Correct regulation of the septation initiation network in Schizosaccharomyces pombe requires the activities of par1 and par2

In Schizosaccharomyces pombe, the initiation of cytokinesis is regulated by a septation initiation network (SIN). We previously reported that deletion of par1 and par2, two S. pombe genes encoding B' regulatory subunits of protein phosphatase 2A, causes a multiseptation phenotype, very similar to that seen in hyperactive SIN mutants. In this study, we examined the genetic interactions between par deletions and mutations in the genes encoding components of SIN and found that deletion of par1 and par2 suppressed the morphological and viability defects caused by overproduction of Byr4p and rescued a loss-of-function allele of spg1. However, par deletions could not suppress any mutations in genes downstream of spg1 in the SIN pathway. We showed further that, in suppressing the lethality of a spg1 loss-of-function allele, the correct localization of Cdc7p to the spindle pole body (SPB), which is normally lost in spg1 mutant cells, was restored. The fact that par mutant cells themselves exhibited a symmetric localization of Cdc7p to SPBs indicated a hyperactivity of SIN in such cells. On the basis of our epistasis analyses and cytological studies, we concluded that par genes normally negatively regulate SIN at or upstream of cdc7, ensuring that multiple rounds of septation do not occur.

Loss of a protein phosphatase 2A regulatory subunit (Cdc55p) elicits improper regulation of Swe1p degradation

CDC55 encodes a Saccharomyces cerevisiae protein phosphatase 2A (PP2A) regulatory subunit. cdc55-null cells growing at low temperature exhibit a failure of cytokinesis and produce abnormally elongated buds, but cdc55-null cells producing the cyclin-dependent kinase Cdc28-Y19F, which is unable to be inhibited by Y19 phosphorylation, show a loss of the abnormal morphology. Furthermore, cdc55-null cells exhibit a hyperphosphorylation of Y19. For these reasons, we have examined in wild-type and cdc55-null cells the levels and activities of the kinase (Swe1p) and phosphatase (Mih1p) that normally regulate the extent of Cdc28 Y19 phosphorylation. We find that Mih1p levels are comparable in the two strains, and an estimate of the in vivo and in vitro phosphatase activity of this enzyme in the two cell types indicates no marked differences. By contrast, while Swe1p levels are similar in unsynchronized and S-phase-arrested wild-type and cdc55-null cells, Swe1 kinase is found at elevated levels in mitosis-arrested cdc55-null cells. This excess Swe1p in cdc55-null cells is the result of ectopic stabilization of this protein during G(2) and M, thereby accounting for the accumulation of Swe1p in mitosis-arrested cells. We also present evidence indicating that, in cdc55-null cells, misregulated PP2A phosphatase activity is the cause of both the ectopic stabilization of Swe1p and the production of the morphologically abnormal phenotype.

In organello formaldehyde crosslinking of proteins to mtDNA: identification of bifunctional proteins

The segregating unit of mtDNA is a protein-DNA complex called the nucleoid. In an effort to understand how nucleoid proteins contribute to mtDNA organization and inheritance, we have developed an in organello formaldehyde crosslinking procedure to identify proteins associated with mtDNA. Using highly purified mitochondria, we observed a time-dependent crosslinking of protein to mtDNA as determined by sedimentation through isopycnic cesium chloride gradients. We detected approximately 20 proteins crosslinked to mtDNA and identified 11, mostly by mass spectrometry. Among them is Abf2p, an abundant, high-mobility group protein that is known to function in nucleoid morphology, and in mtDNA transactions. In addition to several other proteins with known DNA binding properties or that function in mtDNA maintenance, we identified other mtDNA-associated proteins that were not anticipated, such as the molecular chaperone Hsp60p and a Krebs cycle protein, Kgd2p. Genetic experiments indicate that hsp60-ts mutants have a petite-inducing phenotype at the permissive temperature and that a kgd2Delta mutation increases the petite-inducing phenotype of an abf2Delta mutation. Crosslinking and DNA gel shift experiments show that Hsp60p binds to single-stranded DNA with high specificity for the template strand of a putative origin of mtDNA replication. These data identify bifunctional proteins that participate in the stability of rho(+) mtDNA.

