Biochemical and genetic study of D-glucitol transport and catabolism in Bacillus subtilis.

The catabolic pathway of D-glucitol (sorbitol) in Bacillus subtilis Marburg 168M is characterized. It includes (i) a transport step catalyzed by a D-glucitol permease which is affected by the gutA mutations, (ii) an oxidation step of the intracellular D-glucitol catalyzed by a D-glucitol dehydrogenase, generating intracellular fructose, affected by gutB mutations, and (iii) phosphorylation of the intracellular fructose either at the C1 site or at the C6 site as described previously (A. Delobbe et al., Eur. J. Biochem., 66:485-491, 1976; A. Delobbe et al., EUR. J. Biochem. 51:503-510, 1975). Additional data are given concerning the phosphorylation of fructose by a fructokinase (fructose ATP 6-phosphotransferase), which is affected by the fruC mutation. The isolation of regulatory mutants affected in gutR that synthesize constitutively both the permease and the dehydrogenase indicates the existence of a D-glucitol operon in B. subtilis. Unlike the wild-type strain, these mutants are able to utilize D-xylitol as sole carbon source.     

Characterization of two operons that encode components of fructose-specific enzyme II of the sugar:phosphotransferase system of Streptococcus mutans

Three genes, designated as fruC, fruD and fruI, were predicted to encode polypeptides homologous to fructose-specific enzyme II (II(Fru)) of the phosphoenolpyruvate-dependent sugar:phosphotransferase system, and were cloned from Streptococcus mutans, the primary etiological agent of human dental caries. The fruC and fruD genes encoded domains BC and domain A of II(Fru), respectively. The fruI gene encoded IICBA(Fru). Northern hybridization and slot blot analysis showed that expression of fruI was inducible by sucrose and fructose, while fruCD were expressed constitutively and at much lower levels. Inactivation of either fruI or fruCD alone, or of both fruCD and fruI, had no major impact on growth on fructose at a concentration of 0.5% (w/v). However, when the strains were grown with 0.2% fructose as the sole carbohydrate source, a significant decrease in the growth rate was seen with the fruCD/fruI double mutants. Assays of sugar:phosphotransferase activity showed that the fruCD/fruI double mutants had roughly 30% of the capacity of the wild-type strain to transport fructose via the phosphoenolpyruvate-dependent sugar:phosphotransferase system. Xylitol toxicity assays indicated that the inducible fructose permease was responsible for xylitol transport.     

Fructose utilization and phytopathogenicity of Spiroplasma citri

Spiroplasma citri is a plant-pathogenic mollicute. Recently, the so-called nonphytopathogenic S. citri mutant GMT 553 was obtained by insertion of transposon Tn4001 into the first gene of the fructose operon. Additional fructose operon mutants were produced either by gene disruption or selection of spontaneous xylitol-resistant strains. The behavior of these spiroplasma mutants in the periwinkle plants has been studied. Plants infected via leafhoppers with the wild-type strain GII-3 began to show symptoms during the first week following the insect-transmission period, and the symptoms rapidly became severe. With the fructose operon mutants, symptoms appeared only during the fourth week and remained mild, except when reversion to a fructose+ phenotype occurred. In this case, the fructose+ revertants quickly overtook the fructose- mutants and the symptoms soon became severe. When mutant GMT 553 was complemented with the fructose operon genes that restore fructose utilization, severe pathogenicity, similar to that of the wild-type strain, was also restored. Finally, plants infected with the wild-type strain and grown at 23 degrees C instead of 30 degrees C showed late symptoms, but these rapidly became severe. These results are discussed in light of the role of fructose in plants. Fructose utilization by the spiroplasmas could impair sucrose loading into the sieve tubes by the companion cells and result in accumulation of carbohydrates in source leaves and depletion of carbon sources in sink tissues.     

Mutants of Escherichia coli K-12 with increased resistance to ionizing radiation. VI. Increased radioresistance and heat shock proteins

By means of one-dimensional electrophoresis, it is shown that in radiation-resistant Gamr444 and Gamr445 mutants of Escherichia coli K-12 high-molecular weight heat shock proteins are hyperproduced at 32-37 degrees C and are induced more intensively during heat shock (in comparison to the parental wild-type strain AB1157). When the missense htpR15 mutation of the positive regulatory htpR gene for heat shock proteins was introduced by transduction into the genome of the Gamr444 mutant, its enhanced radiation-resistance disappeared but could be restored upon introduction of pKV3 plasmid bearing the htpR+ gene. These data show that heat shock proteins are participating in the enhanced radioresistance of Gamr mutants.     

