Yogendra S. Rajpurohit

Involvement of a Protein Kinase Activity Inducer in DNA Double Strand Break Repair and Radioresistance of Deinococcus radiodurans

Transgenic bacteria producing pyrroloquinoline quinone, a known cofactor for dehydrogenases and an inducer of a periplasmic protein kinase activity, show resistance to both oxidative stress and protection from nonoxidative effects of radiation and DNA-damaging agents. Deinococcus radiodurans R1 encodes an active pyrroloquinoline quinone synthase, and constitutive synthesis of pyrroloquinoline quinone occurred in wild-type bacteria. Disruption of a genomic copy of pqqE resulted in cells that lacked this cofactor. The mutant showed a nearly 3-log decrease in gamma radiation resistance and a 2-log decrease in mitomycin C tolerance compared to wild-type cells. The mutant cells did not show sensitivity to UVC radiation. Expression of pyrroloquinoline quinone synthase in trans showed that there was functional complementation of gamma resistance and mitomycin C tolerance in the pqqE mutant. The sensitivity to gamma radiation was due to impairment or slow kinetics of DNA double strand break repair. Low levels of (32)P incorporation were observed in total soluble proteins of mutant cells compared to the wild type. The results suggest that pyrroloquinoline quinone has a regulatory role as a cofactor for dehydrogenases and an inducer of selected protein kinase activity in radiation resistance and DNA strand break repair in a radioresistant bacterium.

Characterization of a DNA damage‐inducible membrane protein kinase from Deinococcus radiodurans and its role in bacterial radioresistance and DNA strand break repair

Deinococcus radiodurans mutant lacking pyrroloquinoline–quinone (PQQ) synthesis shows sensitivity to γ‐rays and impairment of DNA double strand break repair. The genome of this bacterium encodes five putative proteins having multiple PQQ binding motifs. The deletion mutants of corresponding genes were generated, and their response to DNA damage was monitored. Only the Δdr2518 mutant exhibited higher sensitivity to DNA damage. Survival of these cells decreased by 3‐log cycle both at 6 kGy γ‐rays and 1200 J m−2 UV (254 nm) radiation, and 2.5‐log cycle upon 14 days desiccation at 5% humidity. The Δdr2518 mutant showed complete inhibition of DSB repair until 24 h PIR and disappearance of a few phosphoproteins. The Δdr2518pqqE:cat double mutant showed γ‐ray sensitivity similar to Δdr2518 indicating functional interaction of these genes in D. radiodurans. DR2518 contains a eukaryotic type Ser/Thr kinase domain and structural topology suggesting stress responsive transmembrane protein. Its autokinase activity in solution was stimulated by nearly threefold with PQQ and twofold with linear DNA, but not with circular plasmid DNA. More than 15‐fold increase in dr2518 transcription and several‐fold enhanced in vivo phosphorylation of DR2518 were observed in response to γ irradiation. These results suggest that DR2518 as a DNA damage‐responsive protein kinase plays an important role in radiation resistance and DNA strand break repair in D. radiodurans.

Structure-function study of deinococcal serine/threonine protein kinase implicates its kinase activity and DNA repair protein phosphorylation roles in radioresistance of Deinococcus radiodurans

The DR2518 (RqkA) a eukaryotic type serine/threonine protein kinase in Deinococcus radiodurans was characterized for its role in bacterial response to oxidative stress and DNA damage. The K42A, S162A, T169A and S171A mutation in RqkA differentially affected its kinase activity and functional complementation for γ radiation resistance in Δdr2518 mutant. For example, K42A mutant was completely inactive and showed no complementation while S171A, T169A and T169A/S171A mutants were less active and complemented proportionally to different levels as compared to wild type. Amongst, different DNA binding proteins that purified RqkA could phosphorylate, PprA a DNA repair protein, phosphorylation had improved its affinity to DNA by 4 fold and could enhance its supportive role in intermolecular ligation by T4 DNA ligase. RqkA phosphorylates PprA at threonine 72 (T72), serine 112 (S112) and threonine 144 (T144) in vitro with the majority of it goes to T72 site. Unlike wild type PprA and single mutants of T72, S112 and T144 residues, the T72AS112A double and T72AS112AT144A triple mutant derivatives of PprA did not phosphorylate in vivo and also failed to complement PprA loss in D. radiodurans. Deletion of rqkA in pprA::cat background enhanced radiosensitivity of pprA mutant, which became nearly similar to ΔrqkA resistance to γ radiation. These results suggested that K42 of RqkA is essential for catalytic functions and the kinase activity of RqkA as well as phosphorylation of PprA have roles in γ radiation resistance of D. radiodurans.

