Antimycin-insensitive mutants of Candida utilis II. The effects of antimycin on Cytochrome b.

1. Cytochrome b-562 is more reduced in submitochondrial particles of mutant 28 during the aerobic steady-state respiration with succinate than in particles of the wild type. When anaerobiosis is reached, the reduction of cytochrome b is preceded by a rapid reoxidation in the mutnat. A similar reoxidation is observed in the wild type in the present of low concentrations of antimycin. 2. In contrast to the wild type, inhibition of electron transport in the mutant has a much higher antimycin titre than effects on cytochromes b (viz., aerobic steady-state reduction; reduction in the presence of substrate, cyanide and oxygen; the 'red shift' and lowering of E'-o of cytochrome b-562). Moreover, the titration curve of electron transport is hyperbolic whereas the curves for the reduction are sigmoidal. The conclusion is, that in both mutant and wild type, the actions of antimycin on electron transport and cytochromes b are separable. 3. The red shift in the mutant is more extensive than in the wild type. 4. Cytochrome b-558 and cytochrome b-566 (that absorbs in mutant and wild type at 564.5 nm) do not respond simultaneously to addition of antimycin, indicating that they are two separate cytochromes. 5. The difference between the effect of antimycin on electron transport and cytochromes b reduction is also found in intact cells of the mutant. 6. A model is suggested for the wild-type respiratory chain in which (i) the cytochromes b lie, in an uncoupled system, out of the main electron-transfer chain, (ii) antimycin induces a conformation change in QH-2-cytochrome c reductase resulting in effects on cytochrome b and inhibition of electron transport, (iii) a second antimycin-binding site with low affinity to the antibiotic is present, capable of inhibiting electron transport.     

Antimycin-insensitive mutants of Candida utilis. II. The effects of antimycin on cytochrome b

1. Cytochrome b-562 is more reduced in submitochondrial particles of mutant 28 during the aerobic steady-state respiration with succinate than in particles of the wild type. When anaerobiosis is reached, the reduction of cytochrome b is preceded by a rapid reoxidation in the mutant. A similar reoxidation is observed in the wild type in the presence of low concentrations of antimycin.

2. In contrast to the wild type, inhibition of electron transport in the mutant has a much higher antimycin titre than effects on cytochromes b (viz., aerobic steadystate reduction; reduction in the presence of substrate, cyanide and oxygen; the ‘red shift’ and lowering of E′₀ of cytochrome b-562). Moreover, the titration curve of electron transport is hyperbolic whereas the curves for the reduction are sigmoidal. The conclusion is, that in both mutant and wild type, the actions of antimycin on electron transport and cytochromes b are separable.

3. The red shift in the mutant is more extensive than in the wild type.

4. Cytochrome b-558 and cytochrome b-566 (that absorbs in mutant and wild type at 564.5 nm) do not respond simultaneously to addition of antimycin, indicating that they are two separate cytochromes.

5. The difference between the effect of antimycin on electron transport and cytochromes b reduction is also found in intact cells of the mutant.

6. A model is suggested for the wild-type respiratory chain in which (i) the cytochromes b lie, in an uncoupled system, out of the main electron-transfer chain, (ii) antimycin induces a conformation change in QH₂-cytochrome c reductase resulting in effects on cytochrome b and inhibition of electron transport, (iii) a second antimycinbinding site with low affinity to the antibiotic is present, capable of inhibiting electron transport.     

Gene mutation eliminating antimycin A-tolerant electron transport in Ustilago maydis

A class of mutants of Ustilago maydis selected on a fungitoxic oxathiin lack of antimycin A-tolerant respiratory system which is present in wild-type cells. This system provides, directly or indirectly, for considerable resistance to antimycin A because growth of mutant cells lacking the system is much more sensitive to the antibiotic than that of the wild type. Antimycin A-sensitive O(2) uptake and growth is found in half of the progeny from crosses of mutant to wild type. All antimycin A-sensitive segregants are somewhat more resistant to oxathiins than the antimycin A-resistant segregants. The respiration of the mutant is strongly inhibited by cyanide and azide at concentrations which stimulate respiration of the wild type. Respiration of both mutant and wild type is about equally inhibited by rotenone. It appears that the mutation alters some component of the respiratory system located between the rotenone inhibition site and the antimycin A inhibition site that permits shift of electron transport to an alternate terminal oxidase when the normal electron transport pathway is blocked.     

