A specific 3' exonuclease activity of UvrABC

Specific cutting of undamaged DNA by UvrABC nuclease is observed. It occurs seven nucleotides (nt) from the 3' terminus of oligonucleotides annealed to single-stranded M13 DNA circles. Although the location of the UvrABC cut on undamaged DNA is similar to that of the cut on the 5' side of a damaged DNA site during the dual incision reaction, the cut of undamaged DNA is not an intermediate in the dual incision step. On DNA duplexes with a single AAF adduct, the anticipated cut at the eighth phosphodiester bond 5' of the lesion is present, but extra cuts at 7-nt increments are observed at the 15th and 22nd phosphodiester bonds. We suggest that these additional cuts are made by the UvrABC activity observed on undamaged DNA; such activity is referred to as ABC 3' exonuclease and may play a significant role by providing a suitable gap for RecA-mediated recombinational exchanges during repair of interstrand crosslinks and closely opposed lesions. This ABC 3' exonuclease activity depends on higher concentrations of Uvr proteins as compared with dual incision and may be relevant to reactions that occur when UvrA and UvrB are increased during SOS induction.

UvrAB activity at a damaged DNA site: is unpaired DNA present?

To study the activity of the Escherichia coli UvrA and UvrB nucleotide excision repair proteins during the formation of the pre-incision complex at a damaged DNA site, we used substrates with modifications around a single 2-(acetylamino)fluorene (AAF) lesion. Based on the release of AAF-containing oligonucleotides from a single-stranded DNA circle, we conclude that during interaction with our substrates UvrAB introduces changes in DNA which are localized at the lesion and are limited to 1-3 bp. Since these changes might include a denaturation of DNA at the lesion site and, consequently, a bubble structure might be present in a pre-incision complex, we studied incision activity of UvrABC excinuclease on substrates with 1-4 unpaired bases next to an AAF adduct. Opening more than one base on either or both sides of the lesion caused a significant decrease in the incision activity of UvrABC, but did not change the position of the incision sites. We conclude that the UvrAB action leading to a pre-incision complex does not include the formation of a bubble intermediate generated by extensive denaturation of base pairs.

The limited strand-separating activity of the UvrAB protein complex and its role in the recognition of DNA damage

The recognition by Escherichia coli Uvr nucleotide excision repair proteins of a variety of lesions with diverse chemical structures and the presence of helicase activity in the UvrAB complex which can displace short oligonucleotides annealed to single-stranded DNA led to a model in which this activity moves UvrAB along undamaged DNA to damaged sites where the lesion blocks further translocation and the protein-DNA pre-incision complex is formed. To evaluate this mechanism for damage recognition, we constructed substrates with oligonucleotides of different lengths annealed to single-stranded DNA circles and placed a single 2-(acetylamino)fluorene (AAF) lesion either on the oligonucleotide or on the circle. For the substrates with no lesion, the UvrAB complex effectively displaced a 22-mer but not a 27-mer or longer fragments. The presence of AAF on the oligonucleotide significantly increased the release of the 27-mer but oligomers of 30 or longer were not separated. Placing the lesion on the circular strand did not block the release of the fragments. Instead, the releasing activity of UvrAB was stimulated and also depended on the length of the annealed oligonucleotide. These observations do not agree with the predictions of a damage recognition mechanism that depends on helicase-driven translocation. Most likely, the strand-separating activity of UvrAB is a consequence of local changes occurring during the formation of a DNA-protein pre-incision complex at the damaged site and is not due to translocation of the protein along undamaged DNA to locate a lesion.

Sabia virus incident at Yale University

An incident involving a human exposure to a newly isolated arenavirus, Sabia virus, in the Yale Arbovirus Research Unit occurred at Yale University on August 8, 1994. A senior-level visiting research scientist was exposed to Sabia virus while purifying the virus from a large volume of tissue culture fluid. The exposure resulted in development of a Sabia virus infection followed by recovery of the patient. The incident resulted in a comprehensive review by a Yale faculty committee and an external expert committee. As a result, a number of new practices and procedures were added to Yale's biosafety policy for investigating infectious agents in BL-3 facilities.

