Growth and ultrastructure of Streptomyces venezuelae during chloramphenicol production.

Streptomyces venezuelae (3022a) was grown in flask cultures and fermentors, using three media having differential effects on chloramphenicol production. Micromorphology, ultrastructure and chloramphenicol concentrations were studied during the growth cycle in each medium. Chloramphenicol production was greatest in the glycerol-serine-lactate (GSL) medium, less in the glycerol-nutrient broth-yeast extract (GNY) medium and very low in glucose-mineral salts (GA) medium. In GSL and GA, much growth was in the form of microcolonies, especially in flask cultures, while short hyphal fragments predominated in GNY. The major ultrastructural features were the high frequency of mesosomes in fragmenting hyphae in GNY, and electron-transparent zones which appeared during chloramphenicol synthesis in GSL. None of the structural abnormalities induced by chloramphenicol in sensitive organisms were observed in S. venezuelae despite high levels of the antibiotic in GSL medium.     

Catabolite repression in Streptomyces venezuelae. Induction of beta-galactosidase, chloramphenicol production, and intracellular cyclic adenosine 3',5'-monophosphate concentrations

Chloramphenicol production was studied in cultures of Streptomyces venezuelae growing in a simple buffered medium with ammonia as the nitrogen source and glucose, lactose, or a glucose-lactose mixture as the sole source of carbon. With each carbon source the antibiotic was formed during growth. In the glucose-lactose medium, the production pattern was biphasic; a marked decrease in the rate of synthesis was associated with depletion of glucose from the medium and a corresponding diauxie pause in growth. Cells of S. venezuelae contained an inducible beta-galactosidase. Induction by lactose was suppressed by glucose. Measurement of the concentration of intracellular adenosine 3',5'-cyclic monophosphate during growth of cultures with glucose or a glucose-lactose mixture as the source of carbon showed no appreciable changes coinciding with depletion of glucose or the onset of chloramphenicol biosynthesis. It is concluded that the cyclic nucleotide does not mediate selective nutrient utilization or control antibiotic biosynthesis in this organism.     

Effect of ammonium on chloramphenicol production by Streptomyces venezuelae in batch and continuous cultures

Cultures of Streptomyces venezuelae presented with a mixture of ammonium and an amino acid as nitrogen sources used both compounds together. Absence of ammonium repression of alternative nitrogen assimilation pathways was also observed when ammonium was added to cultures already growing on proline. The presence of ammonium in the medium ab initio depressed the yield of chloramphenicol. However, its addition to a culture growing on proline caused only a temporary inhibition of antibiotic synthesis, even when sufficient ammonium was added to create an excess. Continuous cultures supplied with ammonium as the growth-limiting nutrient showed no significant change in specific antibiotic production at different specific growth rates. The overall results indicate that in S. venezuelae neither nitrogen utilization pathways nor chloramphenicol biosynthesis is controlled by nitrogen repression.     

Biochemistry and genetics of chloramphenicol production

In Streptomyces venezuelae, chloramphenicol is derived by an unusual diversion of chorismate, the branchpoint intermediate of the pathway involved in the biosynthesis of aromatic amino acids. In the chloramphenicol-producing organism, the DAHP synthetase was neither feedback inhibited nor repressed. Chorismate mutase was not repressed or inhibited by the intermediates or end-products of the shikimate-chorismate pathway. However, anthranilate synthetase and prephenate dehydratase are feedback inhibited by tryptophan and phenylalanine, respectively. During growth, when primary metabolism is not perfectly coordinated, decreasing demand for aromatic amino acids results in shunting of chorismate towards chloramphenicol biosynthesis.The endogenous synthesis of chloramphenicol produced by Streptomyces venezuelae is inhibited by the increasing concentration of chloramphenicol in the medium. Arylamine synthetase, the first enzyme involved in chloramphenicol biosynthesis, is repressed by the secreted chloramphenicol, by dl-p-aminophenylalanine and l-threo-p-aminophenylserinol. The excess intracellular chorismate pool is diverted to other aromatic shunt metabolites if biosynthesis of chloramphenicol is inhibited. There appears to be a glutamine binding protein subunit which is shared by several enzymes involved in amination of the aromatic ring of chorismate.Chloramphenicol producing organism also inactivated intracellular chloramphenicol. However, the resistance of the streptomycetes is due to inducible impermeability of the organism to chloramphenicol during antibiotic production. Streptomyces venezuelae is sensitive to chloramphenicol when it is not engaged in antibiotic production. The resistance to and production of chloramphenicol are induced simultaneously.A linkage map for 17 marker loci using Streptomyces venezuelae has been constructed. Restriction enzyme map of a plasmid from the chloramphenicol-producing streptomycetes has also been developed. The role of the plasmid in chloramphenicol biosynthesis and the life-cycle of the Streptomyces venezuelae is not yet understood.     

