Temperature-sensitive initiation of DNA replication in a mutant of Escherichia coli K12

Summary A mutant of E. coli K12 appears to be temperature-sensitive in the process of initiation of DNA replication. After a temperature shift from 33 to 42°C, the amount of residual DNA synthesis (Fig. 1) and the number of residual cell divisions (Figs. 2,4) indicate that rounds of DNA replication in process are completed, but new rounds cannot be initiated. Following the alignment of chromosomal DNA by amino acid starvation at 33° C no residual DNA synthesis at 42°C takes place (Fig. 5). When the temperature is lowered to 33°C after a period of inhibition at 42°C, the following observations are made: 1. DNA replication resumes and proceeds synchroneously, (Figs. 7, 8a), 2. cells start to divide again only after a lag period of about 1 hour 3. a temporary increase in cell volume is correlated with the frequency of initiation of DNA synthesis (Fig. 8a, b). In a lysogenic mutant strain prophage is inducible; with all bacteriophages tested, replication of phage DNA is not inhibited at 42°C.     

The fate of newly made DNA in Escherichia coli mutants thermosensitive in DNA synthesis

Summary E. coli mutants exist in which DNA synthesis is thermosensitive. In one class of these mutants DNA synthesis stops immediately if a critical temperature (42°C) is reached. When DNA replication in such mutants is followed by ³H thymidine incorporation at 33°C, it is found that 1. only the newly made DNA is degraded at 42°C, 2. the discontinuously replicated DNA is lost predominantly at 42°C, 3. 1–3% of the chromosomal DNA is rendered acid soluble at 42°C without concomitant loss of viability of the cells at 33°C.Replication of phage DNA is inhibited in the same mutant at 42°C. However, when DNA synthesis is followed in infected cells at 33°C it is found that 1. no degradation of specific DNA seems to occur at 42°C in the early phase of infection, 2. replicating DNA molecules in the late phase of infection are completed at 42°C before DNA synthesis comes to a halt.     

Induction of protein X in Escherichia coli.

Summary Certain treatments that damage DNA and/or inhibit replication in E. coli have been reported to induce synthesis of a new protein, termed protein X, in recA ⁺ lexA ⁺ strains. We have examined some of the treatments that might induce protein X and we have, in particular, tested the hypothesis of Gudas and Pardee (1975) that DNA degradation products play an essential role in the induction process.We confirmed that UV irradiation, nalidixic acid treatment, or thymine starvation result in protein X synthesis in wild type strains. However, we found that UV irradiation, unlike nalidixic acid, also induced protein X in recB strains, in which little DNA degradation occurs. Furthermore, we found that the presence of DNA fragments resulting from host-controlled restriction of phage DNA did not affect protein X synthesis. We conclude that no causal relationship exists between the production of DNA fragments and induction of protein X.The presence of the plasmid R46, which confers enhanced mutagenesis and UV resistance on its host, did not affect protein X synthesis. Growth in the presence of 5-bromouracil, which does not result in production of degradation fragments, resulted eventually in a low rate of protein X synthesis. In dnaA mutants, deficient in the initiation of new rounds of replication, UV irradiation induced protein X, again unlike nalidixic acid. Thus, the inhibition of active replication forks is not an essential requirement for protein X induction.     

Ultraviolet mutagenesis and inducible DNA repair in Caulobacter crescentus

Summary The ability to reactivate ultraviolet (UV) damaged phage CbK (W-reactivation) is induced by UV irradiation of Caulobacter crescentus cells. Induction of W-reactivation potential is specific for phage CbK, requires protein synthesis, and is greatly reduced in the presence of the rec-526 mutation. The induction signal generated by UV irradiation is transient, lasting about 1 1/2–2 h at 30°C; if chloramphenicol is present during early times after UV irradiation, induction of W-reactivation does not occur. Induction is maximal when cells are exposed to 5–10 J/m² of UV, a dose that also results in considerable mutagenesis of the cells. Taken together, these observations demonstrate the existence of a UV inducible, protein synthesis requiring, transiently signalled, rec-requiring DNA repair system analogous to W-reactivation in Escherichia coli. In addition, C. crescentus also has an efficient photoreactivation system that reverses UV damage in the presence of strong visible light.     

