ATP requirement for acidic resistance in Escherichia coli

ATP participates in many cellular metabolic processes as a major substrate to supply energy. Many systems for acidic resistance (AR) under extremely acidic conditions have been reported, but the role of ATP has not been examined. To clarify whether or not ATP is necessary for the AR in Escherichia coli, the AR of mutants deficient in genes for ATP biosynthesis was investigated in this study. The deletion of purA or purB, each of which encodes enzymes to produce AMP from inosinate (IMP), markedly decreased the AR. The content of ATP in these mutants decreased rapidly at pH 2.5 compared to that of the wild type. The AR was again decreased significantly by the mutation of adk, which encoded an enzyme to produce ADP from AMP. The DNA damage in the purA and purB mutants was higher than that in the wild type. These results demonstrated that metabolic processes that require ATP participate in survival under extremely acidic conditions, and that one such system is the ATP-dependent DNA repair system.     

Mutations in the Mitochondrial Atp Synthase Gamma Subunit Suppress a Slow-Growth Phenotype of Yme1 Yeast Lacking Mitochondrial DNA

In Saccharomyces cerevisiae, inactivation of the nuclear gene YME1 causes several phenotypes associated with impairment of mitochondrial function. In addition to deficiencies in mitochondrial compartment integrity and respiratory growth, yme1 mutants grow extremely slowly in the absence of mitochondrial DNA. We have identified two genetic loci that, when mutated, act as dominant suppressors of the slow-growth phenotype of yme1 strains lacking mitochondrial DNA. These mutations only suppressed the slow-growth phenotype of yme1 strains lacking mitochondrial DNA and had no effect on other phenotypes associated with yme1 mutations. One allele of one linkage group had a collateral respiratory deficient phenotype that allowed the isolation of the wild-type gene. This suppressing mutation was in ATP3, a gene that encodes the gamma subunit of the mitochondrial ATP synthase. Recovery of two of the suppressing ATP3 alleles and subsequent sequence analysis placed the suppressing mutations at strictly conserved residues near the C terminus of Atp3p. Deletion of the ATP3 genomic locus resulted in an inability to utilize nonfermentable carbon sources. atp3 deletion strains lacking mitochondrial DNA grew slowly on glucose media but were not as compromised for growth as yme1 yeast lacking mitochondrial DNA.     

Adenylate kinases from thermosensitive Escherichia coli strains

The adk genes from several thermosensitive (ts) mutants of Escherichia coli were cloned and sequenced. The mutations responsible for the thermolability of the gene product, the enzyme adenylate kinase, were established. From five independently isolated strains analysed, two contain a CCG to TCG transition changing proline 87 to serine (P87S), another two have a TCT to TTT transition that mutates serine 129 to phenylalanine (S129F), and the last one was found not to contain a mutation in the adk gene. Overproducing strains were constructed that contain ts genes in the genome as well as in the plasmids. These strains grow at high temperature, although much slower than wild-type. Most probably, the high rate of synthesis of adenylate kinase compensates for the destruction of the thermolabile protein by the elevated temperature. Mutated proteins were purified. The P87S but not the S129F mutation was found to cause thermosensitivity of the adenylate kinase reaction. Revertants of thermosensitivity were isolated and the nature of the mutation was determined by the RNase digestion method of RNA-DNA hybrids and by DNA sequencing. The revertants of the P87S mutation regained the wild-type sequence, whereas the revertants of the S129F strain retained the original mutation in the adenylate kinase gene. These results are discussed in the light of the three-dimensional structure of the enzyme and the possible role of adenylate kinase in phospholipid synthesis.     

