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.     

Molecular events during the release of delta-aminolevulinate dehydratase from catabolite repression.

Transfer of exponential-phase cells of Saccharomyces cerevisiae, previously grown in 2% glucose, to a derepression medium resulted in a prompt increase in the level of delta-aminolevulinate dehydratase, the rate-limiting enzyme of heme biosynthesis under these conditions. This derepression exhibited a lag of 35 min at 23 degrees C and required the participation of both RNA and protein syntheses. Dissection of the molecular events during this lag period disclosed that RNA synthesis, rnal gene function (messenger RNA transport from nucleus to cytosol), and initiation of protein synthesis were completed within less than 10, 18, and 24 min, respectively. The potential regulation of derepression by mitochondrial gene products and mitochondrial function was probed by means of a series of isogenic, respiration-deficient (rho-, pet-, and mit-) mutants; no such regulation was found.     

Yeast cells lacking the mitochondrial gene encoding the ATP synthase subunit 6 exhibit a selective loss of complex IV and unusual mitochondrial morphology

Atp6p is an essential subunit of the ATP synthase proton translocating domain, which is encoded by the mitochondrial DNA (mtDNA) in yeast. We have replaced the coding sequence of Atp6p gene with the non-respiratory genetic marker ARG8m. Due to the presence of ARG8m, accumulation of rho-/rho0 petites issued from large deletions in mtDNA could be restricted to 20-30% by growing the atp6 mutant in media lacking arginine. This moderate mtDNA instability created favorable conditions to investigate the consequences of a specific lack in Atp6p. Interestingly, in addition to the expected loss of ATP synthase activity, the cytochrome c oxidase respiratory enzyme steady-state level was found to be extremely low (<5%) in the atp6 mutant. We show that the cytochrome c oxidase-poor accumulation was caused by a failure in the synthesis of one of its mtDNA-encoded subunits, Cox1p, indicating that, in yeast mitochondria, Cox1p synthesis is a key target for cytochrome c oxidase abundance regulation in relation to the ATP synthase activity. We provide direct evidence showing that in the absence of Atp6p the remaining subunits of the ATP synthase can still assemble. Mitochondrial cristae were detected in the atp6 mutant, showing that neither Atp6p nor the ATP synthase activity is critical for their formation. However, the atp6 mutant exhibited unusual mitochondrial structure and distribution anomalies, presumably caused by a strong delay in inner membrane fusion.     

Isolation and preliminary characterisation of twenty-five temperature-sensitive mutants of mouse cytomegalovirus

Abstract To study the pathogenicity of mouse cytomegalovirus (MCMV) and to identify virulence determinants, we have isolated and phenotypically characterised 25 temperature-sensitive ( ts ) mutants. Six of these ( tsm 9, tsm 13, tsm 20, tsm 22, tsm 28 and tsm 30) failed to replicate in mice and were avirulent. Five mutants ( tsm 14, tsm 18, tsm 19, tsm 25 and tsm27 ) were to similar virulence to the parenthal wild-type ( wt ) virus, five ( tsm 7, tsm 15, tsm 24, tsm31 ) were 12–100 fold less virulent, five ( tsm 8, tsm 12, tsm 16, tsm 23 and tsm 29) were 150–1500 fold less virulent and four ( tsm 10, tsm 11, tsm 17 and tsm 21) were between 2,000 and 85,000 fold less virulent than wt . One mutant ( tsm 28) did not plaque or replicate at 39°C while 5 other mutants ( tsm 7, tsm 9, tsm 23, tsm 24 and tsm 27) also failed to plaque at 39°C but only failed to replicate or replicated poorly at 40°C. A further two mutants ( tsm 10 and tsm 13) were able to plaque and replicate at 39°C but not 40°C. Six other mutants ( tsm 14, tsm 15, tsm 16, tsm21 , tsm 22 and tsm 30) failed to form plaques at 40°C and were severely restricted in their replication at 40°C. The remaining 11 mutants exhibited varying degrees of restriction in ability to plaque and/or replicate at non-permissive temperatures. These 25 mutants, together with 6 isolated previously, comprise at least 24 complementation groups.     

Temperature-sensitive mutant rho-115 rho-RNA binary complexes, and stabilization by substrates and analogues

Summary To determine the molecular basis for the temperature-sensitivity of pure rho RNA-dependent ATPase from Escherichia coli mutant rho-115 cells, we investigated mutant rho binding to [³H] polyC as measured by retention on nitrocellulose filters. Complexes of wild-type rho and polyC incubated at 37°C and 45°C were similarly stable. At 37°C mutant rho-polyC binary complexes were inactivated at a slightly faster rate than complexes with wild-type rho. Upon shift to 45°C the quantity of rho-115 bound to polyC declined immediately, resulting in one-fifth of the quantity of complexes observed at 37°C. Shift back to 37°C restored the level of observed complexes by two-fold. The inclusion of ATP or the analogue - methylene ATP during 45°C incubation resulted in stable mutant rho-polyC complexes. The hydrolysis product ADP was also effective in stabilizing binary complexes at 45°C but this effect was observed with an order of magnitude more ADP than ATP. Adenine, adenosine, AMP or P_i had no stabilizing effect. We conclude that the mutant rho-115 protein exhibits a structural instability as a result of binding RNA. Furthermore ATP confers a wild-type phenotype upon rho-115 protein, probably as a result of conformational change due to binding of this compound. The effect of ATP on the stability of mutant rho-polyC binary complexes supports the model of ATP modulation of rho-RNA interaction proposed by Galluppi and Richardson (1980).     

