Conserved polar loop region of Escherichia coli subunit c of the F1F0 H+-ATPase. Glutamine 42 is not absolutely essential, but substitutions alter binding and coupling of F1 to F0

The uncE114 mutation (Gln42----Glu) in subunit c of the Escherichia coli H+ ATP synthetase causes uncoupling of proton translocation from ATP hydrolysis (Mosher, M. E., White, L. K., Hermolin, J., and Fillingame, R. H. (1985) J. Biol. Chem. 260, 4807-4814). In the background of strain ER, the mutation led to dissociation of F1 from the membrane. Ten revertants to the uncE114 mutation were isolated, and the uncE gene was cloned and sequenced. Six of the revertants were intragenic and had substitutions of glycine, alanine, or valine for the mutant glutamate residue at position 42. The intragenic, revertant uncE genes were incorporated into an otherwise wild type chromosome of strain ER. Membrane vesicles prepared from each of the revertants showed a restoration of F1 binding to F0. The Val42 revertant differed from the other two revertants in that the ATPase activity of F1 was inhibited when membrane bound. This was shown by the stimulation of ATPase activity when F1 was released from the membrane. The Gly42 and Ala42 revertants demonstrated membrane ATPase activity that was resistant to dicyclohexylcarbodiimide treatment. Resistance was shown to be due to the increased dissociation of F1 from the membrane under ATPase assay conditions. The Ala42 revertant showed a significant reduction in ATP-dependent quenching of quinacrine fluorescence that was attributed to less efficient coupling of ATP hydrolysis to H+ translocation, whereas the other revertants showed responses very near to that of wild type. Minor changes in the F1-F0 interaction in all three revertants were indicated by an increase in H+ leakiness, as judged by reduced NADH-dependent quenching of quinacrine fluorescence. The minor defects in the revertants support the idea that residue 42 is involved in the binding and coupling of F1 to F0 but also show that the conserved glutamine (or asparagine) is not absolutely necessary in this function.     

Possible salt bridges between transmembrane alpha-helices of the lactose carrier of Escherichia coli.

Although it is energetically extremely unfavorable to have charged amino acid residues of a polypeptide in the hydrophobic environment of the membrane phospholipid bilayer, a few such charged residues are found in membrane-spanning regions of membrane proteins. Ion pairs (salt bridges) would be much more stable in low dielectric media than single ionized residues. This paper provides indirect evidence for a salt bridge between Asp-240 and Lys-319 in the lactose carrier of Escherichia coli. When Asp-240 was changed to alanine by site-directed mutagenesis, there was a loss of the ability to accumulate methyl-beta-D-thiogalactopyranoside (TMG), melibiose, or lactose. Fast-growing revertants were isolated on melibiose minimal agar plates. Two second-site revertants were isolated: Asp-240-->Ala plus Gly-268-->Val and Asp-240-->Ala plus Lys-319-->Gln. These revertants showed extremely poor accumulation of TMG, melibiose, and lactose, but showed significant "downhill" lactose entry into beta-galactosidase-containing cells with sugar concentrations of 2 and 5 mM. It is concluded that there is some important interaction between Asp-240 and Lys-319, possibly a salt bridge.     

Temperature-Sensitive Pleiotropic Revertants from a Mutant in the AROM Gene Cluster of NEUROSPORA CRASSA

Genetical and biochemical studies have been performed with revertants induced in a polyaromatic mutant (No. 58) in the arom gene cluster of Neurospora crassa. In addition to complete and partial revertants able to grow on minimal at both 25 degrees and 35 degrees , temperature-sensitive revertants capable of growth on minimal at 25 degrees but not at 35 degrees have been recovered. One of these revertants has been shown to lack biosynthetic dehydroquinase activity at both temperatures (utilizing the inducible catabolic isozyme for growth at 25 degrees ), to have dehydroshikimate reductase activity only at 25 degrees , and to form an arom aggregate having a molecular weight approximately one-half that of wild type. These results are interpreted as indicating that pleiotropic mutants in the arom gene cluster can result from missense mutations, as well as from nonsense mutations as indicated in previous studies.     

