Disparity mutagenesis model possesses the ability to realize both stable and rapid evolution in response to changing environments without altering mutation rates.

AbstractHIV-1 has high mutation rates and exists as mutant swarms in the host. Rapid evolution of HIV-1 allows the virus to outpace host immune system, leading to viral persistence. Novel approaches to target immutable components are needed to clear HIV-1 infection. Here we report a pattern-recognition receptor CARD8 that senses enzymatic activity of the HIV-1 protease, which is indispensable for the virus. All subtypes of HIV-1 can be sensed by CARD8 despite substantial viral diversity. HIV-1 evades CARD8 sensing because the viral protease remains inactive in infected cells prior to viral budding. Induction of premature intracellular activation of the viral protease triggers CARD8 inflammasome-mediated pyroptosis of HIV-1-infected cells. This strategy leads to clearance of latent HIV-1 in patient CD4+ T cells after virus reactivation. Taken together, our study identifies CARD8 as an inflammasome sensor of HIV-1 that holds promise as a strategy for clearance of persistent HIV-1 infection.

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Rapid evolution of the human mutation spectrum

10.1101/084343 ◽

2016 ◽

Cited By ~ 5

Author(s):

Kelley Harris ◽

Jonathan K. Pritchard

Keyword(s):

Mutation Rate ◽

Genetic Modifier ◽

Rapid Evolution ◽

Biological Information ◽

Mutation Rates ◽

Specific Sequence ◽

Mutational Spectra ◽

Damage Repair ◽

Human Mutation ◽

System Selection

AbstractDNA is a remarkably precise medium for copying and storing biological information. This high fidelity results from the action of hundreds of genes involved in replication, proofreading, and damage repair. Evolutionary theory suggests that in such a system, selection has limited ability to remove genetic variants that change mutation rates by small amounts or in specific sequence contexts. Consistent with this, using SNV variation as a proxy for mutational input, we report here that mutational spectra differ substantially among species, human continental groups and even some closely-related populations. Close examination of one signal, an increased TCC→TTC mutation rate in Europeans, indicates a burst of mutations from about 15,000 to 2,000 years ago, perhaps due to the appearance, drift, and ultimate elimination of a genetic modifier of mutation rate. Our results suggest that mutation rates can evolve markedly over short evolutionary timescales and suggest the possibility of mapping mutational modifiers.

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Selection constrains high rates of satellite DNA mutation in Daphnia pulex

10.1101/156554 ◽

2017 ◽

Author(s):

Jullien M. Flynn ◽

Ian Caldas ◽

Melania E. Cristescu ◽

Andrew G. Clark

Keyword(s):

Satellite Dna ◽

Related Species ◽

Rapid Evolution ◽

Daphnia Pulex ◽

Selective Constraint ◽

Mutation Rates ◽

Stabilizing Selection ◽

Closely Related Species ◽

Dna Mutation ◽

Evolutionary Forces

AbstractA long-standing evolutionary puzzle is that all eukaryotic genomes contain large amounts of tandemly-repeated satellite DNA whose composition varies greatly among even closely related species. To elucidate the evolutionary forces governing satellite dynamics, quantification of the rates and patterns of mutations in satellite DNA copy number and tests of its selective neutrality are necessary. Here we used whole-genome sequences of 28 mutation accumulation (MA) lines of Daphnia pulex in addition to six isolates from a non-MA population originating from the same progenitor to both estimate mutation rates of abundances of satellite sequences and evaluate the selective regime acting upon them. We found that mutation rates of individual satellite sequence “kmers” were both high and highly variable, ranging from additions/deletions of 0.29 – 105 copies per generation (reflecting changes of 0.12 - 0.80 percent per generation). Our results also provide evidence that new kmer sequences are often formed from existing ones. The non-MA population isolates showed a signal of either purifying or stabilizing selection, with 33 % lower variation in kmer abundance on average than the MA lines, although the level of selective constraint was not evenly distributed across all kmers. The changes between many pairs of kmers were correlated, and the pattern of correlations was significantly different between the MA lines and the non-MA population. Our study demonstrates that kmer sequences can experience extremely rapid evolution in abundance, which can lead to high levels of divergence in genome-wide satellite DNA composition between closely related species.

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A Mobile Element in mutS Drives Hypermutation in a Marine Vibrio

mBio ◽

10.1128/mbio.02045-16 ◽

2017 ◽

Vol 8 (1) ◽

Cited By ~ 9

Author(s):

Nathaniel D. Chu ◽

Sean A. Clarke ◽

Sonia Timberlake ◽

Martin F. Polz ◽

Alan D. Grossman ◽

...