Role of the carbon source in regulating chloramphenicol production by Streptomyces venezuelae: studies in batch and continuous cultures

Both carbon- and nitrogen-limited media that supported a biphasic pattern of growth and chloramphenicol biosynthesis were devised for batch cultures of Streptomyces venezuelae. Where onset of the idiophase was associated with nitrogen depletion, a sharp peak of arylamine synthetase activity coincided with the onset of antibiotic production. The specific activity of the enzyme was highest when the carbon source in the medium was also near depletion at the trophophase-idiophase boundary. In media providing a substantial excess of carbon source through the idiophase, the peak specific activity was reduced by 75%, although the timing of enzyme synthesis was unaltered. Moreover, chemostat cultures in which the growth rate was limited by the glucose concentration in the input medium failed to show a decrease in specific production of chloramphenicol as the steady-state intracellular glucose concentration was increased. The results suggest that a form of "carbon catabolite repression" regulates synthesis of chloramphenicol biosynthetic enzymes during a trophophase-idiophase transition induced by nitrogen starvation. However, this regulatory mechanism does not establish the timing of antibiotic biosynthesis and does not function during nitrogen-sufficient growth in the presence of excess glucose.     

Glucose suppression of beta-glucosidase activity in a chloramphenicol-producing strain of Streptomyces venezuelae

beta-Glucosidase activity was induced in Streptomyces venezuelae during growth on cellobiose, gentiobiose, salicin, methyl beta-glucoside, and p-nitrophenyl beta-D-glucopyranoside. Activity in cell extracts was separated by DEAE-cellulose chromatography into two fractions differing in substrate preference. One component showed higher activity with, and was more strongly induced by, cellobiose; the other showed greater activity and inducibility with salicin. Addition of glucose to cultures severely depressed induction of beta-glucosidase activity by cellobiose but not by salicin. Acetate and several amino acids inhibited induction by either substrate. The action of glucose was not reversed by cyclic AMP. Cultures of S. venezuelae using glucose, cellobiose, or a mixture of the two saccharides as their carbon source produced chloramphenicol during growth. In contrast with its effect on the induction of cellobiose activity, glucose did not suppress chloramphenicol production, indicating that the control mechanisms that establish carbon source preferences are not linked to those that regulate antibiotic biosynthesis in this organism.     

Mechanisms of Proteus resistance to chloramphenicol]

Data on chloramphenicol sensitivity of clinical Proteus strains isolated within 1970--1975 and some mechanisms of their resistance to this antibiotic are presented. It was found that most of the Proteus strains (62.82 +/- 2.15 per cent) were resistant to chloramphenicol. 75 per cent of the isolates had resistance of transmissive character. Resistance of the Proteus cultures to chloramphenicol was not a stable feature and was lost during storage under laboratory conditions. Direct correlation between stability of the antibiotic resistance in the Proteus, the resistance level and the period of the culture storage was found. It was shown that the transmissive resistance to chloramphenicol in the Proteus cultures was due to synthesis of a highly active constituitive chloramphenicol-inactivating enzyme. Direct relation between the Proteus resistance level to chloramphenicol and the rate of the enzyme synthesis was noted. A number of the Proteus strains phenotypically sensitive to this antibiotic was capable of its inactivation. Still, the activity of the enzyme was low. The rate of the enzyme synthesis and the level of the acquired resistance in the chloramphenicol resistant mutants depended on the presence or absence of the enzyme in the cells of the initial sensitive strain. The capacity for chloramphenicol accumulation in a number of the chloramphenicol resistant mutants of the Proteus was decreased.     