Mutations of putP that alter the lithium sensitivity of Salmonella typhimurium

The putP gene encodes the major proline permease in Salmonella typhimurium that couples transport of proline to the sodium electrochemical gradient. To identify residues involved in the cation binding site, we have isolated putP mutants that confer resistance to lithium during growth on proline. Wild-type S. typhimurium can grow well on proline as the sole carbon source in media supplemented with NaCl, but grows poorly when LiCl is substituted for NaCl. In contrast to the growth phenotype, proline permease is capable of transporting proline via Na+/proline or Li+/proline symport. Therefore, we selected mutants that grow well on media containing proline as the sole carbon source in the presence of lithium ions. All of the mutants assayed exhibit decreased rates of Li+/proline and Na+/proline cotransport relative to wild type. The location of each mutation was determined by deletion mapping: the mutations cluster in two small deletion intervals at the 5' and 3' termini of the putP gene. The map positions of these lithium resistance mutations are different from the locations of the previously isolated substrate specificity mutations. These results suggest that Lir mutations may define domains of the protein that fold to form the cation binding site of proline permease.     

Single point mutations in either gene encoding the subunits of the heterooctameric yeast phosphofructokinase abolish allosteric inhibition by ATP

Yeast phosphofructokinase is a heterooctameric enzyme subject to a complex allosteric regulation. A mutation in the PFK1 gene, encoding the larger -subunits, rendering the enzyme insensitive to allosteric inhibition by ATP was found to be caused by an exchange of proline 728 for a leucine residue. By in vitro mutagenesis, we introduced this mutation in either PFK1 or PFK2 and found that the exchange in either subunit drastically reduced the sensitivity of the holoenzyme to ATP inhibition. This was accompanied by a lack of allosteric activation by AMP, fructose 2,6-bisphosphate, or ammonium and an increased resistance to heat inactivation. Yeast cells carrying either one mutation or both in conjunction did not display a strong phenotype when grown on fermentable carbon sources and did not show any significant changes in intermediary metabolites. Growth on non-fermentable carbon sources was clearly impaired. The strain carrying both mutant alleles was more sensitive to Congo Red than the wild-type strain or the single mutants indicating differences in cell wall composition. In addition, we found single pfk null mutants to be less viable than wild type at different storage temperatures and a pfk2 null mutant to be temperature-sensitive for growth at 37 degrees C. The latter mutant was shown to be respiration-dependent for growth on glucose.     

Role of adenosine kinase in the control of Streptomyces differentiations: Loss of adenosine kinase suppresses sporulation and actinorhodin biosynthesis while inducing hyperproduction of undecylprodigiosin in Streptomyces lividans

Adenosine kinase (ADK) catalyses phosphorylation of adenosine (Ado) and generates adenosine monophosphate (AMP). ADK gene (adk(Sli), an ortholog of SCO2158) was disrupted in Streptomyces lividans by single crossover-mediated vector integration. The adk(Sli) disruption mutant (Deltaadk(Sli)) was devoid of sporulation and a plasmid copy of adk(Sli) restored sporulation ability in Deltaadk(Sli), thus indicating that loss of adk(Sli) abolishes sporulation in S. lividans. Ado supplementation strongly suppressed sporulation ability in S. lividans wild-type (wt), supporting that disruption of adk(Sli) resulted in Ado accumulation, which in turn suppressed sporulation. Cell-free experiments demonstrated that Deltaadk(Sli) lacked ADK activity and in vitro characterization confirms that adk(Sli) encodes ADK. The intracellular level of Ado was highly elevated while the AMP level was significantly reduced after loss of adk(Sli) while Deltaadk(Sli) displayed no significant derivation from wt in the levels of S-adenosylhomocysteine (SAH) and S-adenosylmethionine (SAM). Notably, Ado supplementation to wt lowered AMP content, albeit not to the level of Deltaadk(Sli), implying that the reduction of AMP level is partially forced by Ado accumulation in Deltaadk(Sli). In Deltaadk(Sli), actinorhodin (ACT) production was suppressed and undecylprodigiosin (RED) production was dramatically enhanced; however, Ado supplementation failed to exert this differential control. A promoter-probe assay verified repression of actII-orf4 and induction of redD in Deltaadk(Sli), substantiating that unknown metabolic shift(s) of ADK-deficiency evokes differential genetic control on secondary metabolism in S. lividans. The present study is the first report revealing the suppressive role of Ado in Streptomyces development and the differential regulatory function of ADK activity in Streptomyces secondary metabolism, although the underlying mechanism has yet to be elucidated.     

cysQ, a gene needed for cysteine synthesis in Escherichia coli K-12 only during aerobic growth.

