Molecular characterization of a cellulase-negative mutant of Hypocrea jecorina

The "cbh2 activating element," CAE, consisting of two separate boxes (ATTGG = CCAAT and GTAATA, respectively) is essential for cellobiohydrolase II gene expression in the filamentous fungus Hypcrea jecorina. Here we report that cell-free extracts from a cellulase-negative mutant form CAE-protein complexes with higher mobility and lower binding-strength compared to the wild type. EMSA analysis demonstrated an increased mobility of the GTAATA-binding protein complex and, supported by in vivo footprinting, a lowered binding strength of the HAP2/3/5 proteins. However, the hap2/hap3/hap5 genes of the mutant are unaltered and transcribed normally. A nucleotide fragment of the cbh1 promoter containing a (GG)CTAATA motif without an adjacent CCAAT box is also bound by cell-free extracts of H. jecorina, and the protein-DNA complex of the mutant shows the characteristic increase in mobility. We conclude that this mutant is defective in the functional formation of the CAE-protein complexes but not in their binding to the target sequences itself.     

Effect of different carbon sources on cellulase production by Hypocrea jecorina (Trichoderma reesei) strains

The ascomycete Hypocrea jecorina, an industrial (hemi)cellulase producer, can efficiently degrade plant polysaccharides. At present, the biology underlying cellulase hyperproduction of T. reesei, and the conditions for the enzyme induction, are not completely understood. In the current study, three different strains of T. reesei, including QM6a (wild-type), and mutants QM9414 and RUT-C30, were grown on 7 soluble and 7 insoluble carbon sources, with the later group including 4 pure polysaccharides and 3 lignocelluloses. Time course experiments showed that maximum cellulase activity of QM6a and QM9414 strains, for the majority of tested carbon sources, occurred at 120 hrs, while RUT-C30 had the greatest cellulase activity around 72 hrs. Maximum cellulase production was observed to be 0.035, 0.42 and 0.33 µmol glucose equivalents using microcrystalline celluloses for QM6a, QM9414, and RUTC-30, respectively. Increased cellulase production was positively correlated in QM9414 and negatively correlated in RUT-C30 with ability to grow on microcrystalline cellulose.     

Metabolic engineering strategies for the improvement of cellulase production by Hypocrea jecorina

Hypocrea jecorina (= Trichoderma reesei) is the main industrial source of cellulases and hemicellulases used to depolymerise plant biomass to simple sugars that are converted to chemical intermediates and biofuels, such as ethanol. Cellulases are formed adaptively, and several positive (XYR1, ACE2, HAP2/3/5) and negative (ACE1, CRE1) components involved in this regulation are now known. In addition, its complete genome sequence has been recently published, thus making the organism susceptible to targeted improvement by metabolic engineering. In this review, we summarise current knowledge about how cellulase biosynthesis is regulated, and outline recent approaches and suitable strategies for facilitating the targeted improvement of cellulase production by genetic engineering.     

Glycerol catabolism in wild-type and mutant strains ofPseudomonas aeruginosa

Glycerol uptake, glycerol kinase (EC 2.7.1.30) and glycerol-3-phosphate dehydrogenase (EC 1.1.99.5) activities are specifically induced during growth ofPseudomonas aeruginosa PAO on either glycerol or glycerol-3-phosphate. Mutants of strain PAO unable to grow on both glycerol and glycerol-3-phosphate were isolated. Mutant PFB 121 was deficient in an inducible, membrane-bound, pyridine nucleotide-independent, glycerol-3-phosphate dehydrogenase activity and PFB 82 was deficient in glycerol uptake and glycerol kinase and glycerol-3-phosphate dehydrogenase activities. Each mutant spontaneously reverted to wild phenotype, which indicates that each contained a single genetic lesion. These results demonstrate that membrane-bound, inducible glycerol-3-phosphate dehydrogenase is required for catabolism of both glycerol and glycerol-3-phosphate and provide suggestive evidence for a single regulatory locus that controls the synthesis of glycerol uptake, glycerol kinase, and glycerol-3-phosphate dehydrogenase inP. aeruginosa.     

