Deletion analysis of the Ure2p in Saccharomyces cerevisiae and effect of NCR on the production of ethyl carbamate during wine fermentations

Erasmus, Daniel J.

12 1900

Thesis (MSc)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: The wine yeast Saccharomyces cerevisiae has the ability to utilize several different nitrogenous compounds to fulfill its metabolic requirements. Based upon different growth rates of the yeast in a particular nitrogen source, nitrogen compounds have been classified as either good or poor nitrogen sources. In an environment which contains different quality nitrogen sources, such as grape must, the yeast first utilizes good and then the poor nitrogen sources. This discrimination between good and poor nitrogen sources is referred to as nitrogen catabolite repression (NCR). Examples of good nitrogen sources are ammonia, glutamine and asparagine. Nitrogen sources such as allantoin, y-aminobutyrate (GABA), arginine and proline are poor quality nitrogen sources. Several regulatory proteins, Ure2p, Gln3p, Da180p,Gat1pand Deh1p, mediate NCR in S. cerevisiae. These trans-acting factors regulate transcription of NCR sensitive genes. All these proteins, except Ure2p, bind cis-acting elements in the promoters of genes that are responsible for degradation of poor nitrogen sources. Gln3p is an activator of NCR sensitive genes in the absence of good nitrogen sources. The predominant mechanism by which NCR functions is by using Ure2p to inactivate the activator Gln3p in the presence of a good nitrogen source. Several research groups have studied the Ure2p, mainly due to its prion-like characteristics. The Ure2p has two domains: a prion inducing domain located in the N-terminal region and a NCR regulatory domain located in the C-terminal domain. The aims of this study were (i) to determine the part of the C-terminal domain which is responsible for NCR, (ii) to establish if ure2 deletion mutants produce less ethyl carbamate during wine fermentations and (iii) if NCR functions in industrial yeast strains. Nested deletions of the URE2 gene revealed that the NCR regulatory domain resides in the last ten amino acids of the Ure2p. This was established by Northern blot analysis on the NCR sensitive genes DAL5, CAN1, and GAP1 genes. Ethyl carbamate in wine is produced by spontaneous chemical reaction between urea and ethanol in wine. Urea is produced by S. cerevisiae during the metabolism of arginine. Arginine is degraded to ornithine and urea by arginase, the product of the CAR1 gene. Degradation of urea by S. cerevisiae is accomplished by urea amidolyase, a bi-functional enzyme and product of the DUR1,2 gene which is subject to NCR. This study investigated if a ure2 mutant strain produced less ethyl carbamate during wine fermentations. Wine fermentations were conducted with diploid laboratory strains: a ure2 mutant strain and its isogenic wild type strain. GC/MS analysis of the wine revealed that the ure2 mutant produced less ethyl carbamate but more ethanol than the wild type strain when arginine, di-ammoniumphosphate, asparagine or glutamine were added as nitrogen sources, in combinations and separately. There was no significant difference between the wild type fermentation and the ure2 mutant fermentation when no nitrogen was added. It was found that a combination between the deletion of URE2 and the addition of a good nitrogen source resulted in lower levels of ethyl carbamate. High density micro array analysis done on an industrial strain wine yeast in Chardonnay grape must revealed that the GAP1, CAN1, CAR1 and DUR1,2 genes, responsible for transport and metabolism of arginine and degradation of urea, are NCR sensitive. These data strongly suggest that NCR functions in industrial yeast strains. / AFRIKAANSE OPSOMMING: Die wyngis Saccharomyces cerevisiae kan verskillende stikstofbronne gebruik om in sy stikstofbehoeftes te voldoen. Stikstofbronne word as goeie of swak stikstofbronne geklassifiseer op grond van die groeitempo van die gis op die betrokke stikstofbron. 'n Goeie stikstofbron laat die gis vinniger groei as wat dit op 'n swak stikstofbron sou groei. In omgewings soos druiwemos waar daar 'n verskeidenheid van stikstofbronne teenwoordig is, sal die gis eers die goeie bronne en daarna die swak bronne benut. Stikstofbronne soos ammonium, asparagien en glutamien word geklassifiseer as goeie bronne. Allantoïen, y-amino-butaraat (GABA), prolien en arginien word as swak stikstofbronne geklassifiseer. Die meganisme waarmee S. cerevisiae tussen die stikstofbronne onderskei, staan as stikstof kataboliet onderdrukking (NCR) bekend. Die proteïene wat vir verantwoordelik is NCR naamlik Ure2p, Gln3p, Gat1 p, Dal80p en Deh1 p, bind met die uitsondering van Ure2p, almal aan cis-werkende elemente in die promoters van NCR-sensitiewe gene. Die trans-werkende faktore reguleer die transkripsie van NCR-sensitiewe gene. NCR werk hoofsaaklik deur die inhibering van Gln3p deur Ure2p in die teenwoordigheid van 'n goeie stikstofbron. Die oorgrote meerderheid NCR-sensitiewe gene word deur Gln3p in die afwesigheid van 'n goeie stikstofbron geaktiveer. Heelwat navorsing is op die prionvormings vermoë van Ure2p gedoen. Ure2p het twee domeine: 'n N-terminale domein wat vir prionvorming verantwoordelik is en die C-terminale domein waar die NCR funksie van Ure2p gesetel is. Die doel van die studie was (i) om te bepaal waar in die C-terminale domein van Ure2p die NCR regulering geleë is, (ii) of ure2 delesie mutante minder etielkarbamaat tydens wynfermentasies produseer en (iii) of NCR in industriële gisrasse funksioneel is. Delesie analises van URE2 het getoon dat die NCR regulerings domein in die laaste tien aminosure gesetel is. Dit is vas gestel m.b.v. noordlike klad tegniek analises op die OALS, CAN1 en GAP1 gene.Etielkarbamaat in wyn word deur die spontane chemiese reaksie tussen ureum en alkohol geproduseer. Ureum word gedurende die metabolisme van arginien in S. cerevisiae geproduseer. Arginien word deur arginase, produk van die CAR1 geen, na ornitien en ureum afgebreek. Die bi-funksionele ureum amidoliase, gekodeer deur die DUR1,2 geen, breek ureum na CO2 en NH/ af. As gevolg van die NCRsensitiwiteit van dié gene is ondersoek ingestel na In ure2 mutant se vermoë om minder etielkarbamaat tydens wynfermentasies te produseer. Chardonnay druiwemos is met In diploiede laboratorium ras en die isogeniese ure2 mutant gefermenteer. GC/MS analise op die wyn het getoon dat die ure2 mutant minder etielkarbamaat, maar meer alkohol in vergelyking met die wilde tipe gis produseer, as arginien, di-ammoniumfosfaat, asparagien en glutamien, afsonderlik of gesamentlik byvoeg is. Daar was egter nie In merkwaardige verskil tussen die fermentasies waar geen stikstof bygevoeg is nie. Dit dui daarop dat In kombinasie van In URE2 delesie en die byvoeging van stikstof etielkarbamaat vlakke verlaag. Mikro-skyfie analise van In industriële gis in Chardonnay mos het getoon dat die GAP1, CAN1, CAR1 en DUR1,2 gene wat verantwoordelik is vir die transport en metabolisme van arginien en degradasie van ureum, wel NCR-sensitief is. Dit dui daarop dat NCRwel in industriële gisrasse funksioneel is.