Fructose transport in Bacillus subtilis.

The transport of fructose in Bacillus subtilis was studied in various mutant strains lacking the following activities: ATP-dependent fructokinase (fruC), the fructose 1-phosphate kinase (fruB) the phosphofructokinase (pfk), the enzyme I of the phosphoenolpyruvate phosphotransferase system (the thermosensitive mutation ptsI1), and a transport activity (fruA). Combinations of these mutations indicated that the transport of fructose in Bacillus subtilis is tightly coupled to its phosphorylation either in fructose 1-phosphate, identified in vivo and in vitro or in fructose 6-phosphate identified by indirect lines of evidence. These steps of fructose metabolism were shown to depend on the activity of the enzyme I of the phosphoenolpyruvate phosphotransferase systems. The fruA mutations affect the transport of fructose when the bacteria are submitted to catabolite repression. The mutations were localized on the chromosome of Bacillus subtilis in a cluster including the fruB gene. When grown in a medium supplemented by a mixture of potassium glutamate and succinate the fruA mutants are able to carry on the two vectorial metabolisms generating fructose 6-phosphate as well as fructose 1-phosphate. A negative search of strictly negative transport mutants in fruA strains indicated that more than two structural genes are involved in the transport of fructose.     

Escherichia coli dnaK null mutants are inviable at high temperature.

DnaK, a major Escherichia coli heat shock protein, is homologous to major heat shock proteins (Hsp70s) of Drosophila melanogaster and humans. Null mutations of the dnaK gene, both insertions and a deletion, were constructed in vitro and substituted for dnaK+ in the E. coli genome by homologous recombination in a recB recC sbcB strain. Cells carrying these dnaK null mutations grew slowly at low temperatures (30 and 37 degrees C) and could not form colonies at a high temperature (42 degrees C); furthermore, they also formed long filaments at 42 degrees C. The shift of the mutants to a high temperature evidently resulted in a loss of cell viability rather than simply an inhibition of growth since cells that had been incubated at 42 degrees C for 2 h were no longer capable of forming colonies at 30 degrees C. The introduction of a plasmid carrying the dnaK+ gene into these mutants restored normal cell growth and cell division at 42 degrees C. These null mutants showed a high basal level of synthesis of heat shock proteins except for DnaK, which was completely absent. In addition, the synthesis of heat shock proteins after induction in these dnaK null mutants was prolonged compared with that in a dnaK+ strain. The well-characterized dnaK756 mutation causes similar phenotypes, suggesting that they are caused by a loss rather than an alteration of DnaK function. The filamentation observed when dnaK mutations were incubated at a high temperature was not suppressed by sulA or sulB mutations, which suppress SOS-induced filamentation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Positive regulation of amidase synthesis in Pseudomonas aeruginosa.

Mutants of Pseudomonas aeruginosa were isolated that were acetamide-negative in growth phenotype at 41 degrees C and constitutive for amidase synthesis at 28 degrees C. Two mutants were derived from the magno-constitutive amidase mutant PAC111 (C11), and a third from a mutant that had enhanced inducibility by formamide, PAC153 (F6). The three temperature-sensitive mutants produced amidases with the same thermal stabilities as the wild-type enzyme. Cultures growing exponentially at 28 degrees C, synthesizing amidase constitutively, ceased amidase synthesis almost immediately on transfer to 41 degrees C. Cultures growing at 41 degrees C were transferred to 28 degrees C and had a lag of about 0.5 of a generation before amidase synthesis became detectable. Pulse-heating for 10 min at 45 degrees C of a culture growing exponentially at 28 degrees C resulted in a lag of about 0.5 of a generation before amidase synthesis recommenced after returning to 28 degrees C. Acetamide-negative mutants that were unable to synthesize amidase at any growth temperature were isolated from an inducible strain producing the mutant B amidase PAC398 (IB10). Two mutants were examined that gave revertants producing B amidase but with novel regulatory phenotypes. It is suggested that amidase synthesis is regulated by positive control exerted by gene amiR.     

