Datasets for evolutionary comparative genomics

Many decisions about genome sequencing projects are directed by perceived gaps in the tree of life, or towards model organisms. With the goal of a better understanding of biology through the lens of evolution, however, there are additional genomes that are worth sequencing. One such rationale for whole-genome sequencing is discussed here, along with other important strategies for understanding the phenotypic divergence of species.     

Datasets for evolutionary comparative genomics

Many decisions about genome sequencing projects are directed by perceived gaps in the tree of life, or towards model organisms. With the goal of a better understanding of biology through the lens of evolution, however, there are additional genomes that are worth sequencing. One such rationale for whole-genome sequencing is discussed here, along with other important strategies for understanding the phenotypic divergence of species.     

A comprehensive framework for global patterns in biodiversity

The present study proposes to reconcile the different spatial and temporal scales of regional species production and local constraint on species richness. Although interactions between populations rapidly achieve equilibrium and limit membership in ecological communities locally, these interactions occur over heterogeneous environments within large regions, where the populations of species are stably regulated through competition and habitat selection. Consequently, exclusion of species from a region depends on long‐term regional‐scale environmental change or evolutionary change among interacting populations, bringing species production and extinction onto the same scale and establishing a link between local and regional processes.     

Isochores and the evolutionary genomics of vertebrates

The nuclear genomes of vertebrates are mosaics of isochores, very long stretches (>300kb) of DNA that are homogeneous in base composition and are compositionally correlated with the coding sequences that they embed. Isochores can be partitioned in a small number of families that cover a range of GC levels (GC is the molar ratio of guanine+cytosine in DNA), which is narrow in cold-blooded vertebrates, but broad in warm-blooded vertebrates. This difference is essentially due to the fact that the GC-richest 10-15% of the genomes of the ancestors of mammals and birds underwent two independent compositional transitions characterized by strong increases in GC levels. The similarity of isochore patterns across mammalian orders, on the one hand, and across avian orders, on the other, indicates that these higher GC levels were then maintained, at least since the appearance of ancestors of warm-blooded vertebrates. After a brief review of our current knowledge on the organization of the vertebrate genome, evidence will be presented here in favor of the idea that the generation and maintenance of the GC-richest isochores in the genomes of warm-blooded vertebrates were due to natural selection.     

Comparative genomics and evolutionary biology

Data of large-scale DNA sequencing are relevant to some of the most fundamental issues in evolutionary biology: suboptimality, homology, hierarchy, ancestry, novelties, the role of natural selection, and the relative importance of directional versus stabilizing selection. Already, these data provided the best available evidence for some evolutionary phenomena, and in several cases led to refinement of old concepts. Still, the Darwinian evolutionary paradigm will successfully accommodate comparative genomics.     

From the sequence to cell modeling: comprehensive functional genomics in Escherichia coli

As a result of the enormous amount of information that has been collected with E. coli over the past half century (e.g. genome sequence, mutant phenotypes, metabolic and regulatory networks, etc.), we now have detailed knowledge about gene regulation, protein activity, several hundred enzyme reactions, metabolic pathways, macromolecular machines, and regulatory interactions for this model organism. However, understanding how all these processes interact to form a living cell will require further characterization, quantification, data integration, and mathematical modeling, systems biology. No organism can rival E. coli with respect to the amount of available basic information and experimental tractability for the technologies needed for this undertaking. A focused, systematic effort to understand the E. coli cell will accelerate the development of new post-genomic technologies, including both experimental and computational tools. It will also lead to new technologies that will be applicable to other organisms, from microbes to plants, animals, and humans. E. coli is not only the best studied free-living model organism, but is also an extensively used microbe for industrial applications, especially for the production of small molecules of interest. It is an excellent representative of Gram-negative commensal bacteria. E. coli may represent a perfect model organism for systems biology that is aimed at elucidating both its free-living and commensal life-styles, which should open the door to whole-cell modeling and simulation.     

