Hydrogen sulphide production by Zymomonas and its elimination in a mutant strain

Strains of Zymomonas mobilis grown in media containing either glucose or sucrose were assessed for the production of hydrogen sulphide (H₂S). In a liquid medium with low glucose concentration (20 g l^?1) only a proportion of the strains tested formed H₂S, but in medium containing a higher glucose concentration (100 g l^?1) all the strains tested produced H₂S. Four Z. mobilis strains were assayed quantitatively for H₂S production and strain ZM4 was found to produce the most H₂S in glucose medium. The amount of yeast extract and glucose, and the type of sugar used in the medium affected the amount of H₂S formed by strain ZM4. A mutant, designated ZM4701, of strain ZM4 was isolated which did not produce any detectable H₂S in liquid medium containing yeast extract plus either glucose or sucrose. The nutritional requirements of ZM4701 were investigated.     

Inhibition analysis of inhibitors derived from lignocellulose pretreatment on the metabolic activity of Zymomonas mobilis biofilm and planktonic cells and the proteomic responses

Lignocellulose pretreatment produces various toxic inhibitors that affect microbial growth, metabolism, and fermentation. Zymomonas mobilis is an ethanologenic microbe that has been demonstrated to have potential to be used in lignocellulose biorefineries for bioethanol production. Z. mobilis biofilm has previously exhibited high potential to enhance ethanol production by presenting a higher viable cell number and higher metabolic activity than planktonic cells or free cells when exposed to lignocellulosic hydrolysate containing toxic inhibitors. However, there has not yet been a systematic study on the tolerance level of Z. mobilis biofilm compared to planktonic cells against model toxic inhibitors derived from lignocellulosic material. We took the first insight into the concentration of toxic compound (formic acid, acetic acid, furfural, and 5‐HMF) required to reduce the metabolic activity of Z. mobilis biofilm and planktonic cells by 25% (IC₂₅), 50% (IC₅₀), 75% (IC₇₅), and 100% (IC₁₀₀). Z. mobilis strains ZM4 and TISTR 551 biofilm were two‐ to three fold more resistant to model toxic inhibitors than planktonic cells. Synergetic effects were found in the presence of formic acid, acetic acid, furfural, and 5‐HMF. The IC₂₅ of Z. mobilis ZM4 biofilm and TISTR 551 biofilm were 57 mm formic acid, 155 mm acetic acid, 37.5 mm furfural and 6.4 mm 5‐HMF, and 225 mm formic acid, 291 mm acetic acid, 51 mm furfural and 41 mm 5‐HMF, respectively. There was no significant difference found between proteomic analysis of the stress response to toxic inhibitors of Z. mobilis biofilm and planktonic cells on ZM4. However, TISTR 551 biofilms exhibited two proteins (molecular chaperone DnaK and 50S ribosomal protein L2) that were up‐regulated in the presence of toxic inhibitors. TISTR 551 planktonic cells possessed two types of protein in the group of 30S ribosomal proteins and motility proteins that were up‐regulated.     

The intracellular sucrase (SacA) of Zymomonas mobilis is not involved in sucrose assimilation

The intracellular sucrase SacA from Zymomonas mobilis was purified to homogeneity from a recombinant E. coli strain containing the SacA gene under an expression system. The protein was monomeric with a molecular mass of 58 kDa. The sucrase activity was maximal at 25 °C and thermal stability of the purified protein was low (50% recovery after 30 min at 46 °C ). The activation energy was low at 33 kJ mol^–1. Maximum activity was at pH 6.5. Activity was strongly inhibited (>99%) by SH blocking reagents and reducing agents slightly (10–60%) increased the activity of purified SacA. The sucrase showed a low K _M (42 mM) and k _cat (125 s^–1) which indicated its very low efficiency for sucrose hydrolysis. A mutant strain of Z. mobilis not able to grow on sucrose was isolated. This strain (ZM4S) lacked the two sucrases SacB and SacC but SacA was present in the intracellular fraction. Therefore, SacA alone is unable to allow growth Z. mobilis on sucrose.     

