PHOTODYNAMIC AND SUNLIGHT INACTIVATION OF ESCHERICHIA COLI STRAINS DIFFERING IN NEAR-UV SENSITIVITY AND RECOMBINATION PROFICIENCY

Abstract— Stationary cells of four Escherichia coli strains exhibiting all four possible combinations of genes controlling near-UV sensitivity ( nur vs nur ⁺) and recombination proficiency (far-UV sensitivity; recA1 us recA ⁺) have been inactivated by visible light in the presence of acridine orange (AO, 10µg/m l ) and sunlight. The results demonstrate that strains sensitive to near-UV inactivation are also sensitive to inactivation by visible light in the presence of AO and sunlight irrespective of the recA allele carried by the strain. These results may be interpreted to mean that major mechanisms of inactivation of stationary E. coli cells by near-UV, visible light in the presence of AO and sunlight are similar and not closely related to the mechanism of inactivation by far-UV.     

GENETIC CONTROL OF NEAR-UV (300–400nm) SENSITIVITY INDEPENDENT OF THE recA GENE IN STRAINS OF ESCHERICHIA COLI K12

Abstract— Stationary cells of isogenic pairs of Escherichia coli K12 strains presumably differing only in the recA function have been inactivated with near-UV (300–400 nm) radiation. Based on near-UV inactivation kinetics, the strains can be divided into two discrete categories in which near-UV sensitivity does not necessarily correlate with far-UV sensitivity conferred by two different recA alleles. Lack of overlap between near-UV and far-UV ( recA ) sensitivity can be explained hy assuming that a different chromosomal gene ( nur ) controls near-UV sensitivity. Support for this hypothesis comes from a mating experiment in which four selected recombinants, isogenic with respect to auxotrophic markers, were identified exhibiting all four possible combinations of far-UV ( recA 1 vs recA ⁺ ) and near-UV sensitivity ( nur vs nur⁺ ). Transduction with phase P1 has shown that introduction of the recA 1 allele into a recA⁺ recipient does not affect the near-UV sensitivity of the recipient. Additional matings together with transduction experiments suggest that the nur gene is located at a position on the E. coli linkage map clearly separable from recA (minute 58).     

DIFFERENTIAL SENSITIVITY TO INACTIVATION OF NUR AND NUR+ STRAINS OF ESCHERICHIA COLI AT SIX SELECTED WAVELENGTHS IN THE UVA,UVB AND UVC RANGES*

The radiation response of stationary-phase cells of Escherichia coli strains RT4 (nur⁺) and RT2 (nur) was measured at 6 selected wavelengths between 254 and 405 ran. The relative response of the nur⁺. and nur strains was almost the same at 254 and 290 nm. However, the differential sensitivity of the RT4 and RT2 strains (ratio of the initial F₃₇ values of the nur⁺ to the nur strains) was 2.7 at 313 nm, 3.2 at 334 nm, 3.1 at 365 nm, and 2.3 at 405 nm. Thus, the fluence enhancing effect of the nur genotype extends over the wavelength range of approximately 300 to 420 nm. The substantial effect of nur at 313 nm strongly suggests that the increased sensitivity of the nur strain is the consequence of a repair deficiency that reduces the efficiency of mending DNA lesions produced by UVA (320–400 nm) and UVB (290–320 nm), but not UVC (200–290 nm) radiation.     

THE INTERACTION OF A GENE (nur) CONTROLLING NEAR-UV SENSITIVITY AND THE polA1 GENE IN STRAINS OF E. COLI K12

Abstract— When stationary cell populations of the Escherichia coli W3110 strain and the polA1 mutant (p3478) derived directly from it were compared for their sensitivity to near-UV (NUV, 300–400 nm) inactivation, the polA1 strain proved to be more sensitive. By appropriate matings and transductions, four essentially isogenic strains have been developed which carry all four possible combinations of genes conferring far-UV (FUV, 200-300 nm) sensitivity ( polA1 vs. polA ⁺) and NUV sensitivity ( nur vs. nur ⁺). Stationary cells of strains carrying either the polA1 or polA ⁺ allele in combination with the nur allele are indistinguishable in their sensitivity to NUV inactivation and are equivalent in their NUV sensitivity to the original polA1 mutant strain (p3478). With the two strains carrying the nur ⁺ allele, stationary cell populations of the polA1 strain are clearly more sensitive to NUV inactivation than is the polA ⁺ strain. The NUV sensitizing effect of the polA1 mutation in a nur ⁺ genetic background is about the same as that of the nur mutation at the 0.37 survival level. This may mean that the polA1 and nur mutations sensitize E. coli stationary cell populations to NUV inactivation by a common mechanism.     

