Conformational changes play a role in regulating the activity of the proline utilization pathway-specific regulator in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, the ability to use proline as a nitrogen source requires the Put3p transcriptional regulator, which turns on the expression of the proline utilization genes, PUT1 and PUT2, in the presence of the inducer proline and in the absence of preferred nitrogen sources. Changes in target gene expression occur through an alteration in activity of the DNA-bound Put3p, a member of the Zn(II)2Cys6 binuclear cluster family of proteins. Here, we report that the 'on' conformation can be mimicked in the absence of proline by the insertion of an epitope tag in several different places in the protein, as well as by specific amino acid changes that suppress a put3 mutation leading to non-inducibility of the pathway. In addition, the presence of proline causes a conformational change in the Put3 protein detected by increased sensitivity to thrombin or V8 protease. These findings suggest that Put3p shifts from an inactive to an activate state via conformational changes.

Cross-pathway regulation in Saccharomyces cerevisiae: activation of the proline utilization pathway by Ga14p in vivo.

The Put3p and Gal4p transcriptional activators are members of a distinct class of fungal regulators called the Cys(6) Zn(II)(2) binuclear cluster family. This family includes over 50 different Saccharomyces cerevisiae proteins that share a similar domain organization. Gal4p activates the genes of the galactose utilization pathway permitting the use of galactose as the sole source of carbon and energy. Put3p controls the expression of the proline utilization pathway that allows yeast cells to grow on proline as the sole nitrogen source. We report that Gal4p can activate the PUT structural genes in a strain lacking Put3p. We also show that the activation of PUT2 by Gal4p depends on the presence of the inducer galactose and the Put3p binding site and that activation increases with increased dosage of Gal4p. Put3p cannot activate the GAL genes in the absence of Gal4p. Our in vivo results confirm previously published in vitro data showing that Gal4p is more promiscuous than Put3p in its DNA binding ability. The results also suggest that under appropriate circumstances, Gal4p may be able to function in place of a related family member to activate expression.

The regulator of the yeast proline utilization pathway is differentially phosphorylated in response to the quality of the nitrogen source.

The proline utilization pathway in Saccharomyces cerevisiae is regulated by the Put3p transcriptional activator in response to the presence of the inducer proline and the quality of the nitrogen source in the growth medium. Put3p is constitutively bound to the promoters of its target genes, PUT1 and PUT2, under all conditions studied but activates transcription to the maximum extent only in the absence of rich nitrogen sources and in the presence of proline (i.e., when proline serves as the sole source of nitrogen). Changes in target gene expression therefore occur through changes in the activity of the DNA-bound regulator. In this report, we demonstrate by phosphatase treatment of immunoprecipitates of extracts metabolically labeled with (32)P or (35)S that Put3p is a phosphoprotein. Examination of Put3p isolated from cells grown on a variety of nitrogen sources showed that it was differentially phosphorylated as a function of the quality of the nitrogen source: the poorer the nitrogen source, the slower the gel migration of the phosphoforms. The presence of the inducer does not detectably alter the phosphorylation profile. Activator-defective and activator-constitutive Put3p mutants have been analyzed. One activator-defective mutant appears to be phosphorylated in a pattern similar to that of the wild type, thus separating its ability to be phosphorylated from its ability to activate transcription. Three activator-constitutive mutant proteins from cells grown on an ammonia-containing medium have a phosphorylation profile similar to that of the wild-type protein in cells grown on proline. These results demonstrate a correlation between the phosphorylation status of Put3p and its ability to activate its target genes and suggest that there are two signals, proline induction and quality of nitrogen source, impinging on Put3p that act synergistically for maximum expression of the proline utilization pathway.

Functional analysis of the PUT3 transcriptional activator of the proline utilization pathway in Saccharomyces cerevisiae.

Proline can serve as a nitrogen source for the yeast Saccharomyces cerevisiae when preferred sources of nitrogen are absent from the growth medium. PUT3, the activator of the proline utilization pathway, is required for the transcription of the genes encoding the enzymes that convert proline to glutamate. PUT3 is a 979 amino acid protein that constitutively binds a short DNA sequence to the promoters of its target genes, but does not activate their expression in the absence of induction by proline and in the presence of preferred sources of nitrogen. To understand how PUT3 is converted from an inactive to an active state, a dissection of its functional domains has been undertaken. Biochemical and molecular tests, domain swapping experiments, and an analysis of activator-constitutive and activator-defective mutant proteins indicate that PUT3 is dimeric and activates transcription with its negatively charged carboxyterminus, which does not appear to contain a proline-responsive domain. A mutation in the conserved central domain found in many fungal activators interferes with activation without affecting DNA binding protein stability. Intragenic suppressors of the central domain mutation have been isolated and analyzed.

