Biology:Most recent common ancestor

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Short description: Most recent individual from which all organisms in a group are directly descended


In biology and genetic genealogy, the most recent common ancestor (MRCA), also known as the last common ancestor (LCA), of a set of organisms is the most recent individual from which all the organisms of the set are descended. The term is also used in reference to the ancestry of groups of genes (haplotypes) rather than organisms.

The MRCA of a set of individuals can sometimes be determined by referring to an established pedigree. However, in general, it is impossible to identify the exact MRCA of a large set of individuals, but an estimate of the time at which the MRCA lived can often be given. Such time to most recent common ancestor (TMRCA) estimates can be given based on DNA test results and established mutation rates as practiced in genetic genealogy, or by reference to a non-genetic, mathematical model or computer simulation.

In organisms using sexual reproduction, the matrilineal MRCA and patrilineal MRCA are the MRCAs of a given population considering only matrilineal and patrilineal descent, respectively. The MRCA of a population by definition cannot be older than either its matrilineal or its patrilineal MRCA. In the case of Homo sapiens, the matrilineal and patrilineal MRCA are also known as "Mitochondrial Eve" (mt-MRCA) and "Y-chromosomal Adam" (Y-MRCA) respectively.

The age of the human MRCA is unknown. It is no greater than the age of either the Y-MRCA or the mt-MRCA, estimated at around 200,000 years.

Unlike in pedigrees of individual humans or domesticated lineages where historical parentage is known, in the inference of relationships among species or higher groups of taxa (systematics or phylogenetics), ancestors are not directly observable or recognizable. They are inferences based on patterns of relationship among taxa inferred in a phylogenetic analysis of extant organisms and/or fossils.[1]

The last universal common ancestor (LUCA) is the most recent common ancestor of all current life on Earth, estimated to have lived some 3.5 to 3.8 billion years ago (in the Paleoarchean).[2][3][note 1]

MRCA of different species

EuryarchaeotaNanoarchaeotaCrenarchaeotaProtozoaAlgaePlantSlime moldsAnimalFungusGram-positive bacteriaChlamydiaeChloroflexiActinobacteriaPlanctomycetesSpirochaetesFusobacteriaCyanobacteriaThermophilesAcidobacteriaProteobacteria
Evolutionary tree showing the divergence of modern species from the last universal ancestor in the center.[5] The three domains are colored, with bacteria blue, archaea green, and eukaryotes red.

The project of a complete description of the phylogenetic relationships among all biological species is dubbed the "tree of life". This involves inference of ages of divergence for all hypothesized clades; for example, the MRCA of all Carnivora (i.e. the MRCA of "cats and dogs") is estimated to have diverged some 42 million years ago (Miacidae).[6]

The concept of the last common ancestor from the perspective of human evolution is described for a popular audience in The Ancestor's Tale by Richard Dawkins (2004). Dawkins lists "concestors" of the human lineage in order of increasing age, including hominin (human–chimpanzee), hominine (human–gorilla), hominid (human–orangutan), hominoid (human–gibbon), and so on in 40 stages in total, down to the last universal common ancestor (human–bacteria).

MRCA of a population identified by a single genetic marker

Main page: Biology:Coalescent theory

It is also possible to consider the ancestry of individual genes (or groups of genes, haplotypes) instead of an organism as a whole. Coalescent theory describes a stochastic model of how the ancestry of such genetic markers maps to the history of a population.

Unlike organisms, a gene is passed down from a generation of organisms to the next generation either as perfect replicas of itself or as slightly mutated descendant genes. While organisms have ancestry graphs and progeny graphs via sexual reproduction, a gene has a single chain of ancestors and a tree of descendants. An organism produced by sexual cross-fertilization (allogamy) has at least two ancestors (its immediate parents), but a gene always has one ancestor per generation.

Patrilineal and matrilineal MRCA

Main pages: Biology:Mitochondrial Eve and Biology:Y-chromosomal Adam
Through random drift or selection, lineage will trace back to a single person. In this example over 5 generations, the colors represent extinct matrilineal lines and black the matrilineal line descended from the mt-MRCA.