Oxidative Metabolism of a Pigmented Mutant of Rhizobium meliloti and its Revertants

Non-infective pigmented mutants of Rhizobium meliloti have been obtained by u.v. irradiation. The majority of colourless revertants of a pigmented mutant obtained by u.v. irradiation nodulated the host plant indicating that pigmentation in rhizobium and ability to nodulate are genetically linked and may have some pleiotrophic effect. All the nodulating revertants and the parent strain oxidized pentoses, hexoses, dihexoses, tricarboxylic acid (TCA) cycle intermediates and related compounds at a higher rate than the non-nodulating revertants and pigmented mutant. Significant differences in the oxidation of pentoses and TCA cycle intermediates in nodulating and non-nodulating revertants indicate that these two energy yielding pathways are operating less efficiently in non-nodulating revertants and suggests that the working of these two pathways may be essential for the nodulation process.     

Cysteine mutagenesis of the amino acid residues of transmembrane helix I in the melibiose carrier of Escherichia coli

The melibiose carrier of Escherichia coli is a sugar-cation cotransport system that utilizes Na(+), Li(+), or H(+). This membrane transport protein consists of 12 transmembrane helices. Starting with the cysteine-less melibiose carrier, cysteine has been substituted individually for amino acids 17-37, which includes all of the residues in membrane helix I. The carriers with cysteine substitutions were studied for their transport activity and the effect of the water soluble sulfhydryl reagent p-chloro- mercuribenzenesulfonic acid (PCMBS). Cysteine substitution caused loss of transport activity in six of the mutants (G17C, K18C, D19C, Y32C, T34C, and D35C). PCMBS caused greater than 50% inhibition in eleven mutants (F20C, A21C, I22C, G23C, I24C, V25C, Y26C, M27C, Y28C, M30C, and Y31C). We suggest that the residues whose cysteine derivatives were inhibited by PCMBS face the aqueous channel and that helix I is completely surrounded by aqueous environment. Second site revertants were isolated from K18C and Y31C. The revertants were found to have mutations in helices I, IV, and VII.     

A mitochondrial ribosomal RNA mutation and its nuclear suppressors

Summary We have isolated cold-resistant revertants from a mitochondrial cold-sensitive mutation, cs909, localized in the 21S ribosomal RNA gene.Two types of revertants have been isolated: (1) strong revertants which were shown to be due to a single, nuclear, dominant suppressor; (2) weak revertants which are all due to the presence of a single, nuclear, recessive suppressor.The recessive suppressor, when separated from the mitochondrial mutation, itself confers a cold-sensitive phenotype, that is, there is a mutual suppression between the mitochondrial cold-sensitive mutation and the nuclear cold-sensitive mutation. The suppressor by itself produces modified ribosomes and therefore probably codes for an element of the mitochondrial ribosome such as a ribosomal protein.     

Structure-function relationships of a membrane pore forming toxin revealed by reversion mutagenesis

Cyt2Aa1 is a haemolytic membrane pore forming toxin produced by Bacillus thuringiensis subsp. kyushuensis. To investigate membrane pore formation by this toxin, second-site revertants of an inactive mutant toxin Cyt2Aa1-I150A were generated by random mutagenesis using error-prone PCR. The decrease in side chain length caused by the replacement of isoleucine by alanine at position 150 in the alphaD-beta4 loop results in the loss of important van der Waals contacts that exist in the native protein between I150 and K199 and L203 on alphaE. 28 independent revertants of I150A were obtained and their relative toxicity can be explained by the position of the residue in the structure and the effect of the mutation on side-chain interactions. Analysis of these revertants revealed that residues on alphaA, alphaB, alphaC, alphaD and the loops between alphaA and alphaB, alphaD and beta5, beta6 and beta7 are important in pore formation. These residues are on the surface of the molecule suggesting that they may participate in membrane binding and toxin oligomerization. Changing the properties of the amino acid side-chains of these residues could affect the conformational changes required to transform the water-soluble toxin into the membrane insertion competent state.     

