Your search keyword '"Parallel evolution"' showing total 2,938 results

101. Genome-wide selection signatures reveal widespread synergistic effects of two different stressors in Drosophila melanogaster.

Author

Burny, Claire, Nolte, Viola, Dolezal, Marlies, and Schlötterer, Christian

Subjects

*DROSOPHILA melanogaster, *BODY temperature regulation, *TEMPERATURE effect, *GENETIC variation, *EXTREME environments, *DROSOPHILIDAE, *DROSOPHILA

Abstract

Experimental evolution combined with whole-genome sequencing (evolve and resequence (E&R)) is a powerful approach to study the adaptive architecture of selected traits. Nevertheless, so far the focus has been on the selective response triggered by a single stressor. Building on the highly parallel selection response of founder populations with reduced variation, we evaluated how the presence of a second stressor affects the genomic selection response. After 20 generations of adaptation to laboratory conditions at either 18°C or 29°C, strong genome-wide selection signatures were observed. Only 38% of the selection signatures can be attributed to laboratory adaptation (no difference between temperature regimes). The remaining selection responses are either caused by temperature-specific effects, or reflect the joint effects of temperature and laboratory adaptation (same direction, but the magnitude differs between temperatures). The allele frequency changes resulting from the combined effects of temperature and laboratory adaptation were more extreme in the hot environment for 83% of the affected genomic regions—indicating widespread synergistic effects of the two stressors. We conclude that E&R with reduced genetic variation is a powerful approach to study genome-wide fitness consequences driven by the combined effects of multiple environmental factors. [ABSTRACT FROM AUTHOR]

Published

2022

102. Detecting bacterial adaptation within individual microbiomes.

Author

Lieberman, Tami D.

Subjects

*BACTERIAL adaptation, *HUMAN microbiota, *DRUG metabolism, *PHYSIOLOGICAL adaptation, *COMMUNITIES, *IMMUNE system, *COMMENSALISM

Abstract

The human microbiome harbours a large capacity for within-person adap)tive mutations. Commensal bacterial strains can stably colonize a person for decades, and billions of mutations are generated daily within each person’s microbiome. Adaptive mutations emerging during health might be driven by selective forces that vary across individuals, vary within an individual, or are completely novel to the human population. Mutations emerging within individual microbiomes might impact the immune system, the metabolism of nutrients or drugs, and the stability of the community to perturbations. Despite this potential, relatively little attention has been paid to the possibility of adaptive evolution within complex human-associated microbiomes. This review discusses the promise of studying within)microbiome adaptation, the conceptual and technical limitations that may have contributed to an underappreciation of adaptive de novo mutations occurring within microbiomes to date, and methods for detecting recent adaptive evolution. [ABSTRACT FROM AUTHOR]

Published

2022

103. Repeated colonization of alpine habitats by Arabidopsis arenosa viewed through freezing resistance and ice management strategies.

Author

Kaplenig, D., Bertel, C., Arc, E., Villscheider, R., Ralser, M., Kolář, F., Wos, G., Hülber, K., Kranner, I., Neuner, G., and Byers, D.

Subjects

*COLONIZATION (Ecology), *FREEZING, *FREEZES (Meteorology), *PLANT adaptation, *ACCLIMATIZATION, *ARABIDOPSIS, *HABITATS

Abstract

Success or failure of plants to cope with freezing temperatures can critically influence plant distribution and adaptation to new habitats. Especially in alpine environments, frost is a likely major selective force driving adaptation. In Arabidopsis arenosa (L.) Lawalrée, alpine populations have evolved independently in different mountain ranges, enabling studying mechanisms of acclimation and adaptation to alpine environments.We tested for heritable, parallel differentiation in freezing resistance, cold acclimation potential and ice management strategies using eight alpine and eight foothill populations. Plants from three European mountain ranges (Niedere Tauern, Făgăraș and Tatra Mountains) were grown from seeds of tetraploid populations in four common gardens, together with diploid populations from the Tatra Mountains. Freezing resistance was assessed using controlled freezing treatments and measuring effective quantum yield of photosystem II, and ice management strategies by infrared video thermography and cryomicroscopy.The alpine ecotype had a higher cold acclimation potential than the foothill ecotype, whereby this differentiation was more pronounced in tetraploid than diploid populations. However, no ecotypic differentiation was found in one region (Făgăraș), where the ancient lineage had a different evolutionary history. Upon freezing, an ice lens within a lacuna between the palisade and spongy parenchyma tissues was formed by separation of leaf tissues, a mechanism not previously reported for herbaceous species.The dynamic adjustment of freezing resistance to temperature conditions may be particularly important in alpine environments characterized by large temperature fluctuations. Furthermore, the formation of an extracellular ice lens may be a useful strategy to avoid tissue damage during freezing. [ABSTRACT FROM AUTHOR]

Published

2022

104. Lost and found: Totton's Minyaspis faroni revived and molecular evidence of paraphyly of Oxynaspis and Minyaspis.

Author

Brickner, Itzchak, Koplovitz, Gil, Simon-Blecher, Noa, and Achituv, Yair

Subjects

*BARNACLES, *SYMBIOSIS, *SPECIES

Abstract

The stalked barnacles Minyaspis faroni associated with antipatharians known from the southern Red Sea have been recently recorded in the northern Red Sea. Two genera of oxynaspids, Oxyaspis and Minyaspis, differ morphologically in the coverage of the capitulum. In Oxyaspis, the capitulum is covered by calcified plates, whereas in Minyaspis, the plates are reduced, and there is an uncalcified area between plates. Molecular analyses revealed that species with reduced plates do not cluster in the same clade, whereas species with full coverage and uncalcified capitula are found in the same clade. Our analysis indicates that the reduction of opercular plates in the epibiotic barnacles has occurred more than once in the barnacle evolutionary pathway. The reduction in shell plates' number, size, shape and thickness is an adaptive character of epibiotic symbiosis. This mode of life, common in thoracican barnacles, leads to adaptive morphological changes. Hence, the morphology of shell plates is not a homologous feature but reflects parallel evolution. [ABSTRACT FROM AUTHOR]

Published

2022

105. Parallel local adaptation to an alpine environment in Arabidopsis arenosa.

Author

Wos, Guillaume, Arc, Erwann, Hülber, Karl, Konečná, Veronika, Knotek, Adam, Požárová, Doubravka, Bertel, Clara, Kaplenig, Dominik, Mandáková, Terezie, Neuner, Gilbert, Schönswetter, Peter, Kranner, Ilse, and Kolář, Filip

Subjects

*GENE flow, *ARABIDOPSIS, *NATURAL selection, *FLOWERING of plants, *GROWING season

Abstract

1. Parallel local adaptation, that is, when distinct genetic lineages independently adapt to the same selective environment, provides strong evidence for the action of natural selection. A few cases of parallel local adaptation were reported in plants but underlying mechanisms promoting or preventing the parallel response, such as the balance between migration and selection, were rarely quantified. Here, we conducted a transplant experiment to test whether distinct foothill–alpine population pairs of Arabidopsis arenosa exhibited similar adaptive responses to a contrasting alpine environment. We further investigated selection and migration patterns in these populations. 2. Seedlings of 16 foothill and alpine populations of A. arenosa from four distinct mountain regions (one occupied by diploid and three by tetraploid populations) were transplanted into one low- and one high-elevation site. We recorded fitness proxies over two growing seasons to test whether the elevation-of-origin advantage was manifested in the same way across the four regions of origin. Then, we quantified the strength of selection on the traits at each transplantation site and used coalescent simulations to estimate past gene flow intensity between each pair of foothill and alpine populations in each region. 3. We demonstrated that the four pairs of populations exhibited similar adaptive responses to elevation difference in terms of survival, number of flowering plants, stem height and accumulation of above-ground dry biomass; the other traits (rosette size, number of leaves, stems and flowers) exhibited rather regional-specific patterns. In addition, we found minor effects of ploidy level on the fitness proxies recorded. Our selection and migration analysis revealed that parallel local adaptation was probably achieved by differential selective pressure at low versus high elevation in combination with lack or limited gene flow between foothill and alpine populations. 4. Synthesis. We show that the previously documented strong morphological and genetic distinctness of alpine A. arenosa compared to their foothill counterparts, which has been hypothesized to be driven by natural selection, is indeed mirrored in fitness differences consistent with parallel local adaptation. Our results provide experimental support for the repeatability of adaptive evolution and highlight the prominent role of divergent selection. [ABSTRACT FROM AUTHOR]

Published

2022

106. Genomic basis and phenotypic manifestation of (non‐)parallel serpentine adaptation in Arabidopsis arenosa.

Author

Konečná, Veronika, Šustr, Marek, Požárová, Doubravka, Čertner, Martin, Krejčová, Anna, Tylová, Edita, and Kolář, Filip

Subjects

*SERPENTINE, *ARABIDOPSIS, *POPULATION differentiation, *PLANT adaptation, *POISONS, *PHENOTYPES

Abstract

Parallel evolution is common in nature and provides one of the most compelling examples of rapid environmental adaptation. In contrast to the recent burst of studies addressing genomic basis of parallel evolution, integrative studies linking genomic and phenotypic parallelism are scarce. Edaphic islands of toxic serpentine soils provide ideal systems for studying rapid parallel adaptation in plants, imposing strong, spatially replicated selection on recently diverged populations. We leveraged threefold independent serpentine adaptation of Arabidopsis arenosa and combined reciprocal transplants, ion uptake phenotyping, and available genome‐wide polymorphisms to test if parallelism is manifested to a similar extent at both genomic and phenotypic levels. We found pervasive phenotypic parallelism in functional traits yet with varying magnitude of fitness differences that was congruent with neutral genetic differentiation between populations. Limited costs of serpentine adaptation suggest absence of soil‐driven trade‐offs. On the other hand, the genomic parallelism at the gene level was significant, although relatively minor. Therefore, the similarly modified phenotypes, for example, of ion uptake arose possibly by selection on different loci in similar functional pathways. In summary, we bring evidence for the important role of genetic redundancy in rapid adaptation involving traits with polygenic architecture. [ABSTRACT FROM AUTHOR]

