Effect of mutation of cysteinyl residues in yeast Cu-metallothionein

Metallothioneins have been isolated from Saccharomyces cerevisiae CUP1 mutants generated by Wright et al. (Wright, C. F., Hamer, D. H., and McKenney, K. (1986) Nucleic Acids Res. 14, 8489-8499). In the mutant metallothioneins, pairs of cysteinyl residues have been converted to seryl residues. The mutant proteins differ only in the positions of the double substitutions; each mutant molecule contains 10 cysteinyl residues. Each mutant protein lacks the first 8 residues at the amino terminus from the decoded gene sequence of the CUP1 locus. Mutant molecules consist of 53 residues analogous to the wild-type metallothionein and are designated 9/11, 24/26, 36/38, and 49/50 (in reference to the sequence positions of the Cys----Ser conversions). The properties of the mutant metallothioneins are vastly different, and host cells harboring the different plasmid-encoded mutant molecules show marked differences in sensitivity to CuSO4. Growth inhibition was observed at CuSO4 concentrations up to mM in cells containing the 9/11, 24/26, and 36/38 molecules, but not for cells containing protein 49/50. A CuSO4 concentration of 5 mM was required to inhibit the growth of yeast containing either 49/50 or the wild-type metallothionein. In the purified proteins the copper binding stoichiometry of each molecule, except protein 24/26, was nearly 8 mol eq. Protein 24/26 bound 5.5 copper ions/molecule. The Cu(I) chelator bathocuproine disulfonate reacted with over 50% of the copper ions in proteins 9/11, 24/26, and 36/38, but less than 10% of the copper ions in proteins 49/50 and wild-type metallothionein were reactive. The thiolates in 9/11, 24/26, and 36/38 were also more reactive in a disulfide exchange reaction with dithiodipyridine compared with the sulfhydryls in 49/50 and the wild-type molecules. The four mutant copper proteins are luminescent and exhibit a similar quantum yield. The cluster structures contributing to the particular electronic transitions are markedly more sensitive to oxygen in proteins 9/11, 24/26, and 36/38 compared with 49/50 and the wild-type molecules. The air-sensitive proteins exhibit a tertiary fold not recognized by polyclonal antibodies directed to a conformational epitope on yeast Cu-metallothionein. Protein 49/50 cross-reacts with the antibody in a concentration-dependent fashion similar to the wild-type protein. Mutation of 2 cysteinyl residues in the carboxyl portion of metallothionein does not significantly alter properties of the molecule, whereas mutation of several cysteines in the amino-terminal portion of the molecule yields a different conformation.     

Yeast metallothionein. Sequence and metal-binding properties

The protein product of the CUP1 locus in Cu-resistant Saccharomyces cerevisiae has been purified and characterized. The protein was found to lack the first 8 amino acids predicted by the nucleotide sequence of the gene. The residues removed from the amino-terminal region include 5 hydrophobic residues, two of which are aromatic. The unique amino terminus starting at Gln9 of the putative DNA translation product was observed for metallothionein purified in the presence of various protease inhibitors or from a pep4 mutant yeast strain deficient in vacuolar proteases. The remainder of the primary structure of the protein is equivalent to the decoded DNA sequence, so yeast metallothionein is a 53-residue polypeptide of molecular weight 5655. The isolated protein contained 8 copper ions ligated by 12 cysteines/molecule. Reconstitution studies of the apo-molecule revealed that 8 mol eq of Cu(I) conferred maximal stability against proteolysis and depleted the zinc content of zinc-saturated metallothionein. These assays suggested that the protein has 8 binding sites for Cu(I). Ag(I) ions bound to the protein with the same stoichiometry. Yeast metallothionein was also observed to coordinate Cd(II) and Zn(II) ions in vitro. In studies of direct binding, protection against proteolysis, and metal ion exchange, these divalent ions were found to associate with the protein with a maximal stoichiometry of 4 ions/molecule. Yeast metallothionein thus exhibits two distinct binding configurations for Cu(I) and Cd(II) as does the mammalian protein.     