The initial steps in assimilation of sulfate during cysteine biosynthesis entail sulfate uptake and sulfate activation by formation of adenosine 5'-phosphosulfate, conversion to 3'-phosphoadenosine 5'-phosphosulfate, and reduction to sulfite. Mutations in a previously uncharacterized Escherichia coli gene, cysQ, which resulted in a requirement for sulfite or cysteine, were obtained by in vivo insertion of transposons Tn5tac1 and Tn5supF and by in vitro insertion of resistance gene cassettes. cysQ is at chromosomal position 95.7 min (kb 4517 to 4518) and is transcribed divergently from the adjacent cpdB gene. A Tn5tac1 insertion just inside the 3' end of cysQ, with its isopropyl-beta-D-thiogalactopyranoside-inducible tac promoter pointed toward the cysQ promoter, resulted in auxotrophy only when isopropyl-beta-D-thiogalactopyranoside was present; this conditional phenotype was ascribed to collision between converging RNA polymerases or interaction between complementary antisense and cysQ mRNAs. The auxotrophy caused by cysQ null mutations was leaky in some but not all E. coli strains and could be compensated by mutations in unlinked genes. cysQ mutants were prototrophic during anaerobic growth. Mutations in cysQ did not affect the rate of sulfate uptake or the activities of ATP sulfurylase and its protein activator, which together catalyze adenosine 5'-phosphosulfate synthesis. Some mutations that compensated for cysQ null alleles resulted in sulfate transport defects. cysQ is identical to a gene called amtA, which had been thought to be needed for ammonium transport. Computer analyses, detailed elsewhere, revealed significant amino acid sequence homology between cysQ and suhB of E. coli and the gene for mammalian inositol monophosphatase. Previous work had suggested that 3'-phosphoadenoside 5'-phosphosulfate is toxic if allowed to accumulate, and we propose that CysQ helps control the pool of 3'-phosphoadenoside 5'-phosphosulfate, or its use in sulfite synthesis.     

Glycine betaine loses its osmoprotective activity in a bspA strain of Erwinia chrysanthemi

Erwinia chrysanthemi insertion mutants were isolated that grew poorly specifically in the presence of glycine betaine (GB) or its analogues in high-salt media. Transposon insertions were found to affect the bspA gene, which forms an operon including the psd locus coding for phosphatidylserine decarboxylase. Initial GB uptake is not affected by the bspA mutation. However, in high-salt medium, its initial accumulation is followed by a reduced glucose uptake and a release of GB but not a loss of viability. BspA is homologous to the widespread MscS channel, YggB, but does not seem to constitute a mechanosensitive channel. We suggest that BspA is a protein sensing both intracellular GB and the extracellular salt content of the medium, the hypothesis being built on the observation that BspA is necessary to maintain the GB pool during osmoadaptation in high-salt media containing this osmoprotectant.     

Cloning and sequencing of the adenylate kinase gene (adk) of Escherichia coli.

Adenylate kinase, the product of the adk locus in Escherichia coli K12, catalyzes the conversion of AMP and ATP to two molecules of ADP. The gene has been cloned by complementation of an adk temperature sensitive mutation. The DNA sequence of the complete coding region and of 5'- and 3'-untranslated regions were determined. The resulting protein sequence was found to contain several regions of high homology with cytosolic adenylate kinase of pig muscle (AK1), whose three-dimensional structure has been determined. The most significant of the amino acid exchanges is the replacement of histidine 36 with glutamine. This residue is believed to play a role in catalysis through metal ion binding. The codon usage pattern and the determination of adenylate kinase molecules per cell shows that the enzyme is one of the more abundant soluble proteins of the bacterial cells.     

