Transcriptional control of the calactose operon by the capR (lon) and capT genes

DNA-binding specificity of the Lon protease alpha-domain from Brevibacillus thermoruber WR-249

Lon protease has been well studied in many aspects; however, the DNA-binding specificity of Lon in prokaryotes has not been clearly identified. Here we examined the DNA-binding activity of Lon protease alpha-domains from Brevibacillus thermoruber (Bt), Bacillus subtilis (Bs), and Escherichia coli (Ec). MALDI-TOF mass spectroscopy showed that the alpha-domain from Bt-Lon binds to the duplex nucleotide sequence 5'-CTGTTAGCGGGC-3' (ms1) and protected it from DNase I digestion. Surface plasmon resonance showed that the Bt-Lon alpha-domain binds with ms1 double-stranded DNA tighter than Bs- and Ec-Lon alpha-domains, whereas the Bt-Lon alpha-domain has dramatically lower affinity for double-stranded DNA with 0 and 50% identity to the ms1 binding sequence. Our results indicated that Bt-Lon alpha-domain plays a critical role with ms1 sequence in the DNA-binding specificity.

lon gene product of Escherichia coli is a heat-shock protein

The product of the pleiotropic gene lon is a protein with protease activity and has been tentatively identified as protein H94.0 on the reference two-dimensional gel of Escherichia coli proteins. Purified Lon protease migrated with the prominent cellular protein H94.0 in E. coli K-12 strains. Peptide map patterns of Lon protease and H94.0 were identical. A mutant form of the protease had altered mobility during gel electrophoresis. An E. coli B/r strain that is known to be defective in Lon function contained no detectable H94.0 protein under normal growth conditions. Upon a shift to 42 degrees C, however, the Lon protease was induced to high levels in K-12 strains and a small amount of protein became detectable at the H94.0 location in strain B/r. Heat induction of Lon protease was dependent on the normal allele of the regulatory gene, htpR, establishing lon as a member of the high-temperature-production regulon of E. coli.

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.

An inducible DNA replication-cell division coupling mechanism in E. coli

Cell division is a tightly regulated periodic process. In steady-state cultures of Enterobacteriaceae, division takes place at a well defined cell mass and is strictly coordinated with DNA replication. In wild-type Escherichia coli the formation of cells lacking DNA is very rare, and interruptions of DNA replication arrest cell division. The molecular bases of this replication-division coupling have been elusive but several models have been proposed. It has been suggested, for example, that the termination of a round of DNA replication may trigger a key event required for cell division. A quite different model postulates the existence of a division inhibitor which prevents untimely division and whose synthesis is induced to high levels when DNA replication is perturbed. The work reported here establishes the existence of the latter type of replication-division coupling in E. coli, and shows that the sfiA gene product is an inducible component of this division inhibition mechanism which is synthesized at high levels after perturbations of DNA replication.

Identification and purification of the Lon+ (capR+) gene product, a DNA-binding protein

The polypeptide product of the lon (capR) gene was identified and partially purified from bacterial strains homozygous for the capR(+) or capR9 (ochre mutation) alleles cloned with pSC101. A 94,000-dalton polypeptide was identified as the lon (capR) gene product. Studies of binding to DNA cellulose columns and nitrocellulose filters indicate that the capR(+) and capR9 proteins bind DNA.

Regulation of hexuronate system genes in Escherichia coli K-12: multiple regulation of the uxu operon by exuR and uxuR gene products

New regulatory mutants of Escherichia coli K-1 carrying alterations of the uxuR gene were isolated and characterized. In the presence of superrepressed or derepressed uxuR mutations, mannonic hydrolyase (uxuA) and oxidoreductase relationship analyses suggested that the uxuR gene product acted as a repressor in the control of uxuA-uxuB operon expression. uxuR mutations were localized near min 97, and the following gene order was established: (argH)-uxuR-uxuB-uxuA-(thr). Properties of exuR (point and deletion) mutants showed that both exuR and uxuR regulatory gene products were involved in the control of the uxuA uxuB operon. Analysis of exuR uxuR double-derepressed mutants suggested that exuR and uxuR repressors act cooperatively to repress the uxu operon.