Published

2022

107. Parallel Differentiation and Plastic Adjustment of Leaf Anatomy in Alpine Arabidopsis arenosa Ecotypes.

Author

Bertel, Clara, Kaplenig, Dominik, Ralser, Maria, Arc, Erwann, Kolář, Filip, Wos, Guillaume, Hülber, Karl, Holzinger, Andreas, Kranner, Ilse, and Neuner, Gilbert

Subjects

LEAF anatomy, COLONIZATION (Ecology), ARABIDOPSIS, PLASTICS, LEAVE of absence, CHLOROPLASTS, AMYLOPLASTS

Abstract

Functional and structural adjustments of plants in response to environmental factors, including those occurring in alpine habitats, can result in transient acclimation, plastic phenotypic adjustments and/or heritable adaptation. To unravel repeatedly selected traits with potential adaptive advantage, we studied parallel (ecotypic) and non-parallel (regional) differentiation in leaf traits in alpine and foothill ecotypes of Arabidopsis arenosa. Leaves of plants from eight alpine and eight foothill populations, representing three independent alpine colonization events in different mountain ranges, were investigated by microscopy techniques after reciprocal transplantation. Most traits clearly differed between the foothill and the alpine ecotype, with plastic adjustments to the local environment. In alpine populations, leaves were thicker, with altered proportions of palisade and spongy parenchyma, and had fewer trichomes, and chloroplasts contained large starch grains with less stacked grana thylakoids compared to foothill populations. Geographical origin had no impact on most traits except for trichome and stomatal density on abaxial leaf surfaces. The strong parallel, heritable ecotypic differentiation in various leaf traits and the absence of regional effects suggests that most of the observed leaf traits are adaptive. These trait shifts may reflect general trends in the adaptation of leaf anatomy associated with the colonization of alpine habitats. [ABSTRACT FROM AUTHOR]

Published

2022

108. AF‐vapeR: A multivariate genome scan for detecting parallel evolution using allele frequency change vectors.

Author

Whiting, James R., Paris, Josephine R., van der Zee, Mijke J., and Fraser, Bonnie A.

Subjects

GENE frequency, VECTOR analysis, ERROR rates, EIGENVALUES, HAPLOTYPES

Abstract

The repeatability of evolution at the genetic level has been demonstrated to vary along a continuum from complete parallelism to divergence. In order to better understand why this continuum exists within and among systems, hypotheses must be tested using high‐confidence candidate loci for repeatability. However, few methods have been developed to scan SNP data for signatures specifically associated with repeatability, as opposed to local adaptation.We present AF‐vapeR (Allele Frequency Vector Analysis of Parallel Evolutionary Responses), an approach designed to identify genomic regions exhibiting highly correlated allele frequency changes within haplotypes and among replicated allele frequency change vectors. The method divides the genome into windows of an equivalent number of SNPs, and within each window performs eigen decomposition over normalised allele frequency change vectors (AFVs), each derived from a replicated pair of populations/species. Properties of the resulting eigenvalue distribution can be used to compare regions of the genome for those exhibiting strong geometric parallelism, and can also be compared against a null distribution derived from randomly permuted AFVs. Furthermore, the shape of the eigenvalue distribution can reveal multiple axes of parallelism within datasets.We demonstrate the utility of this approach to detect different modes of parallel evolution using simulations, and a reduced type‐II error rate compared with intersecting FST outliers. Lastly, we apply AF‐vapeR to four previously published datasets (stickleback, Drosophila, guppies and Galapagos finches) which comprise a range of sampling and sequencing strategies, and lineage ages. We detect known parallel regions while also identifying novel candidates.The main benefits of this approach include a reduced false‐negative rate under many conditions, an emphasis on signals associated specifically with repeatable evolution as opposed to local adaptation, and an opportunity to identify different modes of parallel evolution at the first instance. [ABSTRACT FROM AUTHOR]

Published

2022

109. Variation in the genomic basis of parallel phenotypic and ecological divergence in benthic and pelagic morphs of Icelandic Arctic charr (Salvelinus alpinus).

Author

Brachmann, Matthew K., Parsons, Kevin, Skúlason, Skúli, Gaggiotti, Oscar, and Ferguson, Moira

Subjects

*ARCTIC char, *GENE flow, *PHENOTYPES, *BENTHIC animals, *SINGLE nucleotide polymorphisms, *NITROGEN isotopes, *GENOME-wide association studies

Abstract

Sympatric adaptive phenotypic divergence should be underlain by genomic differentiation between subpopulations. When divergence drives similar patterns of phenotypic and ecological variation within species we expect evolution to draw on common allelic variation. We investigated divergence histories and genomic signatures of adaptive divergence between benthic and pelagic morphs of Icelandic Arctic charr. Divergence histories for each of four populations were reconstructed using coalescent modelling and 14,187 single nucleotide polymorphisms. Sympatric divergence with continuous gene flow was supported in two populations while allopatric divergence with secondary contact was supported in one population; we could not differentiate between demographic models in the fourth population. We detected parallel patterns of phenotypic divergence along benthic‐pelagic evolutionary trajectories among populations. Patterns of genomic differentiation between benthic and pelagic morphs were characterized by outlier loci in many narrow peaks of differentiation throughout the genome, which may reflect the eroding effects of gene flow on nearby neutral loci. We then used genome‐wide association analyses to relate both phenotypic (body shape and size) and ecological (carbon and nitrogen stable isotopes) variation to patterns of genomic differentiation. Many peaks of genomic differentiation were associated with phenotypic and ecological variation in the three highly divergent populations, suggesting a genomic basis for adaptive divergence. We detected little evidence for a parallel genomic basis of differentiation as most regions and outlier loci were not shared among populations. Our results show that adaptive divergence can have varied genomic consequences in populations with relatively recent common origins, similar divergence histories, and parallel phenotypic divergence. [ABSTRACT FROM AUTHOR]

Published

2022

110. Life history evolution during a climate-driven butterfly range expansion

Author

Ittonen, Mats and Ittonen, Mats

Abstract

Climate change pushes species polewards and upwards – as temperatures rise, species move to areas that were previously too cold for them. During range expansions, species encounter unfamiliar environmental conditions, which may require evolutionary adaptation, but expanding populations may often be hampered by their genetic and demographic properties. Whether range-expanding populations can adapt may greatly affect species distributions, but the question is largely unexplored for native species expanding in response to climate change. In seasonal environments, organisms must endure harsh conditions and synchronise growth and reproduction with the presence of food and mates. To time their life cycles, many animals and plants use seasonal changes in daylength. Insects typically overwinter in diapause (dormancy with paused development and suppressed metabolism), which is induced by short days well before winter. But across-latitude differences in daylength pose challenges for latitudinal range expansions. I focus on whether traits related to seasonal timing and winter survival have evolved during range expansion of the wall brown butterfly (Lasiommata megera) in Sweden. In Chapter I, I confirmed that the wall brown has, in 2000–2020, expanded northwards along the eastern and western coasts of Sweden, and in Chapter II, I demonstrated that these parallel expansions have proceeded independently from the south, in isolation from each other. Laboratory experiments in Chapter I revealed that caterpillars from northern populations have evolved to correctly interpret their local daylength cues. This rapid evolution, repeated along two range expansions, indicates that latitudinal differences in daylength may seldom hinder insect range expansions. In Chapter II, I found that northern range margin populations have lower genetic variation than southern ones but are unlikely to have received much locally maladaptive gene flow from the south. Further, a genomic scan suggested that

Published

2024

111. The Population Genomics of Parallel Adaptation: Lessons from Threespine Stickleback

Author

Hohenlohe, Paul A., Magalhaes, Isabel Santos, Rajora, Om P., Editor-in-Chief, and Oleksiak, Marjorie F., editor

Published

2020

112. Parallel morphological evolution and habitat‐dependent sexual dimorphism in cave‐ vs. surface populations of the Asellus aquaticus (Crustacea: Isopoda: Asellidae) species complex

Author

Gergely Balázs, Anna Biró, Žiga Fišer, Cene Fišer, and Gábor Herczeg

Subjects

adaptation, colonization, parallel evolution, sexual dimorphism, subterranean, troglomorphy, Ecology, QH540-549.5

Abstract

Abstract Studying parallel evolution (repeated, independent evolution of similar phenotypes in similar environments) is a powerful tool to understand environment‐dependent selective forces. Surface‐dwelling species that repeatedly and independently colonized caves provide unique models for such studies. The primarily surface‐dwelling Asellus aquaticus species complex is a good candidate to carry out such research, because it colonized several caves in Europe. By comparing 17 functional morphological traits between six cave and nine surface populations of the A. aquaticus species complex, we investigated population divergence in morphology and sexual dimorphism. We found habitat‐dependent population divergence in 10 out of 17 traits, likely reflecting habitat‐driven changes in selection acting on sensory systems, feeding, grooming, and antipredator mechanisms. Sexual dimorphism was present in 15 traits, explained by sexual selection acting on male traits important in male–male agonistic behavior or mate guarding and fecundity selection acting on female traits affecting offspring number and nursing. In eight traits, the degree of sexual dimorphism was habitat dependent. We conclude that cave‐related morphological changes are highly trait‐ and function‐specific and that the strength of sexual/fecundity selection strongly differs between cave and surface habitats. The considerable population variation within habitat type warrants further studies to reveal cave‐specific adaptations besides the parallel patterns.

Published

2021

113. Dynamics of Podospora anserina Genome Evolution in a Long-Term Experiment

Author

Olga A. Kudryavtseva, Evgeny S. Gerasimov, Elena S. Glagoleva, Anna A. Gasparyan, Saveliy M. Agroskin, Mikhail A. Belozersky, and Yakov E. Dunaevsky

Subjects

experimental evolution, long-term experiment, parallel evolution, Podospora anserina, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The Podospora anserina long-term evolution experiment (PaLTEE) is the only running filamentous fungus study, which is still going on. The aim of our work is to trace the evolutionary dynamics of the accumulation of mutations in the genomes of eight haploid populations of P. anserina. The results of the genome-wide analysis of all of the lineages, performed 8 years after the start of the PaLTEE, are presented. Data analysis detected 312 single nucleotide polymorphisms (SNPs) and 39 short insertion-deletion mutations (indels) in total. There was a clear trend towards a linear increase in the number of SNPs depending on the experiment duration. Among 312 SNPs, 153 were fixed in the coding regions of P. anserina genome. Relatively few synonymous mutations were found, exactly 38; 42 were classified as nonsense mutations; 72 were assigned to missense mutations. In addition, 21 out of 39 indels identified were also localized in coding regions. Here, we also report the detection of parallel evolution at the paralog level in the P. anserina model system. Parallelism in evolution at the level of protein functions also occurs. The latter is especially true for various transcription factors, which may indicate selection leading to optimization of the wide range of cellular processes under experimental conditions.

