Amino acid replacements of the evolutionarily invariant tryptophan at position 64 in mutant forms of iso-1-cytochrome c from Saccharomyces cerevisiae

Tryptophan located at position 59 in vertebrate cytochromes c and at position 64 in yeast iso-1-cytochrome c is an evolutionarily invariant residue that is believed to be essential to the operation of the cytochrome c molecule. We show that this residue is replaced in at least partially functional iso-1-cytochromes c from cyc1 revertants of the yeast Saccharomyces cerevisiae. Tryptophan, tyrosine and leucine are found at position 64 in the revertants from the cyc1-84 mutant, confirming the genetic evidence (Sherman et al., 1974) that the mutant contains an UAG nonsense codon and establishing that the site of the mutation corresponds to the normal tryptophan 64. In a revertant from the cyc1.189 mutant, position 64 is occupied by a residue of phenylalanine. All three altered proteins are unstable, implying that tryptophan 64 has an essential and unique role for maintaining the normal structure of the cytochrome c molecule. In addition the iso-1-cytochrome c with leucine 64 and tyrosine 64 have greatly reduced biological activities, while iso-1-cytochrome c with the phenylalanine replacement has at least 20% of the wild-type activity or more. It remains uncertain whether the reduced specific activities are due to distorted tertiary structures or due to the specific lack of the tryptophan residue that may also have a direct functional role.     

Tyrosine substitutions resulting from suppression of amber mutants of iso-1-cytochrome c in yeast

The suppressors SUP6-2 and SUP7-2 can cause the production of approxi- mately 25 to 60% of the normal amount of iso-1-cytochrome c when they are coupled to the amber (UAG) mutants cy1–179 and cy1–76. The iso-1-cytochromes c contain residues of tyrosine at the positions which correspond to the sites of the amber codons. SUP6-2 and SUP7-2 do not suppress ochre (UAA) mutants. The SUP6-2 and the SUP7-2 genes are apparently alleles of the SUP6-1 and SUP7-1 genes, respectively, which cause the insertion of tyrosine at ochre (UAA) codons (ochre-specific suppressors). It is suggested that the gene products of the allelic amber suppressors and ochre-specific suppressors (the SUP6-1 and SUP6-2 suppressors and theSUP7-1 andSUP7-2 suppressors) are two differently altered forms of the same tyrosine tRNA.     

Variation of Mutagenic Action on Nonsense Mutants at Different Sites in the Iso-1-Cytochrome c Gene of Yeast

Three ochre and two amber mutants in yeast have been definitively identified by the amino acid replacements in iso-1-cytochromes c from intragenic revertants. Except for rare and sometimes unusual changes, all of the replacements were single amino acids whose codons differed from UAA or UAG by one base. These assignments, which were based on the absence of tryptophan replacements in ochre revertants, could be corroborated from the studies of two groups of suppressors that were shown to act on either the ochre or amber mutants. All five nonsense mutants are located at different sites in the cyc1 gene and all are at sites that can be occupied by amino acids having a wide range of structures. The relative frequencies of the amino acid replacements indicate that identical codons located at different sites may respond differently to a mutagenic agent. Notably glutamine replacements occurred almost exclusively in UV-induced revertants of only one ochre mutant cyc1–9, but not at all or at reduced proportions in the others. Similarly, lysine replacements occurred almost exclusively in the NA-induced revertants of only the ochre mutant cyc1–72, but not at all in the others. These and other results reveal that mutation of A·T base pairs by UV and nitrous acid are dependent upon the location of the codon within the gene as well as the location of the base pair within the codon. From these findings, it appears as if the type of base-pair changes induced by UV and nitrous acid are strongly influenced by adjacent nucleotide sequences.     

Structural gene for yeast iso-2-cytochrome c.