Roles of URE2 and GLN3 in the proline utilization pathway in Saccharomyces cerevisiae.

The yeast Saccharomyces cerevisiae can use alternative nitrogen sources such as arginine, urea, allantoin, gamma-aminobutyrate, or proline when preferred nitrogen sources like glutamine, asparagine, or ammonium ions are unavailable in the environment. Utilization of alternative nitrogen sources requires the relief of nitrogen repression and induction of specific permeases and enzymes. The products of the GLN3 and URE2 genes are required for the appropriate transcription of many genes in alternative nitrogen assimilatory pathways. GLN3 appears to activate their transcription when good nitrogen sources are unavailable, and URE2 appears to repress their transcription when alternative nitrogen sources are not needed. The participation of nitrogen repression and the regulators GLN3 and URE2 in the proline utilization pathway was evaluated in this study. Comparison of PUT gene expression in cells grown in repressing or derepressing nitrogen sources, in the absence of the inducer proline, indicated that both PUT1 and PUT2 are regulated by nitrogen repression, although the effect on PUT2 is comparatively small. Recessive mutations in URE2 elevated expression of the PUT1 and PUT2 genes 5- to 10-fold when cells were grown on a nitrogen-repressing medium. Although PUT3, the proline utilization pathway transcriptional activator, is absolutely required for growth on proline as the sole nitrogen source, a put3 ure2 strain had somewhat elevated PUT gene expression, suggesting an effect of the ure2 mutation in the absence of the PUT3 product. PUT1 and PUT2 gene expression did not require the GLN3 activator protein for expression under either repressing or derepressing conditions. Therefore, regulation of the PUT genes by URE2 does not require a functional GLN3 protein. The effect of the ure2 mutation on the PUT genes is not due to increased internal proline levels. URE2 repression appears to be limited to nitrogen assimilatory systems and does not affect genes involved in carbon, inositol, or phosphate metabolism or in mating-type control and sporulation.

Proline biosynthesis in Saccharomyces cerevisiae: molecular analysis of the PRO1 gene, which encodes gamma-glutamyl kinase.

The PRO1 gene of Saccharomyces cerevisiae encodes the 428-amino-acid protein gamma-glutamyl kinase (ATP:L-glutamate 5-phosphotransferase, EC 2.7.2.11), which catalyzes the first step in proline biosynthesis. Amino acid sequence comparison revealed significant homology between the yeast and Escherichia coli gamma-glutamyl kinases throughout their lengths. Four close matches to the consensus sequence for GCN4 protein binding and one close match to the RAP1 protein-binding site were found in the PRO1 upstream region. The response of the PRO1 gene to changes in the growth medium was analyzed by measurement of steady-state mRNA levels and of beta-galactosidase activity encoded by a PRO1-lacZ gene fusion. PRO1 expression was not repressed by exogenous proline and was not induced by the presence of glutamate in the growth medium. Although expression of the PRO1 gene did not change in response to histidine starvation, both steady-state PRO1 mRNA levels and beta-galactosidase activities were elevated in a gcd1 strain and reduced in a gcn4 strain. In addition, a pro1 bradytrophic strain became completely auxotrophic for proline in a gcn4 strain background. These results indicate that PRO1 is regulated by the general amino acid control system.

Proline biosynthesis in Saccharomyces cerevisiae: analysis of the PRO3 gene, which encodes delta 1-pyrroline-5-carboxylate reductase.

The PRO3 gene of Saccharomyces cerevisiae encodes the 286-amino-acid protein delta 1-pyrroline-5-carboxylate reductase [L-proline:NAD(P+) 5-oxidoreductase; EC 1.5.1.2], which catalyzes the final step in proline biosynthesis. The protein has substantial similarity to the pyrroline carboxylate reductases of diverse bacterial species, soybean, and humans. Using RNA hybridization and measurements of enzyme activity, we have determined that the expression of the PRO3 gene appears to be constitutive. It is not repressed by the pathway end product (proline), induced by the initial substrate (glutamate), or regulated by the general control system. Its expression is not detectably altered when cells are grown in a wide range of nitrogen sources or when glycerol and ethanol replace glucose as the carbon source. The possibility that this enzyme has other functions in addition to proline biosynthesis is discussed.

