Isolation and characterization of mutations affecting expression of the delta9- fatty acid desaturase gene, OLE1, in Saccharomyces cerevisiae

Exogenous Regulators Enhance the Yield and Stress Resistance of Chlamydospores of the Biocontrol Agent Trichoderma harzianum T4

Trichoderma strains have been successfully used in plant disease control. However, the poor stress resistance of mycelia and conidia makes processing and storage difficult. Furthermore, they cannot produce chlamydospores in large quantities during fermentation, which limits the industrialization process of chlamydospore preparation. It is important to explore an efficient liquid fermentation strategy for ensuring chlamydospore production in Trichoderma harzianum. We found that the addition of mannitol, glycine betaine, and N-acetylglucosamine (N-A-G) during liquid fermentation effectively increases the yield of chlamydospores. Furthermore, we provided evidence that chlamydospores have stronger tolerance to high temperature, ultraviolet, and hypertonic stress after the addition of mannitol and trehalose. Lipids are an important component of microbial cells and impact the stress resistance of microorganisms. We studied the internal relationship between lipid metabolism and the stress resistance of chlamydospores by detecting changes in the lipid content and gene expression. Our results showed that mannitol and trehalose cause lipid accumulation in chlamydospores and increase the unsaturated fatty acid content. In conclusion, we verified that these exogenous regulators increase the production of chlamydospores and enhance their stress resistance by regulating lipid metabolism. In addition, we believe that lipid metabolism is an important part of the chlamydospore production process and impacts the stress resistance of chlamydospores. Our findings provide clues for studying the differentiation pathway of chlamydospores in filamentous fungi and a basis for the industrial production of chlamydospores.

Fetal bovine serum concentration affects delta9 desaturase activity of Trypanosoma cruzi

Fetal bovine serum (FBS) is an important factor in the culture of Trypanosoma cruzi, since this parasite obtains and metabolizes fatty acids (FAs) from the culture medium, and changes in FBS concentration reduce the degree of unsaturation of FAs in phosphoinositides. When T. cruzi epimastigotes were cultured with 5% instead of 10% FBS, and stearic acid was used as the substrate, (9) desaturase activity decreased by 50%. Apparent K (m) and V (m) values for stearic acid, determined from Lineaweaver-Burk plots, were 2 microM and 219 pmol/min/mg of protein, respectively. In studies of the requirement for reduced pyridine nucleotide, (9) desaturase activity reached a maximum with 8 microM NADH and then remained constant; the apparent K (m) and V (m) were 4.3 microM and 46.8 pmol/min/mg of protein, respectively. The effect of FBS was observed only for (9) desaturase activity; (12) desaturase activity was not affected. The results suggest that decreased FBS in culture medium is a signal that modulates (9) desaturase activity in T. cruzi epimastigotes.

Primary Structure, Regioselectivity, and Evolution of the Membrane-bound Fatty Acid Desaturases of Claviceps purpurea

Two cDNAs with sequence similarity to fatty acid desaturase genes were isolated from the phytopathogenic fungus, Claviceps purpurea. The predicted amino acid sequences of the corresponding genes, named CpDes12 and CpDesX, share 87% identity. Phylogenetic analysis indicates that CpDes12 and CpDesX arose by gene duplication of an ancestral Delta(12)-desaturase gene after the divergence of Nectriaceae and Clavicipitaceae. Functional expression of CpDes12 and CpDesX in yeast (Saccharomyces cerevisiae) indicated that CpDes12 is primarily a "Delta(12)"-desaturase, whereas CpDesX is a novel desaturase catalyzing "Delta(12)," "Delta(15)," and "omega(3)" types of desaturation with omega(3) activity predominating. CpDesX sequentially desaturates both 16:1-9c and 18:1-9c to give 16:3-9c,12c,15c and 18:3-9c,12c,15c, respectively. In addition, it could also act as an omega(3)-desaturase converting omega(6)-polyunsaturates 18:3-6c,9c,12c, 20:3-8c,11c,14c, and 20:4-5c,8c,11c,14c to their omega(3) counterparts 18:4-6c,9c,12c,15c, 20:4-8c,11c,14c,17c, and 20:5-5c,8c,11c,14c,17c, respectively. By using reciprocal site-directed mutagenesis, we demonstrated that two residues (isoleucine at 152 and alanine at 206) are critical in defining the catalytic specificity of these enzymes and the C-terminal amino acid sequence (residues 302-477) was also found to be important. These data provide insights into the nature of regioselectivity in membrane-bound fatty acid desaturases and the relevant structural determinants. The authors suggest that the regios-electivity of such enzymes may be best understood by considering the relative importance of more than one regioselective preference. In this view, CpDesX is designated as anu + 3(omega(3)) desaturase, which primarily references an existing double bond (nu + 3 regioselectivity) and secondarily shows preference for omega(3) desaturation.

