DAL82, a second gene required for induction of allantoin system gene transcription in Saccharomyces cerevisiae

TorC1 and nitrogen catabolite repression control of integrated GABA shunt and retrograde pathway gene expression

Despite our detailed understanding of how the lower GABA shunt and retrograde genes are regulated, there is a paucity of validated information concerning control of GAD1, the glutamate decarboxylase gene which catalyzes the first reaction of the GABA shunt. Further, integration of glutamate degradation via the GABA shunt has not been investigated. Here, we show that while GAD1 shares a response to rapamycin-inhibition of the TorC1 kinase, it does so independently of the Gln3 and Gat1 NCR-sensitive transcriptional activators that mediate transcription of the lower GABA shunt genes. We also show that GABA shunt gene expression increases dramatically in response to nickel ions. The α-ketoglutarate needed for the GABA shunt to cycle, thereby producing reduced pyridine nucleotides, derives from the retrograde pathway as shown by a similar high increase in the retrograde reporter, CIT2 when nickel is present in the medium. These observations demonstrate high integration of the GABA shunt, retrograde, peroxisomal glyoxylate cycle, and β-oxidation pathways.

Genes of Different Catabolic Pathways Are Coordinately Regulated by Dal81 in Saccharomyces cerevisiae

Yeast can use a wide variety of nitrogen compounds. However, the ability to synthesize enzymes and permeases for catabolism of poor nitrogen sources is limited in the presence of a rich one. This general mechanism of transcriptional control is called nitrogen catabolite repression. Poor nitrogen sources, such as leucine, γ-aminobutyric acid (GABA), and allantoin, enable growth after the synthesis of pathway-specific catabolic enzymes and permeases. This synthesis occurs only under conditions of nitrogen limitation and in the presence of a pathway-specific signal. In this work we studied the temporal order in the induction of AGP1, BAP2, UGA4, and DAL7, genes that are involved in the catabolism and use of leucine, GABA, and allantoin, three poor nitrogen sources. We found that when these amino acids are available, cells will express AGP1 and BAP2 in the first place, then DAL7, and at last UGA4. Dal81, a general positive regulator of genes involved in nitrogen utilization related to the metabolisms of GABA, leucine, and allantoin, plays a central role in this coordinated regulation.

Dal81 enhances Stp1- and Stp2-dependent transcription necessitating negative modulation by inner nuclear membrane protein Asi1 in Saccharomyces cerevisiae

The yeast transcription factors Stp1 and Stp2 are synthesized as latent cytoplasmic precursors. In response to extracellular amino acids, the plasma membrane SPS sensor endoproteolytically excises the N-terminal domains that mediate cytoplasmic retention, enabling the processed forms to efficiently enter the nucleus and induce gene expression. Cytoplasmic retention is not absolute, low levels of full-length Stp1 and Stp2 "leak" into the nucleus, and the concerted action of inner nuclear membrane proteins Asi1, Asi2, and Asi3 restricts their promoter access. In cells lacking Asi function, the precursor forms bind promoters and constitutively induce gene expression. To understand the requirement of Asi-dependent repression, spontaneous mutations in Required for Latent Stp1/2-mediated transcription (RLS) genes that abolish the constitutive expression of SPS sensor-regulated genes in an asi1Delta strain were selected. A single gene, allelic with DAL81, was identified. We show that Dal81 indiscriminately amplifies the transactivation potential of both full-length and processed Stp1 and Stp2 by facilitating promoter binding. In dal81Delta mutants, the repressing activity of the Asi proteins is dispensable, demonstrating that without amplification, the levels of full-length Stp1 and Stp2 that escape cytoplasmic retention are insufficient to activate transcription. Conversely, the high levels of processed Stp1 and Stp2 that accumulate in the nucleus of induced cells activate transcription in the absence of Dal81.