Cloning human pyrroline-5-carboxylate reductase cDNA by complementation in Saccharomyces cerevisiae.

Pyrroline-5-carboxylate reductase (EC 1.5.1.2) catalyzes the NAD(P)H-dependent conversion of pyrroline-5-carboxylate to proline. We cloned a human pyrroline-5-carboxylate reductase cDNA by complementation of proline auxotrophy in a Saccharomyces cerevisiae mutant strain, DT1100. Using a HepG2 cDNA library in a yeast expression vector, we screened 10(5) transformants, two of which gained proline prototrophy. The plasmids in both contained similar 1.8-kilobase inserts, which when reintroduced into strain DT1100, conferred proline prototrophy. The pyrroline-5-carboxylate reductase activity in these prototrophs was 1-3% that of wild type yeast, in contrast to the activity in strain DT1100 which was undetectable. The 1810-base pair pyrroline-5-carboxylate reductase cDNA hybridizes to a 1.85-kilobase mRNA in samples from human cell lines and predicts a 319-amino acid, 33.4-kDa protein. The derived amino acid sequence is 32% identical with that of S. cerevisiae. By genomic DNA hybridization analysis, the human reductase appears to be encoded by a single copy gene which maps to chromosome 17.

Analysis of constitutive and noninducible mutations of the PUT3 transcriptional activator.

The Saccharomyces cerevisiae PUT3 gene encodes a transcriptional activator that binds to DNA sequences in the promoters of the proline utilization genes and is required for the basal and induced expression of the enzymes of this pathway. The sequence of the wild-type PUT3 gene revealed the presence of one large open reading frame capable of encoding a 979-amino-acid protein. The protein contains amino-terminal basic and cysteine-rich domains homologous to the DNA-binding motifs of other yeast transcriptional activators. Adjacent to these domains is an acidic domain with a net charge of -17. A second acidic domain with a net charge of -29 is located at the carboxy terminus. The midsection of the PUT3 protein has homology to other activators including GAL4, LAC9, PPR1, and PDR1. Mutations in PUT3 causing aberrant (either constitutive or noninducible) expression of target genes in this system have been analyzed. One activator-defective and seven activator-constitutive PUT3 alleles have been retrieved from the genome and sequenced to determine the nucleotide changes responsible for the altered function of the protein. The activator-defective mutation is a single nucleotide change within codon 409, replacing glycine with aspartic acid. One activator-constitutive mutation is a nucleotide change at codon 683, substituting phenylalanine for serine. The remaining constitutive mutations resulted in amino acid substitutions or truncations of the protein within the carboxy-terminal 76 codons. Mechanisms for regulating the activation function of the PUT3 protein are discussed.

Proline-independent binding of PUT3 transcriptional activator protein detected by footprinting in vivo.

The PUT3 gene product is a transcriptional activator required for expression of the enzymes of the proline utilization pathway. Using two methods of footprinting in vivo, we have determined that PUT3 protein is poised at the promoters of the genes encoding these enzymes and that proline-mediated induction modulates the activity of constitutively bound PUT3.

Isolation of constitutive mutations affecting the proline utilization pathway in Saccharomyces cerevisiae and molecular analysis of the PUT3 transcriptional activator.

The enzymes of the proline utilization pathway (the products of the PUT1 and PUT2 genes) in Saccharomyces cerevisiae are coordinately regulated by proline and the PUT3 transcriptional activator. To learn more about the control of this pathway, constitutive mutations in PUT3 as well as in other regulators were sought. A scheme using a gene fusion between PUT1 (S. cerevisiae proline oxidase) and galK (Escherichia coli galactokinase) was developed to select directly for constitutive mutations affecting the PUT1 promoter. These mutations were secondarily screened for their effects in trans on the promoter of the PUT2 (delta 1-pyrroline-5-carboxylate dehydrogenase) gene by using a PUT2-lacZ (E. coli beta-galactosidase) gene fusion. Three different classes of mutations were isolated. The major class consisted of semidominant constitutive PUT3 mutations that caused PUT2-lacZ expression to vary from 2 to 22 times the uninduced level. A single dominant mutation in a new locus called PUT5 resulted in low-level constitutive expression of PUT2-lacZ; this mutation was epistatic to the recessive, noninducible put3-75 allele. Recessive constitutive mutations were isolated that had pleiotropic growth defects; it is possible that these mutations are not specific to the proline utilization pathway but may be in genes that control several pathways. Since the PUT3 gene appears to have a major role in the regulation of this pathway, a molecular analysis was undertaken. This gene was cloned by functional complementation of the put3-75 mutation. Strains carrying a complete deletion of this gene are viable, proline nonutilizing, and indistinguishable in phenotype from the original put3-75 allele. The PUT3 gene encodes a 2.8-kilobase-pair transcript that is not regulated by proline at the level of RNA accumulation. The presence of the gene on a high-copy-number plasmid did not alter the regulation of one of its target genes, PUT2-lacZ, suggesting that the PUT3 gene product is not limiting and that a titratable repressor is not involved in the regulation of this pathway.

