Effect of suppressors of SOS-mediated filamentation on sfiA operon expression in Escherichia coli

In Escherichia coli, the cell division block observed during the SOS response requires the product of the sfiA gene, whose expression is regulated negatively by the LexA repressor and positively by the RecA protease. We have studied the effect on sfiA expression of sfiA, sfiB, infA, and infB mutations, which are known to affect SOS-associated filamentation. To measure sfiA expression in the different strains, we first constructed a lambda transducing phage carrying an sfiA::lac operon fusion. Mutations at the sfiA locus (dominant and recessive) and the sfiB locus (recessive) had no effect on sfiA expression. The mutations tif (at the recA locus) and tsl (at the lexA locus) are known to induce filamentation and a high level of sfiA expression at 42 degrees C. The infB1 mutation, which suppresses filamentation in a tif tsl strain at 42 degrees C, reduced sfiA expression at 42 degrees C in tif tsl infB1 and tsl infB1 strains but not in a tif infB1 strain. The infA3 mutation, which suppresses tif-mediated filamentation, reduced induction of sfiA expression in a tif infA3 strain at 42 degrees C or after UV irradiation. The isolation and characterization of sfiA constitutive strains revealed only lexA-linked mutations in a sfiA-background, suggesting that LexA is the only readily eliminated repressor of the sfiA gene. Nevertheless, the infA and infB mutations could define elements involved in the regulation of sfiA expression.     

Novel mechanism of cell division inhibition associated with the SOS response in Escherichia coli.

Certain Escherichia coli strains were shown to possess a novel system of cell division inhibition, called the SfiC+ phenotype. SfiC+ filamentation had a number of properties similar to those of sfiA-dependent division inhibition previously described: (i) both are associated with the SOS response induced by expression of the recA(Tif) mutation, (ii) both are associated with cell death, (iii) both are amplified in mutants lacking the Lon protease, and (iv) both are suppressed by sfiB mutations. SfiC+ filamentation and sfiA-dependent division inhibition differed in (i) the physiological conditions under which loss of viability is observed, (ii) the extent of amplification in lon mutants, (iii) their genetic regulation (SfiC+ filamentation is not under direct negative control of the LexA repressor), and (iv) their genetic determinants (SfiC+ filamentation depends on a locus, sfiC+, near 28 min on the E. coli map and distinct from sfiA).     

Inhibition of cell division in hupA hupB mutant bacteria lacking HU protein.

Escherichia coli hupA hypB double mutants that lack HU protein have severe cellular defects in cell division, DNA folding, and DNA partitioning. Here we show that the sfiA11 mutation, which alters the SfiA cell division inhibitor, reduces filamentation and production of anucleate cells in AB1157 hupA hupB strains. However, lexA3(Ind-) and sfiB(ftsZ)114 mutations, which normally counteract the effect of the SfiA inhibitor, could not restore a normal morphology to hupA hupB mutant bacteria. The LexA repressor, which controls the expression of the sfiA gene, was present in hupA hupB mutant bacteria in concentrations half of those of the parent bacteria, but this decrease was independent of the specific cleavage of the LexA repressor by activated RecA protein. One possibility to account for the filamentous morphology of hupA hupB mutant bacteria is that the lack of HU protein alters the expression of specific genes, such as lexA and fts cell division genes.     

Two pathways of division inhibition in UV-irradiated E. coli

We have investigated the mechanism of division inhibition in E. coli following UV-irradiation or nalidixic acid treatment. After UV, two separate mechanisms, both dependent upon recA+, appear to block division. One mechanism is dependent upon sfiA and sfiB, is inhibited by low levels (4 micrograms/ml) of rifamycin and is expressed in tif mutants at 42 degrees C. The second mechanism is independent of sfiA, and sfiB, is resistant to rifamycin and does not occur in cells lacking DNA replication forks. We suggest that this second mechanism is the result of the failure to terminate DNA replication in inhibited cells. Nalidixic acid inhibition of cell division also appears to involve both mechanisms but as found previously replication forks are also necessary to induce the sfi pathway.     

Coupling of DNA replication and cell division: sulB is an allele of ftsZ.

