Genetic Studies of Acridine-Induced Mutants in STREPTOCOCCUS PNEUMONIAE

The mutagenic properties of acridines on pneumococcus are described. All seven acridines tested were mutagenic at the amiA locus conferring a resistance to 10^-5 m aminopterin. The effects of quinacrine were more specifically investigated. It was observed that: mutants can be obtained only by treatment of exponentially growing cells; a sharp maximum mutagenic effect occurs at a concentration slightly lower than the bacteriostatic value; and the amount of quinacrine required to yield the maximum mutagenic effect decreases with the pH of the medium. Moreover, the number of mutants detected after quinacrine treatment varies from locus to locus. The majority of quinacrine-induced mutants are readily reverted by quinacrine, but not by nitrosoguanidine treatment. This suggests that in pneumococcus quinacrine induces mainly frameshift mutations. A further study of the revertants obtained by quinacrine treatment of quinacrine-induced mutants strengthens this interpretation: most of the revertants result from a mutation at the same site; some partial revertants exhibiting an intermediate resistance to aminopterin were found to contain two very closely linked mutated sites, each mutation conferring the maximum level of resistance to aminopterin. Thus, the majority of quinacrine-induced mutants at the amiA locus of pneumococcus consists of frameshift mutations. Nearly all of the isolated mutants induced by quinacrine as well as other acridines belong to the low efficiency class of transformation. It was concluded that the mismatch resulting from the pairing between the wild type and the frameshift-containing sequence is recognized by the excision-repair system involved in the discrimination function in a way similar to that in which it recognizes mismatched base pairs between a transition mutation and the wild-type sequence.     

Dihydrofolate reductase and aminopterin resistance in Pneumococcus

Summary Wild-type pneumococci derived from Avery's strain R36A are sensitive to extracellular concentrations of the folate antimetabolite aminopterin exceeding 1.0x10^-6 M. Three classes of resistant strains are phenotypically distinguishable: amiB-r, amiA-r and amiD-r strains are resistant to low (1.5x10^-6 M), intermediate (0.5–4.0×10^-5 M) and high (4.5x10^-4 M) aminopterin levels respectively. The amiA and amiB regions are weakly linked, but linkage has not been established between either of these loci and the amiD region.Consistent with the maximum resistance conferred by mutations in the amiA locus, dihydrofolate (FH₂) reductase in cell-free extracts (CFE) of amiA-r strains has a two- to six-fold greater affinity for the substrate than dose the enzyme in wild-type CFE (Table 1); FH₂ reductase from amiA-r strains may also have reduced affinity for aminopterin. Specific activity of the enzyme is not affected by mutation in the amiA locus (Table 1) and its affinity for the cofactor (NADPH) is probably unaffected by mutation in this locus (Table 4). Dihydrofolate reductase activity in amiA5 CFE is considerably more thermolabile than that in wild-type CFE (Table 2).The enzyme in CFE of the high resistance strain amiD1 has the same affinity for the substrate, cofactor and antimetabolite as FH₂ reductase in wild-type CFE (Figs. 1–4, 8 and 9; Table 4). However, specific activity of the enzyme in amiD1 CFE is 11-fold higher than that in wild-type CFE (Table 1) and it is much more heat stable (Table 2).Some properties of FH₂ reductase in CFE of the high resistance recombinant strain amiA5amiD1 are intermediate between those in CFE of wild-type and amiD1.Preliminary results suggest that CFE of wild-type and amiA5 contain a factor, which is neither dialyzable nor heat sensitive, that has an inhibitory effect upon activity and stability of FH₂ reductase in amiD1 CFE (Tables 2 and 3).     

Polarity of localised conversion in Streptococcus pneumoniae transformation

Summary Localised conversion in pneumococcal transformation is a process that spans a few nucleotides when the 5-ATTAAT/3-TAAGTA configuration occurs at the pairing step. It was first observed in two-point crosses between an amiA mutation (amiA36) carrying this sequence and other closely linked mutants of the locus. The yield of the amiA resistance allele conversion to wild type is 20%. In order to characterize this process, which differs from longpatch conversion by the length of DNA repair, gene requirements and sequence specificity, we devised expreriments to detect the reciprocal conversion, AmiA⁺ to AmiA^r. For this purpose we examined the suppressibility by a pneumococcal informational suppressor of several nonsense mutations at the locus. Amber (UAG) and ochre (UAA) mutations are suppressed whereas UGA is not suppressed. In this genetic background, where amiA36 is partly suppressed, it was possible to select for double mutants in a cross between amiA36 and a closely linked non-suppressible marker. Direct isolation of such double mutants was also performed without any screening in crosses between amiA36 and the same linked marker in cloned DNA. The frequency of double mutants was very low (1/175) suggesting that there is no conversion of wild-type to mutant alleles. Thus conversion is a polarized process changing specifically A to C.     

