Deinococcus radiodurans - the consummate survivor

Relatively little is known about the biochemical basis of the capacity of Deinococcus radiodurans to endure the genetic insult that results from exposure to ionizing radiation and can include hundreds of DNA double-strand breaks. However, recent reports indicate that this species compensates for extensive DNA damage through adaptations that allow cells to avoid the potentially detrimental effects of DNA strand breaks. It seems that D. radiodurans uses mechanisms that limit DNA degradation and that restrict the diffusion of DNA fragments that are produced following irradiation, to preserve genetic integrity. These mechanisms also increase the efficiency of the DNA-repair proteins.     

How radiation kills cells: survival of Deinococcus radiodurans and Shewanella oneidensis under oxidative stress

We have recently shown that Deinococcus radiodurans and other radiation resistant bacteria accumulate exceptionally high intracellular manganese and low iron levels. In comparison, the dissimilatory metal-reducing bacterium Shewanella oneidensis accumulates Fe but not Mn and is extremely sensitive to radiation. We have proposed that for Fe-rich, Mn-poor cells killed at radiation doses which cause very little DNA damage, cell death might be induced by the release of Fe(II) from proteins during irradiation, leading to additional cellular damage by Fe(II)-dependent oxidative stress. In contrast, Mn(II) ions concentrated in D. radiodurans might serve as antioxidants that reinforce enzymic systems which defend against oxidative stress during recovery. We extend our hypothesis here to include consideration of respiration, tricarboxylic acid cycle activity, peptide transport and metal reduction, which together with Mn(II) transport represent potential new targets to control recovery from radiation injury.     

Protein oxidation implicated as the primary determinant of bacterial radioresistance

In the hierarchy of cellular targets damaged by ionizing radiation (IR), classical models of radiation toxicity place DNA at the top. Yet, many prokaryotes are killed by doses of IR that cause little DNA damage. Here we have probed the nature of Mn-facilitated IR resistance in Deinococcus radiodurans, which together with other extremely IR-resistant bacteria have high intracellular Mn/Fe concentration ratios compared to IR-sensitive bacteria. For in vitro and in vivo irradiation, we demonstrate a mechanistic link between Mn(II) ions and protection of proteins from oxidative modifications that introduce carbonyl groups. Conditions that inhibited Mn accumulation or Mn redox cycling rendered D. radiodurans radiation sensitive and highly susceptible to protein oxidation. X-ray fluorescence microprobe analysis showed that Mn is globally distributed in D. radiodurans, but Fe is sequestered in a region between dividing cells. For a group of phylogenetically diverse IR-resistant and IR-sensitive wild-type bacteria, our findings support the idea that the degree of resistance is determined by the level of oxidative protein damage caused during irradiation. We present the case that protein, rather than DNA, is the principal target of the biological action of IR in sensitive bacteria, and extreme resistance in Mn-accumulating bacteria is based on protein protection.     

Sensitivity of Deinococcus radiodurans to near-ultraviolet radiation

Although Dienococcus radiodurans is notoriously resistant to far-ultraviolet radiation (FUV; 254 nm), it is highly sensitive to near-ultraviolet radiation (NUV; 300-400 nm), thus demonstrating that the mechanisms of damage (and/or recovery) by the two types of irradiation are different. This observed difference between FUV and NUV effects in D. radiodurans agrees with previous studies with Escherichia coli. Near-ultraviolet radiation produces DNA damage which is presumed to be single-strand breaks (SSB) in the DNA of D. radiodurans. Unique lesions, such as DNA-protein crosslinks could not be demonstrated in this study. Cells that were pre-irradiated with a small dose of NUV were subsequently protected against inactivating doses of NUV. The data presented are consistent with induced DNA repair following NUV damage in D. radiodurans; this is in contrast to FUV damage where DNA repair is constitutive but not induced.     

Expression of recA in Deinococcus radiodurans.

Deinococcus (formerly Micrococcus) radiodurans is remarkable for its extraordinary resistance to ionizing and UV irradiation and many other agents that damage DNA. This organism can repair > 100 double-strand breaks per chromosome induced by ionizing radiation without lethality or mutagenesis. We have previously observed that expression of D. radiodurans recA in Escherichia coli appears lethal. We now find that the RecA protein of D. radiodurans is ot detectable in D. radiodurans except in the setting of DNA damage and that termination of its synthesis is associated with the onset of deinococcal growth. The synthesis of Shigella flexneri RecA (protein sequence identical to that of E. coli RecA) in recA-defective D. radiodurans is described. Despite a large accumulation of the S. flexneri RecA in D. radiodurans, there is no complementation of any D. radiodurans recA phenotype, including DNA damage sensitivity, inhibition of natural transformation, or inability to support a plasmid that requires RecA for replication. To ensure that the cloned S. flexneri recA gene was not inactivated, it was rescued from D. radiodurans and was shown to function normally in E. coli. We conclude that neither D. radiodurans nor S. flexneri RecA is functional in the other species, nor are the kinetics of induction and suppression similar to each other, indicating a difference between these two proteins in their modes of action.     