Fermentation

Wine and wine making -- Microbiology

Saccharomyces cerevisiae

Urethane

Nitrogen catabolite repression

Studies on the regulation of conidiation in species of Trichoderma

Steyaert, Johanna M.

January 2007

A characteristic feature of species of Trichoderma is the production of concentric rings of conidia in response to alternating light-dark conditions. In response to a single burst of light, a single ring of conidia forms at what was the colony perimeter. On the basis of these observations, competency to photoconidiate has been proposed to be due to the age and metabolic rate of the hyphal cell. In this study, conidiation was investigated in five biocontrol isolates (T. hamatum, T. atroviride, T. asperellum, T. virens and T. harzianum) using both a morphological and molecular approach. All five isolates produced concentric conidial rings under alternating light-dark conditions on potato-dextrose agar (PDA), however, in response to a 15 min burst of blue light, only T. asperellum and T. virens produced a clearly, defined conidial ring which correlated with the colony margin at the time of light exposure. Both T. harzianum and T. hamatum photoconidiated in a disk-like fashion and T. atroviride produced a broken ring with a partially filled in appearance. On the basis of these results, it was postulated that competency to photoconidiate is a factor of the metabolic state of the hyphal cell rather than chronological age or metabolic rate. The influence of the source of nitrogen on photoconidiation was assessed on pH-buffered (pH 5.4) minimal medium (MM) amended with glutamine, urea or KNO₃. In the presence of glutamine or urea, T. asperellum and T. harzianum conidiated in a disk, whereas, when KNO₃ was the sole nitrogen source, a ring of conidia was produced. Further, in the presence of increasing amounts of glutamine, the clearly defined photoconidial ring produced on PDA by T. asperellum became disk-like. These results clearly demonstrated that primary nitrogen promotes photoconidiation in these isolates and strongly suggests that competency of a hyphal cell to conidiate in response to light is dependent on the nitrogen catabolite repression state of the cell. The experiments were repeated for all five isolates on unbuffered MM. Differences were apparent between the buffered and unbuffered experiments for T. atroviride. No photoconidiation was observed in T. atroviride on buffered medium whereas on unbuffered medium, rings of conidia were produced on both primary and secondary nitrogen. These results show that photoconidiation in T. atroviride is influenced by the buffering capacity of the medium. Conidiation in response to light by T. hamatum and T. virens was absent in all nitrogen experiments, regardless of the nitrogen source and buffering capacity, whereas both isolates conidiated in response to light on PDA. These results imply that either both sources of nitrogen are required for photoconidiation, or a factor essential for conidiation in these two isolates was absent in the minimal medium. Mycelial injury was also investigated in five biocontrol isolates of Trichoderma. On PDA, all isolates except T. hamatum conidiated in response to injury. On nitrogen amended MM, conidiation in response to injury was again observed in all isolates except for T. hamatum. In T. atroviride, injury-induced conidiation was observed on all medium combinations except the pH-buffered MM amended with glutamine or urea and T. virens conidiated in response to injury on primary nitrogen only, regardless of the buffering capacity. These results have revealed conidiation in response to injury to be differentially regulated between isolates/species of Trichoderma. On unbuffered MM amended with glutamine or urea, conidiation in response to injury occurred at the colony perimeter only in T. atroviride. It was hypothesised that the restriction of conidiation to the perimeter may be due to changes in the pH of the agar. The experiment was repeated and the pH values of the agar under the growing colony measured at the time of light induction (48 h) or injury (72 h). The areas under the hyphal fronts were acidified to below the starting value of the medium (pH 5.4) and the centres of the plates were alkalinised. The region of acidification at the time of stimuli correlated with the production of conidia, which implicates a role for crossregulation of conidiation by the ambient pH. The influence of the ambient pH on injury-induced conidiation was investigated in T. hamatum and T. atroviride on MM amended with glutamine and PDA, pH-buffered from pH 2.8 to 5.6. Thickening of the hyphae around the injury site was observed at the lowest pH values on MM in both T. atroviride and T. hamatum, however no conidia were