THE EXPRESSION OF LIQUID HOLDING RECOVERY IN ULTRAVIOLET-IRRADIATED ESCHERICHIA COLI REQUIRES A DEFICIENCY IN GROWTH MEDIUM-DEPENDENT DNA REPAIR

Ultraviolet (UV) irradiated Escherichia coli K-12 recA cells (but not rec⁺ cells) show enhanced survival if they are held in buffer prior to plating for viability. To understand the role of the recA mutation in this liquid holding recovery (LHR) phenomenon, we have studied LHR in a temperature sensitive recA 200 mutant. The detection of LHR requires that the irradiated cells be recA when they are plated on growth medium, but the recA deficiency plays no role during liquid holding (LH). We conclude that it is the extreme sensitivity of recA cells in growth medium to unrepaired DNA daughter-strand gaps that magnifies the beneficial effects of the excision repair of DNA lesions during LH. Furthermore, we demonstrate a correlation between a strain's inability to perform growth medium dependent repair and its ability to express LHR. The relative amount of LHR was: recA > recF > lexA > recB > wild type (with the recB and wild-type strains showing negative LHR). Two strains did not show this correlation; the uvrD strain showed less LHR than expected from its UV radiation sensitivity, while the polA strain showed more. The molecular bases for these exceptions are explored.     

ACTION SPECTRA FOR LETHALITY IN RECOMBINATION-LESS STRAINS OF SALMONELLA TYPHIMURIUM AND ESCHERICHIA COLI*

Abstract— Action spectra for lethality of both stationary and exponentially growing cells of recombinationless (recA) mutants of Salmonella typhimurium and Escherichia coli were obtained. Maximum sensitivity was observed at 260nm which corresponds to the maximum absorbance of DNA. However, a shoulder occurred in the 280–300 nm range that departed significantly from the absorption spectrum of DNA. At wavelengths longer than 320nm, the shapes of inactivation curves departed significantly from those at wavelengths shorter than 320nm and survival curves at wavelengths longer than 320nm had a large shoulder. A small peak or shoulder occurred in the 330–340nm region of the action spectra. The special sensitivity of recA mutants to broad spectrum near-UV radiation may be due to synergistic effects of different wavelengths. Parallels between the inactivation of recA mutants and the induction of a photoproduct of l -tryptophan toxic for recA mutants (now known to be H₂O₂) suggest that H₂O₂ photoproduct from endogenous tryptophan may be involved in the high sensitivity of these strains to broad spectrum near-UV radiation.     

The roles of the rel+ gene and of 4-thiouridine in killing and photoprotection of Escherichia coli by near-ultraviolet radiation

Abstract— Photoprotection is a reduction in response to far-UV (190–300. nm) radiation in cells that have been previously exposed to longer wavelengths. It has been proposed that photoprotection operates by means of a growth delay that permits more time for dark repair. Growth delay in Escherichia coli utilizes 4-thiouridine (⁴Srd) in transfer RNA as a chromophore and it requires the rel⁺ gene, which exerts a stringent control upon RNA synthesis. Mutants that were either rel or ⁴Srd^? were isolated from E. coli B, utilizing a near-UV-induced growth-delay selection technique. The rel mutants, which undergo little growth delay after near-UV irradiation, show only 50% as much photoprotection as wild types, while ⁴Srd^? mutants show no photoprotection at all. Thus, photoprotection appears to utilize ⁴Srd as its sole chromophore in E. coli B and B/r, and no more than 50% of photoprotection in these strains can be a result of near-UV-induced growth delay.     

Inactivation by Pulsed Light of Bacillus subtilis Spores with Impaired Protection Factors

The resistance to pulsed light (PL) of spores of Bacillus subtilis strain 168 and of strains with mutations increasing sensitivity to UV‐C or affecting spore structure was evaluated and compared to resistance to continuous UV‐C and moist heat, in order to reveal original mechanisms of inactivation by PL. Spores of B. subtilis strain 168 (1A1) and eight mutant strains (sspA, sspB, sspAB, cotA, gerE, cotE, uvrA and recA) were exposed to PL (up to 1.77 J cm^?2), continuous UV‐C (up to 147 mJ cm^?2) and moist heat at 90°C. Spores of the strains lacking proteins linked to coat formation or structure (cotA, gerE and cotE) were markedly more sensitive to PL than 1A1, while their sensitivity to continuous UV‐C or to moist heat was similar to the one of strain 1A1. Coat proteins had a major contribution to the resistance of B. subtilis spores to PL irradiation characterized by short‐time and high‐energy pulses of white light in the wavelengths 200–1100 nm. In contrast the role of coat proteins to UV‐C or to moist heat resistance was marginal or null.     