Phenotypic reversion in some early blocked sporulation mutants of Bacillus subtilis. Genetic study of polymyxin resistant partial revertants

Summary A class of suppressor mutations restores, in pleiotropic sporulation mutants of B. subtilis (SPO mutants), the wild type level of resistance to Polymyxin, and, most often, other properties of the wild strain as well, but never the ability to sporulate. These suppressors, extracistronic, are active on mutations occurring in any one of the 5 genes in which SPO mutations have been found. The phenotype of the suppressed strains is dependent on both the suppressed (SPO) and the suppressive mutations. All these suppressors are located in a single locus and some of them are thermosensitive. The evidence suggests that a physiological compensation is at work in the partial revertants, so that the locus at which the suppressors are located was called cps X. Two hypotheses are discussed that might account for these observations.     

Growth inhibition of Escherichia coli K-12 by L-valine: a consequence of a regulatory pattern.

Summary We studied the production of the ilvG gene product, the valine resistant acetolactate synthase isoenzyme II, in an ilvO ⁺ G ⁺ ilvB ilvHI derivative of Escherichia coli K-12. This strain contains mutations in the structural genes for the valine sensitive acetolactate synthase isoenzymes I and III. We find that the ilvG gene is not expressed in this strain when grown with either isoleucine and valine or with isoleucine, leucine and valine, or when limited for either isoleucine or valine. Since we previously found that the ilvG gene is expressed in an ilvO603 containing strain (Favre et al., 1976), we presume that the mechanism by which E. coli K-12 regulates the ilv gene cluster is responsible for the lack of ilvG expression in the ilvO ⁺ strain. The valine sensitivity of E. coli K-12 is a consequence of this regulatory pattern.     

The Saccharomyces cerevisiae SGE1 gene product: a novel drug-resistance protein within the major facilitator superfamily

Several pleiotropic drug sensitivities have been described in yeast. Some involve the loss of putative drug efflux pumps analogous to mammalian P-glycoproteins, others are caused by defects in sterol synthesis resulting in higher plasma membrane permeability. We have constructed a Saccharomyces cerevisiae strain that exhibits a strong crystal violet-sensitive phenotype. By selecting cells of the supersensitive strain for normal sensitivity after transformation with a wild-type yeast genomic library, a complementing 10-kb DNA fragment was isolated, a 3.4-kb subfragment of which was sufficient for complementation. DNA sequence analysis revealed that the complementing fragment comprised the recently sequenced SGE1 gene, a partial multicopy suppressor of gal11 mutations. The supersensitive strain was found to be a sge1 null mutant. Overexpression of SGE1 on a high-copy-number plasmid increased the resistance of the supersensitive strain. Disruption of SGE1 in a wild-type strain increased the sensitivity of the strain. These features of the SGE1 phenotype, as well as sequence homologies of SGE1 at the amino acid level, confirm that the Sge1 protein is a member of the drug-resistance protein family within the major facilitator superfamily (MFS).     

Identification of a gene for alpha-tubulin in Aspergillus nidulans.

This paper demonstrates that revertants of temperature-sensitive benA (β-tubulin) mutations in Aspergillus nidulans can be used to identify proteins which interact with β-tubulin. Three benomyl-resistant benA (β-tubulin) mutants of Aspergillus nidulans, BEN 9, BEN 15 and BEN 19, were found to be temperature-sensitive (ts^?) for growth. Temperature sensitivity co-segregated with benomyl resistance among the progeny of outcrosses of BEN 9, 15 and 19 to a wild-type strain, FGSC#99, indicating that temperature sensitivity was caused by mutations in the benA gene in these strains. Eighteen revertants to ts⁺ were isolated by selection at the restrictive temperature. Four had back-mutations in the benA gene and fourteen carried extragenic suppressor mutations. Two of the back-mutated strains had β-tubulins which differed from the β-tubulins of their parental strains by one (1^?) or two (2^?) negative charges on two-dimensional gel electrophoresis. Although the β-tubulins of the extragenic suppressor strains were all electrophoretically identical to those of the parental strains, one of the suppressor strains, BEN 9R7, had an electrophoretic abnormality in α1-tubulin (1⁺). A heterozygous diploid between this strain and a strain with wild-type α1-tubulin was found to have both wild-type and mutant (1⁺) α1-tubulins. This experiment rules out post-translational modification as a possible cause of the α1-tubulin abnormality. Thus the suppressor mutation in BEN 9R7 must be in a structural gene for α1-tubulin. We propose that this gene be designated tubA to denote that it is a gene for α1-tubulin in A. nidulans.     