Cooperative activation of lipocalin-type prostaglandin D synthase gene expression by activator protein-2beta in proximal promoter and upstream stimulatory factor 1 within intron 4 in human brain-derived TE671 cells

We investigated the activation mechanism of gene expression of lipocalin-type prostaglandin D synthase (L-PGDS) in human brain-derived TE671 cells. Reporter analyses of constructs carrying various lengths of the promoter region and intron 1 to 6, or 3'-untranslated region of the human L-PGDS gene demonstrated that one atypical E-box (aE-box) at +2569 in intron 4 was critical for transactivation of the gene. The aE-box inside the intron 4 functioned as an enhancer element in both directions and in a cell-type specific manner in TE671 cells. Yeast one-hybrid screening revealed that upstream stimulatory factor (USF) 1 bound to the aE-box. Expression of exogenous USF1 induced the endogenous L-PGDS expression in TE671 cells, whereas administration of USF1 siRNA suppressed L-PGDS expression. Binding of USF1 to the aE-box was confirmed by performing electrophoretic mobility shift assay and chromatin immunoprecipitation assay. Furthermore, USF1-mediated transcriptional activation was dependent upon activator protein (AP)-2beta binding to the AP-2 element at position -98 in the proximal promoter region of human L-PGDS gene. These results indicate that L-PGDS gene expression in TE671 cells was activated by USF1 through the aE-box within intron 4 and cooperatively by AP-2beta in the promoter in a cell-type-specific manner.

Identification and characterization of a very long-chain fatty acid elongase gene in the methylotrophic yeast, Hansenula polymorpha

To understand the biosynthetic network of fatty acids in the methylotrophic yeast Hansenula polymorpha, which is able to produce poly-unsaturated fatty acids, we have attempted to identify genes encoding fatty acid elongase. Here we have characterized HpELO1, a fatty acid elongase gene encoding a 319-amino-acid protein containing five predicted membrane-spanning regions that is conserved throughout the yeast Elo protein family. Phylogenetic analysis of the deduced amino acid sequence suggests that HpELO1 is an ortholog of the Saccharomyces cerevisiae ELO3 gene that is involved in the elongation of very long-chain fatty acids (VLCFAs). In the fatty acid profile of the Hpelo1Delta disruptant by gas chromatography/mass spectrometry, the amount of C24:0 and C26:0 decreased to undetectable levels, whereas there was a large accumulation of C22:0, suggesting that the HpELO1 is involved in the elongation of VLCFAs and is essential for the production of C24:0. Expression of HpELO1 suppressed the lethality of the S. cerevisiae elo2Delta elo3Delta double disruptant and recovered the synthesis of VLCFAs. Similar to the S. cerevisiae elo3Delta strain, the Hpelo1Delta disruptant exhibited the extraordinary growth sensitivity to fumonisin B(1), a ceramide synthase inhibitor. Furthermore, cells of the Hpelo1Delta disruptant were more sensitive to Zymolyase and more flocculent than the wild-type cells, clumping together and falling rapidly out of suspension, suggesting that the Hpelo1Delta mutation causes changes in cell wall composition and structure.