Multiple biochemical effects of a series of X-ray induced mutations at the albino locus in the mouse

Further studies of the four radiation-induced lethal albino mutations causing glucose 6-phosphatase deficiency in the mouse have shown that there is also a deficiency of tyrosine aminotransferase in the newborn albino mutants. These two enzymes can be induced in fetal and newborn heterozygous or homozygous normal littermate controls by injection of glucagon or dibutyryl cyclic AMP, but not in the albino mutants. Microsomal NADH-cytochrome c reductase was found to be increased in the albino mutants. The multiple biochemical abnormalities in the albino mutants, in addition to the lack of gene dosage effect in the heterozygotes, suggest the involvement of genes other than the structural genes for particular enzymes. When a new radiation-induced lethal albino mutation was tested against the four original alleles, complementation resulted, and double heterozygotes were found to be viable, with normal enzyme levels.Supported by grants from the National Institutes of Health, 5 R01 AM 11448-05, 5R01 HD-00193-17, 5T01 GM00110-09, GM19100, and by a grant from the American Cancer Society, VC-64N.     

The Cpx proteins of Escherichia coli K-12: evidence that cpxA, ecfB, ssd, and eup mutations all identify the same gene.

An existing cpxA(Ts) mutant was resistant to amikacin at levels that inhibited completely the growth of a cpxA+ and a cpxA deletion strain and failed to grow as efficiently on exogenous proline. These properties are similar to those of mutants altered in a gene mapped to the cpxA locus and variously designated as ecfB, ssd, and eup. The amikacin resistance phenotype of the cpxA mutant was inseparable by recombination from the cpxA mutant phenotype (inability to grow at 41 degrees C without exogenous isoleucine and valine) and was recessive to the cpxA+ allele of a recombinant plasmid. Using methods that ensured independent mutations in the cpxA region of the chromosome, we isolated six new amikacin-resistant mutants following nitrosoguanidine mutagenesis. Three-factor crosses mapped the mutations to the cpxA locus. When transferred by P1 transduction to a cpxB11 Hfr strain, each of the mutations conferred the Tra- and Ilv- phenotypes characteristic of earlier cpxA mutants. Two of the new mutations led to a significantly impaired ability to utilize exogenous proline, and four led to partial resistance to colicin A. Two of the new cpxA alleles were recessive to the cpxA+ allele, and four were dominant, albeit to different degrees. On the basis of these data, we argue that cpxA, ecfB, eup, and ssd are all the same gene. We discuss the cellular function of the cpxA gene product in that light.     

Regulation of cytoplasmic proline levels in Salmonella typhimurium: effect of osmotic stress on synthesis, degradation, and cellular retention of proline.

I investigated the effects of osmotic stress on the synthesis and catabolism of proline in Salmonella typhimurium by measuring the intracellular and extracellular proline levels in various strains. In the wild-type strain, exposure to 0.8 M NaCl did not cause a significant change in the intracellular proline level; however, it brought about a 6.5-fold increase in the intracellular glutamate pool size. These results indicate that gamma-glutamyl kinase is inhibited by proline in wild-type cells in media of normal or elevated osmolarity. I also tested whether proline is subject to turnover in cells wild type with respect to the enzymes of the proline degradation pathway. In strains that were wild type for proline biosynthesis, the loss of the proline catabolic enzymes, due to putA mutations, did not result in a statistically significant increase in the intracellular proline levels. Therefore, in the wild-type strain, proline turnover does not seem to be important for control of the intracellular proline levels. However, in a proline-overproducing mutant, a putA lesion caused a threefold increase in the intracellular proline level and a 6.5-fold increase in the extracellular proline level, indicating that proline is subject to turnover in the overproducing mutant. The proline-overproducing mutants excreted large quantities of the proline into the culture medium; osmotic stress altered the partitioning of proline such that the ratio of intracellular to extracellular levels of proline increased with increased osmotic stress. The increased cellular retention of proline in media of high osmolarity is probably due to the functioning of the ProP and ProU proline transport systems, which are stimulated under conditions of osmotic stress.     

