scholarly journals Reproductive longevity predicts mutation rates in primates

2018 ◽  
Author(s):  
Gregg W.C. Thomas ◽  
Richard J. Wang ◽  
Arthi Puri ◽  
R. Alan Harris ◽  
Muthuswamy Raveendran ◽  
...  
Keyword(s):  
Mutation Rate ◽  
De Novo ◽  
Paternal Age ◽  
Mutation Rates ◽  
Specific Mutation ◽  
Genetic Constraints ◽  
Wide Range ◽  
Owl Monkeys ◽  
Species Specific ◽  
Multicellular Organisms

AbstractMutation rates vary between species across several orders of magnitude, with larger organisms having the highest per-generation mutation rates. Hypotheses for this pattern typically invoke physiological or population-genetic constraints imposed on the molecular machinery preventing mutations1. However, continuing germline cell division in multicellular eukaryotes means that organisms with longer generation times and of larger size will leave more mutations to their offspring simply as a by-product of their increased lifespan2,3. Here, we deeply sequence the genomes of 30 owl monkeys (Aotus nancymaae) from 6 multi-generation pedigrees to demonstrate that paternal age is the major factor determining the number of de novo mutations in this species. We find that owl monkeys have an average mutation rate of 0.81 × 10−8 per site per generation, roughly 32% lower than the estimate in humans. Based on a simple model of reproductive longevity that does not require any changes to the mutational machinery, we show that this is the expected mutation rate in owl monkeys. We further demonstrate that our model predicts species-specific mutation rates in other primates, including study-specific mutation rates in humans based on the average paternal age. Our results suggest that variation in life history traits alone can explain variation in the per-generation mutation rate among primates, and perhaps among a wide range of multicellular organisms.

scholarly journals Mutation rates and the evolution of germline structure

2015 ◽  
Author(s):  
Aylwyn Scally
Keyword(s):  
Mutation Rate ◽  
De Novo ◽  
Active Role ◽  
Paternal Age ◽  
Mutation Rates ◽  
State Transitions ◽  
Evolutionary Changes ◽  
Sequencing Studies ◽  
Paternal Age Effect ◽  
Stem Cell State

AbstractGenome sequencing studies of de novo mutations in humans have revealed surprising incongruities with our understanding of human germline mutation. In particular, the mutation rate observed in modern humans is substantially lower than that estimated from calibration against the fossil record, and the paternal age effect in mutations transmitted to offspring is much weaker than expected from our longstanding model of spermatogenesis. I consider possible explanations for these discrepancies, including evolutionary changes in life history parameters such as generation time and the age of puberty, a possible contribution from undetected post-zygotic mutations early in embryo development, and changes in cellular mutation processes at different stages of the germline. I suggest a revised model of stem cell state transitions during spermatogenesis, in which ‘dark’ gonial stem cells play a more active role than hitherto envisaged, with a long cycle time undetected in experimental observations. More generally I argue that the mutation rate and its evolution depend intimately on the structure of the germline in humans and other primates.

Evolution of mutation rate and virulence among human retroviruses

1994 ◽  
Vol 346 (1317) ◽  
pp. 333-343 ◽  
Keyword(s):  
Immune System ◽  
Mutation Rate ◽  
Hiv Infections ◽  
Molecular Data ◽  
Mutation Rates ◽  
Rapid Progression ◽  
Human T Cell ◽  
Large Numbers ◽  
The Individual ◽  
Multicellular Organisms

High mutation rates are generally considered to be detrimental to the fitness of multicellular organisms because mutations untune finely tuned biological machinery. However, high mutation rates may be favoured by a need to evade an immune system that has been strongly stimulated to recognize those variants that reproduced earlier during the infection, hiv infections conform to this situation because they are characterized by large numbers of viruses that are continually breaking latency and large numbers that are actively replicating throughout a long period of infection. To be transmitted, HIVS are thus generally exposed to an immune system that has been activated to destroy them in response to prior viral replication in the individual. Increases in sexual contact should contribute to this predicament by favouring evolution toward relatively high rates of replication early during infection. Because rapid replication and high mutation rate probably contribute to rapid progression of infections to aids, the interplay of sexual activity, replication rate, and mutation rate helps explain why HIV-1 has only recently caused a lethal pandemic, even though molecular data suggest that it may have been present in humans for more than a century. This interplay also offers an explanation for geographic differences in progression to cancer found among infections due to the other major group of human retroviruses, human T-cell lymphotropic viruses (HTLV). Finally, it suggests ways in which we can use natural selection as a tool to control the aids pandemic and prevent similar pandemics from arising in the future.

