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.     

Insights into the evolutionary process of genome degradation

Studies of noncoding and pseudogene sequence diversity, particularly in Rickettsia, have begun to reveal the basic principles of genome degradation in microorganisms. Increasingly, studies of genes and genomes suggest that there has been an extensive amount of horizontal gene transfer among microorganisms. As this inflow of genetic material does not seem generally to have resulted in genome size expansions, however, degenerative processes must be at the very least as widespread as horizontal gene transfer. The basic principles of gene degradation and elimination that are being explored in Rickettsia are likely to be of major importance for our understanding of how microbial genomes evolve.     

Evolution of organellar genomes

Accumulating molecular data, particularly complete organellar genome sequences, continue to advance our understanding of the evolution of mitochondrial and chloroplast DNAs. Although the notion of a single primary origin for each organelle has been reinforced, new models have been proposed that tie the acquisition of mitochondria more closely to the origin of the eukaryotic cell per se than is implied by classic endosymbiont theory. The form and content of the ancestral proto-mitochondrial and proto-chloroplast genomes are becoming clearer but unusual patterns of organellar genome structure and organization continue to be discovered. The 'single-gene circle' arrangement recently reported for dinoflagellate chloroplast genomes is a notable example of a highly derived organellar genome.     

The genome of the malaria parasite

The genome of the human malaria parasite Plasmodium falciparum is being sequenced by an international consortium. Two of the parasite's 14 chromosomes have been completed and several other chromosomes are nearly finished. Even at this early stage of the project, analysis of the genome sequence has provided promising new leads for drug and vaccine development.     

The nature of the last universal common ancestor

Cytologically, prokaryotes appear simpler and thus evolutionarily 'older' than eukaryotes. In terms of RNA processing, however, prokaryotes are sophisticated and eukaryotes, which retain many features of an RNA-world, appear primitive. The last universal common ancestor may have been mesophilic and could have had many features of the eukaryote genome, but its cytology is unknown.     

Origin of multicellular eukaryotes - insights from proteome comparisons

The complete genomes of the yeast Saccharomyces cerevisiae and the nematode worm Caenorhabditis elegans have recently become available allowing the comparison of the complete protein sets of a unicellular and multicellular eukaryote for the first time. These comparisons reveal some striking trends in terms of expansions or extensive shuffling of specific domains that are involved in regulatory functions and signaling. Similar comparisons with the available sequence data from the plant Arabidopsis thaliana produce consistent results. These observations have provided useful insights regarding the origin of multicellular organisms.     

Selfish operons: the evolutionary impact of gene clustering in prokaryotes and eukaryotes

The Selfish Operon Model postulates that the organization of bacterial genes into operons is beneficial to the constituent genes in that proximity allows horizontal cotransfer of all genes required for a selectable phenotype; eukaryotic operons formed for very different reasons. Horizontal transfer of selfish operons most probably promotes bacterial diversification.     

Interspersed repeats and other mementos of transposable elements in mammalian genomes

The bulk of the human genome is ultimately derived from transposable elements. Observations in the past year lead to some new and surprising ideas on functions and consequences of these elements and their remnants in our genome. The many new examples of human genes derived from single transposon insertions highlight the large contribution of selfish DNA to genomic evolution.     

Orthologs, paralogs and genome comparisons

During the past decade, ancient gene duplications were recognized as one of the main forces in the generation of diverse gene families and the creation of new functional capabilities. New tools developed to search data banks for homologous sequences, and an increased availability of reliable three-dimensional structural information led to the recognition that proteins with diverse functions can belong to the same superfamily. Analyses of the evolution of these superfamilies promises to provide insights into early evolution but are complicated by several important evolutionary processes. Horizontal transfer of genes can lead to a vertical spread of innovations among organisms, therefore finding a certain property in some descendants of an ancestor does not guarantee that it was present in that ancestor. Complete or partial gene conversion between duplicated genes can yield phylogenetic trees with several, apparently independent gene duplications, suggesting an often surprising parallelism in the evolution of independent lineages. Additionally, the breakup of domains within a protein and the fusion of domains into multifunctional proteins makes the delineation of superfamilies a task that remains difficult to automate.     

Observing the living genome

Dynamic pictures of living genomes are now beginning to emerge from systematic studies of gene expression patterns using DNA microarrays. The rich information represented in the variation in each gene's expression provides the basis for a new kind of genomic map.     

Noncoding RNA genes

Some genes produce RNAs that are functional instead of encoding proteins. Noncoding RNA genes are surprisingly numerous. Recently, active research areas include small nucleolar RNAs, antisense riboregulator RNAs, and RNAs involved in X-dosage compensation. Genome sequences and new algorithms have begun to make systematic computational screens for noncoding RNA genes possible.     

The minimal genome concept

Complete genome sequences are becoming available for a large number of diverse species. Quantification of gene content, of gene family expansion, of orthologous gene conservation, as well as their displacement, are now possible - laying the ground for the estimation of the minimal set of proteins sufficient for cellular life. The consensus of computational results suggests a set close to 300 genes. These predictions will be evaluated by engineering of small bacterial genomes.     

Shaping the genome--restriction-modification systems as mobile genetic elements

A restriction enzyme gene is often linked to a modification methylase gene the role of which is to protect a recognition site on DNA from breakage by the former. Loss of some restriction-modification gene complexes leads to cell death through restriction breakage in the genome. Their behavior as genomic parasites/symbionts may explain the distribution of restriction sites and clarify certain aspects of bacterial recombination repair and mutagenesis. A comparison of bacterial genomes supports the hypothesis that restriction-modification gene complexes are mobile elements involved in various genome rearrangements and evolution.     

Motor systems: Neurobiology of behaviour

A selection of World Wide Web sites relevant to papers published in this issue of Current Opinion in Neurobiology.     

Web alert. Biopolymers model systems

A selection of World Wide Web sites relevant to papers published in this issue of Current Opinion in Chemical Biology.     

Growth and development. Web alert

A selection of World Wide Web sites relevant to the reviews published in this issue of Current Opinion in Microbiology.     

Neurobiology

A selection of interesting papers that were published in the two months before our press date in major journals most likely to report significant results in neurobiology.     

Chemical biology: Paper alert

A selection of interesting papers that were published in the two months before our press date in major journals most likely to report significant results in chemical biology.