Isolation of U(VI) reduction-deficient mutants of Shewanella putrefaciens

A U(VI) reduction-deficient mutant (Urr) screening technique was developed and combined with chemical mutagenesis procedures to identify a Urr mutant of Shewanella putrefaciens strain 200. The Urr mutant lacked the ability to grow anaerobically on U(VI) and NO(2)(-), yet retained the ability to grow anaerobically on eight other compounds as terminal electron acceptor. All 11 members of previously isolated sets of Fe(III) and Mn(IV) reduction-deficient mutants of S. putrefaciens 200 displayed Urr-positive phenotypes with the Urr screen and were capable of anaerobic growth on U(VI). This is the first reported isolation of a respiratory mutant that is unable to grow anaerobically on U(VI) as terminal electron acceptor.     

Isolation of anaerobic respiratory mutants of Shewannella putrefaciens and genetic analysis of mutants deficient in anaerobic growth on Fe3+.

A genetic approach was used to study (dissimilatory) ferric iron (Fe3+) reduction in Shewanella putrefaciens 200. Chemical mutagenesis procedures and two rapid plate assays were developed to facilitate the screening of Fe3+ reduction-deficient mutants. Sixty-two putative Fe3+ reduction-deficient mutants were identified, and each was subsequently tested for its ability to grow anaerobically on various compounds as sole terminal electron acceptors, including Fe3+, nitrate (NO3-), nitrite (NO2-), manganese oxide (Mn4+), sulfite (SO3(2-)), thiosulfate (S2O3(2-)), trimethylamine N-oxide, and fumarate. A broad spectrum of mutants deficient in anaerobic growth on one or more electron acceptors was identified. Nine of the 62 mutants (designated Fer mutants) were deficient only in anaerobic growth on Fe3+ and retained the ability to grow on all other electron acceptors. These results suggest that S. putrefaciens expresses at least one terminal Fe3+ reductase that is distinct from other terminal reductases coupled to anaerobic growth. The nine Fer mutants were conjugally mated with an S. putrefaciens genomic library harbored in Escherichia coli S17-1. Complemented S. putrefaciens transconjugants were identified by the acquired ability to grow anaerobically on Fe3+ as the sole terminal electron acceptor. All recombinant cosmids that conferred the Fer+ phenotype appeared to carry a common internal region.     

Design and Application of Two Rapid Screening Techniques for Isolation of Mn(IV) Reduction-Deficient Mutants of Shewanella putrefaciens

Chemical mutagenesis procedures and two newly developed rapid plate assays were used to identify two Mn(IV) reduction-deficient (Mnr) mutants of Shewanella putrefaciens. All eleven members of a set of previously isolated Fe(III) reduction-deficient (Fer) mutants displayed Mnr-positive phenotypes on the plate assays and were also capable of anaerobic growth on Mn(IV) as the sole terminal electron acceptor.     

Dissimilatory Fe(III) and Mn(IV) Reduction by Shewanella putrefaciens Requires ferE, a Homolog of the pulE (gspE) Type II Protein Secretion Gene

