Distinct cis-acting signals enhance 3' endpoint formation of CYC1 mRNA in the yeast Saccharomyces cerevisiae.

The cyc1-512 mutant of the yeast Saccharomyces cerevisiae contains a 38 bp deletion in the 3' untranslated region of the CYC1 gene, resulting in CYC1 mRNAs that are elongated, presumably labile, and reduced to 10% of the normal level. Analysis with S1 nuclease and a novel PCR procedure revealed that the low amount of cyc1-512 mRNA contained many discrete 3' termini at certain sites, ranging from the wild-type position to over 2000 nucleotides (nt) downstream. The cyc1-512 mRNA deficiency was completely or almost completely restored in eight intragenic revertants that contained six different single and multiple base-pair changes within a 300 bp region downstream from the translation terminator codon. Two of the six different reversions formed the sequence TAG...TATGTA, whereas the other four reversions created the sequences TATATA or TACATA. The positions of these revertant sequences varied, even though they caused an increased use of specific major downstream mRNA 3' endpoints, apparently identical to those seen in the cyc1-512 mRNA. However, several revertants contained minor end points not corresponding to any of the cyc1-512 mRNAs. The capacity of these three signals to form 3' ends was confirmed with sequences constructed by site-directed mutagenesis. We therefore suggest that the production of 3' termini of yeast mRNA may involve at least two functionally distinct elements working in concert. One type of element determines the sites of preferred 3' mRNA termini, as represented by the cyc1-512 termini. The second type of element, which includes TAG...TATGTA and TATATA motifs, operates at a distance to enhance the use of the downstream 3' preferred sites.(ABSTRACT TRUNCATED AT 250 WORDS)

Multiple base-pair mutations in yeast.

The nucleotide changes associated with both forward and reverse mutations at the CYC1 locus in the yeast Saccharomyces cerevisiae have been investigated by sequencing the mutated gene product, iso-1-cytochrome c and, more directly, by sequencing appropriate DNA segments. Although the majority of these mutations are the result of single base-pair changes, approximately 10% are the result of multiple mutations and these occur predominantly at certain sites and with certain patterns. Most multiple base-pair changes occur within 20 nucleotides of each other and are generally within six nucleotides. On the basis of the frequencies and patterns of mutations, these nucleotide changes are considered to have occurred as single, concerted events, rather than as multiple independent mutations. Analysis of these mutations indicates that multiple base-pair changes can arise by widely differing mechanisms. We have recognized the following classes of mutations: multiple base-pair changes that yield (1) direct repeats or (2) inverted repeats of local DNA sequences; (3) substitutions of two tandem base-pairs; (4) frameshift and contiguous single base-pair substitutions; and (5) recombination of the CYC1 gene with a non-allelic gene, resulting in alterations within contiguous segments that can be over 150 nucleotides in length. Some of the multiple base-pair changes do not fall into any of these categories. We suggest mechanisms to account for each of these five classes.

Differential mismatch repair can explain the disproportionalities between physical distances and recombination frequencies of cyc1 mutations in yeast.

Recombination rates have been examined in two-point crosses of various defined cyc1 mutations that cause the loss or nonfunction of iso-1-cytochrome c in the yeast Saccharomyces cerevisiae. Recombinants arising by three different means were investigated, including X-ray induced mitotic recombination, spontaneous mitotic recombination, and meiotic recombination. Heteroallelic diploid strains were derived by crossing cyc1 mutants containing a series of alterations at or near the same site to cyc1 mutants containing alterations at various distances. Marked disproportionalities between physical distances and recombination frequencies were observed with certain cyc1 mutations, indicating that certain mismatched bases can significantly affect recombination. The marker effects were more pronounced when the two mutational sites of the heteroalleles were within about 20 base pairs, but separated by at least 4 base pairs. Two alleles, cyc1-163 and cyc1-166, which arose by G.C----C.G transversions at nucleotide positions 3 and 194, respectively, gave rise to especially high rates of recombination. Other mutations having different substitutions at the same nucleotide positions were not associated with abnormally high recombination frequencies. We suggest that these marker effects are due to the lack of repair of either G/G or C/C mismatched base pairs, while the other mismatched base pair of the heteroallele undergoes substantial repair. Furthermore, we suggest that diminished recombination frequencies are due to the concomitant repair of both mismatches within the same DNA tract.

Yeast iso-1-cytochrome c: genetic analysis of structural requirements.

We describe the use of classical and molecular genetic techniques to investigate the folding, stability, and enzymatic requirements of iso-1-cytochrome c from the yeast Saccharomyces cerevisiae. Interpretation of the defects associated with an extensive series of altered forms of iso-1-cytochrome c was facilitated by the recently resolved three dimensional structure of iso-1-cytochrome c [(1987) J. Mol. Biol. 199, 295-314], and by comparison with the phylogenetic series of eukaryotic cytochromes c. Residue replacements that abolish iso-1-cytochrome c function appear to do so by affecting either heme attachment or protein stability; no replacements that abolish electron transfer function without affecting protein structure were uncovered. Most nonfunctional forms retained at least partial covalent attachment to the heme moiety; heme attachment was abolished only by replacements of Cys19 and Cys22, which are required for thioether linkage, and His23, a heme ligand. Replacements were uncovered that retain function at varying levels, including replacements at evolutionarily conserved positions, some of which were structurally and functionally indistinguishable from wild type iso-1-cytochrome c.