Treatments that damage DNA in Escherichia coli result in the inhibition of cell division. This inhibition is controlled by the lexA-recA regulatory circuit and can be specifically uncoupled by the mutations sulA (sfiA) and sulB (sfiB), which map at 21 and 2 min, respectively. Presently it is thought that sulA codes for an inducible inhibitor of cell division, the expression of which is controlled directly by the lexA repressor. In this report, it is shown that sulB is an allele of ftsZ, an essential cell division gene. A sulB mutation leads to an altered ftsZ gene product which is slightly thermosensitive and has an altered mobility on polyacrylamide gels. It is suggested that the altered ftsZ gene product is resistant to the sulA inhibitor, thus permitting cell division after induction of the SOS response. It is also shown that an increase in the gene dosage of ftsZ delays the onset of filamentation after SOS induction.     

Genetic and phenotypic characterization of dnaC mutations.

The dna-1, dna-2, dna-7, and dna-28 mutations, all of which are located near min 89.5 on the E. coli linkage map, have been characterized further. As previously demonstrated for dna-2 and dna-28, neither the dna-1 nor dna-7 mutation affects the ability of a strain to produce bacteriophage lambda at temperatures non-permissive for the continued replication of the bacterial chromosome. The reported temperature-sensitive inhibition of lambda production in a strain carrying dna-7 is shown to be a consequence of a thermosensitive host specificity mutation in the hsm gene and not of the dna-7 mutation. The four dna mutations are recessive to the wild type and define a single dnaC cistron according to standard complementation criteria. Unlike other characterized dnaC mutants, however, strains carrying the dnaC1 or dnaC7 alleles exhibit an abrupt cessation of deoxyribonucleic acid synthesis at 42 C that appears to be more compatible with a defect in deoxyribonucleic acid chain elongation rather than in initiation. The possibility that the apparent elongation defect is actually a composite effect of residual synthesis and deoxyribonucleic acid degradation is raised by the net deoxyribonucleic acid degradation observed in the dnaC1 strain at 42 C. Several alternative possibilities for the function of the dnaC gene product are suggested.     

Genetic and morphological characterization of ftsB and nrdB mutants of Escherichia coli.

The ftsB gene of Escherichia coli is believed to be involved in cell division. In this report, we show that plasmids containing the nrdB gene could complement the ftsB mutation, suggesting that ftsB is an allele of nrdB. We compared changes in the cell shape of isogenic nrdA, nrdB, ftsB, and pbpB strains at permissive and restrictive temperatures. Although in rich medium all strains produced filaments at the restrictive temperature, in minimal medium only a 50 to 100% increase in mean cell mass occurred in the nrdA, nrdB, and ftsB strains. The typical pbpB cell division mutant also formed long filaments at low growth rates. Visualization of nucleoid structure by fluorescence microscopy demonstrated that nucleoid segregation was affected by nrdA, nrdB, and ftsB mutations at the restrictive temperature. Measurements of beta-galactosidase activity in lambda p(sfiA::lac) lysogenic nrdA, nrdB, and ftsB mutants in rich medium at the restrictive temperature showed that filamentation in the nrdA mutant was caused by sfiA (sulA) induction, while filamentation in nrdB and ftsB mutants was sfiA independent, suggesting an SOS-independent inhibition of cell division.     

Suppression of tif-mediated induction of SOS functions in Escherichia coli by an altered dnaB protein.

The tif-1 mutation in the Escherichia coli recA gene is known to cause induction of the various "SOS" functions at high temperature, including massive synthesis of the recA protein, lethal filamentation, elevated mutagenesis, and, in lambda lysogens, induction of prophage. It is shown here that the deoxyribonucleic acid initiation mutation dnaB252 suppresses all these manifestations of tif expression. Induction of lambda by ultraviolet irradiation, however, is not affected by the dnaB252 mutation. No similar suppression of tif is observed with other dnaB mutations affecting deoxyribonucleic acid elongation or with other deoxyribonucleic acid initiation mutations at the dnaA and dnaC loci. The fact that an alteration of the dnaB protein specifically suppresses tif-mediated SOS induction implies a role of the replication apparatus in this process, as has been suggested for ultraviolet induction. The induction of lambda is known to proceed via repressor cleavage, presumably promoted by an activated (protease) form of the recA protein. Since lambda induction is normal after ultraviolet irradiation of the tif-1 dnaB252(lambda) strain, tif-mediated induction in this strain may be blocked in a tif-specific step leading to activation of the recA (tif) protein. It is possible that the recA (tif) mutant protein may be directly involved in the replication complex in processes leading to this activation.     