produced, whereas both Trichoderma species conidiated on pH-buffered PDA in a strictly low pH-dependent fashion. This is the first observation of injury-induced conidiation in T. hamatum. The influence of the ambient pH on photoconidiation was assessed in T. hamatum, T. atroviride and T. harzianum using both buffered and unbuffered PDA from pH 2.8 to 5.2. On buffered PDA, no conidiation in response to light was observed above pH 3.2 in T. hamatum, above 4.0 in T. atroviride and above 4.4 in T. harzianum, whereas on unbuffered PDA it occurred at all pH values tested. It was postulated that conidiation at pH values above 4.4 on unbuffered PDA was due to acidification of the agar. The pH values of the agar under the growing colony were measured at the time of light exposure and in contrast to the MM with glutamine experiments, alkalisation of the agar had occurred in both T. atroviride and T. hamatum. No change in medium pH was recorded under the growing T. harzianum colony. These results indicate that low pH-dependence of photoconidiation is directly related to the buffering capacity of the medium. Recent studies have linked regulation of conidiation in T. harzianum to Pac1, the PacC orthologue. In fungi, PacC regulates gene expression in response to the ambient pH. In these studies pH-dependent photoconidiation occurred only on buffered PDA and on unbuffered PDA conidiation occurred at significantly higher ambient pH levels. It is proposed that the influence of ambient pH on conidiation in the isolates used in this study is not due to direct Pac1 regulation. The T. harzianum isolate used in this study produced profuse amounts of the yellow anthraquinone pachybasin. Production of this secondary metabolite was strictly pH-dependent, irrespective of the buffering capacity of the medium. Studies in T. harzianum have linked Pac1 regulation to production of an antifungal α-pyrone. pH-dependence on both buffered and unbuffered media strongly suggests that pachybasin production may also be under the control of Pac1. Photoconidiation studies on broth-soaked filter paper, revealed rhythmic conidiation in the pachybasin producing T. harzianum isolate. Diffuse rings of conidia were produced in dark-grown cultures and, in cultures exposed to light for 15 min at 48 h, the rings were clearly defined. These results show that conidiation is under the control of an endogenous rhythm in T. harzianum and represent the first report of circadian conidiation in a wild-type Trichoderma. A Free-Running Rhythm (FRR) assay was used to investigate rhythmic gene expression in T. atroviride IMI206040 and a mutant derivative, in which the wc-2 orthologue, blr-2, was disrupted. Over a 3 d period, expression of gpd, which encodes the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase, oscillated with a period of about 48 h. In the Δblr-2 mutant, the gpd rhythm was absent. These results revealed that in T. atroviride, gpd expression is under the control of an endogenous clock and that clock-regulated expression of gpd is associated with a functional BLR complex. Using degenerate primers, a portion of frq, which encodes the N. crassa clock oscillator FREQUENCY, was isolated from T. atroviride and used to probe the FRR assay northern blots. No frq expression was detected at any time point, which suggests that the circadian clock in Trichoderma does not involve FREQUENCY. In a concurrent study, orthologues of rco-1 (rcoT) were isolated and sequenced from T. atroviride and T. hamatum using a combination of degenerate, inverse and specific PCR. RcoT is an orthologue of the yeast global co-repressor Tup1 and in the filamentous fungi, RcoT orthologues have been demonstrated to negatively regulate conidiation. Genomic analysis of all available rcoT orthologues revealed the conservation of erg3, a major ergosterol biosynthesis gene, upstream from rcoT in ascomycetous filamentous fungi, but not in the ascomycetous yeast or in the basidiomycetes. These studies have significantly contributed to our understanding of the regulatory factors controlling conidiation in Trichoderma and have multiple implications for Trichoderma biocontrol; most notable the promotion of conidiation by primary nitrogen and low pH. Incubation conditions can be altered to suit the nitrogen and pH preferences of a biocontrol strain in order to promote cost effective conidial production, however this is not easily achieved in the soil, where the biocontrol strain must perform in a highly buffered environment optimised for plant growth. Successful use of Trichoderma biocontrol strains may involve the screening and targeting of strains to the appropriate pH conditions or the selection of new strains on the basis of capacity to perform under a given range of conditions.