Mitochondrial heredity of resistance to 3-(3,4-dichlorophenyl)-1,1-dimethylurea, an inhibitor of cytochrome b oxidation, in Saccharomyces cerevisiae.

3-(3,4-dichlorophenyl)-1,1-dimethylurea (diuron), an inhibitor of cytochrome b oxidation, has been used for the selection of three resistant mutants (diur) of Saccharomyces cerevisiae. The mutant diur-64 exhibits in vivo cross-resistance to antimycin A while diur-34 and diur-1 are more sensitive to antimycin A than the parental strain. The three mutants exhibit mitochondrial inheritance according to the following criteria: mitotic segregation of diuron-resistant and diuron-sensitive diploids is obtained among the diploid progeny of a cross between diur and dius; non-Mendelian segregation of diuron resistance (4:0) is observed in spores of tetrads issued from diuron-resistant diploid; extensive ethidium bromide treatment leads to the formation of Q- mutants which no longer transmit diur and dius alleles. Evidence for two distinct diuron-resistant loci were obtained by allelism tests. Recombination analysis shows that diuron-resistance is not located in the polar region of the mitochondrial genome. The diur loci are not linked to the erythromycin locus since the upper limit in recombinants frequency (26%) for a non-polar region is obtained between diur and eryr. A low recombinants frequency (3%) is observed in crosses between diur-34 mutation and the two mutants cob1 and cob2 suggesting that diur-34 might be located between these two cytochrome-b-deficient loci. The resistance to diuron is also expressed in vitro since the oxidation rates of succinate by sonicated submitochondrial particles from the mutants are clearly less sensitive to diuron than that of the wild type.     

Effects of a missense exonic mutation in cytochrome b gene, observed on isolated mitochondrial complex III of Saccharomyces cerevisiae: consequence for the antimycin binding site

The mitochondrial complex III was isolated from a wild type strain of Saccharomyces cerevisiae PS409 and from two mutants, PS490 and PS493, carrying a missense mutation in the structural gene of cytochrome b (in exons B1 and B4 respectively). These mutants synthesize cytochrome b in variable proportions, but they are unable to grow on a respirable substrate. Strain PS493 does not bind antimycin, whereas strain PS490 contains less cytochromes b and c1 but shows a strong binding to the inhibitor. The complex isolated from the wild type strain or mutant PS493 exhibited a specific cytochrome b and cytochrome c1 heme content of approximately 8 and 4 nmol/mg of protein respectively. This content was about 3 and 2 nmol/mg with PS490, which leads to a molar stoichiometry of 1.3 : 1 for cytochromes b and c1, instead of an 'ideal' ratio of 2 : 1 expected with b-c1 complex, and obtained with the two other strains. This implies that the association (or presence) of b and c1 cytochromes is not pre-requisite for complex III assembly. The wild type complex III isolated from PS409 was found to have a high level of CoQ2H2 activity, using a synthetic coenzyme Q analog as substrate (440 s-1 mol of cytochrome c reduced/mol of cytochrome c1). This activity is fully inhibited by antimycin. The complexes isolated from the two box mutants exhibited no such activity. Analysis of the subunit composition of the three isolated complexes on sodium dodecyl sulfate-gel electrophoresis showed that all the bands belonging to the b-c1 complex were synthesized in both mutants as well as in the wild type strain. Some of them appeared to have slightly diminished, but no specific decrease of a band has been observed in mutant PS493 that does not bind antimycin, with respect to mutant PS490 which binds strongly to the inhibitor. It should be noted that the subunit of about 12-13 kDa, qualified as the antimycin binding protein, is equally present in the three complexes. The results suggest that the loss of antimycin binding in mutant PS493 might be due to conformational perturbations in the modified complex rather than to the disappearance or significant modification of some protein support.     