A physical map of the genome of ethanol fermentative bacterium Zymomonas mobilis ZM4 and localization of genes on the map

A physical map of the Zymomonas mobilis ZM4 genome has been constructed from the results of reciprocal Southern hybridization with PmeI, PacI, and NotI-digested genomic DNA fragments and linking cosmid clones. Restriction enzyme-digested Z. mobilis ZM4 genome was electrophoresed with phage lambda DNA concatemers as a size standard in a Bio-Rad CHEF-DRII pulsed-field gel electrophoresis (PFGE) system. The restriction enzyme PmeI generated 15 fragments (3–625 kb), and PacI produced 19 fragments (7–525 kb). Each size of restriction fragment was calculated by comparison to the size of phage lambda DNA concatemers, and the genome size of Z. mobilis ZM4 was estimated to be 2085.5 kb. The 19 known genes and three rrn operons were localized on the map.     

Structures of iron-dependent alcohol dehydrogenase 2 from Zymomonas mobilis ZM4 with and without NAD+ cofactor

The ethanologenic bacterium Zymomonas mobilis ZM4 is of special interest because it has a high ethanol yield. This is made possible by the two alcohol dehydrogenases (ADHs) present in Z. mobilis ZM4 (zmADHs), which shift the equilibrium of the reaction toward the synthesis of ethanol. They are metal-dependent enzymes: zinc for zmADH1 and iron for zmADH2. However, zmADH2 is inactivated by oxygen, thus implicating zmADH2 as the component of the cytosolic respiratory system in Z. mobilis. Here, we show crystal structures of zmADH2 in the form of an apo-enzyme and an NAD⁺-cofactor complex. The overall folding of the monomeric structure is very similar to those of other functionally related ADHs with structural variations around the probable substrate and NAD⁺ cofactor binding region. A dimeric structure is formed by the limited interactions between the two subunits with the bound NAD⁺ at the cleft formed along the domain interface. The catalytic iron ion binds near to the nicotinamide ring of NAD⁺, which is likely to restrict and locate the ethanol to the active site together with the oxidized Cys residue and several nonpolar bulky residues. The structures of the zmADH2 from the proficient ethanologenic bacterium Z. mobilis, with and without NAD⁺ cofactor, and modeling ethanol in the active site imply that there is a typical metal-dependent catalytic mechanism.     

Polymorphic Variants of Human Rhodanese Exhibit Differences in Thermal Stability and Sulfur Transfer Kinetics

Rhodanese is a component of the mitochondrial H₂S oxidation pathway. Rhodanese catalyzes the transfer of sulfane sulfur from glutathione persulfide (GSSH) to sulfite generating thiosulfate and from thiosulfate to cyanide generating thiocyanate. Two polymorphic variations have been identified in the rhodanese coding sequence in the French Caucasian population. The first, 306A→C, has an allelic frequency of 1% and results in an E102D substitution in the encoded protein. The second polymorphism, 853C→G, has an allelic frequency of 5% and leads to a P285A substitution. In this study, we have examined differences in the stability between wild-type rhodanese and the E102D and P285A variants and in the kinetics of the sulfur transfer reactions. The Asp-102 and Ala-285 variants are more stable than wild-type rhodanese and exhibit k_cat/K_m,CN values that are 17- and 1.6-fold higher, respectively. All three rhodanese forms preferentially catalyze sulfur transfer from GSSH to sulfite, generating thiosulfate and glutathione. The k_cat/K_m,sulfite values for the variants in the sulfur transfer reaction from GSSH to sulfite were 1.6- (Asp-102) and 4-fold (Ala-285) lower than for wild-type rhodanese, whereas the k_cat/K_m,GSSH values were similar for all three enzymes. Thiosulfate-dependent H₂S production in murine liver lysate is low, consistent with a role for rhodanese in sulfide oxidation. Our studies show that polymorphic variations that are distant from the active site differentially modulate the sulfurtransferase activity of human rhodanese to cyanide versus sulfite and might be important in differences in susceptibility to diseases where rhodanese dysfunction has been implicated, e.g. inflammatory bowel diseases.     