Published

2023

114. Inversions and parallel evolution.

Author

Westram, Anja M., Faria, Rui, Johannesson, Kerstin, Butlin, Roger, and Barton, Nick

Subjects

*CHROMOSOME inversions, *PARALLEL processing, *CHROMOSOMAL rearrangement, *GENOMICS, *PHENOTYPES, *GENE flow

Abstract

Local adaptation leads to differences between populations within a species. In many systems, similar environmental contrasts occur repeatedly, sometimes driving parallel phenotypic evolution. Understanding the genomic basis of local adaptation and parallel evolution is a major goal of evolutionary genomics. It is now known that by preventing the break-up of favourable combinations of alleles across multiple loci, genetic architectures that reduce recombination, like chromosomal inversions, can make an important contribution to local adaptation. However, little is known about whether inversions also contribute disproportionately to parallel evolution. Our aim here is to highlight this knowledge gap, to showcase existing studies, and to illustrate the differences between genomic architectures with and without inversions using simple models. We predict that by generating stronger effective selection, inversions can sometimes speed up the parallel adaptive process or enable parallel adaptation where it would be impossible otherwise, but this is highly dependent on the spatial setting. We highlight that further empirical work is needed, in particular to cover a broader taxonomic range and to understand the relative importance of inversions compared to genomic regions without inversions. This article is part of the theme issue 'Genomic architecture of supergenes: causes and evolutionary consequences'. [ABSTRACT FROM AUTHOR]

Published

2022

115. Adaptation to environmental temperature in divergent clades of the nematode Pristionchus pacificus.

Author

Leaver, Mark, Moreno, Eduardo, Kayhan, Merve, McGaughran, Angela, Rödelsperger, Christian, Sommer, Ralf J., and Hyman, Anthony A.

Subjects

*BODY temperature regulation, *COLD-blooded animals, *INFORMATION modeling, *CLIMATE change, *ALTITUDES, *DEMOGRAPHIC change

Abstract

Because of ongoing climate change, populations of organisms are being subjected to stressful temperatures more often. This is especially problematic for ectothermic organisms, which are likely to be more sensitive to changes in temperature. Therefore, we need to know if ectotherms have adapted to environmental temperature and, if so, what are the evolutionary mechanisms behind such adaptation. Here, we use the nematode Pristionchus pacificus as a case study to investigate thermal adaptation on the Indian Ocean island of La Réunion, which experiences a range of temperatures from coast to summit. We study the evolution of high‐temperature tolerance by constructing a phylogenetic tree of strains collected from many different thermal niches. We show that populations of P. pacificus at low altitudes have higher fertility at warmer temperatures. Most likely, this phenotype has arisen recently and at least twice independently, consistent with parallel evolution. We also studied low‐temperature tolerance and showed that populations from high altitudes have increased their fertility at cooler temperatures. Together, these data indicate that P. pacificus strains on La Réunion are subject to divergent selection, adapting to hot and cold niches at the coast and summit of the volcano. Precisely defining these thermal niches provides essential information for models that predict the impact of future climate change on these populations. [ABSTRACT FROM AUTHOR]

Published

2022

116. Genomic signatures of the evolution of a diurnal lifestyle in Strigiformes.

Author

Espíndola-Hernández, Pamela, Mueller, Jakob C., and Kempenaers, Bart

Subjects

*OWLS, *NEURAL development, *COMPARATIVE method, *BIRDS of prey, *SPECIES

Abstract

Understanding the targets of selection associated with changes in behavioral traits represents an important challenge of current evolutionary research. Owls (Strigiformes) are a diverse group of birds, most of which are considered nocturnal raptors. However, a few owl species independently adopted a diurnal lifestyle in their recent evolutionary history. We searched for signals of accelerated rates of evolution associated with a diurnal lifestyle using a genome-wide comparative approach. We estimated substitution rates in coding and noncoding conserved regions of the genome of seven owl species, including three diurnal species. Substitution rates of the noncoding elements were more accelerated than those of protein-coding genes. We identified new, owl-specific conserved noncoding elements as candidates of parallel evolution during the emergence of diurnality in owls. Our results shed light on the molecular basis of adaptation to a new niche and highlight the importance of regulatory elements for evolutionary changes in behavior. These elements were often involved in the neuronal development of the brain. [ABSTRACT FROM AUTHOR]

Published

2022

117. Macrobiotus ariekammensis species complex provides evidence for parallel evolution of claw elongation in macrobiotid tardigrades.

Author

Stec, Daniel, Vončina, Katarzyna, Kristensen, Reinhardt Møbjerg, and Michalczyk, Łukasz

Subjects

*TARDIGRADA, *BIOLOGICAL classification, *SPECIES, *SUBSPECIES, *CLAWS, *MOLECULAR phylogeny

Abstract

The recent integrative revision of the family Macrobiotidae demonstrated monophyly of the genus Macrobiotus and its complex, mosaic morphological evolution. Here, we analyse three Macrobiotus populations that exhibit extraordinary claw morphology characterized by elongated primary branches. Two of these populations, from the Arctic, were initially classified as Macrobiotus ariekammensis , but detailed integrative analyses resulted in splitting them into two subspecies: Macrobiotus ariekammensis ariekammensis and Macrobiotus ariekammensis groenlandicus subsp. nov.. The third population was Macrobiotus kirghizicus from Kyrgyzstan. Given the unusual phenotype of the above-mentioned taxa, we tested whether they constitute a distinct lineage in the family Macrobiotidae and could be delineated as a new genus. Although the phylogenetic investigation showed that the three taxa form a monophyletic group, the clade is nested in the genus Macrobiotus. Therefore, despite their morphological distinctiveness, a new genus cannot be established and we group these taxa in the Macrobiotus ariekammensis species complex instead. The complex includes the three above-mentioned taxa and Macrobiotus ramoli , which is included based on morphological characters. Moreover, our results provide evidence for rapid parallel evolution of long claws in macrobiotid tardigrades inhabiting cold and icy environments. Finally, we discuss the validity of the recent suppression of the genus Xerobiotus , which gathers macrobiotids with reduced claws. [ABSTRACT FROM AUTHOR]

Published

2022

118. Genetic basis for the evolution of pelvic‐fin brooding, a new mode of reproduction, in a Sulawesian fish.

Author

Montenegro, Javier, Fujimoto, Shingo, Ansai, Satoshi, Nagano, Atsushi J., Sato, Masahiro, Maeda, Yusuke, Tanaka, Rieko, Masengi, Kawilarang W. A., Kimura, Ryosuke, Kitano, Jun, and Yamahira, Kazunori

Subjects

*INTROGRESSION (Genetics), *ANIMAL reproduction, *LOCUS (Genetics), *ANIMAL clutches, *CONVERGENT evolution, *GENOMICS

Abstract

Modes of reproduction in animals are diverse, with different modes having evolved independently in multiple lineages across a variety of taxa. However, an understanding of the genomic change driving the transition between different modes of reproduction is limited. Several ricefishes (Adrianichthyidae) on the island of Sulawesi have a unique mode of reproduction called "pelvic‐fin brooding," wherein females carry externally fertilized eggs until hatching using their pelvic fins. Phylogenomic analysis demonstrated pelvic‐fin brooders to have evolved at least twice in two distant clades of the Adrianichthyidae. We investigated the genetic architecture of the evolution of this unique mode of reproduction. Morphological analyses and laboratory observations revealed that females of pelvic‐fin brooders have longer pelvic fins and a deeper abdominal concavity, and that they can carry an egg clutch for longer than nonbrooding adrianichthyids, suggesting that these traits play important roles in this reproductive mode. Quantitative trait locus mapping using a cross between a pelvic‐fin brooder Oryzias eversi and a nonbrooding O. dopingdopingensis reveals different traits involved in pelvic‐fin brooding to be controlled by different loci on different chromosomes. Genomic analyses of admixture detected no signatures of introgression between two lineages with pelvic‐fin brooders, indicating that introgression is unlikely to be responsible for repeated evolution of pelvic‐fin brooding. These findings suggest that multiple independent mutations may have contributed to the convergent evolution of this novel mode of reproduction. [ABSTRACT FROM AUTHOR]

Published

2022

119. Leaf Economic and Hydraulic Traits Signal Disparate Climate Adaptation Patterns in Two Co-Occurring Woodland Eucalypts.

Author

Prober, Suzanne M., Potts, Brad M., Harrison, Peter A., Wiehl, Georg, Bailey, Tanya G., Costa e Silva, João, Price, Meridy R., Speijers, Jane, Steane, Dorothy A., and Vaillancourt, René E.

Subjects

EUCALYPTUS, FORESTS & forestry, POPULATION differentiation, BIODIVERSITY conservation, CLIMATE change

Abstract

With climate change impacting trees worldwide, enhancing adaptation capacity has become an important goal of provenance translocation strategies for forestry, ecological renovation, and biodiversity conservation. Given that not every species can be studied in detail, it is important to understand the extent to which climate adaptation patterns can be generalised across species, in terms of the selective agents and traits involved. We here compare patterns of genetic-based population (co)variation in leaf economic and hydraulic traits, climate–trait associations, and genomic differentiation of two widespread tree species (Eucalyptus pauciflora and E. ovata). We studied 2-year-old trees growing in a common-garden trial established with progeny from populations of both species, pair-sampled from 22 localities across their overlapping native distribution in Tasmania, Australia. Despite originating from the same climatic gradients, the species differed in their levels of population variance and trait covariance, patterns of population variation within each species were uncorrelated, and the species had different climate–trait associations. Further, the pattern of genomic differentiation among populations was uncorrelated between species, and population differentiation in leaf traits was mostly uncorrelated with genomic differentiation. We discuss hypotheses to explain this decoupling of patterns and propose that the choice of seed provenances for climate-based plantings needs to account for multiple dimensions of climate change unless species-specific information is available. [ABSTRACT FROM AUTHOR]

Published

2022

120. Attempting genetic inference from directional asymmetry during convergent hindlimb reduction in squamates.

Author

Swank, Samantha, Elazegui, Ethan, Janidlo, Sophia, Sanger, Thomas J., Bell, Michael A., and Stuart, Yoel E.

