Hamilton O. Smith

Complete Genome Sequence of the Methanogenic Archaeon, Methanococcus jannaschii

The complete 1.66-megabase pair genome sequence of an autotrophic archaeon, Methanococcus jannaschii, and its 58- and 16-kilobase pair extrachromosomal elements have been determined by whole-genome random sequencing. A total of 1738 predicted protein-coding genes were identified; however, only a minority of these (38 percent) could be assigned a putative cellular role with high confidence. Although the majority of genes related to energy production, cell division, and metabolism in M. jannaschii are most similar to those found in Bacteria, most of the genes involved in transcription, translation, and replication in M. jannaschii are more similar to those found in Eukaryotes. The Methanococcus jannaschii Genome Database

DNA sequence of both chromosomes of the cholera pathogen Vibrio cholerae

Here we determine the complete genomic sequence of the Gram negative, γ-Proteobacterium Vibrio cholerae El Tor N16961 to be 4,033,460 base pairs (bp). The genome consists of two circular chromosomes of 2,961,146 bp and 1,072,314 bp that together encode 3,885 open reading frames. The vast majority of recognizable genes for essential cell functions (such as DNA replication, transcription, translation and cell-wall biosynthesis) and pathogenicity (for example, toxins, surface antigens and adhesins) are located on the large chromosome. In contrast, the small chromosome contains a larger fraction (59%) of hypothetical genes compared with the large chromosome (42%), and also contains many more genes that appear to have origins other than the γ-Proteobacteria. The small chromosome also carries a gene capture system (the integron island) and host ‘addiction’ genes that are typically found on plasmids; thus, the small chromosome may have originally been a megaplasmid that was captured by an ancestral Vibrio species. The V. cholerae genomic sequence provides a starting point for understanding how a free-living, environmental organism emerged to become a significant human bacterial pathogen.

Genome sequence of the dissimilatory metal ion-reducing bacterium Shewanella oneidensis

Shewanella oneidensis is an important model organism for bioremediation studies because of its diverse respiratory capabilities, conferred in part by multicomponent, branched electron transport systems. Here we report the sequencing of the S. oneidensis genome, which consists of a 4,969,803–base pair circular chromosome with 4,758 predicted protein-encoding open reading frames (CDS) and a 161,613–base pair plasmid with 173 CDSs. We identified the first Shewanella lambda-like phage, providing a potential tool for further genome engineering. Genome analysis revealed 39 c-type cytochromes, including 32 previously unidentified in S. oneidensis, and a novel periplasmic [Fe] hydrogenase, which are integral members of the electron transport system. This genome sequence represents a critical step in the elucidation of the pathways for reduction (and bioremediation) of pollutants such as uranium (U) and chromium (Cr), and offers a starting point for defining this organisms complex electron transport systems and metal ion–reducing capabilities.

A preliminary comparison of the mouse and human genomes

Abstract Accurate annotated assemblies of the mouse and human genomes enable a detailed comparison of the organization and evolution of the two genomes. We have completed several assemblies of both the mouse, with and without public data, and human genomes. Analysis of these assemblies suggests the mouse genome is about 10% smaller than the human genome primarily because of a difference in the content of repetitive DNA between the two genomes. More than 300,000 positions in these two genomes can be aligned with one another based on short segments of sequence similarity. These conserved segments significantly enhance the resolution of the resultant comparative maps and can be used to divide the genomes into regions of conserved-shared synteny. The genes found in such regions are highly conserved as is their relative order and orientation. Comparison of the human and mouse genome is expected to be key to deciphering the important biological information encoded in the mammalian genome. A prerequisite to comparing complex genomes such as those of mouse and human is the availability of annotated assemblies of both genomes that are comparable in quality and completeness. Since February 2001, we have assembled, annotated and delivered to our subscribers two versions of the human genome and two versions of the mouse genome. A third assembly of the human genome is being completed and will be delivered by fall of 2002. These annotated assemblies provide the starting materials for the genome-wide comparisons of the mouse and human reported here. We will begin with a description of the first Celera whole genome assembly of the mouse to provide a general basis of the quality and completeness of these data and then will report the results of a preliminary comparison between these two genomes.