The external amino acid signaling pathway promotes activation of Stp1 and Uga35/Dal81 transcription factors for induction of the AGP1 gene in Saccharomyces cerevisiae

Yeast cells respond to the presence of amino acids in their environment by inducing transcription of several amino acid permease genes including AGP1, BAP2, and BAP3. The signaling pathway responsible for this induction involves Ssy1, a permease-like sensor of external amino acids, and culminates with proteolytic cleavage and translocation to the nucleus of the zinc-finger proteins Stp1 and Stp2, the lack of which abolishes induction of BAP2 and BAP3. Here we show that Stp1-but not Stp2-plays an important role in AGP1 induction, although significant induction of AGP1 by amino acids persists in stp1 and stp1 stp2 mutants. This residual induction depends on the Uga35/Dal81 transcription factor, indicating that the external amino acid signaling pathway activates not only Stp1 and Stp2, but also another Uga35/Dal81-dependent transcriptional circuit. Analysis of the AGP1 gene's upstream region revealed that Stp1 and Uga35/Dal81 act synergistically through a 21-bp cis-acting sequence similar to the UAS(AA) element previously found in the BAP2 and BAP3 upstream regions. Although cells growing under poor nitrogen-supply conditions display much higher induction of AGP1 expression than cells growing under good nitrogen-supply conditions, the UAS(AA) itself is totally insensitive to nitrogen availability. Nitrogen-source control of AGP1 induction is mediated by the GATA factor Gln3, likely acting through adjacent 5'-GATA-3' sequences, to amplify the positive effect of UAS(AA). Our data indicate that Stp1 may act in combination with distinct sets of transcription factors, according to the gene context, to promote induction of transcription in response to external amino acids. The data also suggest that Uga35/Dal81 is yet another transcription factor under the control of the external amino acid sensing pathway. Finally, the data show that the TOR pathway mediating global nitrogen control of transcription does not interfere with the external amino acid signaling pathway.

The External Amino Acid Signaling Pathway Promotes Activation of Stp1 and Uga35/Dal81 Transcription Factors for Induction of the AGP1 Gene in Saccharomyces cerevisiae

Yeast cells respond to the presence of amino acids in their environment by inducing transcription of several amino acid permease genes including AGP1, BAP2, and BAP3. The signaling pathway responsible for this induction involves Ssy1, a permease-like sensor of external amino acids, and culminates with proteolytic cleavage and translocation to the nucleus of the zinc-finger proteins Stp1 and Stp2, the lack of which abolishes induction of BAP2 and BAP3. Here we show that Stp1—but not Stp2—plays an important role in AGP1 induction, although significant induction of AGP1 by amino acids persists in stp1 and stp1 stp2 mutants. This residual induction depends on the Uga35/Dal81 transcription factor, indicating that the external amino acid signaling pathway activates not only Stp1 and Stp2, but also another Uga35/Dal81-dependent transcriptional circuit. Analysis of the AGP1 gene’s upstream region revealed that Stp1 and Uga35/Dal81 act synergistically through a 21-bp cis-acting sequence similar to the UASAA element previously found in the BAP2 and BAP3 upstream regions. Although cells growing under poor nitrogen-supply conditions display much higher induction of AGP1 expression than cells growing under good nitrogen-supply conditions, the UASAA itself is totally insensitive to nitrogen availability. Nitrogen-source control of AGP1 induction is mediated by the GATA factor Gln3, likely acting through adjacent 5′-GATA-3′ sequences, to amplify the positive effect of UASAA. Our data indicate that Stp1 may act in combination with distinct sets of transcription factors, according to the gene context, to promote induction of transcription in response to external amino acids. The data also suggest that Uga35/Dal81 is yet another transcription factor under the control of the external amino acid sensing pathway. Finally, the data show that the TOR pathway mediating global nitrogen control of transcription does not interfere with the external amino acid signaling pathway.

Genetic analysis of the signalling pathway activated by external amino acids in Saccharomyces cerevisiae