Keyword(s):

Marine Bacterium ◽

Mobile Element ◽

Mobile Elements ◽

Mutation Rates ◽

Vibrio Splendidus ◽

Trade Off ◽

Changing Environments ◽

Dna Mutations ◽

Translation Start ◽

Genetic Sequences

ABSTRACT Bacteria face a trade-off between genetic fidelity, which reduces deleterious mistakes in the genome, and genetic innovation, which allows organisms to adapt. Evidence suggests that many bacteria balance this trade-off by modulating their mutation rates, but few mechanisms have been described for such modulation. Following experimental evolution and whole-genome resequencing of the marine bacterium Vibrio splendidus 12B01, we discovered one such mechanism, which allows this bacterium to switch to an elevated mutation rate. This switch is driven by the excision of a mobile element residing in mutS, which encodes a DNA mismatch repair protein. When integrated within the bacterial genome, the mobile element provides independent promoter and translation start sequences for mutS—different from the bacterium’s original mutS promoter region—which allow the bacterium to make a functional mutS gene product. Excision of this mobile element rejoins the mutS gene with host promoter and translation start sequences but leaves a 2-bp deletion in the mutS sequence, resulting in a frameshift and a hypermutator phenotype. We further identified hundreds of clinical and environmental bacteria across Betaproteobacteria and Gammaproteobacteria that possess putative mobile elements within the same amino acid motif in mutS. In a subset of these bacteria, we detected excision of the element but not a frameshift mutation; the mobile elements leave an intact mutS coding sequence after excision. Our findings reveal a novel mechanism by which one bacterium alters its mutation rate and hint at a possible evolutionary role for mobile elements within mutS in other bacteria. IMPORTANCE DNA mutations are a double-edged sword. Most mutations are harmful; they can scramble precise genetic sequences honed over thousands of generations. However, in rare cases, mutations also produce beneficial new traits that allow populations to adapt to changing environments. Recent evidence suggests that some bacteria balance this trade-off by altering their mutation rates to suit their environment. To date, however, we know of few mechanisms that allow bacteria to change their mutation rates. We describe one such mechanism, driven by the action of a mobile element, in the marine bacterium Vibrio splendidus 12B01. We also found similar mobile genetic sequences in the mutS genes of many different bacteria, including clinical and agricultural pathogens. These mobile elements might play an as yet unknown role in the evolution of these important bacteria. IMPORTANCE DNA mutations are a double-edged sword. Most mutations are harmful; they can scramble precise genetic sequences honed over thousands of generations. But in rare cases, mutations also produce beneficial new traits that allow populations to adapt to changing environments. Recent evidence suggests that some bacteria balance this trade-off by altering their mutation rates to suit their environment. To date, however, we know of few mechanisms that allow bacteria to change their mutation rates. We describe one such mechanism, driven by the action of a mobile element, in the marine bacterium Vibrio splendidus 12B01. We also found similar mobile genetic sequences in the mutS genes of many different bacteria, including clinical and agricultural pathogens. These mobile elements might play an as yet unknown role in the evolution of these important bacteria.

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CARD8 is an inflammasome sensor for HIV-1 protease activity

Science ◽

10.1126/science.abe1707 ◽

2021 ◽

Vol 371 (6535) ◽

pp. eabe1707 ◽

Cited By ~ 2

Author(s):

Qiankun Wang ◽

Hongbo Gao ◽

Kolin M. Clark ◽

Christian Shema Mugisha ◽

Keanu Davis ◽

...

Keyword(s):

Protease Activity ◽

Rapid Evolution ◽

Viral Persistence ◽

Viral Reactivation ◽

Mutation Rates ◽

Host Immune System ◽

Viral Budding ◽

Infected Cells ◽

Latent Hiv ◽

Hiv 1

HIV-1 has high mutation rates and exists as mutant swarms within the host. Rapid evolution of HIV-1 allows the virus to outpace the host immune system, leading to viral persistence. Approaches to targeting immutable components are needed to clear HIV-1 infection. Here, we report that the caspase recruitment domain–containing protein 8 (CARD8) inflammasome senses HIV-1 protease activity. HIV-1 can evade CARD8 sensing because its protease remains inactive in infected cells before viral budding. Premature intracellular activation of the viral protease triggered CARD8 inflammasome–mediated pyroptosis of HIV-1–infected cells. This strategy led to the clearance of latent HIV-1 in patient CD4+ T cells after viral reactivation. Thus, our study identifies CARD8 as an inflammasome sensor of HIV-1, which holds promise as a strategy for the clearance of persistent HIV-1 infection.

