Division behavior and shape changes in isogenic ftsZ, ftsQ, ftsA, pbpB, and ftsE cell division mutants of Escherichia coli during temperature shift experiments.

Isogenic ftsZ, ftsQ, ftsA, pbpB, and ftsE cell division mutants of Escherichia coli were compared with their parent strain in temperature shift experiments. To improve detection of phenotypic differences in division behavior and cell shape, the strains were grown in glucose-minimal medium with a decreased osmolality (about 100 mosM). Already at the premissive temperature, all mutants, particularly the pbpB and ftsQ mutants, showed an increased average cell length and cell mass. The pbpB and ftsQ mutants also exhibited a prolonged duration of the constriction period. All strains, except ftsZ, continued to initiate new constrictions at 42 degrees C, suggesting the involvement of FtsZ in an early step of the constriction process. The new constrictions were blunt in ftsQ and more pronounced in ftsA and pbpB filaments, which also had elongated median constrictions. Whereas the latter strains showed a slow recovery of cell division after a shift back to the permissive temperature, ftsZ and ftsQ filaments recovered quickly. Recovery of filaments occurred in all strains by the separation of newborn cells with an average length of two times LO, the length of newborn cells at the permissive temperature. The increased size of the newborn cells could indicate that the cell division machinery recovers too slowly to create normal-sized cells. Our results indicate a phenotypic resemblance between ftsA and pbpB mutants and suggest that the cell division gene products function in the order FtsZ-FtsQ-FtsA, PBP3. The ftsE mutant continued to constrict and divide at 42 degrees C, forming short filaments, which recovered quickly after a shift back to the permissive temperature. After prolonged growth at 42 degree C, chains of cells, which eventually swelled up, were formed. Although the ftsE mutant produced filaments in broth medium at the restrictive temperature, it cannot be considered a cell division mutant under the presently applied conditions.     

Temperature-Sensitive Cell Division Mutants of Escherichia coli with Thermolabile Penicillin-Binding Proteins

The thermostability of the penicillin-binding proteins (PBPs) of 31 temperature-sensitive cell division mutants of Escherichia coli has been examined. Two independent cell division mutants have been found that have highly thermolabile PBP3. Binding of [(14)C]benzylpenicillin to PBP3 (measured in envelopes prepared from cells grown at the permissive temperature) was about 30% of the normal level at 30 degrees C, and the ability to bind [(14)C]benzylpenicillin was rapidly lost on incubation at 42 degrees C. The other PBPs were normal in both mutants. At 30 degrees C both mutants were slightly longer than their parents and on shifting to 42 degrees C they ceased dividing, but cell mass and deoxyribonucleic acid synthesis continued and long filaments were formed. At 42 degrees C division slowly recommenced, but at 44 degrees C this did not occur. The inhibition of division at 42 degrees C was suppressed by 0.35 M sucrose, and in one of the mutants it was partially suppressed by 10 mM MgCl(2). PBP3 was not stabilized in vitro at 42 degrees C by these concentrations of sucrose or MgCl(2). Revertants that grew as normal rods at 42 degrees C regained both the normal level and the normal thermostability of PBP3. The results provide extremely strong evidence that the inactivation of PBP3 at 42 degrees C in the mutants is the cause of the inhibition of cell division at this temperature and identify PBP3 as an essential component of the process of cell division in E. coli. It is the inactivation of this protein by penicillins and cephalosporins that results in the inhibition of division characteristic of low concentrations of many of these antibiotics.     

Ribonucleic Acid Polymerase Mutant of Escherichia coli Defective in Flagella Formation

Escherichia coli K-12 mutants that are resistant to bacteriophage chi, defective in motility, and unable to grow at high temperature (42 degrees C) were isolated from among those selected for rifampin resistance at low temperature (30 degrees C) after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. Genetic analysis of one such mutant indicated the presence of two mutations that probably affect the beta subunit of ribonucleic acid (RNA) polymerase: one (rif) causing rifampin resistance and the other (Ts-74) conferring resistance to phage chi (and loss of motility) and temperature sensitivity for growth. Observations with an electron microscope revealed that the number of flagella per mutant cell was significantly reduced, suggesting that the Ts-74 mutation somehow affected flagella formation at the permissive temperature. When a mutant culture was transferred from 30 to 42 degrees C, deoxyribonucleic acid synthesis accelerated normally, but RNA or protein synthesis was enhanced relatively little. The rate of synthesis of beta and beta' subunits of RNA polymerase was low even at 30 degrees C and was further reduced at 42 degrees C, in contrast to the parental wild-type strain. Expression of the lactose and other sugar fermentation operons, as well as lysogenization with phage lambda, occurred normally at 30 degrees C, suggesting that the mutation does not cause general shut-off of gene expression regulated by cyclic adenosine 3',5'-monophosphate.     