Mitochondrial DNA (mtDNA) is nearly immune to sexual mixing, unlike the nuclear DNA whose chromosomes are shuffled and recombined in Mendelian inheritance. Mitochondrial DNA, therefore, can be used to trace matrilineal inheritance and to find the Mitochondrial Eve (also known as the African Eve), the most recent common ancestor of all humans via the mitochondrial DNA pathway.

Likewise, Y chromosome is present as a single sex chromosome in the male individual and is passed on to male descendants without recombination. It can be used to trace patrilineal inheritance and to find the Y-chromosomal Adam, the most recent common ancestor of all humans via the Y-DNA pathway.

Approximate dates for Mitochondrial Eve and Y-chromosomal Adam have been established by researchers using genealogical DNA tests. Mitochondrial Eve is estimated to have lived about 200,000 years ago. A paper published in March 2013 determined that, with 95% confidence and that provided there are no systematic errors in the study's data, Y-chromosomal Adam lived between 237,000 and 581,000 years ago.[7][8]

The MRCA of all humans alive today would, therefore, need to have lived more recently than either.[9][note 2]

It is more complicated to infer human ancestry via autosomal chromosomes. Although an autosomal chromosome contains genes that are passed down from parents to children via independent assortment from only one of the two parents, genetic recombination (chromosomal crossover) mixes genes from non-sister chromatids from both parents during meiosis, thus changing the genetic composition of the chromosome.

Time to MRCA estimates

Different types of MRCAs are estimated to have lived at different times in the past. These time to MRCA (TMRCA) estimates are also computed differently depending on the type of MRCA being considered. Patrilineal and matrilineal MRCAs (Mitochondrial Eve and Y-chromosomal Adam) are traced by single gene markers, thus their TMRCA are computed based on DNA test results and established mutation rates as practiced in genetic genealogy. The time to the genealogical MRCA (most recent common ancestor by any line of descent) of all living humans cannot be traced genetically because the DNA of the great majority of ancestors is completely lost after a few hundred years. It is therefore computed based on non-genetic, mathematical models and computer simulations.

Since Mitochondrial Eve and Y-chromosomal Adam are traced by single genes via a single ancestral parent line, the time to these genetic MRCAs will necessarily be greater than that for the genealogical MRCA. This is because single genes will coalesce more slowly than tracing of conventional human genealogy via both parents. The latter considers only individual humans, without taking into account whether any gene from the computed MRCA actually survives in every single person in the current population.[11]

TMRCA via genetic markers

Mitochondrial DNA can be used to trace the ancestry of a set of populations. In this case, populations are defined by the accumulation of mutations on the mtDNA, and special trees are created for the mutations and the order in which they occurred in each population. The tree is formed through the testing of a large number of individuals all over the world for the presence or lack of a certain set of mutations. Once this is done it is possible to determine how many mutations separate one population from another. The number of mutations, together with estimated mutation rate of the mtDNA in the regions tested, allows scientists to determine the approximate time to MRCA (TMRCA) which indicates time passed since the populations last shared the same set of mutations or belonged to the same haplogroup.

In the case of Y-Chromosomal DNA, TMRCA is arrived at in a different way. Y-DNA haplogroups are defined by single-nucleotide polymorphism in various regions of the Y-DNA. The time to MRCA within a haplogroup is defined by the accumulation of mutations in STR sequences of the Y-Chromosome of that haplogroup only. Y-DNA network analysis of Y-STR haplotypes showing a non-star cluster indicates Y-STR variability due to multiple founding individuals. Analysis yielding a star cluster can be regarded as representing a population descended from a single ancestor. In this case the variability of the Y-STR sequence, also called the microsatellite variation, can be regarded as a measure of the time passed since the ancestor founded this particular population. The descendants of Genghis Khan or one of his ancestors represents a famous star cluster that can be dated back to the time of Genghis Khan.[12]

TMRCA calculations are considered critical evidence when attempting to determine migration dates of various populations as they spread around the world. For example, if a mutation is deemed to have occurred 30,000 years ago, then this mutation should be found amongst all populations that diverged after this date. If archeological evidence indicates cultural spread and formation of regionally isolated populations then this must be reflected in the isolation of subsequent genetic mutations in this region. If genetic divergence and regional divergence coincide it can be concluded that the observed divergence is due to migration as evidenced by the archaeological record. However, if the date of genetic divergence occurs at a different time than the archaeological record, then scientists will have to look at alternate archaeological evidence to explain the genetic divergence. The issue is best illustrated in the debate surrounding the demic diffusion versus cultural diffusion during the European Neolithic.[13]