Construction of a shuttle vector for Zymomonas mobilis

Summary An Escherichia coli-Zymomonas mobilis shuttle vector was constructed from a 15.5 kb native plasmid of ZM6 00 and the E. coli plasmid, pBR329. Integrative transfer of this shuttle vector from E. coli to Z. mobilis was achieved with the aid of the mobilizing plasmid, pRK2013. The shuttle vector was stable in Z. mobilis for at least 300 generations without antibiotic selection.Offprint requests to: S. F. Delaney     

Use of sulfate reducing cell suspension bioreactors for the treatment of SO2 rich flue gases

This paper describes a novel bioscrubber concept for biological flue gas desulfurization, based on the recycling of a cell suspension of sulfite/sulfate reducing bacteria between a scrubber and a sulfite/sulfate reducing hydrogen fed bioreactor. Hydrogen metabolism in sulfite/sulfate reducing cell suspensions was investigated using batch activity tests and by operating a completely stirred tank reactor (CSTR). The maximum specific hydrogenotrophic sulfite/sulfate reduction rate increased with 10% and 300%, respectively, by crushing granular inoculum sludge and by cultivation of this sludge as cell suspension in a CSTR. Operation of a sulfite fed CSTR (hydraulic retention time 4 days; pH 7.0; sulfite loading rate 0.5–1.5 g SO ₃ ^2- l^-1 d^-1) with hydrogen as electron donor showed that high (up to 1.6 g l^-1) H₂S concentrations can be obtained within 10 days of operation. H₂S inhibition, however, limited the sulfite reducing capacity of the CSTR. Methane production by the cell suspension disappeared within 20 days reactor operation. The outcompetition of methanogens in excess of H₂ can be attributed to CO₂ limitation and/or to sulfite or sulfide toxicity. The use of cell suspensions opens perspectives for monolith or packed bed reactor configurations, which have a much lower pressure drop compared to air lift reactors, to supply H₂ to sulfite/sulfate reducing bioreactors.     

Flocculating Zymomonas mobilis is a promising host to be engineered for fuel ethanol production from lignocellulosic biomass

Whereas Saccharomyces cerevisiae uses the Embden‐Meyerhof‐Parnas pathway to metabolize glucose, Zymomonas mobilis uses the Entner‐Doudoroff (ED) pathway. Employing the ED pathway, 50% less ATP is produced, which could lead to less biomass being accumulated during fermentation and an improved yield of ethanol. Moreover, Z. mobilis cells, which have a high specific surface area, consume glucose faster than S. cerevisiae, which could improve ethanol productivity. We performed ethanol fermentations using these two species under comparable conditions to validate these speculations. Increases of 3.5 and 3.3% in ethanol yield, and 58.1 and 77.8% in ethanol productivity, were observed in ethanol fermentations using Z. mobilis ZM4 in media containing ～100 and 200 g/L glucose, respectively. Furthermore, ethanol fermentation bythe flocculating Z. mobilis ZM401 was explored. Although no significant difference was observed in ethanol yield and productivity, the flocculation of the bacterial species enabled biomass recovery by cost‐effective sedimentation, instead of centrifugation with intensive capital investment and energy consumption. In addition, tolerance to inhibitory byproducts released during biomass pretreatment, particularly acetic acid and vanillin, was improved. These experimental results indicate that Z. mobilis, particularly its flocculating strain, is superior to S. cerevisiae as a host to be engineered for fuel ethanol production from lignocellulosic biomass.     