The respiratory chain of Paramecium tetraurelia in wild type and the mutant Cl1. II. Cyanide-insensitive respiration. Function and regulation.

1. The cyanide-insensitive respiration in Paramecium tetraurelia was found to be located in mitochondria. 2. Sensitivity of the mitochondrial respiration to cyanide depended on growth conditions. Under standard conditions of growth, 15--20% of respiration was insensitive to 1 mM cyanide. Full resistance to 1 mM cyanide was observed by growing cells in the presence of erythromycin (100--400 microgram/ml) 0.2 mM cyanide. The mitochondrial respiration of the mutant Cl1 harvested during the exponential phase of growth was largely insensitive to cyanide (more than 80%). 3. Pyruvate was oxidized at the same rate by wild type mitochondria and mitochondria of the mutant Cl1. In contrast, succinate oxidation was 2--3 times faster in mitochondria of the mutant Cl1 than in wild type mitochondria. 4. The cyanide-insensitive respiration was inhibited by 1 mM salicylhydroxamic acid to nearly 100%. Other efficient respiratory inhibitors included amytal and heptylhydroxyquinoline. Antimycin was not inhibitory even at concentrations as high as 5 microgram/mg protein, a finding consistent with the lack of antimycin binding sites.     

Reduced plasma membrane permeability in a multiple cross-resistant strain of Saccharomyces cerevisiae.

Single nuclear gene inheritance was shown to be responsible for increased resistance to: eight diverse inhibitors of mitochondrial function (antimycin, carbonylcyanide-m-chlorophenylhydrazone, chloramphenicol, oligomycin, tetracycline, triethyltin bromide, triphenylmethylphosphonium bromide and triton-X-165); and an inhibitor of cytoplasmic protein synthesis (cycloheximide). Continuous monitoring of oxygen uptake during respiratory adaptation showed that anerobic pretreatment of resistant cells sensitized respiratory adaptation to chloramphenicol and antimycin. However, since a depression of mitochondrial function by catabolite repression did not result in sensitization to antimycin, alteration of the mitochondrial membrane does not appear to be responsible for resistance to mitochondrial inhibition. Alteration of cellular binding sites was not responsible for resistance since in vitro mitochondrial protein synthesis was sensitive to chloramphenicol and in vitro mitochondrial respiration was sensitive to oligomycin, carbonylcyanide-m-chlorophenylhydrazone, and antimycin. Autoradiography of an ethylacetate-ethanol extract of [14C]chloramphenicol-treated resistant cells indicated that resistance was not due to enzymatic modification of inhibitors. The maintenance of an antimycin-resistant respiration by protoplasts of resistant cells ruled out the involvement of the cell wall in cellular resistance. The reduced transport of [14C]chloramphenicol by resistant cells (1% of normal cells) indicated that a single nuclear gene mutation can alter the permeability of the plasma membrane to many diverse inhibitors.     

On the formation of rho- petites in yeast. II. Effects of mutation tsm-8 on mitochondrial functions and rho-factor stability in Saccharomyces cerevisiae.

1. In non-fermentable substrates growth of mutant tsm-8 cells of Saccharomyces cerevisiae is restricted to about one generation after shift from 23 to 35 degrees C. Non-permissive conditions (35 degrees C, glycerol) cause a gradual decrease in respiration to about 20% of the activity at permissive temperature 23 degrees C). 2. Anaerobically grown and glucose-repressed mutant cells exhibit a decreased adaptation rate of mitochondrial functions to aerobic growth and non-fermentative growth, even at 23 degrees C, as revealed by determination of respiratory rates and mitochondrial protein synthesis. 3. At 35 degrees C, rho+ cells of mutant tsm-8 are converted to p- cells within 6-8 generations of growth, in all fermentable substrates tested. Drugs or antibiotics as nalidixic acid, acriflavin, chloramphenicol and erythromycin, bongkrecic acid, antimycin and FCCP, as well as anaerobiosis, have little or no influence on this kinetics. A heat shock does not yield rho- petites to a significant extent. 4. Reversion of tsm-8 cells to wild type function, which occurs spontaneously with a frequency of 10(-8), is found to be due to a mitochondrial mutational event.     

