Genetic conflicts during meiosis and the evolutionary origins of centromere complexity

2006 ◽  
Vol 34 (4) ◽  
pp. 569-573 ◽  
Author(s):  
H.S. Malik ◽  
J.J. Bayes
Keyword(s):  
Positive Selection ◽  
Dna Sequence ◽  
Rapid Evolution ◽  
Genetic Conflict ◽  
Centromeric Dna ◽  
Preferential Transmission ◽  
Evolutionary Origins ◽  
Genetic Conflicts ◽  
Centromere Drive

Centromeric DNA evolves rapidly, ranging in size and complexity over several orders of magnitude. Traditional attempts at studying centromeres have left unexplained the causes underlying this complexity and rapid evolution. Instead of directly studying centromeric DNA sequence, our approach has been to study the proteins that epigenetically determine centromere identity. We have discovered that centromeric histones (CenH3s) have evolved under positive selection in multiple lineages, suggesting an involvement in recurrent genetic conflict. Our hypothesis is that ‘centromere-drive’ is the source of this conflict. Under this model, centromeres compete via microtubule attachments for preferential transmission in female meioses occurring in animals and plants. Since only one of four meiotic products will become the egg, this competition confers a selfish advantage to chromosomes that can make more microtubule attachments, resulting in runaway expansions of centromeric satellites. While beneficial to the ‘driving’ chromosome, these expansions can have deleterious effects on the fitness of an organism and of the species. CenH3s as well as other heterochromatin proteins have evolved under positive selection to suppress the deleterious consequences of ‘centromere-drive’ by restoring meiotic parity.

scholarly journals Conflicts with diarrheal pathogens trigger rapid evolution of an intestinal signaling axis

2020 ◽  
Author(s):  
Clayton M. Carey ◽  
Sarah E. Apple ◽  
Zoё A. Hilbert ◽  
Michael S. Kay ◽  
Nels C. Elde
Keyword(s):  
Positive Selection ◽  
Rapid Evolution ◽  
Genetic Conflict ◽  
Selective Pressures ◽  
Heat Stable ◽  
Guanylate Cyclase C ◽  
Signaling Axis ◽  
History Of ◽  
Water Secretion

AbstractThe pathogenesis of infectious diarrheal diseases is largely attributed to enterotoxin proteins that disrupt intestinal water absorption, causing severe dehydration. Despite profound health consequences, the impacts of diarrhea-causing microbes on the evolutionary history of host species are largely unknown. We investigated patterns of genetic variation in mammalian Guanylate Cyclase-C (GC-C), an intestinal receptor frequently targeted by bacterial enterotoxins, to determine how hosts might adapt in response to diarrheal infections. Under normal conditions, GC-C interacts with endogenous guanylin peptides to promote water secretion in the intestine, but signaling can be hijacked by bacterially-encoded heat-stable enterotoxins (STa) during infection, which leads to overstimulation of GC-C and diarrhea. Phylogenetic analysis in mammals revealed evidence of recurrent positive selection in the GC-C ligand-binding domain in primates and bats, consistent with selective pressures to evade interactions with STa. Using in vitro assays and transgenic intestinal organoids to model STa-mediated diarrhea, we show that GC-C diversification in these lineages results in substantial variation in toxin susceptibility. In bats, we observe a unique pattern of compensatory coevolution in the endogenous GC-C ligand uroguanylin, reflecting intense bouts of positive selection at the receptor-ligand interface. These findings demonstrate control of water physiology as a previously unrecognized interface for genetic conflict and reveal diarrheal pathogens as a source of selective pressure among diverse mammals.

scholarly journals Rapid evolution at the Drosophila telomere: transposable element dynamics at an intrinsically unstable locus

Genetics ◽  
2020 ◽  
Vol 217 (2) ◽  
Author(s):  
Michael P McGurk ◽  
Anne-Marie Dion-Côté ◽  
Daniel A Barbash
Keyword(s):  
Copy Number ◽  
Large Scale ◽  
Insertion Site ◽  
Rapid Evolution ◽  
Interspecific Variation ◽  
High Rate ◽  
Evolutionary Strategy ◽  
Control Mechanisms ◽  
Genetic Conflict ◽  
Number Variation

AbstractDrosophila telomeres have been maintained by three families of active transposable elements (TEs), HeT-A, TAHRE, and TART, collectively referred to as HTTs, for tens of millions of years, which contrasts with an unusually high degree of HTT interspecific variation. While the impacts of conflict and domestication are often invoked to explain HTT variation, the telomeres are unstable structures such that neutral mutational processes and evolutionary tradeoffs may also drive HTT evolution. We leveraged population genomic data to analyze nearly 10,000 HTT insertions in 85  Drosophila melanogaster genomes and compared their variation to other more typical TE families. We observe that occasional large-scale copy number expansions of both HTTs and other TE families occur, highlighting that the HTTs are, like their feral cousins, typically repressed but primed to take over given the opportunity. However, large expansions of HTTs are not caused by the runaway activity of any particular HTT subfamilies or even associated with telomere-specific TE activity, as might be expected if HTTs are in strong genetic conflict with their hosts. Rather than conflict, we instead suggest that distinctive aspects of HTT copy number variation and sequence diversity largely reflect telomere instability, with HTT insertions being lost at much higher rates than other TEs elsewhere in the genome. We extend previous observations that telomere deletions occur at a high rate, and surprisingly discover that more than one-third do not appear to have been healed with an HTT insertion. We also report that some HTT families may be preferentially activated by the erosion of whole telomeres, implying the existence of HTT-specific host control mechanisms. We further suggest that the persistent telomere localization of HTTs may reflect a highly successful evolutionary strategy that trades away a stable insertion site in order to have reduced impact on the host genome. We propose that HTT evolution is driven by multiple processes, with niche specialization and telomere instability being previously underappreciated and likely predominant.