Radiation sensitivity of a mutant of Escherichia coli K-12 associated with DNA replication: Evidence for a new repair function

Summary The isolation and properties of a new radiation sensitive mutant of Escherichia coli K-12 are described which shows a correlation between radiation sensitivity and replication of irradiated DNA. The mutation, called rer, is located between argB and purD loci. The mutant, when grown in tryptone broth after irradiation, is sensitive to UV and -rays and incorporates little or no ³H-thymidine but in minimal glucose-salts medium both the radiation sensitivity and incorporation of ³H-thymidine remain identical to that of the parent strain. Studies with a temperature sensitive double mutant rer dnaC show that 1 hr incubation of irradiated cells at 42° C before their transfer to 30° C results in higher survival as compared to their incubation at 30° C only. It is suggested that rer controls the replication of irradiated DNA and thus regulates the coordination between replication and repair of DNA.     

Role of DNA replication in the induction and turn-off of the SOS response in Escherichia coli

Summary We have studied the role of DNA replication in turnon and turn-off of the SOS response in Escherichia coli using a recA::lac fusion to measure levels of recA expression.An active replication fork does not seem to be necessary for mitomycin C induced recA expression: a dnaA43 initiation defective mutant, which does not induce the SOS response at non-permissive temperature, remains mitomycin C inducible after the period of residual DNA synthesis. This induction seems to be dnaC dependent since in a dnaC325 mutant recA expression not only is not induced at 42° C but becomes mitomycin C non-inducible after the period of residual synthesis.Unscheduled halts in DNA replication, generally considered the primary inducing event, are not sufficient to induce the SOS response: no increase in recA expression was observed in dnaG(Ts) mutants cultivated at non-permissive temperature. The replication fork is nonetheless involved in induction, as seen by the increased spontaneous level of recA expression in these strains at permissive temperature.Turn-off of SOS functions can be extremely rapid: induction of recA expression by thymine starvation is reversed within 10 min after restoration of normal DNA replication. We conclude that the factors involved in induction-activated RecA (protease) and the activating molecule (effector)-do not persist in the presence of normal DNA replication.Abbreviations Ts thermosensitive - SDS sodium dodecyl sulfate - Ap ampicillin - UV ultraviolet - X-Gal 5-bromo-4-chloro-3-indolyl--D-galactoside     

Mating due to loss of surface exclusion as a cause for thermosensitive growth of bacteria containing the Rtsl plasmid

Summary At 25° C, Rtsl⁺ bacteria grow to about 5x10⁹ bacterial/ml before leveling off, whereas at 42° C they grow from 2.6x10⁸ bacteria/ml for only 2.3 generations after temperature shift before the growth is inhibited with a zig-zag pattern at the plateau. When diluted, Rtsl⁺ bacteria grow rapidly at 42° C, until the concentration reaches as high as the undiluted 42° C culture when growth measured by colony counts stops and the zig-zag pattern again appears. This density-dependent growth inhibition is not due to the presence of stable growth inhibitor(s). Mating experiments show that at 42° C, Rtsl⁺ bacteria retain good donor ability; at the same time, they become good recipients in mating with Hfr (Rtsl) bacteria. SDS-PAGE reveals that membranes are altered at 42° C. Examination of DNA synthesis indicates that chromosomal DNA is synthesized at both 25° C and 42° C at high bacterial concentration, but that of the Rtsl plasmid is slowed down at 42° C. The labeling experiments suggest that in 2 h there are 2 rounds of plasmid replication at 25° C, 3.5 rounds at 42° C when bacteria are diluted, and 0.6 rounds at 42° C when bacteria are not diluted. These results suggest that the growth inhibition of Rtsl⁺ bacteria at 42° C is probably the consequence of mating initiated due to loss of surface exclusion.     

Variable expression of the ssb-1 allele in different strains of Escherichia coli K12 and B: Differential suppression of its effects on DNA replication, DNA repair and ultraviolet mutagenesis

Summary We have transduced the mutant allele ssb-1, which encodes a temperature-sensitive single-strand DNA binding protein (SSB), into several Escherichia coli strains, and have examined colony-forming ability, DNA replication, sensitivity to ultraviolet light (UV) and UV-induced mutability at the nonpermissive temperature. We have found: 1) that the degree of ssb-1-mediated temperature-sensitivity of colony-forming ability and of DNA replication is strain-dependent, resulting in plating efficiencies at 42° C (relative to 30° C) ranging from 100% to 0.002%; 2) that complete suppression of the temperature-sensitivity caused by ssb-1 occurs only on nutrient agar, and not in any other medium tested; 3) that strains in which ssb-1-mediated temperature-sensitivity is completely suppressed show moderate UV sensitivity and normal UV mutability at 30° C, but much more extreme UV sensitivity and drastically reduced UV mutability at 42° C; and 4) that defects in excision repair or in other Uvr⁺-dependent processes are not responsible for most of the UV sensitivity promoted by ssb-1. We discuss our results in relation to the known properties of SSB and its possible role in the induction of DNA damage-inducible (SOS) functions.     