Routes for fructose utilization by Escherichia coli

There are three main routes for the utilization of fructose by Escherichia coli. One (Route A) predominates in the growth of wild-type strains. It involves the functioning of the phosphoenolpyruvate:glycose phosphotransferase system (PTS) and a fructose operon, mapping at min. 48.7, containing genes for a membrane-spanning protein (fruA), a 1-phosphofructose kinase (fruK) and a diphosphoryl transfer protein (fruB), under negative regulation by a fruR gene mapping at min. 1.9. A second route (Route B) also involves the PTS and membrane-spanning proteins that recognize a variety of sugars possessing the 3,4,5-D-arabino-hexoseconfiguration but with primary specificity for mannose(manXYZ), mannitol (mtlA) and glucitol (gutA) and which, if over-produced, can transport also fructose. A third route (Route C), functioning in mutants devoid of Routes A and B, does not involve the PTS: fructose diffuses into the cell via an isoform (PtsG-F) of the major glucose permease of the PTS and is then phosphorylated by ATP and a manno(fructo)kinase (Mak+) specified by a normally cryptic 1032 bp ORF (yajF) of hitherto unknown function (Mak-o), mapping at min. 8.8 and corresponding to a peptide of 344 amino acids. Conversion of the Mak-o to the Mak+ phenotypeinvolves an A24D mutation in a putative regulatory region.     

A mutant of Streptococcus pneumoniae that exhibits thermosensitive penicillin tolerance and the paradoxical effect

Mutants of Streptococcus pneumoniae that contain active autolysin and yet cannot be induced to lyse during treatment with penicillin (Lyt+Tol+ mutants) have been described. We have now shown that these mutants are temperature dependent (32 degrees C); at 37 degrees C these bacteria underwent penicillin-induced lysis. In addition, mutants at the lysis-permissive temperature showed the so-called 'paradoxical response' to penicillin. Temperature shift experiments indicated that the change from tolerant to lytic response or vice versa is a fast process. No differences were detected in autolysin specific activity or in the kinetics of inhibition of protein, peptidoglycan and teichoic acid syntheses in cells treated with penicillin at 32 and 37 degrees C. The results of genetic crosses indicated that the thermosensitivity of penicillin-induced autolysis in the Lyt+Tol+ mutants is not a property of the autolytic enzyme itself. The observations suggest that the thermosensitive process in the mutants represents either a step(s) in autolysin regulation or involves some difference in the structure of the cell walls produced at 32 degrees C versus 37 degrees C.     

Genetic control of galactokinase synthesis in Saccharomyces cerevisiae: evidence for constitutive expression of the positive regulatory gene gal4.

Temperature-sensitive (ts) mutants for the gal80 and gal4 genes of Saccharomyces cerevisiae were isolated and characterized. These mutants were classified into two categories; one showed thermolability (TL) and the other showed temperature-sensitive synthesis (TSS) of the respective products. Both the TL and TSS gal80 mutants are constitutive for galactokinase activity at 35 degrees C and, because they are derived from a dominant super-repressible GAL80s mutant, are uninducible at 25 degrees C. Both the TL and TSS gal4 mutants are galactose negative at 35 degrees C and galactose positive at 25 degrees C. None of the ts gal4 mutations affected the thermolability of galactokinase activity in cell extracts. Induction of galactokinase activity was studied with these mutants. The results indicate that the gal80 gene codes for a repressor and the gal4 gene codes for a positive factor indispensable for the expression of the structural genes or their products. However, striking evidence that the expression of the gal4 gene is constitutive and not under the control of gal80 was provided by a kinetic study with the TL gal4 mutant. The TL gal4 mutant pregrown in glycerol nutrient medium at 35 degrees C showed a prolonged lag period (35 min) in the induction of galactokinase activity at 25 degrees C, whereas the same mutant pregrown at 25 degrees C showed the same lag period as those observed in the wild-type strain and a revertant clone derived from the TL gal4 mutant (15 min).     

Saccharomyces cerevisiae cdc2 mutants fail to replicate approximately one-third of their nuclear genome.

Chromosomal DNA replication was examined in temperature-sensitive mutants of Saccharomyces cerevisiae defective in a gene required for the completion of S phase at the nonpermissive temperature, 37 degrees C. Based on incorporation of radioactive precursors and density transfer experiments, strains carrying three different alleles of cdc2 failed to replicate approximately one-third of their nuclear genome at 37 degrees C. Whole-cell autoradiography experiments demonstrated that 93 to 96% of the cells synthesized DNA at 37 degrees C. Therefore, all cells failed to replicate part of their genome. DNA isolated from terminally arrested cells was of normal size as measured on neutral and alkaline sucrose gradients, suggesting that partially replicated DNA molecules do not accumulate and that DNA strands are ligated properly in cdc2 mutants. In addition, electron microscopic examination of the equivalent of more than one genome's DNA from arrested cells failed to reveal any partially replicated molecules. The sequences which failed to replicate at 37 degrees C were not highly specific; eight different cloned sequences replicated to the same extent as total DNA. The 2-microns plasmid DNA and rDNA replicated significantly less well than total DNA, but approximately one-half of these sequences replicated at 37 degrees C. These observations suggest that cdc2 mutants are defective in an aspect of initiation of DNA replication common to all chromosomes such that a random fraction of the chromosomes fail to initiate replication at 37 degrees C, but that once initiated, replication proceeds normally.     