The acetolactate synthase isoenzymes of Escherichia coli K-12.

Summary Strains of Escherichia coli K-12 possessing only one of the three genes coding for acetolactate synthetase activity present either in the wild type or in its ilv0603 derivative were prepared and analyzed. Extracts prepared from these strains show different values of acetolactate synthase specific activity and different sensitivity to valine inhibition. These strains show a unique pattern of growth inhibition by different substances.Temperature sensitive (ts) mutations in the ilvB and ilvG genes, have been isolated and characterized. Extracts of these strains were found to have an acetolactate synthase activity more heat labile than that of a strain containing the corresponding wild type allele. We conclude that ilvB and ilvG are the structural genes for two different forms of acetolactate synthase activity, most likely two isoenzymes. Moreover, since the strains containing a ts mutation show a temperature sensitive auxotrophy for isoleucine and valine, these two acetolactate synthases participate in isoleucine and valine biosynthesis. Similar evidence for a third acetolactate synthase, the product of the ilvHI genes, has been reported previously.We propose the following names for the acetolactate synthase isoenzymes: acetolactate synthase I (AHAS I), the product of the ilvB gene; acetolactate synthase II (AHAS II), the product of ilvG gene; and acetolactate synthase III (AHAS III), the product of the ilvHI genes.     

The vestigial locus of Drosophila melanogaster is involved in resistance to inhibitors of dTMP synthesis

The vestigal (vg) gene encodes a nuclear protein which plays a major role in the formation of the wing of Drosophila. Resistance or sensitivity to aminopterin, an inhibitor of the dihydrofolate reductase enzyme in D. melanogaster, seems to be associated with a specific alteration in vg gene function. Wild-type and vg mutant strains selected for growth on increasing concentrations of aminopterin display changes in physiological and biochemical parameters such as viability on normal and aminopterin-containing media, duration of development, wing phenotype, dihydrofolate reductase activity, and cross-resistance to fluorodeoxyuridine (FUdR) and to methotrexate. Our results indicate that the mechanisms of resistance differ in the wild-type and mutant strains. The vg ^83b27 mutant, in which the major part of intron 2 of the vg gene is deleted, is associated with a high rate of resistance to FUdR, an inhibitor of thymidylate synthetase. Moreover, vg ^83b27/vg ^BGheterozygotes, which are wild type when grown on normal medium, display a strong vg phenotype when grown on aminopterin. Our results indicate a role for the vestigial locus in mediating resistance to inhibitors of dTMP synthesis.     

Isolation and transposon mutagenesis of a Pseudomonas putida KT2442 toluene-resistant variant: involvement of an efflux system in solvent resistance

A toluene-resistant variant of Pseudomonas putida KT2442, strain TOL, was isolated after liquid cultivation under xylene followed by toluene for 1 month in each condition. Almost all the populations of the variant strain formed small but readily visible colonies under toluene within 24 h at 30°C. The toluene-resistant strain also showed an increase in resistance to some unrelated antibiotics. Several toluene-sensitive Tn5 mutants have been isolated from the toluene-resistant strain and showed various levels of sensitivity. Most of these mutations did not cause significant changes in antibiotic resistance; however, one of the mutants (TOL-4) was highly susceptible to both organic solvents and various antibiotics, especially β-lactams. Sequencing analysis revealed that the mutation in TOL-4 had been introduced into a gene that may encode a transporter protein of an efflux system. This efflux system is very similar to one of the multidrug efflux systems of Pseudomonas aeruginosa. These observations indicate that a multidrug efflux system plays a major role in the organic solvent resistance of P. putida TOL. However, several other genes may also be involved. Received: December 18, 1997 / Accepted: March 16, 1998     

