Your search keyword '"genomic architecture"' showing total 268 results

251. Comparative Genomics of Methanopyrus sp. SNP6 and KOL6 Revealing Genomic Regions of Plasticity Implicated in Extremely Thermophilic Profiles.

Author

Yu Z, Ma Y, Zhong W, Qiu J, and Li J

Abstract

Methanopyrus spp. are usually isolated from harsh niches, such as high osmotic pressure and extreme temperature. However, the molecular mechanisms for their environmental adaption are poorly understood. Archaeal species is commonly considered as primitive organism. The evolutional placement of archaea is a fundamental and intriguing scientific question. We sequenced the genomes of Methanopyrus strains SNP6 and KOL6 isolated from the Atlantic and Iceland, respectively. Comparative genomic analysis revealed genetic diversity and instability implicated in niche adaption, including a number of transporter- and integrase/transposase-related genes. Pan-genome analysis also defined the gene pool of Methanopyrus spp., in addition of ~120-Kb genomic region of plasticity impacting cognate genomic architecture. We believe that Methanopyrus genomics could facilitate efficient investigation/recognition of archaeal phylogenetic diverse patterns, as well as improve understanding of biological roles and significance of these versatile microbes.

Published

2017

252. Mapping genomes in 3D

Author

Nicole Rusk

Subjects

ComputingMethodologies_PATTERNRECOGNITION, Evolutionary biology, Genomic architecture, High resolution, Cell Biology, Biology, Molecular Biology, Biochemistry, Genome, Biotechnology

Abstract

Refinements in methods to uncover the higher-order structure of the genome will allow functional insight into genomic architecture at high resolution.

Published

2009

253. [Untitled]

Author

Doron Lancet, Tsviya Olender, and Ronny Aloni

Subjects

Genetics, Olfactory receptor, medicine.anatomical_structure, Phylogenetics, Genomic architecture, medicine, Sequence alignment, Computational biology, Biology, Genome, Gene, Human genetics, Conserved sequence

Abstract

Background Mammalian olfactory receptor (OR) genes reside in numerous genomic clusters of up to several dozen genes. Whole-genome sequence alignment nets of five mammals allow their comprehensive comparison, aimed at reconstructing the ancestral olfactory subgenome.

Published

2006

254. Neurogenomics and the role of a large mutational target on rapid behavioral change.

Author

Stanley CE Jr and Kulathinal RJ

Subjects

Animals, Behavior, Biological Evolution, Evolution, Molecular, Humans, Behavior, Animal, Genome, Mutation

