Genome of the extremely radiation-resistant bacterium Deinococcus radiodurans viewed from the perspective of comparative genomics.

The bacterium Deinococcus radiodurans shows remarkable resistance to a range of damage caused by ionizing radiation, desiccation, UV radiation, oxidizing agents, and electrophilic mutagens. D. radiodurans is best known for its extreme resistance to ionizing radiation; not only can it grow continuously in the presence of chronic radiation (6 kilorads/h), but also it can survive acute exposures to gamma radiation exceeding 1,500 kilorads without dying or undergoing induced mutation. These characteristics were the impetus for sequencing the genome of D. radiodurans and the ongoing development of its use for bioremediation of radioactive wastes. Although it is known that these multiple resistance phenotypes stem from efficient DNA repair processes, the mechanisms underlying these extraordinary repair capabilities remain poorly understood. In this work we present an extensive comparative sequence analysis of the Deinococcus genome. Deinococcus is the first representative with a completely sequenced genome from a distinct bacterial lineage of extremophiles, the Thermus-Deinococcus group. Phylogenetic tree analysis, combined with the identification of several synapomorphies between Thermus and Deinococcus, supports the hypothesis that it is an ancient group with no clear affinities to any of the other known bacterial lineages. Distinctive features of the Deinococcus genome as well as features shared with other free-living bacteria were revealed by comparison of its proteome to the collection of clusters of orthologous groups of proteins. Analysis of paralogs in Deinococcus has revealed several unique protein families. In addition, specific expansions of several other families including phosphatases, proteases, acyltransferases, and Nudix family pyrophosphohydrolases were detected. Genes that potentially affect DNA repair and recombination and stress responses were investigated in detail. Some proteins appear to have been horizontally transferred from eukaryotes and are not present in other bacteria. For example, three proteins homologous to plant desiccation resistance proteins were identified, and these are particularly interesting because of the correlation between desiccation and radiation resistance. Compared to other bacteria, the D. radiodurans genome is enriched in repetitive sequences, namely, IS-like transposons and small intergenic repeats. In combination, these observations suggest that several different biological mechanisms contribute to the multiple DNA repair-dependent phenotypes of this organism.

Physiologic determinants of radiation resistance in Deinococcus radiodurans.

Immense volumes of radioactive wastes, which were generated during nuclear weapons production, were disposed of directly in the ground during the Cold War, a period when national security priorities often surmounted concerns over the environment. The bacterium Deinococcus radiodurans is the most radiation-resistant organism known and is currently being engineered for remediation of the toxic metal and organic components of these environmental wastes. Understanding the biotic potential of D. radiodurans and its global physiological integrity in nutritionally restricted radioactive environments is important in development of this organism for in situ bioremediation. We have previously shown that D. radiodurans can grow on rich medium in the presence of continuous radiation (6,000 rads/h) without lethality. In this study we developed a chemically defined minimal medium that can be used to analyze growth of this organism in the presence and in the absence of continuous radiation; whereas cell growth was not affected in the absence of radiation, cells did not grow and were killed in the presence of continuous radiation. Under nutrient-limiting conditions, DNA repair was found to be limited by the metabolic capabilities of D. radiodurans and not by any nutritionally induced defect in genetic repair. The results of our growth studies and analysis of the complete D. radiodurans genomic sequence support the hypothesis that there are several defects in D. radiodurans global metabolic regulation that limit carbon, nitrogen, and DNA metabolism. We identified key nutritional constituents that restore growth of D. radiodurans in nutritionally limiting radioactive environments.

Engineering Deinococcus radiodurans for metal remediation in radioactive mixed waste environments.

We have developed a radiation resistant bacterium for the treatment of mixed radioactive wastes containing ionic mercury. The high cost of remediating radioactive waste sites from nuclear weapons production has stimulated the development of bioremediation strategies using Deinococcus radiodurans, the most radiation resistant organism known. As a frequent constituent of these sites is the highly toxic ionic mercury (Hg) (II), we have generated several D. radiodurans strains expressing the cloned Hg (II) resistance gene (merA) from Escherichia coli strain BL308. We designed four different expression vectors for this purpose, and compared the relative advantages of each. The strains were shown to grow in the presence of both radiation and ionic mercury at concentrations well above those found in radioactive waste sites, and to effectively reduce Hg (II) to the less toxic volatile elemental mercury. We also demonstrated that different gene clusters could be used to engineer D. radiodurans for treatment of mixed radioactive wastes by developing a strain to detoxify both mercury and toluene. These expression systems could provide models to guide future D. radiodurans engineering efforts aimed at integrating several remediation functions into a single host.