Interaction of the UvrABC endonuclease with DNA containing a psoralen monoadduct or cross-link. Differential effects of superhelical density and comparison of preincision complexes

The effect of negative supercoiling on UvrABC incision of covalently closed duplex DNA circles containing either a furan-side monoadduct or a cross-link of 4'-hydroxymethyl-4,5',8-trimethylpsoralen at a unique site was examined. The rate of UvrABC incision of these DNA substrates was measured as a function of superhelical density, sigma, for values of sigma between 0 and -0.050. The monoadducted DNA substrate was incised at close to the maximum rate at all superhelical densities, with only a slight stimulation of activity between sigma = 0 and -0.035. In contrast, efficient UvrABC incision of the cross-linked DNA substrate required the DNA to be underwound, and activity showed a linear dependence on superhelical density up to sigma = -0.035. DNase I protection studies show that in the presence of both UvrA and UvrB a protein complex binds to the site of a psoralen monoadduct or cross-link in linear DNA. This UvrA-UvrB-dependent complex binds with similar affinity to both the monoadducted and the cross-linked DNA helices. However, differences in the DNase I footprint on these two DNA substrates indicate that the interaction of this protein complex is different at these two lesions. The addition of UvrC to linear DNA molecules that are saturated at the site of the lesion with the UvrA-UvrB-dependent complex resulted in efficient nicking of the monoadducted DNA, but not the cross-linked DNA. Thus, the properties of a DNA lesion site that lead to UvrAB recognition and binding are not necessarily sufficient to allow incision when all three Uvr subunits are present. We propose that after recognition and binding of a lesion site by the UvrAB complex and prior to incision, the damaged DNA helix undergoes a conformational change such as unwinding or melting that is induced by the lesion-bound Uvr complex.

Localization of DNA repair synthesis by human cell extracts to a short region at the site of a lesion

Double-stranded bacteriophage M13 DNA molecules were constructed containing a single specifically placed 2-(acetylamino)fluorene adduct or a single 4'-hydroxymethyl-4,5',8-trimethylpsoralen monoadduct. These circular DNA molecules were used to analyze in vitro DNA repair synthesis by cell extracts from normal human lymphoid cell lines. Both types of lesions stimulate DNA repair synthesis at the site of the adduct. DNA repair synthesis induced by the 2-(acetyl-amino)fluorene adduct took place in the damaged strand and was confined to a region within a 31-base pair restriction fragment around the adduct.

UvrABC incision of N-methylmitomycin A-DNA monoadducts and cross-links

The Escherichia coli UvrABC endonuclease is a multisubunit enzyme that initiates the repair of a wide variety of DNA lesions in vivo by making dual incisions on a damaged strand at the eighth or ninth phosphodiester bond 5' and the fourth or fifth phosphodiester bond 3' to the modified base. It has been hypothesized that UvrABC is able to recognize a broad spectrum of lesions because it does not recognize the lesion per se but rather gross helical distortions that the lesion induces in the DNA. Several lesions have recently been studied which are thermal stabilizing and are not believed to distort the DNA grossly, including the CC-1065-N-3-adenine and anthramycin-N-2-guanine adducts. We have studied the activity of UvrABC in vitro on another thermal stabilizing and nondistortive adduct, N-methylmitomycin A (NMA), a bifunctional DNA-alkylating agent that reacts with guanine on the side facing the minor groove, yielding either monoadducts or interstrand cross-links. NMA adducts increase the thermal stability of DNA, and theoretical calculations indicate that NMA adducts do not grossly distort the DNA helix. Our results show that UvrABC makes incisions at the eighth phosphodiester bond 5' and the fifth phosphodiester bond 3' to an NMA monoadduct, consistent with the incision pattern observed for the majority of other lesions that are also recognized by UvrABC. DNA containing a site-specific NMA cross-link was also recognized and incised by UvrABC. The rate of incision of NMA cross-linked DNA was about 200-fold higher in supercoiled molecules than in relaxed molecules, whereas the rate of incision of DNA containing NMA monoadducts was stimulated approximately 2-fold by supercoiling. The signal for UvrABC recognition and incision of damaged DNA is discussed in relation to the ability of UvrABC to incise NMA adducts as well as other nondistortive lesions.