Abstract

Background: Behavior, while complex and dynamic, is among the most diverse, derived, and rapidly evolving traits in animals. The highly labile nature of heritable behavioral change is observed in such evolutionary phenomena as the emergence of converged behaviors in domesticated animals, the rapid evolution of preferences, and the routine development of ethological isolation between diverging populations and species. In fact, it is believed that nervous system development and its potential to evolve a seemingly infinite array of behavioral innovations played a major role in the successful diversification of metazoans, including our own human lineage. However, unlike other rapidly evolving functional systems such as sperm-egg interactions and immune defense, the genetic basis of rapid behavioral change remains elusive., Presentation of the Hypothesis: Here we propose that the rapid divergence and widespread novelty of innate and adaptive behavior is primarily a function of its genomic architecture. Specifically, we hypothesize that the broad diversity of behavioral phenotypes present at micro- and macroevolutionary scales is promoted by a disproportionately large mutational target of neurogenic genes. We present evidence that these large neuro-behavioral targets are significant and ubiquitous in animal genomes and suggest that behavior's novelty and rapid emergence are driven by a number of factors including more selection on a larger pool of variants, a greater role of phenotypic plasticity, and/or unique molecular features present in large genes. We briefly discuss the origins of these large neurogenic genes, as they relate to the remarkable diversity of metazoan behaviors, and highlight key consequences on both behavioral traits and neurogenic disease across, respectively, evolutionary and ontogenetic time scales., Testing the Hypothesis: Current approaches to studying the genetic mechanisms underlying rapid phenotypic change primarily focus on identifying signatures of Darwinian selection in protein-coding regions. In contrast, the large mutational target hypothesis places genomic architecture and a larger allelic pool at the forefront of rapid evolutionary change, particularly in genetic systems that are polygenic and regulatory in nature. Genomic data from brain and neural tissues in mammals as well as a preliminary survey of neurogenic genes from comparative genomic data support this hypothesis while rejecting both positive and relaxed selection on proteins or higher mutation rates. In mammals and invertebrates, neurogenic genes harbor larger protein-coding regions and possess a richer regulatory repertoire of miRNA targets and transcription factor binding sites. Overall, neurogenic genes cover a disproportionately large genomic fraction, providing a sizeable substrate for evolutionary, genetic, and molecular mechanisms to act upon. Readily available comparative and functional genomic data provide unexplored opportunities to test whether a distinct neurogenomic architecture can promote rapid behavioral change via several mechanisms unique to large genes, and which components of this large footprint are uniquely metazoan., Implications of the Hypothesis: The large mutational target hypothesis highlights the eminent roles of mutation and functional genomic architecture in generating rapid developmental and evolutionary change. It has broad implications on our understanding of the genetics of complex adaptive traits such as behavior by focusing on the importance of mutational input, from SNPs to alternative transcripts to transposable elements, on driving evolutionary rates of functional systems. Such functional divergence has important implications in promoting behavioral isolation across short- and long-term timescales. Due to genome-scaled polygenic adaptation, the large target effect also contributes to our inability to identify adapted behavioral candidate genes. The presence of large neurogenic genes, particularly in the mammalian brain and other neural tissues, further offers emerging insight into the etiology of neurodevelopmental and neurodegenerative diseases. The well-known correlation between neurological spectrum disorders in children and paternal age may simply be a direct result of aging fathers accumulating mutations across these large neurodevelopmental genes. The large mutational target hypothesis can also explain the rapid evolution of other functional systems covering a large genomic fraction such as male fertility and its preferential association with hybrid male sterility among closely related taxa. Overall, a focus on mutational potential may increase our power in understanding the genetic basis of complex phenotypes such as behavior while filling a general gap in understanding their evolution.

Published

2016

255. Recombination patterns reveal information about centromere location on linkage maps.

Author

Limborg MT, McKinney GJ, Seeb LW, and Seeb JE

Subjects

Animals, Hordeum genetics, Salmonidae genetics, Centromere, Chromosome Mapping, Computational Biology methods, Genetic Linkage, Recombination, Genetic

Abstract

Linkage mapping is often used to identify genes associated with phenotypic traits and for aiding genome assemblies. Still, many emerging maps do not locate centromeres - an essential component of the genomic landscape. Here, we demonstrate that for genomes with strong chiasma interference, approximate centromere placement is possible by phasing the same data used to generate linkage maps. Assuming one obligate crossover per chromosome arm, information about centromere location can be revealed by tracking the accumulated recombination frequency along linkage groups, similar to half-tetrad analyses. We validate the method on a linkage map for sockeye salmon (Oncorhynchus nerka) with known centromeric regions. Further tests suggest that the method will work well in other salmonids and other eukaryotes. However, the method performed weakly when applied to a male linkage map (rainbow trout; O. mykiss) characterized by low and unevenly distributed recombination - a general feature of male meiosis in many species. Further, a high frequency of double crossovers along chromosome arms in barley reduced resolution for locating centromeric regions on most linkage groups. Despite these limitations, our method should work well for high-density maps in species with strong recombination interference and will enrich many existing and future mapping resources., (© 2015 The Authors. Molecular Ecology Resources published by John Wiley & Sons Ltd.)

Published

2016

256. Evidence for extensive parallelism but divergent genomic architecture of adaptation along altitudinal and latitudinal gradients in Populus trichocarpa.