Shewanella putrefaciens strain 200 respires anaerobically on a wide range of compounds as the sole terminal electron acceptor, including ferric iron [Fe(III)] and manganese oxide [Mn(IV)]. Previous studies demonstrated that a 23.3-kb S. putrefaciens wild-type DNA fragment conferred metal reduction capability to a set of respiratory mutants with impaired Fe(III) and Mn(IV) reduction activities (T. DiChristina and E. DeLong, J. Bacteriol. 176:1468-1474, 1994). In the present study, the smallest complementing fragment was found to contain one open reading frame (ORF) (ferE) whose translated product displayed 87% sequence similarity to Aeromonas hydrophila ExeE, a member of the PulE (GspE) family of proteins found in type II protein secretion systems. Insertional mutants E726 and E912, constructed by targeted replacement of wild-type ferE with an insertionally inactivated ferE construct, were unable to respire anaerobically on Fe(III) or Mn(IV) yet retained the ability to grow on all other terminal electron acceptors. Nucleotide sequence analysis of regions flanking ferE revealed the presence of one partial and two complete ORFs whose translated products displayed 55 to 70% sequence similarity to the PulD, -F, and -G homologs of type II secretion systems. A contiguous cluster of 12 type II secretion genes (pulC to -N homologs) was found in the unannotated genome sequence of Shewanella oneidensis (formerly S. putrefaciens) MR-1. A 91-kDa heme-containing protein involved in Fe(III) reduction was present in the peripheral proteins loosely attached to the outside face of the outer membrane of the wild-type and complemented (Fer+) B31 transconjugates yet was missing from this location in Fer mutants E912 and B31 and in uncomplemented (Fer-) B31 transconjugates. Membrane fractionation studies with the wild-type strain supported this finding: the 91-kDa heme-containing protein was detected with the outer membrane fraction and not with the inner membrane or soluble fraction. These findings provide the first genetic evidence linking dissimilatory metal reduction to type II protein secretion and provide additional biochemical evidence supporting outer membrane localization of S. putrefaciens proteins involved in anaerobic respiration on Fe(III) and Mn(IV).     

Isolation of mutants of Hansenula polymorpha defective in the assembly of octameric alcohol oxidase

Alcohol oxidase (AO) is a peroxisomal enzyme that catalyses the first step in methanol metabolism in yeast. Monomeric, inactive AO protein is synthesised in the cytosol and subsequently imported into peroxisomes, where the enzymatically active, homo-octameric form is found. The mechanisms involved in AO octamer assembly are largely unclear. Here we describe the isolation of Hansenula polymorpha mutants specifically affected in AO assembly. These mutants are unable to grow on methanol and display reduced AO activities. Based on their phenotypes, three major classes of mutants were isolated. Three additional mutants were isolated that each displayed a unique phenotype. Complementation analysis revealed that the isolated AO assembly mutants belonged to 10 complementation groups.     

Escherichia coli derivatives lacking both alcohol dehydrogenase and phosphotransacetylase grow anaerobically by lactate fermentation.

Escherichia coli mutants lacking alcohol dehydrogenase (adh mutants) cannot synthesize the fermentation product ethanol and are unable to grow anaerobically on glucose and other hexoses. Similarly, phosphotransacetylase-negative mutants (pta mutants) neither excrete acetate nor grow anaerobically. However, when a strain carrying an adh deletion was selected for anaerobic growth on glucose, spontaneous pta mutants were isolated. Strains carrying both adh and pta mutations were observed by in vivo nuclear magnetic resonance and shown to produce lactic acid as the major fermentation product. Various combinations of adh pta double mutants regained the ability to grow anaerobically on hexoses, by what amounts to a homolactic fermentation. Unlike wild-type strains, such adh pta double mutants were unable to grow anaerobically on sorbitol or on glucuronic acid. The growth properties of strains carrying various mutations affecting the enzymes of fermentation are discussed in terms of redox balance.     

A rapid mutant screening technique for detection of technetium [Tc(VII)] reduction-deficient mutants of Shewanella oneidensis MR-1

Microbial metal reduction forms the basis of alternate bioremediation strategies for reductive precipitation and immobilization of toxic metals such as the radionuclide technetium [Tc(VII)]. A rapid mutant screening technique was developed to identify Shewanella oneidensis MR-1 respiratory mutants unable to reduce Tc(VII) as anaerobic electron acceptor. The Tc(VII) reduction-deficient (Tcr) mutant screening technique was based on the observation that wild-type S. oneidensis produced a black Tc(IV) precipitate on its colony surface during growth on Tc(VII)-amended agar, while colonies arising from mutagenized cells did not. Tcr mutants unable to produce the black precipitate were subsequently tested for anaerobic growth on an array of three electron donors and 13 alternate electron acceptors. The Tcr mutants displayed a broad spectrum of anaerobic growth deficiencies, including several that were unable to reduce Tc(VII) with hydrogen or lactate as electron donor, yet retained the ability to reduce Tc(VII) with formate. This report describes the development of a novel Tcr mutant screening technique and its application to identify the first set of Tcr mutants in a metal-reducing member of the genus Shewanella.     

