The role of transmembrane domain III in the lactose permease of Escherichia coli.

Deletion of putative transmembrane helix III from the lactose permease of Escherichia coli results in complete loss of transport activity. Similarly, replacement of this region en bloc with 23 contiguous Ala, Leu, or Phe residues abolishes active lactose transport. The observations suggest that helix III may contain functionally important residues; therefore, this region was subjected to Cys-scanning mutagenesis. Using a functional mutant devoid of Cys residues (C-less permease) each residue from Tyr 75 to Leu 99 was individually replaced with Cys. Twenty-one of the 25 mutants accumulate lactose to > 70% of the steady-state exhibited by C-less permease, and an additional 3 mutants transport to lower, but significant levels (40-60% of C-less). Cys replacement for Leu 76 results in low transport activity (18% of C-less). However, when placed in the wild-type background, mutant Leu 76-->Cys exhibits highly significant rates of transport (55% of wild type) and steady-state levels of lactose accumulation (65% of wild type). Immunoblots reveal that the mutants are inserted into the membrane at concentrations comparable to wild type. Studies with N-ethylmaleimide show that mutant Gly 96-->Cys is rapidly inactivated, whereas the other single-Cys mutants are not altered significantly by the alkylating agent. Moreover, the rate of inactivation of Gly 96-->Cys permease is enhanced at least 2-fold in the presence of beta-galactopyranosyl 1-thio-beta, D-galactopyranoside. The observations demonstrate that although no residue per se appears to be essential, structural properties of helix III are important for active lactose transport.     

Genetic studies of the pyrimidine permeases from Saccharomyces cerevisiae: lack of intragenic complementation.

Summary A search for intragenic complementation of mutants of the cytosine and uracil permeases of Saccharomyces cerevisiae was made. Among numerous diploïd pairs of mutants of the cytosine permease gene no complementation was found. Similarly negative results were obtained with pairs of mutants of the uracil permease. The significance of these results is discussed.     

Photoaffinity labelling of the purine-cytosine permease of Saccharomyces cerevisiae

8-Azidoadenine was used as a photoaffinity reagent to characterize the purine-cytosine permease of Saccharomyces cerevisiae. It is a potent competitive inhibitor of cytosine uptake and irradiation of the cells incubated with the label induced the irreversible inactivation of cytosine uptake. Addition of excess cytosine prevented this labelling which was restricted to the outer face of the plasma membrane since it was not accumulated by the cells. In the strain with the amplified purine-cytosine permease gene the maximum cytosine uptake rate was increased 4-5-fold relative to wild type without a modification of the Michaelis constant of uptake (Kt); no uptake could be measured in the deleted strain. The relative amounts of specific labelling determined for the cells and for membrane preparations were 0, 1 and 4 for the null, the wild-type and the amplified strains, respectively. One major band specifically labelled by [3H]azidoadenine, corresponding to a polypeptide with an apparent molecular mass of 45 kDa, was observed in the wild type, amplified in the strain carrying the multicopy plasmid and not detected in the deleted strain. Therefore this polypeptide corresponds to the purine-cytosine permease.     

Role of uracil-DNA glycosylase in the repair of deaminated cytosine residues of DNA in Escherichia coli.

Uracil-DNA glycosylase, which acts specifically on uracil-containing DNA, was purified 250-fold from an extract of Escherichia coli 1100. The enzyme releases free uracil from DNA, producing alkali-labile apyrimidinic sites in the DNA. The enzyme is active on both native and heat-denatured DNA of phage PBS1, which contains uracil in place of thymine. piX174 DNA which had been treated with bisulfite and then at alkaline pH was susceptible to the action of uracil-DNA glycosylase. Since DNA treated with bisulfite alone was less susceptible to the enzyme, it is likely that the enzyme recognizes deaminated cytosine, namely uracil, but not bisulfite adducts of uracil and cytosine in the treated DNA. DNA treated with nitrite or hydroxylamine was not attacked by the enzyme. Enzyme activity acting on bisulfite-treated DNA was absent from an extract of E. coli mutant BD10 (ung). The mutant exhibited higher sensitivity to bisulfite than did the wild-type strain and was unable to reactivate phage T1 pre-exposed to bisulfite and weak alkali.     

Cysteine scanning mutagenesis of putative transmembrane helices IX and X in the lactose permease of Escherichia coli.

Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino-acid residue in putative transmembrane helices IX and X and the short intervening loop was systematically replaced with Cys (from Asn-290 to Lys-335). Thirty-four of 46 mutants accumulate lactose to high levels (70-100% or more of C-less), and an additional 7 mutants exhibit lower but highly significant lactose accumulation. As expected (see Kaback, H.R., 1992, Int. Rev. Cytol. 137A, 97-125), Cys substitution for Arg-302, His-322, or Glu-325 results in inactive permease molecules. Although Cys replacement for Lys-319 or Phe-334 also inactivates lactose accumulation, Lys-319 is not essential for active lactose transport (Sahin-Tóth, M., Dunten, R.L., Gonzalez, A., & Kaback, H.R., 1992, Proc. Natl. Acad. Sci. USA 89, 10547-10551), and replacement of Phe-334 with leucine yields permease with considerable activity. All single-Cys mutants except Gly-296 --> Cys are present in the membrane in amounts comparable to C-less permease, as judged by immunological techniques. In contrast, mutant Gly-296 --> Cys is hardly detectable when expressed at a relatively low rate from the lac promoter/operator but present in the membrane in stable form when expressed at a high rate from T7 promoter. Finally, studies with N-ethylmaleimide (NEM) show that only a few mutants are inactivated significantly. Remarkably, the rate of inactivation of Val-315 --> Cys permease is enhanced at least 10-fold in the presence of beta-galactopyranosyl 1-thio-beta-D-galactopyranoside (TDG) or an H+ electrochemical gradient (delta mu-H+). The results demonstrate that only three residues in this region of the permease -Arg-302, His-322, and Glu-325-are essential for active lactose transport. Furthermore, the enhanced reactivity of the Val-315 --> Cys mutant toward NEM in the presence of TDG or delta mu-H+ probably reflects a conformational alteration induced by either substrate binding or delta mu-H+.     

Growth inhibition of Saccharomyces cerevisiae by the immunosuppressant leflunomide is due to the inhibition of uracil uptake via Fur4p

The immunosuppressant leflunomide inhibits cytokine-stimulated proliferation of lymphoid cells in vitro and also inhibits the growth of the eukaryotic microorganism Saccharomyces cerevisiae. To elucidate the molecular mechanism of action of the drug, two yeast genes which suppress the anti-proliferative effect when present in multiple copies were cloned and designated MLF1 and MLF2 for multicopy suppressor of leflunomide sensitivity. DNA sequencing analysis revealed that the MLF1 gene is identical to the FUR4 gene, which encodes a uracil permease and functions to import uracil efficiently. The MLF2 was found to be identical to the URA3 gene. Excess exogenous uracil also overcomes the anti-proliferative effect of leflunomide on yeast cells. Uracil prototrophy also conferred resistance to leflunomide. Uracil uptake was inhibited by leflunomide. Thus, the growth inhibition by leflunomide seen in a S. cerevisiae ura3 auxotroph is due to the inhibition of the entry of exogenous uracil via the Fur4 uracil permease. Received: 7 May 1998 / Accepted: 16 July 1998     

Excision of cytosine and thymine from DNA by mutants of human uracil-DNA glycosylase.

Uracil-DNA glycosylase (UDG) protects the genome by removing mutagenic uracil residues resulting from deamination of cytosine. Uracil binds in a rigid pocket at the base of the DNA-binding groove of human UDG and the specificity for uracil over the structurally related DNA bases thymine and cytosine is conferred by shape complementarity, as well as by main chain and Asn204 side chain hydrogen bonds. Here we show that replacement of Asn204 by Asp or Tyr147 by Ala, Cys or Ser results in enzymes that have cytosine-DNA glycosylase (CDG) activity or thymine-DNA glycosylase (TDG) activity, respectively. CDG and the TDG all retain some UDG activity. CDG and TDG have kcat values in the same range as typical multisubstrate-DNA glycosylases, that is at least three orders of magnitude lower than that of the highly selective and efficient wild-type UDG. Expression of CDG or TDG in Escherichia coli causes 4- to 100-fold increases in the yield of rifampicin-resistant mutants. Thus, single amino acid substitutions in UDG result in less selective DNA glycosylases that release normal pyrimidines and confer a mutator phenotype upon the cell. Three of the four new pyrimidine-DNA glycosylases resulted from single nucleotide substitutions, events that may also happen in vivo.     