Erythritol metabolism in wild-type and mutant strains of Schizophyllum commune

Erythritol uptake and metabolism were compared in wild-type mycelium and a dome morphological mutant of the wood-rotting mushroom Schizophyllum commune. Wild-type mycelium utilized glucose, certain hexitols, and pentitols including ribitol, as well as d-erythrose, erythritol, and glycerol as sole carbon sources for growth. The dome mutant utilized all of these compounds except d-erythrose and erythritol. Erythritol- or glycerol-grown wild-type mycelium incorporated erythritol into various cellular constituents, whereas glucose-grown cells lagged considerably before initiation of erythritol uptake. This acquisition was inhibited by cycloheximide. Dome mycelium showed behavior similar to wild-type in uptake of erythritol after growth on glucose or glycerol, except that erythritol was not further catabolized. Enzymes of carbohydrate metabolism were compared in cell extracts of glucose-cultured wild-type mycelium and dome. Enzymes of hexose monophosphate catabolism, nicotinamide adenine dinucleotide (NAD)-dependent sugar alcohol dehydrogenases, and reduced nicotinamide adenine dinucleotide phosphate (NADPH)-coupled erythrose reductase were demonstrated in both. The occurrence of erythrose reductase was unaffected by the nature of the growth carbon source, showed optimal activity at pH 7, and generated NAD phosphate and erythritol as products of the reaction. Glycerol-, d-erythrose-, or erythritol-grown wild-type mycelium contained an NAD-dependent erythritol dehydrogenase absent in glucose cells. Erythritol dehydrogenase activity was optimal at pH 8.8 and produced erythrulose during NAD reduction. Glycerol-growth of dome mycelium induced the erythritol uptake system, but a functional erythritol dehydrogenase could not be demonstrated. Neither wild-type nor dome mycelium produced erythritol dehydrogenase during growth on ribitol. Erythritol metabolism in wild-type cells of S. commune, therefore, involves an NADPH-dependent reduction of d-erythrose to produce erythritol, followed by induction of an NAD-coupled erythritol dehydrogenase to form erythrulose. A deficiency in erythritol dehydrogenase rather than permeability barriers explains why dome cannot employ erythritol as sole carbon source for mycelial growth.     

Glutamate transport in wild-type and mutant strains of Escherichia coli

Halpern, Yeheskel S. (Hebrew University-Hadassah Medical School, Jerusalem, Israel), and Meir Lupo. Glutamate transport in wild-type and mutant strains of Escherichia coli. J. Bacteriol. 90:1288-1295. 1965.-Mutants of Escherichia coli able to grow on glutamate as their source of carbon showed glutamate dehydrogenase and glutamate-oxaloacetate transaminase activities similar to those possessed by the parent strain. The mutants took up glutamate at a much faster rate and showed a several-fold greater capacity for concentrating the amino acid than did the corresponding parent strains. Curvilinear double reciprocal plots of velocity of uptake versus glutamate concentration were obtained with the E. coli H strains. A break in the curve of glutamate uptake was observed with the E. coli K-12 strains when incubated in a glucose medium. It is suggested that these findings may be due to allosteric activation of glutamate permease by its substrate.     

The metabolic role and evolution of L-arabinitol 4-dehydrogenase of Hypocrea jecorina.

L-Arabinitol 4-dehydrogenase (Lad1) of the cellulolytic and hemicellulolytic fungus Hypocrea jecorina (anamorph: Trichoderma reesei) has been implicated in the catabolism of L-arabinose, and genetic evidence also shows that it is involved in the catabolism of D-xylose in xylitol dehydrogenase (xdh1) mutants and of D-galactose in galactokinase (gal1) mutants of H. jecorina. In order to identify the substrate specificity of Lad1, we have recombinantly produced the enzyme in Escherichia coli and purified it to physical homogeneity. The resulting enzyme preparation catalyzed the oxidation of pentitols (L-arabinitol) and hexitols (D-allitol, D-sorbitol, L-iditol, L-mannitol) to the same corresponding ketoses as mammalian sorbitol dehydrogenase (SDH), albeit with different catalytic efficacies, showing highest k(cat)/K(m) for L-arabinitol. However, it oxidized galactitol and D-talitol at C4 exclusively, yielding L-xylo-3-hexulose and D-arabino-3-hexulose, respectively. Phylogenetic analysis of Lad1 showed that it is a member of a terminal clade of putative fungal arabinitol dehydrogenase orthologues which separated during evolution of SDHs. Juxtapositioning of the Lad1 3D structure over that of SDH revealed major amino acid exchanges at topologies flanking the binding pocket for d-sorbitol. A lad1 gene disruptant was almost unable to grow on L-arabinose, grew extremely weakly on L-arabinitol, D-talitol and galactitol, showed reduced growth on D-sorbitol and D-galactose and a slightly reduced growth on D-glucose. The weak growth on L-arabinitol was completely eliminated in a mutant in which the xdh1 gene had also been disrupted. These data show not only that Lad1 is indeed essential for the catabolism of L-arabinose, but also that it constitutes an essential step in the catabolism of several hexoses; this emphasizes the importance of such reductive pathways of catabolism in fungi.     