Detection of Mutations in Tumor Suppressor Genes

Defects in vital genes occur in a high percentage of human diseases, including cancer. Defects could be due to the accumulation of mutations in the genes leading to the production of faulty proteins. Although the biological significance of such mutant proteins still remains in question, recent experiments have demonstrated that genes overproducing faulty proteins are often associated with tumor cell growth. Thep53tumor suppressor gene is the most frequently mutated gene yet identified in human cancer. It is mutated in wide variety of human cancers. Missense mutations are common for thep53gene and are essential for the transforming ability of the oncogene. The wild-typep53gene may directly suppress cell growth or indirectly activate genes that are involved in growth suppression. Thus inactivation of wild-typep53by point mutation may contribute to transformation. Therefore, identification of such mutations have potential clinical implications. Recently, polymerase chain reaction-based advanced molecular techniques had a profound impact on the detection and identification of such mutations. These techniques are sensitive and quantitative tools for the study of the pathogenesis of neoplastic diseases at the single-cell level.     

Dihydrofolate reductase activity and resistance to aminopterin in various species of Drosophila

Summary The aim of our work was to compare the mechanisms of resistance to aminopterin, inhibitor of the dihydrofolate reductase enzyme, between different Drosophila species and those described for cultured cells. Moreover we compared the systematic species divisions based on morphological traits and those based on a molecular approach. For this purpose, the effect of aminopterin on viability and wing phenotype was studied in different Drosophila species. Dihydrofolate reductase was measured in adult flies. We found an important dihydrofolate reductase activity in the melanogaster sub-group compared to the other species studies. Wing effect was observed only in this sub-group. The effects of aminopterin on the wing phenotype were very similar to the phenotype of rudimentary mutants. Both deplete the pyrimidine pool and it has been shown by the studies of the structural genes of the nucleotide pyrimidine pathway that the wing tissue is very sensitive to every pertubation of this metabolism.The D. ananassae species was found to be fully resistant at the concentrations of the inhibitor tested. No or very little dihydrofolate reductase activity was detected. The binding of the enzyme to the inhibitor was comparable to that found in the Oregon strain of D. melanogaster. The purine and pyrimidine salvage pathways were investigated and the D. ananassae species displayed an important thymidine kinase activity. The D. ananassae flies were sensitive on Sang medium compared to the Oregon flies but were able to use exogenous bases or nucleosides more efficiently. Therefore the mechanism of resistance to aminopterin in Drosophila may be different from those described for methotrexate in mammalian cultured cells, as indicated by the results obtained for D. ananassae.     

Restoration of enzyme activity by recessive missense suppressors in the fungus Coprinus.

Summary The acu-1 locus in Coprinus is the structural gene for acetyl-CoA synthetase. Five suppressor gene mutations, which suppress the acu-1,34 missense allele, were induced by mutagen treatment. All five suppressors were shown to have properties expected for tRNA structural gene mutations: they are recessive, they show a gene dosage effect in any doubly heterozygous combination of two sup ⁺ mutations and they are allele specific in action.Crosses between suppressed mutants established that at least four suppressor loci were represented. Doubly suppressed mutants derived from these crosses were used to show that the gene dosage effect is maintained when two sup ⁺ mutations are in cis as well as trans combinations in the two nuclei of the basidiomycete dikaryon.Extracts of the unsuppressed acu-1.34 mutant contained less than 2% of wild type acetyl-CoA synthetase activity whereas extracts of four of the five suppressor strains showed activities ranging from 28 to 37% of wild type. Only a slight increase in activity was detected in the fifth suppressor strain but this was associated with a temperature sensitive sup ⁺ phenotype. All five sup ⁺ mutations restored the ability of the acu-1.34 mutant to induce isocitrate lyase, an enzyme which, under the conditions of growth used, can only be induced when acetyl-CoA synthetase activity is present. Thus all five suppressors act to restore normal acu-1 protein function.     