The Saccharomyces cerevisiae PUT3 activator protein associates with proline-specific upstream activation sequences.

The PUT1 and PUT2 genes encoding the enzymes of the proline utilization pathway of Saccharomyces cerevisiae are induced by proline and activated by the product of the PUT3 gene. Two upstream activation sequences (UASs) in the PUT1 promoter were identified by homology to the PUT2 UAS. Deletion analysis of the two PUT1 UASs showed that they were functionally independent and additive in producing maximal levels of gene expression. The consensus PUT UAS is a 21-base-pair partially palindromic sequence required in vivo for induction of both genes. The results of a gel mobility shift assay demonstrated that the proline-specific UAS is the binding site of a protein factor. In vitro complex formation was observed in crude extracts of yeast strains carrying either a single genomic copy of the PUT3 gene or the cloned PUT3 gene on a 2 microns plasmid, and the binding was dosage dependent. DNA-binding activity was not observed in extracts of strains carrying either a put3 mutation that caused a noninducible (Put-) phenotype or a deletion of the gene. Wild-type levels of complex formation were observed in an extract of a strain carrying an allele of PUT3 that resulted in a constitutive (Put+) phenotype. Extracts from a strain carrying a PUT3-lacZ gene fusion formed two complexes of slower mobility than the wild-type complex. We conclude that the PUT3 product is either a DNA-binding protein or part of a DNA-binding complex that recognizes the UASs of both PUT1 and PUT2. Binding was observed in extracts of a strain grown in the presence or absence of proline, demonstrating the constitutive nature of the DNA-protein interaction.

In vitro import of cytochrome c peroxidase into the intermembrane space: release of the processed form by intact mitochondria.

Cytochrome c peroxidase (CCP) is a nuclearly encoded hemoprotein located in the intermembrane space (IMS) of Saccharomyces cerevisiae mitochondria. Wild-type preCCP synthesized in rabbit reticulocyte lysates, however, was inefficiently translocated into isolated mitochondria and was inherently resistant to externally added proteases. To test whether premature heme addition to the apoprecursor was responsible for the protease resistance and the inability to import preCCP, site-directed mutagenesis was used to replace the axial heme ligand (His175) involved in forming a pseudo-covalent link between the heme iron and CCP. Mutant proteins containing Leu, Arg, Met, or Pro at residue 175 of mature CCP were sensitive to proteolysis and were imported into isolated mitochondria as judged by proteolytic processing of the precursor. The inhibition of wild-type CCP translocation across the outer membrane may result from the inability of the heme-containing protein to unfold during the translocation process. Although the protease responsible for cleaving preCCP to its mature form is believed to be located in the IMS, most of the processed CCP was located in the supernatant rather than the mitochondrial pellet. Since the outer membranes were shown to be intact, the anomalous localization indicated that preCCP may not have been completely translocated into the IMS before proteolytic processing or that conformationally labile proteins may not be retained by the outer membrane. Proteolytic maturation of preCCP also occurred in the presence of valinomycin, suggesting that the precursor may be completely or partially translocated across the outer mitochondrial membrane independent of a potential across the inner mitochondrial membrane.

A regulatory region responsible for proline-specific induction of the yeast PUT2 gene is adjacent to its TATA box.