Application of the PHO5-gene-fusion technology to molecular genetics and biotechnology in yeast

Modern biological scientists employ numerous approaches for solving their problems. Among these approaches, the gene fusion is surely one of the well-established valuable tools in various fields of biological sciences. A wide range of applications have been developed to analyze a variety of biological phenomena such as transcriptional regulation, pre-mRNA processing, mRNA decay, translation, protein localization and even protein transport in both prokaryotic and eukaryotic organisms. Gene fusions were also used for the study of protein purification, protein structure, protein folding, protein-protein interaction and protein-DNA interaction. Here, we describe applications of gene fusion technology using the Saccharomyces cerevisiae PHO5 gene encoding repressible acid phosphatase to molecular genetics and biotechnology in S. cerevisiae. Using the PHO5 gene fusion as a reporter, we have identified several cis- and trans-acting genes of S. cerevisiae which are involved in splicing of pre-mRNA, biosynthesis of amino acids, ubiquitin-dependent protein degradation, signal transduction of oxygen and unsaturated fatty acid, regulation of transcription by the nucleosome and chromatin. The PHO5 gene fusions exhibiting the mating-type specific expression were also generated to develop a breeding technique for industrial yeast. It is concluded that the PHO5 gene fusion is extremely useful and should be further exploited to investigate various cellular steps of the eukaryotic gene expression.

Dosage-dependent functions of fatty acid desaturase Ole1p in growth and morphogenesis of Candida albicans

Conditions in the infected human host trigger virulence attributes of the fungal pathogenCandida albicans. Specific inducers and elevated temperatures lead to hyphal development or regulate chlamydospore development. To explore if these processes are affected by membrane lipids, an investigation of the functions of the Ole1 fatty acid desaturase (stearoyl-CoA desaturase) inC. albicans, which synthesizes oleic acid, was undertaken. A conditional strain expressingOLE1from the regulatableMET3promoter was unable to grow in repressing conditions, indicating thatOLE1is an essential gene. In contrast, a mutant lacking both alleles ofOLE2, encoding a Ole1p homologue, was viable and had no apparent phenotypes. Partial repression ofMET3p–OLE1slightly lowered oleic acid levels and decreased membrane fluidity; these conditions permitted growth in the yeast form, but prevented hyphal development in aerobic conditions and blocked the formation of chlamydospores. In contrast, in hypoxic conditions, which trigger an alternative morphogenetic pathway, hyphal morphogenesis was unaffected. Because aerobic morphogenetic signalling and oleic acid biosynthesis require oxygen, it is proposed that oleic acid may function as a sensor activating specific morphogenetic pathways in normoxic conditions.

Merging of multiple signals regulating delta9 fatty acid desaturase gene transcription in Saccharomyces cerevisiae

Fatty acid desaturation, which requires molecular oxygen (O2) as an electron acceptor, is catalyzed by delta9 fatty acid desaturase, which is encoded by OLE1 in Saccharomyces cerevisiae. Transcription of the OLE1 gene is repressed by unsaturated fatty acids (UFAs) and activated by hypoxia and low temperatures via the endoplasmic reticulum membrane protein Mga2p. We previously reported the isolation of the nfo3-1 (negative factor for OLE1) mutant, which exhibits enhanced expression of OLE1 in the presence of UFA and under aerobic conditions. In this work, we demonstrated that the NFO3 gene is identical to OLE1 and that the nfo3-1 mutation (renamed ole1-101) alters arginine-346, in the vicinity of the conserved histidine-rich motif essential for the catalytic function of the Ole1 protein, to lysine. The ratio of UFAs to total fatty acids in the ole1-101 mutant was 60%, compared to 75% in the wild type, suggesting that the reduction in relative levels of intracellular UFAs activates OLE1 transcription. However, in ole1-101 cells grown in the presence of oleic acid, the level of OLE1 expression remained high, although the relative amount of UFAs in the ole1-101 mutant cells was almost the same as that in wild-type cells growing under the same conditions. By contrast, when cells were grown with linoleic acid, which has a lower melting point than oleic acid, the elevation of the OLE1 expression level due to the ole1-101 mutation was almost completely suppressed. These observations suggest that the ole1-101 cells activate OLE1 transcription by sensing not only the intracellular UFA level, but also membrane fluidity or the nature of the UFA species itself. Furthermore, we found that not only the fatty acid- regulated (FAR) element but also the O2- regulated (O2R) element in the OLE1 promoter was involved in the activation of OLE1 transcription by the ole1-101 mutation, and that the effects of the low-oxygen signal and the ole1-101-generated signal on OLE1 expression were not additive. Taken together, these findings suggest that signals associated with hypoxia, low temperatures and intracellular UFA depletion activate OLE1 transcription by a common pathway.