Defect in expression of heat-shock proteins at high temperature in xthA mutants.

Escherichia coli mutants lacking exonuclease III (xthA) are defective in the induction of heat-shock proteins upon severe heat-shock treatment (upshift from 30 to 50 degrees C) but not mild heat-shock treatment (upshift from 30 to 42 degrees C). We show that this defect is due to the xthA mutation by complementation. Furthermore, increasing the gene dosage of xthA+ prolongs the synthesis of heat shock proteins seen after a shift to 42 degrees C. Increasing the gene dosage of htpR+ partially suppresses the defect of xthA mutants in the synthesis of heat-shock proteins at 50 degrees C. When an xthA strain was incubated at 42 degrees C before a shift to 50 degrees C, it was then able to carry out the synthesis of heat-shock proteins at 50 degrees C.     

Physiological and genetic regulation of the aldohexuronate transport system in Escherichia coli.

In Escherichia coli K-12, the specificity of the aldohexuronate transport system (THU) is restricted to glucuronate and galacturonate. There is a relatively high basal-level activity in uninduced wild-type or isomeraseless strains. Supplementary activity is obtained with the inducers mannonic amide (five-fold), galacturonate (fourfold), fructuronate (fivefold), and tagaturonate (sevenfold). Specific THU- mutants were selected as strains unable to grow on either aldohexuronate but able to grow on fructuronate or tagaturonate. The remaining transport activity in uninduced and induced THU- starins represents less than 20% of that found in the wild type. Conjugation and transduction experiments indicate that all of the THU- mutations are located in a unique locus, exuT, half-way between the tolC (59 min) and argG (61 min) markers. exuT is closely linked to the uxaC-uxaA operon (60 min) and to the regulatory gene exuR (60 min), which controls the above-mentioned operon and the uxaB operon (45 min). Growth on either aldohexuronate and transport activity are fully recovered when exuT mutants are allowed to revert to exuT+ on galacturonate or glucuronate. Reversion on glucuronate alone may lead to the mutational derepression of the 2-keto-3-deoxygluconate transport system, which is uninducible in the wild type, which also takes up glucuronate, and whose structural gene belongs to the kdg regulon. Such strains, which remain unable to grow on galacturonate, are exuT and kdgR (constitutive allele of the regulatory gene kdgR of the kdg regulon). THU activity is superrepressed in an exuR mutant in which the uxaC-uxaA operon and the uxaB operon are superrepressed; exuR+/exuR merodiploids are also superrepressed. In a thermosensitive exuR mutant in which the above-mentioned operons are constitutive at 42 degrees C, the THU activity is fully derepressed at this temperature. On the basis of these and other results, it is concluded that THU is coded for by the structural gene exuT, which is negatively controlled by the exuR gene product and which probably belongs to an operon distinct from the uxaA-uxaC operon.     

Genetic analysis of Escherichia coli K-12 chromosomal mutants defective in expression of F-plasmid functions: identification of genes cpxA and cpxB.

Two temperature-sensitive, chromosomal mutants of Escherichia coli were selected for their inability to express deoxyribonucleic acid donor activity and other activities associated with the conjugative plasmid F. These mutants were also auxotrophic for isoleucine and valine at 41 degrees C. Each mutant strain contained two altered genes: cpxA, located at 88 min on the E. coli K-12 genetic map, and cpxB, located at 41 min. Mutations in both genes were required for maximal expression of mutant phenotypes. The parent strain of mutants KN401 and KN312 already contained the cpxB mutation that is present in both mutants (cpxB1). This mutation by itself was cryptic. The cpxA mutations represent different mutant alleles since they are of independent origin. A cpxA mutation by itself significantly affected the expression of plasmid functions and growth at 41 degrees C in the absence of isoleucine and valine, but strains containing both a cpxA and cpxB mutation were more severely affected. Along with the observation that both cpxA mutations were revertable, the temperature sensitivity of cpxA cpxB+ cells suggests that both cpxA alleles contain point mutations that do not completely destroy the activity of the cpxA gene product.     

Bacteriophage T4 gol site: sequence analysis and effects of the site on plasmid transformation.