Estimation of the species-specific mutation rates at the DRB1 locus in humans and chimpanzee

2006 ◽  
Vol 68 (5) ◽  
pp. 427-431 ◽  
Author(s):  
J. Ohashi ◽  
I. Naka ◽  
A. Toyoda ◽  
M. Takasu ◽  
K. Tokunaga ◽  
...  
Keyword(s):  
Mutation Rates ◽  
Specific Mutation ◽  
Drb1 Locus ◽  
Species Specific

scholarly journals Paternal Age Explains a Major Portion of De Novo Germline Mutation Rate Variability in Healthy Individuals

PLoS ONE ◽  
2016 ◽  
Vol 11 (10) ◽  
pp. e0164212 ◽  
Author(s):  
Simon L. Girard ◽  
Cynthia V. Bourassa ◽  
Louis-Philippe Lemieux Perreault ◽  
Marc-André Legault ◽  
Amina Barhdadi ◽  
...  
Keyword(s):  
Mutation Rate ◽  
Germline Mutation ◽  
De Novo ◽  
Paternal Age ◽  
Major Portion ◽  
Healthy Individuals

scholarly journals De novo mutations across 1,465 diverse genomes reveal novel mutational insights and reductions in the Amish founder population

2019 ◽  
Author(s):  
Michael D. Kessler ◽  
Douglas P. Loesch ◽  
James A. Perry ◽  
Nancy L. Heard-Costa ◽  
Brian E. Cade ◽  
...  
Keyword(s):  
Genetic Variation ◽  
Mutation Rate ◽  
De Novo ◽  
Population Level ◽  
Mutation Rates ◽  
Founder Population ◽  
Single Nucleotide ◽  
Genome Wide ◽  
Nucleotide Mutation ◽  
Rare Genetic Variation

Abstractde novo Mutations (DNMs), or mutations that appear in an individual despite not being seen in their parents, are an important source of genetic variation whose impact is relevant to studies of human evolution, genetics, and disease. Utilizing high-coverage whole genome sequencing data as part of the Trans-Omics for Precision Medicine (TOPMed) program, we directly estimate and analyze DNM counts, rates, and spectra from 1,465 trios across an array of diverse human populations. Using the resulting call set of 86,865 single nucleotide DNMs, we find a significant positive correlation between local recombination rate and local DNM rate, which together can explain up to 35.5% of the genome-wide variation in population level rare genetic variation from 41K unrelated TOPMed samples. While genome-wide heterozygosity does correlate weakly with DNM count, we do not find significant differences in DNM rate between individuals of European, African, and Latino ancestry, nor across ancestrally distinct segments within admixed individuals. However, interestingly, we do find significantly fewer DNMs in Amish individuals compared with other Europeans, even after accounting for parental age and sequencing center. Specifically, we find significant reductions in the number of T→C mutations in the Amish, which seems to underpin their overall reduction in DNMs. Finally, we calculate near-zero estimates of narrow sense heritability (h2), which suggest that variation in DNM rate is significantly shaped by non-additive genetic effects and/or the environment, and that a less mutagenic environment may be responsible for the reduced DNM rate in the Amish.SignificanceHere we provide one of the largest and most diverse human de novo mutation (DNM) call sets to date, and use it to quantify the genome-wide relationship between local mutation rate and population-level rare genetic variation. While we demonstrate that the human single nucleotide mutation rate is similar across numerous human ancestries and populations, we also discover a reduced mutation rate in the Amish founder population, which shows that mutation rates can shift rapidly. Finally, we find that variation in mutation rates is not heritable, which suggests that the environment may influence mutation rates more significantly than previously realized.

scholarly journals Mutation rate dynamics reflect ecological change in an emerging zoonotic pathogen

PLoS Genetics ◽  
2021 ◽  
Vol 17 (11) ◽  
pp. e1009864
Author(s):  
Gemma G. R. Murray ◽  
Andrew J. Balmer ◽  
Josephine Herbert ◽  
Nazreen F. Hadijirin ◽  
Caroline L. Kemp ◽  
...  
Keyword(s):  
Genome Size ◽  
Mutation Rate ◽  
Evolutionary Dynamics ◽  
Bacterial Species ◽  
Invasive Disease ◽  
Mutation Rates ◽  
Ecological Change ◽  
Zoonotic Pathogen ◽  
Wide Range ◽  
The Impact