Protein analysis and genetic studies have led to the identification of the structural genes of iso-1-cytochrome c and iso-2-cytochrome c, which constitute, respectively, 95% and 5% of the total amount of cytochrome c in the yeast Saccharomyces cerevisiae. The structural gene CYC1 for iso-1-cytochrome c was previously identified by Sherman et al. (1966) and the structural gene CYC7 for iso-2-cytochrome c is identified in this investigation. A series of the following mutations were selected by appropriate procedures and shown by genetic tests to be allelic: CYC7+ →CYC7-1 →cyc7-1-1 →CYC7-1-1-A, etc., where CYC7 + denotes the wild-type allele determining iso-2-cytochrome c; CYC7-1 denotes a dominant mutant allele causing an approximately 30-fold increase of iso-2-cytochrome c with a normal sequence, and was used as an aid in selecting deficient mutants; cyc7-1-1 denotes a recessive mutant allele causing complete deficiency of iso-2-cytochrome c; and CYC7-1-1-A denotes an intragenic revertant having an altered iso-2-cytochrome c at the same level as iso-2-cytochrome c in the CYC7-1 strains. The suppression of cyc7-1-1 with the known amber suppressor SUP7-a indicated that the defect in cyc7-1-1 was an amber (UAG) nonsense codon. Sequencing revealed a single amino acid replacement of a tyrosine residue for the normal glutamine residue at position 24 in iso-2-cytochrome c from the suppressed cyc7-1-1 strain and also in five revertants of cyc7-1-1, of which three were due to extragenic suppression and two to intragenic reversion. The nature of the mutation that elevated the level of normal iso-2-cytochrome c in the CYC7-1 strain was not identified, although it occurred at or very near the CYC7 locus but outside the translated portion of the gene and it may be associated with a chromosomal aberration. Genetic studies demonstrated that CYC7 is not linked to CYC1, the structural gene for iso-1-cytochrome c.     

Yeast mutants defective in iso-2-cytochrome c.

The structural gene CYC7 for yeast iso-2-cytochrome c was previously identified by isolating a mutant, cyc7-1-1, totally lacking iso-2-cytochrome c and demonstrating that revertants of this mutant contained iso-2-cytochrome c with an altered primary structure (Downie et al., 1977). In this paper we describe a variety of different types of mutants that completely or partially lack iso-2-cytochrome c due to mutations in either the structural gene, CYC7, or unlinked “regulatory” genes. The iso-2-cytochrome c-deficient mutants were isolated by benzidine staining of over 3 × 10⁵ colonies from ?^? strains (cytoplasmic petites) that lacked iso-1-cytochrome c due to the deletion cyc1-1 and that contain abnormally high levels of iso-2-cytochrome c due to a chromosomal translocation, CYC7-1, adjacent to the normal structural gene CYC7 +. The cytochrome c content of mutants not staining with the benzidine reagents was estimated by low temperature spectroscopy, and 139 mutants containing significantly decreased levels of iso-2-cytochrome c were analyzed genetically by complementation with previously identified cyc mutants. In this way 50 mutants at the cyc2 and cyc3 loci were identified along with a group of 62 mutants of the structural gene cyc7. The different types of mutants of the structural gene which were uncovered and which were more or less anticipated included those that completely lacked iso-2-cytochrome c, those that were suppressible by UAA or UAG suppressors, those that lacked iso-2-cytochrome c but had increased levels after growth at lower temperatures, and those that exhibited visibly altered c_a absorption bands of iso-2-cytochrome c. Iso-2-cytochrome c mutants with altered primary structures were obtained from intragenic revertants of several of these mutants, confirming our earlier conclusion that cyc7 is the structural gene. In addition we observed an unexpected class of mutants that lacked iso-2-cytochrome c when in the ?^? state but contained approximately the CYC7-1 parental level when in the ?⁺ state. Two of these mutants, cyc7-1-47 and cyc7-1-49, were shown to contain altered iso-2-cytochromes c. The different contents of the abnormal iso-2cytochromes c suggest that cytochrome c has different environments in ?⁺ and ?^? mitochondria and that the ?⁺ condition may stabilize certain altered proteins.     