Temperature sensitive initiation of DNA synthesis in a mutant of Salmonella typhimurium

Summary A mutant (dna-1) of Salmonella typhimurium defective in DNA synthesis is described. DNA synthesis is stopped in this mutant at 42° after a residual synthesis amounting to about 50 to 60% of the total cellular DNA in minimal medium and about 120 to 200% in a medium enriched with amino acids. Reshift back to permissive temperature after the inhibition of DNA synthesis at 42° allows for recovery of DNA synthesis after a lag of about 30 min. Protein synthesis is required during that lag for the recovery of DNA synthesis at permissive temperature. The density transfer experiments indicate that in the mutant dna-1 chromosome termini are replicated normally at 42° while the initiation of new rounds of replication is inhibited although the mutation is probably leaky at this temperature. The mutant is hypersensitive to sodium deoxycholate at 42° which suggests alteration of the membrane structure.     

Size distribution and molecular polarity of nascent DNA in a temperature-sensitive dna G mutant of Escherichia coli

Summary In the dna G t.s. strain BT 308, made lysogenic for the phage , nascent DNA was labelled by short pulses of ³H-thymidine, isolated and separated as a function of size by alkaline sucrose gradient sedimentation. The molecular polarity of the labelled DNA was then determined by hybridization to the separated strands of DNA.At 30° C, strand r DNA, made in the direction opposite that of fork movement, is synthesized in the form of short pieces. The first observable consequences of a shift to 42° C are the preferential inhibition of strand r synthesis and the small amount of strand r DNA which is made is recovered in long pieces of DNA rather than in short fragments. This indicates that the t.s. product, in strain BT 308, may be involved in the synthesis of the strand growing in the direction opposite that of replication fork movement.Newly synthesized strand l DNA, made in the same direction as replication fork movement, is found in long pieces in wild-type bacteria; it is found in pieces of intermediate size in strain BT 308 at 30° C as well as at 42° C. This indicates additional differences in the replication machinery between strain BT 308 and wild-type bacteria.     

Prophage induction in Escherichia coli K12 cells deficient in DNA polymerase I.

Summary The induction of prophage by ultraviolet light has been measured inE. coli K12 lysogenic cells deficient in DNA polymerase I. The efficiency of the induction process was greater inpolA1 polC(dnaE) double mutants incubated at the temperature that blocks DNA replication than inpolA ⁺ polC single mutants. Similarly, thepolA1 mutation sensitizedtif-promoted lysogenic induction in apolA1 tif strain at 42°. In strains bearing thepolA12 mutation, which growth normally at 30°, induction of the prophage occured after the shift to 42°. It is concluded that dissapearance of the DNA polymerase I activity leads to changes in DNA replication that are able, per se, to trigger the prophage induction process.     

Kinetics of induction of error-prone repair of bacteriophage lambda by temperature shift in an Escherichia coli dnaB mutant.

Summary Preincubation at 42^o, before infection at permissive temperature by phage , of an Escherichia coli dnaB mutant, provokes a significant increase in survival and mutagenesis of ultraviolet irradiated phage as well as mutagenesis of untreated phage. Similarly to UV irradiation and many chemical mutagens, the inhibition of DNA synthesis by temperature shift of this dnaB mutant induces SOS repair. This work shows that replication blockage in bacterial DNA is not only mutagenic for bacterial DNA itself (Witkin, 1975) but also for normally replicating DNA, probably due to induction of diffusible products.     

