxonomic level s genus in this case is specified If that level cannot be specified i e if the clade in question is unranked a more detailed description of the relevant sister groups may be needed As can be seen the term is not reflective of ancestral states or proximity to the common ancestor of extant species In this example orangutans differ from the other genera in their Asian range This fact plus their basal status provides a hint that the most recent common ancestor of extant great apes may have been Eurasian see below a suggestion that is consistent with other evidence 19 Of course lesser apes are entirely Asiatic However orangutans also differ from African apes in their more highly arboreal lifestyle a trait generally viewed as ancestral among the apes 20 21 Relevance to biogeographic history EditGiven that the deepest phylogenetic split in a group is likely to have occurred early in its history identification of the most basal subclade s in a widely dispersed taxon or clade can provide valuable insight into its region of origin however the lack of additional species in a clade is not evidence that it carries the ancestral state for most traits Most deceptively people often believe that the direction of migration away from the area of origin can also be inferred as in the Amaurobioides and Noctilionoidea cases below As with all other traits the phylogeographic location of one clade that connects to the root does not provide information about the ancestral state Examples where such unjustified inferences may have been made include Spiders of the genus Amaurobioides are present in South Africa Australia New Zealand and Chile 22 23 The most basal clade is South African DNA sequence evidence indicates that after their South American ancestors reached South Africa they dispersed eastward all the way back to South America over an interval of about 8 million years 23 Iguanid lizards sensu lato are distributed throughout the Americas on Madagascar and on Fiji and Tonga in the western South Pacific The Malagasy forms Opluridae were previously thought to be basal with an estimated divergence date from the others of 162 million years not long before the time of Madagascar s separation from Africa 24 This suggested that iguanids once had a widespread Gondwanan distribution after the Malagasy and New World representatives were separated by vicariance less isolated Old World iguanids became extinct through competition with other lizard groups e g agamids In contrast western Pacific iguanids are nested deeply within American iguanids 25 having apparently colonized their isolated range after an epic 10 000 km rafting event 26 27 However a 2022 study found oplurids to be closely allied with the American iguanians Leiosauridae having only diverged 60 million years ago following a likely rafting event of their own 28 Due to this neither of the Old World iguanids are thought to represent basal lineages Coral snakes comprise about 16 species in Asia and over 65 species in the Americas However none of the American clades are basal implying that the group s ancestry was in the Old World 29 Extant australidelphian marsupials constitute about 240 species in Australasia and one species the monito del monte in South America The fact that the monito del monte occupies a basal position the most basal species genus family and order in the superorder Australidelphia is an important clue that its origin was in South America This conclusion is consistent with the fact that the South American order Didelphimorphia is basal within infraclass Marsupialia i e extant marsupials as a whole also appear to have originated in South America 18 n 10 n 11 n 12 While the bat superfamily Noctilionoidea has over 200 species in the Neotropics two in New Zealand and two in Madagascar the basal position of the Malagasy family 36 suggests in combination with the fossil record and the next most basal placement of the New Zealand family that the superfamily originated in Africa and then migrated eastward to South America proliferating there but surviving in the Old World only in refugia 37 The genus Urocyon gray and island foxes is basal in the canine subfamily 38 suggesting a North American origin of the nearly worldwide group This is consistent with fossil evidence