A Mutant of Escherichia coli with a Defect in Energy Metabolism

Turnock, G.; Erickson, Sandra K.; Ackrell, Brian A.C.; Birch, Barbara

doi:10.1099/00221287-70-3-507

Cited by 18 publications

(8 citation statements)

References 8 publications

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“…Alternatively, internalization of the aminoglycoside when bound to a ribosomal site could enhance the protonmotive force due to the electrochemical characteristics of aminoglycosides. An increased rate of streptomycin and gentamicin entry has been shown here to occur with AN120 and apparently in a mutant described by Turnock et al (38,39), so this seems a feasible proposal. Mutants 12,1977 on May 12, 2018 by guest http://aac.asm.org/ (F. L. Jackson, unpublished data) (uncoupled bacteria utilize succinate poorly as an energy source), and loss of permeability control for amino acids and nucleotides (1,18).…”

supporting

confidence: 61%

Effects of Membrane-Energy Mutations and Cations on Streptomycin and Gentamicin Accumulation by Bacteria: a Model for Entry of Streptomycin and Gentamicin in Susceptible and Resistant Bacteria

Bryan

Elzen

1977

Antimicrob Agents Chemother

265

184

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Several mutants of Escherichia coli affecting aerobic energy generation and energization of the bacterial membrane have been examined for their effect on streptomycin and gentamicin accumulation and susceptibility. A heme-deficient mutant (K207) and two mutants [colicin K insensitive] and NR-70) associated with defective aerobic active transport were associated with decreased transport of streptomycin and gentamicin and increased resistance to those antibiotics. These mutants also exhibited increased resistance to several other aminoglycoside antibiotics, but not the aminocyclitol spectinomycin. The same observations were made with a ubiquinone-deficient mutant, but a strA derivative of this mutant was shown additionally to be saturable for streptomycin accumulation at a concentration four or more times lower than that required for saturation of the parent. A mutant uncoupled for adenosine 5'-triphosphate synthesis from electron transport and membrane Mg-adenosine 5'-triphosphatase deficient was hypersensitive to those aminoglycosides tested and spectinomycin, and showed enhanced transport of streptomycin and gentamicin. A variety of compounds structurally related to streptomycin were examined at high concentrations for inhibition of streptomycin uptake in a strA mutant ofE. coli K-12 SA 1306, but no evidence for competition was detected, suggesting the absence of a common transport carrier. Four different divalent cations were shown to inhibit streptomycin and gentamicin accumulation in E. coli K-12 SA 1306. Divalent cations were shown to inhibit uptake of these two drugs in two bacterial species with distinct cell wall structures, Pseudomonas aeruginosa and Staphylococcus aureus, and to inhibit streptomycin uptake in spheroplasts of streptomycin-susceptible and -resistant E. coli. However, calcium had almost no inhibitory effect on streptomycin uptake by the ubiquinone-deficient mutant E. coli AN66. These and previous findings have been used to formulate a model for aminoglycoside entry into bacteria using a low-affinity membranous complex involved in membrane energization that includes respiratory quinones, which probably act to bind and transport aminoglycosides across the cell membrane. This phase of transport is associated with the lowest accumulation rate (termed energy-dependent phase I) that is rate limiting for susceptibility. It is further proposed that subsequent association of the membrane-bound aminoglycoside with higher-affinity binding sites on membrane-associated ribosomes carrying out a normal ribosomal cycle and protein synthesis results in a more rapid transport rate (termed energy-dependent phase II). The increased rate could result from a state of membrane energization analogous to that causing enhanced aminoglycoside transport rates seen in the uncoupled mutant, AN120. How this model explains the mechanism by which enzymatically modified aminoglycosides render cells resistant to unmodified aminoglycosides is also discussed.The action of the aminoglycoside antibiotics cumulation by bacter...

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supporting

confidence: 61%

Effects of Membrane-Energy Mutations and Cations on Streptomycin and Gentamicin Accumulation by Bacteria: a Model for Entry of Streptomycin and Gentamicin in Susceptible and Resistant Bacteria

Bryan

Elzen

1977

Antimicrob Agents Chemother

265

184

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“…A number of mutants ofEscherichia coli have been isolated with a defect in oxidative phosphorylation [1][2][3][4][5][6][7]. The mutants isolated thus far, all map in the same region of the chromosome (73.5 min) and all are affected in the membrane Mg 2÷-Ca 2+ ATPase complex.…”

Section: Introductionmentioning

confidence: 99%

“…The mutants isolated thus far, all map in the same region of the chromosome (73.5 min) and all are affected in the membrane Mg 2÷-Ca 2+ ATPase complex. One class of mutants has been shown to lack ATPase catalytic activity [1,3,5,7], while a second class of mutants retains the ATPase activity [2,4,6], but in a form which is resistant to the energy transfer inhibitor DCCD** [2]. Studies of active transport in mutants of the first class have provided evidence that phosphate-bond energy is not required for the aerobic transport of certain solutes in E. coli [5,8,9].…”

Section: Introductionmentioning

confidence: 99%

Active transport in mutants of Escherichia coli with alterations in the membrane ATPase complex

Kanner

Gutnick

1973

FEBS Letters

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“…Mutants lacking this enzyme were isolated in several laboratories (1)(2)(3)(4)(5)(6)(7). Studies with such mutants have been useful in distinguishing transport systems driven by an energized membrane state from those that require substrate level phosphorylation (8,9).…”

mentioning

confidence: 99%

Purification and Properties of Reconstitutively Active and Inactive Adenosinetriphosphatase from Escherichia coli

Futai

Sternweis

Heppel

1974

Proc. Natl. Acad. Sci. U.S.A.

226

113

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The Mg2+-and Ca"-stimulated ATPase (EC 3.6.1.3; ATP phosphohydrolase) (bacterial coupling factor) was purified from two strains of E. coli by two different procedures: (a) method of Nelson, Kanner, and Gutnick [Proc. Nat. Acad. Sci. USA (1974) 71, 2720-27241 and (b) a modified procedure described in this paper. The ATPase purified from E. coli K12 (X) by the first procedure had 4 subunits (a, ,, -y, and e). It did not bind to a deficient membrane, nor did it reconstitute ATP-driven transhydrogenase activity. Our modified procedure (b) yielded 5 subunits (a, ,, -y, 6, and e). This ATPase could bind to a deficient membrane and reconstitute ATP-driven transhydrogenase. This finding suggests that the 5 subunit is required for the reaction with the membrane. The molecular weight of the 4-subunit ATPase was significantly lower than that of the 5-subunit ATPase, as judged by equilibrium centrifugation. The specific ATPase activities of both preparations were about the same. These two procedures were also applied to E. coli ML308-225.

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A Mutant of Escherichia coli with a Defect in Energy Metabolism

Cited by 18 publications

References 8 publications

Effects of Membrane-Energy Mutations and Cations on Streptomycin and Gentamicin Accumulation by Bacteria: a Model for Entry of Streptomycin and Gentamicin in Susceptible and Resistant Bacteria

Effects of Membrane-Energy Mutations and Cations on Streptomycin and Gentamicin Accumulation by Bacteria: a Model for Entry of Streptomycin and Gentamicin in Susceptible and Resistant Bacteria

Active transport in mutants of Escherichia coli with alterations in the membrane ATPase complex

Purification and Properties of Reconstitutively Active and Inactive Adenosinetriphosphatase from Escherichia coli

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