Chloramphenicol resistance in Streptomyces: cloning and characterization of a chloramphenicol hydrolase gene from Streptomyces venezuelae

A 6.5 kb DNA fragment containing a chloramphenicol-resistance gene of Streptomyces venezuelae ISP5230 was cloned in Streptomyces lividans M252 using the high-copy-number plasmid vector pIJ702. The gene was located within a 2.4 kb KpnI-SstI fragment of the cloned DNA and encoded an enzyme (chloramphenicol hydrolase) that catalysed removal of the dichloroacetyl moiety from the antibiotic. The deacylated product, p-nitrophenylserinol, was metabolized to p-nitrobenzyl alcohol and other compounds by enzymes present in S. lividans M252. Examination of the genomic DNA from several sources using the cloned 6.5 kb SstI fragment from S. venezuelae ISP5230 as a probe showed a hybridizing region in the DNA from S. venezuelae 13s but none in the DNA from another chloramphenicol producer, Streptomyces phaeochromogenes NRRLB 3559. The resistance phenotype was not expressed when the 6.5 kb SstI fragment or a subfragment was subcloned behind the lac-promoter of plasmid pTZ18R in Escherichia coli.     

Comparative Study of the Events Associated with Colicin Induction

Colicinogenic factors ColI and ColV, which have been shown to behave as sex factors, could not be induced with mitomycin C. In contrast, the ColE(1), ColE(2), and ColE(3) factors, which do not exhibit any fertility factor characteristics, are inducible by this agent. The induced production of colicins E(1), E(2), and E(3) was accompanied by a loss in viability at a concentration of mitomycin C which was bacteriostatic to noncolicinogenic cells or to cells carrying the ColV or ColI factors. The loss in viability accompanying the mitomycin C induction of the ColE(1), ColE(2), or ColE(3) factors also occurred when colicin synthesis was blocked by chloramphenicol or amino acid starvation. However, chloramphenicol was able to block the loss of viability of a recipient cell after mitomycin C induction of a newly acquired Col factor if the antibiotic was present throughout the mating period. No detectable internal colicin or colicin precursor could be demonstrated during the lag period prior to the appearance of colicin outside the cell 20 to 30 min after the addition of mitomycin C. If chloramphenicol was present during the lag period following the addition of mitomycin C, colicin synthesis began immediately after the removal of these antibiotics. The synthesis of tryptophan synthetase and induced beta-galactosidase proceeded normally throughout the lag period and well into the period of colicin production. Regulation of beta-galactosidase synthesis did not seem to be profoundly affected during the lag period subsequent to mitomycin C addition. Induced colicin synthesis, like bacterial or induced prophage protein synthesis, was subject to inhibition by virulent phage infection.     

Action of heliomycin on protein and mucleic acid synthesis in Staphylococcus aureus]

Heliomycin inhibited synthesis of RNA in Staph. aureua which was clearly shown in the study of the antibiotic effect on RNA synthesis in the lag phase of the culture development: heliomycin markedly lowered the maximum RNA level in the biomass observed in the culture at the beginning of the exponential growth. On further growth of the culture heliomycin induced a significant retardness of the process of the natural decrease in the RNA biomass level resulting in increased content of RNA in the cells growing in the presence of heliomycin as compared to the control culture. Retarded natural decrease in the RNA biomass level in the presence of heliomycin was observed also on the antibiotic addition just at the beginning of the exponential growth, during the period of maximum RNA accumulation in the cells. Heliomycin had no effect on synthesis and biomass levels of DNA. Heliomycin inhibited the protein synthesis and was close to chloramphenicol by the level of inhibition of the summation protein synthesis in the biomass. However, comparison of the effect of the above antibiotics on synthesis of beta-galactosidase, an individual enzyme protein showed that heliomycin was much less active as an inhibitor of protein synthesis in comparison to chloramphenicol.     

Formation of the yeast mitochondrial membrane. 3. Accumulation of mitochondrial proteins synthesized in both the cytoplasm and mitochondria in yeast undergoing glucose depression

