Genomic deletions in Rhodococcus based on transformation of linear heterologous DNA.

Several genome engineering methods have been developed for Rhodococcus. However, they suffer from limitations such as extensive cloning, multiple steps, successful expression of heterologous genes via plasmid etc. Here, we report a rapid method for performing genomic deletions/disruptions in Rhodococcus spp. using heterologous linear DNA. The method is cost effective and less labour intensive. The applicability of the method was demonstrated by successful disruption of rodA and orphan parA. None of the disrupted genes were found to be essential for the viability of the cell. Disruption of orphan parA and rodA resulted in elongated cells and short rods, respectively. This is the first report demonstrating disruption of rodA and orphan parA genes by electroporation of heterologous linear DNA in Rhodococcus spp.

Role of Bacterial Cytoskeleton and Other Apparatuses in Cell Communication.

The bacterial cytoskeleton is crucial for sensing the external environment and plays a major role in cell to cell communication. There are several other apparatuses such as conjugation tubes, membrane vesicles, and nanotubes used by bacterial cells for communication. The present review article describes the various bacterial cytoskeletal proteins and other apparatuses, the physical structures they form and their role in sensing environmental stress. The implications of this cellular communication in pathogenicity are discussed.

How similar or dissimilar cells are produced by bacterial cell division?

DNA replication, segregation and cell division are vital processes and require an interplay of multiple proteins. These processes are highly conserved across bacteria yet similar or dissimilar progeny are produced after cell division. This review describes the bacterial cell division in considerable detail. This includes studies on model microorganisms which produce similar progeny such as Escherichia coli and Vibrio cholerae, and dissimilar progeny such as sporulating Bacillus subtilis, Actinobacteria, Caulobacter crescentus etc. The mechanism of symmetric and asymmetric cell division and its regulation has also been discussed.

Rhodoccoccus erythropolis Is Different from Other Members of Actinobacteria: Monoploidy, Overlapping Replication Cycle, and Unique Segregation Pattern.

Among actinomycetes, chromosome organization and segregation studies have been limited to Streptomyces coelicolor, Corynebacterium glutamicum, and Mycobacterium spp. There are differences with respect to ploidy and chromosome organization pattern in these bacteria. Here, we report on chromosome replication, organization, and segregation in Rhodococcus erythropolis PR4, which has a circular genome of 6.5 Mbp. The origin of replication of R. erythropolis PR4 was identified, and the DNA content in the cell under different growth conditions was determined. Our results suggest that the number of origins increases as the growth medium becomes rich, suggesting an overlapping replication cell cycle in this bacterium. Subcellular localization of the origin region revealed polar positioning in minimal and rich media. The terminus, which is the last region to be replicated and segregated, was found to be localized at the cell center in large cells. The middle markers corresponding to the 1.5-Mb and 4.7-Mb loci did not overlap, suggesting discontinuity in the segregation of the two arms of the chromosome. Chromosome segregation was not affected by inhibiting cell division. Deletion of parA or parB affected chromosome segregation. Unlike in C. glutamicum and Streptomyces spp., diploidy or polyploidy was not observed in R. erythropolis PR4. Our results suggest that R. erythropolis is different from other members of Actinobacteria; it is monoploid and has a unique chromosome segregation pattern. This is the first report on chromosome organization, replication, and segregation in R. erythropolis PR4.IMPORTANCE Rhodococci are highly versatile Gram-positive bacteria with high bioremediation potential. Some rhodococci are pathogenic and have been suggested as emerging threats. No studies on the replication, segregation, and cell cycle of these bacteria have been reported. Here, we demonstrate that the genus Rhodococcus is different from other actinomycetes, such as members of the genera Corynebacterium, Mycobacterium, and Streptomyces, with respect to ploidy and chromosome organization and segregation. Such studies will be useful not only in designing better therapeutics pathogenic strains in the future but also for studying genome maintenance in strains used for bioremediation.

Deletion of pyruvate decarboxylase gene in Zymomonas mobilis by recombineering through bacteriophage lambda red genes.

Zymomonas mobilis ZM4 is a gram negative ethanologenic bacterium used in several biotechnological applications. Metabolic engineering in this bacterium is limited because of the available genome engineering tools. In the present study, we report genome engineering in this bacterium using bacteriophage lambda Red genes. Stability of plasmid replicons RK2 (pSIM9) and pBBR1 (pSIM7) containing the lambda Red genes was found to be 78% and 74%, respectively. We demonstrate successful deletion of pyruvate decarboxylase gene by recombineering in Z. mobilis. The deletion was confirmed by PCR and by estimating the metabolites formed. Ethanol, which was the main product in wild type cells, was formed in almost negligible amount in the pdc-deleted mutant. The developed Δpdc Z. mobilis cells can be exploited for production of desired bioproducts by expression of suitable enzymes that can regenerate NAD+.

Localization of Low Copy Number Plasmid pRC4 in Replicating Rod and Non-Replicating Cocci Cells of Rhodococcus erythropolis PR4.

Rhodococcus are gram-positive bacteria, which can exist in two different shapes rod and cocci. A number of studies have been done in the past on replication and stability of small plasmids in this bacterium; however, there are no reports on spatial localization and segregation of these plasmids. In the present study, a low copy number plasmid pDS3 containing pRC4 replicon was visualized in growing cells of Rhodococcus erythropolis PR4 (NBRC100887) using P1 parS-ParB-GFP system. Cells were initially cocci and then became rod shaped in exponential phase. Cocci cells were found to be non-replicating as evident by the presence of single fluorescence focus corresponding to the plasmid and diffuse fluorescence of DnaB-GFP. Rod shaped cells contained plasmid either present as one fluorescent focus observed at the cell center or two foci localized at quarter positions. The results suggest that the plasmid is replicated at the cell center and then it goes to quarter position. In order to observe the localization of plasmid with respect to nucleoid, plasmid segregation was also studied in filaments where it was found to be replicated at the cell center in a nucleoid free region. To the best of our knowledge, this is the first report on segregation of small plasmids in R. erythropolis.

Isolation and molecular characterization of a stationary phase promoter useful for gene expression in Gordonia.

Gordonia are gram-positive bacteria belonging to Actinomycetes family with a wide variety of industrial and environmental applications. The genetic toolbox, however, is limited for manipulation of these organisms. In the present study, a new promoter has been isolated from Gordonia sp. IITR 100 and characterized in detail. The promoter was found to be functional in Escherichia coli. The minimal promoter was identified in a 166bp fragment by deletion mapping. The putative -35 and -10 hexamer showed four and five nucleotide matches respectively with the E. coli consensus sequence. Three direct repeats and an imperfect inverted repeat upstream to -35 were found. The isolated promoter was found to be six times stronger than the Pkan promoter observed by cloning lacZ downstream to each of them in a plasmid in E. coli. The ß-galactosidase activity was maximum at stationary phase and found to be ~800MU for Gordonia sp. IITR 100 and E. coli. This is the first report of a stationary phase promoter isolated and characterized from Gordonia.