Role of sulA and sulB in filamentation by lon mutants of Escherichia coli K-12.

Cells containing the pleiotropic Escherichia coli mutation lon filament extensively and die after exposure to ultraviolet light. Outside suppressors of the ultraviolet sensitivity, called sul, have previously been described at two loci; these mutations reverse the ultraviolet sensitivity of lon strains but do not affect the mucoidal or degradation defect of these strains. An isogenic set of strains carrying combinations of lon, sulA, and sulI was constructed, and their behavior during normal growth and after ultraviolet treatment was studied. sulA mutations had no detectable phenotype in lon+ cells; the lon sulA strains filamented transiently after ultraviolet irradiation, as did lon+ sul+ cells. We found that the sulB mutation, which alters cell morphology and slows recovery from transient filamentation after ultraviolet treatment, was epistatic to both lon and sulA. Whereas sulA mutations were recessive to the wild-type allele, sulB was partially dominant. The simplest model to account for our observations is that sulA and lon participate in a pathway of filamentation independent of that which produces transient filamentation in wild-type strains; sulB product may be the target of sulA action and may play a role in normal cell division.     

Mutations in the Ion gene of E. coli K12 phenotypically suppress a mutation in the sigma subunit of RNA polymerase

We have isolated spontaneous temperature-resistant revertants of a temperature-sensitive mutation (rpoD800) in the sigma subunit of E. coli K12 RNA polymerase. These revertants still contained the rpoD800 allele. They were mucoid, and sensitive to ultraviolet light and the radiomimetic agent nitrofurantoin, which are characteristics of lon mutants. One revertant, Tr29, was mapped to the lon region of the chromosome. Lon- rpoD800 double mutants were constructed, and were phenotypically indistinguishable from the spontaneous temperature-resistant revertant. It is the degradation-deficient property of lon mutants that is responsible for the suppression of the temperature-sensitive phenotype. We show that the rpoD800 sigma polypeptide is a substrate for the ion proteolytic system, and that mutations in lon decrease the rate of mutant sigma degradation. The rate of synthesis of mutant sigma was also affected in lon- strains. The net effect of lon-mutations was to increase the concentration of mutant sigma. We conclude that the temperature-sensitive phenotype results from insufficient concentration, rather than altered function, of the mutant protein.     

Mapping of sul, the suppressor of lon in Escherichia coli.

The suppressor sul, which is allele specific for the ultraviolet sensitivity gene lon, has been mapped by conjugation and transductional crosses in Escherichia coli K-12 and B/r. Previously, sul was reported to lie in the azi region of the Escherichia coli chromosome. Evidence is presented which positions sul close to and clockwise of fabA on the Escherichia coli map. Cotransductional frequencies of 31.3% were obtained between sul and pyrD, and frequencies of 82% were obtained between sul and fabA. Also, the mucoid phenotype of K-12 lon strains grown on minimal glucose agar plates at 37 C was not significantly effected in sul derivatives. No differences between the sul of Escherichia coli B/r and that of K-12 derivatives with regard to map location or effect on mucoid production were observed.     

Overproduction of FtsZ suppresses sensitivity of lon mutants to division inhibition.

Escherichia coli lon mutants are sensitive to UV light and other DNA-damaging agents. This sensitivity is due to the loss of the lon-encoded ATP-dependent proteolytic activity which results in increased stability of the cell division inhibitor SulA. Introduction of the multicopy plasmid pZAQ containing the ftsZ gene, which is known to increase the level of FtsZ, suppressed the sensitivity of lon mutants to the DNA-damaging agents UV and nitrofurantoin. Alterations of pZAQ which reduced the expression of ftsZ reduced the ability of this plasmid to suppress the UV sensitivity. Examination of the kinetics of cell division revealed that pZAQ did not suppress the transient filamentation seen after exposure to UV, but did suppress the long-term inhibition that is normally observed. lon strains carrying pZAQ could stably maintain a multicopy plasmid carrying sulA (pBS2), which cannot otherwise be introduced into lon mutants. In addition, the increased temperature sensitivity of lexA(Ts) strains containing pBS2 was suppressed by pZAQ. These results suggest that SulA inhibits cell division by inhibiting FtsZ and that this interaction is stoichiometric.     

Deg phenotype of Escherichia coli lon mutants.