Isolation and Characterization of Bacteria from the Baltic Sea

A bacteriological examination was done on samples of water and sediment from three localities in the Baltic. The highest numbers of bacteria were recovered from areas subjected to pollution. The isolates included members of the family Enterobacteria-ceae, the genus Pseudomonas and strains of Aeromonas hydrophila, Alteromonas putrefaciens and some Gram positive bacteria. It is suggested tentatively that H2S production in the black sediments was caused by Alt. putrefaciens. None of the isolates had an absolute requirement for NaCl, although all of them were salt-tolerant to varying degrees, and most were able to grow aerobically at salinities comparable with those found in seawater. Isolates belonging to the family Enterobacteriaceae were, however, unable to grow anaerobically under comparable conditions. Freshwater strains of several genera of the family Enterobacteriaceae and of Aeromonas hydrophila and Aer. sobria displayed salt tolerance identical with that of the Baltic isolates. One strain each of Escherichia coli, Klebsiella pneumoniae and Yersinia enterocolitica survived well during three weeks at 17°C in artificial seawater lacking both carbon and nitrogen sources. These results suggest the need for a re-evaluation of the persistence of potentially pathogenic bacteria in the sea.     

Temperature-sensitive mutants of Escherichia coli B which can grow in high-osmotic medium at the nonpermissive temperature

Two temperature sensitive (TS) mutants (C4 tos and D2 tos) were isolated after mutagenesis of E. coli B/SM by N-methyl-N'-nitro-N-nitrosoguanidine (NMNG), which can grow even at 42 C in high-osmotic medium supplemented by addition of sucrose, NaCl or other compounds. Neither of the mutants lyzed when transferred to low-osmotic medium after growning at the nonpermissive temperature in high osmotic medium. One of these mutants, C4 tos, grew at 42 C in a long filamentous form. When bacteria growing exponentially at 30 C were shifted to 42 C, they continued to grow at a reduced rate even in low-osmotic medium. This strain could also grow or start to grow in low-osmotic medium when supplied with a factor or factors secreted from growing bacteria of another strain. This mutant strain could grow in low-osmotic medium at 42 C when it was cultured anaerobically. The other mutant strain obtained (D2 tos) displayed normal morphology even when grown at 42 C. When it was shifted from 30 to 42 C in low-osmotic medium, increase of mass, measured as optical density, continued for a while, but viability, measured as the number of colony-formers, stopped increasing and then decreased rapidly.     

Reduction of N-oxides and sulfoxide by the same terminal reductase inProteus mirabilis

Proteus mirabilis can grow anaerobically on the fermentable substrate, glucose. When the glucose medium was supplemented with an electron acceptor, growth doubled. However, the organism failed to grow anaerobically on the oxidizable substrate glycerol unless the medium was supplemented with an external electron acceptor. Dimethyl sulfoxide (DMSO), trimethylamine N-oxide (TMAO), nicotinamide N-oxide (NAMO), and nitrate (NO₃) can serve this function. Cell-free extracts ofP. mirabilis can reduce these compounds in the presence of various electron donors. In order to determine whether the same or different terminal reductase(s) are involved in the reduction of these compounds, we isolated mutants unable to grow on glycerol/DMSO medium. When these mutants were tested on glycerol medium containing TMAO, NAMO, and NO₃ as electron acceptors, it was found that there were two groups. Group I mutants were unable to grow with DMSO, TMAO, and NAMO, while their growth was unaffected with NO₃. Group II mutants were unable to grow on any electron acceptor including NO₃. Enzyme assays using reduced benzyl viologen with both groups of mutants were in agreement with growth studies. On the basis of these results, we conclude that the same terminal reductase is involved in the reduction of DMSO, TMAO, and NAMO (group I) and that the additional loss of NO₃ reductase in group II mutants is probably owing to a defect in the synthesis or insertion of molybdenum cofactor.     