Identification and sequence of the gene encoding cytochrome c heme lyase in the yeast Saccharomyces cerevisiae.

Mitochondrial cytochrome c contains a heme group covalently attached through thioether linkages to two cysteinyl residues of the protein. We demonstrate here that the nuclear gene, CYC3, in the yeast Saccharomyces cerevisiae, encodes cytochrome c heme lyase (CCHL), the enzyme catalyzing the attachment of heme to apocytochrome c. Mitochondrial extracts from cyc3- mutants are deficient in CCHL activity compared with extracts from normal strains, whereas strains carrying multiple copies of the CYC3 gene exhibit high levels of the activity. The CYC3 gene was cloned by functional complementation of a cyc3- mutant using a previously isolated plasmid containing the gene PYK1, which is tightly linked to CYC3. An open reading frame encoding a protein of 269 amino acids was identified from the DNA sequence of a fragment encompassing the CYC3 gene, and the corresponding transcript shown to be approximately 0.9 kb in length. CCHL appears to be a single polypeptide chain which acts specifically on the two forms of cytochrome c, but not on cytochrome c1.

Highly mutable sites for ICR-170-induced frameshift mutations are associated with potential DNA hairpin structures: studies with SUP4 and other Saccharomyces cerevisiae genes.

The majority of the mutations induced by ICR-170 in both the CYC1 gene (J. F. Ernst et al. Genetics 111:233-241, 1985) and the HIS4 gene (L. Mathison and M. R. Culbertson, Mol. Cell. Biol. 5:2247-2256, 1985) of the yeast Saccharomyces cerevisiae were recently shown to be single G . C base-pair insertions at monotonous runs of two or more G . C base pairs. However, not all sites were equally mutable; in both the CYC1 and HIS4 genes there is a single highly mutable site where a G . C base pair is preferentially inserted at a [sequence in text]. Here we report the ICR-170 mutagen specificity at the SUP4-o tyrosine tRNA gene of yeast. Genetic fine structure analysis and representative DNA sequence determination of ICR-170-induced mutations revealed that there is also a single highly mutable site in SUP4-o and that the mutation is a G . C base-pair insertion at a monotonous run of G . C base pairs. Analysis of DNA sequences encompassing the regions of highly mutable sites for all three genes indicated that the mutable sites are at the bases of potential hairpin structures; this type of structure could not be found at any of the other, less mutable G . C runs in SUP4, CYC1, and HIS4. Based on these results and recent information regarding novel DNA structural conformations, we present a mechanism for ICR-170-induced mutagenesis. (i) ICR-170 preferentially binds to DNA in the beta conformation; factors that increase the temporal stability of this structure, such as adjacent stem-and-loop formation, increase the frequency of ICR-170 binding; (ii) the observed mutagen specificity reflects formation of a preferred ICR-170 intercalative geometry at [sequence in text] sites; (iii) during replication or repair, ICR-170 remains associated with the single-stranded template; (iv) stuttering or strand slippage by the polymerization complex as it encounters the mutagen results in nucleotide duplication; (v) subsequent replication or mismatch repair fixes the insertion into the genome. This mechanism accounts for both the IRC-170 mutagenic specificity and the molecular basis of the highly mutable sites in S. cerevisiae.

Amino acid replacements in yeast iso-1-cytochrome c. Comparison with the phylogenetic series and the tertiary structure of related cytochromes c.

The structural and folding requirements of eukaryotic cytochromes c have been investigated by determining the appropriate DNA sequences of a collection of 46 independent cyc 1 missense mutations obtained in the yeast Saccharomyces cerevisiae and by deducing the corresponding amino acid replacements that abolish function of iso-1-cytochrome c. A total of 33 different replacements at 19 amino acid positions were uncovered in this and previous studies. Because all of these nonfunctional iso-1-cytochromes c are produced at far below the normal level and because a representative number are labile in vitro, most of the replacements appear to be affecting stability of the protein or heme attachment. By considering the tertiary structure of related cytochromes c, the loss of function of most of the mutant iso-1-cytochromes c could be attributed to either replacements of critical residues that directly interact with the heme group or to replacements that disrupt the proper folding of the protein. The replacements of residues interacting with the heme group include those required for covalent attachment (Cys-19 and Cys-22), ligand formation (His-23 and Met-85), and formation of the immediate heme environment (Leu-37, Tyr-53, Trp-64, and Leu-73). Proper folding of the protein is prevented by replacements of glycine residues at sites that cannot accommodate side chains (Gly-11 and Gly-34); by replacements of residues with proline, which limit the torsion angle (Leu-14 and His-38); and by replacements apparently unable to direct the local folding of the backbone into the proper conformation (Pro-35, Tyr-72, Asn-75, Pro-76, Lys-84, Leu-99, and Leu-103). Even though most of the missense mutations occurred at sites corresponding to evolutionarily invariant or conserved residues, a consideration of the replacements in functional revertants indicates that the requirement for residues evolutionarily preserved is less stringent than commonly assumed.