indicating a North American origin for the canid family as a whole the other two canid subfamilies the extinct Borophaginae 39 and Hesperocyoninae 40 the latter being basal in Canidae were both endemic to North America Notes Edit Meaning the lowest taxonomic ranks of the respective clades the highest ranks should be the same assuming they are ranked See the Amborella example in which one basal clade is a single extant species that is also the sole living representative of an order Amborellales Meanwhile the other unranked sister basal clade has about 250 000 species For example C might be a genus and the other basal clade s might have the higher ranks of subfamily or family In the great apes example Gorilla is the basal genus of subfamily Homininae while Pongo is the basal genus of family Hominidae The two basal clades of the latter both have the highest rank of subfamily i e Homininae and Ponginae Greater diversification of a clade may also be associated with colonization of a new land mass especially if larger or less competitive than the ancestral land mass see the coral snake marsupial and noctilionoid bat examples For example the giant panda represents the most basal extant species genus and subfamily within Ursidae 9 but its specializations for a bamboo diet are not ancestral ursid characters 10 That is in the diagram below both basal clades 1 and 2 are more basal than non basal clade 1 which in turn is more basal than non basal clades 2 and 3 Since a lineage is a linear chain of descent all lineages within a clade can be traced back not only to the root but to the origin of life Thus from a phylogenetic standpoint the notion of a lineage being basal is nonsensical However in genetics basal lineage refers to a lineage connecting a common ancestor with a single variant allele to a branch ancestor with two descendant variants New Caledonia is viewed as a refugium i e in this case the geographic location of the basal clade is not thought to provide evidence for the locale in which angiosperms originated These conclusions have been supported by the finding of Eocene fossil remains of the microbiotherian Woodburnodon casei in Antarctica 30 which is presumed to have served as a way station on the migration route to Australia before the final breakup of Gondwana Similarly among australobatrachian frogs the South American family Calyptocephalellidae with 5 extant species living in the same Valdivian forest as the monito del monte is basal to the Australasian families Limnodynastidae and Myobatrachidae 31 with about 120 extant species suggesting a South American origin for the group 32 This is consistent with the finding of a fossil from the South American family in Antarctica 33 Ratites may have similarly traveled overland from South America to colonize Australia 34 a fossil ratite is known from Antarctica 35 and South American rheas are more basal within the group than Australo Pacific ratites 34 References Edit a b c d Smith Stacey 2016 09 19 For the love of trees The ancestors are not among us For the love of trees Retrieved 2022 03 07 a b c Crisp Michael D Cook Lyn G 2005 Do early branching lineages signify ancestral traits Trends in Ecology amp Evolution 20 3 122 128 doi 10 1111 j 0307 6970 2004 00262 x PMID 16701355 S2CID 82371239 a b Krell Frank T Cranston Peter S 2004 Which side of the tree is more basal Systematic Entomology 29 3 279 281 doi 10 1016 j tree 2004 11 010 PMID 16701355 S2CID 12285373 Heard S B Hauser D L 1995 Key evolutionary innovations and their ecological mechanisms Historical Biology 10 2 151 173 doi 10 1080 10292389509380518 Engel M S Grimaldi D A 2004 New light shed on the oldest insect Nature 427 6975 627 630 Bibcode 2004Natur 427 627E doi 10 1038 nature02291 PMID 14961119 S2CID 4431205 Fernandez Mazuecos M Blanco Pastor J L Juan A Carnicero P Forrest A Alarcon M Vargas P Glover B J 2019 Macroevolutionary dynamics of nectar spurs a key evolutionary innovation New Phytologist 222 2 1123 1138 doi 10 1111 nph 15654 hdl 10045 89954 PMID 30570752 S2CID 58567195 Baum D A 4 November 2013 Phylogenetics and the History of Life The Princeton Guide to Evolution Princeton University Press p 57 ISBN 978 1 4008 4806 5 OCLC 861200134 a b Jenner Ronald A 2006 Unburdening evo devo ancestral attractions model