Deg. one of the Escherichia coli systems for degrading abnormal polypeptides (e.g., nonsense fragments), is also involved in the degradation of some classes of missense proteins. Both missense proteins of beta-galactosidase and temperature-sensitive phage products appear to be degraded by the Deg system. Mutations in the Deg system are indistinguishable from mutations classically called lon or capR; all map near proC, all are mucoid, defective in protein degradation, sensitive to radiomimetic agents, and defective in P1 lysogenization. All are able to propagate temperature-sensitive phage better than lon+ parental strains. Mutations that suppress the radiation sensitivity of these strains (sul) also suppress the P1 lysogenization defect, but do not affect mucoidy or the degradation defect.     

Dominance of Ultraviolet Radiation Resistance in Partial Diploids of Escherichia coli K-12

Although an F'13 capR(+)/capR9 strain is nonmucoid and an F'13 capR9/capR(+) strain is mucoid, both strains are ultraviolet (UV)-resistant. In contrast, haploid capR9 strains are UV-sensitive. Therefore, UV resistance is dominant to UV sensitivity, regardless of whether the capR(+) allele is on the chromosome or on the F'13 episome.     

Identification of the gene lon (capR) product as a 94-kilodalton polypeptide by cloning and deletion analysis.

A mutation in the lon (capR) gene of Escherichia coli K-12 effects several phenotypic alterations in the mutant cell, such as overproduction of capsular polysaccharide and sensitivity to ultraviolet or ionizing radiation. A previously cloned 9.2-megadalton (Md) EcoRI fragment contained the capR+ gene and specified two polypeptides, 94 kilodaltons (K) and 67K. To provide evidence that the 94K polypeptide is the capR+ gene product, we constructed a capR+ plasmid pJMC40, having a 2.0-Md EcoRI-PstI fragment which codes only for the 94K polypeptide. Plasmids pJMC22 and pJMC30, having deletions of 0.7 and 0.8 Md, respectively, from one end of the 2.0-Md fragment, were also constructed. Each codes for a shortened stable polypeptide (from the 94K). Neither plasmid can confer the capR+ phenotype to capR mutants, confirming that the unaltered 94K polypeptide is the capR+ gene product. Plasmids pJMC51 and pJMC52 each have a deletion of 0.7 Md from the other end of the 2.0-Md fragment, differing only in the orientation of the remaining 1.3-Md fragment with respect to the cloning vehicle. They are nonfunctional with respect to capR+ and do not code for a common polypeptide from the 1.3-Md fragment. These data indicate that the fragments in pJMC22 and pJMC30, which both code for shortened 94K polypeptides, contain the promoter-operator region of the capR gene. The deletion plasmids were also used to map chromosomal capR mutations.     

Saturation and specificity of the Lon protease of Escherichia coli.

Lon is an ATP-dependent protease of Escherichia coli. The lon mutation has a pleiotropic phenotype: UV sensitivity, mucoidy, deficiency for lysogenization by bacteriophage lambda and P1, and lower efficiency in the degradation of abnormal proteins. All of these phenotypes are correlated with the loss of protease activity. Here we examine the effects of overproduction of one Lon substrate, SulA, and show that it protects two other substrates from degradation. To better understand this protection, we mutagenized the sulA gene and selected for mutants that have partially or totally lost their ability to saturate the Lon protease and thus can no longer protect another substrate. Some of the SulA mutants lost their ability to protect RcsA from degradation but could still protect the O thermosensitive mutant protein (Ots). All of the mutants retained their capacity to induce cell division inhibition. It was also found that deletion of the C-terminal end of SulA affected its activity but did not affect its susceptibility to Lon. We propose that Lon may have more than one specificity for peptide cleavage.     