Insertion of inverted Ter sites into the terminus region of the Escherichia coli chromosome delays completion of DNA replication and disrupts the cell cycle

To investigate the co-ordination between DNA replication and cell division, we have disrupted the DNA replication cycle of Escherichia coli by inserting inverted Ter sites into the terminus region to delay completion of the chromosome. The inverted Ter sites (designated Inv Ter :: spc ^r) were initially inserted into the chromosome of a Δ tus strain to allow unrestrained chromosomal replication. We then introduced a functional tus gene by transforming the Inv Ter :: spc ^r strain with a plasmid carrying the tus gene under control of an arabinose-inducible promoter. In the presence of 0.2% arabinose, the cells formed long filaments, suggesting that activation of the inverted Ter sites by Tus arrested DNA replication and delayed the onset of cell division. Induction of sfiA , a gene in the SOS regulon, was observed following arrest of DNA replication; however, when a sfiB114 allele was introduced into Inv Ter :: spc ^r strain, long filaments were still formed, suggesting that the sfi -independent pathway also caused filamentation. Either recA :: cam ^r or lexA3 alleles suppressed filamentation when introduced in the Inv Ter strain. Interestingly, in both the recA :: cam ^r and lexA3 mutants, virtually all cells had a nucleoid, suggesting that cell division was proceeding even though DNA replication was not complete. These results suggest that DNA replication and cell division are uncoupled when recA is inactivated or when genes repressed by LexA cannot be induced.     

Dissociation of tsl-tif-Induced Filamentation and recA Protein Synthesis in Escherichia coli K-12

In Escherichia coli, expression of the tif-1 mutation (in the recA gene) induces the "SOS response" at 40 degrees C, including massive synthesis of the recA(tif) protein, cell filamentation, appearance of new repair and mutagenic activities, and prophage induction. Expression of the tsl-1 mutation (in the lexA gene) induces massive synthesis of the recA protein and cell filamentation at 42 degrees C, although other SOS functions are not induced. In this paper we show that the septation inhibition induced in tif and tsl strains at 42 degrees C is not due to the presence of a high concentration of recA protein since (i) no recA mutants (相似文献   

Characteristics of cold-sensitive mutants of Escherichia coli K-12 defective in deoxyribonucleic acid replication.

Four cold-sensitive mutants of Escherichia coli have been isolated which show a reduced ability to synthesize deoxyribonucleic acid at low temperature. The mutants also have a reduced ability to incorporate nucleoside triphosphates into deoxyribonucleic acid at low temperature in cell preparations made permeable with toluene. All four mutations are located at or near the dnaA locus on the E. coli genetic map. They are recessive to the wild-type allele and two of them can be integratively suppressed by F episomes.     

Recessive mutations conferring resistance to carbon catabolite repression of galactokinase synthesis in Saccharomyces cerevisiae

A total of 37 recessive mutations showing enhanced resistance to the glucose repression of galactokinase synthesis have been isolated by a selection procedure with a GAL81 gal7 double mutant. These mutations were grouped into three different complementation classes. One class, reg1, contains mutants arising from mutations at a site close to, but complementing, the gal3 locus. The reg1 mutant also showed resistance to the glucose repression of invertase synthesis but not to that of alpha-D-glucosidase. The two other classes were identified as arising from recessive mutations at the GAL82 locus and the GAL83 locus, respectively, at which various dominant mutations were isolated previously. When in a constitutive background due to the GAL81 or gal80 mutation, the GAL82 and GAL83 mutations did not show a mutually additive effect on the resistance to glucose repression of galactokinase synthesis, while the reg1 and GAL82 (or GAL83) mutations did. Based upon the specific behavior of cells with various genotypes for the above genes in response to the concentration of galactose and glucose in the medium, we propose a model involving three independent circuits for glucose signals in the regulation of the structural genes for the galactose pathway enzymes.     

Thermosensitive mutations affecting ribonucleic acid polymerases in Saccharomyces cerevisiae.

Among 150 temperature-sensitive Saccharomyces cerevisiae mutants which we have isolated, 15 are specifically affected in ribonucleic acid (RNA) synthesis. Four of these mutants exhibit particularly drastic changes and were chosen for a more detailed study. In these four mutants, RNA synthesis is immediately blocked after a shift at the nonpermissive temperature (37 C), protein synthesis decays at a rate compatible with messenger RNA half-life, and deoxyribonucleic acid synthesis increases by about 40%. All the mutations display a recessive phenotype. The segregation of the four allelic pairs ts-/ts+ in diploids is mendelian, and the four mutants belong to three complementation groups. The elution patterns (diethylaminoethyl-Sephadex) of the three RNA polymerases of the mutants grown at 37 C for 3.5 h show very low residual activities. The in vitro thermodenaturation confirms the in vivo results; the half-lives of the mutant activities at 45 C are 10 times smaller than those of the wild-type enzymes. Polyacrylamide gel electrophoresis shows that the synthesis of all species of RNA is thermosensitive. The existence of three distinct genes, which are each indispensable for the activity of the three RNA polymerases in vivo as well as in vitro, strongly favors the hypothesis of three common subunits in the three RNA polymerases.     