In vitro repair of psoralen-DNA cross-links by RecA, UvrABC, and the 5'-exonuclease of DNA polymerase I

Psoralens produce DNA interstrand cross-links which are thought to be repaired via a sequential excision and recombination mechanism in Escherichia coli. The first round of incision by UvrABC has been characterized: it results in 11-base oligonucleotide cross-linked to an intact DNA strand (Van Houten, B., Gamper, B., Holbrook, S.R., Hearst, J.E., and Sancar, A. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 8077-8081). In the present work, DNA substrates containing 4'-hydroxymethyl-4,5',8-trimethylpsoralen (HMT) cross-links in defined positions are constructed and used to analyze the other steps in repair. It is shown that RecA protein mediates strand transfer past an oligonucleotide cross-linked to a single-stranded DNA circle and that the resulting heteroduplex is a substrate for the UvrABC complex: it excises a double-stranded oligonucleotide which contains the HMT cross-link. It is also found that the first round of UvrABC incision does not lead directly to strand exchange but that an intervening step is needed. That step is carried out in vitro by the 5'-exonuclease activity of DNA polymerase I (pol I) which creates a single-stranded DNA region (a gap) at an incised cross-link such that RecA can initiate strand exchange. Studies using cross-linked oligonucleotides showed that the gap produced by pol I results from the inability of the polymerase to add nucleotides to a 3'-OH end two to three nucleotides away from the furan side of an HMT cross-link. Pol I can, however, extend a 3'-OH end next to the pyrone side of the cross-link. Since UvrABC incises predominantly the furan side of psoralen cross-links in duplex DNA, this discrepancy has important consequences for repair.

Repair of plasmid DNA damaged in vitro with cis- or trans-diamminedichloroplatinum(II) in Escherichia coli

Plasmid pBR322 was modified in vitro with the antitumor compound cis-diamminedichloroplatinum(II) (cis-DDP) or the isomeric trans-DDP. The numbers of platinum adducts were determined by atomic absorption spectrophotometry. DNA-repair-proficient and various DNA-repair-deficient (uvrB, uvrD, recB and recA) strains of Escherichia coli were transformed by the damaged plasmids and the ratios of the transformation frequencies of cells by damaged plasmids relative to those by untreated plasmids were determined. Results of transformation assays indicated that the uvrB gene function was essential for repair of plasmid DNA damaged with cis-DDP. A functional recA gene product seemed to be of minor importance for repair of plasmids damaged with cis-DDP. trans-DDP had a different effect on plasmid DNA. trans-DDP-modified DNA was better able to transform cells than cis-DDP-modified DNA, and the DNAs appeared to be repaired differently. Prior induction of SOS functions increased the survival of plasmids treated with cis-DDP in wild-type and uvrD mutants, but did not increase the survival of plasmids damaged with trans-DDP in these strains. In in vitro repair experiments, plasmid DNA modified with cis-DDP was more readily incised by the UVRABC excinuclease than that modified with trans-DDP.

Radiosensitization, pharmacokinetics, and toxicity of a 2-nitroimidazole nucleoside (RA-263)

A 2-nitroimidazole nucleoside, 1-(2',3'-dideoxy-alpha-D-erythro-hex-2'-enopyranosyl)-2-nitroimida zole (RA-263), has been investigated for its radiosensitization, pharmacokinetics, and toxicity properties. The in vitro radiosensitization tests against hypoxic Chinese hamster (V-79) cells demonstrated that RA-263 was a more potent radiosensitizer than misonidazole and at 2 mM concentration approached the oxic curve. Significant in vitro radiosensitization activity was also observed in EMT6 mammary tumor cells. The in vitro cytotoxicity data suggested that RA-263 is considerably more toxic to hypoxic cells than misonidazole. The increased cytotoxicity may be related to its higher depletion of nonprotein thiols (NPSH) than misonidazole. The combined effects of radiosensitization and hypoxic cell toxicity were measured by preincubation of the V-79 cells for 4 h under hypoxic conditions before irradiation. The results demonstrated a synergistic response by causing a significant decrease in the extrapolation number with loss of shoulder of the radiation survival curves. The in vivo radiosensitization experiments conducted by the in vivo-in vitro cloning assay with the EMT6 mammary tumor indicate that RA-263 is an effective sensitizer. Pharmacokinetic data suggested that RA-263 was eliminated from plasma by a rapid alpha phase and a slower beta phase with T 1/2 of 36 and 72 min, respectively. The concentration in the brain was approximately one-sixth of tumor concentration, suggesting that RA-263 is excluded from the CNS. Moreover, RA-263 was two times less toxic than misonidazole on equimolar basis by acute LD50 tests. This agent was also significantly less mutagenic than misonidazole in a strain of Escherichia coli.