Isolation and characterization of par1(+) and par2(+): two Schizosaccharomyces pombe genes encoding B' subunits of protein phosphatase 2A

Protein phosphatase 2A (PP2A) is one of the major serine/threonine phosphatases found in eukaryotic cells. We cloned two genes, par1(+) and par2(+), encoding distinct B' subunits of PP2A in fission yeast. They share 52% identity at the amino acid sequence level. Neither gene is essential but together they are required for normal septum positioning and cytokinesis, for growth at both high and low temperature, and for growth under a number of stressful conditions. Immunofluorescence microscopy revealed that Par2p has a cell-cycle-related localization pattern, being localized at cell ends during interphase and forming a medial ring in cells that are undergoing septation and cytokinesis. Our analyses also indicate that Par1p is more abundant than Par2p in the cell. Cross-organism studies showed that both par1(+) and par2(+) could complement the rts1Delta allele in Saccharomyces cerevisiae, albeit to different extents, in spite of the fact that neither contains a serine/threonine-rich N-terminal domain like that found in the S. cerevisiae homolog Rts1p. Thus, while Schizosaccharomyces pombe is more similar to higher eukaryotes with respect to its complement of B'-encoding genes, the function of those proteins is conserved relative to that of Rts1p.

Translational thermotolerance in Saccharomyces cerevisiae

While protein synthesis is rapidly inactivated in Saccharomyces cerevisiae, cells shifted from log growth at 30 degrees C to 43 degrees C, a 1-h 37 degrees C treatment given to cells just prior to the shift to 43 degrees C partially blocks this inactivation. By contrast, such a pre-heat shock treatment has no protective effect on translational inactivation at 45 degrees C or higher. Cells allowed to approach stationary phase not only develop an enhanced thermotolerance relative to log cells but also exhibit a pronounced resistance to inactivation of protein synthesis at 43 degrees C as well as at 45 degrees C. We have found that this 'translational thermotolerance' can also be induced in S. cerevisiae by briefly treating log phase cells at 30 degrees C with cycloheximide. Using such a procedure to induce stabilization of protein synthesis at 43 degrees C, we have been able to show that heat shock-induced proteins are not responsible for the establishment of this protective effect. This work shows that enhanced thermotolerance can be induced in log cells even after a shift to 43 degrees C, as long as a prior translational thermotolerance has been established. Furthermore, we show that the capacity of plateau cells to maintain translation at 43 degrees C contributes significantly to their state of enhanced thermotolerance.

SCS1, a multicopy suppressor of hsp60-ts mutant alleles, does not encode a mitochondrially targeted protein

We identified and isolated a Saccharomyces cerevisiae gene which, when overexpressed, suppressed the temperature-sensitive phenotype of cells expressing a mutant allele of the gene encoding the mitochondrial chaperonin, Hsp60. This gene, SCS1 (suppressor of chaperonin sixty-1), encodes a 757-amino-acid protein of as yet unknown function which, nonetheless, has human, rice, and Caenorhabditis elegans homologs with high degrees (ca. 60%) of amino acid sequence identity. SCS1 is not an essential gene, but SCS1-null strains do not grow above 37 degrees C and show some growth-related defects at 30 degrees C as well. This gene is expressed at both 30 and 38 degrees C, producing little or no differences in mRNA levels at these two temperatures. Overexpression of SCS1 could not complement an HSP60-null allele, indicating that suppression was not due to the bypassing of Hsp60 activity. Of 10 other hsp60-ts alleles tested, five could also be suppressed by SCS1 overexpression. There were no common mutant phenotypes of the strains expressing these alleles that give any clue as to why they were suppressible while others were not. An epitope (influenza virus hemagglutinin)-tagged form of SCS1 in single copy complemented an SCS1-null allele. The Scs1-hemagglutinin protein was found to be at comparable levels and in similar multiply modified forms in cells growing at both 30 and 38 degrees C. Surprisingly, when localized either by cell fractionation procedures or by immunocytochemistry, these proteins were found not in mitochondria but in the cytosol. The overexpression of SCS1 had significant effects on the cellular levels of mRNAs encoding the proteins Cpn10 and Mgel, two other mitochondrial protein cochaperones, but not on mRNAs encoding a number of other mitochondrial or cytosolic proteins analyzed. The implications of these findings are discussed.