The permease-like amino acid sensor Ssy1p of Saccharomyces cerevisiae is required for transcriptional induction, in response to external amino acids, of several genes encoding peptide and amino acid permeases. Among them is AGP1 encoding a low-affinity, broad-specificity amino acid permease important for the utilization of amino acids as a nitrogen source. We report here data from experiments aimed at identifying components of the signalling pathway activated by Ssy1p. Overproduction of the large amino-terminal tail of Ssy1p interferes negatively with the induction of AGP1 in wild-type cells. Furthermore, overproduction of this domain can relieve growth defects of a ssy1 null strain, indicating that the N-terminal tail of Ssy1p is an important functional element of the pathway. Consistent with a role for Ssy1p in the recognition of amino acids, a mutant form of the protein with a Thr to Ile substitution in the eighth predicted transmembrane domain is competent for the induction of AGP1 by leucine but not by other amino acids. In a screen for other mutants defective in the Ssy1p pathway, we confirmed that PTR3 and SSY5 encode additional factors essential for AGP1 expression in response to multiple amino acids. Data obtained by overproducing Ptr3p and Ssy5p in ssy1Delta, ptr3Delta and ssy5Delta mutants suggest that Ptr3p acts downstream from Ssy1p and Ssy5p downstream from Ptr3p in the transduction pathway. Furthermore, two-hybrid experiments indicated that Ptr3p interacts with Ssy5p and that Ptr3p can self-associate. Finally, the Cys-6-Zn2 transcription factor Uga35p/Dal81p required for the induction of AGP1 is also essential for the expression of two other genes under Ssy1p-Ptr3p-Ssy5p control, namely BAP2 and PTR2, suggesting that the protein is yet another component of the amino acid signalling pathway.

Roles of the Dal82p domains in allophanate/oxalurate-dependent gene expression in Saccharomyces cerevisiae

Allophanate/oxalurate-induced gene expression in Saccharomyces cerevisiae requires at least five transcription factors, four of which act positively (Gln3p, Gat1p, Dal81p, and Dal82p) and one negatively (Dal80p). Gln3p binds to and Gat1p is proposed to bind to single GATA sequences; Dal80p binds to pairs of specifically oriented and spaced GATA sequences, and Dal82p binds to a pathway-specific element, UIS(ALL). Dal82p consists of at least three domains as follows: (i) UIS(ALL) DNA-binding, (ii) transcriptional activation, and (iii) coiled-coil(DAL82). Here we show that the coiled-coil(DAL82) domain possesses two demonstrable functions. (i) It prevents Dal82p-mediated transcription when inducer is absent. (ii) It is a major, although not exclusive, domain through which the inducer signal is received. Supporting the latter conclusion, a 38-amino acid fragment, containing little more than the coiled-coil(DAL82) domain, supports oxalurate-inducible, Dal81p-dependent, reporter gene transcription. Dal81p is required for inducer responsiveness of LexAp-Dal82p and LexAp coiled-coil(DAL82)-mediated transcription but isn't needed for inducer-dependent activation mediated by a Dal82p containing deletions in both the coiled-coil(DAL82), UIS(ALL)-binding domains. There may be an interaction between Dal81p and the coiled-coil(DAL82) domain since (i) Dal81p is required for transcription mediated by LexA-coiled-coil(DAL82)p and (ii) a Dal81p-Dal82p complex is detected by two-hybrid assay.

Functional domain mapping and subcellular distribution of Dal82p in Saccharomyces cerevisiae

Previous studies have shown that (i) Dal81p and Dal82p are required for allophanate-induced gene expression in Saccharomyces cerevisiae; (ii) the cis-acting element mediating the induced transcriptional response to allophanate is a dodecanucleotide, UIS(ALL); and (iii) Dal82p binds specifically to UIS(ALL). Here we show that Dal82p is localized to the nucleus and parallels movement of the DNA through the cell cycle. Deletion analysis of DAL82 identified and localized three functional domains. Electrophoretic mobility shift assays identified a peptide (consisting of Dal82p amino acids 1-85) that is sufficient to bind a DNA fragment containing UIS(ALL). LexA-tethering experiments demonstrated that Dal82p is capable of mediating transcriptional activation. The activation domain consists of two parts: (i) an absolutely required core region (amino acids 66-99) and (ii) less well defined regions flanking residues 66-99 that are required for full wild-type levels of activation. The Dal82p C terminus contains a predicted coiled-coil motif that down-regulates Dal82p-mediated transcriptional activation.