Repair of haloethylnitrosourea-induced DNA damage in mutant and adapted bacteria

The sensitivities of Escherichia coli K-12 strain AB1157, its uvrA-deficient mutant AB1886, and its recA mutant AB2463 to N,N'-bis(2-chloroethyl)-N-nitrosourea, N-(2-chloroethyl)-N-nitrosourea, and N-ethyl-N-nitrosourea have been determined. These data indicate that loss of either uvr excision repair or recA-dependent DNA repair greatly increases sensitivity to the haloethylnitrosoureas. At the same time, loss of recA-dependent DNA repair increases sensitivity to N-ethyl-N-nitrosourea significantly while loss of uvr excision repair increases sensitivity to this agent only marginally. Adapting the uvrA-deficient and recA-deficient mutants by growth in N-methyl-N'-nitro-N-nitrosoguanidine increases survival after exposure to either N-methyl-N'-nitro-N-nitrosoguanidine or N-ethyl-N-nitrosourea, but neither adapted strain loses its sensitivity to N,N'-bis(2-chloroethyl)-N-nitrosourea. Taken together, these data indicate that the haloethylnitrosoureas cause other important cytotoxic lesions in DNA in addition to those involving alkylation of the O6 position of guanine and that the uvrA and recA gene products are involved in the repair of these lesions.

Reactions of the UVRABC excision nuclease with DNA damaged by diamminedichloroplatinum(II)

Mutants of Escherichia coli, which are blocked in excision repair (uvrA6, uvrB5, or uvrC34) are exceptionally sensitive to the antitumor drug cis-Pt(II)(NH3)2Cl2 (cis-DDP) but not the trans isomer. Plasmid DNA, damaged by either the cis or trans compound and treated with the UVRABC excision nuclease was cut as shown by conversion of supercoiled DNA to relaxed forms. All three protein products of the uvrA, uvrB, and uvrC genes were required for incision. End-labeled fragments damaged with cis-DDP and reacted with the UVRABC nuclease were cut at the 8th phosphodiester bond 5' and at the 4th phosphodiester bond 3' to adjacent GG's. DNA treated with trans-DDP was not cut appreciably at adjacent GG's by the repair enzyme as subsequent analysis of reaction products after enzyme digestion gave a pattern similar to those obtained with control untreated fragments. The results indicate that the UVRABC nuclease may promote cell survival by the removal of adjacent GG's which are crosslinked by cis-Pt(II)(NH3)2Cl2.

Cross-linking studies with the uvrA and uvrB proteins of E. coli

The interactions of the uvrA and uvrB proteins with DNA have been investigated using a DNA-protein cross-linking technique. It is demonstrated that hydrolysis of ATP by the uvrA protein facilitates cross-linking of this protein to single-stranded DNA, whether the DNA is UV irradiated or not. In contrast, cross-linking to unirradiated double-stranded DNA is not facilitated by ATP hydrolysis and is in fact increased by the substitution of the non-hydrolysable analogue aTP gamma S for ATP. In the presence of ATP, a dose-dependent increase is observed in the amount of uvrA protein which can be cross-linked to UV-irradiated double-stranded DNA. Binding of uvrB protein to puvrA-DNA complexes has a stabilising effect and increases the number of complexes which can be cross-linked whether the substrate is single- or double-stranded DNA. We can find no evidence that ATP hydrolysis by uvrA protein results in unwinding of UV-damaged DNA.

Analysis of mRNA synthesis following induction of the Escherichia coli SOS system

Escherichia coli responds to impairment of DNA synthesis by inducing a system of DNA repair known as the SOS response. Specific genes are derepressed through proteolytic cleavage of their repressor, the lexA gene product. Cleavage in vivo requires functional RecA protein in a role not yet understood. We used mRNA hybridization techniques to follow the rapid changes that occur with induction in cells with mutations in the recA operator or in the repressor cleavage site. These mutations allowed us to uncouple the induction of RecA protein synthesis from its role in inducing the other SOS functions. Following induction with ultraviolet light, we observed increased rates of mRNA synthesis from five SOS genes within five minutes, maximum expression ten to 20 minutes later and then a later decline to near the initial rates. The presence of a recA operator mutation did not significantly influence these kinetics, whereas induction was fully blocked by an additional mutation in the repressor cleavage site. These experiments are consistent with activation of RecA protein preceding repressor cleavage and derepression of SOS genes. The results also suggest that the timing and extent of induction of individual SOS genes may be different.