Degradation of the DNA of recA mutants of Escherichia coli K-12 after irradiation with ultraviolet light. II. Further studies including a recA uvrA double mutant

Abstract— The u.v.-induced degradation of the DNA of the recA1 mutant of Escherichia coli K-12 has been further investigated. The extensive degradation was mostly prevented by an additional mutation in the uvrA gene. Furthermore, when amino acid-starved recA bacteria were irradiated and held under a condition preventing DNA replication, the DNA was degraded very little. The mode of u.v.-induced DNA degradation was investigated by comparing the time course of release of label from the acid-insoluble fraction of two growing cultures of a recA uvrA double mutant; the one was pulse-labeled with ³H-thymidine and the other was pulse-labeled and chased thereafter for 12 min. It was found that, in spite of very little degradation of the bulk of DNA. the label incorporated into the former culture was lost rapidly from the acid-insoluble fraction. while the label incorporated into the latter culture was not. It was concluded. therefore. that breakdown of the replicating point is characteristic of recA mutants and that degradation of the bulk of DNA is induced in some way by the function of the uvrA gene. Therefore, the degradation of the major part of DNA which follows the degradation of the replicating point appears to be a secondary phenomenon.     

SENSITIVITY OF STRAINS OF ESCHERICHIA COLI DIFFERING IN REPAIR CAPABILITY TO FAR UV,NEAR UV AND VISIBLE RADIATIONS*

Abstract— In stationary phase, strains of Escherichia coli deficient in excision (B/r Her) or recombination repair (K.12 AB2463) were more sensitive than a repair proficient strain (B/r) to monochromatic near-ultraviolet (365 nm) and visible (460 nm) radiations. The relative increase in sensitivity of mutants deficient in excision or recombination repair, in comparision to the wildtype, was less at 365 nm than at 254 nm. However, a strain deficient in both excision and recombination repair (K12 AB2480) showed a large, almost equal, increase in sensitivity over mutants deficient in either excision or recombination repair at 365 nm and 254 nm. All strains tested were highly resistant to 650 nm radiation. Action spectra for lethality of strains B/r and B/r Her in stationary phase reveal small peaks or shoulders in the 330–340, 400–410 and 490–510 nm wavelength ranges. The presence of 5μg/ml acriflavine (an inhibitor of repair) in the plating medium greatly increased the sensitivity of strain B/r to radiation at 254, 365 and 460 nm, while strains E. coli B/r Her and K12 AB2463 were sensitized by small amounts. At each of the wavelengths tested, acriflavine in the plating medium had at most a small effect on E. coli K.12 AB2480. Acriflavine failed to sensitize any strain tested at 650 nm. Evidence supports the interpretation that lesions induced in DNA by 365 nm and 460 nm radiations play the major role in the inactivation of E. coli by these wavelengths. Single-strand breaks (or alkali-labile bonds), but not pyrimidine dimers are candidates for the lethal DNA lesions in uvrA and repair proficient strains. At high fluences lethality may be enhanced by damage to the excision and recombination repair systems.     

THE PHOTOTOXICITY OF PHENYLHEPTATRIYNE: OXYGEN-DEPENDENT HEMOLYSIS OF HUMAN ERYTHROCYTES AND INACTIVATION OF Escherichia coli

Abstract— Phenylheptatriyne (PHT) plus near-ultraviolet light(320–400 nm; NUV) hemolyzed human erythrocytes in an oxygen dependent manner. When the phototoxicity of PHT plus NUV was tested with a series of Escherichia coli strains carrying all four possible combinations of genes controlling excision proficiency ( uvrA6 vs uvrA ⁺) and catalase activity (HPII, katF vs katF *), the membrane was found to be an important lethal target. Consistent with this observation. PHT plus NUV did not induce histidine independent ( his-4 ⁺) mutations in the four tester strains (RT7h-RT10h). Using tester strain RT10h, it was shown that there was no inactivation by PHT plus NUV in nitrogen. Results of experiments with an E. coli fatty acid auxotroph (K1060) treated with PHT plus NUV are also consistent with membrane proteins being the chief targets for attack. Radicals were formed during the photolysis of PHT plus NUV in aqueous solutions, both in the presence of air and under nitrogen. Since PHT plus NUV did not hemolyze erythrocytes or inactivate E. coli cells under nitrogen, these radicals are not cytotoxic.     