On the structure of the deo operon of Escherichia coli

A characterization of a specialized transducing lambda phage for the deo operon (lambdaddeo), and some composite colE1-deo plasmids is given in this paper. This includes localization of the RSmaI, RHind/III, RBamI, and REcoRI sensitive sites. The deo genes have been localized by construction of composite colE1-deo plasmids. Using the DNA fragments, obtained by digestion with REcoRI and RHindIII, respectively, as templates in an in vitro protein synthesizing system, it has been possible to give the direction of transcription and the exact location of the deo genes, relative to the endonuclease sites. Furthermore, the cytO,P and deoO,P regions have been mapped relative to the structural genes. Supercoiled co1E1-deo DNA has been used as template in the in vitro system; this DNA gives essentially the same results as the endonuclease-fragmented DNA. The use of the different types of templates is discussed.

Regulation of beta-glucuronidase synthesis in Escherichia coli K-12: pleiotropic constitutive mutations affecting uxu and uidA expression

Among the beta-glucuronidase (UID)-constitutive mutants obtained by growth on methyl-beta-D-galacturonide, some strains are also derepressed for the two enzymes of the uxu operon: mannonate oxidoreductase (MOR) and mannonate hydrolyase (HLM). By conjugation and transduction experiments, two distinct constitutive mutations were separated in each pleiotropic mutant strain. One of them was specific for uidA gene expression and was characterized as affecting either uidO or uidR sites. The second type of mutation was mapped close to the uxu operon and was found to be responsible for the pleiotropic effect revealed in the primary mutants: after separation such a mutation still fully derepresses MOR and HLM synthesis but weakly derepresses UID synthesis. The pleiotropic effect of this mutation was maintained even though the activity of the structural genes was altered. This rules out the occurrence of an internal derepressing interaction between these enzymes. In merodiploid strains, uxu-linked constitutive mutations were recessive to the wild-type allele, suggesting that these mutations could affect a regulatory gene. The uxuR gene is probably a specific regulatory gene for a very close operon, uxu. Moreover, it has a weak effect on uidA expression. Thus, UID synthesis would be negatively controlled through the activity of two repressor molecules that are synthesized by two distinct regulatory genes, uidR and uxuR. These two repressing factors are antagonized, respectively, by phenyl-thio-beta-D-glucuronide and mannonic amide and could cooperate in a unique repression/induction control over uidA expression. Constitutive mutations affecting the control sites of uidA gene probably characterize two distinct attachment sites in the operator locus for each of the repressor molecules.

Prophage induction and cell division in E. coli. III. Mutations sfiA and sfiB restore division in tif and lon strains and permit the expression of mutator properties of tif

In E. coli K12, cell filamentation promoted by tif is enhanced by the lon mutation; in contrast, prophage induction and repair of UV-irradiated phage lambda, also promoted by tif, are not affected by lon. From a tif lon double mutant, "revertants" having recovered the ability to divide at 41 degrees were isolated, among which most (95%) had also lost their Lon filamentous phenotype after ultraviolet (UV) irradiation. From these 95% of revertants: (1) 94% are suppressed for the whole Tif phenotype, by additional mutations that render them deficient in DNA repair, as judged from their high UV sensitivity; some have been characterized as recA mutants. (2) 1% have recovered a control on cell division at 41 degrees or after UV irradiation by means of secondary mutations altering neither the other phenotypic properties of tif and lon, nor the repair and recombination ability of the cells: in particular, this class of "revertants" remains thermoinducible upon lysogenisation; the mutations which specifically suppress filamentation have been mapped at two loci, sfiA and sfiB, cotransducible respectively with pyrD and leu. In the remaining 5% of revertants that still exhibit an UV-induced filamentous growth, 3% can be tentatively classified as true tif+ revertants; 2% behave as tif thermodependent revertants, showing suppression of the Tif (and Lon) phenotype only at 41 degrees: 2recAts have been identified in this class. Non-lysogenic tif lon sfi and tif sfi strains remain viable during prolonged growth at 41 degrees. Under these conditions, tif expresses mutator properties, which can be conveniently analyzed in this sfi background. The action of lif, lon and sfi mutations is tentatively interpreted on the basis of a negative control of cell division specifically associated with DNA repair.

