Functional analysis of the yeast genome

The release of the complete genome sequence of the yeast Saccharomyces cerevisiae has ushered in a new phase of genome research in which sequence function will be assigned. The goal is to determine the biological function of each of the >6,000 open reading frames in the yeast genome. Innovative approaches have been developed that exploit the sequence data and yield information about gene expression levels, protein levels, subcellular localization and gene function for the entire genome.     

Biodiversity, genomes, and DNA sequence databases

There are ∼1.4 million organisms on this planet that have been described morphologically but there is no comparable coverage of biodiversity at the molecular level. Little more than 1% of the known species have been subject to any molecular scrutiny and eukaryotic genome projects have focused on a group of closely related model organisms. The past year, however, has seen an ∼80% increase in the number of species represented in sequence databases and the completion of the sequencing of three prokaryotic genomes. Large-scale sequencing projects seem set to begin coverage of a wider range of the eukaryotic diversity, including green plants, microsporidians and diplomonads.     

Eukaryote genome duplication - where's the evidence?

Several eukaryotes, including maize, yeast and Xenopus, are degenerate polyploids formed by relatively recent whole-genome duplications. Ohno's conjecture that more ancient genome duplications occurred in an ancestor of vertebrates is probably at least partly true but the present shortage of gene sequence and map information from vertebrates makes it difficult to either prove or disprove this hypothesis. Candidate paralogous segments in mammalian genomes have been identified but the lack of statistical rigour means that many of the proposals in the literature are probably artefacts.     

Multicellular Ascomycetous Fungal Genomes Contain More Than 8000 Genes

Fungi comprise a large monophyletic group of uni- and multicellular eukaryotic organisms in which many species are of economic or medical importance. Fungal genomes are variable in size (13–42 Mb), and multicellular species support true spatial and temporal cell-type-specific regulation of gene expression. In a 38.8-kbAspergillus nidulanscontiguous genomic DNA region, a transposable element and 12 potential genes were identified, 7 similar to genes in other organisms. This observation is consistent with the prediction that multicellular ascomycetous fungi harbor 8000–9000 genes in a 36-Mb average genome. Thus, the genomic DNA sequence of filamentous fungi will provide substantial amounts of genetic and functional information that is not available in yeast, for the human and other metazoan minimal gene complement.     

Unravelling the Leishmania genome

The past few years have seen significant advances in our understanding of eukaryotic genomes. In the field of parasitology, this is best exemplified by the application of genome mapping techniques to the study of genome structure and function in the protozoan parasite, Leishmania. Although much is known about the organism and the diseases it causes, molecular genetics has only recently begun to play a major part in elucidating some of the unusual characteristics of this interesting parasite. Mapping of the small (35 Mb) genome and determination of the functional role of genes by the application of in vitro homologous gene targeting techniques are revealing novel avenues for the development of prophylactic measures.     

Plastid evolution: origins, diversity, trends

The amazing diversity of extant photosynthetic eukaryotes is largely a result of the presence of formerly free-living photosynthesizing organisms that have been sequestered by eukaryotic hosts and established as plastids in a process known as endosymbiosis. The evolutionary history of these endosymbiotic events was traditionally investigated by studying ultrastructural features and pigment characteristics but in recent years has been approached using molecular sequence data and gene trees. Two important developments, more detailed studies of members of the Cyanobacteria (from which plastids ultimately derive) and the availability of complete plastid genome sequences from a wide variety of plant and algal lineages, have allowed a more accurate reconstruction of plastid evolution.     

Bioinformatics: from genome data to biological knowledge

Recently, molecular biologists have sequenced about a dozen bacterial genomes and the first eukaryotic genome. We can now obtain answers to detailed questions about the complete set of genes of an organism. Bioinformatics methods are increasingly used for attaching biological knowledge to long lists of genes, assigning genes to biological pathways, comparing the gene sets of different species, identifying specificity factors, and describing sets of highly conserved proteins common to all domains of life. Substantial progress has recently been made in the availability of primary and added-value databases, in the development of algorithms and of network information services for genome analysis. The pharmaceutical industry has greatly benefited from the accumulation of sequence data through the identification of targets and candidates for the development of drugs, vaccines, diagnostic markers and therapeutic proteins.     

History assignment: when was the mitochondrion founded?

The near simultaneous radiation of the major eukaryotic evolutionary assemblages — plants, animals, fungi, and at least three other complex protist assemblages worthy of ‘kingdom level’ status — was preceded by the divergence of many independent protist lineages. The earliest branches are represented by organisms that do not contain mitochondria or plastids, suggesting that the primitive eukaryotic state did not include these organelles. New information about nuclear-coded proteins that localize in the mitochondrion, however, suggests that the ancestral symbionts for mitochondria were present in the first eukaryotes. Phylogenetic support for this hypothesis is persuasive but it is not possible to account for the relative times of divergence for mitochondria and their ancestral symbionts relative to eukaryotic branching patterns inferred from nuclear genes.     

Aging and genetic instability in yeast

There is a striking link between increasing age and the incidence of cancer in humans. One of the hallmarks of cancer, genomic instability, has been observed in all types of organisms. In the yeast Saccharomyces cerevisiae, it was recently discovered that during the replicative lifespan, aging cells switch to a state of high genomic instability that persists until they die. In considering these and other recent results, we suggest that accumulation of oxidatively damaged protein in aging cells results in the loss of function of gene products critical for maintaining genome integrity. Determining the identity of these proteins and how they become damaged represents a new challenge for understanding the relationship between age and genetic instability.     

