Induction and inhibition of the allantoin permease in Saccharomyces cerevisiae.

Allantoin uptake in Saccharomyces cerevisiae is mediated by an energy-dependent, low-Km, active transport system. However, there is at present little information concerning its regulation. In view of this, we investigated the control of alloantoin transport and found that it was regulated quite differently from the other pathway components. Preincubation of appropriate mutant cultures with purified allantoate (commercial preparations contain 17% allantoin), urea, or oxalurate did not significantly increase allantoin uptake. Preincubation with allantoin, however, resulted in a 10- to 15-fold increase in the rate of allantoin accumulation. Two allantoin analogs were also found to elicit dramatic increases in allantoin uptake. Hydantoin and hydantoin acetic acid were able to induce allantoin transport to 63 and 95% of the levels observed with allantoin. Neither of these compounds was able to serve as a sole nitrogen source for S. cerevisiae, and they may be non-metabolizable inducers of the allantoin permease. The rna1 gene product appeared to be required for allantoin permease induction, suggesting that control was exerted at the level of gene expression. In addition, we have shown that allantoin uptake is not unidirectional; efflux merely occurs at a very low rate. Allantoin uptake is also transinhibited by addition of certain amino acids to the culture medium, and several models concerning the operation of such inhibition were discussed.     

The DAL7 promoter consists of multiple elements that cooperatively mediate regulation of the gene''s expression.

Expression of the allantoin system genes in Saccharomyces cerevisiae is induced by allophanate or its analog, oxalurate. This work provides evidence for the involvement of distinct types of cis-acting elements in the induction process. The first element was found to have the properties of an upstream activation sequence (UAS). This element was localized to a 16-base-pair (bp) DNA fragment containing a short 5-bp sequence that occurred repeatedly in the upstream region of DAL7. When present in two or more copies, the 16-bp fragment supported high-level beta-galactosidase production in a CYC1-lacZ expression vector; there was, however, no response to the allantoin pathway inducer. The second element had the properties of a negatively acting element or upstream repression sequence (URS). This element was localized to a 16-bp DNA fragment containing an 8-bp sequence that was repeated four times in the upstream region of DAL7. A fragment containing the 8-bp repeated sequence placed adjacent to the UAS-containing fragment mediated inhibition of the ability of the UAS to support lacZ expression regardless of whether inducer was present. A third element, designated an upstream induction sequence (UIS), was required for response to inducer. The UIS was localized to a small DNA fragment containing an approximately 10-bp sequence that was repeated twice in the upstream region of DAL7. When a fragment containing the 10-bp repeated sequence was placed adjacent to these UAS and URS elements, the construction (UIS-UAS-URS) supported normal oxalurate-mediated induction of beta-galactosidase synthesis. These data are consistent with the suggestion that multiple, cis-acting elements participate in the induction process.     

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.     

Transcriptional regulation of the DAL5 gene in Saccharomyces cerevisiae

We demonstrate that the DAL5 gene, encoding a necessary component of the allantoate transport system, is constitutively expressed in Saccharomyces cerevisiae. Its relatively high basal level of expression did not increase further upon addition of allantoin pathway intermediates. However, steady-state DAL5 mRNA levels dropped precipitously when a repressive nitrogen source was provided. These control characteristics of DAL5 expression make this gene a good model with which to unravel the mechanism of nitrogen catabolite repression. Its particular advantage relative to other potentially useful genes derives from its lack of control by induction and hence the complicating effects of inducer exclusion.     

Oxalurate transport in Saccharomyces cerevisiae.

Oxalurate, the gratuitous inducer of the allantoin degradative enzymes, was taken into the cell by an energy-dependent active transport system with an apparent Km of 1.2 mM. Efflux of previously accumulated oxalurate was rapid, with a half-life of about 2 min. The oxalurate uptake system appears to be both constitutively produced and insensitive to nitrogen catabolite repression. The latter observations suggest that failure of oxalurate to bring about induction of allophanate hydrolase in cultures growing under repressive conditions does not result from inducer exclusion, but rather from repression of dur1,2 gene expression.     

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 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.     

Location of the Genes That Control Induction of the Allantoin-Degrading Enzymes in SACCHAROMYCES CEREVISIAE

In an effort to understand the regulation of allantoin degradation in Saccharomyces cerevisiae, we isolated two classes of mutants, each defective in the induction process associated with production of the pathway enzymes. Mutation at one locus (DAL80) results in constitutive expression of the genes involved in allantoin catabolism. Mutation at the second locus (DAL-81) results in the loss of ability to induce these enzymes. This report describes genetic data indicating that the DAL80 and DAL81 loci are situated approximately 13 cM from the centromere on the right arm of chromosome XI and 9 cM proximal to the DAL1 locus on chromosome IX, respectively.     

Identification of the ureidoglycolate hydrolase gene in the DAL gene cluster of Saccharomyces cerevisiae.

This report describes the isolation of the genes encoding allantoicase (DAL2) and ureidoglycolate hydrolase (DAL3), which are components of the large DAL gene cluster on the right arm of chromosome IX of Saccharomyces cerevisiae. During this work a new gene (DAL7) was identified and found to be regulated in the manner expected for an allantoin pathway gene. Its expression was (i) induced by allophanate, (ii) sensitive to nitrogen catabolite repression, and (iii) responsive to mutation of the DAL80 and DAL81 loci, which have previously been shown to regulate the allantoin degradation system. Hybridization probes generated from these cloned genes were used to analyze expression of the allantoin pathway genes in wild-type and mutant cells grown under a variety of physiological conditions. When comparison was possible, the patterns of mRNA and enzyme levels observed in various strains and physiological conditions were very similar, suggesting that the system is predominantly regulated at the level of gene expression. Although all of the genes seem to be controlled by a common mechanism, their detailed patterns of expression were, at the same time, highly individual and diverse.     