Interactions of the UVRABC endonuclease in vivo and in vitro with DNA damage produced by antineoplastic anthracyclines

The anthracycline antineoplastic agents Adriamycin and N-trifluoroacetyl-Adriamycin-14-valerate were assayed in vivo and in vitro for ability to produce DNA lesions recognized by the UVRABC endonuclease, a DNA repair enzyme of Escherichia coli which recognizes large, bulky lesions in DNA. We found that, while both drugs produce DNA lesions, only the lesions produced by Adriamycin were toxic. Hence, anthracycline antineoplastic activity may be related to production of large, bulky lesions in DNA, while toxicity may correlate with toxicity measured in a simple E. coli DNA repair mutant test system.

Sequences of the E. coli uvrC gene and protein

We have determined the sequence of a 2400 bp region of E. coli chromosomal DNA containing the uvrC gene. The coding region of uvrc is 2267 bp in length, encodes a polypeptide with a calculated molecular weight of 66,038 daltons, and is preceded by a typical E. coli ribosome binding site. By constructing deletion derivatives we have established that a uvrC promoter lies within the 113 bp region preceding the translational start of uvrC. The codon usage in uvrC is strongly biased in favor of codons used infrequently in E. coli, which may contribute to the relatively low intracellular concentration of uvrC protein.

Use of an Escherichia coli mutant strain permits measurement of single-stranded apurinic-apyrimidinic endonuclease in crude extracts: studies with untransformed cells and cells transformed with plasmids containing the uvrC gene

We have constructed a strain of Escherichia coli that is defective in exonuclease VII and uracil-DNA glycosylase activities. This strain (xse ung) facilitates the quantitation of single-stranded apurinic-apyrimidinic endonuclease activity in crude extracts. Quantitative comparisons of single-stranded apurinic-apyrimidinic endonuclease activity under conditions in which uvrC protein is overexpressed showed no differences, suggesting that single-stranded apurinic-apyrimidinic endonuclease and uvrC protein are probably distinct.

A novel repair enzyme: UVRABC excision nuclease of Escherichia coli cuts a DNA strand on both sides of the damaged region

The uvrA, uvrB, and uvrC proteins of Escherichia coli were purified from strains that greatly overproduce these proteins. Using the purified proteins, the UVRABC nuclease was reconstituted in vitro. The reconstituted enzyme acted specifically on DNA damaged with UV, cis-platinum, and psoralen plus near UV. When UV-irradiated DNA was used as substrate, the enzyme made two cuts on the damaged DNA strand, one on each side of the damaged region. The enzyme hydrolyzed the eighth phosphodiester bond on the 5' side of pyrimidine dimers. On the 3' side of pyrimidine dimers, the UVRABC nuclease cut the fourth or the fifth phosphodiester bond 3' to pyrimidine dimers. The oligonucleotide with the damaged bases that is generated by these two cuts was released during treatment with the enzyme. We have also obtained evidence suggesting that the enzyme acts by the same mechanism on PydC photoproducts which are thought to be of primary importance in UV-induced mutagenesis.

Properties and regulation of the UVRABC endonuclease

This report summarizes the cloning of the uvrA, uvrB and uvrC genes of E. coli, the identification and isolation of the gene products, the regulation of the genes, and reconstitution of active UVRABC endonuclease from the individually isolated components.

The uvrB gene of Escherichia coli has both lexA-repressed and lexA-independent promoters

We have found that the uvrB gene of Escherichia coli is transcribed from at least two promoters, which we call P1 and P2. Transcription from P1 begins with an ATP at +1, and transcription from P2 begins primarily with a GTP at -31. A binding site for the lexA protein (LEXA), located between the -35 sequence and Pribnow box of P2, regulates transcription from this promoter. In vitro, LEXA inhibits transcription from P2 but has no detectable effect on transcription from P1. A third promoter, P3, was also detected at -341; transcription from P3 is toward uvrB but terminates in vitro in the region of the LEXA binding site. The binding of LEXA to P2 inhibits transcription from the P3 promoter even though several hundred nucleotides separate the two promoters. The data suggest that a transcribing RNA polymerase stalls when it reaches the repressor-operator complex but remains bound to the DNA, causing a jamming of RNA polymerases between P3 and the repressor-operator complex at P2. The physiological significance of P3 is unknown.