Phosphorylation positively regulates DNA binding of the carbon catabolite repressor Cre1 of Hypocrea jecorina (Trichoderma reesei)

Cre1 of the ascomycete Hypocrea jecorina is a Cys(2)His(2) zinc finger DNA-binding protein functioning as regulator for carbon catabolite repression. It represents the functional equivalent of yeast Mig1, known to be negatively regulated by the Snf1-kinase at the nuclear import level. We demonstrate that Cre1 is also a phosphoprotein, and identify Ser(241) within an acidic protein region as phosphorylation target. In contrast to Mig1 phosphorylation is required for DNA binding of Cre1. A S241E mutation mimics phosphorylation, whereas a S241A mutant protein shows phosphorylation-independent DNA binding activity, suggesting that phosphorylation is required to release Cre1 from an inactive conformation involving unphosphorylated Ser(241). Retransformation of a H. jecorina cre1-non functional mutant with Cre1-S241A leads to permanent carbon catabolite repression in cellobiohydrolase I expression. Contrary to Mig1, the amino acid sequence surrounding Ser(241) (HSNDEDD) suggests that phosphorylation may occur by a casein kinase II-like protein. This is supported by a mutation of E244V leading to loss of phosphorylation, loss of DNA binding, and gain of carbon catabolite derepression. Our results imply that the regulation of carbon catabolite repression at the level of DNA binding strongly differs between Saccharomyces cerevisiae and H. jecorina.     

Three-dimensional structure of an intact glycoside hydrolase family 15 glucoamylase from Hypocrea jecorina

The three-dimensional structure of a complete Hypocrea jecorina glucoamylase has been determined at 1.8 A resolution. The presented structure model includes the catalytic and starch binding domains and traces the course of the 37-residue linker segment. While the structures of other fungal and yeast glucoamylase catalytic and starch binding domains have been determined separately, this is the first intact structure that allows visualization of the juxtaposition of the starch binding domain relative to the catalytic domain. The detailed interactions we see between the catalytic and starch binding domains are confirmed in a second independent structure determination of the enzyme in a second crystal form. This second structure model exhibits an identical conformation compared to the first structure model, which suggests that the H. jecorina glucoamylase structure we report is independent of crystal lattice contact restraints and represents the three-dimensional structure found in solution. The proposed starch binding regions for the starch binding domain are aligned with the catalytic domain in the three-dimensional structure in a manner that supports the hypothesis that the starch binding domain serves to target the glucoamylase at sites where the starch granular matrix is disrupted and where the enzyme might most effectively function.     

The neutral carotenoids of wild-type and mutant strains of Neurospora crassa

The neutral carotenoids of wild-type Neurospora crassa and of carotenoid mutants at four discrete genetic loci were isolated using gradient elution chromatography on deactivated alumina columns. Carotenoids were identified by absorption spectrophotometry and thin layer cochromatography with carotenoid standards. Phytoene, phytofluene, -carotene, -carotene, neurosporene, torulene, lycopene, and 3,4-dehydrolycopene were isolated from wild type. Phytoene, phytofluene, -carotene, -carotene, neurosporene, -carotene, lycopene, and one unknown carotenoid, tentatively identified as 15,15-cis--carotene, were isolated from a yellow mutant, ylo-1. ylo-1 also contained residual carotenoids having similar absorption spectra to, but very different chromatographic behavior from, phytofluene, -carotene, -carotene, and lycopene. Albino and colored al-1 mutants contained large amounts of phytoene and only traces of other neutral carotenoids. Albino al-2 and al-3 mutants contained only traces of neutral carotenoids.     