Specific induction of transitions and transversions of G-C base pairs by 4-nitroquinoline-1-oxide in iso-1-cytochrome c mutants of yeast

The base-pair changes induced by the highly carcinogenic agent, 4-nitroquinoline-1-oxide, have been determined from the reversion rates of defined tester strains and from the amino acid replacements of revertant iso-1-cytochromes c. The mutant codons and the base-pair changes of reverse mutations of 14 cyc1 mutants were previously determined from alterations of iso-1-cytochromes c in intragenic revertants. These 14 cyc1 mutants, which were used as tester strains, included nine mutants with altered AUG initiation codons, an ochre (UAA) mutant, an amber (UAG) mutant and three frameshift mutants (Stewart et al., 1971,1972; Stewart &; Sherman, 1972,1974; Sherman &; Stewart, 1973). NQO² induced a high rate of reversion in the initiation mutant cyc1-131, the only mutant in the group which reverts to normal iso-1-cytochrome c by a G · C → A · T transition. In addition, NQO produces a significant rate of reversion of all cyc1 mutants which revert by G · C transversions, e.g. the amber (UAG) mutant and the initiation mutants containing AGG, and probably CUG mutant codons. It did not revert the ochre mutant which contains no G · C base pairs. Ten NQO-induced revertants of the amber mutant cyc1-179 contained the expected replacements of residues of tyrosine, and ten NQO-induced revertants of each of the cyc1-131 and cyc1-133 initiation mutants all contained the expected normal iso-1-cytochrome c. The structures of these iso-1-cytochromes c and the pattern of reversion of the tester strains indicate that base-pair substitutions arise at G · C base pairs which are the site of NQO attack. Thus NQO induces G · C → A · T transitions, G · C → T · A transversions and possibly G · C → C · G transversions. Because of its mode of action, NQO may be useful in less-defined systems for identifying G · C base pairs in mutant codons.     

Differentiation between Amber and Ochre Mutants of Yeast by Reversion with 4-Nitroquinoline-1-Oxide

4-nitroquinoline-1-oxide (NQO) induces high frequencies of intragenic revertants of amber (UAG) but not ochre (UAA) mutants of yeast. Distinction of the amber and ochre codons was made with well-characterized nonsense mutants of the iso-1-cytochrome c gene (cyc1 mutants) as well as with nonsense mutants having nutritional requirements. Thus the NQO-induced reversion frequencies corroborated the assignments that were based on the pattern of amino acid replacements in intragenic revertants and on the speficity of suppression. It was concluded from these results and from the results of a previous investigation with other cyc1 mutants (Prakash, Stewart and Sherman 1974) that NQO induces transversions of G:C base pairs at many sites and that the specificity is not strongly influenced by neighboring base pairs in at least the strains examined in these studies. NQO was previously shown to induce G:C → A:T transitions at least at one site and this and the previous study established that it does not significantly mutate A:T base pairs at numerous sites. Thus NQO can be used to selectively mutate G:C base pairs and to determine if the pathways of reverse mutations involve G:C base pairs. Suppressors that act on either amber or ochre mutants were induced with NQO, indicating that they can arise by mutations of G:C base pairs.     

Serine insertion caused by the ribosomal suppressor SUP46 in yeast

The ribosomal suppressor SUP46 isolated from the yeast Saccharomyces cerevisiae suppresses a broad range of mutations, including at least some UAA, UAG and UGA alleles. The SUP46 suppressor causes the insertion of serine into iso-1-cytochrome c at the site of the UAA mutation in the cyc1-72 allele. It is believed that the altered ribosomes in the SUP46 suppressor allow a serine tRNA to misread UAA codons.     

Amino acid replacements resulting from super-suppression of nonsense mutants of iso-1-cytochrome c from yeast

The eight class I, set 1 super-suppressor genes, SUP2, SUP3, SUP4, SUP5, SUP6, SUP7, SUP8 and SUP11 are not closely linked and map at distinct loci throughout the genome of yeast. Each of these suppressors causes the production of 5 to 10% of the normal amount of iso-1-cytochrome c when it is individually coupled to the ochre (UAA) mutant cy1-2. All eight iso-1-cytochromes c contain a residue of tyrosine at position 20 which corresponds to the site of the ochre codon. Several of these super-suppressors also were shown to act on cy1-9, but at a much lower efficiency. It was shown that iso-1-cytochrome c from one of the suppressed cy1-9 strains contains a tyrosine at position 2, which corresponds to the site of the ochre codon in this mutant. It is suggested that the gene product of the eight super-suppressors is tyrosine transfer RNA.     

