Showing papers by "Kenneth H. Wolfe published in 1999"

Proteinases and associated genes of parasitic helminths

Abstract: Many parasites have deployed proteinases to accomplish some of the tasks imposed by a parasitic life style, including tissue penetration, digestion of host tissue for nutrition and evasion of host immune responses. Information on proteinases from trematodes, cestodes and nematode parasites is reviewed, concentrating on those worms of major medical and economical importance. Their biochemical characterization is discussed, along with their putative biological roles and, where available, their associated genes. For example, proteinases expressed by the various stages of the schistosome life-cycle, in particular the well-characterized cercarial elastase which is involved in the penetration of the host skin and the variety of proteinases, such as cathepsin B (Sm31), cathepsin L1, cathepsin L2, cathepsin D, cathepsin C and legumain (Sm32), which are believed to be involved in the catabolism of host haemoglobin. The various endo- and exoproteinases of Fasciola hepatica, the causative agent of liver fluke disease, are reviewed, and recent reports of how these enzymes have been successfully employed in cocktail vaccines are discussed. The various proteinases of cestodes and of the diverse superfamilies of parasitic nematodes are detailed, with special attention being given to those parasites for which most is known, including species of Taenia, Echinococcus, Spirometra, Necator, Acylostoma and Haemonchus. By far the largest number of papers in the literature and entries to the sequence data bases dealing with proteinases of parasitic helminths report on enzymes belonging to the papain superfamily of cysteine proteinases. Accordingly, the final section of the review is devoted to a phylogenetic analysis of this superfamily using over 150 published sequences. This analysis shows that the papain superfamily can be divided into two major branches. Branch A contains the cathepin Bs, the cathepsin Cs and a novel family termed cathepsin Xs, while Branch B contains the cruzipains, cathepsin Ls, papain-like and aleurain/cathepsin H-like proteinases. The relationships of the helminth proteinases, and similar proteinases from protozoan parasites and other organisms, within these groups are discussed.

Proteome composition and codon usage in spirochaetes: species-specific and DNA strand-specific mutational biases.

Abstract: The genomes of the spirochaetes Borrelia burgdorferi and Treponema pallidum show strong strand-specific skews in nucleotide composition, with the leading strand in replication being richer in G and T than the lagging strand in both species. This mutation bias results in codon usage and amino acid composition patterns that are significantly different between genes encoded on the two strands, in both species. There are also substantial differences between the species, with T.pallidum having a much higher G+C content than B. burgdorferi. These changes in amino acid and codon compositions represent neutral sequence change that has been caused by strong strand- and species-specific mutation pressures. Genes that have been relocated between the leading and lagging strands since B. burgdorferi and T.pallidum diverged from a common ancestor now show codon and amino acid compositions typical of their current locations. There is no evidence that translational selection operates on codon usage in highly expressed genes in these species, and the primary influence on codon usage is whether a gene is transcribed in the same direction as replication, or opposite to it. The dnaA gene in both species has codon usage patterns distinctive of a lagging strand gene, indicating that the origin of replication lies downstream of this gene, possibly within dnaN. Our findings strongly suggest that gene-finding algorithms that ignore variability within the genome may be flawed.

Gene duplication and gene conversion in the Caenorhabditis elegans genome.

Abstract: A comprehensive analysis of duplication and gene conversion for 7394 Caenorhabditis elegans genes (about half the expected total for the genome) is presented. Of the genes examined, 40% are involved in duplicated gene pairs. Intrachromosomal or cis gene duplications occur approximately two times more often than expected. In general the closer the members of duplicated gene pairs are, the more likely it is that gene orientation is conserved. Gene conversion events are detectable between only 2% of the duplicated pairs. Even given the excesses of cis duplications, there is an excess of gene conversion events between cis duplicated pairs on every chromosome except the X chromosome. The relative rates of cis and trans gene conversion and the negative correlation between conversion frequency and DNA sequence divergence for unconverted regions of converted pairs are consistent with previous experimental studies in yeast. Three recent, regional duplications, each spanning three genes are described. All three have already undergone substantial deletions spanning hundreds of base pairs. The relative rates of duplication and deletion may contribute to the compactness of the C. elegans genome.

G+C content variation along and among Saccharomyces cerevisiae chromosomes.

Abstract: Past analyses of the genome of the yeast Saccharomyces cerevisiae have revealed substantial regional variation in G+C content. Important questions remain, though, as to the origin, nature, significance, and generality of this variation. We conducted an extensive analysis of the yeast genome to try to answer these questions. Our results indicate that open reading frames (ORFs) with similar G+C contents at silent codon positions are significantly clustered on chromosomes. This clustering can be explained by very short range correlations of silent-site G+C contents at neighboring ORFs. ORFs of high silent-site G+C content are disproportionately concentrated on shorter chromosomes, which causes a negative relationship between chromosome length and G+C content. Contrary to previous reports, there is no correlation between gene density and silent-site G+C content in yeast. Chromosome III is atypical in many regards, and possible reasons for this are discussed.