Multiple regulator gene control of the galactose operon in Escherichia coli K-12

Previous studies showed that nonsense mutations in either of two genes (capR or capS) or an undefined mutation in a third gene (capT) led to pleiotropic effects: (i) increased capsular polysaccharide synthesis (mucoid phenotype); (ii) increased synthesis of enzymes specified by at least four spatially separated operons involved in synthesis of capsular polysaccharide including the product of the galE gene, UDP-galactose-4-epimerase (EC 5.1.3.2) in capR mutants. The present study demonstrated that the entire galactose (gal) operon (galE, galT, and galK) is derepressed by mutations in either the capR or the capT genes, but not by mutation in capS. Double mutants (capR9 capT) were no more derepressed than the capR9 mutant, indicating that capR9 and capT regulate the gal operon via a common pathway. Isogenic double mutants containing either galR(+), galR(-), galR(s), or galO(c) in combination with either capR(+) or capR9 were prepared and analyzed for enzymes of the gal operon. The results demonstrated that capR9 caused derepression as compared to capR(+) in all of the combinations. Strains with a galR(s) mutation are not induced, for the gal operon, by any galactose compound including d-fucose, and this was confirmed in the present study using d-fucose. Nevertheless, the derepression of galR(s) capR9 compared to galR(s) capR(+) was four- to sixfold. The same derepression was observed when galR(+)capR9 was compared to galR(+)capR(+). The data eliminate the explanation that internal induction of the gal operon by a galactose derivative was causing increased gal operon enzyme synthesis in capR or capT mutants. Furthermore, the same data suggest that the galR and capR genes are acting independently to derepress the gal operon. A modified model for the structure of the gal operon is proposed to explain these results. The new feature of the model is that two operator sites are suggested, one to combine with the galR repressor and one to combine with the capR repressor.     

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.     

Derepression of Phosphomannose Isomerase by Regulator Gene Mutations Involved in Capsular Polysaccharide Synthesis in Escherichia coli K-12

A regulator gene mutation (capR) that causes increased synthesis of capsular polysaccharide and derepressed synthesis of several enzymes involved in polysaccharide synthesis also derepresses phosphomannose isomerase (PMI) synthesis. In contrast, a second mutation (capS, which maps separately from capR) that causes increased production of the same polysaccharide does not lead to increased synthesis of PMI (nor of several of the other enzymes involved in polysaccharide synthesis). Introduction of the capR9 allele by transduction or mutation of capR(+) to capR can change the phenotype of a mannose-negative nonmucoid strain to a mannose-positive mucoid phenotype. Thus, genotype capR(+)man-2 is mannose-negative and nonmucoid, but genotype capR9 man-2 is mannose positive and mucoid. Other interactions between these alleles in the synthesis of capsular polysaccharide are recorded.     

Depression of guanosine diphosphate-mannose pyrophosphorylase by mutations in two different regulator genes involved in capsular polysaccharide synthesis in Escherichia coli K-12

Mutations in a regulator gene (capR) that causes increased synthesis of capsular polysaccharide and derepressed synthesis of several enzymes involved in polysaccharide synthesis also derepress synthesis of guanosine diphosphate (GDP)-mannose pyrophosphorylase. In addition, a second mucoid mutation (capS, which maps separately from capR) also results in the derepression of GDP-mannose pyrophosphorylase. New conditions for assaying GDP-mannose hydrolyase and GDP-l-fucose synthetase permitted us to show that these enzymes are also derepressed in the capS mucoid strain. Although phosphomannose isomerase and uridine diphosphate-galactose-4-epimerase are derepressed in capR mucoid strains, they are not derepressed in capS mucoid strains. A nonmucoid mutant of a strain containing the capR9 (mucoid) allele was deficient in GDP-mannose pyrophosphorylase.     

Thermoresistant revertants of an Escherichia coli strain carrying tif-1 and ruv mutations: non-suppressibility of ruv by sfi.

Spontaneous thermoresistant revertants were isolated from Tif1 Ruv- and Tif1 Ruv+ strains of Escherichia coli K-12. They were divided into five groups; backmutants to tif+ and recA structural gene mutants accounted for at least two of these groups. Mutations with an unconditional RecA- phenyotype were detected at a higher frequency in the Tif1 Ruv- strains (65%) than in the Tif1 Ruv+ strains (25%). A third group consisted of revertants exhibiting a RecA- phenotype at low temperature. Revertants with normal recombination ability and UV resistance, but with a thermosensitive defect in propagating lambda bio11 phage, were also isolated (group 4). The alleles responsible for this property were cotransducible with the srl gene, suggesting that they are located at the recA locus. Other revertants, which might carry lex, LEXB, or zab mutations, were UV sensitive and were able to propagate lambda bio11 phage (group 5). The sfi mutation, which suppresses filamentation in the Tif1 and UV-sensitive Lon- strains, does not restore UV resistance of the Ruv- mutant.     

