Your search keyword '"Karam, Jim D."' showing total 5 results

1. Bacteriophage T4 and its relatives.

Author

Karam, Jim D. and Miller, Eric S.

Subjects

*GENOMES, *BACTERIOPHAGE T4

Abstract

The article discusses various papers published within the issue including "Genomes of the T4-related phages as windows on microbial evolution," by V. Petrov and colleagues, "T4-related phages of the marine ecosystem," by M. Clokie and colleagues, and "Mobile DNA elements of the T4-related phages," by D. Edgell.

Published

2010

2. Genomes of the T4-related bacteriophages as windows on microbial genome evolution.

Author

Petrov, Vasiliy M., Ratnayaka, Swarnamala, Nolan, James M., Miller, Eric S., and Karam, Jim D.

Subjects

GENOMES, GENETICS, GENES, BACTERIOPHAGES, DNA, BACTERIOPHAGE genomes

Abstract

The T4-related bacteriophages are a group of bacterial viruses that share morphological similarities and genetic homologies with the well-studied Escherichia coli phage T4, but that diverge from T4 and each other by a number of genetically determined characteristics including the bacterial hosts they infect, the sizes of their linear doublestranded (ds) DNA genomes and the predicted compositions of their proteomes. The genomes of about 40 of these phages have been sequenced and annotated over the last several years and are compared here in the context of the factors that have determined their diversity and the diversity of other microbial genomes in evolution. The genomes of the T4 relatives analyzed so far range in size between ~160,000 and ~250,000 base pairs (bp) and are mosaics of one another, consisting of clusters of homology between them that are interspersed with segments that vary considerably in genetic composition between the different phage lineages. Based on the known biological and biochemical properties of phage T4 and the proteins encoded by the T4 genome, the T4 relatives reviewed here are predicted to share a genetic core, or "Core Genome" that determines the structural design of their dsDNA chromosomes, their distinctive morphology and the process of their assembly into infectious agents (phage morphogenesis). The Core Genome appears to be the most ancient genetic component of this phage group and constitutes a mere 12-15% of the total protein encoding potential of the typical T4-related phage genome. The high degree of genetic heterogeneity that exists outside of this shared core suggests that horizontal DNA transfer involving many genetic sources has played a major role in diversification of the T4-related phages and their spread to a wide spectrum of bacterial species domains in evolution. We discuss some of the factors and pathways that might have shaped the evolution of these phages and point out several parallels between their diversity and the diversity generally observed within all groups of interrelated dsDNA microbial genomes in nature. [ABSTRACT FROM AUTHOR]

Published

2010

3. Divergence of the mRNA targets for the Ssb proteins of bacteriophages T4 and RB69.

Author

Borjac-Natour, Jamilah M., Petrov, Vasiliy M., and Karam, Jim D.

Subjects

MESSENGER RNA, BACTERIOPHAGES, PROTEIN binding, DNA replication, VIRUSES, GENETIC repressors

Abstract

The single-strand binding (Ssb) protein of phage T4 (T4 gp32, product of gene 32) is a mRNA-specific autogenous translational repressor, in addition to being a sequence-independent ssDNA-binding protein that participates in phage DNA replication, repair and recombination. It is not clear how this physiologically essential protein distinguishes between specific RNA and nonspecific nucleic acid targets. Here, we present phylogenetic evidence suggesting that ssDNA and specific RNA bind the same gp32 domain and that plasticity of this domain underlies its ability to configure certain RNA structures for specific binding. We have cloned and characterized gene 32 of phage RB69, a relative of T4 We observed that RB69 gp32 and T4 gp32 have nearly identical ssDNA binding domains, but diverge in their C-terminal domains. In T4 gp32, it is known that the C-terminal domain interacts with the ssDNA-binding domain and with other phage-induced proteins. In translation assays, we show that RB69 gp32 is, like T4 gp32, an autogenous translational repressor. We also show that the natural mRNA targets (translational operators) for the 2 proteins are diverged in sequence from each other and yet can be repressed by either gp32. Results of chemical and RNase sensitivity assays indicate that the gp32 mRNA targets from the 2 related phages have similar structures, but differ in their patterns of contact with the 2 repressors. These and other observations suggest that a range of gp32-RNA binding specificities may evolve in nature due to plasticity of the protein-nucleic acid interaction and its response to modulation by the C-terminal domain of this translational repressor. [ABSTRACT FROM AUTHOR]

Published

2004

4. Bacteriophages: The viruses for all seasons of molecular biology.

Author

Karam, Jim D.

Subjects

*BACTERIOPHAGES, *VIRUSES, *MOLECULAR biology, *BIOMOLECULES, *MEDICAL microbiology, *RESEARCH

Abstract

Bacteriophage research continues to break new ground in our understanding of the basic molecular mechanisms of gene action and biological structure. The abundance of bacteriophages in nature and the diversity of their genomes are two reasons why phage research brims with excitement. The pages of Virology Journal will reflect the excitement of the "New Phage Biology." [ABSTRACT FROM AUTHOR]

Published

2005

5. Genetic diversity among five T4-like bacteriophages.

Author

Nolan JM, Petrov V, Bertrand C, Krisch HM, and Karam JD

Subjects

Animals, Bacteriophages genetics, Base Sequence, Computational Biology methods, Genome, Viral, Humans, Mice, Molecular Sequence Data, Open Reading Frames genetics, RNA, Transfer chemistry, RNA, Transfer genetics, Sequence Alignment, Viral Proteins genetics, Aeromonas hydrophila virology, Aeromonas salmonicida virology, Bacteriophage T4 genetics, Bacteriophages classification, Coliphages genetics, Genetic Variation

Abstract

Background: Bacteriophages are an important repository of genetic diversity. As one of the major constituents of terrestrial biomass, they exert profound effects on the earth's ecology and microbial evolution by mediating horizontal gene transfer between bacteria and controlling their growth. Only limited genomic sequence data are currently available for phages but even this reveals an overwhelming diversity in their gene sequences and genomes. The contribution of the T4-like phages to this overall phage diversity is difficult to assess, since only a few examples of complete genome sequence exist for these phages. Our analysis of five T4-like genomes represents half of the known T4-like genomes in GenBank., Results: Here, we have examined in detail the genetic diversity of the genomes of five relatives of bacteriophage T4: the Escherichia coli phages RB43, RB49 and RB69, the Aeromonas salmonicida phage 44RR2.8t (or 44RR) and the Aeromonas hydrophila phage Aeh1. Our data define a core set of conserved genes common to these genomes as well as hundreds of additional open reading frames (ORFs) that are nonconserved. Although some of these ORFs resemble known genes from bacterial hosts or other phages, most show no significant similarity to any known sequence in the databases. The five genomes analyzed here all have similarities in gene regulation to T4. Sequence motifs resembling T4 early and late consensus promoters were observed in all five genomes. In contrast, only two of these genomes, RB69 and 44RR, showed similarities to T4 middle-mode promoter sequences and to the T4 motA gene product required for their recognition. In addition, we observed that each phage differed in the number and assortment of putative genes encoding host-like metabolic enzymes, tRNA species, and homing endonucleases., Conclusion: Our observations suggest that evolution of the T4-like phages has drawn on a highly diverged pool of genes in the microbial world. The T4-like phages harbour a wealth of genetic material that has not been identified previously. The mechanisms by which these genes may have arisen may differ from those previously proposed for the evolution of other bacteriophage genomes.

Published

2006