A PEST-like sequence mediates phosphorylation and efficient ubiquitination of yeast uracil permease.

Uptake of uracil by the yeast Saccharomyces cerevisiae is mediated by a specific permease encoded by the FUR4 gene. Uracil permease located at the cell surface is subject to two covalent modifications: phosphorylation and ubiquitination. The ubiquitination step is necessary prior to permease endocytosis and subsequent vacuolar degradation. Here, we demonstrate that a PEST-like sequence located within the cytoplasmic N terminus of the protein is essential for uracil permease turnover. Internalization of the transporter was reduced when some of the serines within the region were converted to alanines and severely impaired when all five serines within the region were mutated or when this region was absent. The phosphorylation and degree of ubiquitination of variant permeases were inversely correlated with the number of serines replaced by alanines. A serine-free version of this sequence was very poorly phosphorylated, and elimination of this sequence prevented ubiquitination. Thus, it appears that the serine residues in the PEST-like sequence are required for phosphorylation and ubiquitination of uracil permease. A PEST-like sequence in which the serines were replaced by glutamic acids allowed efficient permease turnover, suggesting that the PEST serines are phosphoacceptors.

Ubiquitin and endocytic internalization in yeast and animal cells.

Endocytosis is involved in a wide variety of cellular processes, and the internalization step of endocytosis has been extensively studied in both lower and higher eukaryotic cells. Studies in mammalian cells have described several endocytic pathways, with the main emphasis on clathrin-dependent endocytosis. Genetic studies in yeast have underlined the critical role of actin and actin-binding proteins, lipid modification, and the ubiquitin conjugation system. The combined results of studies of endocytosis in higher and lower eukaryotic cells reveal an interesting interplay in the two systems, including a crucial role for ubiquitin-associated events. The ubiquitylation of yeast cell-surface proteins clearly acts as a signal triggering their internalization. Mammalian cells display variations on the common theme of ubiquitin-linked endocytosis, according to the cell-surface protein considered. Many plasma membrane channels, transporters and receptors undergo cell-surface ubiquitylation, required for the internalization or later endocytic steps of some cell-surface proteins, whereas for others, internalization involves interaction with the ubiquitin conjugation system or with ancillary proteins, which are themselves ubiquitylated. Epsins and Eps15 (or Eps15 homologs), are commonly involved in the process of endocytosis in all eukaryotes, their critical role in this process stemming from their capacity to bind ubiquitin, and to undergo ubiquitylation.

Genetic and biochemical characterization of mutants of Saccharomyces cerevisiae blocked in six different steps of heme biosynthesis.

Heme-deficient mutants of Saccharomyces cerevisiae have been isolated from two isogenic strains with the use of an enrichment method based on photodynamic properties of Zn-protoporphyrin. They defined seven non-overlapping complementation groups. A mutant representative of each group was further analysed. Genetic analysis showed that each mutant carried a single nuclear recessive mutations. Biochemical studies showed that the observed accumulation and/or excretion of the different heme synthesis precursors by the mutant cells correlated well with the enzymatic deficiencies measured in acellular extracts. Six of the seven mutants were blocked in a different enzyme activity: 5-aminolevulinate synthase, porphobilinogen synthase, uroporphyrinogen I synthase, uroporphyrinogen decarboxylase, coproporphyrinogen III oxidase and ferrochelatase. The other mutant had the same phenotype as the mutant deficient in ferrochelatase activity. However, it possessed a normal ferrochelatase activity when measured in vitro, so this mutant was assumed to be deficient in protoporphyrinogen oxidase activity or in the transport and/or reduction of iron. The absence of PBG synthesis led to a total lack of uroporphyrinogen I synthase activity. The absence of heme, the end product, led to an important increase of coproporphyrinogen III oxidase activity, while the activity of 5-aminolevulinate synthase, the first enzyme of the pathway, was not changed. These results are discussed in terms of possible modes of regulation of heme synthesis pathway in yeast.

The presequence of yeast 5-aminolevulinate synthase is not required for targeting to mitochondria.

A truncated form of the yeast mitochondrial 5-aminolevulinate (ALA) synthase was constructed by deletion of the first 75 amino acid residues of its precursor form. This truncated ALA synthase which lost its entire presequence and 40 residues of the mature part possesses a new amino terminus quite different from a typical mitochondrial presequence. This modified protein expressed in vivo is found entirely located within mitochondria. Although it was now unable to reach the matrix space, it was internalized as shown by its resistance to protease in isolated mitochondria. Pulse-chase radiolabeling in the presence of an uncoupler suggests that a membrane potential is not required for the targeting of this truncated ALA synthase. Thus, the amino-terminal signal, if indispensable as a matrix targeting signal, could be replaced by an internal sequence or a particular folding for recognition by the import machinery.

Casein kinase I-dependent phosphorylation within a PEST sequence and ubiquitination at nearby lysines signal endocytosis of yeast uracil permease.