MET2 affects production of hydrogen sulfide during wine fermentation

The production of hydrogen sulfide (H₂S) during yeast fermentation contributes negatively to wine aroma. We have mapped naturally occurring mutations in commercial wine strains that affect production of H₂S. A dominant R₃₁₀G mutant allele of MET2, which encodes homoserine O-acetyltransferase, is present in several wine yeast strains as well as in the main lab strain S288c. Reciprocal hemizygosity and allele swap experiments demonstrated that the MET2 _R310G allele confers reduced H₂S production. Mutations were also identified in genes encoding the two subunits of sulfite reductase, MET5 and MET10, which were associated with reduced H₂S production. The most severe of these, an allele of MET10, showed five additional phenotypes: reduced growth rate on sulfate, elevated secretion of sulfite, and reduced production in wine of three volatile sulfur compounds: methionol, carbon disulfide and methylthioacetate. Alleles of MET5 and MET10, but not MET2, affected H₂S production measured by colour assays on BiGGY indicator agar, but MET2 effects were seen when bismuth was added to agar plates made with Sauvignon blanc grape juice. Collectively, the data are consistent with the hypothesis that H₂S production during wine fermentation results predominantly from enzyme activity in the sulfur assimilation pathway. Lower H₂S production results from mutations that reduce the activity of sulfite reductase, the enzyme that produces H₂S, or that increase the activity of l-homoserine-O-acetyltransferase, which produces substrate for the next step in the sulfur assimilation pathway.     

Identification of Genes Affecting Hydrogen Sulfide Formation in Saccharomyces cerevisiae

A screen of the Saccharomyces cerevisiae deletion strain set was performed to identify genes affecting hydrogen sulfide (H₂S) production. Mutants were screened using two assays: colony color on BiGGY agar, which detects the basal level of sulfite reductase activity, and production of H₂S in a synthetic juice medium using lead acetate detection of free sulfide in the headspace. A total of 88 mutants produced darker colony colors than the parental strain, and 4 produced colonies significantly lighter in color. There was no correlation between the appearance of a dark colony color on BiGGY agar and H₂S production in synthetic juice media. Sixteen null mutations were identified as leading to the production of increased levels of H₂S in synthetic juice using the headspace analysis assay. All 16 mutants also produced H₂S in actual juices. Five of these genes encode proteins involved in sulfur containing amino acid or precursor biosynthesis and are directly associated with the sulfate assimilation pathway. The remaining genes encode proteins involved in a variety of cellular activities, including cell membrane integrity, cell energy regulation and balance, or other metabolic functions. The levels of hydrogen sulfide production of each of the 16 strains varied in response to nutritional conditions. In most cases, creation of multiple deletions of the 16 mutations in the same strain did not lead to a further increase in H₂S production, instead often resulting in decreased levels.     

Simultaneous saccharification and ethanol fermentation of sago starch using immobilized Zymomonas mobilis

Simultaneous saccharification and ethanol fermentation (SSF) of sago starch using amyloglucosidase (AMG) and immobilized Zymomonas mobilis ZM4 on sodium alginate was studied. The immobilized Zymomonas cells were more thermo-stable than free Zymomonas cells in this system. The optimum temperature in the SSF system was 40°C, and 0.5% (v/w) AMG concentration was adopted for the economical operation of the system. The final ethanol concentration obtained was 68.3 g/l and the ethanol yield, Y_p/s, was 0.49 g/g (96% of the theoretical yield). After 6 cycles of reuse at 40°C with 15% sago starch hydrolysate, the immobilized Z. mobilis retained about 50% of its ethanol fermenting ability.     

Oxidation and reduction of sulfite by chloroplasts and formation of sulfite addition compounds