W-mutagenesis in the bisulfite-treated lambda phage

Survival of phage lambda cI857 inactivated by bisulfite (pH 5.6, 37 degrees C) is higher (the dose modification factor approx. 1.2) and frequency of bisulfite-induced c-mutations 2-4-fold lower on the lawn of the wild-type strain ung+, as compared to ung-1 mutant deficient in uracil-DNA glycosylase. Irradiation of host cells by a moderate UV dose inducing SOS repair system enhances the frequency of bisulfite-induced c-mutations 2-3-fold in the wild-type (ung+) host, but not in the ung-1 mutant. It is suggested that W-mutagenesis in bisulfite-treated lambda phage in the ung+ cells is due to SOS repair of apyrimidinic sites which are produced during excision of uracil residues, the products of cytosine deamination.     

Control of the pyrimidine biosynthetic pathway in Pseudomonas pseudoalcaligenes

The five de novo enzyme activities unique to the pyrimidine biosynthetic pathway were found to be present in Pseudomonas pseudoalcaligenes ATCC 17440. A mutant strain with 31-fold reduced orotate phosphoribosyltransferase (encoded by pyrE) activity was isolated that exhibited a pyrimidine requirement for uracil or cytosine. Uptake of the nucleosides uridine or cytidine by wild-type or mutant cells was not detectable; explaining the inability of the mutant strain to utilize either nucleoside to satisfy its pyrimidine requirement. When the wildtype strain was grown in the presence of uracil, the activities of the five de novo enzymes were depressed. Pyrimidine limitation of the mutant strain led to the increase in aspartate transcarbamoylase and dihydroorotate dehydrogenase activities by more than 3-fold, and dihydroorotase and orotidine 5-monophosphate decarboxylase activities about 1.5-fold, as compared to growth with excess uracil. It appeared that the syntheses of the de novo enzymes were regulated by pyrimidines. In vitro regulation of aspartate transcarbamoylase activity in P. pseudoalcaligenes ATCC 17440 was investigated using saturating substrate concentrations; transcarbamoylase activity was inhibited by P_i, PP_i, uridine ribonucleotides, ADP, ATP, GDP, GTP, CDP, and CTP.     

Alanine-scanning mutagenesis reveals a cytosine deaminase mutant with altered substrate preference

Suicide gene therapy of cancer is a method whereby cancerous tumors can be selectively eradicated while sparing damage to normal tissue. This is accomplished by delivering a gene, encoding an enzyme capable of specifically converting a nontoxic prodrug into a cytotoxin, to cancer cells followed by prodrug administration. The Escherichia coli gene, codA, encodes cytosine deaminase and is introduced into cancer cells followed by administration of the prodrug 5-fluorocytosine (5-FC). Cytosine deaminase converts 5-FC into cytotoxic 5-fluorouracil, which leads to tumor-cell eradication. One limitation of this enzyme/prodrug combination is that 5-FC is a poor substrate for bacterial cytosine deaminase. The crystal structure of bacterial cytosine deaminase (bCD) reveals that a loop structure in the active site pocket of wild-type bCD comprising residues 310-320 undergoes a conformational change upon cytosine binding, making several contacts to the pyrimidine ring. Alanine-scanning mutagenesis was used to investigate the structure-function relationship of amino acid residues within this region, especially with regard to substrate specificity. Using an E. coli genetic complementation system, seven active mutants were identified (F310A, G311A, H312A, D314A, V315A, F316A, and P318A). Further characterization of these mutants reveals that mutant F316A is 14-fold more efficient than the wild-type at deaminating cytosine to uracil. The mutant D314A enzyme demonstrates a dramatic decrease in cytosine activity (17-fold) as well as a slight increase in activity toward 5-FC (2-fold), indicating that mutant D314A prefers the prodrug over cytosine by almost 20-fold, suggesting that it may be a superior suicide gene.     

Specific mutator effects of ung (uracil-DNA glycosylase) mutations in Escherichia coli.

Studies of trpA reversions revealed that G:C leads to A:T transitions were stimulated about 30-fold in E. coli ung mutants, whereas other base substitutions were not affected. A dUTPase (dut) mutation, which increases the incorporation of uracil into DNA in place of thymine, had no significant effect on the rate of G:C leads to A:T transitions. The results support the proposal that the glycosylase functions to reduce the mutation rate in wild-type cells by acting in the repair of DNA cytosine residues that have undergone spontaneous deamination to uracil. Further support was provided by the finding that when lambda bacteriophages were treated with bisulfite, an agent known to produce cytosine deamination, the frequency of clear-plaque mutants was increased an additional 20-fold by growth on an ung host. Bisulfite-induced mutations of the cellular chromosome, however, were about equal in ung+ and ung strains; it was found that during the treatment of ung+ cells with bisulfite, the glycosylase was inactivated.     