The Saccharomyces cerevisiae ATP22 gene codes for the mitochondrial ATPase subunit 6-specific translation factor

Mutations in the Saccharomyces cerevisiae ATP22 gene were previously shown to block assembly of the F0 component of the mitochondrial proton-translocating ATPase. Further inquiries into the function of Atp22p have revealed that it is essential for translation of subunit 6 of the mitochondrial ATPase. The mutant phenotype can be partially rescued by the presence in the same cell of wild-type mitochondrial DNA and a rho- deletion genome in which the 5'-UTR, first exon, and first intron of COX1 are fused to the fourth codon of ATP6. The COX1/ATP6 gene is transcribed and processed to the mature mRNA by splicing of the COX1 intron from the precursor. The hybrid protein translated from the novel mRNA is proteolytically cleaved at the normal site between residues 10 and 11 of the subunit 6 precursor, causing the release of the polypeptide encoded by the COX1 exon. The ability of the rho- suppressor genome to express subunit 6 in an atp22 null mutant constitutes strong evidence that translation of subunit 6 depends on the interaction of Atp22p with the 5'-UTR of the ATP6 mRNA.     

Influence of defective virion core proteins on RNA maturation with an avian sarcoma virus.

The RNA of the avian sarcoma virus B77 temperature-sensitive mutant LA334 was investigated using electrophoretic analysis. The RNA from mutant virus grown at the nonpermissive temperature (42degrees C) showed a heterogeneous peak between 80 and 125S, and another at about 35S. The RNA of the mutant virus grown at the permissive temperature (35 degrees C) behaved like wild-type B77 virus RNA, exhibiting a major peak at 70S. The homology between the various RNA fractions and virus-specific DNA probe was determined, indicating that mutant virus grown at the nonpermissive temperature contains relatively large amounts of nonviral-specific RNA.     

A mutant rho ATPase from Escherichia coli that is temperature-sensitive in the presence of RNA

Summary The Escherichia coli mutant rho-115 suppresses lac operon polarity conferred by the lacZ::IS1 insertion MS319. The ATPase activity of purified rho-115 protein was maximal at 40°C, in contrast to 45°C for rho ⁺. At higher temperatures (50°C, 55°C), the fractions of activities at maximal temperature were consistently lower for rho-115 compared to rho ⁺. The 30-minute time course of rho-115 ATP hydrolysis was linear at 37°C but at 45°C the linear kinetics of hydrolysis reached a plateau between 10 and 15 minutes. The 30-minute time courses for rho ⁺ were linear at both 37°C and 45°C. The rho-115 and rho ⁺ ATPase activities were equally heat-stable during preincubation at 45°C in buffer. Inclusion of ATP during preincubation protected these rho proteins from inactivation to the same extent. The presence of polyC during preincubation protected rho ^- activity but produced substantial inactivation of rho-115 ATPase. The presence of polyU during preincubation gave similar results. Concentrations of polyC between 625 ng/ml and 100 g/ml yielded the same extent of rho-115 ATPase inactivation during preincubation at 45°C. Thermal inactivation of rho-115 ATPase by polyC was halted by shifting preincubation temperature from 45°C to 35°C, indicating that polyC-induced destabilization of rho-115 was irreversible.     

Effect of Macromolecular Synthesis on the Coordinate Morphogenesis of Polar Surface Structures in Caulobacter crescentus

The Caulobacter polar surface structures (flagella, pili, and the deoxyribonucleic acid phage phiCbK receptors), which are expressed at proximal sites of swarmer cells in a coordinate manner (Shapiro, Annu. Rev. Microbiol., 30:377-407, 1976) could be blocked by a single mutation. The mutant C. crescentus CB13 ple-801 did not form these surface structures when grown at 35 degrees C. Upon shift down to 25 degrees C, the mutant cells initiated the formation of the surface structures. When mitomycin C was added to the mutant culture upon shift down from 35 to 25 degrees C, phiCbK receptor formation was inhibited to a minimal level. Rifampin and chloramphenicol completely inhibited phiCbK receptor formation when added to the mutant culture upon shift down. Deoxyribonucleic acid as well as ribonucleic acid and protein synthesis seem to be required for the formation of phiCbK receptors. Penicillin V also inhibited phiCbK receptor formation, indicating the involvement of cell wall synthesis. When the mutant CB13 ple-801 cells were shifted down briefly from 35 to 25 degrees C and then shifted up to 35 degrees C, flagella and phiCbK receptors were formed even at 35 degrees C to different extents depending on how long the cells were incubated at 25 degrees C. This formation of the surface structures at 35 degrees C was inhibited by rifampin. From these results, it appears that translation, assembly, or localization processes for the formation of the surface structures are not temperature sensitive at 35 degrees C in the pleiotropic mutant CB13 ple-801. The syntheses of deoxyribonucleic acid and the cell wall do not appear to be temperature sensitive either, since the mutant grows normally at 35 degrees C. It is suggested that there exists a regulatory step that commits the cells to initiate the synthesis of requisite ribonucleic acid for the formation of the polar surface structures.