Stability of deletion,insertion and point mutations at the bronze locus in maize

Summary Phenotypic revertants from several kinds of mutations, including deletions, have been detected by pollen analysis at the wx and Adh loci in maize. Mutations in these genes give phenotypic revertants with median frequencies of 0.7 and 0.5×10^–5, respectively. However, the nature of such revertants can only be analyzed following their recovery from conventional matings. In the current study large seed populations derived from crosses involving several bz (bronze) locus mutations in maize were examined for reversion to a Bz (purple) expression. Deletion, insertion and point mutations were included in the study. Principally, over 2 million gametes of the bz-R mutation, which is shown here to be associated with a 340 base pair deletion within the transcribed region of the gene, have been screened for reversion. No revertants from it or any of the other bz mutations have been recovered, even though a total of almost 5 million gametes from homoallelic crosses have been examined to date. Results from seed analysis are discussed in reference to those from pollen analysis in maize.     

Double-strand break repair and G2 block in Chinese hamster ovary cells and their radiosensitive mutants

Two X-ray-sensitive mutants of the CHO K1 cell line were examined for their cell-cycle progression after irradiation with gamma-rays, and for their ability to rejoin double-strand breaks (DSBs) as detected by neutral filter elution. Both mutants were impaired in DSB rejoining and both were irreversibly blocked in the G2 phase of the cell cycle as determined by cytofluorometry. From one mutant we have isolated several revertants. The revertants stem from genomic DNA transfection experiments and may have been caused by gene uptake. All revertants survived gamma-irradiation as did the wild-type CHO line. One of them has been examined for its ability to rejoin DSBs and was found to be similar to the wild type.     

Tn916-induced mutations in the hemolysin determinant affecting virulence of Listeria monocytogenes.

A genetic determinant essential for hemolysin production by Listeria monocytogenes has been inactivated by insertion of transposon Tn916 into L. monocytogenes DNA. The transposon was transferred by means of conjugation of a streptomycin-resistant L. monocytogenes recipient strain with Streptococcus faecalis CG110 on membrane filters. Among the tetracycline-resistant transconjugants, mutants were detected which had lost hemolytic activity. When tested in a mouse model, these mutants appeared to have lost the virulence that characterizes the parental strain. An extracellular protein of 58,000 apparent molecular weight was eliminated in the nonhemolytic mutants. In some of the mutants, the decrease in the production of the 58,000-dalton protein was accompanied by the production of a new protein of 49,000 apparent molecular weight. Hemolytic revertants regained the hemolytic phenotype and virulence and produced the extracellular protein that characterizes the recipient strain. Hybridization studies with Tn916 DNA indicated that the transposon is present in EcoRI and HindIII fragments of the nonhemolytic mutants. Single copies of Tn916 were detected in the chromosomal DNA of two of the three nonhemolytic mutants that were studied in detail. In hemolytic, tetracycline-sensitive revertants Tn916 appeared to be completely excised from the chromosome.     

Revertants of pleiotropic cross resistance and collateral sensitivity in yeast: A multivariate analysis

Summary Five different selective media (Table 2) were used to isolate revertants of a pleiotropic cross resistant and collaterally sensitive strain of yeast. Of the 2676 revertants isolated, 1542 were visually classified as complete revertants, 238 as dauermodifications and 896 as partial revertants. Growth of the 896 partial revertants was evaluated on 24 diagnostic media (Table 1). Multivariate classification of revertant growth (Fig. 1) arranged the revertants into 9 groups and the media into two major groups (Table 4). The identification of two groups of media was consistent with the notion of a single gene alteration of mitochondrial and plasma membrane function in the original mutant strain. The 9 revertant groups had phenotypes suggesting pseudo-wild type (1 group), pseudo-mutant type (2 groups), loss of collateral sensitivity (2 groups), loss of cross resistance (1 group) and loss of different aspects of the resistance phenotype (3 groups). One of the latter 3 groups had a phenotype similar to strains reported by Guerineau et al. (Biochem. Biophys. Res. Commun. 61, 462) to be deficient in 2 DNA. The five media used to select revertants enriched for different groups within the 9 different groups of revertants (Table 5). The multivariate analyses used in this paper would be of general use in the analysis of other complex pleiotropic phenotypes.     