TMRCA of all living humans

The age of the MRCA of all living humans is unknown. It is necessarily younger than the age of either the matrilinear or the patrilinear MRCA, both of which have an estimated age of between roughly 100,000 and 200,000 years ago.[14]

A study by mathematicians Joseph T. Chang, Douglas Rohde and Steve Olson used a theoretical model to calculate that the MRCA may have lived remarkably recently, possibly as recently as 2,000 years ago. It concludes that the MRCA of all humans probably lived in East Asia, which would have given them key access to extremely isolated populations in Australia and the Americas. Possible locations for the MRCA include places such as the Chuckchi and Kamchatka Peninsulas that are close to Alaska, places such as Indonesia and Malaysia that are close to Australia or a place such as Taiwan or Japan that is more intermediate to Australia and the Americas. European colonization of the Americas and Australia was found by Chang to be too recent to have had a substantial impact on the age of the MRCA. In fact, if the Americas and Australia had never been discovered by Europeans, the MRCA would only be about 2.3% further back in the past than it is.[15][16][17]

Note that the age of the MRCA of a population does not correspond to a population bottleneck, let alone a "first couple". It rather reflects the presence of a single individual with high reproductive success in the past, whose genetic contribution has become pervasive throughout the population over time. It is also incorrect to assume that the MRCA passed all, or indeed any, genetic information to every living person. Through sexual reproduction, an ancestor passes half of his or her genes to each descendant in the next generation; in the absence of pedigree collapse, after just 32 generations the contribution of a single ancestor would be on the order of 2−32, a number proportional to less than a single basepair within the human genome.[18]

Identical ancestors point

Main page: Biology:Identical ancestors point

The MRCA is the most recent common ancestor shared by all individuals in the population under consideration. This MRCA may well have contemporaries who are also ancestral to some but not all of the extant population. The identical ancestors point is a point in the past more remote than the MRCA at which time there are no longer organisms which are ancestral to some but not all of the modern population. Due to pedigree collapse, modern individuals may still exhibit clustering, due to vastly different contributions from each of ancestral population.[19]

See also


Notes

  1. The composition of the LUCA is not directly accessible as a fossil, but can be studied by comparing the genomes of its descendants, organisms living today. By this means, a 2016 study identified a set of 355 genes inferred to have been present in the LUCA.[4]
  2. Notions such as Mitochondrial Eve and Y-chromosomal Adam yield common ancestors that are more ancient than for all living humans.[10]