Overlapping positive and negative GATA factor binding sites mediate inducible DAL7 gene expression in Saccharomyces cerevisiae

Allantoin pathway gene expression in Saccharomyces cerevisiae responds to two different environmental stimuli. The expression of these genes is induced in the presence of allantoin or its degradative metabolites and repressed when a good nitrogen source (e. g. asparagine or glutamine) is provided. Three types of cis-acting sites and trans-acting factors are required for allantoin pathway gene transcription as follows: (i) UAS(NTR) element associated with the transcriptional activators Gln3p and Gat1p, (ii) URS(GATA) element associated with the repressor Dal80p, and (iii) UIS(ALL) element associated with the Dal82 and Dal81 proteins required for inducer-dependent transcription. Most of the work leading to the above conclusions has employed inducer-independent allantoin pathway genes (e.g. DAL5 and DAL3). The purpose of this work is to extend our understanding of these elements and their roles to inducible allantoin pathway genes using the DAL7 (encoding malate synthase) as a model. We show that eight distinct cis-acting sites participate in the process as follows: a newly identified GC-rich element, two UAS(NTR), two UIS(ALL), and three URS(GATA) elements. The two GATA-containing UAS(NTR) elements are coincident with two of the three GATA sequences that make up the URS(GATA) elements. The remaining URS(GATA) GATA sequence, however, is not a UAS(NTR) element but appears to function only in repression. The data provide insights into how these cis- and trans-acting factors function together to accomplish the regulated expression of the DAL7 gene that is observed in vivo.

Nitrogen catabolite repression in Saccharomyces cerevisiae

In Saccharomyces cerevisiae the expression of all known nitrogen catabolite pathways are regulated by four regulators known as Gln3, Gat1, Dal80, and Deh1. This is known as nitrogen catabolite repression (NCR). They bind to motifs in the promoter region to the consensus sequence 5'GATAA 3'. Gln3 and Gat1 act positively on gene expression whereas Dal80 and Deh1 act negatively. Expression of nitrogen catabolite pathway genes known to be regulated by these four regulators are glutamine, glutamate, proline, urea, arginine. GABA, and allantonie. In addition, the expression of the genes encoding the general amino acid permease and the ammonium permease are also regulated by these four regulatory proteins. Another group of genes whose expression is also regulated by Gln3, Gat1, Dal80, and Deh1 are some proteases, CPS1, PRB1, LAP1, and PEP4, responsible for the degradation of proteins into amino acids thereby providing a nitrogen source to the cell. In this review, all known promoter sequences related to expression of nitrogen catabolite pathways are discussed as well as other regulatory proteins. Overview of metabolic pathways and promotors are presented.

Sequencing analysis of a 24.7 kb fragment of yeast chromosome XIV identifies six known genes, a new member of the hexose transporter family and ten new open reading frames

The DNA sequence of a 24.7 kb region covering the left arm of chromosome XIV from Saccharomyces cerevisiae was determined. This region contains 17 open reading frames (ORFs) which code for proteins of more than 100 amino acids. Five ORFs correspond to the KRE1, ATP11, DAL82, RFA2 and MCK1 loci, described previously. Two ORFs present high similarity to known proteins: NO345 with the hexose transporter family, and NO351 with the yeast chorismate mutase/prephenate dehydratase enzyme encoded by PHA2. Six ORFs show limited similarity with known proteins or some specific features: NO339 presents 11 potential transmembrane domains. NO343, which is internal to NO345, presents a putative signal sequence and a potential transmembrane domain. NO348 shows similarity with YCW2, TUP1 and SEC13. NO364 reveals a signature for a pyridoxal-phosphate attachment site. Finally, NO384 and NO388 present a biased amino acid composition, being rich in Asn or Glu/Lys/Arg, respectively. Four other ORFs (NO342, NO376, NO381 and NO397) show no similarity to proteins within the databases screened.

Cis- and trans-acting elements determining induction of the genes of the gamma-aminobutyrate (GABA) utilization pathway in Saccharomyces cerevisiae

In S. cerevisiae, gamma-aminobutyrate (GABA) induces transcription of the UGA genes required for its utilization as a nitrogen source. Analysis of the 5' region of the UGA1 and UGA4 genes led to the identification of a conserved GC-rich sequence (UASGABA) essential to induction by gamma-aminobutyrate. Alone, this UASGABA element also supported some levels of reporter gene transcription in the presence of gamma-aminobutyrate. To be effective, UASGABA requires two positive-acting proteins that both contain a Cys6-Zn2 type zinc-finger motif, namely pathway-specific Uga3p and pleiotropic Uga35p(Dal81p/DurLp). Further analysis of the UGA4 gene revealed that Gln3p, a global nitrogen regulatory protein containing a GATA zinc-finger domain, is required in order to reach high levels of gamma-aminobutyrate-induced transcription. The Gln3p factor exerts its function mainly through a cluster of 5'-GAT(A/T)A-3'(UASGATA) situated just upstream from UASGABA. The role of Gln3p is less predominant in UGA1 than in UGA4 gene expression. We propose that tight coupling between the UASGABA and UASGATA elements enables the cell to integrate, according to its nitrogen status, the induced expression levels of UGA4.