SENSITIVITY OF HemA MUTANT Escherichia coli CELLS TO INACTIVATION BY NEAR-UV LIGHT DEPENDS ON THE LEVEL OF SUPPLEMENTATION WITH δ-AMINOLEVULINIC ACID

Abstract— Four strains carrying all four possible combinations of the alleles nur, nur⁺, uvr A6 and uvr A ⁺ were transduced to hemA8 . The hemA8 mutation blocks the synthesis of δ-aminolevulinic acid (δ-ALA), one of the first steps in the synthesis of porphyrin and, ultimately, cytochromes essential for aerobic respiration. The cells were grown either with or without δ-ALA and treated with broad-spectrum near-ultraviolet light (NUV; 300–400 nm). hemA8 defective cells grown without δ-ALA were resistant to inactivation by NUV while hemA8 cells were sensitive to such inactivation when supplemented with δ-ALA. The sensitivity to NUV inactivation conferred by the nur gene was retained in the hemA8 derivatives. The sensitivity of such cells to NUV inactivation can be controlled by varying the level of δ-ALA supplementation. The level of δ-ALA supplementation did not influence the sensitivity of the cells to inactivation by far-UV light (FUV; 200–300 nm). The near-UV sensitivity of hemA⁺ cells was not significantly altered when grown with δ-ALA suppiementation suggesting that endogenously formed δ-ALA supports the normal, regulated level of porphyrin synthesis. These results can be interpreted to mean that porphyrin components of the respiratory chain in E. coli represent chromophores involved specifically in broad-spectrum NUV inactivating events.     

THE EFFECTS OF LIQUID HOLDING ON NEAR-UV(300–400 nm) IRRADIATED ESCHERICHIA COLI STRAINS DIFFERING IN NEAR AND FAR-UV RADIATION SENSITIVITY

Abstract— Stationary phase cells from four Escherichia coli strains differing in near- (nur vs. nur ₊) and far-UV (recAl vs. recA₊) radiation sensitivity were subjected to near-UV radiation (NUV) in 0.85% saline. Although the NUV-irradiated cultures yielded increased colony numbers following 24 h of liquid holding (LH), a fluctuation test for each experiment showed that the observed increases were not due to recovery but were in fact due to cell multiplication. The decline in viability observed after NUV with liquid holding using the fluctuation test was equivalent in strains RT2, 3 and 4 while the decline observed with RT1 was less marked. The discrepancy between LH involving cell densities of 10₈-10₉ and 1–4 cells/m/ can be resolved by assuming that with dense cell suspensions, NUV-induced membrane damage leads to leakage or lysis, supplying sufficient nutrients to allow growth of undamaged, surviving cells.     

REPAIR OF NEAR (365 nm)- AND FAR (254 nm)-UV DAMAGE TO BACTERIOPHAGE OF ESCHERICHIA COLI

Abstract: Intact bacteriophage have been irradiated at 365 nm or at 254 nm and then analysed for DNA photoproducts or injected into their bacterial host to test susceptibility of the damage to both phage and host-cell mediated repair systems. Both thymine dimers and single-strand breaks are induced in the phage DNA by 365 nm radiation. The dimers appear to be the major lethal lesion (approximately 2 dimers per lethal event) in both repair deficient bacteriophage T4 and bacteriophage λ. after irradiation with either 254 nm or 365 nm radiation. Damage induced in T4 by either wavelength is equally susceptible to x -gene reactivation (repair sector approximately 0.5). v -gene reactivation acts on a larger fraction of the near-UV damage (repair sector of 0.82 at 365 nm as against 0.66 at 254 nm). The host-cell mediated photoreactivation system is only slightly less effective for near-UV damage but host-cell reactivation (as measured by comparing survival of phage λ. on a uvr⁺ and a uvr^- host) is effective against a far smaller sector of near-UV damage (0.35) than far-UV damage (0.85). Weigle-reactivation (far-UV induced) of near-UV damage to phage λ is not observed. The results suggest that unless the near-UV damaged phage DNA is repaired immediately after injection. the lesions rapidly lose their susceptibility to repair with a consequent loss of activity of the phage particles.     