After exposing intact chloroplasts isolated from spinach (Spinacia oleracea L. cv Yates) and capable of photoreducing CO₂ at high rates to different concentrations of radioactive sulfite in the light or in the dark, ³⁵SO₂ and H₂³⁵S were removed from the acidified suspensions in a stream of nitrogen. Remaining activity could be fractionated into sulfate, organic sulfides, and sulfite addition compounds. When chloroplast suspensions contained catalase, superoxide dismutase and O-acetylserine, the oxidation of sulfite to sulfate was slower in the light than the reductive formation of sulfides that exhibited a maximum rate of about 2 micromoles per milligram chlorophyll per hour, equivalent to about 1% of maximum carbon assimilation. Botht the oxidative and the reductive detoxification of sulfite were very slow in the dark. Oxidation was somewhat, but not much, accelerated in the light in the absence of O-acetylserine, which caused a dramatic decrease in the formation of organic sulfides and an equally dramatic increase in the concentration of sulfite addition compounds whose formation was light-dependent. The sulfite addition compounds were not identified. Addition compounds did not accumulate in the dark. In the light, the electron transport inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea, diuron, decreased not only the reduction, but also the oxidation of sulfite and the formation of addition compounds.     

Transfer of Plasmids to an Antibiotic-Sensitive Mutant of Zymomonas mobilis

Wild-type strains of Zymomonas mobilis exhibit multiple antibiotic resistance and thus restrict the use of many broad-host-range plasmids in them as cloning vehicles. Antibiotic-sensitive mutants of Z. mobilis were isolated and used as hosts for the conjugal transfer of broad-host-range plasmids from Escherichia coli. Such antibiotic-sensitive strains can facilitate the application of broad-host-range plasmids to the study of Z. mobilis.     

Hydrogen sulfide-producing kinetics of Shewanella oneidensis in sulfite and thiosulfate respiration

Shewanella oneidensis is a model species for aquatic ecosystems and plays an important role in bioremediation, biofuel cell manufacturing and biogeochemical cycling. S. oneidensis MR-1 is able to generate hydrogen sulfide from various sulfur species; however, its catalytic kinetics have not been determined. In this study, five in-frame deletion mutants of S. oneidensis were constructed and their H₂S-producing activities were analyzed. SirA and PsrA were the two major contributors to H₂S generation under anoxic cultivation, and the optimum SO₃²⁻ concentration for sulfite respiration was approximately 0.8 mM, while the optimum S₂O₃²⁻ concentration for thiosulfate respiration was approximately 0.4 mM. Sulfite and thiosulfate were observed to interfere with each other during respiration, and a high concentration of sulfite or thiosulfate chelated extracellular free-iron but did not repress the expression of sirA or psrA. Nitrite and nitrate were two preferred electron acceptors during anaerobic respiration; however, under energy-insufficient conditions, S. oneidensis could utilize multiple electron acceptors simultaneously. Elucidiating the stoichiometry of H₂S production in S. oneidensis would be helpful for the application of this species in bioremediation and biofuel cell manufacturing, and would help to characterize the ecophysiology of sulfur cycling.     

The use of stable sulfur isotope labelling to elucidate sulfur metabolism by Clostridium pasteurianum

An unique stable isotope labelling experiment was conducted whereby mixtures of sulfate and sulfite of different isotopic compositions were metabolized by Clostridium pasteurianum. The results showed during reduction of 1 mM SO ₃ ⁼ plus 1 mM SO ₄ ⁼ , essentially all evolved H₂S arose from the sulfite whereas in the case of cellular sulfur, 85% was derived from sulfite and the remainder from sulfate.     

STUDIES ON THE PATHWAY OF SULFIDE PRODUCTION IN A COPPER-ADAPTED YEAST

Metabolism of some sulfur-containing substances was studiedin a copper-resistant strain of yeast (R), its parent strain(P) and respiratory-deficient(RD) mutants from them. The resultsobtained are as follows:

1. Using sulfate, sulfite and thiosulfate as sulfur sources, Rproducedmore H₂S than P, and both of these had the activityhigher than their RD mutants. All of them produced a large amountof H₂S from cysteine, but only little from methionine, cysteinesulfinic acid and S-sulfocysteine.
2. From sulfite and thiosulfate,P and R produced more H₂S inaerobicthan in anaerobic condition.With sulfate and cysteine, however,H₂S production did not differunder those conditions.
3. In both P and R, the sulfate-to-sulfiteand sulfite-to-sulfidereactions were remarkably lowered byiron and zinc deficiencies.But the cysteine-to-sulfide reactionwas not affected by themetal-deficiencies.
4. H₂S productionfrom sulfate was remarkably depressed by highconcentrationsof pantothenate.
5. Rates of reaction steps on a plausible pathway from sulfatetosulfide and to organic sulfur compounds areestimated forthe strainsused. R is characterized by its largecapacity ofthe reaction step from sulfate to sulfite, and excessivesulfitethus formed is liberatedas sulfide not by the way ofcysteine.