Deoxyribonucleic acid synthesis in a temperature-sensitive Escherichia coli dnaH mutant, strain HF4704S.

The dnaH mutant strain HF4704S, isolated by Sakai et al. (1974), was examined for its effect on phiX174 deoxyribonucleic acid (DNA) synthesis. It was found to carry two mutations affecting DNA synthesis. One mutation had no affect on phiX174 DNA synthesis, but did affect the ability of the mutant cells to form colonies on agar medium at 41 degrees C, and caused host DNA synthesis to cease after 1 h at 41 degrees C. The mutant marker cotransduced with ilvD at a frequency of about 9%. It seems likely that this mutation is in the dnaA gene. The second mutation affected the ability of the mutant cells to form colonies on agar medium supplemented with only 2 mug of thymine per ml, and affected both host and phiX174 DNA synthesis in medium supplemented with only 2 mug of thymine per ml. Both effects could be overcone by adding excess exogenous thymine. We were not able to unambiguously determine the map position of this mutant locus. Our data show that the DNA synthesis phenotype of the mutant strain HE4704S is governed by both these mutations, neither of which directly affects the replication of phiX174 DNA.     

Temperature-Sensitive Divisionless Mutant of Bacillus subtilis Defective in the Initiation of Septation

A temperature-sensitive divisionless mutant of Bacillus subtilis 168, tms-12, is shown to be defective in an early step in septum formation at the restrictive temperature. The nature of this defect has been studied by comparing the growth and composition of mutant and wild-type (tms-12(+)) cells at the restrictive (48 C) and permissive (34 C) temperatures. At 48 C, tms-12 cells grow as nonseptate, multinucleate filaments. Filamentation does not appear to be a result of alterations in properties of the cell wall, since the ratio of mucopeptide to teichoic acid, the autolytic activity, and the ability of the walls to protect cells against osmotic shock are comparable in tms-12 filaments and tms-12(+) bacilli grown at 48 C. Synthesis of deoxyribonucleic acid and the segregation of nucleoids also proceed normally during filamentation. The synthesis of membrane, however, is delayed during filamentation of tms-12. No gross alterations were observed in the protein or lipid composition of membranes isolated from mutant filaments. Septum formation resumes when filaments are returned to 34 C and appears to be associated with an increased synthesis of membrane. The occurrence of septa was monitored both by microscopic observation of cross walls and by assays of the number of viable protoplasts released from bacillary filaments upon removal of the cell wall. Septation recovery can be blocked by inhibitors of ribonucleic acid and protein synthesis added during, but not after, the first 7 min of recovery at 34 C. By contrast, inhibition of deoxyribonucleic synthesis does not block recovery.     

Characterization of lexB mutations in Escherichia coli K-12.

Two mutations have been located at the recA locus and phenotypically characterized along with a third one, previously called rec-34. The three mutants behaved similarly to lexA mutants. They were sensitive to ultraviolet (UV) light and X rays, and lambdaFec- phages were able to plate on them. The three mutations were called lexB because they could be distinguished from recA mutations by the last property. lexB mutants were less sensitive to UV and X irradiations than were recA mutants and were, to various degrees, recombination proficient. UV light failed to induce prophage lambda in all three lexB lysogens. In contrast, thymine starvation induced lexB31 and lexB34 lysogens. In lexB34 mutants, but not in lexB30 and lexB31 mutants, UV reactivation occurred at a low level. In Escherichia coli K-12, the recA gene has basic functions in the repair of deoxyribonucleic acid lesions, deoxyribonucleic acid recombination, and prophage induction. The three lexB mutations alter unequally and independently the three functions. This suggests that the recA and lexB mutations affect the same gene.     