Mutants defective in the 33K outer membrane protein of Salmonella typhimurium.

Salmonella typhimurium LT2 lines, if phenotypically rough, are fully sensitive to bacteriocin 4-59, produced by Salmonella canastel strain SL1712. Bacteriocin-resistant mutants fell into three classes. Those resistant to phage ES18 and to albomycin proved to be mutants of class chr (equivalent to tonB of Escherichia coli); these mutants still adsorb the bacteriocin and so are classified as tolerant. Another class of (incompletely) tolerant mutants was resistant to phage PH51; their envelope fractions lacked the band corresponding to outer membrane protein 34K, known to serve for adsorption of phage PH51. A third class of mutants, which did not adsorb the bacteriocin, was unaltered in sensitivity to phages. Their envelopes lacked the 33K band, indicating absence of the outer membrane protein 33K, considered to correspond to outer membrane protein II* of E. coli, which in that species is determined at locus ompA (formerly tolG or con). Phage P22 HT105/1 cotransduced the 33K S. typhimurium gene (to be called ompA, to accord with E. coli usage) with pyrD+ at about 30% frequency when the donor allele was ompA+ or one ompA, but at only 3 to 11% when the donor allele was another ompA. When the donor carried either of two long deletions of the put (proline utilization) operon, phage P22 HT105/1 cotransduced put (and ompA+) with pyrD+ at low frequency. The cotransduction data indicate that ompA of S. typhimurium is located between pyrD and put, nearer the former. This corresponds to the map position of ompA in E. coli K-12.     

A lacZ-ftsZ gene fusion is an analog of the cell division inhibitor sulA.

An in-frame lacZ-ftsZ gene fusion under lac control was fortuitously constructed by subcloning an EcoRI fragment that contains approximately 90% of the ftsZ gene. The identity of the gene fusion was confirmed by isolating an amber mutation in the hybrid gene and then using it to reconstruct the ftsZ gene, which now contained an amber mutation. The hybrid protein (ZZ), which does not possess ftsZ activity, contains seven amino acids of lacZ at its amino terminal end, followed by 35,000 daltons of the carboxyl end of the ftsZ protein. Induction of the hybrid protein resulted in a rapid cessation of cell division which could be reversed by removing the lac inducer. This inhibition of division could be prevented by an increased gene dosage of ftsZ or the presence of the sulB allele of ftsZ, which is known to code for an altered but functional ftsZ protein. An increased gene dosage of ftsZ or the presence of the sulB allele of ftsZ is known to overcome sulA-mediated inhibition of division during the SOS response. Thus, our results suggest that ZZ is an analog of sulA and may aid in determining how sulA inhibits cell division.     

Escherichia coli polypeptide controlled by the lon (capR) ATP hydrolysis-dependent protease and possibly involved in cell division

Mutation in the gene lon (capR) of Escherichia coli K-12 causes conditional inhibition of cell division. Two-dimensional gel electrophoresis was used to compare polypeptides from isogenic capR+ and capR strains. One polypeptide was present in the capR strain but absent in the wild-type strain, and it was proteolyzed when the pure capR+ protease was added to the capR extract. This polypeptide could only be detected in the capR strain when cell division was inhibited, and its synthesis was independent of the SOS response.     

Distribution of mannosamine and mannosaminuronic acid among cell walls of Bacillus species

Some Escherichia coli K-12 lamB mutants, those producing reduced amounts of LamB protein (one-tenth the wild type amount), grow normally on dextrins but transport maltose when present at a concentration of 1 microM at about one-tenth the normal rate. lamB Dex- mutants were found as derivatives of these strains. These Dex- mutants are considerably impaired in the transport of maltose at low concentrations (below 10 microM), and they have a structurally altered LamB protein which is impaired in its interaction with phages lambda and K10 but still interacts with a lambda host range mutant lambda hh*. The Dex- mutants are double lamB mutants carrying one mutation, already present in the parental strains, that reduces LamB synthesis and a second that alters LamB structure. The secondary mutations, present in different independent Dex- mutants, are clustered in the same region of the lamB gene. Dex+ revertants were isolated and analyzed: when the altered LamB protein is made in wild-type amount, due to a reversion of the first mutation, the phenotype reverts to Dex+. However, these Dex+ revertants are still very significantly impaired in maltose transport at low concentrations (below 10 microM).