Testing the basic tenet of the molecular clock and neutral theory by using ancient proteomes

The Genetic Equidistance Phenomenon at the Proteomic Level

10.1101/031914 ◽

2015 ◽

Author(s):

Denghui Luo ◽

Shi Huang

Keyword(s):

Molecular Clock ◽

Ad Hoc ◽

Neutral Theory ◽

Maximum Distance ◽

Complex Species ◽

Molecular Clock Hypothesis ◽

First Results ◽

Small Set ◽

Clock Hypothesis ◽

Genetic Equidistance

The field of molecular evolution started with the alignment of a few protein sequences in the early 1960s. Among the first results found, the genetic equidistance result has turned out to be the most unexpected. It directly inspired the ad hoc universal molecular clock hypothesis that in turn inspired the neutral theory. Unfortunately, however, what is only a maximum distance phenomenon was mistakenly transformed into a mutation rate phenomenon and became known as such. Previous work studied a small set of selected proteins. We have performed proteome wide studies of 7 different sets of proteomes involving a total of 15 species. All 7 sets showed that within each set of 3 species the least complex species is approximately equidistant in average proteome wide identity to the two more complex ones. Thus, the genetic equidistance result is a universal phenomenon of maximum distance. There is a reality of constant albeit stepwise or discontinuous increase in complexity during evolution, the rate of which is what the original molecular clock hypothesis is really about. These results provide additional lines of evidence for the recently proposed maximum genetic diversity (MGD) hypothesis.

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The Rate of Molecular Evolution When Mutation May Not Be Weak

10.1101/259507 ◽

2018 ◽

Cited By ~ 2

Author(s):

A.P. Jason de Koning ◽

Bianca D. De Sanctis

Keyword(s):

Natural Selection ◽

Molecular Evolution ◽

Population Size ◽

Mutation Rate ◽

Molecular Clock ◽

Neutral Theory ◽

Neutral Evolution ◽

Systematic Bias ◽

Effective Population ◽

Sequence Comparisons

AbstractOne of the most fundamental rules of molecular evolution is that the rate of neutral evolution equals the mutation rate and is independent of effective population size. This result lies at the heart of the Neutral Theory, and is the basis for numerous analytic approaches that are widely applied to infer the action of natural selection across the genome and through time, and for dating divergence events using the molecular clock. However, this result was derived under the assumption that evolution is strongly mutation-limited, and it has not been known whether it generalizes across the range of mutation pressures or the spectrum of mutation types observed in natural populations. Validated by both simulations and exact computational analyses, we present a direct and transparent theoretical analysis of the Wright-Fisher model of population genetics, which shows that some of the most important rules of molecular evolution are fundamentally changed by considering recurrent mutation’s full effect. Surprisingly, the rate of the neutral molecular clock is found to have population-size dependence and to not equal the mutation rate in general. This is because, for increasing values of the population mutation rate parameter (θ), the time spent waiting for mutations quickly becomes smaller than the cumulative time mutants spend segregating before a substitution, resulting in a net deceleration compared to classical theory that depends on the population mutation rate. Furthermore, selection exacerbates this effect such that more adaptive alleles experience a greater deceleration than less adaptive alleles, introducing systematic bias in a wide variety of methods for inferring the strength and direction of natural selection from across-species sequence comparisons. Critically, the classical weak mutation approximation performs well only when θ< 0.1, a threshold that many biological populations seem to exceed.

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The genetic equidistance result: misreading by the molecular clock and neutral theory and reinterpretation nearly half of a century later

Science China Life Sciences ◽

10.1007/s11427-013-4452-x ◽

2013 ◽

Vol 56 (3) ◽

pp. 254-261 ◽

Cited By ~ 23

Author(s):

TaoBo Hu ◽

MengPing Long ◽

DeJian Yuan ◽

ZhuBing Zhu ◽

YiMin Huang ◽

...

Keyword(s):

Molecular Clock ◽

Neutral Theory ◽

Genetic Equidistance

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Molecular clock of viral evolution, and the neutral theory.

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.87.24.10015 ◽

1990 ◽

Vol 87 (24) ◽

pp. 10015-10018 ◽

Cited By ~ 118

Author(s):

T. Gojobori ◽

E. N. Moriyama ◽

M. Kimura

Keyword(s):

Molecular Clock ◽

Viral Evolution ◽

Neutral Theory

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Genetic differentiation ofLiparus glabrirostris(Curculionidae: Molytinae) populations from the fragmented habitats of the Alps and Carpathian Mountains

Bulletin of Entomological Research ◽

10.1017/s0007485316000377 ◽

2016 ◽

Vol 106 (5) ◽

pp. 651-662 ◽

Cited By ~ 1

Author(s):

M. Mitrović ◽

Ž. Tomanović ◽

M. Jakovljević ◽

D. Radović ◽

J. Havelka ◽

...