The inhibitors of protein synthesis, chloramphenicol and cycloheximide, were added to cultures of yeast undergoing glucose derepression at different times during the growth cycle. Both inhibitors blocked the increase in activity of coenzyme QH₂-cytochrome c reductase, suggesting that the formation of complex III of the respiratory chain requires products of both mitochondrial and cytoplasmic protein synthesis.The possibility that precursor proteins synthesized by either cytoplasmic or mitochondrial ribosomes may accumulate was investigated by the sequential addition of cycloheximide and chloramphenicol (or the reverse order) to cultures of yeast undergoing glucose derepression. When yeast cells were grown for 3 hr in medium containing cycloheximide and then transferred to medium containing chloramphenicol, the activity of cytochrome oxidase increased at the same rate as the control during the first hour in chloramphenicol. These results suggest that some accumulation of precursor proteins synthesized in the mitochondria had occurred when cytoplasmic protein synthesis was blocked during the growth phase in cycloheximide. In contrast, essentially no products of mitochondrial protein synthesis accumulated as precursors for either oligomycin-sensitive ATPase or complex III of the respiratory chain during growth of the cells in cycloheximide.When yeast were grown for 3 hr in medium containing chloramphenicol followed by 1 hr in cycloheximide, the activities of cytochrome oxidase and succinate-cytochrome c reductase increased at the same rate as the control, while the activities of oligomycin-sensitive ATPase and NADH or coenzyme QH₂-cytochrome c reductase were nearly double that of the control. These data suggest that a significant accumulation of mitochondrial proteins synthesized in the cytoplasm had occurred when the yeast cells were grown in medium containing sufficient chloramphenicol to block mitochondrial protein synthesis. The possibility that proteins synthesized in the cytoplasm may act to control the synthesis of mitochondrial proteins for both oligomycin-sensitive ATPase and complex III of the respiratory chain is discussed.     

Control of synthesis of mRNA''s for T4 bacteriophage-specific dihydrofolate reductase and deoxycytidylate hydroxymethylase.

A 30 degrees C, functional messengers for dCMP hydroxymethylase first appeared 3 to 6 min postinfection and reached their maximum levels at 12 min. Chloramphenicol, added before the phage, reduced the rate of mRNA accumulation. When the antibiotic was added 6 min postinfection, mRNA levels increased at their normal rate but there was no obvious repression of messenger accumulation. Delaying the addition of drug until 8 or 12 min had progressively less effect on the pattern of hydroxymethylase mRNA metabolism. When chloramphenicol was present from preinfection times or from 6 min postinfection, all hydroxymethylase mRNA's synthesized were stable; at later times, however, the ability of the drug to stabilize mRNA decreased with its ability to delay the turnoff of mRNA production. An overaccumulation of hydroxymethylase mRNA was also seen when phage-specific DNA synthesis was inhibited either by mutational lesion in an essential viral gene or by 5-fluorodeoxyuridine. By min 20 of a DNA-negative program, hydroxymethylase mRNA synthesis was repressed to the point where it no longer compensated for decay. However, a finite level of hydroxymethylase mRNA synthesis was maintained at later times of a DNA-negative infection. Such results indicate that replication of the phage chromosome is necessary but not sufficient for a complete turnoff of hydroxymethylase mRNA production. Functions controlled by the maturation-defective proteins (the products of genes 55 and 33) played only a minor role in the regulation of hydroxymethylase mRNA, metabolism. Thus, we favor the hypothesis that a complete turnoff of hydroxymethylase messenger production requires one or more new proteins as well as an interval of DNA replication. The absence of DNA synthesis had no particular effect upon dihydrofolate reductase messenger production. The preinfection addition of chloramphenicol likewise had little effect on dihydrofolate reductase messenger metabolism. These latter data imply that prior synthesis of a phage-coded protein synthesis may not be required for the turnoff of reductase messenger production.     

Emulsan production by Acinetobacter calcoaceticus in the presence of chloramphenicol.

When exponentially growing cultures of Acinetobacter calcoaceticus RAG-1 or RAG-92 were either treated with inhibitors of protein synthesis or starved for a required amino acid, there was a stimulation in the production of emulsan, an extracellular polyanionic emulsifier. Emulsan synthesis in the presence of chloramphenicol was dependent on utilizable sources of carbon and nitrogen and was inhibited by cyanide or azide or anaerobic conditions. Radioactive tracer experiments indicated that the enhanced production of emulsan after the addition of chloramphenicol was due to both the release of material synthesized before the addition of the antibiotic (40%) and de novo synthesis of the polymer (60%). Chemical analysis of RAG-1 cells demonstrated large amounts of polymeric amino sugars; it was estimated that cell-associated emulsan comprised about 15% of the dry weight of growing cells. The data are consistent with the hypothesis that a polymeric precursor of emulsan accumulates on the cell surface during the exponential growth phase; in the stationary phase or during inhibition of protein synthesis, the polymer is released as a potent emulsifier.     