Identification of temperature-sensitive DNA- mutants of Chinese hamster cells affected in cellular and viral DNA synthesis.

We described a strategy which facilitates the identification of cell mutants which are restricted in DNA synthesis in a temperature-dependent manner. A collection of over 200 cell mutants temperature-sensitive for growth was isolated in established Chinese hamster cell lines (CHO and V79) by a variety of selective and nonselective techniques. Approximately 10% of these mutants were identified as ts DNA- based on differential inhibition of macromolecular synthesis at the restrictive temperature (39 degrees C) as assessed by incorporation of [3H]thymidine and [35S]methionine. Nine such mutants, selected for further study, demonstrated rapid shutoff of DNA replication at 39 degrees C. Infections with two classes of DNA viruses extensively dependent on host-cell functions for their replication were used to distinguish defects in DNA synthesis itself from those predominantly affecting other aspects of DNA replication. All cell mutants supported human adenovirus type 2 (Ad2) and mouse polyomavirus DNA synthesis at the permissive temperature. Five of the nine mutants (JB3-B, JB3-O, JB7-K, JB8-D, and JB11-J) restricted polyomavirus DNA replication upon transfection with viral sequences at 33 degrees C and subsequent shift to 39 degrees C either before or after the onset of viral DNA synthesis. Only one of these mutants (JB3-B) also restricted Ad2 DNA synthesis after virion infection under comparable conditions. No mutant was both restrictive for Ad2 and permissive for polyomavirus DNA synthesis at 39 degrees C. The differential effect of these cell mutants on viral DNA synthesis is expected to assist subsequent definition of the biochemical defect responsible.     

A single base change in the acceptor stem of tRNA(3Leu) confers resistance upon Escherichia coli to the calmodulin inhibitor, 48/80

We have isolated several classes of spontaneous mutants resistant to the calmodulin inhibitor 48/80 which inhibits cell division in Escherichia coli K12. Several mutants were also temperature sensitive for growth and this property was exploited to clone a DNA fragment from an E. coli gene library restoring growth at 42 degrees C and drug sensitivity at 30 degrees C in one such mutant. Physical and genetic mapping confirmed that both the mutation and the cloned DNA were located at 15.5 min on the E. coli chromosome at a locus designated feeB. By subcloning, complementation analysis and sequencing, the feeB locus was identified as identical to the tRNA(CUALEU) gene. When the mutant locus was isolated and sequenced, the mutation was confirmed as a single base change, C to A, at position 77 in the acceptor stem of this rare Leu tRNA. In other studies we obtained evidence that this mutant tRNA, recognizing the rare Leu codon, CUA, was defective in translation at both permissive and non-permissive temperatures. The feeB1 mutant is defective in division and shows a reduced growth rate at non-permissive temperature. We discuss the possibility that the mutant tRNA(3Leu) is limiting for the synthesis of a polypeptide(s), requiring several CUA codons for translation which in turn regulates in some way the level or activity of the drug target, a putative cell cycle protein.     

DNA replication termination in Escherichia coli parB (a dnaG allele), parA, and gyrB mutants affected in DNA distribution.

We investigated the Escherichia coli mutants carrying the parB, parA, and gyrB mutations, all of which display faulty chromosome partitioning at the nonpermissive temperature, to see whether their phenotype reflected a defect in the termination of DNA replication. In the parB strain DNA synthesis slowed down at 42 degrees C and the SOS response was induced, whereas in the parA strain DNA synthesis continued normally for 120 min and there was no SOS induction. To see whether replication forks accumulated in the vicinity of terC at the nonpermissive temperature, the mutants were incubated for 60 min at 42 degrees C and then returned to low temperature and pulse-labeled with [3H]thymidine. In all cases the restriction pattern of the labeled DNA was incompatible with that of the terC region, suggesting that replication termination was normal. In the parA mutant no DNA sequences were preferentially labeled, whereas in the parB and gyrB strains there was specific labeling of sequences whose restriction pattern resembled that of oriC. In the case of parB this was confirmed by DNA-DNA hybridization with appropriate probes. This test further revealed that the parB mutant over initiates at oriC after the return to the permissive temperature. Like dna(Ts) strains, the parB mutant formed filaments at 42 degrees C in the absence of SOS-associated division inhibition, accompanied by the appearance of anucleate cells of nearly normal size (28% of the population after 3 h), as revealed by autoradiography. The DNA in the filaments was either centrally located or distributed throughout. The parB mutation lies at 67 min, and the ParB- phenotype is corrected by a cloned dnaG gene or by a plasmid primase, strongly suggesting that parB is an allele of dnaG, the structural gene of the E. coli primase. It is thus likely that the parB mutant possesses an altered primase which does not affect replication termination but causes a partial defect in replication initiation and elongation and in chromosome distribution.     