Keyword(s):

Environmental Changes ◽

Elongation Factor ◽

Morphological Characteristics ◽

Genetic Distances ◽

Bootstrap Support ◽

Evolutionary Divergence ◽

Carpathian Mountains ◽

Mitochondrial Haplotypes ◽

Long Time ◽

The Alps

AbstractPopulations ofLiparus glabrirostris(Curculionidae: Molytinae), a weevil inhabiting higher altitudes of Central Europe, were sampled from 24 localities in the Alps and Carpathian Mountains, and the geographical structuring of genetic variation was analyzed. Comparison of the concatenated mitochondrial cytochrome oxidase subunit I and subunit II sequences revealed consistent genetic divergence between the populations ofL. glabrirostrisfrom different mountain ranges. In phylogenetic analysis using maximum parsimony and median-joining networks, concatenated mitochondrial haplotypes from the Alps and Carpathians clustered as separate lineages, with high bootstrap support. Substantial genetic distances determined between the separated groups ranged from 2.6 to 3.0%, with divergence estimated to have initiated approximately 0.85–0.98 million years ago. The nuclear elongation factor 1α gene was additionally amplified and haplotype analysis showed very low evolutionary divergence (0.2%), with separate clustering as well. The observed divergence suggests that the populations have been isolated for a long time, as a consequence of environmental changes resulting in varying fragmentation of habitats in the Alps and Carpathians, interrupting genetic exchange events and altering the genetic structure ofL. glabrirostrispopulations. On the other hand, comparison of morphological characteristics showed no differences to confirm genetically well differentiated groups of populations. A polymerase chain reaction and restriction fragment length polymorphism-based method was therefore developed to discriminate between the Alpine and Carpathian lineages.

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Genetic equidistance at the nucleotide level

10.1101/105072 ◽

2017 ◽

Author(s):

Dejian Yuan ◽

Shi Huang

Keyword(s):

Dna Sequences ◽

Ad Hoc ◽

Nucleotide Level ◽

Complex Species ◽

Molecular Clock Hypothesis ◽

Primary Determinant ◽

Outgroup Taxon ◽

Clock Hypothesis ◽

Genetic Equidistance ◽

Acid Percentage

AbstractThe genetic equidistance phenomenon was first discovered in 1963 by Margoliash and shows complex taxa to be all approximately equidistant to a less complex species in amino acid percentage identity. The result has been mis-interpretated by the ad hoc universal molecular clock hypothesis, and the much overlooked mystery was finally solved by the maximum genetic diversity hypothesis (MGD). Here, we studied 15 proteomes and their coding DNA sequences (CDS) to see if the equidistance phenomenon also holds at the CDS level. We performed DNA alignments for a total of 5 groups with 3 proteomes per group and found that in all cases the outgroup taxon was equidistant to the two more complex taxa species at the DNA level. Also, when two sister taxa (snake and bird) were compared to human as the outgroup, the more complex taxon bird was closer to human, confirming species complexity rather than time to be the primary determinant of MGD. Finally, we found the fraction of overlap sites where coincident substitutions occur to be inversely correlated with CDS conservation, indicating saturation to be more common in less conserved DNAs. These results establish the genetic equidistance phenomenon to be universal at the DNA level and provide additional evidence for the MGD theory.

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Evaluating the Impact of Purifying Selection on Species-level Molecular Dating

10.1101/622209 ◽

2019 ◽

Author(s):

Chong He ◽

Dan Liang ◽

Peng Zhang

Keyword(s):

Molecular Clock ◽

Neutral Theory ◽

Purifying Selection ◽

Selective Constraint ◽

Species Level ◽

Molecular Dating ◽

Substitution Saturation ◽

Time Estimates ◽

Branch Lengths ◽

The Impact

AbstractThe neutral theory of molecular evolution suggests that the constancy of the molecular clock relies on the neutral condition. Thus, purifying selection, the most common type of natural selection, could influence the constancy of the molecular clock, and the use of genes/sites under purifying selection may produce less reliable molecular dating results. However, in current practices of species-level molecular dating, some researchers prefer to select slowly evolving genes/sites to avoid the potential impact of substitution saturation. These genes/sites are generally under a strong influence of purifying selection. Here, from the data of 23 published mammal genomes, we constructed datasets under various selective constraints. We compared the differences in branch lengths and time estimates among these datasets to investigate the impact of purifying selection on species-level molecular dating. We found that as the selective constraint increases, terminal branches are extended, which introduces biases into the result of species-level molecular dating. This result suggests that in species-level molecular dating, the impact of purifying selection should be taken into consideration, and researchers should be more cautious with the use of genes/sites under purifying selection.

