FtsZ phosphorylation brings about growth arrest upon DNA damage in Deinococcus radiodurans.

The polymerization/depolymerization dynamics of FtsZ play a pivotal role in cell division in the majority of the bacteria. Deinococcus radiodurans, a radiation-resistant bacterium, shows an arrest of growth in response to DNA damage with no change in the level of FtsZ. This bacterium does not deploy LexA/RecA type of DNA damage response and cell cycle regulation, and its genome does not encode SulA homologues of Escherichia coli, which attenuate FtsZ functions in response to DNA damage in other bacteria. A radiation-responsive Ser/Thr quinoprotein kinase (RqkA), characterized for its role in radiation resistance in this bacterium, could phosphorylate several cognate proteins, including FtsZ (drFtsZ) at Serine 235 (S235) and Serine 335 (S335) residues. Here, we reported the detailed characterization of S235 and S335 phosphorylation effects in the regulation of drFtsZ functions and demonstrated that the phospho-mimetic replacements of these residues in drFtsZ had grossly affected its functions that could result in cell cycle arrest in response to DNA damage in D. radiodurans. Interestingly, the phospho-ablative replacements were found to be nearly similar to drFtsZ, whereas the phospho-mimetic mutant lost the wild-type protein's signature characteristics, including its dynamics under normal conditions. The kinetics of post-bleaching recovery for drFtsZ and phospho-mimetic mutant were nearly similar at 2 h post-irradiation recovery but were found to be different under normal conditions. These results highlighted the role of S/T phosphorylation in the regulation of drFtsZ functions and cell cycle arrest in response to DNA damage, which is demonstrated for the first time, in any bacteria.

Molecular insights into replication initiation in a multipartite genome harboring bacterium Deinococcus radiodurans.

Deinococcus radiodurans harbors a multipartite ploid genome system consisting of two chromosomes and two plasmids present in multiple copies. How these discrete genome elements are maintained and inherited is not well understood. PprA, a pleiotropic protein involved in radioresistance, has been characterized for its roles in DNA repair, genome segregation, and cell division in this bacterium. Here, we show that PprA regulates ploidy of chromosome I and II and inhibits the activity of drDnaA, the initiator protein in D. radiodurans. We found that pprA deletion resulted in an increased genomic content and ploidy of both the chromosomal elements. Expression of PprA in trans rescued the phenotypes of the pprA mutant. To understand the molecular mechanism underlying these phenotypes, we characterized drDnaA and drDnaB. As expected for an initiator protein, recombinant drDnaA showed sequence-specific interactions with the putative oriC sequence in chromosome I (oriCI). Both drDnaA and drDnaB showed ATPase activity, also typical of initiator proteins, but only drDnaB exhibited 5'→3' dsDNA helicase activity in vitro. drDnaA and drDnaB showed homotypic and heterotypic interactions with each other, which were perturbed by PprA. Interestingly, PprA has inhibited the ATPase activity of drDnaA but showed no effect on the activity of drDnaB. Regulation of chromosome copy number and inhibition of the initiator protein functions by PprA strongly suggest that it plays a role as a checkpoint regulator of the DNA replication initiation in D. radiodurans perhaps through its interaction with the replication initiation machinery.

Characterization of ori and parS-like functions in secondary genome replicons in Deinococcus radiodurans.

The mechanisms underlying multipartite genome maintenance and its functional significance in extraordinary radioresistance of Deinococcus radiodurans are not well understood. The sequences upstream to parAB operons in chrII (cisII) and MP (cisMP) could stabilize an otherwise, non-replicative colE1 plasmid, in D. radiodurans DnaA and cognate ParB proteins bound specifically with cisII and cisMP elements. The ΔcisII and ΔcisMP cells showed the reduced copy number of cognate replicons and radioresistance as compared with wild type. Fluorescent reporter-operator system inserted in chrI, chrII, and MP in wild type and cisII mutants showed the presence of all three replicons in wild-type cells. Although chrI was present in all the ΔcisII and ΔcisMP cells, nearly half of these cells had chrII and MP, respectively, and the other half had the reduced number of foci representing these replications. These results suggested that cisII and cisMP elements contain both origin of replication and parS-like functions and the secondary genome replicons (chrII and MP) are maintained independent of chrI and have roles in radioresistance of D. radiodurans.