Author

Holliday JA, Zhou L, Bawa R, Zhang M, and Oubida RW

Subjects

Cluster Analysis, CpG Islands genetics, Gene Ontology, Genetic Loci, Polymorphism, Single Nucleotide genetics, Adaptation, Physiological genetics, Altitude, Genome, Plant, Populus genetics, Populus physiology

Abstract

Adaptation to climate across latitude and altitude reflects shared climatic constraints, which may lead to parallel adaptation. However, theory predicts that higher gene flow should favor more concentrated genomic architectures, which would lead to fewer locally maladapted recombinants. We used exome capture to resequence the gene space along a latitudinal and two altitudinal transects in the model tree Populus trichocapra. Adaptive trait phenotyping was coupled with FST outlier tests and sliding window analysis to assess the degree of parallel adaptation as well as the genomic distribution of outlier loci. Up to 51% of outlier loci overlapped between transect pairs and up to 15% of these loci overlapped among all three transects. Genomic clustering of adaptive loci was more pronounced for altitudinal than latitudinal transects. In both altitudinal transects, there was a larger number of these 'islands of divergence', which were on average longer and included several of exceptional physical length. Our results suggest that recapitulation of genetic clines over latitude and altitude involves extensive parallelism, but that steep altitudinal clines generate islands of divergence. This suggests that physical proximity of genes in coadapted complexes may buffer against the movement of maladapted alleles from geographically proximal but climatically distinct populations., (© 2015 The Authors. New Phytologist © 2015 New Phytologist Trust.)

Published

2016

257. Genomic patterns of species diversity and divergence in Eucalyptus.

Author

Hudson CJ, Freeman JS, Myburg AA, Potts BM, and Vaillancourt RE

Subjects

Bayes Theorem, Chromosomes, Plant genetics, Gene Duplication, Genes, Plant, Genetic Markers, Geography, Principal Component Analysis, Species Specificity, Statistics, Nonparametric, Eucalyptus genetics, Genetic Variation, Genome, Plant

Abstract

We examined genome-wide patterns of DNA sequence diversity and divergence among six species of the important tree genus Eucalyptus and investigated their relationship with genomic architecture. Using c. 90 range-wide individuals of each Eucalyptus species (E. grandis, E. urophylla, E. globulus, E. nitens, E. dunnii and E. camaldulensis), genetic diversity and divergence were estimated from 2840 polymorphic diversity arrays technology markers covering the 11 chromosomes. Species differentiating markers (SDMs) identified in each of 15 pairwise species comparisons, along with species diversity (HHW ) and divergence (FST ), were projected onto the E. grandis reference genome. Across all species comparisons, SDMs totalled 1.1-5.3% of markers and were widely distributed throughout the genome. Marker divergence (FST and SDMs) and diversity differed among and within chromosomes. Patterns of diversity and divergence were broadly conserved across species and significantly associated with genomic features, including the proximity of markers to genes, the relative number of clusters of tandem duplications, and gene density within or among chromosomes. These results suggest that genomic architecture influences patterns of species diversity and divergence in the genus. This influence is evident across the six species, encompassing diverse phylogenetic lineages, geography and ecology., (© 2015 University of Tasmania New Phytologist © 2015 New Phytologist Trust.)

Published

2015

258. Genomic atolls of differentiation in coral reef fishes (Hypoplectrus spp., Serranidae).

Author

Puebla O, Bermingham E, and McMillan WO

Subjects

Animals, Belize, Cluster Analysis, Coral Reefs, Genetics, Population, Honduras, Panama, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Evolution, Molecular, Genetic Speciation, Perciformes genetics, Sympatry