Defective Escherichia coli signal peptides function in yeast

To investigate structural characteristics important for eukaryotic signal peptide function in vivo, a hybrid gene with interchangeable signal peptides was cloned into yeast. The hybrid gene encoded nine residues from the amino terminus of the major Escherichia coli lipoprotein, attached to the amino terminus of the entire mature E. coli beta-lactamase sequence. To this sequence were attached sequences encoding the nonmutant E. coli lipoprotein signal peptide, or lipoprotein signal peptide mutants lacking an amino-terminal cationic charge, with shortened hydrophobic core, with altered potential helicity, or with an altered signal-peptide cleavage site. These signal-peptide mutants exhibited altered processing and secretion in E. coli. Using the GAL10 promoter, production of all hybrid proteins was induced to constitute 4-5% of the total yeast protein. Hybrid proteins with mutant signal peptides that show altered processing and secretion in E. coli, were processed and translocated to a similar degree as the non-mutant hybrid protein in yeast (approximately 36% of the total hybrid protein). Both non-mutant and mutant signal peptides appeared to be removed at the same unique site between cysteine 21 and serine 22, one residue from the E. coli signal peptidase II processing site. The mature lipo-beta-lactamase was translocated across the cytoplasmic membrane into the yeast periplasm. Thus the protein secretion apparatus in yeast recognizes the lipoprotein signal sequence in vivo but displays a specificity towards altered signal sequences which differs from that of E. coli.     

The CUP2 gene product regulates the expression of the CUP1 gene, coding for yeast metallothionein.

The yeast CUP1 gene codes for a copper-binding protein similar to metallothionein. Copper sensitive cup1s strains contain a single copy of the CUP1 locus. Resistant strains (CUP1r) carry 12 or more multiple tandem copies. We isolated 12 ethyl methane sulfonate-induced copper sensitive mutants in a wild-type CUP1r parental strain, X2180-1A. Most mutants reduce the copper resistance phenotype only slightly. However, the mutant cup2 lowers resistance by nearly two orders of magnitude. We cloned CUP2 by molecular complementation. The smallest subcloned fragment conferring function was approximately 2.1 kb. We show that CUP2, which is on chromosome VII, codes for or controls the synthesis or activity of a protein which binds the upstream control region of the CUP1 gene on chromosome VIII. Mutant cup2 cells produced extremely low levels of CUP1-specific mRNA, with or without added copper ions and lacked a factor which binds to the CUP1 promoter. Integrated at the cup2 site, the CUP2 plasmid restored the basal level and inducibility of CUP1 expression and led to reappearance of the CUP1-promoter binding factor. Taken collectively, our data establish CUP2 as a regulatory gene for expression of the CUP1 metallothionein gene product.     

Yeast metallothionein function in metal ion detoxification

A genetic approach was taken to test the function of yeast metallothionein in metal ion detoxification. A yeast strain was constructed in which the metallothionein locus was deleted (cup1 delta). The cup1 delta strain was complemented with normal or mutant metallothionein genes under normal or constitutive regulatory control on high copy episomal plasmids. Metal resistance of the cup1 delta strain with and without the metallothionein-expressing vectors was analyzed. The normally regulated metallothionein gene conferred resistance only to copper (1000-fold); constitutively expressed metallothionein conferred resistance to both copper (500-fold) and cadmium (1000-fold), but not to mercury, zinc, silver, cobalt, nickel, gold, platinum, lanthanum, uranium, or tin. Two mutant versions of the metallothionein gene were constructed and tested for their ability to confer metal resistance in the cup1 delta background. The first had a deletion of a highly conserved amino acid sequence (Lys-Lys-Ser-Cys-Cys-Ser). The second was a hybrid gene consisting of the sequences coding for the first 20 amino acids of the yeast protein fused to the monkey metallothionein gene. Expression of these genes under the CUP1 promoter provided significant protection from copper, but none of the other metals tested. These results demonstrate that there is significant flexibility in the structural requirements for metallothionein to function in copper detoxification and that yeast metallothionein is also capable of detoxifying cadmium under conditions of constitutive expression.     

Mutational Analysis of Pre-mRNA Splicing in Saccharomyces Cerevisiae Using a Sensitive New Reporter Gene, Cup1

We have developed a new reporter gene fusion to monitor mRNA splicing in yeast. An intron-containing fragment from the Saccharomyces cerevisiae ACT1 gene has been fused to CUP1, the yeast metallothionein homolog. CUP1 is a nonessential gene that allows cells to grow in the presence of copper in a dosage-dependent manner. By inserting previously characterized intron mutations into the fusion construct, we have established that the efficiency of splicing correlates with the level of copper resistance of these strains. A highly sensitive assay for 5' splice site usage was designed by engineering an ACT1-CUP1 construct with duplicated 5' splice sites; mutations were introduced into the upstream splice site in order to evaluate the roles of these highly conserved nucleotides in intron recognition. Almost all mutations in the intron portion of the 5' consensus sequence abolish recognition of the mutated site, while mutations in the exon portion of the consensus sequence have variable affects on cleavage at the mutated site. Interestingly, mutations at intron position 4 demonstrate that this nucleotide plays a role in 5' splice site recognition other than by base pairing with U1 snRNA. The use of CUP1 as a reporter gene may be generally applicable for monitoring cellular processes in yeast.     

