- 著者
- Naoki Osada
- 出版者
- The Genetics Society of Japan
- 雑誌
- Genes & Genetic Systems (ISSN:13417568)
- 巻号頁・発行日
- vol.90, no.3, pp.133-145, 2015-06-01 (Released:2015-10-27)
- 参考文献数
- 120
- 被引用文献数
- 19 28
Genetic diversity is a key parameter in population genetics and is important for understanding the process of evolution and for the development of appropriate conservation strategies. Recent advances in sequencing technology have enabled the measurement of genetic diversity of various organisms at the nucleotide level and on a genome-wide scale, yielding more precise estimates than were previously achievable. In this review, I have compiled and summarized the estimates of genetic diversity in humans and non-human primates based on recent genome-wide studies. Although studies on population genetics demonstrated fluctuations in population sizes over time, general patterns have emerged. As shown previously, genetic diversity in humans is one of the lowest among primates; however, certain other primate species exhibit genetic diversity that is comparable to or even lower than that in humans. There exists greater than 10-fold variation in genetic diversity among primate species, and I found weak correlation with species fecundity but not with body or propagule size. I further discuss the potential evolutionary consequences of population size decline on the evolution of primate species. The level of genetic diversity negatively correlates with the ratio of non-synonymous to synonymous polymorphisms in a population, suggesting that proportionally greater numbers of slightly deleterious mutations segregate in small rather than large populations. Although population size decline is likely to promote the fixation of slightly deleterious mutations, there are molecular mechanisms, such as compensatory mutations at various molecular levels, which may prevent fitness decline at the population level. The effects of slightly deleterious mutations from theoretical and empirical studies and their relevance to conservation biology are also discussed in this review.
言及状況
外部データベース (DOI)
Twitter (3 users, 8 posts, 6 favorites)
My question for behavioral genetics is: is there enough genetic variation in humans to make meaningful studies? We have nucleotide diversity (π) of 0.001, which is less than cheetahs, 0.069.
Our gene pool seems puddle small.
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https://t.co/SDVZyBKVRn https://t.co/3mUnsd2YZt
@BigRockFan88 @autistocrates Your conclusion is based on a misunderstanding of the methods by which the numbers on those tables are derived. They're not measuring the same thing on the same scale. This paper does a proper comparison between humans and other primates.
https://t.co/aVfQwUlTf4
@Carecans1 @von_Mistont @SerenaJB3 Your accusations of sophistry are pure projection. Your newest definition of race (entirely based on social construction and not genetics, by the way) would make Basques a different race from the rest of the people in Spain.
https://t.co/aVfQwUlTf4
Humans π = 0.001
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Chihuahuas and other domestic dogs π = 0.001 https://t.co/EcJcYXrAgH
@WiringTheBrain @utafrith Fantastic thread. Maybe you can help me out with something: Are humans really less genetically diverse than inbred rats and mice? Humans have nucleotide diversity (π) of ~0.001; inbred mice π ~0.0055, inbred rats π ~0.0022.
https://t.co/qpyclP40tO
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@DKThomp @kph3k Q for geneticists: Are humans really less genetically diverse than inbred rats and mice? Humans have nucleotide diversity (π) of ~0.001; inbred mice π ~0.0055, inbred rats π ~0.0022. Sources below:
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https://t.co/qpyclP40tO
Are humans really less genetically diverse than inbred rats and mice? Humans have nucleotide diversity (π) of ~0.001; inbred mice π ~0.0055, inbred rats π ~0.0022. Sources below. What am I missing here? I have ~0 background in genetics.
Humans: https://t.co/adsvQqSps8