Characterization of a mutant of Schizosaccharomyces pombe lacking cytochrome b-566

1. A chromosomal respiration-deficient mutant of the petite-negative yeast Schizosaccharomyces pombe was isolated. Its mitochondria show respiration rates of about 7% of the wild-type respiration with NADH and succinate as substrate, and 45% with ascorbate in the presence of tetramethyl-p-phenylenediamine. Oxidation of NADH and succinate is insensitive to antimycin and cyanide and that of ascorbate is much less sensitive to cyanide than the wild type.

2. The amounts of cytochromes c₁ and aa₃ are similar in the mutant and wild type. Cytochrome b-566 could not be detected in low-temperature spectra after reduction with various substrates or dithionite. A b-558 is, however, present.

3. The b-cytochromes in the mutant are not reduced by NADH or succinate during the steady state even after addition of ubiquinone-1. QH₂-3: cytochrome c reductase activity is very low and succinate oxidation is highly stimulated by phenazine methosulphate.

4. Antimycin does not bind to either oxidized or reduced mitochondrial particles of the mutant.

5. In contrast to the b-cytochromes of the wild type, b-558 in the mutant reacts with CO.

6. Cytochromes aa₃, c and c₁ are partly reduced in aerated submitochondrial particles isolated from the mutant and the EPR signal of Cu (II), measured at 35°K, is detectable only after the addition of ferricyanide. In the mutant, a signal with a trough at g = 2.01 is found, in addition to the signal at g = 1.98 found in the wild type.

7. The ATPase activity of particles isolated from the mutant is much lower than in the wild type but is still inhibited by oligomycin.     

Photooxidation of the cytochrome b-559 in the presence of various substituted 2-anilinothiophenes and of some other compounds, in Chlamydomonas reinhardtii

Five substituted 2-anilinothiophenes and two substituted carbonylcyanide-phenylhydrazones were comparatively studied with respect to their capacities for inducing photooxidation of the cytochrome b-559 in chloroplast fragments and in whole cells of Chlamydomonas reinhardtii (wild type and P-700-lacking mutant Fl 5). In addition, some other compounds: antimycin A, picric acid, tetraphenylboron and NH4Cl were also tested. Cytochrome b-559 photooxidations were clearly observed in the presence of 2-(3-chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene (ANT 2p), 2-(3,4,5-trichloro)anilino-3,5-dinitrothiophene (ANT 2s), 2-(4-chloro)anilino-3,5-dinitrothiophene and, with greater amplitudes, in the presence of carbonylcyanide-p-trifluoromethoxyphenylhydrazone and carbonylcyanide-m-chlorophenylhydrazone, both in whole cells and in chloroplast fragments. Picric acid, antimycin A and tetraphenylboron were also able to induce cytochrome b-559 photooxidation in chloroplast fragments, but not in whole cells. In the wild type, the highest photoinduced redox changes were 1.1 (carbonylcyanide-p-trifluoromethoxyphenylhydrazone, carbonylcyanide-m-chlorophenyl-hydrazone) and 0.6 (ANT 2p, ANT 2s) mumol of oxidized cytochrome b-559/1 mmol of chlorophyll, corresponding to 40% and 23% of the redox changes which could be induced chemically. All these cytochrome b-559 photooxidations, the greater part of which was inhibited by 3-(3,4-dichloropheny)-1,1-dimethylurea and occurred in the mutant Fl 5, appeared to be mainly Photosystem II-dependent reactions. But 3-(3,4-dichlorophenyl)-1,1-dimethylurea-insensitive Photosystem I-dependent photooxidations of cytochrome b-559 occurred also in the wild type. On the other hand, 2-(4-dimethylamine)-anilino-3,5-dinitrothiophene, 2-N-methyl-(3-chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene and NH4Cl did not induce any cytochrome b-559 photooxidation. These results were discussed taking in consideration the nature of the molecular substitutions of the various tested substances and their respective acceleration of the deactivation reactions of the water-splitting enzyme system Y of photosynthesis capacities which had been defined elsewhere by Renger (Renger, G. (1972) Biochim. Biophys. Acta 256, 428-439) for spinach chloroplasts. Like the acceleration of the deactivation reactions of the water-splitting enzyme system Y effect, the capacity for inducing the cytochrome b-559 photooxidation appeared dependent on the acidity of the NH group and on the number of halogenous substituents in the aromatic ring of the molecule. The greatest action towards cytochrome b-559 photooxidation was obtained with the most active acceleration of the deactivation reactions of the water-splitting enzyme system Y agents: carbonylcyanide-p-trifluoromethoxyphenylhydrazone, ANT 2p and ANT 2s.     