Yeast UAA suppressors effective in ψ+ strains serine-inserting suppressors

Over 200 revertants that suppressed three or more UAA markers were isolated in a haploid strain of yeast, Saccharomyces cerevisiae, containing the ψ⁺ cytoplasmic determinant which increases the efficiency of action of certain suppressors. These revertants were grouped into classes on the basis of suppression of four nutritional markers and the canavanine-resistant marker can1–100, and on the basis of the efficiency of suppression of the cyc1–72 marker which contains a defined UAA mutant codon corresponding to position 06 in iso-1-cytochrome c. Genetic analysis and other tests indicated that 40% of the suppressors were highly efficient and were allelic to one or another of the known tyrosine-inserting suppressors, that 59% of the suppressors were moderately efficient and were allelic to either the previously known serine-inserting suppressor SUP16 or to the newly discovered serine-inserting suppressor SUP17, and that 1% of the suppressors were inefficient and were allelic to the newly discovered SUP26 suppressor. The SUP16 suppressors were shown to be allelic to the previously characterized suppressor SUQ5 whose locus is on the right arm of chromosome XVI. This location and the pattern of suppression suggests that the SUP16 locus may be identical to the previously described SUP15 locus. Genetic analysis established that the newly discovered SUP17 locus is on the left arm of chromosome IX, between the his6 and lys11 markers. The examination of four different strains revealed that the SUP16 and SUP17 suppressors cause insertion of serine in iso-1-cytochrome c at the UAA site of the cyc1–72 mutant. It is suggested that the gene products of the SUP16 and SUP17 loci are redundant forms of the same serine transfer RNA. Because viable haploid strains containing both suppressors were obtainable, it was concluded that SUP16 and SUP17 could not be the sole genes coding for the only UCA-decoding species of serine tRNA.     

Mutants of yeast initiating translation of Iso-1-cytochrome c within a region spanning 37 nucleotides

We used a specially constructed strain, cyc1–345, of the yeast Saccharomyces cerevisiae to isolate revertants that initiated translation of iso-1-cytochrome c at various sites along an extended region of the mRNA. Normal amounts of iso-1-cytochrome c occurred when translation initiated at the abnormal sites corresponding to amino acid positions ?3, ?2, 3 and 5, as well as the normal position ?1; 20% of the normal amounts occurred when translation initiated at the abnormal position 9. These results with cyc1–345 revertants indicate that translation of iso-1-cytochrome c can initiate with the normal efficiency at any site within the region spanning 25 nucleotides. Furthermore, because the lower amount of the short iso-1-cytochrome c in the mutant initiating at position 9 may not necessarily reflect an inefficiency of translation, we believe that translation can initiate with normal or near-normal efficiencies at any site within a 37 nucleotide region, and presumably at any site preceding and following that of the normal initiation codon. These results establish that there is no absolute requirement for a particular sequence 5′ to the initiation codon, and are consistent with our previous suggestion that translation starts at the AUG codon closest to the 5′ end of the mRNA.     

Isolation and Characterization of Amber Suppressors in Yeast

Nonsense suppressors were obtained in a haploid yeast strain containing eight nutritional mutations, that are assumed to be amber or ochre, and the cyc1-179 amber mutation that has a UAG codon corresponding to position 9 in iso-1-cytochrome c. Previous studies established that the biosynthesis and function of iso-1-cytochrome c is compatible with replacements at position 9 of amino acids having widely different structures (Stewart and Sherman 1972). UV-induced revertants, selected on media requiring the reversion of one or two of the amber nutritional markers, were presumed to contain a suppressor if there was the unselected reversion of at least one other marker. The 1088 suppressors that were isolated could be divided into 78 phenotypic classes. Only 43 suppressors of three classes caused the production of more than 50% of the normal amount of iso-1-cytochrome c in the cyc1-179 strain. Genetic analyses indicated that all of these highly efficient amber suppressors are allelic to one or another of the eight suppressors which cause the insertion of tyrosine at ochre (UAA) codons (Gilmore, Stewart and Sherman 1971). Furthermore, only tyrosine has been identified at position 9 in iso-1-cytochrome c in cyc1-179 strains suppressed with these efficient amber suppressors.     

Substitution of serine caused by a recessive lethal suppressor in yeast.