Subjects

*HINDLIMB, *SQUAMATA, *CONVERGENT evolution, *INFERENCE (Logic), *PELVIS, *THREESPINE stickleback, *STICKLEBACKS

Abstract

Loss and reduction in paired appendages are common in vertebrate evolution. How often does such convergent evolution depend on similar developmental and genetic pathways? For example, many populations of the threespine stickleback and ninespine stickleback (Gasterosteidae) have independently evolved pelvic reduction, usually based on independent mutations that caused reduced Pitx1 expression. Reduced Pitx1 expression has also been implicated in pelvic reduction in manatees. Thus, hindlimb reduction stemming from reduced Pitx1 expression has arisen independently in groups that diverged tens to hundreds of millions of years ago, suggesting a potential for repeated use of Pitx1 across vertebrates. Notably, hindlimb reduction based on the reduction in Pitx1 expression produces left‐larger directional asymmetry in the vestiges. We used this phenotypic signature as a genetic proxy, testing for hindlimb directional asymmetry in six genera of squamate reptiles that independently evolved hindlimb reduction and for which genetic and developmental tools are not yet developed: Agamodon anguliceps, Bachia intermedia, Chalcides sepsoides, Indotyphlops braminus, Ophisaurus attenuatuas and O. ventralis, and Teius teyou. Significant asymmetry occurred in one taxon, Chalcides sepsoides, whose left‐side pelvis and femur vestiges were 18% and 64% larger than right‐side vestiges, respectively, suggesting modification in Pitx1 expression in that species. However, there was either right‐larger asymmetry or no directional asymmetry in the other five taxa, suggesting multiple developmental genetic pathways to hindlimb reduction in squamates and the vertebrates more generally. [ABSTRACT FROM AUTHOR]

Published

2022

121. Hybrid evolution repeats itself across environmental contexts in Texas sunflowers (Helianthus).

Author

Mitchell, Nora, Luu, Hoang, Owens, Gregory L., Rieseberg, Loren H., and Whitney, Kenneth D.

Subjects

*COMMON sunflower, *HOMESITES, *BIOLOGICAL fitness, *SUNFLOWERS, *SEEDS, *GARDENS

Abstract

To what extent is evolution repeatable? Little is known about whether the evolution of hybrids is more (or less) repeatable than that of nonhybrids. We used field experimental evolution in annual sunflowers (Helianthus) in Texas to ask the extent to which hybrid evolution is repeatable across environments compared to nonhybrid controls. We created hybrids between Helianthus annuus (L.) and H. debilis (Nutt.) and grew plots of both hybrids and nonhybrid controls through eight generations at three sites in Texas. We collected seeds from each generation and grew each generation × treatment × home site combination at two final common gardens. We estimated the strength and direction of evolution in terms of fitness and 24 traits, tested for repeated versus nonrepeated evolution, and assessed overall phenotypic evolution across lineages and in relation to a locally adapted phenotype. Hybrids consistently evolved higher fitness over time, while controls did not, although trait evolution varied in strength across home sites. Repeated evolution was more evident in hybrids versus nonhybrid controls, and hybrid evolution was often in the direction of the locally adapted phenotype. Our findings have implications for both the nature of repeatability in evolution and the contribution of hybridization to evolution across environmental contexts. [ABSTRACT FROM AUTHOR]

Published

2022

122. Evolution of nuptial-gift-related male prosomal structures: taxonomic revision and cladistic analysis of the genus Oedothorax (Araneae: Linyphiidae: Erigoninae).

Author

Lin, Shou-Wang, Lopardo, Lara, and Uhl, Gabriele

Abstract

Sexual selection has been shown to drive speciation. In dwarf spiders (erigonines), males possess diverse, sexually selected prosomal structures with nuptial-gift-producing glands. The genus Oedothorax is suitable for investigating the evolution of these features due to high structural variation. We have re-delimited this genus based on a phylogenetic analysis. Ten species are Oedothorax s.s. ; five are transferred back to their original generic placement; 25 remain unplaced as ' Oedothorax '. Four junior synonymies are proposed: Callitrichia simplex to Ca. holmi comb. nov.; Gongylidioides kougianensis to G. insulanus comb. nov.; Ummeliata ziaowutai to U. esyunini comb. nov.; Oe. kathmandu to Mitrager unicolor comb. nov. Oedothorax seminolus is a junior synonym of Soulgas corticarius and the transfer of Oe. alascensis to Halorates is confirmed. The replacement name Ca. hirsuta is proposed for Ca. pilosa. The male of Callitrichia longiducta comb. nov. and the female of ' Oedothorax ' nazareti are newly described. Thirty-eight Oedothorax species are transferred to other genera. Callitrichia spinosa is transferred to Holmelgonia. Three genera are erected: Cornitibia , Emertongone and Jilinus. Ophrynia and Toschia are synonymized with Callitrichia. Character optimization suggests multiple origins of different prosomal modification types. Convergent evolution in these traits suggests that sexual selection has played an important role in erigonine diversification. [ABSTRACT FROM AUTHOR]

Published

2022

123. 一种多尺度协同变异的萤火虫粒子群混合算法 及在车间调度中的应用.

Author

周艳平 and 刘永娟

Abstract

Copyright of Computer Measurement & Control is the property of Magazine Agency of Computer Measurement & Control and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

124. Annual Temperatures and Dynamics of Food Availability are Associated with the Pelagic-Benthic Diversification in a Sympatric Pair of Salmonid Fish.

Author

Markevich, G. N., Izvekova, E. I., Anisimova, L. A., Mugue, N. S., Bonk, T. V., and Esin, E. V.

Abstract

Fish diversification into sympatric ecomorph pairs demonstrates a striking parallelism across a number of taxa in numerous lakes. However, there is a dearth of information on environmental conditions, which may orchestrate divergence processes across generations. Here we explore whether the environmental factors affecting food and reproductive niche distinctions could trigger the divergence of the lacustrine-riverine fish species into two morphs based on kokanee Oncorhynchus nerka of the Lake Kronotskoe. We reveal drastic differences in temperature on the tributary reproduction sites affecting the early ontogeny timing and disrupting the time of lakeward migration of the morphs. The juveniles of the benthivorous morph run into the lake in spring during the food abundance peak on the slope, while the planktivorous kokanee migrates to the lake in the summer when the pelagic zone abounds with zooplankton. The dynamics of this food niches is determined by water temperature dynamics and may be stable for long periods of time, thus making each morph adapting to similar condition throughout generations. We suggest that the pelagic-benthic divergence could be explained by the factors, which are extrinsic for fish, making our results applicable for numerous cases of this microevolutionary pathway all over the Holarctic. [ABSTRACT FROM AUTHOR]

Published

2022

125. Attempting genetic inference from directional asymmetry during convergent hindlimb reduction in squamates

Author

Samantha Swank, Ethan Elazegui, Sophia Janidlo, Thomas J. Sanger, Michael A. Bell, and Yoel E. Stuart

Subjects

development, hindlimb loss, micro‐computed tomography, museum specimens, parallel evolution, Pitx1, Ecology, QH540-549.5

Abstract

Abstract Loss and reduction in paired appendages are common in vertebrate evolution. How often does such convergent evolution depend on similar developmental and genetic pathways? For example, many populations of the threespine stickleback and ninespine stickleback (Gasterosteidae) have independently evolved pelvic reduction, usually based on independent mutations that caused reduced Pitx1 expression. Reduced Pitx1 expression has also been implicated in pelvic reduction in manatees. Thus, hindlimb reduction stemming from reduced Pitx1 expression has arisen independently in groups that diverged tens to hundreds of millions of years ago, suggesting a potential for repeated use of Pitx1 across vertebrates. Notably, hindlimb reduction based on the reduction in Pitx1 expression produces left‐larger directional asymmetry in the vestiges. We used this phenotypic signature as a genetic proxy, testing for hindlimb directional asymmetry in six genera of squamate reptiles that independently evolved hindlimb reduction and for which genetic and developmental tools are not yet developed: Agamodon anguliceps, Bachia intermedia, Chalcides sepsoides, Indotyphlops braminus, Ophisaurus attenuatuas and O. ventralis, and Teius teyou. Significant asymmetry occurred in one taxon, Chalcides sepsoides, whose left‐side pelvis and femur vestiges were 18% and 64% larger than right‐side vestiges, respectively, suggesting modification in Pitx1 expression in that species. However, there was either right‐larger asymmetry or no directional asymmetry in the other five taxa, suggesting multiple developmental genetic pathways to hindlimb reduction in squamates and the vertebrates more generally.

Published

2022

126. Examining the molecular basis of coat color in a nocturnal primate family (Lorisidae)

Author

Rachel A. Munds, Chelsea L. Titus, Lais A. A. Moreira, Lori S. Eggert, and Gregory E. Blomquist

Subjects

aposematic, deleterious, MC1R, nonsynonymous, parallel evolution, pigmentation, Ecology, QH540-549.5

Abstract

Abstract Organisms use color for camouflage, sexual signaling, or as a warning sign of danger. Primates are one of the most vibrantly colored Orders of mammals. However, the genetics underlying their coat color are poorly known, limiting our ability to study molecular aspects of its evolution. The role of the melanocortin 1 receptor (MC1R) in color evolution has been implicated in studies on rocket pocket mice (Chaetodipus intermediusi), toucans (Ramphastidae), and many domesticated animals. From these studies, we know that changes in MC1R result in a yellow/red or a brown/black morphology. Here, we investigate the evolution of MC1R in Lorisidae, a monophyletic nocturnal primate family, with some genera displaying high contrast variation in color patterns and other genera being monochromatic. Even more unique, the Lorisidae family has the only venomous primate: the slow loris (Nycticebus). Research has suggested that the contrasting coat patterns of slow lorises are aposematic signals for their venom. If so, we predict the MC1R in slow lorises will be under positive selection. In our study, we found that Lorisidae MC1R is under purifying selection (ω = 0.0912). In Lorisidae MC1R, there were a total of 75 variable nucleotides, 18 of which were nonsynonymous. Six of these nonsynonymous substitutions were found on the Perodicticus branch, which our reconstructions found to be the only member of Lorisidae that has predominantly lighter coat color; no substitutions were associated with Nycticebus. Our findings generate new insight into the genetics of pelage color and evolution among a unique group of nocturnal mammals and suggest putative underpinnings of monochromatic color evolution in the Perodicticus lineage.