Evidence for coupling between membrane and cytoplasmic domains of the yeast plasma membrane H(+)-ATPase. An analysis of intragenic revertants of pma1-105.

A genetic approach was used to identify interacting portions of the plasma membrane H(+)-ATPase from Saccharomyces cerevisiae. The cellular sensitivity of the pma1-105 strain (S368F) to low external pH and to NH4+ was used to select intragenic revertants of two classes: phenotypically wild-type full revertants and partial revertants that were low pH-resistant but retained resistance to hygromycin B. All 10 full revertants had S368 restored. Among five partial revertants mapping to the original site within the phosphorylation domain, S368L and S368V were each found twice. One revertant contained an E367V substitution adjacent to the original S368F alteration. Four of 13 independently isolated second-site revertants mapped to one site, V289F, in the proposed phosphatase domain. Mutations within the proposed phosphatase and phosphorylation domains resulted in enzymes with increased vanadate sensitivity relative to the vanadate-insensitive S368F enzyme. These results suggest that sites S368, E367, and V289 contribute to a vanadate (Pi) binding domain or are able to interact with such a site within the catalytic domain. The remaining nine partial second-site revertants mapped to six sites within the putative transmembrane regions. Mutations within the transmembrane region had less of an effect on vanadate sensitivity. Most revertant enzymes showed small but significant increases in the rate of ATP hydrolysis relative to the S368F enzyme. Several enzymes no longer displayed the acid-sensitive pH-dependence seen in the S368F enzyme. These data provide novel evidence for an interaction between putative transmembrane helices 1-3 and 7 and the ATP hydrolytic portion of the enzyme.     

The interaction between aspartic acid 237 and lysine 358 in the lactose carrier of Escherichia coli.

The lacY from Escherichia coli strains 020 and AE43 have been cloned on plasmids which were designated p020-K358T and pAE43-D237N. These lacY mutants contain amino acid substitutions changing Lys-358 to Thr or Asp-237 to Asn, respectively. The charge neutralizing effect of each mutation is associated with a functional defect in melibiose transport which we exploited in order to isolate second site revertants to the melibiose-positive phenotype. Eleven melibiose-positive revertants of p020-K358T were isolated. All contained a second-site mutation converting Asp-237 to a neutral amino acid (8 to Asn, 1 to Gly, and 2 to Tyr). Twelve melibiose-positive revertants of pAE43-D237N were isolated. Two were second-site revertants converting Lys-358 to a neutrally Gln residue, while the remainder directly reverted Asn-237 to the wild-type Asp-237. We conclude that the functional intimate relationship between Asp-237 and Lys-358 suggests that these residues may be closely juxtaposed in three-dimensional space, possibly forming a 'charge-neutralizing' salt bridge.     

Structure-function relationships of a membrane pore forming toxin revealed by reversion mutagenesis

Cyt2Aa1 is a haemolytic membrane pore forming toxin produced by Bacillus thuringiensis subsp. kyushuensis. To investigate membrane pore formation by this toxin, second-site revertants of an inactive mutant toxin Cyt2Aa1-I150A were generated by random mutagenesis using error-prone PCR. The decrease in side chain length caused by the replacement of isoleucine by alanine at position 150 in the αD-β4 loop results in the loss of important van der Waals contacts that exist in the native protein between I150 and K199 and L203 on αE. 28 independent revertants of I150A were obtained and their relative toxicity can be explained by the position of the residue in the structure and the effect of the mutation on side-chain interactions. Analysis of these revertants revealed that residues on αA, αB, αC, αD and the loops between αA and αB, αD and β5, β6 and β7 are important in pore formation. These residues are on the surface of the molecule suggesting that they may participate in membrane binding and toxin oligomerization. Changing the properties of the amino acid side-chains of these residues could affect the conformational changes required to transform the water-soluble toxin into the membrane insertion competent state.     

Isolation and characterization of revertants of the mammalian temperature sensitive leucyl-tRNA synthetase mutant tsHl.