Genome sequence of the radioresistant bacterium Deinococcus radiodurans R1.

The complete genome sequence of the radiation-resistant bacterium Deinococcus radiodurans R1 is composed of two chromosomes (2,648,638 and 412,348 base pairs), a megaplasmid (177,466 base pairs), and a small plasmid (45,704 base pairs), yielding a total genome of 3,284, 156 base pairs. Multiple components distributed on the chromosomes and megaplasmid that contribute to the ability of D. radiodurans to survive under conditions of starvation, oxidative stress, and high amounts of DNA damage were identified. Deinococcus radiodurans represents an organism in which all systems for DNA repair, DNA damage export, desiccation and starvation recovery, and genetic redundancy are present in one cell.

Whole-genome shotgun optical mapping of Deinococcus radiodurans.

A whole-genome restriction map of Deinococcus radiodurans, a radiation-resistant bacterium able to survive up to 15,000 grays of ionizing radiation, was constructed without using DNA libraries, the polymerase chain reaction, or electrophoresis. Very large, randomly sheared, genomic DNA fragments were used to construct maps from individual DNA molecules that were assembled into two circular overlapping maps (2.6 and 0.415 megabases), without gaps. A third smaller chromosome (176 kilobases) was identified and characterized. Aberrant nonlinear DNA structures that may define chromosome structure and organization, as well as intermediates in DNA repair, were directly visualized by optical mapping techniques after gamma irradiation.

Engineering a recombinant Deinococcus radiodurans for organopollutant degradation in radioactive mixed waste environments.

Thousands of waste sites around the world contain mixtures of toxic chlorinated solvents, hydrocarbon solvents, and radionuclides. Because of the inherent danger and expense of cleaning up such wastes by physicochemical methods, other methods are being pursued for cleanup of those sites. One alternative is to engineer radiation-resistant microbes that degrade or transform such wastes to less hazardous mixtures. We describe the construction and characterization of recombinant Deinococcus radiodurans, the most radiation-resistant organism known, expressing toluene dioxygenase (TDO). Cloning of the tod genes (which encode the multicomponent TDO) into the chromosome of this bacterium imparted to the strain the ability to oxidize toluene, chlorobenzene, 3,4-dichloro-1-butene, and indole. The recombinant strain was capable of growth and functional synthesis of TDO in the highly irradiating environment (60 Gy/h) of a 137Cs irradiator, where 5x10(8)cells/ml degraded 125 nmol/ml of chlorobenzene in 150 min. D. radiodurans strains were also tolerant to the solvent effects of toluene and trichloroethylene at levels exceeding those of many radioactive waste sites. These data support the prospective use of engineered D. radiodurans for bioremediation of mixed wastes containing both radionuclides and organic solvents.

Recombination between a resident plasmid and the chromosome following irradiation of the radioresistant bacterium Deinococcus radiodurans.

Interplasmidic and intrachromosomal recombination in Deinococcus radiodurans has been studied recently and has been found to occur at high frequency following exposure to ionizing radiation. In the current work, we document plasmid-chromosome recombination following exposure of D. radiodurans to 1.75 Mrad (17.5 kGy) 60Co, when the plasmid is present in the cell at the time of irradiation. Recombination is assayed using both physical and allelic polymorphisms of homologous genes in the plasmid and chromosome. Recombination was found to be largely, but not entirely, recA-dependent. Crossovers occur frequently, and a significant fraction of these are non-reciprocal.

Identification and characterization of uvrA, a DNA repair gene of Deinococcus radiodurans.

Deinococcus radiodurans is extraordinarily resistant to DNA damage, because of its unusually efficient DNA repair processes. The mtcA+ and mtcB+ genes of D. radiodurans, both implicated in excision repair, have been cloned and sequenced, showing that they are a single gene, highly homologous to the uvrA+ genes of other bacteria. The Escherichia coli uvrA+ gene was expressed in mtcA and mtcB strains, and it produced a high degree of complementation of the repair defect in these strains, suggesting that the UvrA protein of D. radiodurans is necessary but not sufficient to produce extreme DNA damage resistance. Upstream of the uvrA+ gene are two large open reading frames, both of which are directionally divergent from the uvrA+ gene. Evidence is presented that the proximal of these open reading frames may be irrB+.

