Abstract
BackgroundThe recD mutants of the Antarctic Pseudomonas syringae Lz4W are sensitive to DNA-damaging agents and fail to grow at 4°C. Generally, RecD associates with two other proteins (RecB and RecC) to produce RecBCD enzyme, which is involved in homologous recombination and DNA repair in many bacteria, including Escherichia coli. However, RecD is not essential for DNA repair, nor does its deletion cause any growth defects in E. coli. Hence, the assessment of the P. syringae RecBCD pathway was imperative.Methodology/Principal FindingsMutational analysis and genetic complementation studies were used to establish that the individual null-mutations of all three genes, recC, recB, and recD, or the deletion of whole recCBD operon of P. syringae, lead to growth inhibition at low temperature, and sensitivity to UV and mitomycin C. Viability of the mutant cells dropped drastically at 4°C, and the mutants accumulated linear chromosomal DNA and shorter DNA fragments in higher amounts compared to 22°C. Additional genetic data using the mutant RecBCD enzymes that were inactivated either in the ATPase active site of RecB (RecBK29Q) or RecD (RecDK229Q), or in the nuclease center of RecB (RecBD1118A and RecBΔnuc) suggested that, while the nuclease activity of RecB is not so critical in vivo, the ATP-dependent functions of both RecB and RecD are essential. Surprisingly, E. coli recBCD or recBC alone on plasmid could complement the defects of the ΔrecCBD strain of P. syringae.Conclusions/SignificanceAll three subunits of the RecBCDPs enzyme are essential for DNA repair and growth of P. syringae at low temperatures (4°C). The RecD requirement is only a function of the RecBCD complex in the bacterium. The RecBCD pathway protects the Antarctic bacterium from cold-induced DNA damages, and is critically dependent on the helicase activities of both RecB and RecD subunits, but not on the nuclease of RecBCDPs enzyme.
Highlights
Bacteria living under extreme cold conditions of Antarctica have developed several adaptive features for growth and survival at low temperature [1,2,3,4,5,6,7]
Analysis suggested that the chromosomal gene replacements have occurred through homologous recombination, by double crossover between the DNA segments provided on the suicidal plasmid-constructs and the chromosome of P. syringae (Fig. 1)
P. syringae Lz4W was isolated from the soil samples collected in and around Lake Zube (Lz stands for Lake Zube and 4W stands for white colony no 4) of Schirmacher Oasis, Queen Maud Land as a part of the study of microbial diversity in Antarctica [31,32]
Summary
Bacteria living under extreme cold conditions of Antarctica have developed several adaptive features for growth and survival at low temperature [1,2,3,4,5,6,7]. We reported earlier that the inactivation of recD gene in the Antarctic psychrotrophic bacterium Pseudomonas syringae Lz4W leads to cold sensitivity [6]. The recD mutants of P. syringae are defective for growth at low temperature (4uC), but unlike in Escherichia coli, the mutants are sensitive to DNA damaging agents (e.g., UV and mitomycin C). The recD mutants of the Antarctic Pseudomonas syringae Lz4W are sensitive to DNA-damaging agents and fail to grow at 4uC. The assessment of the P. syringae RecBCD pathway was imperative
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