Anaerobic electron acceptor chemotaxis in Shewanella putrefaciens

Shewanella putrefaciens MR-1 can grow either aerobically or anaerobically at the expense of many different electron acceptors and is often found in abundance at redox interfaces in nature. Such redox interfaces are often characterized by very strong gradients of electron acceptors resulting from rapid microbial metabolism. The coincidence of S. putrefaciens abundance with environmental gradients prompted an examination of the ability of MR-1 to sense and respond to electron acceptor gradients in the laboratory. In these experiments, taxis to the majority of the electron acceptors that S. putrefaciens utilizes for anaerobic growth was seen. All anaerobic electron acceptor taxis was eliminated by the presence of oxygen, nitrate, nitrite, elemental sulfur, or dimethyl sulfoxide, even though taxis to the latter was very weak and nitrate and nitrite respiration was normal in the presence of dimethyl sulfoxide. Studies with respiratory mutants of MR-1 revealed that several electron acceptors that could not be used for anaerobic growth nevertheless elicited normal anaerobic taxis. Mutant M56, which was unable to respire nitrite, showed normal taxis to nitrite, as well as the inhibition of taxis to other electron acceptors by nitrite. These results indicate that electron acceptor taxis in S. putrefaciens does not conform to the paradigm established for Escherichia coli and several other bacteria. Carbon chemo-taxis was also unusual in this organism: of all carbon compounds tested, the only positive response observed was to formate under anaerobic conditions.     

Anaerobic electron acceptor chemotaxis in Shewanella putrefaciens.

Shewanella putrefaciens MR-1 can grow either aerobically or anaerobically at the expense of many different electron acceptors and is often found in abundance at redox interfaces in nature. Such redox interfaces are often characterized by very strong gradients of electron acceptors resulting from rapid microbial metabolism. The coincidence of S. putrefaciens abundance with environmental gradients prompted an examination of the ability of MR-1 to sense and respond to electron acceptor gradients in the laboratory. In these experiments, taxis to the majority of the electron acceptors that S. putrefaciens utilizes for anaerobic growth was seen. All anaerobic electron acceptor taxis was eliminated by the presence of oxygen, nitrate, nitrite, elemental sulfur, or dimethyl sulfoxide, even though taxis to the latter was very weak and nitrate and nitrite respiration was normal in the presence of dimethyl sulfoxide. Studies with respiratory mutants of MR-1 revealed that several electron acceptors that could not be used for anaerobic growth nevertheless elicited normal anaerobic taxis. Mutant M56, which was unable to respire nitrite, showed normal taxis to nitrite, as well as the inhibition of taxis to other electron acceptors by nitrite. These results indicate that electron acceptor taxis in S. putrefaciens does not conform to the paradigm established for Escherichia coli and several other bacteria. Carbon chemo-taxis was also unusual in this organism: of all carbon compounds tested, the only positive response observed was to formate under anaerobic conditions.     

Anaerobic growth defects resulting from gene fusions affecting succinyl-CoA synthetase in Escherichia coli K12

Summary Insertion of the fusion-generating phage Mud1 (Ap, lacZ) yielded two similar isolates, DC511 and DC512, which were unable to grow aerobically on acetate or alphaketoglutarate but which could use succinate, malate, fumarate, glycerol, and various sugars. These mutants were unable to grow anaerobically on most sugars unless provided with methionine, lysine, and delta-aminolevulinic acid, all of which require succinyl-CoA for their synthesis. The insertions of both mutants mapped at 17 min, in the suc operon. Enzyme assays indicated a lack of succinyl-CoA synthetase; however, full activity of the alpha-ketoglutarate dehydrogenase was retained. Beta-galactosidase expression by strains containing these gene fusions was reduced under anaerobic conditions. In aerobically grown cultures, both fusions were induced about fivefold in the presence of acetate. This type of regulation would be expected of a Krebs cycle enzyme.     