Published

2021

127. The diversity of opsins in Lake Baikal amphipods (Amphipoda: Gammaridae)

Author

Polina Drozdova, Alena Kizenko, Alexandra Saranchina, Anton Gurkov, Maria Firulyova, Ekaterina Govorukhina, and Maxim Timofeyev

Subjects

Crustacea: Malacostraca: Amphipoda, Lake Baikal, Ancient ecosystems, Vision, Parallel evolution, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Background Vision is a crucial sense for the evolutionary success of many animal groups. Here we explore the diversity of visual pigments (opsins) in the transcriptomes of amphipods (Crustacea: Amphipoda) and conclude that it is restricted to middle (MWS) and long wavelength-sensitive (LWS) opsins in the overwhelming majority of examined species. Results We evidenced (i) parallel loss of MWS opsin expression in multiple species (including two independently evolved lineages from the deep and ancient Lake Baikal) and (ii) LWS opsin amplification (up to five transcripts) in both Baikal lineages. The number of LWS opsins negatively correlated with habitat depth in Baikal amphipods. Some LWS opsins in Baikal amphipods contained MWS-like substitutions, suggesting that they might have undergone spectral tuning. Conclusions This repeating two-step evolutionary scenario suggests common triggers, possibly the lack of light during the periods when Baikal was permanently covered with thick ice and its subsequent melting. Overall, this observation demonstrates the possibility of revealing climate history by following the evolutionary changes in protein families.

Published

2021

128. DNA vs. Morphology in Delineating Species Boundaries of Endemic Mongolian Eodorcadion Taxa (Coleoptera: Cerambycidae)

Author

Lech Karpiński, Patrick Gorring, and Anthony I. Cognato

Subjects

Central Asia, Dorcadionini, homoplasy, parallel evolution, phylogeny, taxonomy, Biology (General), QH301-705.5

Abstract

This paper provides the first DNA sequences and phylogenetic insight into the Central Asian genus Eodorcadion. We used four molecular markers (COI, CAD, ITS2, and Histone 3) and investigated COI genetic distances to verify phylogenetic position of closely related taxa endemic to Mongolia of the ‘Eodorcadion intermedium species-group’. Histone3 data are presented for the first time for Cerambycidae species. We also designed new PCR primers for better amplification of the Cerambycidae COI barcode region. Morphology of all targeted taxa was examined by means of scanning electron microscopy. Our study showed that while there were very few nucleotide differences among COI sequences of three closely related taxa, such that they shared one haplotype, two of them were grouped separately in the all-data tree, and all three were morphologically distinguishable. Conversely, there was a clear barcode gap between E. intermedium intermedium and all the remaining taxa, including E. intermedium kozlovi. Based on the phylogeny, they belong to two different species-groups; thus, E. kozlovi is herein restored to specific rank. Using Bayesian analysis, we contrasted the COI-based tree with the one supported by nuclear data and showed that COI-only data are not sufficient to resolve the phylogeny of the recently derived flightless groups such as Dorcadionini. We conclude that the Eodorcadion intermedium species-group is a polyphyletic species assemblage, established based on the pattern of the elytral stripes, which may be a case of parallel evolution driven by ecological adaptation.

Published

2023

129. The genetics of adaptation in freshwater Eurasian shad (Alosa).

Author

Sabatino, Stephen J., Pereira, Paulo, Carneiro, Miguel, Dilytė, Jolita, Archer, John Patrick, Munoz, Antonio, Nonnis‐Marzano, Francesco, and Murias, Antonio

Subjects

*FRESH water, *GENETICS, *NUCLEOTIDE sequencing, *PARALLEL processing, *SUBSPECIES

Abstract

Studying the genetics of phenotypic convergence can yield important insights into adaptive evolution. Here, we conducted a comparative genomic study of four lineages (species and subspecies) of anadromous shad (Alosa) that have independently evolved life cycles entirely completed in freshwater. Three naturally diverged (A. fallax lacustris, A. f. killarnensis, and A. macedonica), and the fourth (A. alosa) was artificially landlocked during the last century. To conduct this analysis, we assembled and annotated a draft of the A. alosa genome and generated whole‐genome sequencing for 16 anadromous and freshwater populations of shad. Widespread evidence for parallel genetic changes in freshwater populations within lineages was found. In freshwater A. alosa, which have only been diverging for tens of generations, this shows that parallel adaptive evolution can rapidly occur. However, parallel genetic changes across lineages were comparatively rare. The degree of genetic parallelism was not strongly related to the number of shared polymorphisms between lineages, thus suggesting that other factors such as divergence among ancestral populations or environmental variation may influence genetic parallelism across these lineages. These overall patterns were exemplified by genetic differentiation involving a paralog of ATPase‐α1 that appears to be under selection in just two of the more distantly related lineages studied, A. f. lacustris and A. alosa. Our findings provide insights into the genetic architecture of adaptation and parallel evolution along a continuum of population divergence. [ABSTRACT FROM AUTHOR]

Published

2022

130. Cyphoderia ampulla (Cyphoderiidae: Rhizaria), a tale of freshwater sailors: The causes and consequences of ecological transitions through the salinity barrier in a family of benthic protists.

Author

González‐Miguéns, Rubén, Soler‐Zamora, Carmen, Useros, Fernando, Nogal‐Prata, Sandra, Berney, Cédric, Blanco‐Rotea, Andrés, Carrasco‐Braganza, María Isabel, de Salvador‐Velasco, David, Guillén‐Oterino, Antonio, Tenorio‐Rodríguez, Daniel, Velázquez, David, Heger, Thierry J., Sanmartín, Isabel, and Lara, Enrique

Subjects

*FRESH water, *SALINITY, *CYTOCHROME oxidase, *PROTISTA, *FRESHWATER biodiversity, *SEA level, *ECOSYSTEMS

Abstract

The salinity barrier that separates marine and freshwater biomes is probably the most important division in biodiversity on Earth. Those organisms that successfully performed this transition had access to new ecosystems while undergoing changes in selective pressure, which often led to major shifts in diversification rates. While these transitions have been extensively investigated in animals, the tempo, mode, and outcome of crossing the salinity barrier have been scarcely studied in other eukaryotes. Here, we reconstructed the evolutionary history of the species complex Cyphoderia ampulla (Euglyphida: Cercozoa: Rhizaria) based on DNA sequences from the nuclear SSU rRNA gene and the mitochondrial cytochrome oxidase subunit I gene, obtained from publicly available environmental DNA data (GeneBank, EukBank) and isolated organisms. A tree calibrated with euglyphid fossils showed that four independent transitions towards freshwater systems occurred from the mid‐Miocene onwards, coincident with important fluctuations in sea level. Ancestral trait reconstructions indicated that the whole family Cyphoderiidae had a marine origin and suggest that ancestors of the freshwater forms were euryhaline and lived in environments with fluctuating salinity. Diversification rates did not show any obvious increase concomitant with ecological transitions, but morphometric analyses indicated that species increased in size and homogenized their morphology after colonizing the new environments. This suggests adaptation to changes in selective pressure exerted by life in freshwater sediments. [ABSTRACT FROM AUTHOR]

Published

2022

131. Examining differentiation of sympatric Schizothorax fishes reveals low differentiation in internal compared to external feeding traits.

Author

Gu, H., He, X., Wu, Y., Deng, S., Jiang, Y., Yu, J., Deng, Z., Xing, K., and Wang, Z.

Subjects

*SCHIZOTHORAX, *ADAPTIVE radiation, *FISH evolution, *FISH feeds

Abstract

In the process of sympatric species differentiation, which feeding traits are most differentiated? The complete feeding process of capture, ingestion, and digestion requires certain external, as well as internal traits. Therefore, comprehensive comparisons are needed to study fish feeding habits. This study systematically investigated the adaptive radiation and parallel evolution of Schizothorax fishes, and quantified the external, frame, pharyngeal bone, and digestive traits of the systematically differentiated omnivorous Schizothorax davidi and herbivorous S. wangchiachii. A member of their sister genus, the carnivorous Percocypris pingi, was used as an outgroup control to explore the feeding differentiation of sympatric Schizothorax fishes. The results showed that these species had highly differentiated external traits, while the internal traits (pharyngeal bone and digestive traits) showed low differentiation, indicating that predatory traits diverged first in the differentiation of sympatric Schizothorax fishes, while chewing and digestive traits were slower to diverge. Furthermore, we screened 16 continuous feeding traits, and the quantified values of these traits progressively increased or decreased with increasing nutritional level of food. These findings provide a reference for the selection of quantitative indicators in future studies of sympatric species differentiation. [ABSTRACT FROM AUTHOR]

Published

2022

132. Parallel Evolution of C-Type Lectin Domain Gene Family Sizes in Insect-Vectored Nematodes.

Author

Ning, Jing, Zhou, Jiao, Wang, Haixiang, Liu, Yaning, Ahmad, Faheem, Feng, Xiaohui, Fu, Yu, Gu, Xiaoting, and Zhao, Lilin

Subjects

GENE families, FAMILY size, NEMATODES, CAENORHABDITIS elegans, IMMUNE response, IMMUNE system, COEVOLUTION

Abstract

The dispersal stage of pathogens is crucial for the successful spread and infection of their hosts. Some plant-parasitic nematodes (PPNs) have evolved specialized dispersal stages to reach healthy hosts by being carried out by insect vectors. Because gene gain and loss is a major factor contributing to the evolution of novel characteristics, it is essential to clarify the gene family characteristics among nematodes with different dispersal modes to disentangle the evolution of insect-mediated dispersal. Here, the size of the C-type lectin (CTL) family genes of insect-vectored nematodes was found to be drastically reduced compared with those of self-dispersing nematodes, whereas the diversity of their functional domains was significantly higher. The gene family sizes of vector-dispersed nematodes were only a twentieth of the size of that of a self-dispersing (i.e., without a biotic vector) nematode model Caenorhabditis elegans , and these genes were inactive during the dispersal stage. Phylogenetic analysis showed that some CTL genes of vector-borne PPNs shared higher homology to the animal parasitic nematodes compared with other PPNs. Moreover, homology modeling predicted that the CTLs of insect-vectored nematodes bear remarkable structural similarity to the lectin genes of their vector's immune system. Because CTL genes are important sugar-binding proteins for the innate immune response of C. elegans , the loss of some CTL genes of vector-transmitted PPNs might be responsible for their parallel adaptations to a mutualistic relationship with their vector. These results expand our understanding of the evolutionary benefits of vector-mediated transmission for the nematode and vector-nematode co-evolution. [ABSTRACT FROM AUTHOR]