Stability of the lactose permease in detergent solutions

Protein stability, as measured by irreversible protein aggregation, is one of the central difficulties in the handling of detergent-solubilized membrane proteins. We present a quantitative analysis of the stability of the Escherichia coli lactose (lac) permease and a series of lac permease fusion proteins containing an insertion of cytochrome_b562, T4 lysozyme or β-lactamase in the central hydrophilic loop of the permease. The stability of the proteins was evaluated under a variety of storage conditions by both a qualitative SDS-PAGE assay and by a quantitative hplc assay. Long-chain maltoside detergents were more effective at maintaining purified protein in solution than detergents with smaller head groups and/or shorter alkyl tails. A full factorial experiment established that the proteins were insensitive to sodium chloride concentrations, but greatly stabilized by glycerol, low temperature and the combination of glycerol and low temperature. The accurate quantitation of the protein by absorbance spectroscopy required exclusion of all contact with clarified polypropylene or polyvinyl chloride (PVC) materials. Although some of the fusion proteins were more prone to aggregation than the wild-type permease, the stability of a fusion protein containing a cytochrome_b562 insertion was indistinguishable from that of native lac permease.     

Cysteine scanning mutagenesis of the N-terminal 32 amino acid residues in the lactose permease of Escherichia coli.

Using a functional lactose permease mutant devoid of Cys residues (C-less permease), each amino acid residue in the hydrophilic N-terminus and the first putative transmembrane helix was systematically replaced with Cys (from Tyr-2 to Trp-33). Twenty-three of 32 mutants exhibit high lactose accumulation (70-100% or more of C-less), and an additional 8 mutants accumulate to lower but highly significant levels. Surprisingly, Cys replacement for Gly-24 or Tyr-26 yields fully active permease molecules, and permease with Cys in place of Pro-28 also exhibits significant transport activity, although previous mutagenesis studies on these residues suggested that they may be required for lactose transport. As expected, Cys replacement for Pro-31 completely inactivates, in agreement with previous findings indicating that "helix-breaking" propensity at this position is necessary for full activity (Consler TG, Tsolas O, Kaback HR, 1991, Biochemistry 30:1291-1297). Twenty-nine mutants are present in the membrane in amounts comparable to C-less permease, whereas membrane levels of mutants Tyr-3-->Cys and Phe-12-->Cys are slightly reduced, as judged by immunological techniques. Dramatically, mutant Phe-9-->Cys is hardly detectable when expressed from the lac promoter/operator at a relatively low rate, but is present in the membrane in a stable form when expressed at a high rate from the T7 promoter. Finally, studies with N-ethylmalemide show that 6 Cys-replacement mutants that cluster at the C-terminal end of putative helix I are inactivated significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ubiquitin lys63 is involved in ubiquitination of a yeast plasma membrane protein.

We have recently reported that the yeast plasma membrane uracil permease undergoes cell-surface ubiquitination, which is dependent on the Npi1/Rsp5 ubiquitin-protein ligase. Ubiquitination of this permease, like that of some other transporters and receptors, signals endocytosis of the protein, leading to its subsequent vacuolar degradation. This process does not involve the proteasome, which binds and degrades ubiquitin-protein conjugates carrying Lys48-linked ubiquitin chains. The data presented here show that ubiquitination and endocytosis of uracil permease are impaired in yeast cells lacking the Doa4p ubiquitin-isopeptidase. Both processes were rescued by overexpression of wild-type ubiquitin. Mutant ubiquitins carrying Lys-->Arg mutations at Lys29 and Lys48 restored normal permease ubiquitination. In contrast, a ubiquitin mutated at Lys63 did not restore permease polyubiquitination. Ubiquitin-permease conjugates are therefore extended through the Lys63 of ubiquitin. When polyubiquitination through Lys63 is blocked, the permease still undergoes endocytosis, but at a reduced rate. We have thus identified a natural target of Lys63-linked ubiquitin chains. We have also shown that monoubiquitination is sufficient to induce permease endocytosis, but that Lys63-linked ubiquitin chains appear to stimulate this process.     