Deletion analysis of the promoter of the PUT2 gene that functions in the proline utilization pathway of Saccharomyces cerevisiae identified a PUT2 upstream activation site (UAS). It is contained within a single 40-base-pair (bp) region located immediately upstream of the TATA box and is both necessary and sufficient for proline induction. When placed upstream of a CYC7-lacZ gene fusion, the 40-bp sequence conferred proline regulation on CYC7-lacZ. A 35-bp deletion within the PUT2 UAS in an otherwise intact PUT2 promoter resulted in noninducible expression of a PUT2-lacZ gene fusion. When a plasmid bearing this UAS-deleted promoter was placed in a strain carrying a constitutive mutation in the positive regulatory gene PUT3, expression of PUT2-lacZ was not constitutive but occurred at levels below those found under noninducing conditions. In heterologous as well as homologous gene fusions, the PUT2 UAS appeared to be responsible for uninduced as well as proline-induced levels of expression. Although located immediately adjacent to the PUT2 UAS, the TATA box did not appear to play a regulatory role, as indicated by the results of experiments in which it was replaced by the CYC7 TATA box. A 26-bp sequence containing this TATA box was critical to the expression of PUT2, since a deletion of this region completely abolished transcriptional activity of the gene under both inducing and noninducing conditions. Our results indicate that the PUT2 promoter has a comparatively simple structure, requiring UAS and TATA sequences as well as the PUT3 gene product (directly or indirectly) for its expression.

Gene-enzyme relationships in the proline biosynthetic pathway of Saccharomyces cerevisiae.

The PRO1, PRO2, and PRO3 genes were isolated by functional complementation of pro1, pro2, and pro3 (proline-requiring) strains of Saccharomyces cerevisiae. Independent clones with overlapping inserts were isolated from S. cerevisiae genomic libraries in YEp24 (2 microns) and YCp50 (CEN) plasmids. The identity of each gene was determined by gene disruption, and Southern hybridization and genetic analyses confirmed that the bona fide genes had been cloned. Plasmids containing each gene were introduced into known bacterial proline auxotrophs, and the ability to restore proline prototrophy was assessed. Interspecies complementation demonstrated that the S. cerevisiae PRO1 gene encoded gamma-glutamyl kinase, PRO2 encoded gamma-glutamyl phosphate reductase, and PRO3 encoded delta 1-pyrroline-5-carboxylate reductase. The presence of the PRO3 gene on a high-copy-number plasmid in S. cerevisiae caused a 20-fold overproduction of delta 1-pyrroline-5-carboxylate reductase. The PRO2 gene mapped on chromosome XV tightly linked to cdc66, and the PRO3 gene was located on the right arm of chromosome V between HIS1 and the centromere.

Proline utilization in Saccharomyces cerevisiae: sequence, regulation, and mitochondrial localization of the PUT1 gene product.

The PUT1 gene of Saccharomyces cerevisiae, believed to encode proline oxidase, has been completely sequenced and contains an open reading frame capable of encoding a polypeptide of 476 amino acids in length. The amino terminus of the protein deduced from the DNA sequence has a characteristic mitochondrial import signal; two PUT1-lacZ gene fusions were constructed that produced mitochondrially localized beta-galactosidase in vivo. The transcription initiation and termination sites of the PUT1 mRNA were determined. By using a PUT1-lacZ gene fusion that makes a cytoplasmic beta-galactosidase, the regulation of the PUT1 gene was studied. PUT1 is inducible by proline, responds only slightly to carbon catabolite repression, and is not regulated by the cytochrome activator proteins HAP1 and HAP2. The PUT1 gene is under oxygen regulation; expression in anaerobically grown cells is 10-fold lower than in aerobically grown cells. Oxygen regulation is abolished when cells are respiratory deficient. PUT1 expression in a [rho-] strain grown either aerobically or anaerobically is as high as that seen in a [rho+] strain grown aerobically. Studies on PUT1 promoter deletions define a region between positions -458 and -293 from the translation initiation site that is important for full expression of the PUT1 gene and required for oxygen regulation.

Evidence for positive regulation of the proline utilization pathway in Saccharomyces cerevisiae.