Regulation of the yeast metallothionein gene

To study regulation of the yeast CUP1 gene, we have employed plasmids containing the CUP1 regulatory sequences fused to the Escherichia coli galK gene. A comparison of galK expression from low- and high-copy-number CUP1/galK fusion plasmids demonstrated that both basal and induced levels of galactokinase (GalK) increase proportionately with plasmid copy number. Host strains with an amplified, single or deleted CUP1 locus were compared to look for effects of chromosomal CUP1 gene dosage on expression from the episomal CUP1 promoter. Basal GalK levels are similar in CUP1R and cupls hosts, but can be induced to higher levels in the cup1s than the CUP1R host. In contrast, in a strain deleted for the chromosomal copy of CUP1, synthesis of GalK is constitutive but can be induced to yet higher levels by copper. A hybrid vector, placing the CUP1 coding sequence under the control of a constitutive promoter, was constructed. Introduction of this hybrid CUP1 gene into the deletion host containing the CUP1/galK plasmid restores regulation. Thus, metallothionein, in trans, can effect repression of the CUP1 promoter. The possible roles of metallothionein and free copper in CUP1 regulation are discussed.     

Versatile cassettes designed for the copper inducible expression of proteins in yeast

A series of yeast expression vectors and cassettes utilizing the CUP1 gene of Saccharomyces cerevisiae have been constructed. The cassettes contain multiple cloning sites for gene fusions and were created by inserting a 27-bp polylinker at the +14 position of the CUP1 gene. The cassettes are portable as restriction fragments and enable copper-regulated expression of foreign proteins in S. cerevisiae. In copper sensitive yeast, multiple copies of the CUP1 cassettes confer copper resistance due to the production of the copper metallothionein. Genes cloned into the CUP1 cassettes, however, usually prevent translation of the metallothionein leading to a loss of resistance. This could be useful for one-step cloning into yeast.     

The polyanion-binding domain of cytoplasmic Lys-tRNA synthetase from Saccharomyces cerevisiae is not essential for cell viability.

Cytoplasmic Lys-tRNA synthetase (LysRS) from Saccharomyces cerevisiae is a dimeric enzyme made up of identical subunits of 68 kDa. By limited proteolysis, this enzyme can be converted to a truncated dimer without loss of activity. Whereas the native enzyme strongly interacts with polyanionic carriers, the modified form displays reduced binding properties. KRS1 is the structural gene for yeast cytoplasmic LysRS. It encodes a polypeptide with an amino-terminal extension composed of about 60-70 amino acid residues, compared to its prokaryotic counterpart. This segment, containing 13 lysine residues, is removed upon proteolytic treatment of the native enzyme. The aim of the present study was to probe in vivo the significance of this amino-terminal extension. We have constructed derivatives of the KRS1 gene, encoding enzymes lacking 58 or 69 amino-terminal residues and, by site-directed mutagenesis, we have changed four or eight lysine residues from the amino-terminal segment of LysRS into glutamic acids. Engineered proteins were expressed in vivo after replacement of the wild-type KRS1 allele. The mutant enzymes displayed reduced specific activities (2-100-fold). A series of carboxy-terminal deletions, encompassing 3, 10 or 15 amino acids, were introduced into the LysRS mutants with modified amino-terminal extensions. The removal of three residues led to a 2-7-fold increase in the specific activity of the mutant enzymes. This partial compensatory effect suggests that interactions between the two extreme regions of yeast LysRS are required for a proper conformation of the native enzyme. All KRS1 derivatives were able to sustain growth of yeast cells, although the mutant cell lines displaying a low LysRS activity grew more slowly. The expression, as single-copy genes, of mutant enzymes with a complete deletion of the amino-terminal extension or with four Lys----Glu mutations, that displayed specific activities close to that of the wild-type LysRS, had no discernable effect on cell growth. We conclude that the polycationic extensions of eukaryotic aminoacyl-tRNA synthetases are dispensable, in vivo, for aminoacylation activities. The results are discussed in relation to the triggering role in in situ compartmentalization of protein synthesis that has been ascribed to the polypeptide-chain extensions that characterize most, if not all, eukaryotic aminoacyl-tRNA synthetases.     