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Automated, phylogeny-based genotype delimitation of the Hepatitis Viruses HBV and HCV

PeerJ ◽

10.7717/peerj.7754 ◽

2019 ◽

Vol 7 ◽

pp. e7754

Author(s):

Dora Serdari ◽

Evangelia-Georgia Kostaki ◽

Dimitrios Paraskevis ◽

Alexandros Stamatakis ◽

Paschalia Kapli

Keyword(s):

Species Delimitation ◽

Ad Hoc ◽

Hepatitis Virus ◽

Genetic Distances ◽

Phenotypic Traits ◽

Virus Taxonomy ◽

Hepatitis Viruses ◽

Virus Classification ◽

Distance Methods

Background The classification of hepatitis viruses still predominantly relies on ad hoc criteria, i.e., phenotypic traits and arbitrary genetic distance thresholds. Given the subjectivity of such practices coupled with the constant sequencing of samples and discovery of new strains, this manual approach to virus classification becomes cumbersome and impossible to generalize. Methods Using two well-studied hepatitis virus datasets, HBV and HCV, we assess if computational methods for molecular species delimitation that are typically applied to barcoding biodiversity studies can also be successfully deployed for hepatitis virus classification. For comparison, we also used ABGD, a tool that in contrast to other distance methods attempts to automatically identify the barcoding gap using pairwise genetic distances for a set of aligned input sequences. Results—Discussion We found that the mPTP species delimitation tool identified even without adapting its default parameters taxonomic clusters that either correspond to the currently acknowledged genotypes or to known subdivision of genotypes (subtypes or subgenotypes). In the cases where the delimited cluster corresponded to subtype or subgenotype, there were previous concerns that their status may be underestimated. The clusters obtained from the ABGD analysis differed depending on the parameters used. However, under certain values the results were very similar to the taxonomy and mPTP which indicates the usefulness of distance based methods in virus taxonomy under appropriate parameter settings. The overlap of predicted clusters with taxonomically acknowledged genotypes implies that virus classification can be successfully automated.

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Evolution of New Zealand's Marine Caddisflies: A Phylogenetic and Phylogeographic Assessment of the Chathamiidae (Insecta: Trichoptera)

10.26686/wgtn.17011544 ◽

2021 ◽

Author(s):

◽

Alexander Peter Boast

Keyword(s):

New Zealand ◽

Molecular Clock ◽

Early Pleistocene ◽

Anthropogenic Dispersal ◽

Island Species ◽

South Wales ◽

The Family ◽

Ancient Lineage ◽

Gene Coi ◽

Major Haplogroups

The Chathamiidae are an interesting family of caddisflies, unusual as all of the five known species are believed to breed entirely within the marine intertidal, comprising one of very few known marine insect groups. Additionally the family approaches almost complete endemicity status in New Zealand, and may represent an ancient lineage representative of ancient vicariance from Gondwana. However one species, the common and widespread Philanisus plebeius is also known to have a disjunct population in New South Wales Australia, hypothesised to represent a recent anthropogenic dispersal. This thesis, using DNA information, examined the Chathamiidae at varying phylogenetic levels. Firstly the species Philanisus plebeius was incorporated into a thorough intraspecific phylogeography, including samples from both New Zealand and Australia. The population as a whole was genetically diverse, with the population divisible into two major haplogroups, each restricted to discrete geographic areas with no overlap being observed. One of these groups was restricted to just two localities in the central eastern North Island, whereas the remainder included most remaining samples from both Islands of New Zealand, and also Australia. All Australian samples were found to comprise a single haplotype, differing by a single base pair from the most common haplotype in New Zealand. It was decided that the Australian population therefore represents a recent dispersal event from New Zealand, although unless the Australian haplotype remains undiscovered in New Zealand the level of divergence found is not congruent with a human introduction. One sequence intermediate between the two major haplogroups was identified from a single haplotype from Tauranga. It seemed that much of the population of Philanisus plebeius has been affected by recent demographic expansion, likely due to the effects of the last glacial maximum (LGM). The five species of the Chathamiidae were then analysed in a phylogeny. It was found that the genus Chathamia was polyphyletic, with the species C. integripennis nested within the genus Philanisus. The remaining species, C. brevipennis from the Chatham Islands, was basal to all the remaining members of the family. A strict molecular clock found a recent Pleistocene age (roughly 0.5 Ma) for divergence of the Kermadec Island species Philanisus fasciatus, and a Pliocene-Pleistocene age (roughly 3 Ma) for the Chatham Island species Chathamia brevipennis. For a comparison with the species C. brevipennis, the other Chatham Island caddisfly taxa Oecetis chathamensis, and Hydrobiosis lindsayi were compared with New Zealand relatives; indicated to have late and early Pleistocene ages respectively. A short sequence of the gene COI was amplified for the species Philanisus mataua, however this was found to contain two sequences reflecting either heteroplasmy or sample contamination, inhibiting confident phylogenetic placement. Additionally a larval sample from Sydney was demonstrated to represent C. integripennis, recorded outside of Northern New Zealand for the first time. Finally the Chathamiidae was included in a higher level phylogeny with related families, and was show to comprise a monophyletic group, sister to the Australasian family of the Conoesucidae. A relaxed molecular clock estimated a Cretaceous (roughly 90 Ma) age for the Chathamiidae, congruent with a vicariant age in New Zealand.