A general approach for purifying proteins encoded by cloned genes without using a functional assay: isolation of the uvrA gene product from radiolabeled maxicells

The uvrA protein (UVRA) of E. coli has been extensively purified from a strain in which UVRA is overproduced and specifically labeled with 35S-methionine. This approximately 100-fold overproduction relative to normal strains is a result of having the uvrA gene present on a multicopy plasmid in a spr recA cell that makes defective lexA protein, the normal repressor of the uvrA gene, while the specific labeling of UVRA is done with maxicells. This approach facilitates the preparation of the protein since enzyme assays do not have to be carried out during the intermediate stages of purification. The purified UVRA binds to DNA and has ATPase activity but does not have intrinsic endonuclease activity. When added to extracts of uvrA- cells, the purified UVRA does promote the specific cutting of UV-irradiated DNA. Since this approach for working out rapid purification procedures by specifically labeling the proteins encoded by cloned genes does not require the use of a functional assay, it is a general one that can be applied to a wide variety of other gene products in addition to UVRA.

Identification of the uvrC gene product

We have constructed a multicopy plasmid that carries the uvrC gene of Escherichia coli. By inserting the transposon Tn1000 (previously designated gamma delta) into this plasmid, we obtained many derivatives that fail to complement uvrC34. The proteins synthesized by the original plasmid and the uvrC::Tn1000 derivatives were labeled in maxicells and analyzed on gels, demonstrating that a protein of Mr 70,000 encoded by the original uvrC+ plasmid was absent from the mutated noncomplementing derivatives; this protein is presumed to be the uvrC gene product. We found that this protein of Mr 70,000 binds to DNA and have partially purified the uvrC protein by DNA-cellulose chromatography. Because some of the uvrC::Tn1000 derivatives produce truncated polypeptides, the orientation of expression and the location of the promoter were determined by correlating the sizes of the truncated polypeptides with the sites of insertion of Tn1000.

Sequences of the ssb gene and protein

We have determined the sequences of the ssb gene and protein of Escherichia coli. The coding region of ssb is 534 base pairs and is preceeded and followed by dyad symmetries of 39 base pairs and 27 base pairs, respectively. The promoter for ssb is close to that for uvrA and these two genes are transcribed in opposite directions: ssb clockwise and uvrA counterclockwise on the standard E. coli genetic map. The DNA helix-destabilizing protein encoded by the ssb gene (single-strand binding protein) contains 177 amino acids and has a calculated molecular weight of 18,873. Although there is no extensive sequence homology among the three helix-destabilizing proteins whose sequences are now known, both the E. coli and bacteriophage T4 DNA helix-destabilizing proteins do contain an acidic, alpha-helical region at their carboxy termini that may be functionally homologous. The remainder of the E. coli helix-destabilizing protein can be divided into two apparent domains on the basis of its amino acid sequence. The amino-terminal region (residues 1-105) contains 79% of the charged residues (27 out of 34 total) in the protein and is predicted to have a high degree of secondary structure (alpha helix and beta pleated sheet). In contrast, the region including residues 106-165 contains only two charged amino acids and is devoid of alpha helix or beta pleated sheet.

Impaired incision of ultraviolet-irradiated deoxyribonucleic acid in uvrC mutants of Escherichia coli

The production of single-strand breaks in the deoxyribonucleic acid of irradiated uvrC mutants of Escherichia coli K-12 was studied both in vivo and in vitro. In vivo, uvrC mutants displayed a slow accumulation of breaks after irradiation, and in this respect appeared different from uvrA mutants, in which very few breaks could be detected. The breakage observed in uvrC mutants differed from that observed in wild-type strains in both the slow rate of break accumulation and the very limited dose response. The behavior of the uvrC lig-7(Ts) double mutant was shown not to be consistent with the suggestion of ligase reversal as the explanation for the lower rate and limited dose response of break formation observed in ultraviolet-irradiated uvrC mutants in vivo. Rather, there appeared to be a real defect in incision. In toluene-treated cells, we studied the effect of the ligase inhibitor nicotinamide mononucleotide on strand incision. Whereas uvrC mutants displayed more strand breakage in the presence of this inhibitor, the same amount of breakage was seen in uvrA mutants, and as such the breakage could be judged as not due to the main excision repair pathway. Experiments using a cell-free system comprising the partially purified uvr+ gene products demonstrated clearly that there is a requirement for the uvrC+ gene product for strand incision. We suggest that in vivo in the absence of the uvrC+ gene product, a partial analog of this protein may allow some abnormal incision.