A conserved histidine in cytochrome c maturation permease CcmB of Shewanella putrefaciens is required for anaerobic growth below a threshold standard redox potential

Shewanella putrefaciens strain 200 respires a wide range of compounds as terminal electron acceptor. The respiratory versatility of Shewanella is attributed in part to a set of c-type cytochromes with widely varying midpoint redox potentials (E'(0)). A point mutant of S. putrefaciens, originally designated Urr14 and here renamed CCMB1, was found to grow at wild-type rates on electron acceptors with high E'0 [O2, NO3-, Fe(III) citrate, MnO2, and Mn(III) pyrophosphate] yet was severely impaired for growth on electron acceptors with low E'0 [NO2-, U(VI), dimethyl sulfoxide, TMAO (trimethylamine N-oxide), fumarate, gamma-FeOOH, SO3(2-), and S2O3(2-)]. Genetic complementation and nucleotide sequence analyses indicated that the CCMB1 respiratory mutant phenotype was due to mutation of a conserved histidine residue (H108Y) in a protein that displayed high homology to Escherichia coli CcmB, the permease subunit of an ABC transporter involved in cytochrome c maturation. Although CCMB1 retained the ability to grow on electron acceptors with high E'(0), the cytochrome content of CCMB1 was <10% of that of the wild-type strain. Periplasmic extracts of CCMB1 contained slightly greater concentrations of the thiol functional group (-SH) than did the wild-type strain, an indication that the E(h) of the CCMB1 periplasm was abnormally low. A ccmB deletion mutant was unable to respire anaerobically on any electron acceptor, yet retained aerobic respiratory capability. These results suggest that the mutation of a conserved histidine residue (H108) in CCMB1 alters the redox homeostasis of the periplasm during anaerobic growth on electron acceptors with low (but not high) E'0. This is the first report of the effects of Ccm deficiencies on bacterial respiration of electron acceptors whose E'0 nearly span the entire redox continuum.     

Pleiotropic plasma membrane ATPase mutations of Saccharomyces cerevisiae.

We isolated a large number of mutations in the structural gene for the plasma membrane ATPase (PMA1) of Saccharomyces cerevisiae. These mutations were selected by their resistance to the aminoglycoside antibiotic hygromycin B. Biochemical analysis of purified membrane preparations showed that the plasma membrane ATPase activity of the mutants was reduced as much as 75%. Intragenic complementation of pma1 mutants suggested that the yeast plasma membrane ATPase was a multimeric enzyme. The pma1 mutants were apparently defective in maintaining internal pH; more than half of the mutants were unable to grow either at a low pH or in the presence of a weak acid. Most pma1 mutants were also osmotic pressure sensitive. At a very low temperature (5 degrees C) many pma1 mutants were unable to grow and were arrested as unbudded cells. The three most severely affected mutants were also unable to grow in the presence of NH4+. The most extreme mutant exhibited a severe defect in progression through the cell cycle; on synthetic medium, the cells progressively accumulated nucleus-containing small buds that generally failed to complete bud enlargement and cytokinesis. Most of the pleiotropic phenotypes of pma1 mutants could be suppressed by the addition of 50 mM KCl but not NaCl to the medium.     

Dimethyl sulphoxide reduction by micro-organisms.