organisms and basal baloney Development Genes and Evolution 216 7 8 385 394 doi 10 1007 s00427 006 0084 5 PMID 16733736 S2CID 23140594 Krause J Unger T Nocon A Malaspinas A Kolokotronis S Stiller M Soibelzon L Spriggs H Dear P H Briggs A W Bray S C E O Brien S J Rabeder G Matheus P Cooper A Slatkin M Paabo S Hofreiter M 2008 Mitochondrial genomes reveal an explosive radiation of extinct and extant bears near the Miocene Pliocene boundary BMC Evolutionary Biology 8 220 220 doi 10 1186 1471 2148 8 220 PMC 2518930 PMID 18662376 McLellan Bruce Reiner David C 1994 A Review of Bear Evolution Bears Their Biology and Management 9 1 85 96 doi 10 2307 3872687 JSTOR 3872687 Van Rheede Teun 2005 The Platypus Is in Its Place Nuclear Genes and Indels Confirm the Sister Group Relation of Monotremes and Therians Molecular Biology and Evolution 23 3 587 597 doi 10 1093 molbev msj064 PMID 16291999 Herrera Flores J A Stubbs T L Benton M J Ruta M 2017 Macroevolutionary patterns in Rhynchocephalia is the tuatara Sphenodon punctatus a living fossil Palaeontology 60 3 319 328 doi 10 1111 pala 12284 Li H T Yi T S Gao L M Ma P F Zhang T Yang J B Gitzendanner M A Fritsch P W Cai J Luo Y Wang H van der Bank M Zhang S D Wang Q F Wang J Zhang Z R Fu C N Yang J Hollingsworth P M Chase M W Soltis D E Soltis P S Li D Z 2019 Origin of angiosperms and the puzzle of the Jurassic gap Nature Plants 5 5 461 470 doi 10 1038 s41477 019 0421 0 PMID 31061536 S2CID 146118264 a b Essig F B 2014 07 01 What s so primitive about Amborella Botany Professor Retrieved 2014 10 04 Ramirez Barahona S Sauquet H Magallon S 2020 The delayed and geographically heterogeneous diversification of flowering plant families Nature Ecology amp Evolution 4 9 1232 1238 doi 10 1038 s41559 020 1241 3 PMID 32632260 S2CID 220375828 a b c d e Palmer J D Soltis D E Chase M W 2004 The plant tree of life an overview and some points of view American Journal of Botany 91 10 1437 1445 doi 10 3732 ajb 91 10 1437 PMID 21652302 a b c Christenhusz M J M Byng J W 2016 The number of known plants species in the world and its annual increase Phytotaxa 261 3 201 217 doi 10 11646 phytotaxa 261 3 1 a b Nilsson M A Churakov G Sommer M Van Tran N Zemann A Brosius J Schmitz J 2010 07 27 Penny David ed Tracking Marsupial Evolution Using Archaic Genomic Retroposon Insertions PLOS Biology 8 7 e1000436 doi 10 1371 journal pbio 1000436 PMC 2910653 PMID 20668664 Moya Sola S Alba D M Almecija S Casanovas Vilar I Kohler M De Esteban Trivigno S Robles J M Galindo J Fortuny J 2009 06 16 A unique Middle Miocene European hominoid and the origins of the great ape and human clade PNAS 106 24 9601 9606 Bibcode 2009PNAS 106 9601M doi 10 1073 pnas 0811730106 PMC 2701031 PMID 19487676 MaClatchy L Gebo D Kityo R Pilbeam D 2000 Postcranial functional morphology of Morotopithecus bishopi with implications for the evolution of modern ape locomotion Journal of Human Evolution 39 2 159 183 doi 10 1006 jhev 2000 0407 PMID 10968927 Thorpe S K S Crompton R H 2006 Orangutan positional behavior and the nature of arboreal locomotion in Hominoidea American Journal of Physical Anthropology 131 3 384 401 doi 10 1002 ajpa 20422 PMID 16617429 Kukso F 2016 11 08 Seafaring Spiders Made It around the World in 8 Million Years Scientific American Retrieved 2016 11 10 a b Kuntner M Ceccarelli F S Opell B D Haddad C R Raven Robert J Soto E M Ramirez M J 2016 10 12 Around the World in Eight Million Years Historical Biogeography and Evolution of the Spray Zone Spider Amaurobioides Araneae Anyphaenidae PLOS ONE 11 10 e0163740 Bibcode 2016PLoSO 1163740C doi 10 1371 journal pone 0163740 PMC 5061358 PMID 27732621 Okajima Y Kumazawa Y 2009 07 15 Mitogenomic perspectives into iguanid phylogeny and biogeography Gondwanan vicariance for the origin of Madagascan oplurines Gene 441 1 2 28 35 doi 10 1016 j gene 2008 06 011 PMID 18598742 Schulte J A Valladares J P Larson A September 2003 Phylogenetic Relationships Within Iguanidae Inferred Using Molecular and Morphological Data and a Phylogenetic Taxonomy of Iguanian Lizards Herpetologica 59 3 399 419 doi 10 1655 02 48 S2CID 56054202 Gibbons J R H 1981 07 31 The Biogeography of Brachylophus Iguanidae including the Description of a New Species B vitiensis from Fiji Journal of Herpetology 15 3 255 273 doi 10 2307 1563429 