scholarly journals Cause and Effectors: Whole-Genome Comparisons Reveal Shared but Rapidly Evolving Effector Sets among Host-Specific Plant-Castrating Fungi

mBio ◽  
2019 ◽  
Vol 10 (6) ◽  
Author(s):  
William C. Beckerson ◽  
Ricardo C. Rodríguez de la Vega ◽  
Fanny E. Hartmann ◽  
Marine Duhamel ◽  
Tatiana Giraud ◽  
...  
Keyword(s):  
Positive Selection ◽  
Plant Pathogens ◽  
Pfam Domain ◽  
Rapid Evolution ◽  
Host Specialization ◽  
Secreted Proteins ◽  
Smut Fungi ◽  
Core Proteins ◽  
Genes Encoding ◽  
Species Specific

ABSTRACT Plant pathogens utilize a portfolio of secreted effectors to successfully infect and manipulate their hosts. It is, however, still unclear whether changes in secretomes leading to host specialization involve mostly effector gene gains/losses or changes in their sequences. To test these hypotheses, we compared the secretomes of three host-specific castrating anther smut fungi (Microbotryum), two being sister species. To address within-species evolution, which might involve coevolution and local adaptation, we compared the secretomes of strains from differentiated populations. We experimentally validated a subset of signal peptides. Secretomes ranged from 321 to 445 predicted secreted proteins (SPs), including a few species-specific proteins (42 to 75), and limited copy number variation, i.e., little gene family expansion or reduction. Between 52% and 68% of the SPs did not match any Pfam domain, a percentage that reached 80% for the small secreted proteins, indicating rapid evolution. In comparison to background genes, we indeed found SPs to be more differentiated among species and strains, more often under positive selection, and highly expressed in planta; repeat-induced point mutations (RIPs) had no role in effector diversification, as SPs were not closer to transposable elements than background genes and were not more RIP affected. Our study thus identified both conserved core proteins, likely required for the pathogenic life cycle of all Microbotryum species, and proteins that were species specific or evolving under positive selection; these proteins may be involved in host specialization and/or coevolution. Most changes among closely related host-specific pathogens, however, involved rapid changes in sequences rather than gene gains/losses. IMPORTANCE Plant pathogens use molecular weapons to successfully infect their hosts, secreting a large portfolio of various proteins and enzymes. Different plant species are often parasitized by host-specific pathogens; however, it is still unclear whether the molecular basis of such host specialization involves species-specific weapons or different variants of the same weapons. We therefore compared the genes encoding secreted proteins in three plant-castrating pathogens parasitizing different host plants, producing their spores in plant anthers by replacing pollen. We validated our predictions for secretion signals for some genes and checked that our predicted secreted proteins were often highly expressed during plant infection. While we found few species-specific secreted proteins, numerous genes encoding secreted proteins showed signs of rapid evolution and of natural selection. Our study thus found that most changes among closely related host-specific pathogens involved rapid adaptive changes in shared molecular weapons rather than innovations for new weapons.

scholarly journals Widespread nocturnality of living birds stemming from their common ancestor

2019 ◽  
Vol 19 (1) ◽  
Author(s):  
Yonghua Wu
Keyword(s):  
Positive Selection ◽  
Common Ancestor ◽  
Activity Patterns ◽  
Bright Light ◽  
Night Vision ◽  
Diel Activity ◽  
Divergent Evolution ◽  
Nocturnal Activity ◽  
Evolutionary Origins ◽  
Diel Activity Patterns

Abstract Background Many living birds exhibit some nocturnal activity, but the genetic basis and evolutionary origins of their nocturnality remain unknown. Results Here, we used a molecular phyloecological approach to analyze the adaptive evolution of 33 phototransduction genes in diverse bird lineages. Our results suggest that functional enhancement of two night-vision genes, namely, GRK1 and SLC24A1, underlies the nocturnal adaption of living birds. Further analyses showed that the diel activity patterns of birds have remained relatively unchanged since their common ancestor, suggesting that the widespread nocturnal activity of many living birds may largely stem from their common ancestor rather than independent evolution. Despite this evolutionary conservation of diel activity patterns in birds, photoresponse recovery genes were found to be frequently subjected to positive selection in diverse bird lineages, suggesting that birds generally have evolved an increased capacity for motion detection. Moreover, we detected positive selection on both dim-light vision genes and bright-light vision genes in the class Aves, suggesting divergent evolution of the vision of birds from that of reptiles and that different bird lineages have evolved certain visual adaptions to their specific light conditions. Conclusions This study suggests that the widespread nocturnality of extant birds has a deep evolutionary origin tracing back to their common ancestor.