References

  1. Brower AVZ, Schuh RT (2021). Biological Systematics: Principles and Applications (3rd edn.). Ithaca, NY: Cornell University Press. 
  2. Doolittle WF (February 2000). "Uprooting the tree of life". Scientific American 282 (2): 90–95. doi:10.1038/scientificamerican0200-90. PMID 10710791. Bibcode2000SciAm.282b..90D. 
  3. "The last universal common ancestor: emergence, constitution and genetic legacy of an elusive forerunner". Biology Direct 3: 29. 2008. doi:10.1186/1745-6150-3-29. PMID 18613974. 
  4. Wade, Nicholas (25 July 2016). "Meet Luca, the Ancestor of All Living Things". New York Times. https://www.nytimes.com/2016/07/26/science/last-universal-ancestor.html. 
  5. Ciccarelli FD, Doerks T, von Mering C, Creevey CJ, Snel B, Bork P; Doerks; von Mering; Creevey; Snel; Bork (2006). "Toward automatic reconstruction of a highly resolved tree of life". Science 311 (5765): 1283–87. doi:10.1126/science.1123061. PMID 16513982. Bibcode2006Sci...311.1283C. 
  6. Eizirik, E.; Murphy, W.J.; Koepfli, K.P.; Johnson, W.E.; Dragoo, J.W.; O'Brien, S.J. (2010). "Pattern and timing of the diversification of the mammalian order Carnivora inferred from multiple nuclear gene sequences". Molecular Phylogenetics and Evolution 56 (1): 49–63. doi:10.1016/j.ympev.2010.01.033. PMID 20138220. 
  7. Mendez, Fernando; Krahn, Thomas; Schrack, Bonnie; Krahn, Astrid-Maria; Veeramah, Krishna; Woerner, August; Fomine, Forka Leypey Mathew; Bradman, Neil et al. (7 March 2013). "An African American paternal lineage adds an extremely ancient root to the human Y chromosome phylogenetic tree". American Journal of Human Genetics 92 (3): 454–59. doi:10.1016/j.ajhg.2013.02.002. PMID 23453668. PMC 3591855. http://haplogroup-a.com/Ancient-Root-AJHG2013.pdf.  (primary source)
  8. Barrass, Colin (6 March 2013). "The father of all men is 340,000 years old". New Scientist. https://www.newscientist.com/article/dn23240-the-father-of-all-men-is-340000-years-old.html. 
  9. Dawkins, Richard (2004). The Ancestor's Tale, A Pilgrimage to the Dawn of Life. Boston: Houghton Mifflin Company. ISBN 978-0-618-00583-3. 
  10. Hartwell 2004, p. 539.
  11. Chang, Joseph T.; Donnelly, Peter; Wiuf, Carsten; Hein, Jotun; Slatkin, Montgomery; Ewens, W. J.; Kingman, J. F. C. (1999). "Recent common ancestors of all present-day individuals". Advances in Applied Probability 31 (4): 1002–26, discussion and author's reply, 1027–38. doi:10.1239/aap/1029955256. http://www.stat.yale.edu/~jtc5/papers/Ancestors.pdf. Retrieved 2008-01-29. 
  12. Tatiana Zerjal (2003), The Genetic Legacy of the Mongols, "Archived copy". http://web.unife.it/progetti/genetica/Giorgio/PDFfiles/ajhg2003.pdf. 
  13. Morelli L, Contu D, Santoni F, Whalen MB, Francalacci P et al. (2010). Lalueza-Fox, Carles. ed. "A Comparison of Y-Chromosome Variation in Sardinia and Anatolia Is More Consistent with Cultural Rather than Demic Diffusion of Agriculture". PLOS ONE 5 (4): e10419. doi:10.1371/journal.pone.0010419. PMID 20454687. Bibcode2010PLoSO...510419M. 
  14. Poznik, GD; Henn, BM; Yee, MC; Sliwerska, E; Euskirchen, GM; Lin, AA; Snyder, M; Quintana-Murci, L et al. (2013). "Sequencing Y chromosomes resolves discrepancy in time to common ancestor of males versus females". Science 341 (6145): 562–65. doi:10.1126/science.1237619. PMID 23908239. Bibcode2013Sci...341..562P. 
  15. "Roots of Human Family Tree Are Shallow". July 2006. https://www.washingtonpost.com/wp-dyn/content/article/2006/07/01/AR2006070100463.html. 
  16. "Archived copy". https://tedlab.mit.edu/~dr/Papers/Rohde-MRCA-two.pdf. 
  17. "'Most Recent Common Ancestor' of All Living Humans Surprisingly Recent". https://www.sciencedaily.com/releases/2004/09/040930122428.htm. 
  18. Zhaxybayeva, Olga; Lapierre, Pascal; Gogarten, J. Peter (May 2004). "Genome mosaicism and organismal lineages". Trends in Genetics 20 (5): 254–60. doi:10.1016/j.tig.2004.03.009. PMID 15109780. http://www-bac.esi.umontreal.ca/~dbin1001/h06/presentations/transferts-horizontaux/HGT_genome_Olga_TIG_2004.pdf. Retrieved 2009-02-19. "The Ship of Theseus paradox […] is frequently invoked to illustrate this point […]. Even moderate levels of gene transfer will make it impossible to reconstruct the genomes of early ancestors; …". 
  19. Rohde DL, Olson S, Chang JT; Olson; Chang (September 2004). "Modelling the recent common ancestry of all living humans". Nature 431 (7008): 562–66. doi:10.1038/nature02842. PMID 15457259. Bibcode2004Natur.431..562R. http://steveolson.com/uploads/2009/04/nature-common-ancestors2.pdf. 

Further reading