The SUP-RL1 suppressor in the yeast Saccharomyces cerevisiae causes lethality in haploid strains but not in diploid or aneuploid strains that are heterozygous for the suppressor locus. This recessive lethal suppressor acts on amber (UAG) nutritional markers, and can cause the production of approximately 50% of the normal amount of iso-1-cytochrome c in disomic strains that are heterozygous for the SUP-RL1 suppressor, and that contain the cyc1-179 allele which has an amber codon corresponding to amino acid position 9. The suppressed iso-1-cytochrome c contains a residue of serine at the position that corresponds to the site of the amber codon. SUP-RL1 was found to lie between thr4 and MAL2 on chromosome III, approximately 30 map units from the mating-type locus. It is suggested that the gene product of SUP-RL1 may be a species of serine transfer RNA that normally reads the serine codon UCG, and that is represented only once in the haploid genome.     

Reversion of trpA nonsense mutations by deletion of the chain-termination codons

This paper describes a novel mechanism for reversion of nonsense mutations in the trpA gene of Escherichia coli. This mechanism, deletion of the nonsense codon, was discovered in the course of selecting for missense revertants of trpA(UGA211) and for catalytically active tryptophan synthetase alpha chain revertants of trpA(UAA234) and trpA(UAG234). Each type of revertant trpA was cloned and its DNA sequence determined. trpA(UGA211) gave rise to two previously unidentified types of missense revertant. The first type was expected, namely trpA(CGA211), the result of a base substitution event. The other type, representing approximately 1% of the missense revertants, was unexpected on the basis of single base substitutions and an understanding of which amino acids are functional at alpha chain position 211. It was found to be the result of a 21 base-pair deletion of a region containing codon 211. The tryptophan-independent revertants of both position 234 nonsense mutants occurred at a frequency of approximately 2 per 10(9) viable cells. They were identical in that they both resulted from a 3 base-pair deletion, namely deletion of the chain-terminating codon at position 234. One of them, however, also displayed an A instead of the normal G in the third position of codon 235. The revertants were characterized according to growth in different media and tryptophan synthetase assays performed on crude extracts. These types of mutants should prove interesting and important for the elucidation of alpha chain structure-function relationships, for insight into the assembly and interaction of subunits in this model multienzyme complex, and for the study of mechanisms by which deletions can be generated.     

Formation of composite iso-cytochromes c by recombination between non-allelic genes of yeast

We present evidence that two non-allelic genes, located on two non-homologous chromosomes in the yeast Saccharomyces cerevisiae, recombine and in this process generate new composite genes containing portions of both genes. The two genes CYC1 and CYC7 encode, respectively, iso-1-cytochrome c and iso-2-cytochrome c; CYC1 is located on the right arm of chromosome X and CYC7 is located on the left arm of chromosome V. The coding regions of CYC1 and CYC7 and the corresponding iso-1-cytochrome c and iso-2-cytochrome c are approximately 80% homologous. Composite genes were uncovered among revertants of certain but not all cyc1 mutants lacking iso-1-cytochrome c; composite genes were observed in most revertants from the low-reverting strains cyc1-11, cyc1-136 and cyc1-158, and in low proportions of the revertants from the typically reverting strains cyc1-94 and cyc1-156. Protein analysis of 14 composite iso-cytochromes c and DNA sequencing of five composite genes indicated that recombinational events produced replacements of central portions of the cyc1 gene with a corresponding segment from the wild-type CYC7⁺ gene. The replacements varied in length from 13% to 61% of the translated portion of the CYC1 locus. The formation of composite genes occurred spontaneously at very low frequencies and at low but enhanced frequencies after treatments with mutagens including ultraviolet light, ethylmethane sulfonate, methylmethane sulfonate and nitrous acid. Genetic tests indicated that composite genes are formed mitotically by a conversion-like event in which the wild-type CYC1⁺ allele remains intact. Recombination between non-allelic genes can lead to identical sequences at different loci and to diverse composite genes. These results support the indirect evidence from other eukaryotic systems that non-allelic genes with extensive but not complete homology recombine during evolution.     