Abstract

Because the vast majority of species are well diverged, relatively little is known about the genomic architecture of speciation during the early stages of divergence. Species within recent evolutionary radiations are often minimally diverged from a genomic perspective, and therefore provide rare opportunities to address this question. Here, we leverage the hamlet radiation (Hypoplectrus spp., brightly coloured reef fishes from the tropical western Atlantic) to characterize genomic divergence during the early stages of speciation. Transect surveys and spawning observations in Belize, Honduras and Panama confirm that sympatric barred (H. puella), black (H. nigricans) and butter (H. unicolor) hamlets are phenotypically distinct and reproductively isolated, although hybrid spawnings and individuals with intermediate phenotypes are seen on rare occasions. A survey of approximately 100 000 restriction site-associated SNPs in 126 samples from the three species across the three replicate populations reveals extremely slight genomewide divergence among species (FST  = 0.0038), indicating that ecomorphological differences and functional reproductive isolation are maintained in sympatry in a backdrop of extraordinary genomic similarity. Nonetheless, a very small proportion of SNPs (0.05% on average) are identified as FST outliers among sympatric species. Remarkably, a single SNP is identified as an outlier in repeated populations for the same species pair. A minicontig assembled de novo around this SNP falls into the genomic region containing the HoxCa10 and HoxCa11 genes in 10 teleost species, suggesting an important role for Hox gene evolution in this radiation. This finding, if confirmed, would provide a better understanding of the links between micro- and macroevolutionary processes., (© 2014 John Wiley & Sons Ltd.)

Published

2014

259. The genomic architecture of the PROS1 gene underlying large tandem duplication mutation that causes thrombophilia from hereditary protein S deficiency.

Author

Seo JY, Lee KO, Kim SH, Oh D, Kim DK, and Kim HJ

Subjects

Adult, Base Sequence, Case-Control Studies, Chromosome Breakpoints, Humans, Introns, Male, Molecular Sequence Data, Protein S, Blood Proteins genetics, Gene Duplication, Genome, Human, Protein S Deficiency genetics, Tandem Repeat Sequences

Abstract

Hereditary protein S deficiency from a mutation in the PROS1 gene causes a genetic predisposition to develop venous thromboembolic disorders in humans. Recently, the acknowledgment of the clinical significance of large copy number mutations in protein S deficiency has increased. In this study, the authors investigated the genomic architecture of PROS1 in order to understand the microscopic sequence environment leading to large intragenic copy number mutations in the gene. The study subjects were 3 unrelated male patients with hereditary protein S deficiency from a tandem duplication mutation involving exons 5-10 of PROS1. Breakpoint analyses revealed 10-bp microhomology sequences in the intervening sequence (IVS)-4 and IVS-10 at the duplication junction without additional sequence changes, suggesting a single replication-based event as the potential molecular mechanism of rearrangement and founder effect in the mutant alleles. Further analyses on nucleotide sequences flanking the microhomology sequence revealed the presence of a repeat element (LTR-ERV1) and quadruplex-forming G-rich sequences in IVS-4. The results from genotyping multi-allelic short tandem repeats supported founder effect in the identical mutations in the 3 unrelated patients. In conclusion, we identified unique genomic architectures in the intervening sequences of PROS1 that underlie a large intragenic tandem duplication mutation leading to inherited thrombophilia., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

260. Assessing when chromosomal rearrangements affect the dynamics of speciation: implications from computer simulations.

Author

Feder JL, Nosil P, and Flaxman SM

Abstract

Many hypotheses have been put forth to explain the origin and spread of inversions, and their significance for speciation. Several recent genic models have proposed that inversions promote speciation with gene flow due to the adaptive significance of the genes contained within them and because of the effects inversions have on suppressing recombination. However, the consequences of inversions for the dynamics of genome wide divergence across the speciation continuum remain unclear, an issue we examine here. We review a framework for the genomics of speciation involving the congealing of the genome into alternate adaptive states representing species ("genome wide congealing"). We then place inversions in this context as examples of how genetic hitchhiking can potentially hasten genome wide congealing. Specifically, we use simulation models to (i) examine the conditions under which inversions may speed genome congealing and (ii) quantify predicted magnitudes of these effects. Effects of inversions on promoting speciation were most common and pronounced when inversions were initially fixed between populations before secondary contact and adaptation involved many genes with small fitness effects. Further work is required on the role of underdominance and epistasis between a few loci of major effect within inversions. The results highlight five important aspects of the roles of inversions in speciation: (i) the geographic context of the origins and spread of inversions, (ii) the conditions under which inversions can facilitate divergence, (iii) the magnitude of that facilitation, (iv) the extent to which the buildup of divergence is likely to be biased within vs. outside of inversions, and (v) the dynamics of the appearance and disappearance of exceptional divergence within inversions. We conclude by discussing the empirical challenges in showing that inversions play a central role in facilitating speciation with gene flow.