¹Present address: Research Reactor Institute, Kyoto University,Kumatori-cho, Sennan-gun, Osaka     

Enhanced electrotransformation of the ethanologen Zymomonas mobilis ZM4 with plasmids

The Zymomonas mobilis ZM4 strain with excellent ethanol‐producing capabilities was the first strain of Z. mobilis, which was sequenced. This strain is resistant to transformation, and no previous study has shown a detailed protocol for electrotransfer of ZM4 with foreign DNA. In this work, many electrical and biological parameters were selected and evaluated in order to optimize the electrotransformation of ZM4. First, improved transformation efficiencies of 11 896, 99, 96 and 5989 transformants/μg DNA were separately achieved with shuttle plasmid pZB21‐mini (3082 bp), pZB21 (5930 bp), pZA22 (6994 bp) and broad‐host‐range vector pBBR1MCS‐2 (5144 bp) all prepared from Escherichia coli JM110. The crucial factors affecting the transformation efficiency included the source of the plasmid (the best strain was ZM4), origin and size of the plasmids, growth phase of the cells (the most ideal phase was early log phase with OD₆₀₀ of 0.3–0.4), the electric field strength (generally 11.75 kV/cm–13.25 kV/cm) and the recovery time (3–24 h). Further, based upon the optimal transformation protocol mentioned above for replicative plasmids in ZM4, (i) the electrotransformation by recombinant plasmid pBBR1MCS‐2‐Pgap‐FLP (6880 bp) was an immediate success with the transformation efficiency 10² transformants/μg DNA; (ii) the site‐specific integration efficiencies (expressed in terms of “per μg of DNA”) of 3–6 integrating transformants was obtained using the integrating plasmid pBR328‐ldhR‐cml‐ldhL (7447 bp). This study will assist genetic and biotechnological research of ZM4 and other Z. mobilis strains by providing information about suitable vectors and a more universal and reliable procedure for introducing DNA into this strain.     

Cloning and characterization of a ribitol dehydrogenase from Zymomonas mobilis

Ribitol dehydrogenase (RDH) catalyzes the conversion of ribitol to d-ribulose. A novel RDH gene was cloned from Zymomonas mobilis subsp. mobilis ZM4 and overexpressed in Escherichia coli BL21(DE3). DNA sequence analysis revealed an open reading frame of 795 bp, capable of encoding a polypeptide of 266 amino acid residues with a calculated molecular mass of 28,426 Da. The gene was overexpressed in E. coli BL21(DE3) and the protein was purified as an active soluble form using glutathione S-transferase affinity chromatography. The molecular mass of the purified enzyme was estimated to be ∼28 kDa by sodium dodecyl sulfate-polyacrylamide gel and ∼58 KDa with gel filtration chromatography, suggesting that the enzyme is a homodimer. The enzyme had an optimal pH and temperature of 9.5 and 65°C, respectively. Unlike previously characterized RDHs, Z. mobilis RDH (ZmRDH) showed an unusual dual coenzyme specificity, with a k _cat of 4.83 s⁻¹ for NADH (k _cat/K _m = 27.3 s⁻¹ mM⁻¹) and k _cat of 2.79 s⁻¹ for NADPH (k _cat/K _m = 10.8 s⁻¹ mM⁻¹). Homology modeling and docking studies of NAD⁺ and NADP⁺ into the active site of ZmRDH shed light on the dual coenzyme specificity of ZmRDH.