Cell division and the production of cells lacking nuclear bodies in a mutant of Salmonella typhimurium

Summary There are two distinct division phases when the temperature-sensitive DNA synthesis initiation mutant Salmonella typhimurium strain 11G is shifted from 25° to 38°. The first phase appears to represent segregation of the nuclear bodies formed at 38°. Division in this phase takes place at the normal size and produces mainly organisms with one nuclear body. It is dependent on the termination of the rounds of replication in operation at the time of the temperature shift and sensitive to low doses of penicillin. This division phase continues for 60–75 min and then after a short lag division restarts. At first the cells undergoing the second division phase are only slightly larger than normal but they soon grow into short filaments which bud off cells at both ends even if only one nuclear body is present. The cells budded off in this division phase are about 3 long on both broth and M M. They lack nuclear bodies but have a small amount of DNA which may be exclusively in the form of a large plasmid. This second division phase is also dependent on rounds of replication being allowed to terminate at 38° and is sensitive to low levels of penicillin. It is 80–90 min after the temperature shift before the second division phase starts and this lag is maintained even if rounds of replication have been completed prior to the temperature shift by amino acid starvation at 25°. The occurrence of this lag and the demonstration (using penicillin) of potential division sites at regular intervals along 11G filaments suggest that division is initiated some time before the actual division event.     

Temperature dependent survival of UV-irradiated Escherichia coli K12

Summary We have found that several excision deficient derivatives of Escherichia coli K12 survive better after UV irradiation if incubated at 42°C than if incubated at 30°C. The highest survival was observed when incubation at 42°C followed UV irradiation and was maintained for at least 16 h. Our results indicate that this temperature dependent resistance (TDR) requires a functional recA gene, but not uvr A, uvrB, recF, or recB genes, or the recA441 (tif-1) mutation which allows thermoinduction of the recA-lexA regulon. Our data are consistent with the idea that the increase in survival observed at 42°C reflects enhanced daughterstrand gap repair by DNA strand exchange. Although the conditions used to elicit TDR can induce heat shock proteins and thermotolerance in E. coli, the relationship between the two responses remains to be elucidated.     

DNA repair in Proteus mirabilis. IV. Post-irradiation DNA degradation as influenced by a function inducible in rec+ cells.

Summary Post-irradiation DNA degradation in P. mirabilis rec ⁺ strains after UV irradiation is found to be more extensive in starvation buffer than in growth medium. In growth medium restriction of protein synthesis, but not DNA synthesis, largely prevents the expression of breakdown limitation. By the addition of chloramphenicol during post-irradiation incubation in growth medium the expression of break-down limitation was followed and found to occur 20 to 40 min after UV irradiation. Pre-irradiation by a low dose of UV leads after a corresponding time of post-irradiation incubation to breakdown limitation even in starvation buffer after a second UV exposure.Post-irradiation DNA degradation is presumed to be initiated at the sites of DNA lesions which arise at replication points damaged by UV. While pre-starvation restricts the efficiency of postirradiation DNA degradation by the reduction of the number of replication points active at the time of irradiation, caffeine as well as 2,4-dinitrophenol inhibit DNA degradation even in rec ^- cells probably by the interference with nicking or exonucleoltytic events initiated at those sites in the absence of breakdown limitation.Breakdown limitation is postulated to be due to inducible derepression of REC-functions which lead to the protection and, probably, repair of DNA lesions arising at the replication points following UV exposure.     

Prophage induction in thermosensitive DNA mutants of Bacillus subtilis

Summary Incubation of thermosensitive dna mutants of Bacillus subtilis at the non-permissive temperature leads in some instances to induction of defective prophage PBSX and cell lysis. A clear distinction can be made between mutants affected in DNA replication at the growing point (extension mutants) and those unable to initiate new rounds of replication (initiation mutants). The former promote PBSX induction to a variable and mutation-specific extent, whereas the latter do not exhibit any signs of induction. Analysis of mutants carrying two dna mutations suggests that products of some dna genes involved in initiation and in extension are not essential for induction but can substantially amplify its extent. However, mitomycin C treatment of dna mutants which have completed their residual DNA synthesis leads to a PBSX induction essentially identical to that obtained by mitomycin C treatment of the wild-type strain, which precludes an essential role for any of the mutated proteins in this induction process. On the basis of our observations we propose that the induction signal is related to the number of blocked replication forks: the larger that number, the higher the proportion of induced cells within the population.     

RNase H is not involved in the induction of stable DNA replication in Escherichia coli.

rnh mutations of Escherichia coli inactivating RNase H activity allow the initiation of rounds of DNA replication in the absence of protein synthesis (stable DNA replication). However, levels of RNase H did not change during or after the induction of stable DNA replication in rnh+ strains by incubation with nalidixic acid or UV irradiation.     