Published

2022

133. Supporting safe metamodel evolution with edelta.

Author

Bettini, Lorenzo, Di Ruscio, Davide, Iovino, Ludovico, and Pierantonio, Alfonso

Subjects

*OPERATIONS management

Abstract

Metamodels play a crucial role in any model-based application. They underpin the definition of models and tools, and the development of model management operations, including model transformations and analysis. Like any software artifacts, metamodels are subject to evolution to improve their quality or implement unforeseen requirements. Metamodels can be defined in terms of existing ones to increase the separation of concerns and foster reuse. However, the induced coupling can give additional evolution complexity, and dedicated support is needed to avoid breaking metamodels defined in terms of those being changed. This paper presents a tool-supported approach that can automatically analyze the available metamodels and alert modelers in case of change operations that can give place to invalid situations like dangling references. The approach has been implemented in the Edelta development environment and successfully applied to metamodels retrieved from a publicly available Ecore models dataset. [ABSTRACT FROM AUTHOR]

Published

2022

134. Evolution and Trade-Off Dynamics of Functional Load.

Author

Round, Erich, Dockum, Rikker, and Ryder, Robin J.

Subjects

*MODERN languages, *PHONOTACTICS, *PHONOLOGY, *VOWELS, *LEXICON

Abstract

Functional load (FL) quantifies the contributions by phonological contrasts to distinctions made across the lexicon. Previous research has linked particularly low values of FL to sound change. Here, we broaden the scope of enquiry into FL to its evolution at higher values also. We apply phylogenetic methods to examine the diachronic evolution of FL across 90 languages of the Pama–Nyungan (PN) family of Australia. We find a high degree of phylogenetic signal in FL, indicating that FL values covary closely with genealogical structure across the family. Though phylogenetic signals have been reported for phonological structures, such as phonotactics, their detection in measures of phonological function is novel. We also find a significant, negative correlation between the FL of vowel length and of the following consonant—that is, a time-depth historical trade-off dynamic, which we relate to known allophony in modern PN languages and compensatory sound changes in their past. The findings reveal a historical dynamic, similar to transphonologization, which we characterize as a flow of contrastiveness between subsystems of the phonology. Recurring across a language family that spans a whole continent and many millennia of time depth, our findings provide one of the most compelling examples yet of Sapir's 'drift' hypothesis of non-accidental parallel development in historically related languages. [ABSTRACT FROM AUTHOR]

Published

2022

135. Historical museum samples enable the examination of divergent and parallel evolution during invasion.

Author

Stuart, Katarina C., Sherwin, William B., Austin, Jeremy J., Bateson, Melissa, Eens, Marcel, Brandley, Matthew C., and Rollins, Lee A.

Subjects

*HISTORICAL museums, *BIOLOGICAL invasions, *STURNUS vulgaris, *CLIMATE change, *PLANT invasions, *SELECTIVE exposure, *INTRODUCED species

Abstract

During the Anthropocene, Earth has experienced unprecedented habitat loss, native species decline and global climate change. Concurrently, greater globalization is facilitating species movement, increasing the likelihood of alien species establishment and propagation. There is a great need to understand what influences a species' ability to persist or perish within a new or changing environment. Examining genes that may be associated with a species' invasion success or persistence informs invasive species management, assists with native species preservation and sheds light on important evolutionary mechanisms that occur in novel environments. This approach can be aided by coupling spatial and temporal investigations of evolutionary processes. Here we use the common starling, Sturnus vulgaris, to identify parallel and divergent evolutionary change between contemporary native and invasive range samples and their common ancestral population. To do this, we use reduced‐representation sequencing of native samples collected recently in northwestern Europe and invasive samples from Australia, together with museum specimens sampled in the UK during the mid‐19th century. We found evidence of parallel selection on both continents, possibly resulting from common global selective forces such as exposure to pollutants. We also identified divergent selection in these populations, which might be related to adaptive changes in response to the novel environment encountered in the introduced Australian range. Interestingly, signatures of selection are equally as common within both invasive and native range contemporary samples. Our results demonstrate the value of including historical samples in genetic studies of invasion and highlight the ongoing and occasionally parallel role of adaptation in both native and invasive ranges. [ABSTRACT FROM AUTHOR]

Published

2022

136. Domain-Dependent Evolution Explains Functional Homology of Protostome and Deuterostome Complement C3-Like Proteins.

Author

Peng, Maoxiao, Li, Zhi, Cardoso, João C. R., Niu, Donghong, Liu, Xiaojun, Dong, Zhiguo, Li, Jiale, and Power, Deborah M.

Subjects

PROTEIN domains, PROTEINS, SCISSION (Chemistry), EVOLUTIONARY models, PHAGOCYTOSIS

Abstract

Complement proteins emerged early in evolution but outside the vertebrate clade they are poorly characterized. An evolutionary model of C3 family members revealed that in contrast to vertebrates the evolutionary trajectory of C3-like genes in cnidarian, protostomes and invertebrate deuterostomes was highly divergent due to independent lineage and species-specific duplications. The deduced C3-like and vertebrate C3, C4 and C5 proteins had low sequence conservation, but extraordinarily high structural conservation and 2-chain and 3-chain protein isoforms repeatedly emerged. Functional characterization of three C3-like isoforms in a bivalve representative revealed that in common with vertebrates complement proteins they were cleaved into two subunits, b and a, and the latter regulated inflammation-related genes, chemotaxis and phagocytosis. Changes within the thioester bond cleavage sites and the a-subunit protein (ANATO domain) explained the functional differentiation of bivalve C3-like. The emergence of domain-related functions early during evolution explains the overlapping functions of bivalve C3-like and vertebrate C3, C4 and C5, despite low sequence conservation and indicates that evolutionary pressure acted to conserve protein domain organization rather than the primary sequence. [ABSTRACT FROM AUTHOR]

Published

2022

137. Sensory‐based quantification of male colour patterns in Trinidadian guppies reveals no support for parallel phenotypic evolution in multivariate trait space.

Author

Yong, Lengxob, Croft, Darren P., Troscianko, Jolyon, Ramnarine, Indar W., and Wilson, Alastair J.

Subjects

*GUPPIES, *PHENOTYPES, *SEXUAL selection, *COLOR of fish, *ADAPTIVE testing, *PREDATION

Abstract

Parallel evolution, in which independent populations evolve along similar phenotypic trajectories, offers insights into the repeatability of adaptive evolution. Here, we revisit a classic example of parallelism, that of repeated evolution of brighter males in the Trinidadian guppy (Poecilia reticulata). In guppies, colonisation of low predation habitats is associated with emergence of 'more colourful' phenotypes since predator‐induced viability selection for crypsis weakens while sexual selection by female preference for conspicuousness remains strong. Our study differs from previous investigations in three respects. First, we adopted a multivariate phenotyping approach to characterise parallelism in multitrait space. Second, we used ecologically‐relevant colour traits defined by the visual systems of the two selective agents (i.e., guppy, predatory cichlid). Third, we estimated population genetic structure to test for adaptive (parallel) evolution against a model of neutral phenotypic divergence. We find strong phenotypic differentiation that is inconsistent with a neutral model but very limited support for the predicted pattern of greater conspicuousness at low predation. Effects of predation regime on each trait were in the expected direction, but weak, largely nonsignificant, and explained little among‐population variation. In multitrait space, phenotypic trajectories of lineages colonising low from high predation regimes were not parallel. Our results are consistent with reduced predation risk facilitating adaptive differentiation, potentially by female choice, but suggest that this proceeds in independent directions of multitrait space across lineages. Pool‐sequencing data also revealed SNPs showing greater differentiation than expected under neutrality, among which some are found in genes contributing to colour pattern variation, presenting opportunities for future genetic study. see also the Perspective by Rebecca C. Fuller. [ABSTRACT FROM AUTHOR]

Published

2022

138. Comparative anatomy of the rostrosoma of Solifugae, Pseudoscorpiones and Acari.

Author

Starck, J. Matthias, Belojević, Jelena, Brozio, Jason, and Mehnert, Lisa

Subjects

*PSEUDOSCORPIONS, *COMPARATIVE anatomy, *HISTOLOGY, *FLOOR plans, *PARASITIFORMES

Abstract

We compare the microscopic anatomy of the mouthparts of representative species of Solifugae, Pseudoscorpiones and Parasitiformes (Acari). Specifically, we focus on the epistome, the labrum, the lateral lips (= endites of the pedipalpal coxae) and the musculature of the pharyngeal suction pump. We provide evidence that the labrum is reduced in Solifugae, but present and functional in Pseudoscorpiones and Acari. The epistome constitutes the entire dorsal face of the rostrosoma in Solifugae, but is internalized into the prosoma in Pseudoscorpiones. In Acari, the epistome shows an ancestral morphology, probably close to the ground pattern of chelicerates. The lateral lips of Solifugae contribute to the ventral face of the rostrosoma and the two lips of the mouth opening. In Solifugae, the ventral rostrosoma also includes a sclerite that might derive from a tritosternum. In Pseudoscorpiones, the lateral lips remain independent of the rostrosoma, they interlock ventral to the rostrosoma forming a perioral space. Here, the rostrosoma has an unpaired ventral lip of unresolved morphological origin, which is, however, clearly distinct from the lateral lips of Solifugae. The pharyngeal suction pump differs in all three clades in attachment, number of muscles and origin of muscles. We interpret the data as evidence for independent, parallel evolution of elements of the ground pattern of the (eu)chelicerate mouth parts. Based on the morphological elements of a common euchelicerate ground plan, the rostrosoma evolved independently in the three clades. We reject earlier hypotheses that consider the rostrosoma a character to support a phylogenetic relationship of the three clades. [ABSTRACT FROM AUTHOR]

Published

2022

139. distinct morphological phenotypes of Southeast Asian aborigines are shaped by novel mechanisms for adaptation to tropical rainforests.