Defining the sequence specificity of the Saccharomyces cerevisiae DNA binding protein REB1p by selecting binding sites from random-sequence oligonucleotides

We have used a random selection protocol to define the consensus and range of binding sites for the Saccharomyces cerevisiae REB1 protein. Thirty-five elements were sequenced which bound specifically to a GST-REB1p fusion protein coupled to glutathione-Sepharose under conditions in which more than 99.9% of the random sequences were not retained. Twenty-two of the elements contained the core sequence CGGGTRR, with all but one of the remaining elements containing only one deviation from the core. Of the core sequence, the only residues that were absolutely conserved were the three consecutive G residues. Statistical analysis of a nucleotide-use matrix suggested that the REB1p binding site also extends into flanking sequences with the optimal sequence for REB1p binding being GNGCCGGGGTAACNC. There was a positive correlation between the ability of the sites to bind in vitro and activate transcription in vivo; however, the presence of non-conformants suggests that the binding site may contribute more to transcriptional activation than simply allowing protein binding. Interestingly, one of the REB1p binding elements had a DNAse 1 footprint appreciably longer than other elements with similar affinity. Analysis of its sequence indicated the potential for a second REB1p binding site on the opposite strand. This suggests that two closely positioned low-affinity sites can function together as a highly active site. In addition, database searches with some of the randomly defined REB1p binding sites suggest that related elements are commonly found within 'TATA-less' promoters.

The Saccharomyces cerevisiae DAL80 repressor protein binds to multiple copies of GATAA-containing sequences (URSGATA)

Induced expression of the allantoin (DAL) catabolic genes in Saccharomyces cerevisiae has been suggested to be mediated by interaction of three different types of promoter elements. First is an inducer-independent upstream activation sequence, UASNTR, whose operation is sensitive to nitrogen catabolite repression. The GLN3 product is required for UASNTR-mediated transcriptional activation. This site consists of two separated elements, each of which has a GATAA sequence at its core. Response of the DAL genes to inducer is mediated by a second type of cis-acting element, DAL UIS. The DAL82 and DAL81 genes are required for response to inducer; DAL82 protein is the UIS-binding protein. When only the UASNTR and UIS elements are present, DAL gene expression occurs at high levels in the absence of inducer. We, therefore, hypothesized that a third element, an upstream repressor sequence (URS) mediates maintenance of DAL gene expression at a low level when inducer is absent. Since the DAL and UGA genes are overexpressed and largely inducer independent in dal80 deletion mutants, we have suggested DAL80 protein negatively regulates a wide spectrum of nitrogen-catabolic gene expression, likely in conjunction with a URS element. Here we show that DAL80 protein binds to DAL3 and UGA4 upstream DNA sequences, designated URSGATA, consisting of two GATAA-containing sites separated by at least 15 bp. The preferred orientation of the sites is tail to tail, but reasonable binding activity is also observed with a head-to-tail configuration. URSGATA elements contain the sequence GATAA at their core and hence share sequence homology with UASNTR elements.

The DAL82 protein of Saccharomyces cerevisiae binds to the DAL upstream induction sequence (UIS)

Expression of the DAL2, DAL4, DAL7, DUR1,2, and DUR3 genes in S. cerevisiae is induced by allophanate, the last intermediate in the allantoin catabolic pathway. Analysis of the DAL7 promoter identified a dodecanucleotide, the DAL7 UIS, which was required for inducer-responsiveness. Operation of the DAL7 UIS required functional DAL81 and DAL82 gene products. Since the DAL81 product was not an allantoin pathway-specific regulatory factor, the DAL82 product was considered as the more likely candidate to be the DAL UIS binding protein. Using an E. coli expression system, we showed that DAL82 protein specifically bound to wild type but not mutant DAL UIS sequences. DNA fragments containing DAL UIS elements derived from various DAL gene promoters bound DAL82 protein with different affinities which correlate with the degree of inducer-responsiveness the genes displayed.