Amplification of single-strand DNA binding protein in Escherichia coli

An E. coli strain containing a recombinant plasmid carrying the E. coli ssbA+ gene has been shown to produce 12 to 15 fold increased amounts of single-strand DNA binding-protein relative to wild-type strains. In addition, a gamma transducing phage carrying the E. coli uvrA+ gene has been shown to also carry the ssbA+ gene and to be capable of producing increased amounts of binding protein.

Sequences of the recA gene and protein

We have determined the nucleotide sequence of the recA gene of Escherichia coli; this permits the formulation of the primary structure for the recA protein. This structure is consistent with the amino acid composition of the tryptic peptides obtained from the recA protein. The coding region of the recA gene has 1059 base pairs, which specify 352 amino acids. The recA protein has alanine and phenylalanine as its NH2- and COOH-terminal amino acids, respectively, and has the following amino acid composition: Cys3 Asp20 Asn15 Met9 Thr17 Ser20 Glu30 Gln13 Pro10 Gly35 Ala38 Val22 Ile27 Leu31 Tyr7 Phe10 His2Lys27 Trp2 Arg14. Of the three cysteine residues, only two can be alkylated under reducing and denaturing conditions. The molecular weight of the recA polypeptide is 37,842.

Physical map of the recA gene

We have cloned the recA gene of Echerichia coli K12 and some of its restriction fragments on the plasmid cloning vehicle pBR322. The recA gene was mapped with regard to the restriction sites of EcoRI, BamHI, Pst I, Hha I, Hae III, HinfI, and Taq I restriction endonucleases. The recA promoter was localized by the binding of RNA polymerase to restriction fragments. The initiation point of transcription of recA mRNA and the direction of transcription were determined from in vitro transcription of recA gene fragments and from analysis of the polypeptides made in maxicells that contain plasmids carrying only part of the recA gene.

Potential radiosensitizing agents. Dinitroimidazoles

New compounds of the nitroimidazole series have been synthesized as radiosensitizers which selectively sensitize hypoxic cells to the lethal effect of radiation. The reaction of 2,4(5)-dinitroimidazole (2) with chloroethanol or hydrochloric acid yielded 4(5)-nitro-5(4)-chloroimidazole (3), which upon reaction with ethylene oxide yielded the 4-nitro-5-chloroimidazole-1-ethanol (6). Reaction of 2 with ethylene oxide resulted in a mixture of two compounds, the 2,4-dinitroimidazole-1-ethanol (4) and 2,3-dihydro-5-nitroimidazo[2,1-b]oxazole (5). The structure of the new heterocyclic compound 5 was confirmed by 1H NMR, mass spectrum, and X-ray crystallography. These agents were tested for their ability to sensitize hypoxic Escherichia coli cells to killing by ionizing radiation. Compound 4 was found to be the most active agent of this series of compounds.

Simple method for identification of plasmid-coded proteins

Proteins encoded by plasmid DNA are specifically labeled in UV-irradiated cells of Escherichia coli carrying recA and uvrA mutations because extensive degradation of the chromosome DNA occurs concurrently with amplification of plasmid DNA.

Hypoxic radiosensitizers: prospects for effective compounds with fewer toxic side-effects

Several radiosensitizing chemicals, including a family of simple nitroimidazoles, were examined in E. coli and compared with misonidazole for toxic side-effects on endpoints such as mutagenesis, cell killing and inhibition of the synthesis of the inducible enzyme beta-galactosidase. While all the compounds were similar to misonidazole or better in radiosensitization, marked differences in the various side effects were found. There results show that for E. coli it is possible to find compounds that sensitize as well as misonidazole but which have decreased mutagenicity and fewer other side-effects. Of the compounds examined, KA121 (2,5-dinitroimidazole) is the most promising for future study because it combines good radiosensitization with low mutagenicity and toxicity.