Trichoderma

conidiation

nitrogen catabolite repression

pH regulation

anthraquinone

pachybasin

circadian

free-running rhythm

blr-1

frq

gpd

rcoT

erg3

con-10

A Global Kinase and Phosphatase Interaction Network in the Budding Yeast Reveals Novel Effectors of the Target of Rapamycin (TOR) Pathway

Sharom, Jeffrey Roslan

31 August 2011

In the budding yeast Saccharomyces cerevisiae, the evolutionarily conserved Target of Rapamycin (TOR) signaling network regulates cell growth in accordance with nutrient and stress conditions. In this work, I present evidence that the TOR complex 1 (TORC1)-interacting proteins Nnk1, Fmp48, Mks1, and Sch9 link TOR to various facets of nitrogen metabolism and mitochondrial function. The Nnk1 kinase controlled nitrogen catabolite repression-sensitive gene expression via Ure2 and Gln3, and physically interacted with the NAD+-linked glutamate dehydrogenase Gdh2 that catalyzes deamination of glutamate to alpha-ketoglutarate and ammonia. In turn, Gdh2 modulated rapamycin sensitivity, was phosphorylated in Nnk1 immune complexes in vitro, and was relocalized to a discrete cytoplasmic focus in response to NNK1 overexpression or respiratory growth. The Fmp48 kinase regulated respiratory function and mitochondrial morphology, while Mks1 linked TORC1 to the mitochondria-to-nucleus retrograde signaling pathway. The Sch9 kinase appeared to act as both an upstream regulator and downstream sensor of mitochondrial function. Loss of Sch9 conferred a respiratory growth defect, a defect in mitochondrial DNA transmission, lower mitochondrial membrane potential, and decreased levels of reactive oxygen species. Conversely, loss of mitochondrial DNA caused loss of Sch9 enrichment at the vacuolar membrane, loss of Sch9 phospho-isoforms, and small cell size suggestive of reduced Sch9 activity. Sch9 also exhibited dynamic relocalization in response to stress, including enrichment at mitochondria under conditions that have previously been shown to induce apoptosis in yeast. Taken together, this work reveals intimate connections between TORC1, nitrogen metabolism, and mitochondrial function, and has implications for the role of TOR in regulating aging, cancer, and other human diseases.