Inhibition of existing denitrification enzyme activity by chloramphenicol.

Chloramphenicol completely inhibited the activity of existing denitrification enzymes in acetylene-block incubations with (i) sediments from a nitrate-contaminated aquifer and (ii) a continuous culture of denitrifying groundwater bacteria. Control flasks with no antibiotic produced significant amounts of nitrous oxide in the same time period. Amendment with chloramphenicol after nitrous oxide production had begun resulted in a significant decrease in the rate of nitrous oxide production. Chloramphenicol also decreased (greater than 50%) the activity of existing denitrification enzymes in pure cultures of Pseudomonas denitrificans that were harvested during log-phase growth and maintained for 2 weeks in a starvation medium lacking electron donor. Short-term time courses of nitrate consumption and nitrous oxide production in the presence of acetylene with P. denitrificans undergoing carbon starvation were performed under optimal conditions designed to mimic denitrification enzyme activity assays used with soils. Time courses were linear for both chloramphenicol and control flasks, and rate estimates for the two treatments were significantly different at the 95% confidence level. Complete or partial inhibition of existing enzyme activity is not consistent with the current understanding of the mode of action of chloramphenicol or current practice, in which the compound is frequently employed to inhibit de novo protein synthesis during the course of microbial activity assays. The results of this study demonstrate that chloramphenicol amendment can inhibit the activity of existing denitrification enzymes and suggest that caution is needed in the design and interpretation of denitrification activity assays in which chloramphenicol is used to prevent new protein synthesis.     

Inhibition of existing denitrification enzyme activity by chloramphenicol.

Chloramphenicol completely inhibited the activity of existing denitrification enzymes in acetylene-block incubations with (i) sediments from a nitrate-contaminated aquifer and (ii) a continuous culture of denitrifying groundwater bacteria. Control flasks with no antibiotic produced significant amounts of nitrous oxide in the same time period. Amendment with chloramphenicol after nitrous oxide production had begun resulted in a significant decrease in the rate of nitrous oxide production. Chloramphenicol also decreased (greater than 50%) the activity of existing denitrification enzymes in pure cultures of Pseudomonas denitrificans that were harvested during log-phase growth and maintained for 2 weeks in a starvation medium lacking electron donor. Short-term time courses of nitrate consumption and nitrous oxide production in the presence of acetylene with P. denitrificans undergoing carbon starvation were performed under optimal conditions designed to mimic denitrification enzyme activity assays used with soils. Time courses were linear for both chloramphenicol and control flasks, and rate estimates for the two treatments were significantly different at the 95% confidence level. Complete or partial inhibition of existing enzyme activity is not consistent with the current understanding of the mode of action of chloramphenicol or current practice, in which the compound is frequently employed to inhibit de novo protein synthesis during the course of microbial activity assays. The results of this study demonstrate that chloramphenicol amendment can inhibit the activity of existing denitrification enzymes and suggest that caution is needed in the design and interpretation of denitrification activity assays in which chloramphenicol is used to prevent new protein synthesis.     

Rifampicin and chloramphenicol effects on DNA replication in thymine-prestarved Escherichia coli B/r WP2 thy trp.

When cultures of Escherichia coli B/r WP2 thy trp were prestarved for thymine for 30 min, DNA replication after readdition of thymine was limited to an increase of about 100% in the presence of rifampicin, an antibiotic which inhibits DNA-dependent RNA polymerase. However, chloramphenicol, an antibiotic which blocks protein but not RNA synthesis, did not limit replication. After prolonged thymine prestarvation (55 min) DNA increased only about 50% in the presence of rifampicin, but no such limitation occurred in the presence of chloramphenicol. The ability of a high concentration of rifampicin to limit DNA replication was eliminated by addition of either high or low concentrations of chloramphenicol, indicating that stoichiometric interaction of the antibiotics is not responsible for this effect.     

