rho Mutations restore lamB expression in E. coli K12 strains with an inactive malB region

Summary lamB, the structural gene for receptor, is the second gene of the malK-lamB operon in the malB region of the Escherichia coli K12 chromosome. lamB is essentially not expressed in the absence of an active malT gene product, the activator or the maltose regulon. A malT strain is resistant to phage . We show that: (i) Introduction of rho mutations in malT mutants restores lamB expression to a level sufficient to render the strain sensitive to phage ; (ii) This restoration is not dependent on the main promoter of the malK lamB operon. It depends on the distal part of the malK gene.We propose that rho inactivation unmasks the activity of a promoter located near the distal end of malK. Experiments with Mu insertions in gene malK suggest that in the (-) orientation a Mu promoter is also able to allow lamB expression in a rho background.     

Mitochondrial resistance to miconazole in Saccharomyces cerevisiae

Summary One mutant of mitochondrial origin resistant to miconazole has been isolated and characterized in S. cerevisiae. The mutation is linked to the locus oli1, the structural gene for subunit 9 of ATPase on mitochondrial DNA. Miconazole inhibited the mitochondrial ATPase of the wild type while the enzyme of the resistant mutant was insensitive to this effect. Levels of ATP decreased to one-third of the control in the wild type in the presence of miconazole, while they were unaffected in the mutant.Abbreviations MNNG N-methyl-N-nitrosoguanidine - Mic^s/Mic^r phenotypic sensitivity/resistance to miconazole - M ₁ ^R mitochondrial locus conferring miconazole resistance - rho⁺/rho^- grand/cytoplasmic petite - rho^o cytoplasmic petite deleted of all mitochondrial DNA - w⁺ mitochondrial locus conferring polarity of recombination     

A mutant rho ATPase from Escherichia coli that is temperature-sensitive in the presence of RNA

Summary The Escherichia coli mutant rho-115 suppresses lac operon polarity conferred by the lacZ::IS1 insertion MS319. The ATPase activity of purified rho-115 protein was maximal at 40°C, in contrast to 45°C for rho ⁺. At higher temperatures (50°C, 55°C), the fractions of activities at maximal temperature were consistently lower for rho-115 compared to rho ⁺. The 30-minute time course of rho-115 ATP hydrolysis was linear at 37°C but at 45°C the linear kinetics of hydrolysis reached a plateau between 10 and 15 minutes. The 30-minute time courses for rho ⁺ were linear at both 37°C and 45°C. The rho-115 and rho ⁺ ATPase activities were equally heat-stable during preincubation at 45°C in buffer. Inclusion of ATP during preincubation protected these rho proteins from inactivation to the same extent. The presence of polyC during preincubation protected rho ^- activity but produced substantial inactivation of rho-115 ATPase. The presence of polyU during preincubation gave similar results. Concentrations of polyC between 625 ng/ml and 100 g/ml yielded the same extent of rho-115 ATPase inactivation during preincubation at 45°C. Thermal inactivation of rho-115 ATPase by polyC was halted by shifting preincubation temperature from 45°C to 35°C, indicating that polyC-induced destabilization of rho-115 was irreversible.     

Structure of the malB region in Escherichia coli K12. I. Genetic map of the malK-lamB operon.

Summary A series of deletions, Mu insertions and point mutations affecting the malK-lamB operon have been isolated. They were used to establish a deletion map of this operon, which could be divided in 27 intervals, with 16 in malK and 11 in lamB. One interesting feature of this map is the lack of randomness in the distribution of Mu insertions in the lamB gene; by using data published elsewhere on the physical length of the deletion intervals it can be concluded that about 25% of these Mu insertions are clustered in a segment representing 3% of the gene, and another 20% in a segment representing 2 to 8% of the gene. This map is presently being used to study the biosynthesis, structure, and function of the lamB product, which is an outer membrane protein involved in the transport of maltose and maltodextrin, and which in addition constitutes the receptor for phage .     