Isolation of the structural gene encoding a mutant form of Escherichia coli phosphoenolpyruvate carboxylase deficient in regulation by fructose 1,6-bisphosphate. Identification of an amino acid substitution in the mutant

The structural gene encoding a mutant Escherichia coli phosphoenolpyruvate carboxylase deficient in regulation by fructose 1,6-bisphosphate (Fru-P2) was isolated from total E. coli PpcI genomic DNA. This mutant gene is located on a 4.4-kilobase SalI DNA fragment which, when ligated to SalI-digested pBR322, resulted in the generation of the plasmid pFS16. Detailed restriction mapping of the wild-type and mutant genes for phosphoenolpyruvate carboxylase revealed the presence of a ClaI restriction site at position 563 of the mutant gene only. This ClaI site is located on a 289 PvuII/DdeI fragment which codes for amino acid residues 174-270 of the phosphoenolpyruvate carboxylase enzyme. When this portion of the mutant gene is present in chimeras of the wild-type and mutant genes, the phosphoenolpyruvate carboxylase produced cannot be activated by Fru-P2. The mutation resulting in the generation of the ClaI site in the mutant gene has also resulted in an amino acid substitution at residue 188; threonine in the wild-type enzyme has been replaced by isoleucine in the mutant enzyme. Comparison of the nucleotide sequence of this 289-base pair PvuII/DdeI region of the mutant gene with its homologous region in the wild-type gene verified that this mutation, which resulted in the generation of the ClaI site, is the only change that has occurred on this 289-base pair fragment of the mutant gene, and thus the amino acid replacement of threonine by isoleucine is the only change that could be linked to the inability of the mutant enzyme to be activated by Fru-P2.     

Biosynthesis and posttranslational processing of site-directed endoproteolytic cleavage mutants of pro-neuropeptide Y in mouse pituitary cells

Although pairs of basic amino acids are common endoproteolytic sites in prohormones, the enzymes responsible for these cleavages have not yet been characterized. To investigate the specificity of these endoproteases, cDNAs encoding pro-neuropeptide Y (pro-NPY) containing all four pairs of basic amino acids were expressed in AtT-20 cells. Pro-NPY was selected as a model substrate because it undergoes a single cleavage at the sequence -Lys-Arg- during posttranslational processing. AtT-20 cells, a mouse anterior pituitary corticotrope line, were selected because they synthesize pro-adrenocorticotropic hormone (pro-ACTH)/endorphin and cleave a well characterized subset of the eight pairs of basic amino acids in the precursor. Altered cDNAs encoding pro-NPY with -Arg-Arg-, -Arg-Lys-, or Lys-Lys- at the cleavage site were used to generate stable cell lines. The production of NPY and the carboxyl-terminal peptide was studied using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gel filtration, reversed-phase high performance liquid chromatography, ion-exchange high performance liquid chromatography, tryptic peptide mapping, and microsequencing. Direct amino acid labeling confirmed the identity of the pair of basic amino acids at the cleavage site. Even when the four pairs of basic amino acids were presented in the same structural context, the rate, extent, and type of cleavage was substrate-specific. Pro-NPY(-Arg-Arg-) was cleaved at a rate similar to that observed for the wild-type pro-NPY(-Lys-Arg-). In contrast, pro-NPY(-Arg-Lys-) was cleaved at a much lower rate, and pro-NPY (-Lys-Lys-) was cleaved very poorly. Following endoproteolytic cleavage, the pair of basic amino acids present did not alter the production of mature NPY with a COOH-terminal Tyr-NH2. While two of the three mutant pro-NPY molecules were processed to wild-type carboxyl-terminal peptide, the carboxyl-terminal peptide derived from pro-NPY(-Arg-Lys-) contained an amino-terminal lysine residue, indicating that biosynthetic endoproteolysis occurred in the middle or at the amino terminus of the pair of basic amino acid residues at the cleavage site. Expression of wild-type or mutant pro-NPY inhibited cleavages within the endogenous pro-ACTH/endorphin; poorly cleaved pro-NPY mutants (Lys in the second position of the cleavage site) were the most potent inhibitors of pro-ACTH/endorphin cleavage.     

Subunit IV of yeast cytochrome c oxidase: cloning and nucleotide sequencing of the gene and partial amino acid sequencing of the mature protein.

The six small subunits (IV-VII, VIIa, VIII) of yeast cytochrome c oxidase are encoded by nuclear genes and imported into the mitochondria. We have isolated the gene for subunit IV from a yeast genomic clone bank and determined its complete nucleotide sequence. We have also isolated subunit IV from purified yeast cytochrome c oxidase and determined most of its amino acid sequence which confirms the positioning of approximately 90% of the amino acid residues. The sequence comparison shows that the coding sequence of the gene lacks introns and that subunit IV is made as a precursor with an amino-terminal extension of 25 residues, five of which are basic and none of them acidic. Precursor processing involves cleavage of a Leu-Gln bond.