Regulation of galactose operon at the gal operator-promoter region in Escherichia coli K-12

The capR (lon) product controls expression of the gal operon independently of the galR repressor. Previously, mutations of the gal operon have been isolated that are semiconstitutive and alter response to the capR and/or capT product. Such mutants imply the existence of a distinct site in the operon that responds to capR (capT) control. This mutation could be either in a site near the operator-distal end of the galE gene, which signals rho factor termination of transcription in vitro or in a site in the operator-promoter region. Bacteriophage U3 was used to isolate galE mutations in HC2142 (a mutant exhibiting reduced response to capR control). P1 transduction was used to cross these mutants with a set of galE gene deletion. Analysis of the resulting Gal+ recombinants indicates that the regulatory site is in the operator-promoter region. Hence, it is unlikely that capR functions in control as an anti-rho factor at the operator-distal end of the galE gene, but more likely as previously suggested, at a second operator distinct from one responding to galR repressor control. Upon induction with D-fucose, a promoter mutant (UV211) isolated previously expressed 20 to 30% of the galactose enzymes that the wild type exhibited in the presence of the inducer D-fucose. The effects of various mutations in cya, capR, and galR on galactokinase synthesis in this mutant were determined. Galactokinase was derepressed by capR as well as galR, but the presence or absence of the cya gene product was unimportant.

Multiple regulation of the galactose operon-genetic evidence for a distinct site in the galactose operon that responds to capR gene regulation in Escherichia coli K-12

Previous results demonstrated that the capR (lon) locus, which is not linked to the gal operon, independently controls the synthesis of the gal operon enzymes and gal mRNA, i.e., galO(+)capR9 strains are derepressed 4- to 6-fold as compared to galO(+)capR(+) strains. A mutation has been isolated and localized in the galactose operator region that defines a new and distinct site of control. Mutation in this site, designated galO(capR+), causes a 4-fold increase in the galactose enzymes, galactokinase (EC 2.7.1.6) and UDP-galactose-4-epimerase (EC 5.1.3.2), in a capR(+) background. These mutants exhibit a reduced response to regulation by the unlinked regulator gene capR (lon). However, the galO(capR+) mutants are still subject to control by the galR repressor, since they can be further derepressed by growth in the presence of D-fucose. They also synthesize more galactokinase when grown in glycerol as compared to glucose. Thus there are now at least three, and probably four, sites for control of mRNA synthesis in the operator-promoter regions of the gal operon, making it one of the most complex control systems to date for a single operon in bacteria. The complexity is sufficient to accommodate models for differentiation in higher organisms that require more than one "switch" to control a single group of genes.

Derepression of uridine diphosphate-glucose pyrophosphorylase (galU) in capR(lon), capS, and capT mutants and studies on the galU repressor

Mutation of the capR(lon), capS, or capT genes in Escherichia coli K-12 causes overproduction of capsular polysaccharide leading to a mucoid phenotype. Several of the enzymes involved in capsular polysaccharide synthesis are derepressed in cap mutants. Previously it was shown that uridine diphosphate-glucose (UDPG) pyrophosphorylase, an enzyme involved in the synthesis of three of the nucleotide sugar precursors of the capsule, is derepressed in capR mutants. The control of galU, the gene which codes for UDPG pyrophosphorylase, is described in this study. In addition, it has been found that the enzyme is also derepressed in capS and capT mutants. The effect of galU gene dosage in cap mutants and the wild-type strain (all lysogenic for phi80) was studied by infecting them with the purified transducing phage phi80dgalU. The level of UDPG pyrophosphorylase increased in proportion to the number of galU copies added. The rate of enzyme synthesis in the mutants was about sixfold higher than in the wild type per galU gene added for multiplicities of infection from one to twenty. Thus, all the galU copies added to the wild-type lysogen were repressed. We obtain greater than 20 galU copies per cell by infecting the nonlysogenic strain which allows multiplication of phi80dgalU. With some number of galU copies greater than 20, the rate of UDPG pyrophosphorylase synthesis in the wild type approaches the mutant rate of synthesis. The results suggest that there may indeed be a galU repressor pool in the cell which can be completely titrated. This pool must be composed of more than 20 galU repressor molecules. Since the capR, capS, and capT gene products or combinations thereof are known to control other widely separated operons of the cell besides the galU gene, it is postulated that the galU repressor may be capable of binding other operators. This would account for the relatively large pool of galU repressors per cell.