Regulation of the urea active transporter gene (DUR3) in Saccharomyces cerevisiae

The DUR3 gene, which encodes a component required for active transport of urea in Saccharomyces cerevisiae, has been isolated, and its sequence has been determined. The deduced DUR3 protein profile possesses alternating hydrophobic and hydrophilic regions characteristics of integral membrane proteins. Strong negative complementation observed during genetic analysis of the DUR3 locus suggests that the DUR3 product may polymerize to carry out its physiological function. Expression of DUR3 is regulated in a manner similar to that of other genes in the allantoin pathway. High-level expression is inducer dependent, requiring functional DAL81 and DAL82 genes. Maintenance of DUR3 mRNA at uninduced, nonrepressed basal levels requires the negatively acting DAL80 gene product. DUR3 expression is highly sensitive to nitrogen catabolite repression and also has a partial requirement for the GLN3 product.

The UGA43 negative regulatory gene of Saccharomyces cerevisiae contains both a GATA-1 type zinc finger and a putative leucine zipper

The UGA43 gene of Saccharomyces cerevisiae is required for repression of inducible genes involved in the utilization of 4-aminobutyric acid (GABA) or urea as nitrogen sources. The UGA43 gene has been cloned by complementation of a uga43 mutation. The N-terminal region of the UGA43 protein is very similar to the DNA-binding zinc-finger region typical of the GATA regulatory factor family in vertebrates. UGA43 is the first reported instance of a GATA protein with a negative regulatory function. The C-terminal region of the predicted UGA43 protein contains a putative leucine zipper. Sequencing of three uga43 mutant alleles suggests that the GATA and putative leucine-zipper regions are both required for the repressive activity of UGA43. UGA43 appears to be a highly regulated gene. On "poor" nitrogen sources, UGA43 transcripts are measured at high levels whereas they are nearly undetectable in conditions of nitrogen catabolite repression. The levels measured on "poor" nitrogen sources are further increased in uga43 mutant cells, suggesting that UGA43 exerts negative autoregulation.

Ty insertions upstream and downstream of native DUR1,2 promoter elements generate different patterns of DUR1,2 expression in Saccharomyces cerevisiae

Expression of allantoin pathway genes is subject to induction and nitrogen catabolite repression. Two classes of cis-dominant mutations (DUR80 and DUR1,2-Oh) result in overproduction of DUR1,2 mRNA. In DUR80 mutants, DUR1,2 expression remained inducible, nitrogen catabolite repression sensitive, and unresponsive to cell ploidy, i.e., overproduction was superimposed on normal gene regulation. DUR1,2-Oh mutations, in contrast, generated a pattern of DUR1,2 expression similar to that often reported when a Ty element inserts upstream of a gene, the ROAM phenotype. We analyzed four independent DUR80 and DUR1,2-Oh alleles. The DUR1,2-Oh mutation was, as expected, a Ty insertion at -445 3' of the native DUR1,2 upstream activation sequences (UASs). All three DUR80 alleles were also Ty insertions between -644 and -653 immediately 5' of the native DUR1,2 USASs. We suggest that the difference in DUR1,2-Oh and DUR80 phenotypes depends on whether the native cis-acting elements and transcription factors associated with them can operate. If they can, enhancement of normally regulated DUR1,2 expression is observed. This is a novel phenotype for Ty insertions. If the native DUR1,2 cis-acting elements are not present, the case when Ty insertion occurs 3' of them, a ROAM phenotype is generated. Nitrogen-regulated upstream activation sequence (UASNTR)-homologous sequences present in the Ty delta elements rather than cis-acting elements required for Ty transcription are the most likely candidates to serve as the cis-acting elements mediating the DUR80 phenotype.