Regulation of allantoate transport in wild-type and mutant strains of Saccharomyces cerevisiae.

Accumulation of intracellular allantoin and allantoate is mediated by two distinct active transport systems in Saccharomyces cerevisiae. Allantoin transport (DAL4 gene) is inducible, while allantoate uptake is constitutive (it occurs at full levels in the absence of any allantoate-related compounds from the culture medium). Both systems appear to be sensitive to nitrogen catabolite repression, feedback inhibition, and trans-inhibition. Mutants (dal5) that lack allantoate transport have been isolated. These strains also exhibit a 60% loss of allantoin transport capability. Conversely, dal4 mutants previously described are unable to transport allantoin and exhibit a 50% loss of allantoate transport. We interpret the pleiotropic behavior of the dal4 and dal5 mutations as deriving from a functional interaction between elements of the two transport systems.     

Pleiotropic control of five eucaryotic genes by multiple regulatory elements.

We have previously shown that allophanate acts as an inducer for five structural genes whose products participate in the degradation of allantoin by Saccharomyces cerevisiae. This observation led us to hypothesize that these genes might be controlled in common and to test the hypothesis by searching for mutants unable to induce production of the allantoin-degrading enzymes. Such mutants have been found. These strains grew poorly when provided with any of the allantoin pathway intermediates, but used other nitrogen sources normally. The mutations carried in these strains were recessive to wild-type alleles and complemented mutations in all known loci associated with the allantoin pathway. The locus containing the most thoroughly studied mutation (dal81-1) was not fund to be tightly linked to any of the allantoin pathway structural genes. The low basal levels of allantoin pathway enzymes observed in Dal81- strains remained the same whether or not the inducer was present in the growth medium. However, the levels of enzyme increased moderately when mutants were grown on poor nitrogen sources. From these observations, we conclude that dal81 mutant strains possess a defect in the induction of enzyme synthesis; enzyme production due to relief of nitrogen catabolite repression, however, appears normal. The observed epistatic relationships of mutations in the DAL80 and DAL81 loci suggest that their products may possess a reasonable degree of functional independence.     

Isolation and characterization of mutants that produce the allantoin-degrading enzymes constitutively in Saccharomyces cerevisiae.

Degradation of allantoin, allantoate, or urea by Saccharomyces cerevisiae requires the participation of four enzymes and four transport systems. Production of the four enzymes and one of the active transport systems is inducible; allophanate, the last intermediate of the pathway, functions as the inducer. The involvement of allophanate in the expression of five distinct genes suggested that they might be regulated by a common element. This suggestion is now supported by the isolation of a new class of mutants (dal80). Strains possessing lesions in the DAL80 locus produce the five inducible activities at high, constitutive levels. Comparable constitutive levels of activity were also observed in doubly mutant strains (durl dal80) which are unable to synthesize allophanate. This, with the observation that arginase activity remained at its uninduced, basal level in strains mutated at the DAL80 locus, eliminates internal induction as the basis for constitutive enzyme synthesis. Mutations in dal80 are recessive to wild-type alleles. The DAL80 locus has been located and is not linked to any of the structural genes of the allantoin pathway. Synthesis of the five enzymes produced constitutively in dal80-1-containing mutants remains normally sensitive to nitrogen repression even though the dal80-1 mutation is present. From these observations we conclude that production of the allantoin-degrading enzymes is regulated by the DAL80 gene product and that induction and repression of enzyme synthesis can be cleanly separated mutationally.     

Logical identification of an allantoinase analog (puuE) recruited from polysaccharide deacetylases

The hydrolytic cleavage of the hydantoin ring of allantoin, catalyzed by allantoinase, is required for the utilization of the nitrogen present in purine-derived compounds. The allantoinase gene (DAL1), however, is missing in many completely sequenced organisms able to use allantoin as a nitrogen source. Here we show that an alternative allantoinase gene (puuE) can be precisely identified by analyzing its logic relationship with three other genes of the pathway. The novel allantoinase is annotated in structure and sequence data bases as polysaccharide deacetylase for its homology with enzymes that catalyze hydrolytic reactions on chitin or peptidoglycan substrates. The recombinant PuuE protein from Pseudomonas fluorescens exhibits metal-independent allantoinase activity and stereospecificity for the S enantiomer of allantoin. The crystal structures of the protein and of protein-inhibitor complexes reveal an overall similarity with the polysaccharide deacetylase beta/alpha barrel and remarkable differences in oligomeric assembly and active site geometry. The conserved Asp-His-His metal-binding triad is replaced by Glu-His-Trp, a configuration that is distinctive of PuuE proteins within the protein family. An extra domain at the top of the barrel offers a scaffold for protein tetramerization and forms a small substrate-binding cleft by hiding the large binding groove of polysaccharide deacetylases. Substrate positioning at the active site suggests an acid/base mechanism of catalysis in which only one member of the catalytic pair of polysaccharide deacetylases has been conserved. These data provide a structural rationale for the shifting of substrate specificity that occurred during evolution.