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Phylogenetic Evidence for the Rapid Evolution of Human B19 Erythrovirus

Journal of Virology ◽

10.1128/jvi.80.7.3666-3669.2006 ◽

2006 ◽

Vol 80 (7) ◽

pp. 3666-3669 ◽

Cited By ~ 101

Author(s):

Laura A. Shackelton ◽

Edward C. Holmes

Keyword(s):

Host Cell ◽

Evolutionary Dynamics ◽

Rna Viruses ◽

Rapid Evolution ◽

Evolutionary Change ◽

High Rate ◽

Mutation Rates ◽

Genome Replication ◽

Nucleotide Substitutions ◽

Viral Pathogen

ABSTRACT Human B19 erythrovirus is a ubiquitous viral pathogen, commonly infecting individuals before adulthood. As with all autonomous parvoviruses, its small single-stranded DNA genome is replicated with host cell machinery. While the mechanism of parvovirus genome replication has been studied in detail, the rate at which B19 virus evolves is unknown. By inferring the phylogenetic history and evolutionary dynamics of temporally sampled B19 sequences, we observed a surprisingly high rate of evolutionary change, at approximately 10−4 nucleotide substitutions per site per year. This rate is more typical of RNA viruses and suggests that high mutation rates are characteristic of the Parvoviridae.

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The population genetics of mutations: good, bad and indifferent

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2009.0317 ◽

2010 ◽

Vol 365 (1544) ◽

pp. 1153-1167 ◽

Cited By ~ 74

Author(s):

Laurence Loewe ◽

William G. Hill

Keyword(s):

Population Genetics ◽

Dna Sequences ◽

Quantitative Traits ◽

Current Knowledge ◽

Raw Materials ◽

Mutation Rates ◽

Beneficial Effects ◽

Changing Environments ◽

The Past ◽

Review Current

Population genetics is fundamental to our understanding of evolution, and mutations are essential raw materials for evolution. In this introduction to more detailed papers that follow, we aim to provide an oversight of the field. We review current knowledge on mutation rates and their harmful and beneficial effects on fitness and then consider theories that predict the fate of individual mutations or the consequences of mutation accumulation for quantitative traits. Many advances in the past built on models that treat the evolution of mutations at each DNA site independently, neglecting linkage of sites on chromosomes and interactions of effects between sites (epistasis). We review work that addresses these limitations, to predict how mutations interfere with each other. An understanding of the population genetics of mutations of individual loci and of traits affected by many loci helps in addressing many fundamental and applied questions: for example, how do organisms adapt to changing environments, how did sex evolve, which DNA sequences are medically important, why do we age, which genetic processes can generate new species or drive endangered species to extinction, and how should policy on levels of potentially harmful mutagens introduced into the environment by humans be determined?

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The mutation rates and mutational bias of influenza A virus

10.1101/110197 ◽

2017 ◽

Cited By ~ 4

Author(s):

Matthew D. Pauly ◽

Megan Procario ◽

Adam S. Lauring

Keyword(s):

Influenza Virus ◽

Influenza A Virus ◽

Mutation Rate ◽

Influenza A ◽

Rapid Evolution ◽

Viral Fitness ◽

High Mutation Rate ◽

Mutation Rates ◽

Mutational Bias ◽

Neutral Mutations

AbstractInfluenza virus has a high mutation rate, and this low replicative fidelity contributes to its capacity for rapid evolution. Clonal sequencing and fluctuation tests have suggested that the mutation rate of influenza A virus is 7.1 × 10−6− 4.5 × 10−5substitutions per nucleotide per cell infection cycle and 2.7 × 10−6− 3.0 × 10−5substitutions per nucleotide per strand copied (s/n/r). However, sequencing assays are biased toward mutations with minimal impacts on viral fitness and fluctuation tests typically investigate only a subset of the twelve mutational classes. We developed a fluctuation test based on reversion to fluorescence in a set of virally encoded mutant green fluorescent proteins. This method allowed us to measure the rates of selectively neutral mutations representative of all 12 mutational classes in the context of an unstructured RNA. We measured an overall mutation rate of 1.8 × 10−4s/n/r for PR8 (H1N1) and 2.5 × 10−4s/n/r for Hong Kong 2014 (H3N2). The replication mode was linear. The mutation rates of these divergent strains are significantly higher than previous estimates and suggest that each replicated genome will have an average of 2-3 mutations. The viral mutational spectrum is heavily biased toward A to G and U to C transitions, resulting in a transition to transversion bias of 2.7 and 3.6 for the two strains. These mutation rates were relatively constant over a range of physiological temperatures. Our high-resolution analysis of influenza virus mutation rates will enable more refined models of its molecular evolution.SignificanceThe rapid evolution of influenza virus is a major problem in public health. A key factor driving this rapid evolution is the virus’ very high mutation rate. We developed a new method for measuring the rates of all 12 mutational classes in influenza virus, which eliminates some of the biases of existing assays. We find that the influenza virus mutation rate is much higher than previously reported and is consistent across two distinct strains and a range of temperatures. Our data suggest that influenza viruses replicate at their maximally tolerable mutation rates, highlighting both the virus’ evolutionary potential and its significant constraints.

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