Molecular evolutionary genomics of birds

Insight into the molecular evolution of birds has been offered by the steady accumulation of avian DNA sequence data, recently culminating in the first draft sequence of an avian genome, that of chicken. By studying avian molecular evolution we can learn about adaptations and phenotypic evolution in birds, and also gain an understanding of the similarities and differences between mammalian and avian genomes. In both these lineages, there is pronounced isochore structure with highly variable GC content. However, while mammalian isochores are decaying, they are maintained in the chicken lineage, which is consistent with a biased gene conversion model where the high and variable recombination rate of birds reinforces heterogeneity in GC. In Galliformes, GC is positively correlated with the rate of nucleotide substitution; the mean neutral mutation rate is 0.12-0.15% at each site per million years but this estimate comes with significant local variation in the rate of mutation. Comparative genomics reveals lower d(N)/d(S) ratios on micro- compared to macrochromosomes, possibly due to population genetic effects or a non-random distribution of genes with respect to chromosome size. A non-random genomic distribution is shown by genes with sex-biased expression, with male-biased genes over-represented and female-biased genes under-represented on the Z chromosome. A strong effect of selection is evident on the non-recombining W chromosome with high d(N)/d(S) ratios and limited polymorphism. Nucleotide diversity in chicken is estimated at 4-5 x 10(-3) which might be seen as surprisingly high given presumed bottlenecks during domestication, but is lower than that recently observed in several natural populations of other species. Several important aspects of the molecular evolutionary process of birds remain to be understood and it can be anticipated that the upcoming genome sequence of a second bird species, the zebra finch, as well as the integration of data on gene expression, shall further advance our knowledge of avian evolution.     

phyloXML: XML for evolutionary biology and comparative genomics

Background  

Evolutionary trees are central to a wide range of biological studies. In many of these studies, tree nodes and branches need to be associated (or annotated) with various attributes. For example, in studies concerned with organismal relationships, tree nodes are associated with taxonomic names, whereas tree branches have lengths and oftentimes support values. Gene trees used in comparative genomics or phylogenomics are usually annotated with taxonomic information, genome-related data, such as gene names and functional annotations, as well as events such as gene duplications, speciations, or exon shufflings, combined with information related to the evolutionary tree itself. The data standards currently used for evolutionary trees have limited capacities to incorporate such annotations of different data types.     

Ecological and evolutionary genomics of Saccharomyces cerevisiae

Saccharomyces cerevisiae, the budding yeast, is the most thoroughly studied eukaryote at the cellular, molecular, and genetic levels. Yet, until recently, we knew very little about its ecology or population and evolutionary genetics. In recent years, it has been recognized that S. cerevisiae occupies numerous habitats and that populations harbour important genetic variation. There is therefore an increasing interest in understanding the evolutionary forces acting on the yeast genome. Several researchers have used the tools of functional genomics to study natural isolates of this unicellular fungus. Here, we review some of these studies, and show not only that budding yeast is a prime model system to address fundamental molecular and cellular biology questions, but also that it is becoming a powerful model species for ecological and evolutionary genomics studies as well.     

Comparative and evolutionary genomics of Yersinia pestis

Yersinia pestis is the causative agent of plague, causing three human plague pandemics in history. Comparative and evolutionary genomics of Y. pestis are extensively discussed in this review. Understanding the genomic variability and the adaptive evolution of Y. pestis from the genomic point of view will contribute greatly to plague detection, identification, control and prevention.     

A comprehensive expressed sequence tag linkage map for tiger salamander and Mexican axolotl: enabling gene mapping and comparative genomics in Ambystoma

Expressed sequence tag (EST) markers were developed for Ambystoma tigrinum tigrinum (Eastern tiger salamander) and for A. mexicanum (Mexican axolotl) to generate the first comprehensive linkage map for these model amphibians. We identified 14 large linkage groups (125.5-836.7 cM) that presumably correspond to the 14 haploid chromosomes in the Ambystoma genome. The extent of genome coverage for these linkage groups is apparently high because the total map size (5251 cM) falls within the range of theoretical estimates and is consistent with independent empirical estimates. Unlike most vertebrate species, linkage map size in Ambystoma is not strongly correlated with chromosome arm number. Presumably, the large physical genome size ( approximately 30 Gbp) is a major determinant of map size in Ambystoma. To demonstrate the utility of this resource, we mapped the position of two historically significant A. mexicanum mutants, white and melanoid, and also met, a quantitative trait locus (QTL) that contributes to variation in metamorphic timing. This new collection of EST-based PCR markers will better enable the Ambystoma system by facilitating development of new molecular probes, and the linkage map will allow comparative studies of this important vertebrate group.     