Genetic Evidence for the Action of Oxathiin and Thiazole Derivatives on the Succinic Dehydrogenase System of Ustilago maydis Mitochondria

The inhibitory effect of fungitoxic derivatives of 1,4-oxathiin on substrate oxidation by the basidiomycete Ustilago maydis is diminished by a single-gene mutation (oxr). The difference between mutant and wild type is approximately the same on the basis of inhibition of either growth and operation of the tricarboxylic acid cycle in intact cells or succinate-driven reduction of ferricyanide by mitochondrial preparations. The mutation affects the behavior of the succinic dehydrogenase system of mitochondria not only in the presence but also in the absence of the toxicant, from which it is concluded that some component of the system itself has been modified. The malonate and the antimycin A sensitivity of the oxr mutant is similar to that of the wild type but cross-resistance to thiazole derivatives is easily demonstrated.     

Extrachromosomal inheritance in Schizosaccharomyces pombe. I. Evidence for an extrakaryotically inherited mutation conferring resistance to antimycin.

In crosses of [ANTr8] with auxotrophic strains, resistance to antimycin segregates almost 50:50 in random spore analysis with a slight preponderance for the sensitivity allele. Tetrad analysis, however, shows all possible types of tetrads (2:2; 3:1; 1:3; 4:0; 0:4 resistant versus sensitive) with an excess of 2:2 segregations and sectoring of colonies on antimycin medium indicating an extrachromosomal mode of inheritance. The overall ratio of resistant versus sensitive spores is the same as compared with random spore data. Using a mutant blocked in meiosis (mei 1) mitotic segregation of stable diploids is achieved, leading to a ratio of 20% resistant to 80% sensitive clones. Possible reasons for the bias in transmission of the resistance determinant is discussed.     

The respiratory chain of Paramecium tetraurelia in wild type and the mutant Cl1. I. Spectral properties and redox potentials.

1. Purified mitochondria have been prepared from wild type Paramecium tetraurelia and from the mutant Cl1 which lacks cytochrome aa3. Both mitochondrial preparations are characterized by cyanide insensitivity. Their spectral properties and their redox potentials have been studied. 2. Difference spectra (dithionite reduced minus oxidized) of mitochondria from wild type P. tetraurelia at 77 K revealed the alpha peaks of b-type cytochrome (s) at 553 and 557 nm, of c-type cytochrome at 549 nm and a-type cytochrome at 608 nm. Two alpha peaks at 549 and 545 nm could be distinguished in the isolated cytochrome c at 77 K. After cytochrome c extraction from wild type mitochondria, a new peak at 551 nm was unmasked, probably belonging to cytochdrome c1. The a-type cytochrome was characterized by a split Soret band with maxima at 441 and 450 nm. The mitochondria of the mutant Cl1 in exponential phase of growth differed from the wild type mitochondria in that cytochrome aa3 was absent while twice the quantity of cytochrome b was present. In stationary phase, mitochondria of the mutant were characterized by a new absorption peak at 590 nm. 3. Cytochrome aa3 was present at a concentration of 0.3 nmol/mg protein in wild type mitochondria and ubiquinone at a concentration of 8 nmol/mg protein both in mitochondria of the wild type and the mutant Cl1. Cytochrome aa3 was more susceptible to heat than cytochromes b and c,c1.     

