Your search keyword '"Zoonoses genetics"' showing total 3 results

1. Genomic survey and expression analysis of DNA repair genes in the genus Leptospira.

Author

Martins-Pinheiro M, Schons-Fonseca L, da Silva JB, Domingos RH, Momo LH, Simões AC, Ho PL, and da Costa RM

Subjects

Animals, Gene Expression Regulation, Bacterial, Genome, Bacterial, Host-Pathogen Interactions genetics, Leptospirosis microbiology, Mesocricetus, Models, Animal, Phylogeny, Zoonoses genetics, Zoonoses microbiology, DNA Repair genetics, Leptospira genetics, Leptospirosis genetics

Abstract

Leptospirosis is an emerging zoonosis with important economic and public health consequences and is caused by pathogenic leptospires. The genus Leptospira belongs to the order Spirochaetales and comprises saprophytic (L. biflexa), pathogenic (L. interrogans) and host-dependent (L. borgpetersenii) members. Here, we present an in silico search for DNA repair pathways in Leptospira spp. The relevance of such DNA repair pathways was assessed through the identification of mRNA levels of some genes during infection in animal model and after exposition to spleen cells. The search was performed by comparison of available Leptospira spp. genomes in public databases with known DNA repair-related genes. Leptospires exhibit some distinct and unexpected characteristics, for instance the existence of a redundant mechanism for repairing a chemically diverse spectrum of alkylated nucleobases, a new mutS-like gene and a new shorter version of uvrD. Leptospira spp. shares some characteristics from Gram-positive, as the presence of PcrA, two RecQ paralogs and two SSB proteins; the latter is considered a feature shared by naturally competent bacteria. We did not find a significant reduction in the number of DNA repair-related genes in both pathogenic and host-dependent species. Pathogenic leptospires were enriched for genes dedicated to base excision repair and non-homologous end joining. Their evolutionary history reveals a remarkable importance of lateral gene transfer events for the evolution of the genus. Up-regulation of specific DNA repair genes, including components of SOS regulon, during infection in animal model validates the critical role of DNA repair mechanisms for the complex interplay between host/pathogen.

Published

2016

2. Analysis of pan-genome to identify the core genes and essential genes of Brucella spp.

Author

Yang X, Li Y, Zang J, Li Y, Bie P, Lu Y, and Wu Q

Subjects

Animals, Brucella pathogenicity, Computational Biology, Genes, Essential, Humans, Zoonoses microbiology, Brucella genetics, Energy Metabolism genetics, Genome, Bacterial, Zoonoses genetics

Abstract

Brucella spp. are facultative intracellular pathogens, that cause a contagious zoonotic disease, that can result in such outcomes as abortion or sterility in susceptible animal hosts and grave, debilitating illness in humans. For deciphering the survival mechanism of Brucella spp. in vivo, 42 Brucella complete genomes from NCBI were analyzed for the pan-genome and core genome by identification of their composition and function of Brucella genomes. The results showed that the total 132,143 protein-coding genes in these genomes were divided into 5369 clusters. Among these, 1710 clusters were associated with the core genome, 1182 clusters with strain-specific genes and 2477 clusters with dispensable genomes. COG analysis indicated that 44 % of the core genes were devoted to metabolism, which were mainly responsible for energy production and conversion (COG category C), and amino acid transport and metabolism (COG category E). Meanwhile, approximately 35 % of the core genes were in positive selection. In addition, 1252 potential essential genes were predicted in the core genome by comparison with a prokaryote database of essential genes. The results suggested that the core genes in Brucella genomes are relatively conservation, and the energy and amino acid metabolism play a more important role in the process of growth and reproduction in Brucella spp. This study might help us to better understand the mechanisms of Brucella persistent infection and provide some clues for further exploring the gene modules of the intracellular survival in Brucella spp.

Published

2016

3. Differential sensitivity of porcine endogenous retrovirus to APOBEC3-mediated inhibition.

Author

Park SH, Kim JH, and Jung YT

Subjects

APOBEC-3G Deaminase, Animals, Cytidine Deaminase genetics, Cytosine Deaminase genetics, Endogenous Retroviruses classification, Endogenous Retroviruses genetics, Endogenous Retroviruses physiology, Host-Pathogen Interactions, Humans, Retroviridae classification, Retroviridae genetics, Retroviridae physiology, Retroviridae Infections genetics, Retroviridae Infections immunology, Retroviridae Infections virology, Swine genetics, Swine virology, Transplantation, Heterologous, Zoonoses genetics, Zoonoses immunology, Zoonoses virology, Cytidine Deaminase immunology, Cytosine Deaminase immunology, Endogenous Retroviruses immunology, Retroviridae immunology, Retroviridae Infections enzymology, Swine immunology, Zoonoses enzymology

Abstract

Pigs are considered to be suitable xenotransplantation organ donors. However, the risk of pathogen transmission from pigs to humans is a major concern in the transplantation of porcine tissues. The porcine endogenous retroviruses (PERVs) PERV-A, PERV-A/C, and PERV-B can infect human cells, but PERV-C is an ecotropic virus infecting only pig cells. Thus, several strategies have been proposed to reduce PERV transmission in xenograft recipients. Human APOBEC3G (huA3G) is a single-strand DNA cytosine deaminase, which inactivates the coding capacity of the virus by deamination of cDNA cytosines to uracils. This reaction occurs within the (-) DNA strand during reverse transcription, resulting in a G-to-A mutation in the (+) strand. While recent data have shown that PERV-B is severely inhibited by huA3G and porcine A3Z2-Z3 (poA3F) in a pseudotype assay, little is known about PERV-C. Here, we compare the antiretroviral activities of huA3G, huA3F and poA3Z2-Z3 against PERV-C. Our data show that APOBEC3 was packaged into PERV-C particles and inhibited PERV-C replication in a dose-dependent manner. PERV-C infectivity was strongly inhibited by poA3Z2-Z3, but it did not markedly reduce PERV-B infectivity. This suggests that PERV-C Gag interacts efficiently with poA3Z2-Z3. In addition, we constructed stably huA3G- and poA3Z2-Z3-expressing 293-PERV-PK-CIRCE cells (human 293 cells infected with PK15-derived PERVs) to examine whether PERV is resistant to poA3Z2-Z3 in a virus-spreading assay. The stably expressed huA3G and poA3Z2-Z3 were more packaging-competent than transiently expressed APOBEC3 proteins. These results suggest that poA3Z2-Z3 can inhibit PERV replication in a pseudotype assay as well as in a virus-spreading assay.

Published

2015