Cell growth and division in Escherichia coli: a common genetic control involved in cell division and minicell formation

Escherichia coli Div 124(ts) is a conditional-lethal cell division mutant formed from a cross between a mutant that produces polar anucleated minicells and a temperature-sensitive cell division mutant affected in a stage of cross-wall synthesis. Under permissive growth temperature (30 C), Div 124(ts) grows and produces normal progeny cells and anucleated minicells from its polar ends. When transferred to nonpermissive growth temperature (42 C), growth and macromolecular synthesis continue, but cell division and minicell formation are inhibited. Growth at 42 C results in formation of filamentous cells showing some constrictions along the length of the filaments. Return of the filaments from 42 to 30 C results in cell division and minicell formation in association with the constrictions and other areas along the length of the filaments. This gives rise to a "necklace-type" array of cells and minicells. Recovery of cell division is observed after a lag and is followed by a burst in cell division and finally by a return to the normal growth characteristic of 30 C cultures. Recovery of cell division takes place in the presence of chloramphenicol or nalidixic acid when these are added at the time of shift from 42 to 30 C, and indicates that a division potential for filament fragmentation is accumulated while the cells are at 42 C. This division potential is used for the production of both minicells and cells of normal length. The conditional-lethal temperature sensitive mutation controls a step(s) in cross-wall synthesis common to cell division and minicell formation.     

Delayed nucleoid segregation in Escherichia coli

To study the role of cell division in the process of nucleoid segregation, we measured the DNA content of individual nucleoids in isogenic Escherichia coli cell division mutants by image cytometry. In pbpB(Ts) and ftsZ strains growing as filaments at 42 degrees C, nucleoids contained, on average, more than two chromosome equivalents compared with 1.6 in wild-type cells. Because similar results were obtained with a pbpB recA strain, the increased DNA content cannot be ascribed to the occurrence of chromosome dimers. From the determination of the amount of DNA per cell and per individual nucleoid after rifampicin inhibition, we estimated the C and D periods (duration of a round of replication and time between termination and cell division respectively), as well as the D' period (time between termination and nucleoid separation). Compared with the parent strain and in contrast to ftsQ, ftsA and ftsZ mutants, pbpB(Ts) cells growing at the permissive temperature (28 degrees C) showed a long D' period (42 min versus 18 min in the parent) indicative of an extended segregation time. The results indicate that a defective cell division protein such as PbpB not only affects the division process but also plays a role in the last stage of DNA segregation. We propose that PbpB is involved in the assembly of the divisome and that this structure enhances nucleoid segregation.     

Defective cell division in thermosensitive mutants of Salmonella typhimurium

Summary Two temperature-sensitive mutants ofSalmonella typhimurium defective in cell division (divA anddivC) have been isolated. Cell division in these mutants is arrested at elevated temperature while DNA and protein synthesis are unaffected. This results in formation of long filaments. Filaments returned to permissive temperature divide after a short lag. Inhibition of DNA synthesis by nalidixic acid does not block these divisions. This suggests that the thermosensitive step is required late in the division cycle. Chloramphenicol prevents the division of filaments shifted back to permissive temperature in one of these mutants (divA) and allows limited division to take place in the other mutant (divC). The arrest of cell division at elevated temperature may be phenotypically cured by high osmolarity of the medium. The mutationdivA has been mapped betweenrha andmetB and the mutationdivC betweenleu andaziA.If the filaments ofdivA are starved for thymine and then returned to permissive temperature with the simultaneous restoration of thymine the start of their division is delayed in comparison with the division of the control (unstarved) filaments. The argument is raised that a proper ratio of terminated chromosomes to cell mass must be attained to allow division.     