Characterisation of ParB encoded on multipartite genome in Deinococcus radiodurans and their roles in radioresistance.

The Deinococcus radiodurans multipartite genome consists of 2 chromosomes and 2 plasmids Its genome encodes 4 ParA and 4 ParB proteins on different replicons. Multiple sequence alignments of ParBs encoded on these genome elements showed that ParB of primary chromosome (ParB1) is close to chromosomal type ParB and is found to be different from ParBs encoded on chromosome II (ParB2) and megaplasmid (ParB3) elements. We observed that ParB1, ParB2 and ParB3 exist as dimer in solution and these proteins interact to self but not to its homologs in D. radiodurans, suggesting the specificity in ParBs dimerization. The parB1 deletion mutant showed slow growth under normal condition and relatively reduced resistance to γ-radiation as compared to wild type. The parB2 and parB3 mutants maintained without selection pressure showed loss of radioresistance, which was not observed when maintained with selection pressure. Nearly half of the populations of these mutants showed resistance to antibiotics marked to respective genome elements. Interestingly, all the parB mutants showed increased copy numbers of cognate genome element in cells maintained with antibiotics possibly due to arrest in genome segregation. These results suggested that ParB proteins encoded on multipartite genome system in D. radiodurans form homodimer and not heterodimer with other ParB homologs, and they independently regulate the segregation of respective genome elements. The roles of ParB1 proteins in normal as well as radiation stressed growth of this bacterium have also been ascertained.

Plasmids for making multiple knockouts in a radioresistant bacterium Deinococcus radiodurans.

The gene knockouts are mostly created using homologous recombination-based replacement of target gene(s) with the expressing cassette of selection marker gene(s). Here, we constructed a series of plasmids bearing the expressing cassettes of genes encoding different antibiotics markers like nptII (KanR), aadA (SpecR), cat (CmR) and aac(3) (GenR). D. radiodurans is a radioresistant Gram positive bacterium that does not support the independent maintenance of colE1 origin-based plasmids. Using these constructs, the disruption mutants of both single and multiple genes involved in segregation of secondary genome elements have been generated in this bacterium. Unlike single mutants, the double and triple mutants showed growth retardation under normal growth conditions and the synergistic effects with Topoisomerase II inhibitor on the growth of this bacterium. Thus, these plasmids could be useful in creating multiple deletions/disruptions in bacteria that do not support independent maintenance of colE1 origin-based plasmid.

Phosphorylation of FtsZ and FtsA by a DNA Damage-Responsive Ser/Thr Protein Kinase Affects Their Functional Interactions in Deinococcus radiodurans.