Studies on the mechanism of electron transport in the bc1-segment of the respiratory chain in yeast. II. The binding of antimycin to mitochondrial particles and the function of two different binding sites.

1. In mitochondrial particles antimycin binds to two separate specific sites with dissociation constants KD1 less than 4 - 10(-13) M and KD2 = 3 - 10(-9) M, respectively. 2. The concentrations of the two antimycin binding sites are about equal. The absolute concentration for each binding site is about 100 - 150 pmol per mg of mitochondrial protein. 3. Antimycin bound to the stronger site mainly inhibits NADH-and succinate oxidase. Binding of antimycin to the weaker binding site inhibits the electron flux to exogenously added cytochrome c after blocking cytochrome oxidase by KCN. 4. Under certain conditions cytochrome b and c1 are dispensible components for antimycin-sensitive electron transport. 5. A model of the respiratory chain in yeast is proposed which accounts for the results reported here and previously. (Lang, B., Burger, G., and Bandlow, W. (1974) Biochim. Biophys. Acta 368, 71-85).     

Mucidin resistance in yeast. Isolation, characterization and genetic analysis of nuclear and mitochondrial mucidin-resistant mutants of Saccharomyces cerevisiae.

Mutants of Saccharomyces cerevisiae resistant to the antibiotic mucidin, a specific inhibitor of electron transport between cytochrome b and c, were isolated and divided into three phenotypic groups, as follows. Class 1 mutants were cross-resistant to a variety of mitochondrial inhibitors and exhibited no resistance at the mitochondrial level. Class 2 mutants were specifically resistant to mucidin exhibiting resistance also at the level of isolated mitochondria. Biochemical studies indicated that the mucidin resistance in class 2 mutants involved a modification of mucidin binding of inhibitory sites on the mitochondrial inner membrane without a significance change in the sensitivity of mitochondrial oxygen uptake to antimycin A, 2-heptyl-4-hydroxyquinoline-N-oxide, and 2,3-dimercaptopropanol. Class 3 was represented by a mutant which showed a high degree of resistance to mucidin and was cross-resistant to a variety of mitochondrial inhibitors at the cellular level but exhibited only a resistance to mucidin at the mitochondrial level. Genetic analysis of mucidin-resistant mutants revealed the presence of both nuclear and mitochondrial genes determining mucidin resistance/sensitivity in yeast. Resistance to mucidin in class 1 mutants was due to a single-gene nuclear recessive mutation (mucPR) whereas that in class 2 mutants was caused by mutations of mitochondrial genes. Resistance in class 3 mutant was determined both by single-gene nuclear and mitochondrial mutations. In the mitochondrial mutants the mucidin resistance segregated mitotically and the resistance determinant was lost upon induction of petite mutation by ethidium bromide. Allelism tests indicated that the mucidin resistance mutations fell into two genetic loci (MUC1 and MUC2) which were apparently not closely linked in the mitochondrial genome. Recombination studies showed that the two mitochondrial mucidin loci were not allelic with other mitochondrial loci RIB1, RIB2 and OLI1. An extremely high mucidin resistance at the cellular level was shown to arise from synergistic interaction of the nuclear gene mucPR and the mitochondrial mucidin-resistance gene (MR) in a cell. The results suggest that at least two mitochondrial gene products, responsible for mucidin resistance/sensitivity in yeast, take part in the formation of the cytochrome bc1 region of the mitochondrial respiratory chain.     