DNA sequences of frameshift and other mutations induced by ICR-170 in yeast.

ICR-170-induced mutations in the CYC1 gene of the yeast Saccharomyces cerevisiae were investigated by genetic and DNA sequence analyses. Genetic analysis of 33 cyc1 mutations induced by ICR-170 and sequence analysis of eight representatives demonstrated that over one-third were frameshift mutations that occurred at one site corresponding to amino acid positions 29-30, whereas the remaining mutations were distributed more-or-less randomly, and a few of these were not frameshift mutations. The sequence results indicate that ICR-170 primarily induces G.C additions at sites containing monotonous runs of three G.C base pairs. However, some (Formula: see text) sites within the CYC1 gene were not mutated by ICR-170. Thus, ICR-170 is a relatively specific mutagen that preferentially acts on certain sites with monotonous runs of G.C base pairs.

Substitutions of proline 76 in yeast iso-1-cytochrome c. Analysis of residues compatible and incompatible with folding requirements.

Fine-structure genetic mapping previously revealed numerous nonfunctional cyc1 mutations having alterations at or near the site corresponding to amino acid position 76 of iso-1-cytochrome c from the yeast Saccharomyces cerevisiae. DNA sequencing of the alterations in four of these cyc1 mutations indicated that the normal Pro-76 was replaced by Leu-76. Revertants containing at least partially functional iso-1-cytochromes c were isolated, and the alterations were analyzed by DNA sequencing and protein analysis. Specific activities of the altered iso-1-cytochromes c were estimated in vivo by growth of the strains in lactate medium; compared to normal iso-1-cytochrome c with Pro-76, the following activities were associated with the following replacements: approximately 90% for Val-76, approximately 60% for Thr-76, approximately 30% for Ser-76, approximately 20% for Ile-76, and 0% for Leu-76. In order to develop an understanding of the factors that determine whether or not an altered iso-1-cytochrome c will function, we undertook a theoretical analysis which led to the conclusion that the activity of the proteins was dependent on both short- and long-range interactions. Short-range interactions were estimated from studies on known protein structures which gave the likelihood that various amino acids would be found in a local backbone configuration similar to the native protein; long-range interactions with the rest of the molecule were analyzed by considering the size of the side chain. We believe this approach can be used to analyze a wide variety of mutant proteins.

Submitochondrial localization, cell-free synthesis, and mitochondrial import of 2-isopropylmalate synthase of yeast.

2-Isopropylmalate synthase (EC 4.1.3.12) of yeast is a mitochondrial enzyme. We now provide evidence showing that a large part of the 2-isopropylmalate synthase activity that is associated with the mitochondria is located in the mitochondrial matrix. In vitro translation of total yeast RNA followed by immunoprecipitation with anti-2-isopropylmalate synthase antibody yields two polypeptides. The larger of these has an apparent molecular weight identical to that of purified 2-isopropylmalate synthase subunit (ca. 65,000). It is incorporated into isolated yeast mitochondria with no detectable change in molecular weight. The import requires energy. The smaller polypeptide migrates to a position corresponding to a molecular weight of 63,000-64,000. It is not taken up by mitochondria. Both polypeptides, which also can be obtained by immunoprecipitation of crude extracts, become labeled when in vitro translation is performed in the presence of N-formyl[35S]methionyl-tRNAf. Mutants with no detectable 2-isopropylmalate synthase activity are deficient in either one or both synthase-related polypeptides. These results are discussed in the light of recent evidence for two 2-isopropylmalate synthase-encoding genes in yeast.

Inactivation of yeast alpha-isopropylmalate synthase by CoA. Antagonism between CoA and adenylates and the mechanism of CoA inactivation.

Yeast alpha-isopropylmalate synthase (EC 4.1.3.12) is inactivated by micromolar concentrations of CoA in the presence of Zn2+. We report here that rapid reactivation of inactivated enzyme (full recovery in less than 10 min) occurred in the presence of millimolar concentrations of ATP or ADP, using permeabilized cells. With purified, CoA-inactivated enzyme, ATP had only a weak reactivating effect which increased drastically, however, when a chelator was added at a concentration (0.1 mM) which by itself had little effect. Higher concentrations of chelator (1 mM) caused rapid reactivation even in the absence of ATP. Reactivation was also possible by removing CoA from equilibrium with oxidized glutathione, with acetyl phosphate in the presence of phosphotransacetylase, or by dialysis; however, these processes were very slow. Protection against CoA inactivation of alpha-isopropylmalate synthase was provided by high concentrations of ATP and, to a much lesser extent, ADP, by a high adenylate energy charge, by chelators, and by 3'-dephospho-CoA. Enzyme which had been inactivated with [3H]CoA did not retain any radioactivity (above control) when extracted with phenol. This result, together with other observations, is interpreted to mean that inactivation does not involve covalent modification, but is more likely the result of the formation of an enzyme.CoA.zinc complex held together by noncovalent forces. The physiological significance of the CoA effect is discussed.