PprA: a novel protein from Deinococcus radiodurans that stimulates DNA ligation

The extraordinary radiation resistance of Deinococcus radiodurans results from the efficient capacity of the bacterium to repair DNA double-strand breaks. By analysing the DNA damage repair-deficient mutant, KH311, a unique radiation-inducible gene (designated pprA) responsible for loss of radiation resistance was identified. Investigations in vitro showed that the gene product of pprA (PprA) preferentially bound to double-stranded DNA carrying strand breaks, inhibited Escherichia coli exonuclease III activity, and stimulated the DNA end-joining reaction catalysed by ATP-dependent and NAD-dependent DNA ligases. These results suggest that D. radiodurans has a radiation-induced non-homologous end-joining repair mechanism in which PprA plays a critical role.     

Method for detecting DNA strand breaks in mammalian cells using the Deinococcus radiodurans PprA protein

In a previous study, we identified the novel protein PprA that plays a critical role in the radiation resistance of Deinococcus radiodurans. In this study, we focussed on the ability of PprA protein to recognize and bind to double-stranded DNA carrying strand breaks, and attempted to visualize radiation-induced DNA strand breaks in mammalian cultured cells by employing PprA protein using an immunofluorescence technique. Increased PprA protein binding to CHO-K1 nuclei immediately following irradiation suggests the protein is binding to DNA strand breaks. By altering the cell permeabilization conditions, PprA protein binding to CHO-K1 mitochondria, which is probably resulted from DNA strand break immediately following irradiation, was also detected. The method developed and detailed in this study will be useful in evaluating DNA damage responses in cultured cells, and could also be applicable to genotoxic tests in the environmental and pharmaceutical fields.     

Interplasmidic recombination following irradiation of the radioresistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans R1 and other members of the eubacterial family Deinococcaceae are extremely resistant to ionizing radiation and many other agents that damage DNA. For example, after irradiation, D. radiodurans can repair > 100 DNA double-strand breaks per chromosome without lethality or mutagenesis, while most other organisms can survive no more than 2 or 3 double-strand breaks. The unusual resistance of D. radiodurans is recA dependent, but the repair pathway(s) is not understood. Recently, we described how a plasmid present in D. radiodurans (plasmid copy number, approximately 6 per cell; chromosome copy number, approximately 4 per cell) during high-dose irradiation undergoes extreme damage like the chromosome and is retained by the cell without selection and fully repaired with the same efficiency as the chromosome. In the current work, we have investigated the repair of two similar plasmids within the same cell. These two plasmids were designed to provide both restriction fragment polymorphisms and a drug selection indicator of recombination. This study presents a novel system of analysis of in vivo damage and recombinational repair, exploiting the unique ability of D. radiodurans to survive extraordinarily high levels of DNA damage. We report that homologous recombination among plasmids following irradiation is extensive. For example, 2% of Tcs plasmids become Tcr as a result of productive recombination within a 929-bp region of the plasmids after repair. Our results suggest that each plasmid may participate in as many as 6.7 recombinational events during repair, a value that extrapolates to > 700 events per chromosome undergoing repair simultaneously. These results indicate that the study of plasmid recombination within D. radiodurans may serve as an accurate model system for simultaneously occurring repair in the chromosome.     

RecBC enzyme overproduction affects UV and gamma radiation survival of Deinococcus radiodurans

Deinococcus radiodurans recovering from the effect of acute dose of gamma (gamma) radiation shows a biphasic mechanism of DNA double strands breaks repair that involves an efficient homologous recombination. However, it shows higher sensitivity to near-UV (NUV) than Escherichia coli and lacks RecBC, a DNA strand break (DSB) repair enzyme in some bacteria. Recombinant Deinococcus expressing the recBC genes of E. coli showed nearly three-fold improvements in near-UV tolerance and nearly 2 log cycle reductions in wild type gamma radiation resistance. RecBC over expression effect on radiation response of D. radiodurans was independent of indigenous RecD. Loss of gamma radiation tolerance was attributed to the enhanced rate of in vivo degradation of radiation damaged DNA and delayed kinetics of DSB repair during post-irradiation recovery. RecBC expressing cells of Deinococcus showed wild type response to Far-UV. These results suggest that the overproduction of RecBC competes with the indigenous mechanism of gamma radiation damaged DNA repair while it supports near-UV tolerance in D. radiodurans.     