The Escherichia coli lit gene product is required for the multiplication of bacteriophage T4 at temperatures below 34 degrees C. After infection of a lit mutant host, early gene product synthesis is normal, as is T4 DNA replication; however, the late gene products never appear, and early gene product synthesis eventually ceases. Consequently, at late times, there is no protein synthesis of any kind (W. Cooley, K. Sirotkin, R. Green, and L. Snyder, J. Bacteriol. 140:83-91, 1979; W. Champness and L. Snyder, J. Mol. Biol. 155:395-407, 1982), and no phage are produced. We have isolated T4 mutants which can multiply in lit mutant hosts. The responsible T4 mutations (called gol mutations) completely overcome the block to T4 gene expression (Cooley et al., J. Bacteriol. 140:83-91). We have proposed that gol mutations alter a cis-acting regulatory site on T4 DNA rather than a diffusible gene product and that the wild-type form of the gol site (gol+) somehow interferes with gene expression late in infection (Champness and Snyder, J. Mol. Biol. 155:395-409). In this communication, we report the sequence of the gol region of the T4 genome from five different gol mutants. The gol mutations are all single-base-pair transitions within 40 base pairs of DNA. Therefore, the gol site is at least 40 base pairs long. The sequence data confirm that the gol phenotype is not due to an altered protein. We also report that the gol+ site in plasmids prevents transformation of Lit- but not Lit+ E. coli. Thus, the gol site is at least partially active in the absence of the T4 genome.     

Morphology of an Escherichia coli mutant with a temperature-dependent round cell shape.

Mutants of Escherichia coli capable of growing in the presence of 10 microgram of mecillinam per ml were selected after intensive mutagenesis. Of these mutants, 1.4% formed normal, rod-shaped cells at 30 degrees C but grew as spherical cells at 42 degrees C. The phenotype of one of these rod(Ts) mutants was 88% cotransducible with lip (14.3 min), and all lip+ rod(Ts) transductants of a lip recipient had the following characteristics: (i) growth was relatively sensitive to mecillinam at 30 degrees C but relatively resistant to mecillinam at 42 degrees C; (ii) penicillin-binding protein 2 was present in membranes of cells grown at 30 degrees C in reduced amounts and was undetectable in the membranes of cells grown at 42 degrees C. The mecillinam resistance, penicillin-binding protein 2 defect, and rod phenotypes all cotransduced with lip with high frequency. Thus the mutation [rodA(Ts)] is most likely in the gene for penicillin-binding protein 2 and causes the organism to grow as a sphere at 42 degrees C, although it grows with normal rodlike morphology at 30 degrees C. At 42 degrees C, cells of this strain were round with many wrinkles on their surfaces, as revealed by scanning electron microscopy. In these round cells, chromosomes were dispersed or distributed peripherally, in contrast to normal rod-shaped cells which had centrally located, more condensed chromosomes. The round cells divided asymmetrically on solid agar, and it seemed that the plane of each successive division was perpendicular to the preceding one. On temperature shift-down in liquid medium many cells with abnormal morphology appeared before normal rod-shaped cells developed. Few abnormal cells were seen when cells were placed on solid medium during temperature shift-down. These pleiotropic effects are presumably caused by one or more mutations in the rodA gene.     

Isomaltulose synthase from Klebsiella sp. strain LX3: gene cloning and characterization and engineering of thermostability

The gene (palI) encoding isomaltulose synthase (PalI) from a soil bacterial isolate, Klebsiella sp. strain LX3, was cloned and characterized. PalI converts sucrose into isomaltulose, trehalulose, and trace amounts of glucose and fructose. Sequence domain analysis showed that PalI contains an alpha-amylase domain and (beta/alpha)(8)-barrel structures, suggesting that it belongs to the alpha-amylase family. Sequence alignment indicated that the five amino acid residues of catalytic importance in alpha-amylases and glucosyltransferases (Asp(241), Glu(295), Asp(369), His(145), and His(368)) are conserved in PalI. Purified recombinant PalI displayed high catalytic efficiency, with a Km of 54.6 +/- 1.7 mM for sucrose, and maximum activity (approximately 328.0 +/- 2.5 U/mg) at pH 6.0 and 35 degrees C. PalI activity was strongly inhibited by Fe3+ and Hg2+ and was enhanced by Mn2+ and Mg2+. The half-life of PalI was 1.8 min at 50 degrees C. Replacement of selected amino acid residues by proline significantly increased the thermostability of PalI. Simultaneous replacement of Glu(498) and Arg(310) with proline resulted in an 11-fold increase in the half-life of PalI at 50 degrees C.