Suppressor mutations (rin) that specifically suppress the recA+ dependence of stable DNA replication in Escherichia coli K-12

Summary The sdrA102 mutation confers upon cells the ability to replicate DNA in the absence of protein synthesis. This mutation was combined with the recA200 mutation, which renders the recA protein thermolabile, and had little effect on normal replication. However, the sdrA102 recA200 double mutant exhibited temperature-sensitive stable DNA replication: it replicated DNA continuously in the presence of chloramphenicol at 30°C, whereas at 42°C DNA replication ceased after the DNA content increased only 40–45%. Suppressor mutants (rin; recA-independent) capable of stable DNA replication at 42°C were isolated from the double mutant. The suppressor mutant retained all other recA ^– characteristics, i.e., deficient general recombination, severe UV-sensitivity, and incapability of prophage induction in lysogens. This indicates that the rin mutation specifically suppresses the recA ⁺ dependency of stable DNA replication. It is suggested that the recA ⁺ protein stabilizes a specific structure, similar to an intermediate in recombination, which may function in the initiation of stable DNA replication.     

Prophage induction and cell division in E. coli. II. Linked (recA, zab) and unlinked (lex) suppressors of tif-1-mediated induction and filamentation

Summary The pleiotropy of tif-1, a mutation in E. coli K12 causing, among other effects, cellular filamentation at 42° and thermal induction of lysogenic derivatives, can be explained by the participation of the tif ⁺ gene product in more than one reaction pathway. Pathways that involve the tif ⁺ product may be analyzed by selection of secondary mutations that reverse both tif-1-mediated prophage induction and cell filamentation. Among revertants of a tif-1 lysogen among 20% are recombination deficient. These appear to carry a recA mutation. In addition to this class is a rarer (7%) phenotypically distinguishable class of revertants, called zab, first described here. Markers tif-1, recA and zab are closely linked. Mutations lex which are dominant and located near malB also appear (3%) among tif-1 revertants. The lex ⁺ function is needed for normal UV, X-ray and mitomycin C induction of prophage .The zab mutation resembles recA in causing (1) high sensitivity to UV, X-rays and mitomycin C, (2) drastic DNA degradation following UV irradiation but normal capacity to repair UV-damaged infecting phage (Hcr⁺), (3) failure to carry out UV reactivation and UV mutagenesis of UV-irradiated bacteriophage , (4) a markedly reduced level of spontaneous induction of . In contrast, other capacities, strikingly diminished by recA, are affected less, if at all by zab. Thus zab (1) permits 30–60% normal recombination proficiency, (2) shows real, although very low inducibility of by UV or mitomycin C, (3) permits 100% efficiency of plating of red gam, and (4) does not degrade DNA spontaneously.The hypothesis is proposed that the tif-1 mutation is a regulatory mutation controlling the activity, or more likely the synthesis of repair enzyme(s). The level of these repair enzyme(s), rather than DNA lesions, may govern the stability of the prophage repressor and the capacity of the bacteria to form septa.     

SOS induction by thermosensitive replication mutants of miniF plasmid

Summary MiniF, a 9.3 kb fragment of the dispensable F plasmid, carries genes necessary for its replication and partition as well as for the expression of an SOS signal. The arrest of replication of a thermo-sensitive miniFts at 42°C induced SOS functions such as prophage , sfiA expression, W-reactivation of UV-irradiated phage . Two miniF ts9 and ts17 mutations were located within the KpnI fragment (43.6–46.9) in the minimal oriS replicon. Blocking miniF replication by incBC ⁺ incompatibility genes situated in trans on a second plasmid also induced SOS functions. In contrast, if miniFts17 plasmid escaped the replication block at 42°C by being inserted into pR325, there was no SOS induction. SOS induction by the arrest of miniF replication required the miniF lynA ⁺ locus in cis, the host recA ⁺ and lexA ⁺ genes. We found that SOS induction was increased greatly near the stationary phase and that cell viability declined. During host cell exponential growth, miniFts9 and miniFts17 plasmids were lost rapidly, although SOS induction persisted for several cell generations. We postulate that lynA expresses a persistent product that may lead to the unwinding of chromosomal DNA.