The role of thiol redox systems in the resistance of <Emphasis Type="Italic">Escherichia coli</Emphasis> in the stationary phase

The effect of glutathione (gshA), thioredoxin (trxA), and thioredoxin reductase (trxB) mutations on the adaptation of Escherichia coli to prolonged glucose starvation was investigated. The trxB mutation had the worst consequences for the stationary-phase cells. These bacteria exhibited decreased survival, increased sensitivity to oxidants, and decreased expression of the katE and sulA genes. As the stationary phase proceeded, the physiological resistance to antibiotics increased in all the strains tested; however, the thiol redox system mutants were far less able to develop antibiotic resistance than the parent strain cells. During the stationary phase, a considerable shift was observed in the redox status of intra- and extracellular glutathione toward the oxidative values. These results indicate that the thiol redox systems play an important role in the adaptation of Escherichia coli to prolonged starvation and antibiotic resistance.     

Suppression of erythromycin resistance in ery-M1 mutants of Chlamydomonas reinhardi

Summary After mutagenesis of the erythromycin-resistant Chlamydomonas reinhardi strain ery-M1b, four mutants were isolated, each more sensitive to erythromycin than ery-M1b. All four mutants carry the original ery-M1b mutation which confers resistance and a separate mutation (es) which partially suppresses resistance. The mutants are designated es5ery-M1b, es101ery-M1b, es105ery-M1b, and es115ery-M1b. The suppressor mutations represent at least three different Mendelian loci. The suppressor es101 is located on the same linkage group as ery-M1, while the other suppressors are not linked to ery-M1.Although some of these suppressors can also mask the erythromycin resistance of ery-M2 strains, none had any effect on the non-Mendelian mutant ery-Ula. In addition, each suppressor affected the cross-resistance of ery-M1 mutants to other antibiotics. At least two of the changes in cross-resistance are due solely to the suppressor.Chloroplast ribosomes from cells carrying es5ery-M1b, es101ery-M1b, and es115ery-M1b have a greater affinity for ¹⁴C-erythromycin in vitro than those from ery-M1b. The degree of affinity depends upon the concentration of KCl.Each of these Mendelian suppressors probably affects a chloroplast ribosome function. Hence, a number of nuclear genes must play roles in the biogenesis of the chloroplast ribosome in Chlamydomonas reinhardi.     

Temperature-sensitive,lipopolysaccharide-deficient mutants of Salmonella typhimurium

Two mutants of Salmonella typhimurium LT2, which were temperature-sensitive for lipopolysaccharide (LPS) synthesis, were isolated from a galE ^- strain based on their resistance to phage C21 and sensitivity to sodium deoxycholate at 42°C. They produced LPS of chemotype Rc at 30°C and deep-rough LPS at 42°C. P22-mediated transductional analysis showed that the mutations responsible for temperature sensitivity are located in the rfa cluster where several genes involved in the synthesis of the LPS core are mapped. A plasmid, carrying rfaC, D and F genes of Escherichia coli K-12, complemented these mutations. These genes are responsible for the synthesis of the inner-core region of the LPS molecule. This indicates that genetic defects in these temperature-sensitive mutants affect the inner-core region of LPS.     

Multiple Origins of Cyclodiene Insecticide Resistance in Tribolium castaneum (Coleoptera: Tenebrionidae)

The number of origins of pesticide resistance-associated mutations is important not only to our understanding of the evolution of resistance but also in modeling its spread. Previous studies of amplified esterase genes in a highly dispersive Culex mosquito have suggested that insecticide resistance-associated mutations (specifically a single-gene duplication event) can occur a single time and then spread throughout global populations. In order to provide data for resistance-associated point mutations, which are more typical of pesticide mechanisms as a whole, we studied the number of independent origins of cyclodiene insecticide resistance in the red flour beetle Tribolium castaneum. Target-site insensitivity to cyclodienes is conferred by single point mutations in the gene Resistance to dieldrin (Rdl), which codes for a subunit of a γ-aminobutyric acid (GABA) receptor. These point mutations are associated with replacements of alanine 302 which render the receptor insensitive to block by the insecticide. We collected 141 strains of Tribolium worldwide and screened them for resistance. Twenty-four strains contained resistant individuals. After homozygosing 23 of these resistance alleles we derived a nucleotide sequence phylogeny of the resistant strains from a 694-bp section of Rdl, encompassing exon 7 (which contains the resistance-associated mutation) and part of a flanking intron. The phylogeny also included six susceptible alleles chosen at random from a range of geographical locations. Resistance alleles fell into six clades and three clades contained both resistant and susceptible alleles. Although statistical analysis provided support at only the 5–6% level, the pattern of variation in resistance alleles is more readily explained by multiple independent origins of resistance than by spread of a single resistance-associated mutation. For example, two resistance alleles differed from two susceptible alleles only by the resistance-associated mutation itself, suggesting that they form the susceptible ancestors and that resistance arose independently in several susceptible backgrounds. This suggests that in Tribolium Rdl, de novo mutations for resistance have arisen independently in several populations. Identical alleles were found in geographically distant regions as well, also implying that some Rdl alleles have been exported in stored grain. These differences from the Culex study may stem both from differences in the population genetics of Tribolium versus that of mosquitoes and differences in mutation rates associated with point mutations versus gene duplication events. The Tribolium data therefore suggest that multiple origins of insecticide resistance (associated with specific point mutations) may be more common than the spread of single events. These findings have implications for the way in which we model the evolution and spread of insecticide resistance genes and also suggest that parallel adaptive substitutions may not be uncommon in phyletic evolution. Received: 14 October 1998 / Accepted: 4 January 1999     