'Muprints' of the lac operon demonstrate physiological control over the randomness of in vivo transposition

A method called Muprinting has been developed that uses PCR to generate a detailed picture of the bacteriophage Mu transposition sites in chosen domains of the bacterial chromosome. Muprinting experiments In Escherichia coli show that the frequency of phage integration changes dramatically near two repressor binding sites in the lac operon. When the lac operon was repressed, hotspots for Mu transposition were found near the O₁ and O₂ operators that are proposed to make a repression loop. When cells were grown in lactose, Mu transposition near these operators was greatly diminished. Striking changes In transposition frequencies were limited to the control region and were not found in a region of the lacZ gene lying beyond the O₂ operator. Muprints of the bgl operon showed a different pattern; hotspots for Mu transposition detected in sequences upstream of the bglC promoter when the operon was silenced changed when the operon became activated by mutation. By targeting transposition to the regulatory regions around non-expressed genes, Mu may demonstrate a self-restraint mechanism that allows the virus to move through its host genome without disrupting the functions that contribute to a healthy cell physiology.     

Differential expression of mal genes under cAMP and endogenous inducer control in nutrient-stressed Escherichia coli

LamB glycoporin has an important general role in carbohydrate uptake during growth at low extracellular sugar concentrations. lamB and mal regulon induction during glucose starvation and glucose-limited continuous culture was investigated using lacZ fusions. A low-level burst of lamB induction occurred upon entry into glucose starvation-induced stationary phase but returned to basal levels during continued nutrient deprivation. Glucose-limited continuous culture elicited much higher expression of transporter genes in the mal regulon, as well as [¹⁴C]-maltose-transport activity; malEFG and malKlamB operons in glucose-limited chemostats were expressed to close to half of the level of maltose-induced batch cultures. Limitation-induced expression was dependent on both Crp-cAMP and MalT activation but was independent of RpoS function. As expected for a gene with a Crp-controlled promoter, malT expression was maximal under conditions which elicited the highest cAMP levels, but lamB induction did not behave in a corresponding fashion. Rather, maximal lamB induction occurred at rapid but suboptimal growth rates with micromolar or submicromolar medium glucose. Maximal transport and lamB induction coincided with increased endogenous maltotriose (inducer) concentrations during growth on glucose. Hence regulation of glycoporin and the maltose-transport system is not a starvation- or stationary-phase response but facilitates the adaptation of Escherichia coli to low-nutrient environments through endoinduction.     

Second-site rho mutation: Genetic linkage and polyC-dependent ATPase

Summary Rho has been purified to homogeneity from Escherichia coli double mutant rho-115 sur-38 cells, and from rho ⁺⁺ and rho-115 cells. The sur-38 mutation suppresses the original rho-115 phenotype. We observe that the polyC-dependent ATPases of these three rho preparations have the same specific activities. However, the ATPase of rho from the double rho-115 sur-38 mutant is extremely heat labile, while that from rho-115 shows a heat lability intermediate between the wild type and the double mutant.Transduction analysis suggests that sur-38 is closely linked to rho-115 in the order ilv-sur-38-rho-115-metE. These data are consistent with the model that the sur-38 mutation affects the structural gene for rho.Contact for offprints     

Reduced superhelicity of plasmid DNA produced by the rho-15 mutation in Escherichia coli

Summary The plasmid pJSF6, a derivative of pBR327, could be maintained at 30° C in strains of Escherichia coli containing the strong rho mutation, rho-15. Plasmids extracted from rho-15 cells were always less negatively supercoiled than plasmids from rho ⁺ cells. Transduction experiments designed to separate the rho gene from possible extragenic suppressors showed that the rho allele consistently determined the degree of plasmid superhelicity. Comparison of the superhelicity of plasmids extracted from the rho-15 and from a gyrB mutant showed that at 30° C the negative supercoiling was reduced by the amounts W _rho=4.0±0.3 and W _gyr=6.0±0.3 turns; the effect of the rho-15 mutation on supercoiling was thus comparable to that of the gyrB mutation. A similar effect of the rho-15 mutation on the superhelicity of pBR329 was observed. The observation that the Rho protein has a role in determining DNA superhelicity (though not necessarily a direct role) provides a new point of view for studying the pleiotropic properties of rho mutants.We dedicate this paper to the cherished memory of Ethel S. Tessman, who died May 10, 1986. She encouraged and advised and stimulated each of us in the development of our careers     