scholarly journals Evolutionary origins and diversification of testis-specific short histone H2A variants in mammals

2017 ◽  
Author(s):  
Antoine Molaro ◽  
Janet M. Young ◽  
Harmit S. Malik
Keyword(s):  
Genome Stability ◽  
Histone Variants ◽  
Histone Variant ◽  
Histone H2a ◽  
Genetic Conflict ◽  
Post Translational Modifications ◽  
Evolutionary Origins ◽  
Male Germline ◽  
Early Diversification ◽  
Canonical Histone

Eukaryotic genomes must accomplish the tradeoff between compact packaging for genome stability and inheritance, and accessibility for gene expression. They do so using post-translational modifications of four ancient canonical histone proteins (H2A, H2B, H3 and H4), and by deploying histone variants with specialized chromatin functions. While some histone variants are highly conserved across eukaryotes, others carry out lineage-specific functions. Here, we characterize the evolution of male germline-specific “short H2A variants”, which wrap shorter DNA fragments than canonical H2A. In addition to three previously described H2A.B, H2A.L and H2A.P variants, we describe a novel, extremely short H2A histone variant: H2A.Q. We show that H2A.B, H2A.L, H2A.P and H2A.Q are most closely related to a novel, more canonical mmH2A variant found only in monotremes and marsupials. Using phylogenomics, we trace the origins and early diversification of short histone variants into four distinct clades to the ancestral X chromosome of placental mammals. We show that short H2A variants further diversified by repeated lineage-specific amplifications and losses, including pseudogenization of H2A.L in many primates. We also uncover evidence for concerted evolution of H2A.B and H2A.L genes by gene conversion in many species, involving loci separated by large distances. Finally, we find that short H2As evolve more rapidly than any other histone variant, with evidence that positive selection has acted upon H2A.P in primates. Based on their X chromosomal location and pattern of genetic innovation, we speculate that short H2A histone variants are engaged in a form of genetic conflict involving the mammalian sex chromosomes.

scholarly journals Antimicrobial functions of lactoferrin promote genetic conflicts in ancient primates and modern humans

2016 ◽  
Author(s):  
Matthew F. Barber ◽  
Zev N. Kronenberg ◽  
Mark Yandell ◽  
Nels C. Elde
Keyword(s):  
Positive Selection ◽  
Pathogenic Bacteria ◽  
Modern Human ◽  
Human Populations ◽  
Human Genetic Variation ◽  
Cationic Protein ◽  
Protein Functions ◽  
Genetic Conflicts ◽  
New Protein

Lactoferrin is a multifunctional mammalian immunity protein that limits microbial growth through sequestration of nutrient iron. Additionally, lactoferrin possesses cationic protein domains that directly bind and inhibit diverse microbes. The implications for these dual functions on lactoferrin evolution and genetic conflicts with pathogens remain unclear. Here we show that lactoferrin has been subject to recurrent episodes of positive selection during primate divergence predominately at antimicrobial peptide surfaces consistent with long-term antagonism by pathogens. An abundant lactoferrin polymorphism in human populations and Neanderthals also exhibits signatures of positive selection across primates, linking ancient host-microbe conflicts to modern human genetic variation. Rapidly evolving sites in lactoferrin further correspond to molecular interfaces with pathogenic bacteria causing meningitis, pneumonia, and sepsis. Because microbes actively target lactoferrin to acquire iron, we propose that the emergence of antimicrobial activity provided a pivotal mechanism of adaptation sparking evolutionary conflicts via acquisition of new protein functions.

scholarly journals Molecular and evolutionary strategies of meiotic cheating by selfish centromeres

2018 ◽  
Author(s):  
Takashi Akera ◽  
Emily Trimm ◽  
Michael A. Lampson
Keyword(s):  
Polar Body ◽  
Rapid Evolution ◽  
Meiotic Spindle ◽  
Evolutionary Strategies ◽  
General Strategy ◽  
Meiotic Progression ◽  
Centromere Function ◽  
Destabilizing Factors ◽  
Spindle Microtubules ◽  
Centromere Drive

SummaryAsymmetric division in female meiosis creates selective pressure favoring selfish centromeres that bias their transmission to the egg. This centromere drive can explain the paradoxical rapid evolution of both centromere DNA and centromere-binding proteins despite conserved centromere function. Here, we define a molecular pathway linking expanded centromeres to histone phosphorylation and recrui™ent of microtubule destabilizing factors in an intraspecific hybrid, leading to detachment of selfish centromeres from spindle microtubules that would direct them to the polar body. We also introduce a second hybrid model, exploiting centromere divergence between species, and show that winning centromeres in one hybrid become losers in the other. Our results indicate that increasing destabilizing activity is a general strategy for drive, but centromeres have evolved distinct strategies to increase that activity. Furthermore, we show that drive depends on slowing meiotic progression, suggesting that a weakened meiotic spindle checkpoint evolved as a mechanism to suppress selfish centromeres.

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