Functional dissection of the global repressor Tup1 in yeast: dominant role of the C-terminal repression domain

In the yeast Saccharomyces cerevisiae, Tup1, in association with Cyc8 (Ssn6), functions as a general repressor of transcription. Tup1 and Cyc8 are required for repression of diverse families of genes coordinately controlled by glucose repression, mating type, and other mechanisms. This repression is mediated by recruitment of the Cyc8-Tup1 complex to target promoters by sequence-specific DNA-binding proteins. We created a library of XhoI linker insertions and internal in-frame deletion mutations within the TUP1 coding region. Insertion mutations outside of the WD domains were wild type, while insertions within the WD domains induced mutant phenotypes with differential effects on the target genes SUC2, MFA2, RNR2, and HEM13. Deletion mutations confirmed previous findings of two separate repression domains in the N and C termini. The cumulative data suggest that the C-terminal repression domain, located near the first WD repeat, plays the dominant role in repression. Although the N-terminal repression domain is sufficient for partial repression, deletion of this region does not compromise repression. Surprisingly, deletion of the majority of the histone-binding domain of Tup1 also does not significantly reduce repression. The N-terminal region containing potential alpha-helical coiled coils is required for Tup1 oligomerization and association with Cyc8. Association with Cyc8 is required for repression of SUC2, HEM13, and RNR2 but not MFA2 and STE2.

Mga2p is a putative sensor for low temperature and oxygen to induce OLE1 transcription in Saccharomyces cerevisiae

Various low-temperature-inducible genes such as fatty acid desaturase genes are essential for all living organisms to acclimate to low temperature. However, a low-temperature signal transduction pathway has not been identified in eukaryotes. In yeast Saccharomyces cerevisiae, the Delta9 fatty acid desaturase gene OLE1 is activated by ubiquitin/proteasome-dependent processing of two homologous endoplasmic reticulum membrane proteins, Spt23p and Mga2p. We found that OLE1 transcription was transiently activated with resultant increases in the degree of unsaturation of total fatty acids when culture temperature was downshifted from 30 degrees C to 10 degrees C. This activation was greatly depressed in Deltamga2 cells. Although Mga2p is essential for hypoxic activation of OLE1 transcription, and its hypoxic functions are repressed by unsaturated fatty acids (UFAs), low-temperature activation of the OLE1 gene was not repressed by UFAs. These observations suggest that low-temperature and hypoxic signal transduction pathways share some components, and Mga2p is the first identified eukaryotic sensor for low temperature and oxygen.

THEGENETICS OFFATTYACIDMETABOLISM INSACCHAROMYCESCEREVISIAE

Long-chain fatty acids are a vital metabolic energy source and are building blocks of membrane lipids. The yeast Saccharomyces cerevisiae is a valuable model system for elucidation of gene-function relationships in such eukaryotic processes as fatty acid metabolism. Yeast degrades fatty acids only in the peroxisome, and recently, genes encoding core and auxiliary enzymes of peroxisomal beta-oxidation have been identified. Mechanisms involved in fatty acid induction of gene expression have been described, and novel fatty acid-responsive genes have been discovered via yeast genome analysis. In addition, a number of genes essential for synthesis of the variety of fatty acids in yeast have been cloned. Advances in understanding such processes in S. cerevisiae will provide helpful insights to functional genomics approaches in more complex organisms.