Effect of a recD mutation on DNA damage resistance and transformation in Deinococcus radiodurans

The bacterium Deinococcus radiodurans is resistant to extremely high levels of DNA-damaging agents such as UV light, ionizing radiation, and chemicals such as hydrogen peroxide and mitomycin C. The organism is able to repair large numbers of double-strand breaks caused by ionizing radiation, in spite of the lack of the RecBCD enzyme, which is essential for double-strand DNA break repair in Escherichia coli and many other bacteria. The D. radiodurans genome sequence indicates that the organism lacks recB and recC genes, but there is a gene encoding a protein with significant similarity to the RecD protein of E. coli and other bacteria. We have generated D. radiodurans strains with a disruption or deletion of the recD gene. The recD mutants are more sensitive than wild-type cells to irradiation with gamma rays and UV light and to treatment with hydrogen peroxide, but they are not sensitive to treatment with mitomycin C and methyl methanesulfonate. The recD mutants also show greater efficiency of transformation by exogenous homologous DNA. These results are the first indication that the D. radiodurans RecD protein has a role in DNA damage repair and/or homologous recombination in the organism.     

Radiation resistance of Deinococcus radiodurans R1 with respect to growth phase

Deinococcus species exhibit an extraordinary ability to withstand ionizing radiation (IR). Most of the studies on radiation resistance have been carried out with exponential phase cells. The studies on radiation resistance of Deinococcus radiodurans R1 with respect to different phases of growth showed that late stationary phase cells of D. radiodurans R1 were fourfold more sensitive to IR and heat as compared with exponential or early stationary phase cells. The increased sensitivity of D. radiodurans R1 to IR in the late stationary phase was not due to a decrease in the intracellular Mn/Fe ratio or an increase in the level of oxidative protein damage. The resistance to IR was restored when late stationary phase cells were incubated for 15 min in fresh medium before irradiation, indicating that replenishment of exhausted nutrients restored the metabolic capability of the cells to repair DNA damage. These observations suggest that stress tolerance mechanisms in D. radiodurans R1 differ from established paradigms.     

抗辐射菌中DNA损伤修复主要基因群的研究进展

抗辐射红色球菌对电离辐射具有很高的放射线抵抗性,该菌具有惊人的DNA的二条链切断的修复能力,由辐射等引起的切断损伤DNA在几至十几小时内能高效正确地进行完全修复。在对切断的双链DNA进行修复时,除了大肠杆菌等生物在切断的双链DNA修复时出现的蛋白质以外,还有该菌所特有的修复蛋白质也参与修复。本文对该菌所特有的DNA二条链的切断损伤修复的主要基因及其相互作用进行了简要介绍。     

Salt shield: intracellular salts provide cellular protection against ionizing radiation in the halophilic archaeon, Halobacterium salinarum NRC-1

The halophilic archaeon Halobacterium salinarum NRC-1 was used as a model system to investigate cellular damage induced by exposure to high doses of ionizing radiation (IR). Oxidative damages are the main lesions from IR and result from free radicals production via radiolysis of water. This is the first study to quantify DNA base modification in a prokaryote, revealing a direct relationship between yield of DNA lesions and IR dose. Most importantly, our data demonstrate the significance of DNA radiation damage other than strand breaks on cell survival. We also report the first in vivo evidence of reactive oxygen species scavenging by intracellular halides in H. salinarum NRC-1, resulting in increased protection against nucleotide modification and carbonylation of protein residues. Bromide ions, which are highly reactive with hydroxyl radicals, provided the greatest protection to cellular macromolecules. Modified DNA bases were repaired in 2 h post irradiation, indicating effective DNA repair systems. In addition, measurements of H. salinarum NRC-1 cell interior revealed a high Mn/Fe ratio similar to that of Deinococcus radiodurans and other radiation-resistant microorganisms, which has been shown to provide a measure of protection for proteins against oxidative damage. The work presented here supports previous studies showing that radiation resistance is the product of mechanisms for cellular protection and detoxification, as well as for the repair of oxidative damage to cellular macromolecules. The finding that not only Mn/Fe but also the presence of halides can decrease the oxidative damage to DNA and proteins emphasizes the significance of the intracellular milieu in determining microbial radiation resistance.     

Identification, sequencing, and targeted mutagenesis of a DNA polymerase gene required for the extreme radioresistance of Deinococcus radiodurans.

