Liangyan Wang

DrRRA: a novel response regulator essential for the extreme radioresistance of Deinococcus radiodurans

Two‐component systems are predominant signal transduction pathways in prokaryotes, and also exist in many archaea as well as some eukaryotes. A typical TCS consists of a histidine kinase and a cognate response regulator. In this study, a novel gene encoding a response regulator (we designate it drRRA) is identified to be essential for the extreme radioresistance of Deinococcus radiodurans. DrRRA null mutant (we designate it MR) is sensitive to gamma‐radiation compared with the wild‐type strain. Transcriptional assays show that numerous genes are changed in their transcriptional levels in MR at exponential growth phase under normal or gamma‐radiation condition. Most of them are related to stress response and DNA repair. Antioxidant activity assays exhibit that both superoxide dismutases and catalases are decreased in the mutant, whereas Western blotting assays show that RecA and PprA are also reduced in MR, verifying the microarray and quantitative real‐time PCR data. Furthermore, pulsed‐field gel electrophoresis assay demonstrates that deletion of drRRA results in the delay of genome restitution. These data support the hypothesis that DrRRA contributes to the extreme radioresistance of D. radiodurans through its regulatory role in multiple pathways such as antioxidation and DNA repair pathways.

Effects of carotenoids from Deinococcus radiodurans on protein oxidation

Aims:  To evaluate the antioxidant effect of carotenoids from Deinococcus radiodurans on protein.

DdrB stimulates single-stranded DNA annealing and facilitates RecA-independent DNA repair in Deinococcus radiodurans

The bacterium Deinococcus radiodurans can survive extremely high exposure to ionizing radiation. The repair mechanisms involved in this extraordinary ability are still being investigated. ddrB is one gene that is highly up-regulated after irradiation, and it has been proposed to be involved in RecA-independent repair in D. radiodurans. Here we cloned, expressed and characterized ddrB in order to define its roles in the radioresistance of D. radiodurans. DdrB preferentially binds to single-stranded DNA. Moreover, it interacts directly with single-stranded binding protein of D. radiodurans DrSSB, and stimulates single-stranded DNA annealing even in the presence of DrSSB. The post-irradiation DNA repair kinetics of a ddrB/recA double mutant were compared to ddrB and recA single mutants by pulsed-field gel electrophoresis (PFGE). DNA fragment rejoining in the ddrB/recA double mutant is severely compromised, suggesting that DdrB-mediated single-stranded annealing plays a critical role in the RecA-independent DNA repair of D. radiodurans.

RecO Is Essential for DNA Damage Repair in Deinococcus radiodurans

Here we present direct evidence for the vital role of RecO in Deinococcus radioduranss radioresistance. A recO null mutant was constructed using a deletion replacement method. The mutant exhibited a growth defect and extreme sensitivity to irradiation with gamma rays and UV light. These results suggest that DNA repair in this organism occurs mainly via the RecF pathway.

Protease Activity of PprI Facilitates DNA Damage Response: Mn(2+)-Dependence and Substrate Sequence-Specificity of the Proteolytic Reaction

The extremophilic bacterium Deinococcus radiodurans exhibits an extraordinary resistance to ionizing radiation. Previous studies established that a protein named PprI, which exists only in the Deinococcus-Thermus family, acts as a general switch to orchestrate the expression of a number of DNA damage response (DDR) proteins involved in cellular radio-resistance. Here we show that the regulatory mechanism of PprI depends on its Mn(2+)-dependent protease activity toward DdrO, a transcription factor that suppresses DDR genes’ expression. Recognition sequence-specificity around the PprI cleavage site is essential for DNA damage repair in vivo. PprI and DdrO mediate a novel DNA damage response pathway differing from the classic LexA-mediated SOS response system found in radiation-sensitive bacterium Escherichia coli. This PprI-mediated pathway in D. radiodurans is indispensable for its extreme radio-resistance and therefore its elucidation significantly advances our understanding of the DNA damage repair mechanism in this amazing organism.

The Essential Role of H19 Contributing to Cisplatin Resistance by Regulating Glutathione Metabolism in High-Grade Serous Ovarian Cancer.

Primary and acquired drug resistance is one of the main obstacles encountered in high-grade serous ovarian cancer (HGSC) chemotherapy. Cisplatin induces DNA damage through cross-linking and long integrated non-coding RNAs (lincRNAs) play an important role in chemical induced DNA-damage response, which suggests that lincRNAs may be also associated with cisplatin resistance. However, the mechanism of long integrated non-coding RNAs (lincRNAs) acting on cisplatin resistance is not well understood. Here, we showed that expression of lin-RECK-3, H19, LUCAT1, LINC00961, and linc-CARS2-2 was enhanced in cisplatin-resistant A2780-DR cells, while transcriptome sequencing showed decreased Linc-TNFRSF19-1 and LINC00515 expression. Additionally, we verified that different H19 expression levels in HGSC tissues showed strong correlation with cancer recurrence. H19 knockdown in A2780-DR cells resulted in recovery of cisplatin sensitivity in vitro and in vivo. Quantitative proteomics analysis indicated that six NRF2-targeted proteins, including NQO1, GSR, G6PD, GCLC, GCLM and GSTP1 involved in the glutathione metabolism pathway, were reduced in H19-knockdown cells. Furthermore, H19-knockdown cells were markedly more sensitive to hydrogen-peroxide treatment and exhibited lower glutathione levels. Our results reveal a previously unknown link between H19 and glutathione metabolism in the regulation of cancer-drug resistance.