Identification and characterization of a low oxygen response element involved in the hypoxic induction of a family of Saccharomyces cerevisiae genes. Implications for the conservation of oxygen sensing in eukaryotes

An organism's ability to respond to changes in oxygen tension depends in large part on alterations in gene expression. The oxygen sensing and signaling mechanisms in eukaryotic cells are not fully understood. To further define these processes, we have studied the Delta9 fatty acid desaturase gene OLE1 in Saccharomyces cerevisiae. We have confirmed previous data showing that the expression of OLE1 mRNA is increased in hypoxia and in the presence of certain transition metals. OLE1 expression was also increased in the presence of the iron chelator 1,10-phenanthroline. A 142-base pair (bp) region 3' to the previously identified fatty acid response element was identified as critical for the induction of OLE1 in response to these stimuli using OLE1 promoter-lacZ reporter constructs. Electromobility shift assays confirmed the presence of an inducible band shift in response to hypoxia and cobalt. Mutational analysis defined the nonameric sequence ACTCAACAA as necessary for transactivation. A 20-base pair oligonucleotide containing this nonamer confers up-regulation by hypoxia and inhibition by unsaturated fatty acids when placed upstream of a heterologous promoter in a lacZ reporter construct. Additional yeast genes were identified which respond to hypoxia and cobalt in a manner similar to OLE1. A number of mammalian genes are also up-regulated by hypoxia, cobalt, nickel, and iron chelators. Hence, the identification of a family of yeast genes regulated in a similar manner has implications for understanding oxygen sensing and signaling in eukaryotes.

O2R, a novel regulatory element mediating Rox1p-independent O(2) and unsaturated fatty acid repression of OLE1 in Saccharomyces cerevisiae

Fatty acid desaturation catalyzed by fatty acid desaturases requires molecular oxygen (O(2)). Saccharomyces cerevisiae cells derepress expression of OLE1 encoding Delta9 fatty acid desaturase under hypoxic conditions to allow more-efficient use of limited O(2). It has been proposed that aerobic conditions lead to repression of OLE1 by well-established O(2)-responsive repressor Rox1p, since putative binding sequences for Rox1p are present in the promoter of OLE1. However, we revealed in this study that disruption of ROX1 unexpectedly did not affect the O(2) repression of OLE1, indicating that a Rox1p-independent novel mechanism operates for this repression. We identified by promoter deletion analysis the 50-bp O(2)-regulated (O2R) element in the OLE1 promoter approximately 360 bp upstream of the start codon. Site-directed mutagenesis of the O2R element showed that the putative binding motif (5'-GATAA-3') for the GATA family of transcriptional factors is important for O(2) repression. Anaerobic derepression of OLE1 transcription was repressed by unsaturated fatty acids (UFAs), and interestingly the O2R element was responsible for this UFA repression despite not being included within the fatty acid-regulated (FAR) element previously reported. The fact that such a short 50-bp O2R element responds to both O(2) and UFA signals implies that O(2) and UFA signals merge in the ultimate step of the pathways. We discuss the differential roles of FAR and O2R elements in the transcriptional regulation of OLE1.

Alcohol acetyltransferases and the significance of ester synthesis in yeast

This paper reviews our current knowledge of yeast alcohol acyltransferases. Much of this information has been gathered over the past 10 years through the application of powerful yeast molecular biology techniques. Evidence from gene disruption and expression analysis of members of the alcohol acyltransferase (ATF) gene family indicates that different ester synthases are involved in the synthesis of esters during alcoholic fermentation. The natural physiological rationale behind these enzyme activities remains unclear. However, it is believed that these enzymes may be involved in very different functions, including cellular fatty acid homeostasis and detoxification mechanisms. Insights into the regulation of yeast ester synthesis by oxygen and unsaturated fatty acids have contributed to our understanding of the general mechanisms of gene regulation. In particular, control mechanisms that underpin the oxygen-mediated regulation of ATF1 gene transcription appear to be closely linked to those involved in the regulation of fatty acid metabolism. Data pertaining to the regulation of ATF1 gene transcription have been integrated into a working model for future research.