Physiological Effects of Growth of an Escherichia coli Temperature-Sensitive dnaZ Mutant at Nonpermissive Temperatures

The physiological effects of incubation at nonpermissive temperatures of Escherichia coli mutants that carry a temperature-sensitive dnaZ allele [dnaZ(Ts)2016] were examined. The temperature at which the dnaZ(Ts) protein becomes inactivated in vivo was investigated by measurements of deoxyribonucleic acid (DNA) synthesis at temperatures intermediate between permissive and nonpermissive. DNA synthesis inhibition was reversible by reducing the temperature of cultures from 42 to 30 degrees C; DNA synthesis resumed immediately after temperature reduction and occurred even in the presence of chloramphenicol. Inasmuch as DNA synthesis could be resumed in the absence of protein synthesis, we concluded that the protein product of the dnaZ allele (Ts)2016 is renaturable. Cell division, also inhibited by 42 degrees C incubation, resumed after temperature reduction, but the length of time required for resumption depended on the duration of the period at 42 degrees C. Replicative synthesis of cellular DNA, examined in vitro in toluene-permeabilized cells, was temperature sensitive. Excision repair of ultraviolet light-induced DNA lesions was partially inhibited in dnaZ(Ts) cells at 42 degrees C. The dnaZ(+) product participated in the synthesis of both Okazaki piece (8-12S) and high-molecular-weight DNA. During incubation of dnaZ(Ts)(lambda) lysogens at 42 degrees C, prophage induction occurred, and progeny phage were produced during subsequent incubation at 30 degrees C. The temperature sensitivity of both DNA synthesis and cell division in the dnaZ(Ts)2016 mutant was suppressed by high concentrations of sucrose, lactose, or NaCl. Incubation at 42 degrees C was neither mutagenic nor antimutagenic for the dnaZ(Ts) mutant.     

Cell Division in Escherichia coli: Analysis of Double Mutants for Filamentation and Abnormal Septation of Deoxyribonucleic Acid-Less Cells

The link between chromosome termination, initiation of cell division, and choice of division sites was studied in Escherichia coli by preparing double mutants. Hybrid mutants containing div52-ts, a cell division initiation mutation, and min, mutations which affect the choice of division sites resulting in the septation of minicells, were characterized. The mutants produced minicells and normal cells coordinately under all conditions studied, although the fraction of minicells is half that of the parental minicell strain. The mutant gradually stopped dividing at both the median and minicell septation sites when transferred from 30 to 41 C in rich medium. A synchronous cell division of filaments was induced 15 min after addition of chloramphenicol to the medium, even at 41 C. Divisions were observed at both normal and minicell sites. These results indicate that div52-ts and min functions share a common step in a cell division pathway. A double mutant containing div52-ts and div27-ts, a dnaB mutant which divides in the absence of DNA synthesis, was characterized. The mutant continues to divide after a shift to the high temperature, although at a reduced rate. The behavior of this hybrid mutant suggests a hypothesis that the chromosome termination signal and div52-ts division initiation signal act on a single membrane site which is altered in div27-ts strains.     

Isolation and initial characterization of a temperature-sensitive mutant of mouse FM3A cells defective in cytokinesis

A temperature-sensitive mutant, designated tsFT101, was isolated from a mouse mammary carcinoma cell line, FM3A, and given an initial characterization. In this cell line, cytokinesis was blocked at a non-permissive temperature (39 degrees C), but DNA synthesis and nuclear division proceeded normally for at least 24 h at 39 degrees C as detected respectively by autoradiography and cytofluorometric analysis. As a result, multinucleate cells accumulated at 39 degrees C (more than 95% in 36 h). When the culture was returned to a permissive temperature (33 degrees C) after 24 h of arrest at 39 degrees C, cytokinesis was resumed and there was a rapid decrease in the number of multinucleate cells. At 39 degrees C, tsFT101 cells had less F-actin than cells at 33 degrees C, indicative of the existence of an abnormality in actin polymerization in this mutant.     

Control mechanism of the Escherichia coli K-12 cell cycle is triggered by the cyclic AMP-cyclic AMP receptor protein complex.