Proline transport in Salmonella typhimurium: putP permease mutants with altered substrate specificity.

The putP gene encodes a proline permease required for Salmonella typhimurium LT2 to grow on proline as the sole source of nitrogen. The wild-type strain is sensitive to two toxic proline analogs (azetidine-2-carboxylic acid and 3,4-dehydroproline) also transported by the putP permease. Most mutations in putP prevent transport of all three substrates. Such mutants are unable to grow on proline and are resistant to both of the analogs. To define domains of the putP gene that specify the substrate binding site, we used localized mutagenesis to isolate rare mutants with altered substrate specificity. The position of the mutations in the putP gene was determined by deletion mapping. Most of the mutations are located in three small (approximately 100-base-pair) deletion intervals of the putP gene. The sensitivity of the mutants to the proline analogs was quantitated by radial streaking to determine the affinity of the mutant permeases for the substrates. Some of the mutants showed apparent changes in the kinetics of the substrates transported. These results indicate that the substrate specificity mutations are probably due to amino acid substitutions at or near the active site of proline permease.     

Growth, luminescence, respiration, and the ATP pool during autoinduction in Beneckea harveyi.

The bacterial bioluminescence system is unusual because it is self-induced. In the late logarithmic phase of growth, upon the accumulation of an autoinducer, the synthesis of the components of the system is initiated. We were interested in determining what effect this burst of synthesis and activity has on cellular energy metabolism. The ATP pool of the luminous bacterium Beneckea harveyi was found to dip 10- to 20-fold during the luminescence period, while the respiration per unit cell mass (optical density) increased but by much less. The dip in the ATP pool did not occur in four different types of dark mutants, including one that was temperature conditional and another that was conditional upon added cyclic AMP for luminescence. However, it is neither the synthesis nor the activity of luciferase that is responsible for the ATP dip; the dip does not occur in certain dark "aldehyde" mutants which nevertheless synthesize normal levels of luciferase, whereas it does occur at 36 degrees C in a temperature-sensitive luciferase mutant which forms normal levels of inactive luciferase. Results with other aldehyde mutants implicate the pathway involved in the synthesis of the aldehyde factor with the ATP dip.     

Activation of a new proline transport system in Salmonella typhimurium.

Proline uptake can be mediated by three different transport systems in wild-type Salmonella typhimurium: a high-affinity proline transport system encoded by the putP gene and two glycine-betaine transport systems with a low affinity for proline encoded by the proP and proU genes. However, only the PutP permease transports proline well enough t allow growth on proline as a sole carbon or nitrogen source. By selecting for mutations that allow a putP mutant to grow on proline as a sole nitrogen source, we isolated mutants (designated proZ) that appeared to activate a cryptic proline transport system. These mutants enhanced the transport of proline and proline analogs but did not require the function of any of the known proline transport genes. The mutations mapped between 75 and 77.5 min on the S. typhimurium linkage map. Proline transport by the proZ mutants was competitively inhibited by isoleucine and leucine, which suggests that the ProZ phenotype may be due to unusual mutations that alter the substrate specificity of the branched-chain amino acid transport system encoded by the liv genes.     