Published

2014

261. Theoretical models of the influence of genomic architecture on the dynamics of speciation.

Author

Flaxman SM, Wacholder AC, Feder JL, and Nosil P

Subjects

Cluster Analysis, Computer Simulation, Gene Flow, Genetic Linkage, Mutation, Biological Evolution, Genetic Speciation, Genetics, Population methods, Models, Genetic

Abstract

A long-standing problem in evolutionary biology has been determining whether and how gradual, incremental changes at the gene level can account for rapid speciation and bursts of adaptive radiation. Using genome-scale computer simulations, we extend previous theory showing how gradual adaptive change can generate nonlinear population transitions, resulting in the rapid formation of new, reproductively isolated species. We show that these transitions occur via a mechanism rooted in a basic property of biological heredity: the organization of genes in genomes. Genomic organization of genes facilitates two processes: (i) the build-up of statistical associations among large numbers of genes and (ii) the action of divergent selection on persistent combinations of alleles. When a population has accumulated a critical amount of standing, divergently selected variation, the combination of these two processes allows many mutations of small effect to act synergistically and precipitously split one population into two discontinuous, reproductively isolated groups. Periods of allopatry, chromosomal linkage among loci, and large-effect alleles can facilitate this process under some conditions, but are not required for it. Our results complement and extend existing theory on alternative stable states during population divergence, distinct phases of speciation and the rapid emergence of multilocus barriers to gene flow. The results are thus a step towards aligning population genomic theory with modern empirical studies., (© 2014 John Wiley & Sons Ltd.)

Published

2014

262. Genome-wide congealing and rapid transitions across the speciation continuum during speciation with gene flow.

Author

Feder JL, Nosil P, Wacholder AC, Egan SP, Berlocher SH, and Flaxman SM

Subjects

Animals, Genes, Genetics, Population, Genome, Insect, Linkage Disequilibrium, Microsatellite Repeats, Mutation, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Reproductive Isolation, Selection, Genetic, Sympatry, Tephritidae genetics, Gene Flow, Genetic Speciation, Genome

Abstract

Our current understanding of speciation is often based on considering a relatively small number of genes, sometimes in isolation of one another. Here, we describe a possible emergent genome process involving the aggregate effect of many genes contributing to the evolution of reproductive isolation across the speciation continuum. When a threshold number of divergently selected mutations of modest to low fitness effects accumulate between populations diverging with gene flow, nonlinear transitions can occur in which levels of adaptive differentiation, linkage disequilibrium, and reproductive isolation dramatically increase. In effect, the genomes of the populations start to "congeal" into distinct entities representing different species. At this stage, reproductive isolation changes from being a characteristic of specific, divergently selected genes to a property of the genome. We examine conditions conducive to such genome-wide congealing (GWC), describe how to empirically test for GWC, and highlight a putative empirical example involving Rhagoletis fruit flies. We conclude with cautious optimism that the models and concepts discussed here, once extended to large numbers of neutral markers, may provide a framework for integrating information from genome scans, selection experiments, quantitative trait loci mapping, association studies, and natural history to develop a deeper understanding of the genomics of speciation., (© The American Genetic Association. 2014. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2014