Functional analysis of the yeast genome

Just as Saccharomyces cerevisiae itself provides a model for so many processes essential to eukaryotic life, we anticipate that the methods and the mindset that have moved yeast biological research "beyond the genome" provide a prototype for making similar progress in other organisms. In this review I describe the experimental processes, results and utility of the current large-scale experimental approaches that use genomic data to provide a functional analysis of the yeast genome. Electronic Publication     

Comparative painting of mammalian chromosomes

Comparative chromosome painting has shown that synteny has been conserved for large segments of the genome in various placental mammals. Advances such as spectral karyotyping and multicolour ‘bar coding’ lend speed and precision to comparative molecular cytogenetics. Reciprocal chromosome painting and hybridisations with probes such as yeast artificial chromosomes, cosmids, and fibre fluorescence in situ hybridisation allow subchromosomal assignments of chromosome regions and can identify breakpoints of rearranged chromosomes. Advances in molecular cytogenetics can now be used to test the hypothesis that chromosome rearrangement breakpoints in human pathology and in evolution are correlated.     

Genome research and evolution in trypanosomes

Trypanosoma brucei and Trypanosoma cruzi cause different human diseases. As strategies for immune evasion. T. brucei undergoes antigenic variation whereas T. cruzi becomes an intracellular organism. This fundamental difference is reflected by major differences in their genome organizations. Recent comparisons of their gene sequences indicate that these two trypanosome species are highly divergent evolutionarily.     

Polo-like kinases: positive regulators of cell division from start to finish

Present in organisms ranging from yeast to man, homologues of the Drosophila Polo kinase control multiple stages of cell division. At the onset of mitosis, Polo-like kinases (Plks) function in centrosome maturation and bipolar spindle formation, and they contribute to the activation of cyclin-dependent kinase (Cdk)1—cyclin B. Subsequently, they are required for the inactivation of Cdk1 and exit from mitosis. In the absence of Plk function, mitotic cyclins fail to be destroyed, indicating that Plks are important regulators of the anaphase-promoting complex/cyclosome (APC/C), a key component of the ubiquitin-dependent proteolytic degradation pathway. Finally, recent evidence implicates Plks in the temporal and spatial coordination of cytokinesis.     

Large-scale mutagenesis and functional genomics in yeast

One of the major goals for the post-genome era is determining of the function of proteins predicted in the genome sequence. In many organisms functional assignments have been the results of comparative sequencing, proteomics or expression profiling. In the yeast, Saccharomyces cerevisiae, however, the functional role of a gene can be tested directly by disrupting the gene and examining the phenotype of the mutant. Because precise targeted deletions can be easily constructed, it is also possible to systematically delete every gene in the genome. Here we describe recent progress in yeast genome-wide mutagenesis programs and the results produced from analyzing the mutants created by them. Electronic Publication     

Cloning of the PpMSH-2 cDNA of Physcomitrella patens, a moss in which gene targeting by homologous recombination occurs at high frequency

In the moss Physcomitrella patens integrative transformants from homologous recombination are obtained at an efficiency comparable to that found for yeast. This property, unique in the plant kingdom, allows the knockout of specific genes. It also makes the moss a convenient model to study the regulation of homologous recombination in plants. We used degenerate oligonucleotides designed from AtMSH2 from Arabidopsis thaliana and other known MutS homologues to isolate the P. patens MSH2 (PpMSH2) cDNA. The deduced sequence of the PpMSH2 protein is respectively 60.8% and 59.6% identical to the maize and A. thaliana MSH2. Phylogenic studies show that PpMSH2 is closely related to the group of plant MSH2 proteins. Southern analysis reveals that the gene exists as a single copy in the P. patens genome.     

DNA Chip technologies

The genome sequencing project has generated and will continue to generate enormous amounts of sequence data. Since the first complete genome sequence of bacteriumHacmophilus influenzac was published in 1995, the complete genome sequences of 2 eukaryotic and about 22 prokaryotic organisms have been determined. Given this ever-increasing amounts of sequence information, new strategies are necessary to efficiently pursue the next phase of the genome project—the elucidation of gene expression patterns and gene product function on a whole genome scale. In order to assign functional information to the genome sequence, DNA chip technology was developed to efficiently identify the differential expression pattern of independent biological samples. DNA chip provides a new tool for genome expression analysis that may revolutionize many aspects of human life including new drug discovery and human disease diagnostics.     

Gen(om)e duplications in the evolution of early vertebrates

Phylogenetic analyses and sequence surveys of developmental regulator gene families indicate that two large-scale gene duplications, most likely genome duplications, occurred in ancestors of vertebrates. Relaxed constraints allowed duplicated and thus redundant genes to diverge in a two stage mechanism. Neutral changes dominated at first but then positively selected regulatory changes evolved the novel and increasingly complex vertebrate developmental program.     

Bacterial genome sequencing and drug discovery

The availability of bacterial genome sequence information has opened up many new strategies for antibacterial drug hunting. There are obvious benefits for the idetification and evaluation of new drug targets, but genomic-based technology is also beginning to provide new tools for the downstream, preclinical, optimisation of compounds. The greatest benefit from these new approaches lies in the ability to examine the entire genome (or several genomes) simultaneously and in total. In this way, one potential target can be evaluated against another, and either the total effects of functional impairment can be established or the effects of a compound can be compared across species.     

Prokaryotic genomes: the emerging paradigm of genome-based microbiology

Comparative analysis of the complete sequences of seven bacterial and three archaeal genomes leads to the first generalizations of emerging genome-based microbiology. Protein sequences are, generally, highly conserved, with ∼70% of the gene products in bacteria and archaea containing ancient conserved regions. In contrast, there is little conservation of genome organization, except for a few essential operons. The most striking conclusions derived by comparison of multiple genomes from phylogenetically distant species are that the number of universally conserved gene families is very small and that multiple events of horizontal gene transfer and genome fusion are major forces in evolution.