Dimethyl sulphoxide (DMSO) was reduced to dimethyl sulphide by a wide variety of micro-organism, including prokaryotes and eukaryotes, aerobes and anaerobes. Dimethyl sulphone was not reduced by any of the organisms tested. Cell-free extracts of Escherichia coli reduced DMSO using reduced pyridine nucleotides as electron donors. Activity was greater in anaerobically grown cells than in those grown aerobically. Two other sulphoxides, methionine sulphoxide and tetramethylene sulphoxide, substantially inhibited DMSO reduction by extracts. Mutants of E. coli, which were unable to reduce biotin sulphoxide to biotin, were tested for their ability to reduce DMSO in whole cells and extracts. These mutants were in four different gene loci, bisA to bisD. DMSO reductase activity of the mutants was generally less than that of the wild-type strain, and activity depended upon the gene locus involved, the growth medium and the growth conditions. Only the bisA mutant had very low activity under all conditions. All of the bis mutants were able to grow using methionine sulphoxide as a sulphur source, indicating that biotin sulphoxide and methionine sulphoxide are reduced by different enzyme systems. DMSO may be reduced by both of these enzyme systems.     

Rhizobium japonicum mutant strains unable to grow chemoautotrophically with H2

Rhizobium japonicum strain SR grows chemoautotrophically on a mineral salts medium when incubated in an H2- and CO2-containing atmosphere. Mutant strains unable to grow or that grow very poorly chemoautotrophically with H2 have been isolated from strain SR. The mutant isolation procedure involved mutagenesis with ethyl methane sulfonate, penicillin selection under chemoautotrophic growth conditions, and plating of the survivors onto medium containing carbon. The resulting colonies were replica plated onto medium that did not contain carbon, and the plates were incubated in an H2- and CO2-containing atmosphere. Mutant strains unable to grow under these conditions were chosen. Over 100 mutant strains with defects in chemoautotrophic metabolism were obtained. The phenotypes of the mutants fall into various classes. These include strains unable to oxidize H2 and strains deficient in CO2 uptake. Some of the mutant strains were capable of oxidizing H2 only when artificial electron acceptors were provided. Two mutant strains specifically lack activity of the key CO2-fixing enzyme ribulose 1,5-bisphosphate carboxylase. Other mutant strains lack both H2-oxidizing ability and ribulose 1,5-bisphosphate carboxylase activity.     

Sequential cold-sensitive mutations in Aspergillus fumigatus.

Mutants of thermotolerant fungus Aspergillus fumigatus I-21 (ATCC 32722) unable to grow at 37 degrees C were sought. Cold-sensitive mutants were enriched from progeny spores of gamma-irradiated conidia by two or more incubations at various nonpermissive temperatures alternating with filtrations through chessecloth. The approximate minimum, optimum, and maximum growth temperatures of the parent were 12, 40, and 50 degrees C, respectively. Mutants unable to grow at 37 degrees C were not successfully isolated directly from the wild type. A mutant unable to grow at 25 degrees C was isolated and mutations further increasing the cold sensitivity by increments of 3-5 degrees C were found to occur. Mutants completely unable to grow at 37 degrees C were obtained by five sequential mutations. All mutants grew as fast as the wild-type parent at 45 degrees C and higher. Each mutant produced revertants able to grow not only at the nonpermissive temperature used for its isolation but also at lower temperatures.     

Cycloheximide-Resistant Temperature-Sensitive Lethal Mutations of Saccharomyces Cerevisiae

We describe the isolation and preliminary characterization of a set of pleiotropic mutations resistant to the minimum inhibitory concentration of cycloheximide and screened for ts (temperature-sensitive) growth. These mutations fall into 22 complementation groups of cycloheximide resistant ts lethal mutations (crl). None of the crl mutations appears to be allelic with previously isolated mutations. Fifteen of the CRL loci have been mapped. At the nonpermissive temperature (37°), these mutants arrest late in the cell cycle after several cell divisions. Half of these mutants are also unable to grow at very low temperatures (5°). Although mutants from all of the 22 complementation groups exhibit similar temperature-sensitive phenotypes, an extragenic suppressor of the ts lethality of crl3 does not relieve the ts lethality of most other crl mutants. A second suppressor mutation allows crl10, crl12, and crl14 to grow at 37° but does not suppress the ts lethality of the remaining crl mutants. We also describe two new methods for the enrichment of auxotrophic mutations from a wild-type yeast strain.