The evolutionary genomics of pathogen recombination

A pressing problem in studying the evolution of microbial pathogens is to determine the extent to which these genomes recombine. This information is essential for locating pathogenicity loci by using association studies or population genetic approaches. Recombination also complicates the use of phylogenetic approaches to estimate evolutionary parameters such as selection pressures. Reliable methods that detect and estimate the rate of recombination are, therefore, vital. This article reviews the approaches that are available for detecting and estimating recombination in microbial pathogens and how they can be used to understand pathogen evolution and to identify medically relevant loci.     

Habitat fragmentation and biodiversity: testing for the evolutionary effects of refugia

Concordant areas of endemism among taxa have important implications both for understanding mechanisms of speciation and for framing conservation priorities. Here we discuss the need for careful testing of phylogeographic data for evidence of such concordance, with particular reference to the Indonesian island of Sulawesi. This is because there are good reasons to question whether concordance between taxa is likely to be a common pattern, and because of the serious implications of incorrectly concluding that the biodiversity of a given area can be partitioned in this way.     

Making evolutionary history count: biodiversity planning for coral reef fishes and the conservation of evolutionary processes

Anthropogenic activities are having devastating impacts on marine systems with numerous knock-on effects on trophic functioning, species interactions and an accelerated loss of biodiversity. Establishing conservation areas can not only protect biodiversity, but also confer resilience against changes to coral reefs and their inhabitants. Planning for protection and conservation in marine systems is complex, but usually focuses on maintaining levels of biodiversity and protecting special and unique landscape features while avoiding negative impacts to socio-economic benefits. Conversely, the integration of evolutionary processes that have shaped extant species assemblages is rarely taken into account. However, it is as important to protect processes as it is to protect patterns for maintaining the evolutionary trajectories of populations and species. This review focuses on different approaches for integrating genetic analyses, such as phylogenetic diversity, phylogeography and the delineation of management units, temporal and spatial monitoring of genetic diversity and quantification of adaptive variation for protecting evolutionary resilience, into marine spatial planning, specifically for coral reef fishes. Many of these concepts are not yet readily applied to coral reef fish studies, but this synthesis highlights their potential and the importance of including historical processes into systematic biodiversity planning for conserving not only extant, but also future, biodiversity and its evolutionary potential.     

生物多样性综合评价方法研究

2002年召开的《生物多样性公约》第六次缔约方大会确定了“到2010年在全球范围内大幅度降低生物多样性丧失的速度”的目标, 并要求各国制定生物多样性评价指标, 开展生物多样性评估。本文作者根据科学性、代表性和实用性的原则, 提出了生物多样性综合评价的5个指标, 即物种丰富度、生态系统类型多样性、植被垂直层谱的完整性、物种特有性、外来物种入侵度, 确立了生物多样性综合评价方法; 并以全国31省(市、区)为单元, 开展了全国生物多样性综合评价, 将各省(市、区)生物多样性分为四个等级。云南、四川、广西的生物多样性属“优”, 贵州、湖北、广东、湖南、重庆、福建、西藏、江西、浙江、海南、甘肃、新疆、陕西的生物多样性属“良”, 河南、安徽、山东、山西、河北、北京的生物多样性属“一般”, 吉林、内蒙古、上海、辽宁、宁夏、青海、江苏、黑龙江、天津的生物多样性为“较差”。     

Preparing for the flood: evolutionary biology in the age of genomics

Genome sequencing projects will soon provide a large number of gene sequences from a wide variety of species. Although the impetus of these genome projects involves biotechnology rather than evolutionary biology, several substantial evolutionary problems may potentially be addressed using genomic data.     

Fish genomics: A mini-review on some structural and evolutionary issues

This brief outline of fish genomics will concentrate on some general genome features, as investigated in our laboratory using a "compositional approach". In the first phase (1976-1991) the main experimental tool was density gradient ultracentrifugation, both analytical and preparative. This led to a number of conclusions that were very relevant as far as the genome structure and evolution of vertebrates are concerned. After an intermezzo (1991-2001) in which investigations started to take advantage of the short but increasing supply of nucleotide sequences, a second phase (2001-present) developed on the basis of completely sequenced fish genomes. This led us to the current level of knowledge and to further insights.