Target of Rapamycin

budding yeast

Saccharomyces cerevisiae

yeast

kinase

phosphatase

protein-protein interactions

TOR

nutrients

growth

rapamycin

signaling

network

metabolism

nitrogen catabolite repression

retrograde response

glutamate dehydrogenase

glutamine

glutamate

alpha-ketoglutarate

cell size

aging

lifespan

mitochondria

uncoupled respiration

petite

reactive oxygen species

free radical theory of aging

apoptosis

cancer

glutaminolysis

TORC1

Nnk1

Fmp48

Mks1

Sch9

Gdh2

Ure2

ribosomal protein S6 kinase

S6K

cell biology

molecular biology

0307

0379

0369

0410

0306

A Global Kinase and Phosphatase Interaction Network in the Budding Yeast Reveals Novel Effectors of the Target of Rapamycin (TOR) Pathway

Sharom, Jeffrey Roslan

31 August 2011

In the budding yeast Saccharomyces cerevisiae, the evolutionarily conserved Target of Rapamycin (TOR) signaling network regulates cell growth in accordance with nutrient and stress conditions. In this work, I present evidence that the TOR complex 1 (TORC1)-interacting proteins Nnk1, Fmp48, Mks1, and Sch9 link TOR to various facets of nitrogen metabolism and mitochondrial function. The Nnk1 kinase controlled nitrogen catabolite repression-sensitive gene expression via Ure2 and Gln3, and physically interacted with the NAD+-linked glutamate dehydrogenase Gdh2 that catalyzes deamination of glutamate to alpha-ketoglutarate and ammonia. In turn, Gdh2 modulated rapamycin sensitivity, was phosphorylated in Nnk1 immune complexes in vitro, and was relocalized to a discrete cytoplasmic focus in response to NNK1 overexpression or respiratory growth. The Fmp48 kinase regulated respiratory function and mitochondrial morphology, while Mks1 linked TORC1 to the mitochondria-to-nucleus retrograde signaling pathway. The Sch9 kinase appeared to act as both an upstream regulator and downstream sensor of mitochondrial function. Loss of Sch9 conferred a respiratory growth defect, a defect in mitochondrial DNA transmission, lower mitochondrial membrane potential, and decreased levels of reactive oxygen species. Conversely, loss of mitochondrial DNA caused loss of Sch9 enrichment at the vacuolar membrane, loss of Sch9 phospho-isoforms, and small cell size suggestive of reduced Sch9 activity. Sch9 also exhibited dynamic relocalization in response to stress, including enrichment at mitochondria under conditions that have previously been shown to induce apoptosis in yeast. Taken together, this work reveals intimate connections between TORC1, nitrogen metabolism, and mitochondrial function, and has implications for the role of TOR in regulating aging, cancer, and other human diseases.

Target of Rapamycin

budding yeast

Saccharomyces cerevisiae

yeast

kinase

phosphatase

protein-protein interactions

TOR

nutrients

growth

rapamycin

signaling

network

metabolism

nitrogen catabolite repression

retrograde response

glutamate dehydrogenase

glutamine

glutamate

alpha-ketoglutarate

cell size

aging

lifespan

mitochondria

uncoupled respiration

petite

reactive oxygen species

free radical theory of aging

apoptosis

cancer

glutaminolysis

TORC1

Nnk1

Fmp48

Mks1

Sch9

Gdh2

Ure2

ribosomal protein S6 kinase

S6K

cell biology

molecular biology

0307

0379

0369

0410

0306