cysB and cysE mutants of Escherichia coli K12 show increased resistance to novobiocin

Summary Mutations in the cysB and cysE genes of Escherichia coli K12 cause an increase in resistance to the gyrase inhibitor novobiocin but not to coumermycin, acriflavine and rifampicin. This unusual relationship was also observed among spontaneous novobiocin resistant (Nov^r) mutants: 10% of Nov^r mutants isolated on rich (LA) plates with novobiocin could not grow on minimal plates, and among those approximately half were cysB or cysE mutants. Further analyses demonstrated that cysB and cysE negative alleles neither interfere with transport of novobiocin nor affect DNA supercoiling.     

Antibiotic resistant mutants of Escherichia coli K12 show increases in heterologous gene expression

Using a variety of antibiotics, it was found that nine separate isolates of spontaneous antibiotic resistant mutants of Escherichia coli K12 pPSX-vioABCDE overproduce the anti-tumour antibiotic violacein. Subsequent analysis showed that seven of these mutations occurred on the plasmid pPSX-vioABCDE. The other two overproducing strains carried spontaneous chromosomal mutations to lincomycin and kanamycin. The kanamycin resistant mutant of E. coli K12 DH10B (AA23) and a lincomycin resistant mutant of E. coli K12 LE392 (AA24) increased the synthesis of violacein. The plasmid pPSX-vioABCDE opv-1 contains a violacein over-production (opv-1) mutation which when introduced into either E. coli K12 AA23 or AA24, resulted in a hyper-production of violacein. Remarkably, E. coli K12 AA23 pPSX-vioABCDE opv-1 produced 41 times the normal level of violacein. In addition, both E. coli K12 AA23 and E. coli K12 AA24 demonstrated an increase in expression of an alpha amylase gene from Streptomyces lividans and the urease gene cluster from Klebsiella oxytoca. These results suggest that selection of antibiotic resistant mutants can increase heterologous gene expression in E. coli K12. Additionally, the increased expression is a general effect applicable to genes and gene clusters cloned into E. coli K12 from both Gram-positive and Gram-negative bacteria.     

Characterisation of mutants of Escherichia coli K12, selected by resistance to streptozotocin

Summary From cultures of sensitive bacteria, treated with the antibiotic streptozotocin, two classes of resistant mutants can be isolated: 1) mutants, resistant under all the conditions tested to even the highest doses of the antibiotic. These are either pleiotropicdefective, pts-mutants, or more frequently, mutants lacking a transport system (enzyme II^Nag-complex of the PEP-dependent phosphotransferase system) encoded by the gene nagE. This gene is inducible by N-acetyl-glucosamine and seems to be part of the nag operon. The transport system in question is responsible for the uptake of N-acetyl-glucosamine, of D-glucosamine and of streptozotocin; 2) conditional resistant mutants which are unable to energize or to synthesize the streptozotocin transport system under certain growth conditions but do have the transport activity under other conditions. These include a) mutants auxotrophic for amino acids, vitamins, or nucleotides, b) mutants negative or sensitive to carbohydrates in the medium, and c) mutants with defects in energy metabolism such as PEP synthesis.     

tRNA synthetase mutants of Escherichia coli K-12 are resistant to the gyrase inhibitor novobiocin

In previous studies we demonstrated that mutations in the genes cysB, cysE, and cls (nov) affect resistance of Escherichia coli to novobiocin (J. Rakonjac, M. Milic, and D. J. Savic, Mol. Gen. Genet. 228:307-311, 1991; R. Ivanisevic, M. Milic, D. Ajdic, J. Rakonjac, and D. J. Savic, J. Bacteriol. 177:1766-1771, 1995). In this work we expand this list with mutations in rpoN (the gene for RNA polymerase subunit sigma54) and the tRNA synthetase genes alaS, argS, ileS, and leuS. Similarly to resistance to the penicillin antibiotic mecillinam, resistance to novobiocin of tRNA synthetase mutants appears to depend upon the RelA-mediated stringent response. However, at this point the overlapping pathways of mecillinam and novobiocin resistance diverge. Under conditions of stringent response induction, either by the presence of tRNA synthetase mutations or by constitutive production of RelA protein, inactivation of the cls gene diminishes resistance to novobiocin but not to mecillinam.     

Microcin-E492-insensitive mutants of Escherichia coli K12

Mutations in three Escherichia coli K12 genes, tonB, exbB and the newly discovered semA, reduce sensitivity to the low Mr polypeptide antibiotic microcin E492. The products of the tonB and exbB genes were previously shown to be involved in the uptake of siderophore-complexed iron and in the action of a number of colicins. Strains mutated at or close to semA (collectively referred to as sem mutations) remained fully sensitive to these colicins, and grew as well as wild-type strains under conditions of iron starvation. Expression of a number of sem-lacZ operon fusions was not affected by iron limitation, and sem mutations did not affect the production of iron-regulated outer membrane proteins which are known or thought to be involved in iron uptake. Hfr conjugation and P1 phage transduction experiments indicated that semA is located close to pabB at 40 min on the E. coli K12 chromosome. This places semA close to the mng locus, wherein mutations result in decreased manganese sensitivity. However, strains carrying the semA mutation exhibited increased manganese sensitivity.     

Isolation of haemin-requiring mutants of Escherichia coli K12.