Deinococcus radiodurans and other species of the same genus share extreme resistance to ionizing radiation and many other agents that damage DNA. Two different DNA damage-sensitive strains generated by chemical mutagenesis were found to be defective in a gene that has extended DNA and protein sequence homology with polA of Escherichia coli. Both mutant strains lacked DNA polymerase, as measured in activity gels. Transformation of this gene from wild-type D. radiodurans restored to the mutants both polymerase activity and DNA damage resistance. A technique for targeted insertional mutagenesis in D. radiodurans is presented. This technique was employed to construct a pol mutant isogenic with the wild type (the first example of targeted mutagenesis in this eubacterial family). This insertional mutant lacked DNA polymerase activity and was even more sensitive to DNA damage than the mutants derived by chemical mutagenesis. In the case of ionizing radiation, the survival of the wild type after receiving 1 Mrad was 100% while survival of the insertional mutant extrapolated to 10(-24). These results demonstrate that the gene described here encodes a DNA polymerase and that defects in this pol gene cause a dramatic loss of resistance of D. radiodurans to DNA damage.     

Phototriggered formation and repair of DNA containing a site-specific single strand break of the type produced by ionizing radiation or AP lyase activity

DNA strand breaks are produced by a variety of agents and processes such as ionizing radiation, xenobiotics, oxidative metabolism, and enzymatic processing of DNA base damage. One of the major types of strand breaks produced by these processes is a single nucleotide gap terminating in 5'- and 3'-phosphates. Previously, we had developed a method for sequence-specifically producing such phosphate-terminated strand breaks in an oligodeoxynucleotide by way of two photochemically activated (caged) building blocks placed in tandem. We now report the design and synthesis of a single caged building block consisting of 1,3-(2-nitrophenyl)-1,3-propanediol, for producing phosphate-terminated strand breaks, and its use producing such a break at a specific site in a double-stranded circular DNA vector. To produce the site-specific break in a duplex vector, a primer containing the caged single strand break was extended opposite the single strand form of a circular DNA vector followed by enzymatic ligation and purification. The single strand break could then be formed in quantitative yield by irradiation of the vector with 365 nm light. In contrast to a previous study, it was found that the strand break can be repaired by Escherichia coli DNA polymerase I and E. coli DNA ligase alone, though less efficiently than in the presence of the 3'-phosphate processing enzyme E. coli endonuclease IV. Repair in the absence of endonuclease IV could be attributed to hydrolysis of the 3'-phosphate in the presence of dNTP and to a lesser extent to exonucleolytic removal of the 3'-phosphate-bearing terminal nucleotide by way of the 3' --> 5' exonuclease activity of polymerase I. This work demonstrates that specialized 3'-end processing enzymes such as endonuclease IV or exonuclease III are not absolutely required for repair of phosphate-terminated gaps. In addition to preparing single strand breaks, the caged building block described should also be useful for preparing double strand breaks and multiply damaged sites that might otherwise be difficult to prepare by other methods due to their lability.     

Poly(ADP-ribose) in the cellular response to DNA damage

Poly(ADP-ribose) polymerase is a chromatin-bound enzyme which, on activation by DNA strand breaks, catalyzes the successive transfer of ADP-ribose units from NAD to nuclear proteins. Poly(ADP-ribose) synthesis is stimulated by DNA strand breaks, and the polymer may alter the structure and/or function of chromosomal proteins to facilitate the DNA repair process. Electronmicroscopic studies show that poly(ADP-ribose) unwinds the tightly packed nucleosomal structure of isolated chromatin. Recent studies also show that the presence of poly(ADP-ribose) enhances the activity of DNA ligase. This may increase the capacity of the cell to complete DNA repair. Inhibitors of poly(ADP-ribose) polymerase or deficiencies of the substrate, NAD, lead to retardation of the DNA repair process. When DNA strand breaks are extensive or when breaks fail to be repaired, the stimulus for activation of poly(ADP-ribose) persists and the activated enzyme is capable of totally consuming cellular pools of NAD. Depletion of NAD and consequent lowering of cellular ATP pools, due to activation of poly(ADP-ribose) polymerase, may account for rapid cell death before DNA repair takes place and before the genetic effects of DNA damage become manifest.     