263. Translating Neurogenomics Into New Medicines

Author

Michael D. Ehlers and Jens R. Wendland

Subjects

0301 basic medicine, Modern medicine, Neurogenetics, Genomics, Genome-wide association study, 03 medical and health sciences, 0302 clinical medicine, Circuits, Human genetics, Medicine, GWAS, Brain disorders, Biological Psychiatry, Neurogenomics, Psychiatry, business.industry, Translational medicine, 3. Good health, 030104 developmental biology, Genes, Genomic architecture, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Brain disorders remain one of the defining challenges of modern medicine and among the most poorly served with new therapeutics. Advances in human neurogenetics have begun to shed light on the genomic architecture of complex diseases of mood, cognition, brain development, and neurodegeneration. From genome-wide association studies to rare variants, these findings hold promise for defining the pathogenesis of brain disorders that have resisted simple molecular description. However, the path from genetics to new medicines is far from clear and can take decades, even for the most well-understood genetic disorders. In this review, we define three challenges for the field of neurogenetics that we believe must be addressed to translate human genetics efficiently into new therapeutics for brain disorders.

264. [Untitled]

Subjects

0303 health sciences, Haplotype, Genomics, Biology, Balancing selection, Structural variation, 03 medical and health sciences, 0302 clinical medicine, Evolutionary biology, Genetics, Genomic architecture, Mimicry, Biological sciences, 030217 neurology & neurosurgery, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Supergene

Abstract

Supergenes are genomic regions containing sets of tightly linked loci that control multi-trait phenotypic polymorphisms under balancing selection. Recent advances in genomics have uncovered significant variation in both the genomic architecture as well as the mode of origin of supergenes across diverse organismal systems. Although the role of genomic architecture for the origin of supergenes has been much discussed, differences in the genomic architecture also subsequently affect the evolutionary trajectory of supergenes and the rate of degeneration of supergene haplotypes. In this review, we synthesize recent genomic work and historical models of supergene evolution, highlighting how the genomic architecture of supergenes affects their evolutionary fate. We discuss how recent findings on classic supergenes involved in governing ant colony social form, mimicry in butterflies, and heterostyly in flowering plants relate to theoretical expectations. Furthermore, we use forward simulations to demonstrate that differences in genomic architecture affect the degeneration of supergenes. Finally, we discuss implications of the evolution of supergene haplotypes for the long-term fate of balanced polymorphisms governed by supergenes.

265. [Untitled]

Subjects

0301 basic medicine, Genetics, animal structures, biology, Resistance (ecology), Host (biology), Campylobacter, 030106 microbiology, biology.organism_classification, medicine.disease_cause, Campylobacter jejuni, Microbiology, Colonisation, 03 medical and health sciences, Inbred strain, medicine, Genomic architecture, Intestinal colonisation, Biotechnology

Abstract

Background Campylobacter is the leading cause of foodborne diarrhoeal illness in humans and is mostly acquired from consumption or handling of contaminated poultry meat. In the absence of effective licensed vaccines and inhibitors, selection for chickens with increased resistance to Campylobacter could potentially reduce its subsequent entry into the food chain. Campylobacter intestinal colonisation levels are influenced by the host genetics of the chicken. In the present study, two chicken populations were used to investigate the genetic architecture of avian resistance to colonisation: (i) a back-cross of two White Leghorn derived inbred lines [(61 x N) x N] known to differ in resistance to Campylobacter colonisation and (ii) a 9th generation advanced intercross (61 x N) line.

266. Neurogenomics and the role of a large mutational target on rapid behavioral change

Author

Craig E. Stanley and Rob J. Kulathinal

Subjects

0301 basic medicine, Mutation rate, Candidate gene, Immunology, Neurodevelopmental disease, Rapid evolution, Biology, Genomic architecture, Long genes, Neurogenome, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, Animals, Humans, Allele, Ecology, Evolution, Behavior and Systematics, 2. Zero hunger, Genetics, Neurogenomics, Behavior, Phenotypic plasticity, Genome, Behavior, Animal, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Applied Mathematics, Hypothesis, Biological Evolution, 030104 developmental biology, Evolutionary biology, Modeling and Simulation, Mutation, Sexual isolation, Adaptation, General Agricultural and Biological Sciences, Adaptive behavior (ecology), Functional divergence