The role of cyclic AMP (cAMP) in the cell cycle of Escherichia coli K-12 was studied in three mutant strains. One was KI1812, in which the cya promoter is replaced by the lacUV5 promoter. In KI1812, isopropyl-beta-D-thiogalactopyranoside induced the synthesis of cya mRNA, and at the same time cell division was inhibited and short filaments containing multiple nuclei were formed. The other strains were constructed as double mutants (NC6707 cya sulB [ftsZ(Ts)] and TR3318 crp sulB [ftsZ(Ts)]). In both double mutants, filamentation was repressed at 42 degrees C, but it was induced again by addition of cAMP in strain NC6707 and introduction of pHA7 containing wild-type crp in TR3318. These results indicate that lateral wall synthesis in the E. coli cell cycle is triggered by the cAMP-cAMP receptor protein complex.     

Specific Sindbis virus-coded function for minus-strand RNA synthesis.

The synthesis of minus-strand RNA was studied in cell cultures infected with the heat-resistant strain of Sindbis virus and with temperature-sensitive (ts) belonging to complementation groups A, B, F, and G, all of which exhibited an RNA-negative (RNA-) phenotype when infection was initiated and maintained at 39 degrees C, the nonpermissive temperature. When infected cultures were shifted from 28 degrees C (the permissive temperature) to 39 degrees C at 3 h postinfection, the synthesis of viral minus-strand RNA ceased in cultures infected with ts mutants of complementation groups B and F, but continued in cultures infected with the parental virus and mutans of complementation groups A and G. In cultures infected with ts11 of complementation group B, the synthesis of viral minus-strand RNA ceased, whereas the synthesis of 42S and 26S plus-strand RNAs continued for at least 5 h after the shift to 39 degrees C. However, when ts11-infected cultures were returned to 28 degrees C 1 h after the shift to 39 degrees C, the synthesis of viral minus-strand RNA resumed, and the rate of viral RNA synthesis increased. The recovery of minus-strand synthesis translation of new proteins. We conclude that at least one viral function is required for alphavirus minus-strand synthesis that is not required for plus-strand synthesis. In cultures infected with ts6 of complementation group F, the syntheses of both viral plus-strand and minus-strand RNAs were drastically reduced after the shift to 39 degrees C. Since ts6 failed to synthesize both plus-strand and minus-strand RNAs after the shift to 39 degrees C, at least one common viral component appears to be required for the synthesis of both minus-strand and plus-strand RNAs.     

Novel acriflavin resistance genes, acrC and acrD, in Escherichia coli K-12.

Acriflavine-resistant mutants were isolated from an acriflavine-sensitive (acrA) strain of Escherichia coli K-12 and then tested for temperature sensitivity of cell division. Genetic analysis characterized two new genetic loci, acrC and acrD. The former was mapped between tonA and proA, and the latter between the origin of genetic transfer of HfrH and serB. acrC and acrD mutants could divide but did not initiate a new round of deoxyribonucleic acid (DNA) replication at 43 degrees C. DNA synthesis of the acrC mutant cells ceased after a period of time following temperature shift-up, and thereafter DNA degradation occurred. However, cell mass continued to increase for a long time at the nonpermissive temperature. On the other hand, DNA synthesis of the acrD mutant cells ceased soon after the shift-up, and the cell mass did not appreciably increase during the prolonged incubation.     

Phenethyl Alcohol Resistance in ESCHERICHIA COLI. III. a Temperature-Sensitive Mutation (dnaP) Affecting DNA Replication

A temperature-sensitive DNA replication mutant of E. coli K-12 was isolated among the mutants selected for phenethyl alcohol resistance at low temperatures. This mutation, designated as dnaP18, affects sensitivity of the cell to phenethyl alcohol, sodium deoxycholate and rifampicin, presumably due to an alteration in the membrane structure. At high temperatures (e.g., 42 degrees ), synthesis of DNA, but not RNA or protein, is arrested, leading to the formation of "filaments" in which no septum formation is apparent. Nucleoids observed under electron microscope seem to become dispersed and DNA fibrils less condensed, which may explain the loss of viability under these conditions. Genetic analyses, including reversion studies, indicate that a recessive dnaP mutation located between cya and metE on the chromosome is responsible for both alterations of the membrane properties and temperature sensitivity. The dnaP18 mutation does not affect growth of phage T4 or lambda under conditions where host DNA replication is completely inhibited. Kinetic studies of DNA replication and cell division in this mutant after the temperature shift from 30 to 42 degrees , and during the subsequent recovery at 30 degrees , accumulated evidence suggesting that DNA replication comes to a halt at 42 degrees upon completion of a cycle already initiated before the temperature shift. Since the recovery of DNA synthesis after exposure to 42 degrees does not depend on protein or RNA synthesis or other energy-requiring processes, the product of the mutant dnaP gene appears to be reversibly inactivated at 42 degrees . Taken together with the recessive nature of the present mutation, it was suggested that one of the membrane proteins involved in initiation of DNA replication is affected in this mutant.     