Uracil uptake by Saccharomyces cerevisiae is mediated by the FUR4-encoded uracil permease. The modification of uracil permease by phosphorylation at the plasma membrane is a key mechanism for regulating endocytosis of this protein. This modification in turn facilitates its ubiquitination and internalization. Following endocytosis, the permease is targeted to the lysosome/vacuole for proteolysis. We have previously shown that uracil permease is phosphorylated at several serine residues within a well characterized N-terminal PEST sequence. In this report, we provide evidence that lysine residues 38 and 41, adjacent to the PEST sequence, are the target sites for ubiquitination of the permease. Conservative substitutions at both Lys(38) and Lys(41) give variant permeases that are phosphorylated but fail to internalize. The PEST sequence contains potential phosphorylation sites conforming to the consensus sequences for casein kinase 1. Casein kinase 1 (CK1) protein kinases, encoded by the redundant YCKI and YCK2 genes, are located at the plasma membrane. Either alone supports growth, but loss of function of both is lethal. Here, we show that in CK1-deficient cells, the permease is poorly phosphorylated and poorly ubiquitinated. Moreover, CK1 overproduction rescued the defective endocytosis of a mutant permease in which the serine phosphoacceptors were replaced by threonine (a less effective phosphoacceptor), which suggests that Yck activity may play a direct role in phosphorylating the permease. Permease internalization was not greatly affected in CK1-deficient cells, despite the low level of ubiquitination of the protein. This may be due to CK1 having a second counteracting role in endocytosis as shown by the higher turnover of variant permeases with unphosphorylatable versions of the PEST sequence.

Only one of the charged amino acids located in membrane-spanning regions is important for the function of the Saccharomyces cerevisiae uracil permease.

The transport of uracil into the yeast Saccharomyces cerevisiae is mediated by uracil permease, a specific co-transporter encoded by the FUR4 gene. Uracil permease is a multispan membrane protein that is delivered to the plasma membrane via the secretory pathway. Experimental results led to the proposal of a two-dimensional model of the protein's topology. According to this model, the membrane domain of Fur4p contains three charged amino acid residues (Glu-243, Lys-272 and Glu-539) that are conserved in the members of the FUR family of yeast transporters. We have previously shown that a mis-sense mutation leading to the replacement of Lys-272 by Glu severely impairs the function of uracil permease. In the present paper, the role of the three charged residues present in the membrane-spanning regions of Fur4p was further investigated by using site-directed mutagenesis. The variant permeases were correctly targeted to the plasma membrane and their stabilities were similar to that of the wild-type permease. The effect of the mutations was studied by measuring the uptake constants for uracil on whole cells and equilibrium binding parameters on plasma membrane-enriched fractions. We found no evidence for ionic interaction between either of the glutamic residues in transmembrane segments 3 and 9 and the lysine residue in transmembrane segment 4. Of the three charged residues, only Lys-272 was important for the transport activity of the transporter. Its replacement by Ala, Glu or even Arg strongly impaired both the binding and the translocation of uracil.

Cloning by genetic complementation and restriction mapping of the yeast HEM1 gene coding for 5-aminolevulinate synthase.

We have cloned the structural gene HEM1 for 5-aminolevulinate (ALA) synthase from Saccharomyces cerevisiae by transformation and complementation of a yeast hem1-5 mutant which was previously shown to lack ALA synthase activity (Urban-Grimal and Labbe Bois 1981) and had no immunodetectable ALA synthase protein when tested with yeast ALA synthase antiserum. The gene was selected from a recombinant cosmid pool which contained wild-type yeast genomic DNA fragments of an average size of 40 kb. The cloned gene was identified by the restauration.of growth on a non fermentable carbon source without addition of exogenous ALA. Sub cloning of partial Sau3A digests and functional analysis by transformation allowed us to isolate three independent plasmids, each carrying a 6 kb yeast DNA fragment inserted in either orientation into the single BamHI site of the vector pHCG3 and able to complement hem1-5 mutation. Analysis of the three plasmids by restriction endonucleases showed that HEM1 is contained within a 2.9 kb fragment. The three corresponding yeast trans formants present a 1, 2.5 and 16 fold increase in ALA synthase activity as compared to the wild-type strain. The gene product immunodetected in the transformant yeast cells has identical size as the wild-type yeast ALA synthase and its amount correlates well with the increase in ALA synthase activity.

The yeast plasma membrane uracil permease is stabilized against stress induced degradation by a point mutation in a cyclin-like "destruction box".

Yeast uracil permease appears to be fairly stable in exponentially growing cells, but it undergoes rapid endocytosis followed by degradation when cells are submitted to adverse conditions, such as nutrient starvation or inhibition of protein synthesis. Uracil permease has a sequence (RIALGSLTD) that is very similar to the "destruction box" of mitotic cyclins. This box is required for the ubiquitin-dependent proteolysis of cyclins. We replaced the invariant arginine residue of the putative "destruction box" in uracil permease by an alanine. The mutation significantly protected the permease against stress-induced degradation. This result suggests that ligation to ubiquitin could be a signal for uracil permease degradation.

Endocytosis and degradation of the yeast uracil permease under adverse conditions.