Deinococcus radiodurans, a highly radioresistant bacterium, does not show LexA-dependent regulation of recA expression in response to DNA damage. On the other hand, phosphorylation of DNA repair proteins such as PprA and RecA by a DNA damage-responsive Ser/Thr protein kinase (STPK) (RqkA) could improve their DNA metabolic activities as well as their roles in the radioresistance of D. radiodurans Here we report RqkA-mediated phosphorylation of cell division proteins FtsZ and FtsA in vitro and in surrogate Escherichia coli bacteria expressing RqkA. Mass spectrometric analysis mapped serine 235 and serine 335 in FtsZ and threonine 272, serine 370, and serine 386 in FtsA as potential phosphorylation sites. Although the levels of FtsZ did not change during postirradiation recovery (PIR), phosphorylation of both FtsZ and FtsA showed a kinetic change during PIR. However, in an rqkA mutant of D. radiodurans, though FtsZ underwent phosphorylation, no kinetic change in phosphorylation was observed. Further, RqkA adversely affected FtsA interaction with FtsZ, and phosphorylated FtsZ showed higher GTPase activity than unphosphorylated FtsZ. These results suggest that both FtsZ and FtsA are phosphoproteins in D. radiodurans The increased phosphorylation of FtsZ in response to radiation damage in the wild-type strain but not in an rqkA mutant seems to be regulating the functional interaction of FtsZ with FtsA. For the first time, we demonstrate the role of a DNA damage-responsive STPK (RqkA) in the regulation of functional interaction of cell division proteins in this bacterium.IMPORTANCE The LexA/RecA-type SOS response is the only characterized mechanism of DNA damage response in bacteria. It regulates cell cycle by attenuating the functions of cell division protein FtsZ and inducing the expression of DNA repair proteins. There are bacteria, including Deinococcus radiodurans, that do not show this classical SOS response. D. radiodurans is known for its extraordinary resistance to gamma radiation, and a DNA damage-responsive Ser/Thr protein kinase (RqkA) has been characterized for its role in radioresistance. RqkA phosphorylates a large number of proteins in solution. The phosphorylation of RecA and PprA by RqkA enhanced their activities. FtsZ phosphorylation is inducible by gamma radiation in wild-type D. radiodurans but not in an rqkA mutant. Phosphorylation affected the interaction of FtsZ and FtsA in this bacterium. This study, therefore, brought forth some findings that might lead to the discovery of a new mechanism regulating the bacterial cell cycle in response to DNA damage.

Interdependence of bacterial cell division and genome segregation and its potential in drug development.

Cell division and genome segregation are mutually interdependent processes, which are tightly linked with bacterial multiplication. Mechanisms underlying cell division and the cellular machinery involved are largely conserved across bacteria. Segregation of genome elements on the other hand, follows different pathways depending upon its type and the functional components encoded on these elements. Small molecules, that are known to inhibit cell division and/or resolution of intertwined circular chromosome and maintenace of DNA topology have earlier been tested as antibacterial agents. The utility of such drugs in controlling bacterial infections has witnessed only partial success, possibly due to functional redundancy associated with targeted components. However, in due course, literature has grown with newer information. This review has brought forth some recent findings on bacterial cell division with special emphasis on crosstalk between cell division and genome segregation that could be explored as novel targets in drug development.

Divisome and segrosome components of Deinococcus radiodurans interact through cell division regulatory proteins.

The Deinococcus radiodurans genome encodes many of the known components of divisome as well as four sets of genome partitioning proteins, ParA and ParB on its multipartite genome. Interdependent regulation of cell division and genome segregation is not understood. In vivo interactions of D. radiodurans' sdivisome, segrosome and other cell division regulatory proteins expressed on multicopy plasmids were studied in Escherichia coli using a bacterial two-hybrid system and confirmed by co-immunoprecipitation with the proteins made in E. coli. Many of these showed interactions both with the self and with other proteins. For example, DrFtsA, DrFtsZ, DrMinD, DrMinC, DrDivIVA and all four ParB proteins individually formed at least homodimers, while DrFtsA interacted with DrFtsZ, DrFtsW, DrFtsE, DrFtsK and DrMinD. DrMinD also showed interaction with DrFtsW, DrFtsE and DrMinC. Interestingly, septum site determining protein, DrDivIVA showed interactions with secondary genome ParAs as well as ParB1, ParB3 and ParB4 while DrMinC interacted with ParB1 and ParB3. PprA, a pleiotropic protein recently implicated in cell division regulation, neither interacted with divisome proteins nor ParBs but interacted at different levels with all four ParAs. These results suggest the formation of independent multiprotein complexes of 'DrFts' proteins, segrosome proteins and cell division regulatory proteins, and these complexes could interact with each other through DrMinC and DrDivIVA, and PprA in D. radiodurans.