Expression of the DAL80 gene, whose product is homologous to the GATA factors and is a negative regulator of multiple nitrogen catabolic genes in Saccharomyces cerevisiae, is sensitive to nitrogen catabolite repression

We have cloned the negative regulatory gene (DAL80) of the allantoin catabolic pathway, characterized its structure, and determined the physiological conditions that control DAL80 expression and its influence on the expression of nitrogen catabolic genes. Disruption of the DAL80 gene demonstrated that it regulates multiple nitrogen catabolic pathways. Inducer-independent expression was observed for the allantoin pathway genes DAL7 and DUR1,2, as well as the UGA1 gene required for gamma-aminobutyrate catabolism in the disruption mutant. DAL80 transcription was itself highly sensitive to nitrogen catabolite repression (NCR), and its promoter contained 12 sequences homologous to the NCR-sensitive UASNTR. The deduced DAL80 protein structure contains zinc finger and coiled-coil motifs. The DAL80 zinc finger motif possessed high homology to the transcriptional activator proteins required for expression of NCR-sensitive genes in fungi and the yeast GLN3 gene product required for functioning of the NCR-sensitive DAL UASNTR. It was also homologous to the three GATAA-binding proteins reported to be transcriptional activators in avian and mammalian tissues. The latter correlations raise the possibility that both positive and negative regulators of allantoin pathway transcription may bind to similar sequences.

Expression of the DAL80 gene, whose product is homologous to the GATA factors and is a negative regulator of multiple nitrogen catabolic genes in Saccharomyces cerevisiae, is sensitive to nitrogen catabolite repression

We have cloned the negative regulatory gene (DAL80) of the allantoin catabolic pathway, characterized its structure, and determined the physiological conditions that control DAL80 expression and its influence on the expression of nitrogen catabolic genes. Disruption of the DAL80 gene demonstrated that it regulates multiple nitrogen catabolic pathways. Inducer-independent expression was observed for the allantoin pathway genes DAL7 and DUR1,2, as well as the UGA1 gene required for gamma-aminobutyrate catabolism in the disruption mutant. DAL80 transcription was itself highly sensitive to nitrogen catabolite repression (NCR), and its promoter contained 12 sequences homologous to the NCR-sensitive UASNTR. The deduced DAL80 protein structure contains zinc finger and coiled-coil motifs. The DAL80 zinc finger motif possessed high homology to the transcriptional activator proteins required for expression of NCR-sensitive genes in fungi and the yeast GLN3 gene product required for functioning of the NCR-sensitive DAL UASNTR. It was also homologous to the three GATAA-binding proteins reported to be transcriptional activators in avian and mammalian tissues. The latter correlations raise the possibility that both positive and negative regulators of allantoin pathway transcription may bind to similar sequences.

The allantoinase (DAL1) gene of Saccharomyces cerevisiae

The allantoinase (DAL1) gene from Saccharomyces cerevisiae has been cloned, sequenced, and found to encode a 472 amino acid protein with a Mr of 52,028. DAL1 is expressed in an inducer-independent manner in strain M970 (sigma 1278b genetic background) and modestly responds to mutation of the dal80 locus. Expression was also sensitive to nitrogen catabolite repression (NCR). Correlated with these expression characteristics, the upstream region of DAL1 contained five copies of a sequence that is homologous to the DAL UASNTR element previously shown to be required for transcriptional activation and NCR sensitivity of the DAL5 and DAL7 genes. Missing from the DAL1 5' flanking region were any sequences with significant homology to the DAL7 UIS element required for response to inducer. These observations further support the roles of UASNTR and DAL7 UIS in the regulation of allantoin pathway gene expression.

Upstream induction sequence, the cis-acting element required for response to the allantoin pathway inducer and enhancement of operation of the nitrogen-regulated upstream activation sequence in Saccharomyces cerevisiae

Expression of the DAL2, DAL4, DAL7, DUR1,2, and DUR3 genes in Saccharomyces cerevisiae is induced by the presence of allophanate, the last intermediate of the allantoin degradative pathway. Analysis of the DAL7 5'-flanking region identified an element, designated the DAL upstream induction sequence (DAL UIS), required for response to inducer. The operation of this cis-acting element requires functional DAL81 and DAL82 gene products. We determined the DAL UIS structure by using saturation mutagenesis. A specific dodecanucleotide sequence is the minimum required for response of reporter gene transcription to inducer. There are two copies of the sequence in the 5'-flanking region of the DAL7 gene. There are one or more copies of the sequence upstream of each allantoin pathway gene that responds to inducer. The sequence is also found 5' of the allophanate-inducible CAR2 gene as well. No such sequences were detected upstream of allantoin pathway genes that do not respond to the presence of inducer. We also demonstrated that the presence of a UIS element adjacent to the nitrogen-regulated upstream activation sequence significantly enhances its operation.