Regulation and evaluation of five methanol-inducible promoters in the methylotrophic yeast Candida boidinii

We isolated the promoter regions of five methanol-inducible genes (P(AOD1), alcohol oxidase; P(DAS1), dihydroxyacetone synthase; P(FDH1), formate dehydrogenase; P(PMP20), Pmp20; and P(PMP47), Pmp47) from the Candida boidinii genome, and evaluated their strength and studied their regulation using the acid phosphatase gene of Saccharomyces cerevisiae (ScPHO5) as the reporter. Of the five promoters, P(DAS1) was the strongest methanol-inducible promoter whose strength was approximately 1.5 times higher than that of the commonly used P(AOD1) in methanol-induced cells. Although the expression of P(AOD1) and P(DAS1) was completely repressed by the presence of glucose, formate-induced expression of P(FDH1) was not repressed by glucose. Expression under P(PMP47), another methanol-inducible promoter, was highly induced by oleate. The induction kinetics of P(PMP47) and P(DAS1) revealed that methanol induces the expression of peroxisome membrane protein Pmp47, earlier than the expression of matrix enzyme dihydroxyacetone synthase (Das1p), and that this information is contained in the promoter region of the respective gene. This is the first report which evaluates several methanol-inducible promoters in parallel in the methylotrophic yeast.

Long-chain acyl-CoA-dependent regulation of gene expression in bacteria, yeast and mammals

Fatty acyl-CoA thioesters are essential intermediates in lipid metabolism. For many years there have been numerous conflicting reports concerning the possibility that these compounds also serve regulatory functions. In this review, we examine the evidence that long-chain acyl-CoA is a regulatory signal that modulates gene expression. In the bacteria Escherichia coli, long-chain fatty acyl-CoA bind directly to the transcription factor FadR. Acyl-CoA binding renders the protein incapable of binding DNA, thus preventing transcription activation and repression of many genes and operons. In the yeast Saccharomyces cerevisiae, genes encoding peroxisomal proteins are activated in response to exogenously supplied fatty acids. In contrast, growth of yeast cells in media containing exogenous fatty acids results in repression of a number of genes, including that encoding the delta9-fatty acid desaturase (OLE1). Both repression and activation are dependent upon the function of either of the acyl-CoA synthetases Faa1p or Faa4p. In mammals, purified hepatocyte nuclear transcription factor 4alpha (HNF-4alpha) like E. coli FadR, binds long chain acyl-CoA directly. Coexpression of HNF-4alpha and acyl-CoA synthetase increases the activation of transcription of a fatty acid-responsive promoter, whereas coexpression with thioesterase decreases the fatty acid-mediated response. Conflicting data exist in support of the notion that fatty acyl-CoA are natural ligands for peroxisomal proliferator-activated receptor alpha (PPARalpha).

Molecular mechanism of the multiple regulation of the Saccharomyces cerevisiae ATF1 gene encoding alcohol acetyltransferase

The ATF1 gene encodes an alcohol acetyl transferase (AATase), that catalyses the synthesis of acetate esters from acetyl CoA and several kinds of alcohols. ATF1 transcription is negatively regulated by unsaturated fatty acids and oxygen. A series of analyses of the ATF1 promoter identified an 18 bp element essential for transcriptional activation. Ligation of the 18 bp element into a plasmid carrying the CYC1 promoter deleted UAS-activated transcription and conferred transcriptional repression by unsaturated fatty acids. The 18 bp element contains a binding sequence for Rap1p, which is a transcriptional repressor and activator. In vitro binding studies showed that Rap1p binds to the 18 bp element essential for transcriptional activation. The results of internal deletion studies of the promoter region suggested that there was also a region responsible for ATF1 oxygen regulation. This region contained the consensus binding sequence for the hypoxic repressor Rox1p. In vitro binding studies showed that Rox1p binds to the region responsible for oxygen regulation. To investigate the effect of the hypoxic repressor complex on transcription, ATF1 expression was measured in rox1, tup1 and ssn6 disruptant strains. It was found that rox1, tup1 and ssn6 disruption caused elevated expression of ATF1 under aerobic conditions. Thus, the activation of ATF1 transcription is dependent on Rap1p, and the Rox1p-Tup1p-Ssn6p hypoxic repressor complex is responsible for repression by oxygen. Furthermore, a study of ATF1 expression in a sch9 null mutant suggested that the Sch9p protein kinase is involved in ATF1 trancriptional activation.