Fifty-five haemin-requiring mutants were isolated from haemin-permeable mutants. According to their growth responses to haem precursors and their patterns of porphyrin accumulation, the 55 mutants fell into three groups which were judged to have defects in 5-aminolaevulinate dehydratase, ferrochelatase, and uroporphyrinogen III cosynthase or uroporphyrinogen decarboxylase. In mutants of the group deficient in 5-aminolaevulinate dehydratase, the mutations were adjacent to lac, and evidence is presented that the mutations were in hemB and were commonly deletions extending into proC.     

Mutations to nitrofurantoin and nitrofurazone resistance in Escherichia coli K12

The isolation and properties of nitrofurantoin- and nitrofurazone-resistant mutants have been compared. Nitrofurantoin-resistant mutants were easier to obtain and showed a higher resistance level. There was some cross-resistance at lower drug concentrations but not at higher levels. There was no difference in the UV resistance of most of the mutants obtained although a recB strain, AB2470, did yield nitrofurantoin-resistant mutants with increased UV resistance. This was however the only repair-defective strain which could be mutated to nitrofurantoin resistance. It is suggested that there is a mechanism for nitrofurantoin resistance in Escherichia coli K12 which does not confer resistance to nitrofurazone and which may be associated with the repair of damaged DNA. This mechanism is in addition to that which also confers resistance to nitrofurazone.     

Thiophene-degrading Escherichia coli mutants possess sulfone oxidase activity and show altered resistance to sulfur-containing antibiotics

We have previously isolated mutants of Escherichia coli which show increased oxidation of heterocyclic furan and thiophene substrates. We have now found that strains carrying the thdA mutation express a novel enzyme activity which oxidizes a variety of substrates containing a sulfone (SO2) moiety. Both heterocyclic sulfones (e.g., tetramethylene sulfone) and simple aliphatic sulfones (e.g., ethyl sulfone) were oxidized. The thdA mutants were more resistant than wild-type strains to aromatic sulfone antibiotics such as dapsone. In contrast they showed increased susceptibility to thiolutin, a cyclic antibiotic containing sulfur at the sulfide level of oxidation. Several new thdA mutant alleles were isolated by selecting for increased oxidation of various aliphatic sulfur compounds. These new thdA mutants showed similar sulfone oxidase activity and the same map location (at 10.7 min) as the original thdA1 mutation. The constitutive fadR mutation was required for the phenotypic expression of thdA-mediated oxidation of sulfur compounds. However, the thdA-directed expression of sulfone oxidase activity was not fadR dependent. The thdC and thdD mutations probably protect against the toxicity of thiophene derivatives rather than conferring improved metabolic capability.     

Mutation affecting resistance of Escherichia coli K12 to nalidixic acid

A new mutation, nalD, determining resistance of Escherichia coli to nalidixic acid (NAL) is reported. The nalD mutant described is resistant to NAL at 37 degrees C but sensitive at 30 degrees C. It is defective in penetration of NAL and glycerol through the outer membrane at 37 degrees C. The nalD mutation is located half-way between 89 and 89.5 min on the E. coli genetic map.     

Isolation and characterization of cAMP suppressor mutants of Escherichia coli K12

Summary We have isolated spontaneous and chemically induced revertants of cya mutant strains of Escherichia coli. Three different classes of revertants were obtained. One class consisted of primary site revertants; a second class was pseudorevertants that had phenotypically reverted to wild type but retaining the original cya mutation and the third class of revertants, designated csm, were pseudorevertants hypersensitive to exogenous cAMP. Transductional analysis of the csm mutation indicated the mechanism of suppression in these strains was intergenic. The csm mutation and hypersensitivity to cAMP map in or near the crp gene. Growth of the csm strains of PTS (phosphoenolpyruvate phosphotransferase system) and non-PTS substrates was inhibited by 5 mM cAMP. The csm strains were found to accumulate toxic levels of methylglyocal when grown on non-PTS substrates in the presence of exogenous cAMP. All csm strains were sensitive to catabolite repression mediated by -methylglucoside. Revertants selected as resistant to cAMP fell into four major classes that could be distinguished by their fermentation patterns in the presence and absence of cAMP as well as by their growth response to streptomycin in the presence of cAMP.Paper No. 6623 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, North Carolina 27650, USA     

glnA mutations conferring resistance to methylammonium in Escherichia coli K12

Cells of Escherichia coli K12 were sensitive to 100 mM-methylammonium when cultured under nitrogen limitation, and resistant when grown with an excess of either NH4Cl or glutamine. Glutamine synthetase activity was required for expression of the methylammonium-sensitive phenotype. Mutants were isolated which were resistant to 100 mM-methylammonium, even when grown under nitrogen limitation. P1 bacteriophage transduction and F' complementation analysis revealed that the resistance-conferring mutations mapped either inside the glnA structural gene and/or elsewhere in the E. coli chromosome. Glutamine synthetase was purified from the wild-type and from some of the mutant strains. Strains carrying glnA-linked mutations that were solely responsible for the methylammonium-resistant phenotype yielded an altered enzyme, which was less active biosynthetically with either ammonium or methylammonium as substrate. Sensitivity to methylammonium appeared to be due to synthesis of gamma-glutamylmethylamide by glutamine synthetase, which was synthesized poorly, if at all, by mutants carrying an altered glutamine synthetase enzyme.