Bacteriolytic effect of cessation of glucosamine supply, induced by specific inhibition of glucosamine-6-phosphate synthetase

The antibiotic tetaine (bacilysin) and its C-terminal epoxyaminoacid--anticapsin--are powerful inhibitors of glucosamine-6-phosphate synthetase (EC 5.3.1.19.) in cell-free extracts of Escherichia coli K-12. Tetaine acts on growing cells as a bactericidal agent. This bactericidal action, measured from 10 to 160 muM concentration, is a consequence of the induction of lysis of growing cells. The induction of lysis by tetaine is compared with the lytic action of some beta-lactams. Hypertonic medium, destruction of the antibiotic, presence of chloramphenicol or the addition of N-acetylglucosamine protect E. coli K-12 cells against lysis induced by tetaine. These effects are compared with those observed in the presence of penicillin G. The results indicate that inhibition of early or late stages of peptidoglycan synthesis all result in more or less the same consequence, i.e. death via cell lysis.     

The need for protein synthesis in UV-irradiated Escherichia coli cells for fixation of induced Str mutations

The kinetics of accumulation of fixed Str mutations was determined during incubation in nutritional medium of Escherichia coli WP2 irradiated with 6.8 J/m2 either at log growth phase or after completion of DNA replication. Those Str mutations which lost ability for photoreactivation (fixation I) or susceptibility to antimutagenic activity of mfd-type (fixation II) were considered as fixed mutations. It was shown that both fixations occurred synchronously, starting in about 10 min after irradiation and being over in 40-50 min. In cells irradiated after completion of replication, fixation depended on protein synthesis de novo: chloramphenicol added to irradiated culture blocked fixation. An attempt to study the effect of chloramphenicol on fixation in a culture irradiated at the log phase failed, because of high lethal action of the antibiotic on such cells. Fixation could proceed in the presence of acriflavine. Possible mechanisms for fixation of Str mutations are discussed in connection with the fact of its dependence on protein synthesis.     

A repressor-response regulator gene pair controlling jadomycin B production in Streptomyces venezuelae ISP5230.

A second regulatory gene (jadR(1)) is located immediately upstream of the putative repressor gene (jadR(2)) in the jad cluster for biosynthesis of the antibiotic jadomycin B in Streptomyces venezuelae ISP5230. It encodes a 234-amino acid polypeptide with a sequence resembling those of response regulator proteins in two-component control systems. Features in the conserved C-terminal domain of JadR(1) place the protein in the OmpR-PhoB subfamily of response regulators. In mutants where jadR(1) was deleted or disrupted, jadomycin B was not produced, implying that the gene has an essential role in biosynthesis of the antibiotic. Cloning jadR(1) from S. venezuelae in pJV73A, and introducing additional copies of the gene into the wild-type parent by plasmid transformation gave unstable strains with pJV73A integrated into the chromosome. The transformants initially showed increased production of jadomycin B but gave lower titers as excess copies of jadR(1) were lost; mature cultures stabilized with a wild-type level of antibiotic production. The mutant from which jadR(1) had been deleted could not be transformed with pJV73A. Altering the composition of jadR genes in the chromosome by integration of vectors carrying intact and disrupted copies of jadR(1) and jadR(2) provided evidence that the two genes form a regulatory pair different in function from previously reported two-component systems controlling antibiotic biosynthesis in streptomycetes.     

Requirement for Protein Synthesis in rec-Dependent Repair of Deoxyribonucleic Acid in Escherichia coli after Ultraviolet or X Irradiation

Deprivation of amino acids required for growth or treatment with chloramphenicol or puromycin after irradiation reduced the survival of Rec(+) cells of Escherichia coli K-12 which had been exposed to either ultraviolet (UV) or X radiation. In contrast, these treatments caused little or no reduction in the survival of irradiated recA or recB mutants. The effect of chloramphenicol on the survival of X-irradiated cells was correlated with an inhibition of repair of single-strand breaks in irradiated deoxyribonucleic acid (DNA), previously shown to be controlled by recA and recB. In UV-irradiated cells no effect of chloramphenicol was detected on the repair of single-strand discontinuities in DNA replicated from UV-damaged templates, a process controlled by recA but not by recB. From this we concluded that inhibiting protein synthesis in UV or X-irradiated cells may interfere with some biochemical step in repair dependent upon the recB gene. When irradiated Rec(+) cells were cultured for a sufficient period of time in minimal growth medium before chloramphenicol treatment their survival was no longer decreased by the drug. After X irradiation this occurred in less than one generation time of the unirradiated control cells. After UV irradiation it occurred more slowly and was only complete after several generation times of the unirradiated controls. These observations indicated that replication of the entire irradiated genome was probably not required for rec-dependent repair of X-irradiated cells, although it might be required for rec-dependent repair of UV-irradiated cells.