Protein synthesis in yeast. Identification of an altered elongation factor in thermolabile mutants of the yeast Saccharomyces cerevisiae

Cell-free extracts from the wild type yeast strain (A364A) and from a group of noncomplementing mutants that are conditionally defective in translation were preincubated at a restrictive temperature prior to incubation at a permissive temperature for protein synthesis. Results of these experiments showed that upon exposure to the restrictive temperature (39 degrees C), all five of the noncomplementing mutants lost ability to incorporate amino acid into protein. The wild type parent strain retained better than 80% of the activity under identical conditions of heat treatment. Mutant extracts could be revived to incorporate amino acid by the addition of the purified yeast elongation factor 3. Factors 1 and 2 had no effect. The heat-treated extract from one mutant did not supplement the activity of the other mutant. Although all five of the mutants were inactivated by preincubation at 39 degrees C, each showed a variable rate and extent of thermolability. Heat-treated mutant extracts were fully active in polyphenylalanine synthesis with liver ribosomes but not with the yeast ribosomes. Since liver ribosomes do not require factor 3, this assay then confirms that factor 3 is the thermolabile component in this group of noncomplementing mutants.     

Characterization of RNA synthesis in an Escherichia coli mutant with a temperature-sensitive lesion in stable RNA synthesis

Previous experiments with Escherichia coli strain 2S142 have shown that the synthesis of stable RNA is preferentially blocked at the restrictive temperature. In this paper, we have examined the capacity of this mutant strain to synthesize RNA in vitro. Growth of the strain for as short a period as 10 min at 42 degrees C resulted in a 40 to 60% loss of RNA synthetic capacity and a fourfold decrease in percent rRNA synthesized in toluenized cell preparations. The time course for the loss and recovery of this RNA synthetic capacity correlated very well with the changes in RNA synthesis observed in vivo. We found no difference in temperature sensitivity of the purified RNA polymerase from the mutant and the parental strains. Moreover, there was no detectable alteration in the amount of enzyme, specific activity of the enzyme, or electrophoretic mobility of the subunits when the mutant strain was grown at 42 degrees C. The capacity for rRNA synthesis was also measured with the Zubay in vitro system (Reiness et al., Proc. Natl. Acad. Sci. 72:2881-2885, 1975). Supernatant fractions (S-30) prepared from cells grown at 30 degrees C were capable of up to 31.2% rRNA synthesis, using phi 80d3 DNA as template. S-30 fractions from cells grown at 42 degrees C synthesized 8.6% rRNA. The bottom one-third of the S-100 fraction and the ribosomal salt wash from 30 degrees C cells contained one or more factors which partially restored preferential rRNA synthesis in S-30 fractions from cells grown at 42 degrees C. Preliminary evidence suggests that the factor(s) is protein in nature.     

Escherichia coli dnaK null mutants are inviable at high temperature.

DnaK, a major Escherichia coli heat shock protein, is homologous to major heat shock proteins (Hsp70s) of Drosophila melanogaster and humans. Null mutations of the dnaK gene, both insertions and a deletion, were constructed in vitro and substituted for dnaK+ in the E. coli genome by homologous recombination in a recB recC sbcB strain. Cells carrying these dnaK null mutations grew slowly at low temperatures (30 and 37 degrees C) and could not form colonies at a high temperature (42 degrees C); furthermore, they also formed long filaments at 42 degrees C. The shift of the mutants to a high temperature evidently resulted in a loss of cell viability rather than simply an inhibition of growth since cells that had been incubated at 42 degrees C for 2 h were no longer capable of forming colonies at 30 degrees C. The introduction of a plasmid carrying the dnaK+ gene into these mutants restored normal cell growth and cell division at 42 degrees C. These null mutants showed a high basal level of synthesis of heat shock proteins except for DnaK, which was completely absent. In addition, the synthesis of heat shock proteins after induction in these dnaK null mutants was prolonged compared with that in a dnaK+ strain. The well-characterized dnaK756 mutation causes similar phenotypes, suggesting that they are caused by a loss rather than an alteration of DnaK function. The filamentation observed when dnaK mutations were incubated at a high temperature was not suppressed by sulA or sulB mutations, which suppress SOS-induced filamentation.(ABSTRACT TRUNCATED AT 250 WORDS)