The ureidoglycollate hydrolase (DAL3) gene in Saccharomyces cerevisiae

The DAL3 gene has been sequenced and found to encode a 195 amino acid protein with a molecular weight of 21,727. The four carboxy-terminal amino acids of DAL3 product (Cys-Ile-Ile-Ile) are homologous to those (CAAX) previously shown to be the primary structural signal for post-translational farnesylation of yeast RAS protein and mating factor. This modification is reported to be responsible for membrane localization of proteins containing it. The upstream region of DAL3 contains six copies of a sequence that is homologous to the positively acting DAL UASNTR reported to be required for transcriptional activation of the DAL5 and DAL7 genes. Missing from the DAL3 upstream region were any sequences related to those shown to be required for a DAL7 response to inducer, the UIS element. This correlates with the previous report that DAL3 expression is independent of the allantoin pathway inducer.

Saturation mutagenesis of the UASNTR (GATAA) responsible for nitrogen catabolite repression-sensitive transcriptional activation of the allantoin pathway genes in Saccharomyces cerevisiae

Saturation mutagenesis of the UASNTR element responsible for GLN3-dependent, nitrogen catabolite repression-sensitive transcriptional activation of allantoin pathway genes in yeast cells identified the dodecanucleotide sequence 5'-TTNCTGATAAGG-3' as the minimum required for UAS activity. There was significant flexibility in mutant sequences capable of supporting UAS activity, which correlates well with the high variation in UASNTR homologous sequences reported to be upstream of the DAL and DUR genes. Three of nine UASNTR-like sequences 5' of the DAL5 gene supported high-level transcriptional activation. The others, which contained nonpermissive substitutions, were not active.

Sequences of two adjacent genes, one (DAL2) encoding allantoicase and another (DCG1) sensitive to nitrogen-catabolite repression in Saccharomyces cerevisiae

Reported are the nucleotide sequences of the yeast allantoicase-encoding gene (DAL2) and that of an unknown gene adjacent to it. Expression of the unidentified gene is sensitive to nitrogen catabolite repression (NCR) and regulated by the DAL80 product, a previously documented control element regulating allantoin pathway gene expression. Both genes possess multiple upstream activation sequences (UAS) homologous to the UASNTR element shown to be required for sensitivity to NCR. Also present upstream from DAL2 is a mutant form of the upstream induction sequence required for response of DAL7 to induction. Its occurrence in mutant form is consistent with the poor induction of DAL2 expression observed in vivo.

The DAL81 gene product is required for induced expression of two differently regulated nitrogen catabolic genes in Saccharomyces cerevisiae

We demonstrate that the DAL81 gene, previously thought to be specifically required for induced expression of the allantoin pathway genes in Saccharomyces cerevisiae, functions in a more global manner. The data presented show it to be required for utilization of 4-aminobutyrate as a nitrogen source and for 4-aminobutyrate-induced increases in the steady-state levels of UGA1 mRNA. The DAL81 gene encodes a 970-amino-acid protein containing sequences homologous to the Zn(II)2Cys6 motif and two stretches of polyglutamine residues. Deletion of sequences homologous to the Zn(II)2Cys6 motif did not result in a detectable loss of function. On the other hand, loss of one of the polyglutamine stretches, but not the other, resulted in a 50% loss of DAL81 function.

The DAL81 gene product is required for induced expression of two differently regulated nitrogen catabolic genes in Saccharomyces cerevisiae

We demonstrate that the DAL81 gene, previously thought to be specifically required for induced expression of the allantoin pathway genes in Saccharomyces cerevisiae, functions in a more global manner. The data presented show it to be required for utilization of 4-aminobutyrate as a nitrogen source and for 4-aminobutyrate-induced increases in the steady-state levels of UGA1 mRNA. The DAL81 gene encodes a 970-amino-acid protein containing sequences homologous to the Zn(II)2Cys6 motif and two stretches of polyglutamine residues. Deletion of sequences homologous to the Zn(II)2Cys6 motif did not result in a detectable loss of function. On the other hand, loss of one of the polyglutamine stretches, but not the other, resulted in a 50% loss of DAL81 function.