The genetics of teratocarcinoma transplantation: tumor formation in allogeneic hosts by the embryonal carcinoma cell lines F9 and PCC3

Two cultured lines of murine embryonal carcinoma, F9 and PCC3, have been grafted to a variety of allogeneic hosts. The host strains have been classified by their resistance or sensitivity to these carcinomas. Resistance seems to be immunological in nature.Allograft rejection does not correlate withH-2 haplotype, and seems to be controlled by a limited number of recessive factors, presumably histocompatibility genes. We infer that these factors have limited polymorphism in the mouse species. Recombinational analysis of strain A/He has revealed the presence of a recessive factor linked to theH-2 locus. Tumor resistance of strains C57BL/6 and AKR appears to result from the interaction of dominant or semi-dominant factors in theH-2 region with other recessive elements in the genetic background.Though F₁ hybrids between resistant mouse strains and the syngeneic strain 129 are largely tumor-sensitive, a low level of hybrid resistance to F9 has been observed and shown to be eliminated by X-irradiation.     

Vestigial mutants of Drosophila melanogaster live better in the presence of aminopterin: increased level of dihydrofolate reductase in a mutant

Summary Vestigial (vg) mutants of Drosophila melanogaster are characterized by atrophied wings. In this paper we show that: (1) aminopterin an inhibitor of dihydrofolate reductase (DHFR) and fluorodeoxyuridine (FUdR), an inhibitor of thymidylate synthetase induce nicks in the wings of wild-type flies and phenocopies of the vg mutant phenotype when vg/+ and vg ^B/+ flies are reared on these substances (vg^B is a deficiency of the vg locus). Only thymidine and thymidylate can rescue the flies from the effect of aminopterin. We propose that the vg phenotype is due to a decrease in the dTMP pool in the wings. (2) Mutant vg strains yield more offspring on medium containing aminopterin than on normal medium. The resistance of vg larvae to the inhibitor seems specific to the gene. This is the first case of aminopterin resistance in living eucaryotes. In contrast sensitivity of the vg larvae to FUdR is observed. (3) An increase in the activity and amount of DHFR is observed in mutant strains as compared with the wild-type flies.Our data suggest that the vg ⁺ gene is a regulatory gene acting on the DHFR gene or a structural gene involved in the same metabolic pathway.     

Overexpression of genes encoding tRNA<Superscript>Tyr</Superscript> and tRNA<Superscript>Gln</Superscript> increases the viability of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> strains with nonsense mutations in the <Emphasis Type="Italic">SUP45</Emphasis> gene

At present, the machinery supporting the viability of organisms possessing nonsense mutations in essential genes is not entirely understood. Nonsense mutants of Saccharomyces cerevisiae yeast containing a premature translation termination codon in the essential SUP45 gene are known. These strains are viable in the absence of mutant suppressor tRNAs; hence, the existence of alternative mechanisms providing nonsense suppression and mutant viability is conjectured. Analysis of clones obtained by transformation of a strain bearing a nonsense-mutant allele of SUP45 with a multicopy yeast genomic library revealed three genes encoding wild-type tRNA^Tyr and four genes encoding wild-type tRNA^Gln, which increased nonsense mutant viability. Moreover, overexpression of these genes leads to an increase in the amount of the full-length eRF1 protein in cells and compensates for heat sensitivity in the nonsense mutants. Probable ways of tRNA^Tyr and tRNA^Gln influence on the increase in the viability of strains with nonsense mutations in SUP45 are discussed.