A mutation has been identified that prevents Saccharomyces cerevisiae cells from growing on proline as the sole source of nitrogen, causes noninducible expression of the PUT1 and PUT2 genes, and is completely recessive. In the put3-75 mutant, the basal level of expression (ammonia as nitrogen source) of PUT1-lacZ and PUT2-lacZ gene fusions as measured by beta-galactosidase activity is reduced 4- and 7-fold, respectively, compared with the wild-type strain. Normal regulation is not restored when the cells are grown on arginine as the sole nitrogen source and put3-75 cells remain sensitive to the proline analog, L-azetidine-2-carboxylic acid, indicating that the block is not at the level of transport of the inducer, proline. In a cross between the put3-75 strain and the semidominant, constitutive mutation PUT3c-68, only parental ditype tetrads were found, indicating allelism of the two mutations. Further support for allelism derives from the comparison of enzyme levels in heteroallelic and heterozygous diploid strains. The constitutive allele appears to be fully dominant to the noninducible allele but only partially dominant to the wild type, suggesting an interaction between the wild-type and PUT3c-68 gene products. The PUT3 gene maps on chromosome XI, about 5.7 cM from the centromere. The phenotypes of alleles of the PUT3 gene, either recessive and noninducible (the put3-75 phenotype) or semidominant and constitutive (the PUT3c-68 phenotype), and their pleiotropy suggest that the PUT3 gene product is a positive activator of the proline utilization pathway.

Amino-terminal fragments of delta 1-pyrroline-5-carboxylate dehydrogenase direct beta-galactosidase to the mitochondrial matrix in Saccharomyces cerevisiae.

delta 1-Pyrroline-5-carboxylate (P5C) dehydrogenase, the second enzyme in the proline utilization (Put) pathway of Saccharomyces cerevisiae and the product of the PUT2 gene, was localized to the matrix compartment by a mitochondrial fractionation procedure. This result was confirmed by demonstrating that the enzyme had limited activity toward an externally added substrate that could not penetrate the inner mitochondrial membrane (latency). To learn more about the nature of the import of this enzyme, three gene fusions were constructed that carried 5'-regulatory sequences through codons 14, 124, or 366 of the PUT2 gene ligated to the lacZ gene of Escherichia coli. When these fusions were introduced into S. cerevisiae either on multicopy plasmids or stably integrated into the genome, proline-inducible beta-galactosidase was made. The shortest gene fusion, PUT2-lacZ14, caused the production of a high level of beta-galactosidase that was found exclusively in the cytoplasm. The PUT2-lacZ124 and PUT2-lacZ366 fusions made lower levels of beta-galactosidases that were mitochondrially localized. Mitochondrial fractionation and protease-protection experiments showed that the PUT2-lacZ124 hybrid protein was located exclusively in the matrix, while the PUT2-lacZ366 hybrid was found in the matrix as well as the inner membrane. Thus, the amino-terminal 124 amino acids of P5C dehydrogenase carries sufficient information to target and deliver beta-galactosidase to the matrix compartment. The expression of the longer hybrids had deleterious effects on cell growth; PUT2-lacZ366-containing strains failed to grow on proline as the sole source of nitrogen. In the presence of the longest hybrid beta-galactosidase, the wild-type P5C dehydrogenase was still properly localized in the matrix compartment, but its activity was reduced. The nature of the effects of these hybrid proteins on cell growth is discussed.

Proline utilization in Saccharomyces cerevisiae: analysis of the cloned PUT1 gene.

The PUT1 gene was isolated by functional complementation of a put1 (proline oxidase-deficient) mutation in Saccharomyces cerevisiae. Three independent clones with overlapping inserts of 6.8, 10.5, and 11 kilobases (kb) were isolated from S. cerevisiae genomic libraries in YEp24 (2 micron) and YCp50 (CEN) plasmids. The identity of the PUT1 gene was determined by a gene disruption technique, and Southern hybridization and genetic analyses confirmed that the bona fide gene had been cloned. Plasmids containing the PUT1 gene restored regulated levels of proline oxidase activity to put1 recipient strains. The PUT1 DNA was present in a single copy in the yeast genome and encoded a transcript of ca. 1.5 kb. S1 nuclease protection experiments were used to determine the direction of transcription of the PUT1 message and to localize its 5' and 3' termini within a subcloned 3-kb DNA fragment. Approximately 50-fold more PUT1-specific mRNA was detected in induced (proline-grown) cells than in uninduced (ammonia-grown) cells. A yeast strain carrying the previously identified put3 regulatory mutation that caused constitutive levels of proline oxidase activity was found to have sevenfold elevated PUT1 mRNA levels under noninducing conditions. The absence of a functional electron transport system in vegetative petite (rho-) strains interfered with their ability to use proline as a nitrogen source. Although these strains were Put- and made no detectable proline oxidase activity, PUT1 message was detected under inducing conditions. The PUT1 gene was mapped distal to the GAL2 gene on chromosome XII by tetrad analysis.