Genetic control of mitotic crossing-over in yeasts. III. Induction by 8-methoxypsoralen and long-wave UV irradiation (lambda=365 nm)

The lethal effect of 8-methoxypsoralen (8-MOP) plus 365 nm light has been studied in haploid radiosensitive strains of Saccharomyces cerevisiae. The diploid of wild type and the diploid homozygous for the rad2 mutation (this mutation blocks the excision of UV-induced pyrimidine dimers) were more resistant to the lethal effect of 8-MOP plus 365 nm light than the haploid of wild type and rad2 haploid, respectively. The diploid homozygous for rad54 mutation (the mutation blocks the repair of double-strand breaks in DNA) was more sensitive than haploid rad54. The method of repeated irradiation allowed to study the capacity of radiosensitive diploids to remove monoadducts induced by 8-MOP in DNA. This process was very effective in diploids of wild type and in the rad54 rad54 diploid, while the rad2 rad2 diploid was characterized by nearly complete absence of monoadduct excision. The study of mitotic crossing over and mitotic segregation in yeast diploids, containing a pair of complementing alleles of the ade2 gene (red/pink) has shown a very high recombinogenic effect of 8-MOP plus 365 nm light. The rad2 mutation slightly increased the frequency of mitotic segregation and mitotic crossing over. The rad54 mutation decreased the frequency of mitotic segregation and entirely suppressed mitotic crossing over. The method of repeated irradiation showed that the cross-links, but not monoadducts, are the main cause of high recombinogenic effect of 8-MOP plus 365 nm light. The possible participation of different repair systems in recombinational processes induced by 8-MOP in yeast cells is discussed.     

Single point mutations in domain II of the yeast mitochondrial release factor mRF-1 affect ribosome binding.

We have recently described two yeast strains that are mutated in the MRF1 gene encoding the mitochondrial release factor mRF-1. Both mutants provoke gene-specific defects in mitochondrial translational termination. In the present study we report the cloning, sequencing, as well as an analysis of residual activities of both mutant mrf1 alleles. Each allele specifies a different single amino acid substitution located one amino acid apart. The amino acid changes do not affect the level or cellular localization of the mutant proteins, since equal amounts of wild type and mutant mRF-1 were detected in the mitochondrial compartment. Over-expression of the mutant alleles in wild type and mrf1 mutant yeast strains produces a phenotype consistent with a reduced affinity of the mutant release factors for the ribosome, indicating that the mutations map in a release factor domain involved in ribosome binding. We also demonstrate that nonsense suppression caused by a mutation in the mitochondrial homolog of the E. coli small ribosomal protein S4 can be reversed by a slight over-expression of the MRF1 gene.     

Polyacrylamide gel electrophoresis of intact bacteriophage T4D particles.

A method for the electrophoresis of intact bacteriophage T4D particles through polyacrylamide gels has been developed. It was found that phage particles will migrate through dilute polyacrylamide gels (less than 2.1%) in the presence of a low concentration of MgCl2. As few as 5 x 10(9) phage particles can be seen directly as a light-scattering band during the course of electrophoresis. The band can also be detected by scanning gels at 260 to 265 nm or by eluting viable phage particles from gel slices. A new mutant (eph1) has been identified on the basis of its decreased electrophoretic mobility compared with that of the wild type; mutant particles migrated 14% slower than the wild type particles at pH 8.3 and 35% slower at pH 5.0. The isoelectric points of both the wild type and eph1 mutant were found to be between pH 4.0 and 5.0. Particles of T4 with different head lengths were also studied. Petite particles (heads 20% shorter than normal) migrated at the same rate as normal-size particles. Giant particles, heterogenous with respect to head length (two to nine times normal), migrated faster than normal-size particles as a diffuse band. This diffuseness was due to separation within the band of particles having mobilities ranging from 8 to 35% faster than those of normal-size particles. These observations extend the useful range of polyacrylamide gel electrophoresis to include much larger particles than have previously been studied, including most viruses.