EFFECTS OF ACRIDINE PLUS NEAR ULTRAVIOLET LIGHT ON ESCHERICHIA COLI MEMBRANES AND DNA IN VIVO

Results from a variety of experiments indicate that photodynamic damage to E. coli treated with the hydrophobic photosensitizer acridine plus near-UV light involves both cell membranes and DNA. Split-dose survival experiments with various E. coli mutants reveal that cells defective in rec A, uvr A, or pol A functions are all capable of recovery from photodynamic damage. Alkaline sucrose gradient analysis of DNA from control and treated cells revealed that acridine plus near-UV light treatment converts normal DNA into a more slowly sedimenting form. However, the normal DNA sedimentation properties are not restored under conditions where split-dose recovery is effective. Several lines of evidence suggest that membrane damage may be important in the inactivation of cells by acridine plus near-UV light. These include (a) a strong dependence of sensitivity on the fatty acid composition of the membranes; (b) a strong dependence of sensitivity on the osmolarity of the external medium; and (c) the extreme sensitivity of an E. coli mutant having a defect in its outer membrane barrier properties. Direct evidence that acridine plus near-UV light damages cell membranes was provided by the observations that (a) the plasma membrane becomes permeable to o-nitrophenyl-ß-D-galactopyranoside and (b) the outer membrane becomes permeable to lysozyme after treatment. A notable result was that cells previously sensitized to lysozyme by exposure to acridine plus near-UV light lose that sensitivity upon subsequent incubation. This strongly suggests that E. coli cells are capable of repairing damage localized in the outer membrane.     

Multiple pathways of DNA repair in bacteria and their roles in mutagenesis.

Abstract— In bacteria, three processes of DNA repair are known: photoreactivation, excision repair, and postreplication repair. Photoreactivation, the enzymatic splitting of cyclobutyl pyrimidine dimers in situ, is mediated by exposure of the enzyme-dimer complex to near-UV and visible light. This repair process appears to be error free. The excision repair of UV-induced DNA base damage has been divided into two major pathways on the basis of both physiological requirements and genetic control. The major pathway requires a functional pol A gene, does not require complete growth medium. and appears to be largely error-free and to produce short patches during repair. The second pathway requires complete growth medium and functional recA, recB, recC, lexA, uvrD, and polC genes, and appears to be mutagenic and to produce long patches during repair. There exists a second type of excision repair in which the modified base is removed by an N-glycosidase, and the chain is then nicked by an apurinic (apyrimidinic) acid endonuclease. Subsequent events are presumed to be similar to the above excision repair process. The postreplication repair system has been divided into at least four separate pathways. Three of these are dependent upon functional recB, lexA, and uvrD genes, respectively, and appear to be error free. A fourth pathway depends upon the above gene products, but is blocked by postirradiation treatment with chloramphenicol, and may be the UV-inducible, errorprone, mutagenic pathway of repair (“SOS repair”). A possible fifth pathway depends upon a functional recF gene, and is independent of the recB⁺-dependent pathway. Mutagenesis appears to be the result of error-prone DNA repair, and there is growing evidence that carcinogenesis is also the result of error-prone DNA repair.     

FLUENCE-RATE DEPENDENCE OF MONOPHOTONIC REACTIONS OF NUCLEIC ACIDS IN VITRO AND IN VIVO

The Bunsen-Roscoe law, also known as the reciprocity law ( E = f(F) with F = I t ) has only limited validity for monophotonic reactions of nucleic acids. Especially at low fluence rates, the extent of in vitro and in vivo photoreactions of nucleic acids in the far-UV and near-UV range is a function of the fluence and of the fluence rate ( E = f (F;I)). In vitro experiments with poly(dA)poly(dT) clearly show that the far-UV (254 nm) response, indicated by the changes of the ellipticity at 315 nm, does not obey the Bunsen-Roscoe law at low fluence rates in the range between 1 W m^-2 and 20 W m^-2. In vivo experiments with Escherichia coli revealed very similar anomalies. Studying the growth delay after irradiation with far-UV light at 280 nm or near-UV light at 334 nm, we have confirmed the lack of reciprocity in both spectral ranges. The failure of the Bunsen-Roscoe law for the 280 nm and 334 nm UV irradiation effect at low fluence rates was in the range O < I < 40 W m^-2. In both cases reciprocity occurred at higher fluence rates (40 < I < 100 W m^-2).     