Abstract

Background Behavior, while complex and dynamic, is among the most diverse, derived, and rapidly evolving traits in animals. The highly labile nature of heritable behavioral change is observed in such evolutionary phenomena as the emergence of converged behaviors in domesticated animals, the rapid evolution of preferences, and the routine development of ethological isolation between diverging populations and species. In fact, it is believed that nervous system development and its potential to evolve a seemingly infinite array of behavioral innovations played a major role in the successful diversification of metazoans, including our own human lineage. However, unlike other rapidly evolving functional systems such as sperm-egg interactions and immune defense, the genetic basis of rapid behavioral change remains elusive. Presentation of the hypothesis Here we propose that the rapid divergence and widespread novelty of innate and adaptive behavior is primarily a function of its genomic architecture. Specifically, we hypothesize that the broad diversity of behavioral phenotypes present at micro- and macroevolutionary scales is promoted by a disproportionately large mutational target of neurogenic genes. We present evidence that these large neuro-behavioral targets are significant and ubiquitous in animal genomes and suggest that behavior’s novelty and rapid emergence are driven by a number of factors including more selection on a larger pool of variants, a greater role of phenotypic plasticity, and/or unique molecular features present in large genes. We briefly discuss the origins of these large neurogenic genes, as they relate to the remarkable diversity of metazoan behaviors, and highlight key consequences on both behavioral traits and neurogenic disease across, respectively, evolutionary and ontogenetic time scales. Testing the hypothesis Current approaches to studying the genetic mechanisms underlying rapid phenotypic change primarily focus on identifying signatures of Darwinian selection in protein-coding regions. In contrast, the large mutational target hypothesis places genomic architecture and a larger allelic pool at the forefront of rapid evolutionary change, particularly in genetic systems that are polygenic and regulatory in nature. Genomic data from brain and neural tissues in mammals as well as a preliminary survey of neurogenic genes from comparative genomic data support this hypothesis while rejecting both positive and relaxed selection on proteins or higher mutation rates. In mammals and invertebrates, neurogenic genes harbor larger protein-coding regions and possess a richer regulatory repertoire of miRNA targets and transcription factor binding sites. Overall, neurogenic genes cover a disproportionately large genomic fraction, providing a sizeable substrate for evolutionary, genetic, and molecular mechanisms to act upon. Readily available comparative and functional genomic data provide unexplored opportunities to test whether a distinct neurogenomic architecture can promote rapid behavioral change via several mechanisms unique to large genes, and which components of this large footprint are uniquely metazoan. Implications of the hypothesis The large mutational target hypothesis highlights the eminent roles of mutation and functional genomic architecture in generating rapid developmental and evolutionary change. It has broad implications on our understanding of the genetics of complex adaptive traits such as behavior by focusing on the importance of mutational input, from SNPs to alternative transcripts to transposable elements, on driving evolutionary rates of functional systems. Such functional divergence has important implications in promoting behavioral isolation across short- and long-term timescales. Due to genome-scaled polygenic adaptation, the large target effect also contributes to our inability to identify adapted behavioral candidate genes. The presence of large neurogenic genes, particularly in the mammalian brain and other neural tissues, further offers emerging insight into the etiology of neurodevelopmental and neurodegenerative diseases. The well-known correlation between neurological spectrum disorders in children and paternal age may simply be a direct result of aging fathers accumulating mutations across these large neurodevelopmental genes. The large mutational target hypothesis can also explain the rapid evolution of other functional systems covering a large genomic fraction such as male fertility and its preferential association with hybrid male sterility among closely related taxa. Overall, a focus on mutational potential may increase our power in understanding the genetic basis of complex phenotypes such as behavior while filling a general gap in understanding their evolution. Electronic supplementary material The online version of this article (doi:10.1186/s13062-016-0162-1) contains supplementary material, which is available to authorized users.

267. Evidence for extensive parallelism but divergent genomic architecture of adaptation along altitudinal and latitudinal gradients in Populus trichocarpa

Published

2016

268. Genomic patterns of species diversity and divergence in Eucalyptus

Published

2015