An alternative pathway of recombination of chromosomal fragments precedes recA-dependent recombination in the radioresistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans R1 and other members of this genus are able to repair and survive extreme DNA damage induced by ionizing radiation and many other DNA-damaging agents. The ability of R1 to repair completely > 100 double-strand breaks in its chromosome without lethality or mutagenesis is recA dependent. However, during the first 1.5 h after irradiation, recA+ and recA cells show similar increases in the average size of chromosomal fragments. In recA+ cells, DNA continues to enlarge to wild-type size within 29 h. However, in recA cells, no DNA repair is observed following the first 1.5 h postirradiation. This recA-independent effect was studied further, using two slightly different Escherichia coli plasmids forming adjacent duplication insertions in the chromosome, providing repetitive sequences suitable for circularization by non-recA-dependent pathways following irradiation. After exposure to 1.75 Mrad (17,500 Gy), circular derivatives of the integration units were detected in both recA+ and recA cells. These DNA circles were formed in the first 1.5 h postirradiation, several hours before the onset of detectable recA-dependent homologous recombination. By comparison, D. radiodurans strains containing the same E. coli plasmids as nonrepetitive direct insertions did not form circular derivatives of the integration units before or after irradiation in recA+ or recA cells. The circular derivatives of the tandemly integrated plasmids were formed before the onset of recA-dependent repair and have structures consistent with the hypothesis that DNA repair occurring immediately postirradiation is by a recA-independent single-strand annealing reaction and may be a preparatory step for further DNA repair in wild-type D. radiodurans.

Repair of ionizing-radiation damage in the radiation resistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans is extremely resistant to the lethal and mutagenic effects of ionizing-radiation and many other physical and chemical agents that damage DNA. This resistance is known to be due to D. radiodurans' extremely proficient DNA repair processes. However, little is known about the precise mechanisms employed by this organism to achieve its efficient repair. In the past two years there has been substantial progress in studies on the repair and tolerance of ionizing radiation damage. Areas of progress include: 1) studies on the importance of the deinococcal recA-gene in repair; 2) characterization of a large number of new ionizing radiation-sensitive strains; 3) newly discovered genetic loci with novel repair-related mutational phenotypes; 4) demonstration of efficient interplasmidic and interchromosomal recombination occurring postirradiation; and 5) recent speculations on the mechanisms of radiation resistance and the driving forces of natural selection for DNA damage resistance in D. radiodurans.

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.

Interchromosomal recombination in the extremely radioresistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans and other members of the genus Deinococcus are remarkable for their extreme resistance to ionizing radiation and many other agents that damage DNA. We have recently shown that recombinational processes participate in interplasmidic repair following in vivo irradiation. We now present direct studies on interchromosomal recombination among chromosomes irradiated in vivo during stationary phase (four chromosomes per cell). Following an exposure to 1.75 Mrad (the dose required to achieve a survival of 37%, which degrades the cells' four chromosomes into about 500 fragments), we determined that there may be as many as 175 crossovers per chromosome (700 crossovers per nucleoid) undergoing repair. In addition, these studies suggest that many of the crossovers occurring during repair are nonreciprocal.

A model for repair of radiation-induced DNA double-strand breaks in the extreme radiophile Deinococcus radiodurans.

The bacterium Deinococcus (formerly Micrococcus) radiodurans and other members of the eubacterial family Deinococaceae are extremely resistant to ionizing radiation and many other agents that damage DNA. Stationary phase D. radiodurans exposed to 1.0-1.5 Mrad gamma-irradiation sustains > 120 DNA double-strand breaks (dsbs) per chromosome; these dsbs are mended over a period of hours with 100% survival and virtually no mutagenesis. This contrasts with nearly all other organisms in which just a few ionizing radiation induced-dsbs per chromosome are lethal. In this article we present an hypothesis that resistance of D. radiodurans to ionizing radiation and its ability to mend radiation-induced dsbs are due to a special form of redundancy wherein chromosomes exist in pairs, linked to each other by thousands of four-stranded (Holliday) junctions. Thus, a dsb is not a lethal event because the identical undamaged duplex is nearby, providing an accurate repair template. As addressed in this article, much of what is known about D. radiodurans suggests that it is particularly suited for this proposed novel form of DNA repair.

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.

Defective transformation of chromosomal markers in DNA polymerase I mutants of the radioresistant bacterium Deinococcus radiodurans.