A sensitive genetic assay for the detection of cytosine deamination: determination of rate constants and the activation energy

Previously it has not been possible to determine the rate of deamination of cytosine in DNA at 37 degrees C because this reaction occurs so slowly. We describe here a sensitive genetic assay to measure the rate of cytosine deamination in DNA at a single cytosine residue. The assay is based on reversion of a mutant in the lacZ alpha gene coding sequence of bacteriophage M13mp2 and employs ung- bacterial strains lacking the enzyme uracil glycosylase. The assay is sufficiently sensitive to allow us to detect, at a given site, a single deamination event occurring with a background frequency as low as 1 in 200,000. With this assay, we determined cytosine deamination rate constants in single-stranded DNA at temperatures ranging from 30 to 90 degrees C and then calculated that the activation energy for cytosine deamination in single-stranded DNA is 28 +/- 1 kcal/mol. At 80 degrees C, deamination rate constants at six sites varied by less than a factor of 3. At 37 degrees C, the cytosine deamination rate constants for single- and double-stranded DNA at pH 7.4 are 1 x 10(-10) and about 7 x 10(-13) per second, respectively. (In other words, the measured half-life for cytosine in single-stranded DNA at 37 degrees C is ca. 200 years, while in double-stranded DNA it is on the order of 30,000 years.) Thus, cytosine is deaminated approximately 140-fold more slowly when present in the double helix. These and other data indicate that the rate of deamination is strongly dependent upon DNA structure and the degree of protonation of the cytosine. The data suggest that agents which perturb DNA structure or facilitate direct protonation of cytosine may induce deamination at biologically significant rates. The assay provides a means to directly test the hypothesis.     

Direct sorting of the yeast uracil permease to the endosomal system is controlled by uracil binding and Rsp5p-dependent ubiquitylation

The yeast uracil permease, Fur4p, is downregulated by uracil, which is toxic to cells with high permease activity. Uracil promotes cell surface Rsp5p-dependent ubiquitylation of the permease, signaling its endocytosis and further vacuolar degradation. We show here that uracil also triggers the direct routing of its cognate permease from the Golgi apparatus to the endosomal system for degradation, without passage via the plasma membrane. This early sorting was not observed for a variant permease with a much lower affinity for uracil, suggesting that uracil binding is the signal for the diverted pathway. The FUI1-encoded uridine permease is similarly sorted for early vacuolar degradation in cells exposed to a toxic level of uridine uptake. Membrane proteins destined for vacuolar degradation require sorting at the endosome level to the intraluminal vesicles of the multivesicular bodies. In cells with low levels of Rsp5p, Fur4p can be still diverted from the Golgi apparatus but does not reach the vacuolar lumen, being instead missorted to the vacuolar membrane. Correct luminal delivery is restored by the biosynthetic addition of a single ubiquitin, suggesting that the ubiquitylation of Fur4p serves as a specific signal for sorting to the luminal vesicles of the multivesicular bodies. A fused ubiquitin is also able to sort some Fur4p from the Golgi to the degradative pathway in the absence of added uracil but the low efficiency of this sorting indicates that ubiquitin does not itself act as a dominant signal for Golgi-to-endosome trafficking. Our results are consistent with a model in which the binding of intracellular uracil to the permease signals its sorting from the Golgi apparatus and subsequent ubiquitylation ensures its delivery to the vacuolar lumen.     

Sequence-dependent enhancement of hydrolytic deamination of cytosines in DNA by the restriction enzyme PspGI

Hydrolytic deamination of cytosines in DNA creates uracil and, if unrepaired, these lesions result in C to T mutations. We have suggested previously that a possible way in which cells may prevent or reduce this chemical reaction is through the binding of proteins to DNA. We use a genetic reversion assay to show that a restriction enzyme, PspGI, protects cytosines within its cognate site, 5′-CCWGG (W is A or T), against deamination under conditions where no DNA cleavage can occur. It decreases the rate of cytosine deamination to uracil by 7-fold. However, the same protein dramatically increases the rate of deaminations within the site 5′-CCSGG (S is C or G) by ~15-fold. Furthermore, a similar increase in cytosine deaminations is also seen with a catalytically inactive mutant of the enzyme showing that endonucleolytic ability of the protein is dispensable for its mutagenic action. The sequences of the mutants generated in the presence of PspGI show that only one of the cytosines in CCSGG is predominantly converted to thymine. Our results are consistent with PspGI ‘sensitizing’ the cytosine in the central base pair in CCSGG for deamination. Remarkably, PspGI sensitizes this base for damage despite its inability to form stable complexes at CCSGG sites. These results can be explained if the enzyme has a transient interaction with this sequence during which it flips the central cytosine out of the helix. This prediction was validated by modeling the structure of PspGI–DNA complex based on the structure of the related enzyme Ecl18kI which is known to cause base-flipping.     