Patterns of Genetic and Phenotypic Suppression of lys2 Mutations in the Yeast SACCHAROMYCES CEREVISIAE

A total of 358 lys2 mutants of Saccharomyces cerevisiae have been characterized for suppressibility by the following suppressors: UAA and UAG suppressors that insert tyrosine, serine or leucine; a putative UGA suppressor; an omnipotent suppressor SUP46; and a frameshift suppressor SUF1–1. In addition, the lys2 mutants were examined for phenotypic suppression by the aminoglycoside antibiotic paromomycin, for osmotic remediability and for temperature sensitivity. The mutants exhibited over 50 different patterns of suppression and most of the nonsense mutants appeared similar to nonsense mutants previously described. A total of 24% were suppressible by one or more of the UAA suppressors, 4% were suppressible by one or more of the UAG suppressors, while only one was suppressible by the UGA suppressor and only one was weakly suppressible by the frameshift suppressor. One mutant responded to both UAA and UAG suppressors, indicating that UAA or UAG mutations at certain rare sites can be exceptions to the specific action of UAA and UAG suppressors. Some of the mutants appeared to require certain types of amino acid replacements at the mutant sites in order to produce a functional gene product, while others appeared to require suppressors that were expressed at high levels. Many of the mutants suppressible by SUP46 and paromomycin were not suppressible by any of the UAA, UAG or UGA suppressors, indicating that omnipotent suppression and phenotypic suppression need not be restricted to nonsense mutations. All of the mutants suppressible by SUP46 were also suppressible by paromomycin, suggesting a common mode of action of omnipotent suppression and phenotypic misreading.     

New insights into the incorporation of natural suppressor tRNAs at stop codons in Saccharomyces cerevisiae

Stop codon readthrough may be promoted by the nucleotide environment or drugs. In such cases, ribosomes incorporate a natural suppressor tRNA at the stop codon, leading to the continuation of translation in the same reading frame until the next stop codon and resulting in the expression of a protein with a new potential function. However, the identity of the natural suppressor tRNAs involved in stop codon readthrough remains unclear, precluding identification of the amino acids incorporated at the stop position. We established an in vivo reporter system for identifying the amino acids incorporated at the stop codon, by mass spectrometry in the yeast Saccharomyces cerevisiae. We found that glutamine, tyrosine and lysine were inserted at UAA and UAG codons, whereas tryptophan, cysteine and arginine were inserted at UGA codon. The 5′ nucleotide context of the stop codon had no impact on the identity or proportion of amino acids incorporated by readthrough. We also found that two different glutamine tRNA^Gln were used to insert glutamine at UAA and UAG codons. This work constitutes the first systematic analysis of the amino acids incorporated at stop codons, providing important new insights into the decoding rules used by the ribosome to read the genetic code.     

Analysis of specific misreading in Escherichia coli

The pattern of specific misreading by nonsense suppressors has been investigated using nonsense mutants in the rIIB gene of phage T4 and in the lacZ gene of Escherichia coli. It is shown that a su⁺ transfer RNA which reads UAG also misreads UAA but not UGA, a su⁺ tRNA which reads UAA (while it also reads UAG by wobble) misreads UGA and a su⁺ tRNA which reads UGA also probably misreads UAA but not UAG.These specific types of errors in translation occur in the absence of streptomycin. The addition of the drug raises their level without altering the pattern described. A ribosomal mutation str A reduces the level of specific misreading; by contrast, a ram mutation strongly increases this level. In all cases the specific pattern is not affected.The rate of specific misreading of nonsense codons in different cases ranges from less than 0.001% to more than 3%. Since the frequency of misreading is sitespecific (unpublished observations), the rates obtained cannot be extrapolated to any other codon at any other site.     

Glutamine is incorporated at the nonsense codons UAG and UAA in a suppressor-free Escherichia coli strain

Readthrough of the nonsense codons UAG, UAA, and UGA is seen in Escherichia coli strains lacking tRNA suppressors. Earlier results indicate that UGA is miscoded by tRNA(Trp). It has also been shown that tRNA(Tyr) and tRNA(Gln) are involved in UAG and UAA decoding in several eukaryotic viruses as well as in yeast. Here we have investigated which amino acid(s) is inserted in response to the nonsense codons UAG and UAA in E. coli. To do this, the stop codon in question was introduced into the staphylococcal protein A gene. Protein A binds to IgG, which facilitates purification of the readthrough product. We have shown that the stop codons UAG and UAA direct insertion of glutamine, indicating that tRNA(Gln) can read the two codons. We have also confirmed that tryptophan is inserted in response to UGA, suggesting that it is read by tRNA(Trp).