Author

Zhang, Xiaoming, Liu, Qi, Zhang, Hui, Zhao, Shilei, Huang, Jiahui, Sovannary, Tuot, Bunnath, Long, Aun, Hong Seang, Samnom, Ham, Su, Bing, and Chen, Hua

Subjects

*RAIN forests, *INDIGENOUS peoples, *PHENOTYPES, *HUMAN genetics, *WHOLE genome sequencing

Abstract

Southeast Asian aborigines, the hunter-gatherer populations living in tropical rainforests, exhibit distinct morphological phenotypes, including short stature, dark skin, curly hair and a wide and snub nose. The underlying genetic architecture and evolutionary mechanism of these phenotypes remain a long-term mystery. We conducted whole genome deep sequencing of 81 Cambodian aborigines from eight ethnic groups. Through a genome-wide scan of selective sweeps, we discovered key genes harboring Cambodian-enriched mutations that may contribute to their phenotypes, including two hair morphogenesis genes (TCHH and TCHHL1), one nasal morphology gene (PAX3) and a set of genes (such as ENTPD1-AS1) associated with short stature. The identified new genes and novel mutations suggest an independent origin of the distinct phenotypes in Cambodian aborigines through parallel evolution, refuting the long-standing argument on the common ancestry of these phenotypes among the worldwide rainforest hunter-gatherers. Notably, our discovery reveals that various types of molecular mechanisms, including antisense transcription and epigenetic regulation, contribute to human morphogenesis, providing novel insights into the genetics of human environmental adaptation. [ABSTRACT FROM AUTHOR]

Published

2022

140. Differentiation in the genetic basis of stem trichome development between cultivated tetraploid cotton species

Author

Rong Yuan, Yuefen Cao, Tengyu Li, Feng Yang, Li Yu, Yuan Qin, Xiongming Du, Fang Liu, Mingquan Ding, Yurong Jiang, Hua Zhang, Andrew H. Paterson, and Junkang Rong

Subjects

Cotton, Stem trichome, Seed fiber, Genetic mapping, Correlation analysis, Parallel evolution, Botany, QK1-989

Abstract

Abstract Background Cotton stem trichomes and seed fibers are each single celled structures formed by protrusions of epidermal cells, and were found sharing the overlapping molecular mechanism. Compared with fibers, cotton stem trichomes are more easily observed, but the molecular mechanisms underlying their development are still poorly understood. Results In this study, Gossypium hirsutum (Gh) and G. barbadense (Gb) were found to differ greatly in percentages of varieties/accessions with glabrous stems and in trichome density, length, and number per trichopore. Gh varieties normally had long singular and clustered trichomes, while Gb varieties had short clustered trichomes. Genetic mapping using five F2 populations from crosses between glabrous varieties and those with different types of stem trichomes revealed that much variation among stem trichome phenotypes could be accounted for by different combinations of genes/alleles on Chr. 06 and Chr. 24. The twenty- six F1 generations from crosses between varieties with different types of trichomes had varied phenotypes, further suggesting that the trichomes of tetraploid cotton were controlled by different genes/alleles. Compared to modern varieties, a greater proportion of Gh wild accessions were glabrous or had shorter and denser trichomes; whereas a smaller proportion of Gb primitive accessions had glabrous stems. A close correlation between fuzz fiber number and stem trichome density was observed in both Gh and Gb primitive accessions and modern varieties. Conclusion Based on these findings, we hypothesize that stem trichomes evolved in parallel with seed fibers during the domestication of cultivated tetraploid cotton. In addition, the current results illustrated that stem trichome can be used as a morphological index of fiber quality in cotton conventional breeding.

Published

2021

141. A century of intermittent eco‐evolutionary feedbacks resulted in novel trait combinations in invasive Great Lakes alewives (Alosa pseudoharengus)

Author

Shelby E. Smith, Eric P. Palkovacs, Brian C. Weidel, David B. Bunnell, Andrew W. Jones, and Devin D. Bloom

Subjects

body shape, eco‐evolutionary dynamics, introduced species, migration, parallel evolution, Evolution, QH359-425

Abstract

Abstract Species introductions provide opportunities to quantify rates and patterns of evolutionary change in response to novel environments. Alewives (Alosa pseudoharengus) are native to the East Coast of North America where they ascend coastal rivers to spawn in lakes and then return to the ocean. Some populations have become landlocked within the last 350 years and diverged phenotypically from their ancestral marine population. More recently, alewives were introduced to the Laurentian Great Lakes (~150 years ago), but these populations have not been compared to East Coast anadromous and landlocked populations. We quantified 95 years of evolution in foraging traits and overall body shape of Great Lakes alewives and compared patterns of phenotypic evolution of Great Lakes alewives to East Coast anadromous and landlocked populations. Our results suggest that gill raker spacing in Great Lakes alewives has evolved in a dynamic pattern that is consistent with responses to strong but intermittent eco‐evolutionary feedbacks with zooplankton size. Following their initial colonization of Lakes Ontario and Michigan, dense alewife populations likely depleted large‐bodied zooplankton, which drove a decrease in alewife gill raker spacing. However, the introduction of large, non‐native zooplankton to the Great Lakes in later decades resulted in an increase in gill raker spacing, and present‐day Great Lakes alewives have gill raker spacing patterns that are similar to the ancestral East Coast anadromous population. Conversely, contemporary Great Lakes alewife populations possess a gape width consistent with East Coast landlocked populations. Body shape showed remarkable parallel evolution with East Coast landlocked populations, likely due to a shared response to the loss of long‐distance movement or migrations. Our results suggest the colonization of a new environment and cessation of migration can result in rapid parallel evolution in some traits, but contingency also plays a role, and a dynamic ecosystem can also yield novel trait combinations.

Published

2020

142. The genetics of adaptation in freshwater Eurasian shad (Alosa)

Author

Stephen J. Sabatino, Paulo Pereira, Miguel Carneiro, Jolita Dilytė, John Patrick Archer, Antonio Munoz, Francesco Nonnis‐Marzano, and Antonio Murias

Subjects

adaptation, genomics, parallel evolution, phenotypic convergence, whole‐genome pool‐seq, Ecology, QH540-549.5

Abstract

Abstract Studying the genetics of phenotypic convergence can yield important insights into adaptive evolution. Here, we conducted a comparative genomic study of four lineages (species and subspecies) of anadromous shad (Alosa) that have independently evolved life cycles entirely completed in freshwater. Three naturally diverged (A. fallax lacustris, A. f. killarnensis, and A. macedonica), and the fourth (A. alosa) was artificially landlocked during the last century. To conduct this analysis, we assembled and annotated a draft of the A. alosa genome and generated whole‐genome sequencing for 16 anadromous and freshwater populations of shad. Widespread evidence for parallel genetic changes in freshwater populations within lineages was found. In freshwater A. alosa, which have only been diverging for tens of generations, this shows that parallel adaptive evolution can rapidly occur. However, parallel genetic changes across lineages were comparatively rare. The degree of genetic parallelism was not strongly related to the number of shared polymorphisms between lineages, thus suggesting that other factors such as divergence among ancestral populations or environmental variation may influence genetic parallelism across these lineages. These overall patterns were exemplified by genetic differentiation involving a paralog of ATPase‐α1 that appears to be under selection in just two of the more distantly related lineages studied, A. f. lacustris and A. alosa. Our findings provide insights into the genetic architecture of adaptation and parallel evolution along a continuum of population divergence.

Published

2022

143. Parallel Evolution of C-Type Lectin Domain Gene Family Sizes in Insect-Vectored Nematodes

Author

Jing Ning, Jiao Zhou, Haixiang Wang, Yaning Liu, Faheem Ahmad, Xiaohui Feng, Yu Fu, Xiaoting Gu, and Lilin Zhao

Subjects

C-type lectin, gene family, insect vector, co-evolution, parallel evolution, Plant culture, SB1-1110

Abstract

The dispersal stage of pathogens is crucial for the successful spread and infection of their hosts. Some plant-parasitic nematodes (PPNs) have evolved specialized dispersal stages to reach healthy hosts by being carried out by insect vectors. Because gene gain and loss is a major factor contributing to the evolution of novel characteristics, it is essential to clarify the gene family characteristics among nematodes with different dispersal modes to disentangle the evolution of insect-mediated dispersal. Here, the size of the C-type lectin (CTL) family genes of insect-vectored nematodes was found to be drastically reduced compared with those of self-dispersing nematodes, whereas the diversity of their functional domains was significantly higher. The gene family sizes of vector-dispersed nematodes were only a twentieth of the size of that of a self-dispersing (i.e., without a biotic vector) nematode model Caenorhabditis elegans, and these genes were inactive during the dispersal stage. Phylogenetic analysis showed that some CTL genes of vector-borne PPNs shared higher homology to the animal parasitic nematodes compared with other PPNs. Moreover, homology modeling predicted that the CTLs of insect-vectored nematodes bear remarkable structural similarity to the lectin genes of their vector's immune system. Because CTL genes are important sugar-binding proteins for the innate immune response of C. elegans, the loss of some CTL genes of vector-transmitted PPNs might be responsible for their parallel adaptations to a mutualistic relationship with their vector. These results expand our understanding of the evolutionary benefits of vector-mediated transmission for the nematode and vector-nematode co-evolution.

Published

2022

144. Domain-Dependent Evolution Explains Functional Homology of Protostome and Deuterostome Complement C3-Like Proteins

Author

Maoxiao Peng, Zhi Li, João C. R. Cardoso, Donghong Niu, Xiaojun Liu, Zhiguo Dong, Jiale Li, and Deborah M. Power

Subjects

conserved domain, functional homologues, parallel evolution, complement C3/C4/C5 family, C3-like protein a-subunit, Immunologic diseases. Allergy, RC581-607

Abstract

Complement proteins emerged early in evolution but outside the vertebrate clade they are poorly characterized. An evolutionary model of C3 family members revealed that in contrast to vertebrates the evolutionary trajectory of C3-like genes in cnidarian, protostomes and invertebrate deuterostomes was highly divergent due to independent lineage and species-specific duplications. The deduced C3-like and vertebrate C3, C4 and C5 proteins had low sequence conservation, but extraordinarily high structural conservation and 2-chain and 3-chain protein isoforms repeatedly emerged. Functional characterization of three C3-like isoforms in a bivalve representative revealed that in common with vertebrates complement proteins they were cleaved into two subunits, b and a, and the latter regulated inflammation-related genes, chemotaxis and phagocytosis. Changes within the thioester bond cleavage sites and the a-subunit protein (ANATO domain) explained the functional differentiation of bivalve C3-like. The emergence of domain-related functions early during evolution explains the overlapping functions of bivalve C3-like and vertebrate C3, C4 and C5, despite low sequence conservation and indicates that evolutionary pressure acted to conserve protein domain organization rather than the primary sequence.