A protonmotive force as the source of energy for galactoside transport in energy depletedEscherichia Coli

Summary Uracil transport inSaccharomyces cerevisiae is mediated by a specific permease which does not recognize other pyrimidines such as uridine, cytosine, thymine, 2-hydroxypyrimidine or 5-amino-uracil; hypoxanthine and 6-amino-uracil slightly inhibit the uptake of uracil in a strain lacking cytosine permease activity. Wild type cells concentrate extracellular uracil before its transformation into UMP and subsequent incorporation into nucleic acids. A strain lacking UMP pyrophosphorylase and uridine ribohydrolase (strainfur 1–8 rh, in which the endogenous production as well as the utilization of uracil are lacking) is able to concentrate¹⁴C-2 uracil from the medium. At the same time no other¹⁴C-2 labelled compound could be detected in this strain, thus suggesting that the uptake of uracil in yeast occurs by active transport which is not coupled to the UMP pyrophosphorylase. The optimal pH of uracil uptake in standard growth conditions was 4.3. It was deduced from experiments performed on strainfur 1–8 rh with³H-5 and¹⁴C-2 uracil that the intracellular pool of uracil is recycled once the steady-state has been reached. First order kinetics with similar rate constants were observed for uracil efflux in strainfur 1–8 rh (k min^–1=0.75±0.08) as well as in the strain lacking uracil permease,fur 1–8 rh fur 4–6 (k min^–1=0.60±0.08). The intracellular pool of¹⁴C-2 uracil can be chased in strainfur 1–8 rh by addition of³H uracil without inducing a large initial acceleration of the exit rate (the rate constant remained at 0.60). 2-4-dinitrophenol inhibits the uptake of uracil but also reduces the efflux of uracil in strainfur 1–8 rh fur 4–6. These data and the comparison with cytosine transport in the same organism support the hypothesis that, whereas uracil uptake is a permease mediated active transport, the efflux of uracil does not involve the uracil uptake permease. A coefficient of permeability of 7.4×10^–7 cm sec^–1 was calculated for uracil.     

Peptide substrates rapidly modulate expression of dipeptide and oligopeptide permeases in Candida albicans

Previous studies showed that peptide transport activity in Candida albicans was completely repressed by NH4+, and that growth on amino acids as sole nitrogen source stimulated transport to a basal level. Here we show that addition of peptide mixtures to culture media gives a further 5-fold increase in transport of dipeptides and oligopeptides; the effect is specific for peptide transport, amino acid uptake being unaffected. Presence of peptides but not amino acids overrides NH4+ repression of peptide transport. Step-up activation of transport activity, caused by addition of peptides to incubation media, and step-down inhibition that accompanies removal of peptides, occurs rapidly (within 30 min at 28 degrees C). Step-up is independent of de novo protein synthesis. This substrate-induced regulation is compatible with a rapid, reversible activation of plasma membrane-bound peptide permease(s), or a mechanism of endocytosis involving a cycle of insertion and retrieval of preformed permease components. These results are considered in relation to the expression of peptide permeases in vivo, and the development of synthetic anticandidal peptide carrier prodrugs designed to exploit these systems.     

Uracil-induced down-regulation of the yeast uracil permease

In Saccharomyces cerevisiae the FUR4-encoded uracil permease catalyzes the first step of the pyrimidine salvage pathway. The availability of uracil has a negative regulatory effect upon its own transport. Uracil causes a decrease in the level of uracil permease, partly by decreasing the FUR4 mRNA level in a promoter-independent fashion, probably by increasing its instability. Uracil entry also triggers more rapid degradation of the existing permease by promoting high efficiency of ubiquitination of the permease that signals its internalization. A direct binding of intracellular uracil to the permease is possibly involved in this feedback regulation, as the behavior of the permease is similar in mutant cells unable to convert intracellular uracil into UMP. We used cells impaired in the ubiquitination step to show that the addition of uracil produces rapid inhibition of uracil transport. This may be the first response prior to the removal of the permease from the plasma membrane. Similar down-regulation of uracil uptake, involving several processes, was observed under adverse conditions mainly corresponding to a decrease in the cellular content of ribosomes. These results suggest that uracil of exogenous or catabolic origin down-regulates the cognate permease to prevent buildup of excess intracellular uracil-derived nucleotides.