Mutation rates vary both within and between bacterial species, and understanding what drives this variation is essential for understanding the evolutionary dynamics of bacterial populations. In this study, we investigate two factors that are predicted to influence the mutation rate: ecology and genome size. We conducted mutation accumulation experiments on eight strains of the emerging zoonotic pathogen Streptococcus suis. Natural variation within this species allows us to compare tonsil carriage and invasive disease isolates, from both more and less pathogenic populations, with a wide range of genome sizes. We find that invasive disease isolates have repeatedly evolved mutation rates that are higher than those of closely related carriage isolates, regardless of variation in genome size. Independent of this variation in overall rate, we also observe a stronger bias towards G/C to A/T mutations in isolates from more pathogenic populations, whose genomes tend to be smaller and more AT-rich. Our results suggest that ecology is a stronger correlate of mutation rate than genome size over these timescales, and that transitions to invasive disease are consistently accompanied by rapid increases in mutation rate. These results shed light on the impact that ecology can have on the adaptive potential of bacterial pathogens.

scholarly journals The germline mutational process in rhesus macaque and its implications for phylogenetic dating

2020 ◽  
Author(s):  
Lucie A. Bergeron ◽  
Søren Besenbacher ◽  
Jaco Bakker ◽  
Jiao Zheng ◽  
Panyi Li ◽  
...  
Keyword(s):  
Rhesus Macaque ◽  
Mutation Rate ◽  
De Novo ◽  
Rhesus Macaques ◽  
Average Rate ◽  
Paternal Age ◽  
Divergence Times ◽  
Sequencing Coverage ◽  
Parental Bias ◽  
Mutational Process

AbstractUnderstanding the rate and pattern of germline mutations is of fundamental importance for understanding evolutionary processes. Here we analyzed 19 parent-offspring trios of rhesus macaques (Macaca mulatta) at high sequencing coverage of ca. 76X per individual, and estimated an average rate of 0.77 × 10−8de novo mutations per site per generation (95 % CI: 0.69 × 10−8 - 0.85 × 10−8). By phasing 50 % of the mutations to parental origins, we found that the mutation rate is positively correlated with the paternal age. The paternal lineage contributed an average of 81 % of the de novo mutations, with a trend of an increasing male contribution for older fathers. About 3.5 % of de novo mutations were shared between siblings, with no parental bias, suggesting that they arose from early development (postzygotic) stages. Finally, the divergence times between closely related primates calculated based on the yearly mutation rate of rhesus macaque generally reconcile with divergence estimated with molecular clock methods, except for the Cercopithecidae/Hominoidea molecular divergence dated at 52 Mya using our new estimate of the yearly mutation rate.

scholarly journals Highly accelerated rates of heritable large-scale mutations under prolonged exposure to a metal mixture of copper and nickel

2018 ◽  
Author(s):  
Frédéric J.J. Chain ◽  
Jullien M. Flynn ◽  
James K. Bull ◽  
Melania E. Cristescu
Keyword(s):  
Mutation Rate ◽  
Large Scale ◽  
Prolonged Exposure ◽  
De Novo ◽  
Multiple Stressors ◽  
Copy Number Variations ◽  
Environmental Stressors ◽  
Mutation Rates ◽  
Rate Variation ◽  
Mutational Load

AbstractMutation rate variation has been under intense investigation for decades. Despite these efforts, little is known about the extent to which environmental stressors accelerate mutation rates and influence the genetic load of populations. Moreover, most studies have focused on point mutations rather than large-scale deletions and duplications (copy number variations or “CNVs”). We estimated mutation rates inDaphnia pulexexposed to low levels of environmental stressors as well as the effect of selection onde novomutations. We conducted a mutation accumulation (MA) experiment in which selection was minimized, coupled with an experiment in which a population was propagated under competitive conditions in a benign environment. After an average of 103 generations of MA propagation, we sequenced 60 genomes and found significantly accelerated rates of deletions and duplications in MA lines exposed to ecologically relevant concentrations of metals. Whereas control lines had gene deletion and duplication rates comparable to other multicellular eukaryotes (1.8 × 10−6per gene per generation), a mixture of nickel and copper increased rates fourfold. The realized mutation rate under selection was reduced to 0.4x that of control MA lines, providing evidence that CNVs contribute to mutational load. Our CNV breakpoint analysis revealed that nonhomologous recombination associated with regions of DNA fragility is the primary source of CNVs, plausibly linking metal-induced DNA strand breaks with higher CNV rates. Our findings suggest that environmental stress, in particular multiple stressors, can have profound effects on large-scale mutation rates and mutational load of populations.

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