REDUCED NEAR-UV SENSITIVITY IN Phycomyces MUTANTS AFFECTED IN THE BIOSYNTHESIS OF 6,7-DIMETHYL-8-RIBITYLLUMAZINE

Riboflavin-requiring mutants of Phycomyces blakesleeanus with defects in the genes ribA, ribB, ribC and ribD were analyzed with respect to their contents of flavins, 6,7-dimethyl-8-ribityllu-mazine (DMRL) and pterins as well as their phototropic sensitivity. Strains were grown on minimal medium enriched with 10^?6M riboflavin (RB), and the concentrations of the respective pigments in sporangiophores were determined by HPLC. In strains A607 ribC401 and A641 ribC402 madA7 a loss of DMRL correlated with a loss of near-UV sensitivity. In general terms, the results suggest the participation of DMRL in photoreception, which does not necessarily imply DMRL as a photoreceptor chromophore. In more specific terms, the result could be understood on the basis of a UV/blue-light photoreceptor, which includes besides a flavin also a lumazine-like chromophore. Mutants C318 ribA I and C323 ribA4 accumulated DMRL, the immediate precursor of RB, as well as biopterin and neopterin. Mutant C322 ribB contained normal amounts of DMRL and pterins. Mutant C324 ribD5 had reduced amounts of neopterin and biopterin. The fact that some of the RB-requiring mutants displayed abnormal amounts of pterins indicates a common regulation for the flavin and the pterin pathway.     

Adaptive Evolution of <Emphasis Type="Italic">Escherichia coli</Emphasis> Inactivated in the Phosphotransferase System Operon Improves Co-utilization of Xylose and Glucose Under Anaerobic Conditions

Modification of the phosphoenolpyruvate/sugar phosphotransferase system (PTS) has shown improvement in sugar coassimilation in Escherichia coli production strains. However, in preliminary experiments under anaerobic conditions, E. coli strains with an inactive PTS and carrying pLOI1594, which encodes pyruvate decarboxylase and alcohol dehydrogenase from Zymomonas mobilis, were unable to grow. These PTS⁻ strains were previously evolved under aerobic conditions to grow rapidly in glucose (PTS^- Glucose⁺ phenotype). Thus, in this work, applying a continuous culture strategy under anaerobic conditions, we generate a new set of evolved PTS⁻ Glucose⁺ mutants, VH30N1 to VH30N6. Contrary to aerobically evolved mutants, strains VH30N2 and VH30N4 carrying pLOI1594 grew in anaerobiosis; also, their growth capacity was restored in a 100%, showing specific growth rates (μ ~ 0.12 h⁻¹) similar to the PTS⁺ parental strain (μ = 0.11 h⁻¹). In cultures of VH30N2/pLOI1594 and VH30N4/pLOI1594 using a glucose–xylose mixture, xylose was totally consumed and consumption of sugars occurred in a simultaneous manner indicating that catabolic repression is alleviated in these strains. Also, the efficient sugar coassimilation by the evolved strains caused an increment in the ethanol yields.     

Role of Fapy Glycosylase and UvrABC Excinuclease in the Repair of UVA (320-400 nm)-mediated DNA Damage in Escherichia coli

Abstract— In contrast to the damage caused by far-UV, the damage caused by UVA (320-400 nm) is largely oxygen dependent, suggesting near-UV-mediated DNA damage involves reactive oxygen species. The DNA repair enzymes that recognize oxidized bases may, therefore, be an important part of the cell's near-UV defense repertoire. To evaluate the relative importance of Fpg (Fapy) glycosylase (an enzyme known to remove oxidized bases) and the DNA damage-inducible UvrABC excinuclease in recovery from near-UV-induced stress, we have constructed, fpg and uvrA derivatives of Escherichia coli and tested the response (survival) of these strains to both UVA and far-UV radiation. Relative to control strains, the fpg^- derivatives were found to be consistently more sensitive to the lethal effects of UVA, but not far-UV radiation. In contrast, uvrA mutants were more sensitive than control strains to both UVA and far-UV radiation. Thymine dimers, known to be produced by far-UV and corrected by UvrABC, were not generated by the UVA fluences used in this study, suggesting that some other UVA-induced lesion(s) is recognized and repaired by this excinuclease.