Lambda bacteriophage gene produces and X-ray sensitivity of Escherichia coli: comparison of red-dependent and gam-dependent radioresistance

When gene products of lambda bacteriophage are introduced into a cell by transient induction of a lysogen, increased resistance of the cells to X rays results. This phenomenon has been called phage-induced radioresistance. Genetic studies show at least two classes of induced radioresistance. The first type depends on the products of the lambda red genes and is observed in bacteria that are mutated in the recB gene. It is thought that the lambda red products compensate for the missing RecBC nuclease in the repair of X-ray damage. An optimal effect is obtained even when the lambda red products are supplied 1 h after irradiation. The lesions that are affected by the red-dependent process are probably not deoxyribonucleic acid strand breaks because the extent of deoxyribonucleic acid strand rejoining is not altered by the red products. The second type of phage-induced radioresistance requires the gam product of lambda and is observed in wild-type and polA strains. The lambda gam+ gene produce must be present immediately after irradiation to exert its full effect. In its presence, DNA breakdown is decreased, and a greater fraction of DNA is converted back to high molecular weight. Strains carrying lex, recA, or certain other combinations of mutations do not show any detectable phage-induced radioresistance.

Biochemically aberrant Salmonella enteritidis ser. newington from human sources in Connecticut

Three isolates of a lactose-fermenting, xylose-negative variety of Salmonella enteritidis ser. newington, identical in biochemical and serological reactions and in the antibiogram, were recovered from three patients in different areas of Connecticut in January 1974. Hydrogen sulfide production was not visible in Salmonella-Shigella agar, in triple sugar iron agar, and in Kligler iron agar but was noticed in lysine iron agar and on XLD agar, among others. The amount of fermentable carbohydrates present was found to correlate with failure to show hydrogen sulfide production (pH effect). In contrast to lactose-fermenting Salmonella strains reported by other authors, we could not elicit a direct transfer of the lac(+) character at frequencies above 10(-6). An epidemiological follow-up remained unsuccessful. Recommendations for the recognition of similar strains are presented.

Recombination and postreplication repair

The available data concerning postreplication repair are summarized. In Escherichia coli, recombination is implicated in this repair because the recA+ gene is necessary and because strand exchanges occur that extend over long regions. Other experiments involving phage-induced resistance also point to an interrelation between recombination and repair. In this phenomenon, gene products of lambda bacteriophage are introduced into bacteria, resulting in an increased resistance of the cells when they are subsequently exposed to X rays.

DNA strand breaks measured within 100 milliseconds of irradiation of Escherichia coli by 4 MeV electrons

A method was developed in which E. coli cells were irradiated with four MeV electrons and transferred to alkaline detergent within a fraction of a second. This technique minimizes the amount of repair of radiation damage before analysis without the necessity of using physical or chemical treatments to inhibit repair and alter the physiological condition of the cells. The yield of DNA strans breaks formed in covalent circular superhelical lambda DNA molecules superinfecting E. coli lysogens was about 4-fold greater when the cells were irradiated in oxygen than when they were irradiated under nitrogen anoxia. The same yields were obtained in phosphate buffer at 3 degrees and 22 degrees as well as in growth medium at 37 degrees, and the yields were not altered by the polA1 mutation. When E. coli lysogenic cells superinfected with lambda were irradiated with doses sufficient to introduce at least seven breaks in the phage DNA, the chromosomal DNA and the superinfecting phage DNA sedimented similarly in alkaline sucrose gradients, indicating that both DNAs were broken to a similar extent during irradiation. However, the yield of breaks calculated for chromosomal DNA in similar experiments was greater than the yield calculated from the first break introduced into covalent circular lambda DNA molecules. These apparently contradictory results are explicable either if the initial break in a superhelical molecule occurs with an efficiency different from that for subsequent breaks, or if the pulsed electron radiation produces a high proportion of double-strand breaks.

Interaction of bacterial and lambda phage recombination systems in the x-ray sensitivity of Escherichia coli K-12

E. coli cells lysogenic for the thermoinducible prophage lambdacI857 can be transiently induced by a brief heat treatment. Although this treatment does not kill the cells, some lambda products normally formed during vegetative phage development are made that can alter the response of host cells to x-irradiation by causing an increase in radioresistance. This increased resistance is particularly striking in the recombination-deficient recB-strain, which is normally much more radiosensitive than its recB(+) parent. After pulse-heating at 42 degrees , the survival curve of E. coli recB(-) lysogenized with lambdacI857 does not differ from that of the wild-type strain. Since lambda red mutants do not increase the radioresistance of recB(-) strains, both lambda red gene products, lambda exonuclease and beta-protein, are required to compensate for the missing recB product. Furthermore, phage-induced radioresistance also occurs in recB(+) lysogens even when they carry lambda red(-), but not when the lambda prophage is gam(-). Thus, in wild-type cells, phage-induced radioresistance requires some interaction between the bacterial recB gene product (exonuclease V) and the phage lambda-protein.