JSTOR 1563429 Keogh J S Edwards D L Fisher R N Harlow P S 2008 Molecular and morphological analysis of the critically endangered Fijian iguanas reveals cryptic diversity and a complex biogeographic history Philosophical Transactions of the Royal Society B Biological Sciences 363 1508 3413 3426 doi 10 1098 rstb 2008 0120 PMC 2607380 PMID 18782726 Welt Rachel S Raxworthy Christopher J 2022 02 01 Dispersal not vicariance explains the biogeographic origin of iguanas on Madagascar Molecular Phylogenetics and Evolution 167 107345 doi 10 1016 j ympev 2021 107345 ISSN 1055 7903 PMID 34748875 S2CID 243821392 Slowinski J B Boundy J Lawson R June 2001 The Phylogenetic Relationships of Asian Coral Snakes Elapidae Calliophis and Maticora Based on Morphological and Molecular Characters Herpetologica 57 2 233 245 JSTOR 3893186 Goin F J Zimicz N Reguero M A Santillana S N Marenssi S A Moly J J 2007 New marsupial Mammalia from the Eocene of Antarctica and the origins and affinities of the Microbiotheria Revista de la Asociacion Geologica Argentina 62 4 597 603 Retrieved 2016 07 17 Pyron R A Wiens J J 2011 A large scale phylogeny of Amphibia including over 2800 species and a revised classification of extant frogs salamanders and caecilians Molecular Phylogenetics and Evolution 61 2 543 583 doi 10 1016 j ympev 2011 06 012 PMID 21723399 Feng Y J Blackburn D C Liang D Hillis D M Wake D B Cannatella D C Zhang P 2017 Phylogenomics reveals rapid simultaneous diversification of three major clades of Gondwanan frogs at the Cretaceous Paleogene boundary Proceedings of the National Academy of Sciences 114 29 E5864 E5870 Bibcode 2017PNAS 114E5864F doi 10 1073 pnas 1704632114 PMC 5530686 PMID 28673970 Mors T Reguero M Vasilyan D 2020 First fossil frog from Antarctica implications for Eocene high latitude climate conditions and Gondwanan cosmopolitanism of Australobatrachia Scientific Reports 10 1 5051 Bibcode 2020NatSR 10 5051M doi 10 1038 s41598 020 61973 5 PMC 7181706 PMID 32327670 a b Yonezawa T Segawa T Mori H Campos P F Hongoh Y Endo H Akiyoshi A Kohno N Nishida S Wu J Jin H Adachi J Kishino H Kurokawa K Nogi Y Tanabe H Mukoyama H Yoshida K Rasoamiaramanana A Yamagishi S Hayashi Y Yoshida A Koike H Akishinonomiya F Willerslev E Hasegawa M 2016 12 15 Phylogenomics and Morphology of Extinct Paleognaths Reveal the Origin and Evolution of the Ratites Current Biology 27 1 68 77 doi 10 1016 j cub 2016 10 029 PMID 27989673 Tambussi C P Noriega J I Gazdzicki A Tatur A Reguero M A Vizcaino S F 1994 Ratite bird from the Paleogene La Meseta Formation Seymour Island Antarctica PDF Polish Polar Research 15 1 2 15 20 Archived from the original PDF on 2019 12 28 Retrieved 28 December 2019 Teeling E C Springer M Madsen O Bates P O Brien S Murphy W 2005 01 28 A Molecular Phylogeny for Bats Illuminates Biogeography and the Fossil Record Science 307 5709 580 584 Bibcode 2005Sci 307 580T doi 10 1126 science 1105113 PMID 15681385 S2CID 25912333 Gunnell G F Simmons N B Seiffert E R 2014 02 04 New Myzopodidae Chiroptera from the Late Paleogene of Egypt Emended Family Diagnosis and Biogeographic Origins of Noctilionoidea PLoS ONE 9 2 e86712 Bibcode 2014PLoSO 986712G doi 10 1371 journal pone 0086712 PMC 3913578 PMID 24504061 Lindblad Toh K Wade C M Mikkelsen T S Karlsson E K Jaffe D B Kamal M Clamp M Chang J L Kulbokas E J Zody M C Mauceli E Xie X Breen M Wayne R K Ostrander E A Ponting C P Galibert F Smith D R Dejong P J Kirkness E Alvarez P Biagi T Brockman W Butler J Chin C W Cook A Cuff J Daly M J Decaprio D et al 2005 Genome sequence comparative analysis and haplotype structure of the domestic dog Nature 438 7069 803 819 Bibcode 2005Natur 438 803L doi 10 1038 nature04338 PMID 16341006 Wang Xiaoming Tedford Richard Taylor Beryl 1999 11 17 Phylogenetic systematics of the Borophaginae Carnivora Canidae Bulletin of the American Museum of Natural History 243 hdl 2246 1588 Wang X Tedford R H 2008 Dogs Their Fossil Relatives and Evolutionary History Columbia University Press pp 23 31 ISBN 978 0 231 13528 3 External links Edit Interpreting the Tree Diagram or List of Subgroups on a Tree of Life Page Tree of Life Web Project Retrieved from https en wikipedia org w index php title Basal phylogenetics amp oldid 1127781696, 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.