Different structures of selected and unselected araB-lacZ fusions

Formation of araB-lacZ coding-sequence fusions is a key adaptive mutation system. Eighty-four independent araB-lacZ fusions were sequenced. All fusions carried rearranged MuR linker sequences between the araB and lacZ domains indicating that they arose from the standard intermediate of the well-characterized Mu DNA rearrangement process, the strand transfer complex (STC). Five non-standard araB-lacZ fusions isolated after indirect sib selection had novel structures containing back-to-back inverted MuR linkers. The observation that different isolation procedures gave rise to standard and non-standard fusions indicates that cellular physiology can influence late steps in the multi-step biochemical sequence leading to araB-lacZ fusions. Each araB-lacZ fusion contained two novel DNA junctions. The MuR-lacZ junctions showed‘hot-spotting’according to established rules for Mu target selection. The araB-MuR and MuR-MuR junctions all involved exchanges at regions of short sequence homology. More extensive homology between MuR and araB sequences indicates potential STC isomerization into a resolvable four-way structure analogous to a Holliday junction. These results highlight the molecular complexity of araB-lacZ fusion formation, which may be thought of as a multi-step cell biological process rather than a unitary biochemical reaction.     

Cloning and primary structure of Staphylococcus aureus DNA topoisomerase IV: a primary target of fluoroquinolones

Study of the molecular basis for Legionella pneumophila pathogenicity would be facilitated with an efficient mutagen that can not only mark genomic mutations, but can also be used to reflect gene expression during macrophage infection. A derivative of Jn903, Tn903dlllacZ, is shown to transpose with high efficiency in L. pneumophila. Tn903dlllacZ encodes resistance to kanamycin (Km^R) and carries a 5’truncated lacZ gene that can form translational fusions to L. pneumophila genes upon transposition. The cls-acting Tn903 transposase is supplied outside Tn903dlllacZ, and hence chromosomally integrated copies are stable. Km^R LacZ⁺ insertion mutants of L. pneumophila were isolated and shown by DNA hybridization to carry a single Tn903dlllacZ inserted within their chromosomes at various locations. One particular Km^R LacZ⁺ mutant, AB1156, does not produce the brown pigment (Pig) characteristic of Legionella species. Tn903dlllacZ is responsible for this phenotype since reintroduction of the transposonlinked mutation into a wild-type background results in a Pig phenotype. L. pneumophila pigment production is normally observed in stationary-phase growth of cells in culture, and β-galactosidase activity measured from the pig::lacZ fusion increased during the logarithmic-phase growth and peaked at the onset of stationary phase. Interestingly, pig::lacZ expression also increased during macrophage infection. The pigment itself, however, does not appear to be required for L. pneumophila to grow within or kill host macrophages.     

An rne-1 pnp-7 Double Mutation Suppresses the Temperature-Sensitive Defect of lacZ Gene Expression in a divE Mutant

A divE mutant, which has a temperature-sensitive mutation in the tRNA₁^Ser gene, exhibits differential loss of the synthesis of certain proteins, such as β-galactosidase and succinate dehydrogenase, at nonpermissive temperatures. In Escherichia coli, the UCA codon is recognized only by tRNA₁^Ser. Several genes containing UCA codons are normally expressed after a temperature shift to 42°C in the divE mutant. Therefore, it is unlikely that the defect in protein synthesis at 42°C is simply caused by a defect in the decoding function of the mutant tRNA₁^Ser. In this study, we sought to determine the cause of the defect in lacZ gene expression in the divE mutant. It has also been shown that the defect in lacZ gene expression is accompanied by a decrease in the amount of lacZ mRNA. To examine whether inactivation of mRNA degradation pathways restores the defect in lacZ gene expression, we constructed divE mutants containing rne-1, rnb-500, and pnp-7 mutations in various combinations. We found that the defect was almost completely restored by introducing an rne-1 pnp-7 double mutation into the divE mutant. Northern hybridization analysis showed that the rne-1 mutation stabilized lacZ mRNA, whereas the pnp-7 mutation stabilized mutant tRNA₁^Ser, at 44°C. We present a mechanism that may explain these results.