Positive selection for loss of RpoS function in Escherichia coli

Though RpoS, an alternative sigma factor, is required for survival and adaptation of Escherichia coli under stress conditions, many strains have acquired independent mutations in the rpoS gene. The reasons for this apparent selective loss and the nature of the selective agent are not well understood. In this study, we found that some wild type strains grow poorly in succinate minimal media compared with isogenic strains carrying defined RpoS null mutations. Using an rpoS+ strain harboring an operon lacZ fusion to the highly-RpoS dependent osmY promoter as an indicator strain, we tested if this differential growth characteristic could be used to selectively isolate mutants that have lost RpoS function. All isolated (Suc+) mutants exhibited attenuated beta-galactosidase expression on indicator media suggesting a loss in either RpoS or osmY promoter function. Because all Suc+ mutants were also defective in catalase activity, an OsmY-independent, RpoS-regulated function, it was likely that RpoS activity was affected. To confirm this, we sequenced PCR-amplified products containing the rpoS gene from 20 independent mutants using chromosomal DNA as a template. Sequencing and alignment analyses confirmed that all isolated mutants possessed mutated alleles of the rpoS gene. Types of mutations detected included single or multiple base deletions, insertions, and transversions. No transition mutations were identified. All identified point mutations could, under selection for restoration of beta-galactosidase, revert to rpoS+. Revertible mutation of the rpoS gene can thus function as a genetic switch that controls expression of the regulon at the population level. These results may also help to explain why independent laboratory strains have acquired mutations in this important regulatory gene.     

Major determinants of purine excretion from human lymphoblasts

WI-L2 B lymphoblasts deficient in hypoxanthine-guanine phosphoribosyltransferase (HGPRT) excreted amounts of hypoxanthine two to three times larger than CEM T lymphoblasts deficient in HGPRT, despite similar growth rates. ATP consumption occurred at a higher rate in WI-L2 cells than in CEM cells when cultivated in a glucose-free buffer, because of higher RNA synthesis in WI-L2 cells. The introduction of actinomycin D and azaserine resulted in lower hypoxanthine excretion in WI-L2 cells than in CEM cells, not in parallel with changes of the adenylate pool size. When the energy charge was high, de novo purine synthesis was a major determinant for purine excretion. The adenylate pool ratio (AMP/ATP) change caused by the introduction of oligomycin was greater during ATP depletion and recovery in WI-L2 cells than in CEM cells. WI-L2 cells were observed to have AMP deaminase activity three to four times higher than CEM cells. The major component of AMP deaminase in these cells was liver type. The higher rate of RNA synthesis caused greater changes of (AMP/ATP) and required higher AMP deaminase activity for recovery. When the energy charge was low, AMP deaminase was a major determinant for purine excretion.     

Genetic analysis of Escherichia coli mutants defective in adenylate kinase and sn-glycerol 3-phosphate acyltransferase.

Complementation analysis with independently isolated plA and adk (adenylate kinase) mutants of Escherichia coli showed that all the mutants belong to the same complementation group. The results suggest that the adk (plsA) locus is the structural gene for adenylate kinase.     

Mutations in the Corynebacterium glutamicum proline biosynthetic pathway: a natural bypass of th proA step.

Two chromosomal loci containing the Corynebacterium glutamicum ATCC 17965 proB and proC genes were isolated by complementation of Escherichia coli proB and proC auxotrophic mutants. Together with a proA gene described earlier, these new genes describe the major C. glutamicum proline biosynthetic pathway. The proB and proA genes, closely linked in most bacteria, are in C. glutamicum separated by a 304-amino-acid open reading frame (unk) whose predicted sequence resembles that of the 2-hydroxy acid dehydrogenases. C. glutamicum mutants that carry null alleles of proB, proA, and proC were constructed or isolated from mutagenized cultures. Single proC mutants are auxotrophic for proline and secrete delta1-pyrroline-5-carboxylate, which are the expected phenotypes of bacterial proC mutants. However, the phenotypes or proB and proA mutants are unexpected. A proB mutant has a pleiotropic phenotype, being both proline auxotrophic and affected in cell morphology. Null proA alleles still grow slowly under proline starvation, which suggests that a proA-independent bypass of this metabolic step exists in C. glutamicum. Since proA mutants are complemented by a plasmid that contains the wild-type asd gene of C. glutamicum, the asd gene may play a role in this bypass.