Published

2022

145. The pdm3 Locus Is a Hotspot for Recurrent Evolution of Female-Limited Color Dimorphism in Drosophila

Author

Yassin, Amir, Delaney, Emily K, Reddiex, Adam J, Seher, Thaddeus D, Bastide, Héloïse, Appleton, Nicholas C, Lack, Justin B, David, Jean R, Chenoweth, Stephen F, Pool, John E, and Kopp, Artyom

Subjects

Biological Sciences, Ecology, Genetics, Infectious Diseases, Human Genome, Animals, Biological Evolution, Color, Drosophila, Drosophila Proteins, Female, Gene Expression Regulation, POU Domain Factors, Phenotype, Phylogeny, Pigmentation, Sequence Alignment, Sequence Analysis, DNA, Species Specificity, abdominal pigmentation, parallel evolution, pdm3, sex-limited polymorphism, sexual dimorphism, Medical and Health Sciences, Psychology and Cognitive Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences, Psychology

Abstract

Sex-limited polymorphisms are an intriguing form of sexual dimorphism that offer unique opportunities to reconstruct the evolutionary changes that decouple male and female traits encoded by a shared genome. We investigated the genetic basis of a Mendelian female-limited color dimorphism (FLCD) that segregates in natural populations of more than 20 species of the Drosophila montium subgroup. In these species, females have alternative abdominal color morphs, light and dark, whereas males have only one color morph in each species. A comprehensive molecular phylogeny of the montium subgroup supports multiple origins of FLCD. Despite this, we mapped FLCD to the same locus in four distantly related species-the transcription factor POU domain motif 3 (pdm3), which acts as a repressor of abdominal pigmentation in D. melanogaster. In D. serrata, FLCD maps to a structural variant in the first intron of pdm3; however, this variant is not found in the three other species-D. kikkawai, D. leontia, and D. burlai-and sequence analysis strongly suggests the pdm3 alleles responsible for FLCD originated independently at least three times. We propose that cis-regulatory changes in pdm3 form sexually dimorphic and monomorphic alleles that segregate within species and are preserved, at least in one species, by structural variation. Surprisingly, pdm3 has not been implicated in the evolution of sex-specific pigmentation outside the montium subgroup, suggesting that the genetic paths to sexual dimorphism may be constrained within a clade but variable across clades.

Published

2016

146. Convergent Evolution and the Origin of Complex Phenotypes in the Age of Systems Biology

Author

Washburn, Jacob D, Bird, Kevin A, Conant, Gavin C, and Pires, J Chris

Subjects

convergent evolution, parallel evolution, systems biology, comparative genomics, yeast, cancer, polyploidy, domestication, heterosis, C-4 photosynthesis, Evolutionary Biology, Plant Biology

Abstract

Convergent evolution has fascinated and occasionally mystified biologists since the principle of universal common ancestry was accepted. Similar phenotypes can arise by common ancestry (including preadaptations) or through constraints in the space of possible phenotypes and can increase in a population via either drift or selection. Assessing which of these mechanisms to invoke for any given example remains challenging for both simple and complex phenotypes. However, barriers in this area are slowly breaking down with recent advances in genomics and systems biology. Arenaissance in the study of convergent evolution may be on its way, as surprising explanations for similar phenotypes, such as the metabolic similarities between yeast and cancer cells, are uncovered with network and metabolic models. We argue that although examples of convergence are known from many domains of life, green plants in particular have remarkable promise for the study of convergence because they are experimentally tractable, have considerable “-omics” and systems biology resources available, and show convergence in a number of important and complex traits. Four such examples include the domestication syndrome, duplicate loss and retention patterns following whole-genome duplication, the multiple appearances of C4 and crassulacean acid metabolism photosynthesis, and hybrid vigor.

Published

2016

147. Repeated Evolution of Power-Amplified Predatory Strikes in Trap-Jaw Spiders.

Author

Wood, Hannah M, Parkinson, Dilworth Y, Griswold, Charles E, Gillespie, Rosemary G, and Elias, Damian O

Subjects

Muscle, Skeletal, Animals, Spiders, Predatory Behavior, Evolution, Molecular, Phylogeny, Movement, Biomechanical Phenomena, arachnid, ballistic movement, morphology, parallel evolution, phylogenetics, Muscle, Skeletal, Evolution, Molecular, Developmental Biology, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences

Abstract

Small animals possess intriguing morphological and behavioral traits that allow them to capture prey, including innovative structural mechanisms that produce ballistic movements by amplifying power [1-6]. Power amplification occurs when an organism produces a relatively high power output by releasing slowly stored energy almost instantaneously, resulting in movements that surpass the maximal power output of muscles [7]. For example, trap-jaw, power-amplified mechanisms have been described for several ant genera [5, 8], which have evolved some of the fastest known movements in the animal kingdom [6]. However, power-amplified predatory strikes were not previously known in one of the largest animal classes, the arachnids. Mecysmaucheniidae spiders, which occur only in New Zealand and southern South America, are tiny, cryptic, ground-dwelling spiders that rely on hunting rather than web-building to capture prey [9]. Analysis of high-speed video revealed that power-amplified mechanisms occur in some mecysmaucheniid species, with the fastest species being two orders of magnitude faster than the slowest species. Molecular phylogenetic analysis revealed that power-amplified cheliceral strikes have evolved four times independently within the family. Furthermore, we identified morphological innovations that directly relate to cheliceral function: a highly modified carapace in which the cheliceral muscles are oriented horizontally; modification of a cheliceral sclerite to have muscle attachments; and, in the power-amplified species, a thicker clypeus and clypeal apodemes. These structural innovations may have set the stage for the parallel evolution of ballistic predatory strikes.

Published

2016

148. Partially repeatable genetic basis of benthic adaptation in threespine sticklebacks

Author

Erickson, Priscilla A, Glazer, Andrew M, Killingbeck, Emily E, Agoglia, Rachel M, Baek, Jiyeon, Carsanaro, Sara M, Lee, Anthony M, Cleves, Phillip A, Schluter, Dolph, and Miller, Craig T

Subjects

Biological Sciences, Ecology, Genetics, Human Genome, Adaptation, Physiological, Animals, Biological Evolution, British Columbia, Chromosome Mapping, Crosses, Genetic, Genetic Linkage, Lakes, Phenotype, Quantitative Trait Loci, Selection, Genetic, Smegmamorpha, Convergent evolution, genotyping-by-sequencing, parallel evolution, QTL, skeleton, Evolutionary Biology, Evolutionary biology

Abstract

The extent to which convergent adaptation to similar ecological niches occurs by a predictable genetic basis remains a fundamental question in biology. Threespine stickleback fish have undergone an adaptive radiation in which ancestral oceanic populations repeatedly colonized and adapted to freshwater habitats. In multiple lakes in British Columbia, two different freshwater ecotypes have evolved: a deep-bodied benthic form adapted to forage near the lake substrate, and a narrow-bodied limnetic form adapted to forage in open water. Here, we use genome-wide linkage mapping in marine × benthic F2 genetic crosses to test the extent of shared genomic regions underlying benthic adaptation in three benthic populations. We identify at least 100 Quantitative Trait Loci (QTL) harboring genes influencing skeletal morphology. The majority of QTL (57%) are unique to one cross. However, four genomic regions affecting eight craniofacial and armor phenotypes are found in all three benthic populations. We find that QTL are clustered in the genome and overlapping QTL regions are enriched for genomic signatures of natural selection. These findings suggest that benthic adaptation has occurred via both parallel and nonparallel genetic changes.

Published

2016

149. Independent and parallel evolution of new genes by gene duplication in two origins of C4 photosynthesis provides new insight into the mechanism of phloem loading in C4 species

Author

Kelly, Steven [Univ. of Oxford, Oxford (United Kingdom)]

Published

2016

150. Cast away in the Adriatic: Low degree of parallel genetic differentiation in three‐spined sticklebacks.

Author

Dahms, Carolin, Kemppainen, Petri, Zanella, Linda N., Zanella, Davor, Carosi, Antonella, Merilä, Juha, and Momigliano, Paolo

Subjects

*THREESPINE stickleback, *GENETIC drift, *WHOLE genome sequencing, *GENETIC variation, *COLONIZATION (Ecology), *FRESHWATER biodiversity, *GENE flow

Abstract

The three‐spined stickleback (Gasterosteus aculeatus) has repeatedly and independently adapted to freshwater habitats from standing genetic variation (SGV) following colonization from the sea. However, in the Mediterranean Sea G. aculeatus is believed to have gone extinct, and thus the spread of locally adapted alleles between different freshwater populations via the sea since then has been highly unlikely. This is expected to limit parallel evolution, that is the extent to which phylogenetically related alleles can be shared among independently colonized freshwater populations. Using whole genome and 2b‐RAD sequencing data, we compared levels of genetic differentiation and genetic parallelism of 15 Adriatic stickleback populations to 19 Pacific, Atlantic and Caspian populations, where gene flow between freshwater populations across extant marine populations is still possible. Our findings support previous studies suggesting that Adriatic populations are highly differentiated (average FST ≈ 0.45), of low genetic diversity and connectivity, and likely to stem from multiple independent colonizations during the Pleistocene. Linkage disequilibrium network analyses in combination with linear mixed models nevertheless revealed several parallel marine–freshwater differentiated genomic regions, although still not to the extent observed elsewhere in the world. We hypothesize that current levels of genetic parallelism in the Adriatic lineages are a relic of freshwater adaptation from SGV prior to the extinction of marine sticklebacks in the Mediterranean that has persisted despite substantial genetic drift experienced by the Adriatic stickleback isolates. [ABSTRACT FROM AUTHOR]

Published

2022