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Evolution of New Zealand's Marine Caddisflies: A Phylogenetic and Phylogeographic Assessment of the Chathamiidae (Insecta: Trichoptera)

10.26686/wgtn.17011544.v1 ◽

2021 ◽

Author(s):

◽

Alexander Peter Boast

Keyword(s):

New Zealand ◽

Molecular Clock ◽

Early Pleistocene ◽

Anthropogenic Dispersal ◽

Island Species ◽

South Wales ◽

The Family ◽

Ancient Lineage ◽

Gene Coi ◽

Major Haplogroups

The Chathamiidae are an interesting family of caddisflies, unusual as all of the five known species are believed to breed entirely within the marine intertidal, comprising one of very few known marine insect groups. Additionally the family approaches almost complete endemicity status in New Zealand, and may represent an ancient lineage representative of ancient vicariance from Gondwana. However one species, the common and widespread Philanisus plebeius is also known to have a disjunct population in New South Wales Australia, hypothesised to represent a recent anthropogenic dispersal. This thesis, using DNA information, examined the Chathamiidae at varying phylogenetic levels. Firstly the species Philanisus plebeius was incorporated into a thorough intraspecific phylogeography, including samples from both New Zealand and Australia. The population as a whole was genetically diverse, with the population divisible into two major haplogroups, each restricted to discrete geographic areas with no overlap being observed. One of these groups was restricted to just two localities in the central eastern North Island, whereas the remainder included most remaining samples from both Islands of New Zealand, and also Australia. All Australian samples were found to comprise a single haplotype, differing by a single base pair from the most common haplotype in New Zealand. It was decided that the Australian population therefore represents a recent dispersal event from New Zealand, although unless the Australian haplotype remains undiscovered in New Zealand the level of divergence found is not congruent with a human introduction. One sequence intermediate between the two major haplogroups was identified from a single haplotype from Tauranga. It seemed that much of the population of Philanisus plebeius has been affected by recent demographic expansion, likely due to the effects of the last glacial maximum (LGM). The five species of the Chathamiidae were then analysed in a phylogeny. It was found that the genus Chathamia was polyphyletic, with the species C. integripennis nested within the genus Philanisus. The remaining species, C. brevipennis from the Chatham Islands, was basal to all the remaining members of the family. A strict molecular clock found a recent Pleistocene age (roughly 0.5 Ma) for divergence of the Kermadec Island species Philanisus fasciatus, and a Pliocene-Pleistocene age (roughly 3 Ma) for the Chatham Island species Chathamia brevipennis. For a comparison with the species C. brevipennis, the other Chatham Island caddisfly taxa Oecetis chathamensis, and Hydrobiosis lindsayi were compared with New Zealand relatives; indicated to have late and early Pleistocene ages respectively. A short sequence of the gene COI was amplified for the species Philanisus mataua, however this was found to contain two sequences reflecting either heteroplasmy or sample contamination, inhibiting confident phylogenetic placement. Additionally a larval sample from Sydney was demonstrated to represent C. integripennis, recorded outside of Northern New Zealand for the first time. Finally the Chathamiidae was included in a higher level phylogeny with related families, and was show to comprise a monophyletic group, sister to the Australasian family of the Conoesucidae. A relaxed molecular clock estimated a Cretaceous (roughly 90 Ma) age for the Chathamiidae, congruent with a vicariant age in New Zealand.

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