Characterization of the role of the RadS/RadR two-component system in the radiation resistance of Deinococcus radiodurans

Deinococcus radiodurans shows extraordinary tolerance to DNA damage, and exhibits differential gene expression and protein recycling. A putative response regulator, the DRB0091 (RadR) ORF, was identified from a pool of DNA-binding proteins induced in response to gamma radiation in this bacterium. radR is located upstream of drB0090, which encodes a putative sensor histidine kinase (RadS) on the megaplasmid. Deletion of these genes both individually and together resulted in hypersensitivity to DNA-damaging agents and a delayed or altered double-strand break repair. A ΔradRradS double mutant and a ΔradR single mutant showed nearly identical responses to gamma radiation and UVC. Wild-type RadR and RadS complemented the corresponding mutant strains, but also exhibited significant cross-complementation, albeit at lower doses of gamma radiation. The radS transcript was not detected in the ΔradR mutant, suggesting the existence of a radRS operon. Recombinant RadS was autophosphorylated and could catalyse the transfer of γ phosphate from ATP to RadR in vitro. These results indicated the functional interaction of RadS and RadR, and suggested a role for the RadS/RadR two-component system in the radiation resistance of this bacterium.

Pyrroloquinoline quinone and a quinoprotein kinase support γ-radiation resistance in Deinococcus radiodurans and regulate gene expression.

Deinococcus radiodurans is known for its extraordinary resistance to various DNA damaging agents including γ‐radiation and desiccation. The pqqE:cat and Δdr2518 mutants making these cells devoid of pyrroloquinoline quinone (PQQ) and a PQQ inducible Ser/Thr protein kinase, respectively, became sensitive to γ‐radiation. Transcriptome analysis of these mutants showed differential expression of the genes including those play roles in oxidative stress tolerance and (DSB) repair in D. radiodurans and in genome maintenance and stress response in other bacteria. Escherichia coli cells expressing DR2518 and PQQ showed improved resistance to γ‐radiation, which increased further when both DR2518 and PQQ were present together. Although, profiles of genes getting affected in these mutants were different, there were still a few common genes showing similar expression trends in both the mutants and some others as reported earlier in oxyR and pprI mutant of this bacterium. These results suggested that PQQ and DR2518 have independent roles in γ‐radiation resistance of D. radiodurans but their co‐existence improves radioresistance further, possibly by regulating differential expression of the genes important for bacterial response to oxidative stress and DNA damage.

Phosphorylation of Deinococcus radiodurans RecA Regulates Its Activity and May Contribute to Radioresistance.

Deinococcus radiodurans has a remarkable capacity to survive exposure to extreme levels of radiation that cause hundreds of DNA double strand breaks (DSBs). DSB repair in this bacterium depends on its recombinase A protein (DrRecA). DrRecA plays a pivotal role in both extended synthesis-dependent strand annealing and slow crossover events of DSB repair during the organisms recovery from DNA damage. The mechanisms that control DrRecA activity during the D. radiodurans response to γ radiation exposure are unknown. Here, we show that DrRecA undergoes phosphorylation at Tyr-77 and Thr-318 by a DNA damage-responsive serine threonine/tyrosine protein kinase (RqkA). Phosphorylation modifies the activity of DrRecA in several ways, including increasing its affinity for dsDNA and its preference for dATP over ATP. Strand exchange reactions catalyzed by phosphorylated versus unphosphorylated DrRecA also differ. In silico analysis of DrRecA structure support the idea that phosphorylation can modulate crucial functions of this protein. Collectively, our findings suggest that phosphorylation of DrRecA enables the recombinase to selectively use abundant dsDNA substrate present during post-irradiation recovery for efficient DSB repair, thereby promoting the extraordinary radioresistance of D. radiodurans.

DR1769, a Protein with N-Terminal Beta Propeller Repeats and a Low-Complexity Hydrophilic Tail, Plays a Role in Desiccation Tolerance of Deinococcus radiodurans

The Deinococcus radiodurans genome encodes five putative quinoproteins. Among these, the Δdr2518 and Δdr1769 mutants became sensitive to gamma radiation. DR2518 with beta propeller repeats in the C-terminal domain was characterized as a radiation-responsive serine/threonine protein kinase in this bacterium. DR1769 contains beta propeller repeats at the N terminus, while its C-terminal domain is a proline-rich disordered structure and constitutes a low-complexity hydrophilic region with aliphatic-proline dipeptide motifs. The Δdr1769 mutant showed nearly a 3-log cycle sensitivity to desiccation at 5% humidity compared to that of the wild type. Interestingly, the gamma radiation and mitomycin C (MMC) resistance in mutant cells also dropped by ∼1-log cycle at 10 kGy and ∼1.5-fold, respectively, compared to those in wild-type cells. But there was no effect of UV (254 nm) exposure up to 800 J · m(-2). These cells showed defective DNA double-strand break repair, and the average size of the nucleoid in desiccated wild-type and Δdr1769 cells was reduced by approximately 2-fold compared to that of respective controls. However, the nucleoid in wild-type cells returned to a size almost similar to that of the untreated control, which did not happen in mutant cells, at least up to 24 h postdesiccation. These results suggest that DR1769 plays an important role in desiccation and radiation resistance of D. radiodurans, possibly by protecting genome integrity under extreme conditions.