Characterization of human poly(ADP-ribose) polymerase with autoantibodies

The addition of poly(ADP-ribose) chains to nuclear proteins has been reported to affect DNA repair and DNA synthesis in mammalian cells. The enzyme that mediates this reaction, poly(ADP-ribose) polymerase, requires DNA for catalytic activity and is activated by DNA with strand breaks. Because the catalytic activity of poly(ADP-ribose) polymerase does not necessarily reflect enzyme quantity, little is known about the total cellular poly(ADP-ribose) polymerase content and the rate of its synthesis and degradation. In the present experiments, specific human autoantibodies to poly(ADP-ribose) polymerase and a sensitive immunoblotting technique were used to determine the cellular content of poly(ADP-ribose) polymerase in human lymphocytes. Resting peripheral blood lymphocytes contained 0.5 X 10(6) enzyme copies per cell. After stimulation of the cells by phytohemagglutinin, the poly(ADP-ribose) polymerase content increased before DNA synthesis. During balanced growth, the T lymphoblastoid cell line CEM contained approximately 2 X 10(6) poly(ADP-ribose) polymerase molecules per cell. This value did not vary by more than 2-fold during the cell growth cycle. Similarly, mRNA encoding poly(ADP-ribose) polymerase was detectable throughout S phase. Poly(ADP-ribose) polymerase turned over at a rate equivalent to the average of total cellular proteins. Neither the cellular content nor the turnover rate of poly(ADP-ribose) polymerase changed after the introduction of DNA strand breaks by gamma irradiation. These results show that in lymphoblasts poly(ADP-ribose) polymerase is an abundant nuclear protein that turns over relatively slowly and suggest that most of the enzyme may exist in a catalytically inactive state.     

Inhibition of repair of DNA single strand breaks in mouse leukemia cells by actinomycin D

The effects of Actinomycin D, cytosine arabinoside and temperature shifts on the repair of single strand breaks produced in murine leukemia cell DNA by ionizing radiation have been studied. A recently introduced modification of the alkaline sucrose sedimentation methods was used, allowing breaks to be demonstrated following clinical range irradiation doses. The results contrast to previous data using standard gradient procedures and indicate that low concentrations of Actinomycin D can inhibit single strand break repair, while cytosine arabinoside is ineffective. Inhibition can also be demonstrated by temperature shifts to 3° but not 24°, paralleling previous results from cellular repair studies (Elkind-Sutton repair). The results are consistent with the hypothesis that the accumulation of sublethal radiation damage in mammalian cells may be based on residual non-repaired single strand breaks.     

In vivo damage and recA-dependent repair of plasmid and chromosomal DNA in the radiation-resistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans R1 and other members of this genus share extraordinary resistance to the lethal and mutagenic effects of ionizing radiation. We have recently identified a RecA homolog in strain R1 and have shown that mutation of the corresponding gene causes marked radiosensitivity. We show here that following high-level exposure to gamma irradiation (1.75 megarads, the dose required to yield 37% of CFU for plateau-phase wild-type R1), the wild-type strain repairs > 150 double-strand breaks per chromosome, whereas a recA-defective mutant (rec30) repairs very few or none. A heterologous Escherichia coli-D. radiodurans shuttle plasmid (pMD68) was constructed and found to be retained in surviving D. radiodurans R1 and rec30 following any radiation exposure up to the highest dose tested, 3 megarads. Plasmid repair was monitored in vivo following irradiation with 1.75 megarads in both R1/pMD68 and rec30/pMD68. Immediately after irradiation, plasmids from both strains contained numerous breaks and failed to transform E. coli. While irradiation with 1.75 megarads was lethal to rec30 cultures, a small amount of supercoiled plasmid was regenerated, but it lacked the ability to transform E. coli. In contrast, wild-type cultures showed a cell division arrest of about 10 h, followed by exponential growth. Supercoiled plasmid was regenerated at normal levels, and it readily transformed E. coli. These studies show that D. radiodurans retains a heterologous plasmid following irradiation and repairs it with the same high efficiency as its chromosomal DNA, while the repair defect in rec30 prevents repair of the plasmid. Taken together, the results of this study suggest that plasmid DNA damaged in vivo in D. radiodurans is repaired by recA-dependent mechanisms similar to those employed in the repair of chromosomal DNA.     

耐辐射球菌DNA双链断裂修复机制研究新进展

耐辐射球菌对于电离辐射等DNA损伤剂具有极强的抗性,能够将同一个基因组中同时产生的高达100个以上的DNA双链断裂在数十小时内高效而精准地进行修复,是研究DNA双链断裂修复机制的重要模式生物。同源重组、非同源末端连接和单链退火途径作为3个主要的修复途径参与了耐辐射球菌基因组DNA双链断裂的修复过程。此外,一系列新发现的重要蛋白质,如Ppr I、Ddr B等对于耐辐射球菌基因组的修复过程同样至关重要。根据本实验室和国内外在这一研究领域近年来的报道,以不同的修复途径为线索,综述该菌DNA双链断裂修复机制的最新研究成果。