Radiation-induced forward and reverse specific locus mutations and dominant cataract mutations in treated strain BALB/c and DBA/2 male mice

Strain BALB/c and DBA/2 mice were chosen to investigate the effects of genetic background on the radiation-induced mutation rate since they exhibit differences in their radiation sensitivity. Males were exposed to 3 + 3-Gy X-irradiation and mated to untreated specific locus Test-stock females. Offspring resulting from treated spermatogonia were screened for induced specific locus forward and reverse mutations and dominant cataract mutations. Since BALB/c mice are homozygous brown and albino, specific locus forward mutations could be screened at 5 of the 7 specific loci (a, d, se, p, s), while reverse mutations could be screened at the b and c loci. Strain DBA/2 is homozygous non-agouti, brown and dilute. Therefore, specific locus forward mutations could be screened at 4 loci (c, se, p, s) and reverse mutations were screened at the a, b and d loci. Results indicate no effect of genetic background on the sensitivity to mutation induction of specific locus forward mutations, while for the dominant cataract alleles strain DBA/2 exhibited a higher mutation rate than either strain BALB/c or similarly treated (101/El X C3H/El)F1 mice. If, by confirmation, these differences should be demonstrated to be real, it is interesting that strain DBA/2 should exhibit a greater sensitivity to radiation-induced dominant mutations. First, strain DBA/2 was chosen as radiation resistant or repair competent. The observation that DBA/2 exhibited a higher sensitivity to radiation-induced mutation may indicate a role for repair, albeit misrepair, in the mutation process. Second, that the effect of genotype was only observed for the mutation rate to dominant cataract alleles may reflect a difference in the spectrum of DNA alterations which result in dominant or recessive alleles. A dominant allele is more likely misinformation, such that as heterozygote it interferes with the wild-type allele. By comparison, a recessive allele may result from any DNA alteration leading to the loss of a functional gene product. One reverse mutation at each of the a and d loci was recovered in the present experiments. The similarities of the present results for radiation-induced reverse mutations with the extensive data on the spontaneous reverse mutation rates are interesting. Reverse mutations were recovered only at the a and d loci. Further, the reverse mutations recovered at the a locus were to alternate alleles (at, Aw or Asy) while true reverse mutations were apparently recovered at the d locus.     

Coresistance to Neomycin and Kanamycin by Mutations in an Escherichia coli Locus that Affects Ribosomes

Mutant strains resistant to neomycin or to kanamycin sulfate were isolated from Escherichia coli K-12. Nine mutants were analyzed; all were resistant to both antibiotics (about 150 and 100 mug/ml, respectively), and were designated nek. In the mutant strains, the ribosomes are changed from those of the parental strain; for when they were used in assays for polypeptide formation directed by polyadenylic acid or polycytidylic acid, coding fidelity in presence of the drugs was increased and inhibition of synthesis by the drugs was lessened. Mating experiments and transduction tests showed that all of the nine nek mutants are either closely linked or allelic, and the nek locus is closely linked to two genes-str (streptomycin) and spc (spectinomycin)-known to affect the 30S ribosome. The two nek mutants tested were recessive to the sensitive, wild-type allele. When the nek mutants were compared to the parental strain, pleiotropic effects of the nek mutations were observed. Resistance to low levels of streptomycin and spectinomycin was increased, whereas resistance to chloramphenicol was decreased. Also, the mutants were less able to adapt to high concentrations of lincomycin, and could no longer show phenotypic suppression of an arginine requirement by neomycin or kanamycin. Such pleiotropic effects are suggested to be the rule for mutations in genes that participate in the biosynthesis of a cellular organelle.     

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)     

The sfiA11 mutation prevents filamentation in a response to cell wall damage only in a recA+ genetic background

Summary N--palmitoyl-l-lysyl-l-lysine dihydrochloride ethyl ester (PLL) at sublethal doses causes filamentous growth of E. coli strains except sfiA mutants, which divide normally in its presence. PLL does not elicit the SOS responses as judged by prophage induction, an increase of RecA protein synthesis or induction of the sfiA operon in a sfiA::lacZ fusion strain. Thus, it appears that filamentation caused by PLL is not an SOS function and might be the result of membrane damage by PLL, which is an amphipathic compound and at higher doses causes cell lysis. This indicates that basal levels of the sfiA gene product are sufficient to inhibit cell division in the presence of PLL.We have found further that the phenotype of the sfiA mutation in the presence of PLL requires a recA ⁺ genetic background and does not occur in E. coli recA1 sfiA11, recA13 sfiA11, recA56 sfiA11 and recA441 sfiA11. All these strains, but rec441 sfiA11, however, regain the ability of sfiA11 mutants to divide in the presence of PLL after transformation with the RecA overproducing-plasmid pXO₂. This supports the conclusion that the RecA protein positively affects sfiA11-mediated cell division in the presence of the cell membrane damaging compound, PLL. The basal level of the RecA protein in the recA ⁺sfiA11 strain is sufficient for this process. An increased level due to overproduction from the multicopy plasmid pXO₂ exerts the same effect.