Growth and production of anthracyclines in wild-type and mutant strains ofStreptomyces galilaeus

The course of growth curves with respect to the biosynthesis of anthracyclines was followed in the wild low-producing strain Streptomyces galilaeus JA 3043 and in its mutants G-167 (producing increased quantities of glycosides of epsilon-pyrromycinone) and J-14 (accumulating free epsilon-pyrromycinone). A two-phase type of fermentation (growth phase, production phase) was observed in strains JA 3043 and J-14. The maximum production of anthracyclines occurred only after the end of intense growth of the culture. Two phases of rapid growth separated by a phase of stagnation were observed in strain G-167. The second growth phase proceeded only during late hours of cultivation and was (as compared with the first phase) associated with an intensive biosynthesis of anthracyclines.     

Xylulose fermentation by mutant and wild-type strains of Zygosaccharomyces and Saccharomyces cerevisiae

Anaerobic xylulose fermentation was compared in strains of Zygosaccharomyces and Saccharomyces cerevisiae, mutants and wild-type strains to identify host-strain background and genetic modifications beneficial to xylose fermentation. Overexpression of the gene (XKS1) for the pentose phosphate pathway (PPP) enzyme xylulokinase (XK) increased the ethanol yield by almost 85% and resulted in ethanol yields [0.61 C-mmol (C-mmol consumed xylulose)⁻¹] that were close to the theoretical yield [0.67 C-mmol (C-mmol consumed xylulose)⁻¹]. Likewise, deletion of gluconate 6-phosphate dehydrogenase (gnd1Δ) in the PPP and deletion of trehalose 6-phosphate synthase (tps1Δ) together with trehalose 6-phosphate phosphatase (tps2Δ) increased the ethanol yield by 30% and 20%, respectively. Strains deleted in the promoter of the phosphoglucose isomerase gene (PGI1) – resulting in reduced enzyme activities – increased the ethanol yield by 15%. Deletion of ribulose 5-phosphate (rpe1Δ) in the PPP abolished ethanol formation completely. Among non-transformed and parental strains S. cerevisiae ENY. WA-1A exhibited the highest ethanol yield, 0.47 C-mmol (C-mmol consumed xylulose)⁻¹. Other non-transformed strains produced mainly arabinitol or xylitol from xylulose under anaerobic conditions. Contrary to previous reports S. cerevisiae T23D and CBS 8066 were not isogenic with respect to pentose metabolism. Whereas, CBS 8066 has been reported to have a high ethanol yield on xylulose, 0.46 C-mmol (C-mmol consumed xylulose)⁻¹ (Yu et al. 1995), T23D only formed ethanol with a yield of 0.24 C-mmol (C-mmol consumed xylulose)⁻¹. Strains producing arabinitol did not produce xylitol and vice versa. However, overexpression of XKS1 shifted polyol formation from xylitol to arabinitol. Received: 2 July 1999 / Accepted in revised form: 12 October 1999     

Sophorolipids-induced cellulase production in cocultures of Hypocrea jecorina Rut C30 and Candida bombicola

Sophorose is a potent but expensive inducer for cellulase production. In this study the feasibility of using sophorolipids, natural lipids that contain sophorose, for cellulase induction was investigated. Enhanced cellulase production by Hypocrea jecorina Rut C30 grown on glycerol, a substrate without cellulase-inducing ability, was first confirmed by addition of the crude sophorolipids collected from Candida bombicola fermentation. Cocultures of H. jecorina Rut C30 and C. bombicola were then employed to evaluate the effects of coculture conditions: the cell concentration ratio between the two cultures, the concentration of vegetable oil (as lipid precursor for sophorolipid synthesis, in addition to glycerol as the primary carbon source), the presence of nitrogen source for growth, and the substitution of glucose for glycerol as the primary carbon source. Specific cellulase productivity of H. jecorina Rut C30 was significantly higher under the conditions that promoted sophorolipid production by C. bombicola. The ability of H. jecorina Rut C30 to degrade sophorolipids was also confirmed. The results of the study indicated that the sophorolipids produced by C. bombicola can be degraded by H. jecorina Rut C30 and the sophorose generated from the degradation can effectively induce the fungal cellulase synthesis.