The transformation efficiency of six independently selected chromosomal markers (four for rifampicin resistance and two for acriflavine resistance) was found to be reduced by about 3 logs in a Deinococcus radiodurans strain that was isogenic with wild type except for an insertional mutation in the pol gene that eliminated DNA polymerase I activity (strain 6R1A). D. radiodurans strains UV17 and 303, previously obtained by chemical mutagenesis, were determined to be partially deficient in DNA Pol I activity as assessed in a permeabilized cell system. Both UV17 and 303 demonstrated intermediate transforming efficiencies that correlated with their levels of residual polymerase activity. The transformation efficiency of strain 6R1A could be greatly restored by expression of cloned E. coli DNA Pol I, but not to wild-type levels. Plasmid transfer and chromosomal duplication insertion were not substantially affected by lack of DNA Pol I activity. D. radiodurans is known to possess extraordinarily efficient repair pathways for DNA damage, and is refractory to DNA damage-induced mutagenesis caused by numerous agents, including several that cause base mispairing. We suggest that D. radiodurans may differ from other naturally transformable bacteria in that DNA Pol I is needed to efficiently convert most drug-resistance markers. This unusual mechanism may be required to accomplish chromosomal conversion prior to correction of donor DNA by this organism's efficient repair pathways.

DNA repair in the extremely radioresistant bacterium Deinococcus radiodurans.

Deinococcus radiodurans and other members of the same genus share extraordinary resistance to the lethal and mutagenic effects of ionizing and u.v. radiation and to many other agents that damage DNA. While it is known that this resistance is due to exceedingly efficient DNA repair, the molecular mechanisms responsible remain poorly understood. Following very high exposures to u.v. irradiation (e.g. 500 J m-2, which is non-lethal to D. radiodurans), this organism carries out extremely efficient excision repair accomplished by two separate nucleotide excision repair pathways acting simultaneously. One pathway requires the uvrA gene and appears similar to the UvrABC excinuclease pathway defined in Escherichia coli. The other excision repair pathway is specific for u.v. dimeric photoproducts, but is not mediated by a pyrimidine dimer DNA glycosylase. Instead, it is initiated by a second bona fide endonuclease that may recognize both pyrimidine dimers and pyrimidine-(6-4)pyrimidones. After high doses of ionizing-radiation (e.g. 1.5 Mrad), D. radiodurans can mend > 100 double-strand breaks (dsb) per chromosome without lethality or mutagenesis. Both dsb mending and survival are recA-dependent, indicating that efficient dsb mending proceeds via homologous recombination. D. radiodurans contains multiple chromosomes per cell, and it is proposed that dsb mending requires extensive recombination amongst these chromosomes, a novel phenomenon in bacteria. Thus, D. radiodurans may serve as an easily accessible model system for the double-strand-break-initiated interchromosomal recombination that occurs in eukaryotic cells during mitosis and meiosis.

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.

DNA deoxyribophosphodiesterase and an activity that cleaves DNA containing thymine glycol adducts in Deinococcus radiodurans.

Deinococcus radiodurans is the most radioresistant bacterium discovered to date. Recently it has been demonstrated that this organism contains the DNA repair enzyme uracil-DNA glycosylase and an apurinic/apyrimidinic (AP) endonuclease that may function as part of a DNA base excision repair pathway. We demonstrate here that a DNA deoxyribophosphodiesterase activity that acts on incised AP sites in DNA to remove deoxyribose-phosphate groups is found in lysates prepared from D. radiodurans cells. The partially purified activity was found to be smaller in size than the E. coli dRpase activity, with an estimated molecular weight of 25-30 kDa. In addition, an activity that recognizes and cleaves DNA containing thymine glycols was also detected, with a molecular weight of approximately 30 kDa. This enzyme may be analogous to the thymine glycol glycosylase/AP lyase endonuclease III of E. coli.

Sequencing, targeted mutagenesis and expression of a recA gene required for the extreme radioresistance of Deinococcus radiodurans.

Deinococcus radiodurans and other members of the same genus share extreme resistance to ionizing radiation and many other agents that damage DNA. A DNA damage-sensitive and natural transformation-deficient strain generated by chemical mutagenesis (strain rec30) was found to be defective in a gene that has extended homology with recA of Escherichia coli. Upon transformation with a chromosomal DNA fragment that contained this deinococcal recA gene from wild-type (wt) D. radiodurans both DNA damage resistance and full transformation competence were restored in the rec30 mutant. Targeted insertional mutagenesis of the deinococcal recA gene was used to construct a mutant isogenic with the wt. The insertional mutant was phenotypically indistinguishable from strain rec30, indicating that the recA defect alone was responsible for observed phenotypic alterations. For example, in the case of ionizing radiation, the D37 of the wt was about 1.75 Mrad, while the D37 of rec30 and the insertional mutant were both 25 krad, a 70-fold decrease. Evidence is presented that expression of the deinococcal recA gene in E. coli is lethal, suggesting that the mode of interaction of the deinococcal RecA protein with nucleic acids or other cellular proteins differs at least in part from RecA of E. coli.