Yeast uracil permease follows the secretory pathway to the plasma membrane and is phosphorylated on serine residues in a post-Golgi compartment. The protein was found to be rather stable in growing cells, but its turnover rate (half-life of about 7 h) was much faster than that of most yeast proteins. Several adverse conditions triggered the rapid degradation of uracil permease, and so a loss of uracil uptake. Turnover was rapid when yeast cells were starved of either nitrogen, phosphate, or carbon, and as they approached the stationary growth phase. Rapid permease degradation was also promoted by the inhibition of protein synthesis. The degradation of uracil permease in response to several stresses was strikingly slower in the two mutants, end3 and end4, that are deficient in the internalization step of receptor-mediated endocytosis. Thus, internalization is the first step in the permease degradative pathway. Uracil permease is degraded in the vacuole, since pep4 mutant cells lacking vacuolar protease activities accumulated large amounts of uracil permease, which was located within the vacuole by immunofluorescence. We have yet to determine whether adverse conditions enhance permease endocytosis and subsequent degradation or divert internalized uracil permease from a recycling to a degradative pathway.

The nucleotide sequence of the HEM1 gene and evidence for a precursor form of the mitochondrial 5-aminolevulinate synthase in Saccharomyces cerevisiae.

The biosynthesis of yeast 5-aminolevulinate (ALA) synthase, a mitochondrial protein encoded by the nuclear HEM1 gene, has been studied in vitro in a cell-free translation system and in vivo in whole cells. In vitro translation of mRNA hybrid-selected by the cloned HEM1 gene, or of total RNA followed by immunoprecipitation with anti-(ALA synthase) antibody yielded a single polypeptide of higher molecular mass than the purified ALA synthase. This larger form, also seen in pulse-labeled cells, can be post-translationally processed by isolated mitochondria. These results show that the cytoplasmically made ALA synthase is synthesized with a cleavable extension which was estimated to be about 3.5 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The complete nucleotide sequence of the HEM1 gene and its flanking regions was determined. The 5' ends of the HEM1 mRNAs map from -76 to -63 nucleotides upstream of the translation initiation codon. The open reading frame of 1644 base pairs encodes a protein of 548 amino acids with a calculated Mr of 59,275. The predicted amino-terminal sequence of the protein is strongly basic (five basic and no acidic amino acids within the first 35 residues), rich in serine and threonine and must represent the transient presequence that targets this protein to the mitochondria. Comparison of deduced amino acid sequences indicates a clear homology between the mature yeast and chick embryo liver ALA synthases.

Replacement of Lys by Glu in a transmembrane segment strongly impairs the function of the uracil permease from Saccharomyces cerevisiae.

The co-transport of uracil and protons through the plasma membrane of the yeast Saccharomyces cerevisiae is mediated by a specific permease encoded by the FUR4 gene. The uracil permease is a multi-spanning membrane protein that follows the secretory pathway to the plasma membrane. Recent experimental data led to the proposal of a two-dimensional model of its topology. A spontaneous mutant corresponding to the substitution of Lys-272 by glutamic acid was obtained. The influence of this mutation was studied by comparing the wild-type and mutant permeases produced in a strain carrying a chromosomal deletion of the FUR4 gene. The mutant permease is correctly targeted to the plasma membrane and its stability is similar to that of the wild-type permease. The uptake parameters for the mutant permease were impaired and showed an approximately 65-fold increase of apparent K(m) and a decrease in apparent Vmax. Equilibrium binding measurements with enriched plasma membrane preparations showed an approximately 70-fold increase in apparent Kd in the mutant, whereas its Bmax. was similar to that of the wild type. Lys-272 is fully conserved in the uracil permease family and is predicted to lie in the fourth transmembrane segment of the protein. It seems to be essential for both efficient uracil binding and translocation.

The effects in vivo of mutationally modified uroporphyrinogen decarboxylase in different hem12 mutants of baker's yeast (Saccharomyces cerevisiae).

Nine new hem12 haploid mutants of baker's yeast (Saccharomyces cerevisiae), totally or partially deficient in uroporphyrinogen decarboxylase activity, were subjected to both genetic and biochemical analysis. The mutations sites studied are situated far apart within the HEM12 gene located on chromosome IV. Uroporphyrinogen decarboxylase activity in the cell-free extracts of the mutants was decreased by 50-100%. This correlated well with the decrease of haem formation and the increased accumulation and excretion of porphyrins observed in vivo. The pattern of porphyrins (uroporphyrin and its decarboxylation products) accumulated in the cells of mutants partially deficient in uroporphyrinogen decarboxylase activity did not differ significantly, although differences in vitro were found in the relative activity of the mutant enzyme at the four decarboxylation steps. The excreted porphyrins comprised mainly dehydroisocoproporphyrin or pentacarboxyporphyrin. In heterozygous hem12-1/HEM12 diploid cells, a 50% decrease in decarboxylase activity led to an increased accumulation of porphyrins as compared with the wild-type HEM12/HEM12 diploid, which points to the semi-dominant character of the hem12-1 mutation. The biochemical phenotypes of both the haploid and the heterozygous diploid resembles closely the situation encountered in porphyria cutanea tarda, the most common human form of porphyria.