Nine spontaneous and seven ethyl methanesulfonate induced revertants of the Chinese hamster ovary cell line mutant (tsHl), which possesses a temperature sensitive leucyl-tRNA synthetase, were isolated and characterized with respect to growth rate, leucyl-tRNA synthetase activity and thermolability, intracellular leucine pool size, and rRNA content. Although most revertants had increased leucyl-tRNA synthetase activity, and of those tested, all but one had increased thermostability, each appears to be unique. One revertant may be an intergenic suppressor since it appears to contain an elevated level of tsHl-like synthetase. There was no evidence for any of the revertants having increased rRNA and tRNA contents, however, many showed leucine pools two to three times larger than wild type cells. Since similar increases have been observed in tsHl cells they are believed to result from regulation of leucine pool size by the leucyl-tRNA synthetase and are of a magnitude sufficient to affect significantly the growth of revertants at 38.5 degrees C.     

Pseudomonas aeruginosa outer membrane permeability: isolation of a porin protein F-deficient mutant.

A mutant of Pseudomonas aeruginosa severely deficient in outer membrane protein F levels was isolated by screening heavily mutagenized strains for membrane protein alterations on sodium dodecyl sulphate-polyacrylamide gel electrophoresis. To provide a basis for phenotypic comparison, three independent spontaneous revertants with normal protein F levels were isolated. Neither the protein F-deficient mutant nor its revertants had gross surface alterations as judged by their sensitivities to 31 phages with diverse receptors and their low degrees of leakage of periplasmic beta-lactamase into the supernatant. Outer membrane permeability was measured in whole cells by examining the rates of hydrolysis of a chromogenic beta-lactam, nitrocefin, by periplasmic RP1-encoded beta-lactamase. It was found that the outer membrane permeabilities of wild-type and protein F revertant strains were similar, but low when compared with those of Escherichia coli and an antibiotic-supersusceptible mutant Z61 of P. aeruginosa. The loss of protein F caused a further significant decrease in outer membrane permeability. The results suggest that protein F is a pore-forming protein in vivo and that only a small proportion, as few as 1 in 400, of the protein F molecules form active functional channels in vivo.     

Nonsense suppression in a multiauxotrophic derivative of Escherichia coli 15T-: identification and consequences of an amber triplet in the deoxyribomutase gene

Previously, arginine revertants of Escherichia coli WWU, a derivative of E. coli 15T(-), have been subdivided by two independent methods: (i) the streak morphology on nutrient agar, and (ii) the pattern of phage growth using amber and ochre mutants of bacteriophage T4. In the first assay, revertants were subdivided into two classes according to the appearance of streaks after incubation on nutrient agar, a thick, even line of growth defining normal revertants and a thin, irregular line defining aberrant revertants. In the second assay, revertants were classified by the suppressors they contained. The present work demonstrates that revertants containing an amber suppressor show the aberrant morphology and are also able to catabolize thymidine for energy and carbon. This is in contrast to the parent WWU containing no suppressor, which shows a normal morphology and cannot utilize thymidine as an energy source. Revertants containing no suppressor, isolated specifically for their ability to catabolize thymidine, show an aberrant morphology. Together, these results indicate that the aberrant morphology results from suppression of an amber triplet in a gene of the thymidine catabolic pathway. Enzyme assays show the amber triplet to be in the gene specifying deoxyribomutase. It is suggested that the aberrant arginine revertants are analogous to high thymine-requiring mutants and that, in general, high and low thymine-requiring mutants differ from one another in their ability to catabolize deoxyribose-1-phosphate.     

Short-term treatment with gamma interferon induces stable reversion of ras-transformed mouse fibroblasts.

Persistent revertants have been generated from NIH 3T3 cells transformed by an activated human Ha-ras gene after short-term gamma interferon treatment in the presence of the cardiac aminoglycoside ouabain. Normal fibroblastlike morphology and anchorage dependence are restored in revertants. Tumorigenicity in nude mice is abolished. The revertants continue to express high steady-state levels of the ras oncogene. Partial retransformation of reverted cells is induced after 5-azacytidine treatment or after infection with retrovirus vectors carrying the v-abl, v-fes, v-myc, or v-src oncogene. The revertants resist the transforming activities of the v-Ha-ras and v-mos oncogenes.