Structural and functional studies of MutS2 from Deinococcus radiodurans.

The MutS2 homologues have been found widespread in most prokaryotes, which are involved in DNA repair and reactive oxygen species detoxification. The C-terminal small mutS-related (Smr) domain is critical for its endonucleolytic activity. However, the detailed catalytic mechanism is still unclear. In this study, we first investigated the in vivo role of drMutS2 in Deinococcus radiodurans, the most radiation-resistant organism exhibits the remarkable DNA repair capacity. mutS2 and recA mutS2 double knockout mutants were constructed because the phenotype was strongly masked by the predominant homologous recombination DNA repair pathway in this bacterium. Compared with the recA mutant, cells devoid of both genes showed increased sensitivity to ionizing radiation and oxidative agents, suggesting that drMutS2 is involved in RecA-independent mechanisms that enhance cellular resistance to oxidative stress-induced DNA damage. Moreover, the basal level of reductase activity and thiamine biosynthesis was induced in the absence of mutS2. To characterize its catalytic residues, the Smr domain was crystallized and soaked in buffer containing manganese ions. In contrast to native crystals, the space group of manganese-derivative crystals transformed from monoclinic to orthorhombic unexpectedly. This type of crystals showed improved diffraction resolution to 1.2 Å, which has the highest resolution of currently known Smr structures. Structural comparison revealed that three acidic amino-acid residues, which are all located in the α1 helix, changed the rotamer states after metal soaking. Mutational analysis of conserved residue glutamic acid 710 to alanine yielded a drMutS2 variant with impaired nuclease activity, and could only partially rescue the radiosensitive phenotype of the mutS2 null strain, indicating that glutamic acid 710 is the catalytic residue.

Structural basis for DNA 5´-end resection by RecJ

The resection of DNA strand with a 5´ end at double-strand breaks is an essential step in recombinational DNA repair. RecJ, a member of DHH family proteins, is the only 5´ nuclease involved in the RecF recombination pathway. Here, we report the crystal structures of Deinococcus radiodurans RecJ in complex with deoxythymidine monophosphate (dTMP), ssDNA, the C-terminal region of single-stranded DNA-binding protein (SSB-Ct) and a mechanistic insight into the RecF pathway. A terminal 5´-phosphate-binding pocket above the active site determines the 5´-3´ polarity of the deoxy-exonuclease of RecJ; a helical gateway at the entrance to the active site admits ssDNA only; and the continuous stacking interactions between protein and nine nucleotides ensure the processive end resection. The active site of RecJ in the N-terminal domain contains two divalent cations that coordinate the nucleophilic water. The ssDNA makes a 180° turn at the scissile phosphate. The C-terminal domain of RecJ binds the SSB-Ct, which explains how RecJ and SSB work together to efficiently process broken DNA ends for homologous recombination. DOI: http://dx.doi.org/10.7554/eLife.14294.001

DRA0336, another OxyR homolog, involved in the antioxidation mechanisms in Deinococcus radiodurans

A novel OxyR (DR0615) with one conserved cysteine that senses hydrogen peroxide in Deinococcus radiodurans had been identified in our previous work. Comparative genomics revealed that D. radiodurans possesses another OxyR homolog, OxyR2 (DRA0336). In this study, we constructed the deletion mutant of oxyR2 and the double mutant of both the OxyR homologs to investigate the role of OxyR in response to oxidative stress in D. Radiodurans. Deletion of oxyR2 resulted in an obviously increased sensitivity to hydrogen peroxide, and the double mutant for oxyR and oxyR2 was significantly more sensitive than any of the two single mutants. The total catalase activity of the double mutant was lower than that of any of the single mutants, and reactive oxygen species (ROS) accumulated to a greater extent. DNA microarray analysis further suggested that oxyR2 was involved in antioxidation mechanisms. Site-direct mutagenesis and complementation analysis revealed that C228 in OxyR2 was essential. This is the first report of the presence of two OxyR in one organism. These results suggest that D. radiodurans OxyR and OxyR2 function together to protect the cell against oxidative stress.

Regulation of MntH by a dual Mn(II)- and Fe(II)-dependent transcriptional repressor (DR2539) in Deinococcus radiodurans.

The high intracellular Mn/Fe ratio observed within the bacteria Deinococcus radiodurans may contribute to its remarkable resistance to environmental stresses. We isolated DR2539, a novel regulator of intracellular Mn/Fe homeostasis in D. radiodurans. Electrophoretic gel mobility shift assays (EMSAs) revealed that DR2539 binds specifically to the promoter of the manganese acquisition transporter (MntH) gene, and that DR0865, the only Fur homologue in D. radiodurans, cannot bind to the promoter of mntH, but it can bind to the promoter of another manganese acquisition transporter, MntABC. β-galactosidase expression analysis indicated that DR2539 acts as a manganese- and iron-dependent transcriptional repressor. Further sequence alignment analysis revealed that DR2539 has evolved some special characteristics. Site-directed mutagenesis suggested that His98 plays an important role in the activities of DR2539, and further protein-DNA binding activity assays showed that the activity of H98Y mutants decreased dramatically relative to wild type DR2539. Our study suggests that D. radiodurans has evolved a very efficient manganese regulation mechanism that involves its high intracellular Mn/Fe ratio and permits resistance to extreme conditions.