Structural and biophysical properties of h-FANCI ARM repeat protein

Fanconi anemia complementation groups – I (FANCI) protein facilitates DNA ICL (Inter-Cross-link) repair and plays a crucial role in genomic integrity. FANCI is a 1328 amino acids protein which contains armadillo (ARM) repeats and EDGE motif at the C-terminus. ARM repeats are functionally diverse and evolutionarily conserved domain that plays a pivotal role in protein–protein and protein–DNA interactions. Considering the importance of ARM repeats, we have explored comprehensive in silico and in vitro approach to examine folding pattern. Size exclusion chromatography, dynamic light scattering (DLS) and glutaraldehyde crosslinking studies suggest that FANCI ARM repeat exist as monomer as well as in oligomeric forms. Circular dichroism (CD) and fluorescence spectroscopy results demonstrate that protein has predominantly α- helices and well-folded tertiary structure. DNA binding was analysed using electrophoretic mobility shift assay by autoradiography. Temperature-dependent CD, Fluorescence spectroscopy and DLS studies concluded that protein unfolds and start forming oligomer from 30°C. The existence of stable portion within FANCI ARM repeat was examined using limited proteolysis and mass spectrometry. The normal mode analysis, molecular dynamics and principal component analysis demonstrated that helix-turn-helix (HTH) motif present in ARM repeat is highly dynamic and has anti-correlated motion. Furthermore, FANCI ARM repeat has HTH structural motif which binds to double-stranded DNA.

Studies of protein–protein interactions in Fanconi anemia pathway to unravel the DNA interstrand crosslink repair mechanism

Fanconi anemia (FA), a cancer predisposition syndrome exhibits hallmark feature of radial chromosome formation, and hypersensitivity to DNA crosslinking agents. A set of FA pathway proteins mainly FANCI, FANCD2 and BRCA2 are expressed to repair the covalent crosslink between the dsDNA. However, FA, BRCA pathways play an important role in DNA ICL repair as well as in homologous recombination repair, but the presumptive role of FA-BRCA proteins has not clearly explored particularly in context to function associated protein-protein interactions (PPIs). Here, in-vivo, in-vitro and in-silico studies have been performed for functionally relevant domains of FANCI, FANCD2 and BRCA2. To our conclusion, FANCI ARM repeat interacts with FANCD2 CUE domain and BRCA2 C-terminal region. Interestingly, FANCD2 CUE domain also interacts strongly with BRCA2 C-terminal region. Interactions between BRCA2 CTR and functionally relevant mutations Ser222Ala (cell cycle checkpoint mutant) and Leu231Arg (DNA ICL repair mutant) present in FANCD2 CUE domain have been analysed. To our finding, these mutations abrogate the binding between FANCD2 CUE domain and BRCA2 CTR. Furthermore, (1) different domain of FANCI, FANCD2 and BRCA2 are playing important role in PPIs, (2) mutations cause the impairment in the PPIs which in turn may disrupt the DNA ICL repair mechanism.

Protein–protein interactions of Fanconi anemia proteins FANCI, FANCD2 and BRCA2

Fanconi anemia (FA), a cancer predisposition syndrome, exhibit hallmark feature of radial chromosome formation and hyper sensitivity to DNA crosslinking agents [1]. A set of FA pathway (DNA inter-crosslink repair pathway) proteins mainly FANCI, FANCD2 and BRCA2 were expressed to repair the covalent crosslink between the dsDNA [2]. We have performed the multimodal approach to evaluate the structure and protein-protein interactions (PPI) between the different regions present in FANCI, FANCD2 and BRCA2 proteins. It has been observed that FANCI ARM repeat interacts with FANCD2 Cue domain and BRCA2 central region. Interestingly, FANCD2 Cue domain forms strong interaction with BRCA2 central region. We also tested the interaction between BRCA2 and functionally relevant mutations present in FANCD2 Cue domain, Ser222Ala (cell cycle checkpoint mutant) and Leu231Arg (DNA ICL repair mutant), and observed that mutations abrogates the binding ability. These results suggest that (1) domain and regions present in FANCI, FANCD2 and BRCA2 play important role in PPI, (2) mutations cause the failure in the PPI of these proteins, that affect the cell cycle and DNA repair processes. [1]Alter, B. P. (2003). Cancer 97, 425-440. [2]Cohen, M. M., Simpson, S. J., Honig, G. R., Maurer, H. S., Nicklas, J. W. & Martin, A. O. (1982). American journal of human genetics 34, 794-810.