Requirement of a small cytoplasmic RNA for the establishment of thermotolerance

Thermotolerance is an inducible state that endows cells with an enhanced resistance to thermal killing. Heat shock proteins are believed, and in a few instances have been shown, to be the agents conferring this resistance. The role of a small cytoplasmic RNA (G8 RNA) in developing thermotolerance in Tetrahymena thermophila was investigated by creating a strain devoid of all functional G8 genes. These G8 null cells mounted an apparently normal heat shock response, but they were unable to establish thermotolerance.

Loss of mitochondrial hsp60 function: nonequivalent effects on matrix-targeted and intermembrane-targeted proteins

We have created yeast strains in which the mitochondrial chaperonin, hsp60, can be either physically depleted or functionally inactivated. Cells completely depleted of hsp60 stop growing but retain for awhile the capacity to reaccumulate hsp60. While this newly made hsp60 is targeted to and processed correctly within the mitochondrion, assembly of a functional hsp60 complex does not occur. Rather, the hsp60 monomers are localized in different-size soluble complexes containing another mitochondrial chaperone, the mitochondrial form of hsp70. A number of other mitochondrial matrix-targeted proteins synthesized in the absence of functional hsp60 are imported into mitochondria but often show some buildup of precursor forms and, unlike hsp60, accumulate as insoluble aggregates. By contrast, several mitochondrial proteins normally targeted to the intermembrane space show normal processing in the complete absence of a functional hsp60 complex. Similar and complementary results were obtained when we examined the metabolism of matrix- and intermembrane space-localized proteins in cells expressing three different temperature-sensitive alleles of HSP60. In all cases, matrix-targeted proteins synthesized at nonpermissive (i.e., hsp60-inactivating) temperatures were correctly targeted to and processed within mitochondria but accumulated predominantly or totally as insoluble aggregates. The metabolism of two intermembrane space proteins, cytochrome b2 and cytochrome c1, was unaffected at the nonpermissive temperature, as judged by the correct processing and complete solubility of newly synthesized forms of both proteins. These findings are discussed with regard to current models of intermembrane targeting.

Cytochromes c1 and b2 are sorted to the intermembrane space of yeast mitochondria by a stop-transfer mechanism

The pathway by which cytochromes c1 and b2 reach the mitochondrial intermembrane space has been controversial. According to the "conservative sorting" hypothesis, these proteins are first imported across both outer and inner membranes into the matrix, and then are retranslocated across the inner membrane. Our data argue against this model: import intermediates of cytochromes c1 and b2 were found only outside the inner membrane; maturation of these proteins was independent of the matrix-localized hsp60 chaperone; and dihydrofolate reductase linked to the presequence of either cytochrome was imported to the intermembrane space in the absence of ATP. We conclude that cytochromes c1 and b2 are sorted by a mechanism in which translocation through the inner membrane is arrested by a "stop-transfer" signal in the presequence. The arrested intermediates may be associated with a proteinaceous channel in the inner membrane.

Function of the maize mitochondrial chaperonin hsp60: specific association between hsp60 and newly synthesized F1-ATPase alpha subunits

Mitochondria contain a protein, hsp60, that is induced by heat shock and has been shown to function as a chaperonin in the assembly of mitochondrial enzyme complexes composed of proteins encoded by nuclear genes and imported from the cytosol. To determine whether products of mitochondrial genes are also assembled through an interaction with hsp60, we looked for association between hsp60 and proteins synthesized by isolated mitochondria. We have determined by electrophoretic, centrifugal, and immunological assays that at least two of those proteins become physically associated with hsp60. In mitochondrial matrix extracts, this association could be disrupted by the addition of Mg-ATP. One of the proteins that formed a stable association with hsp60 was the alpha subunit of the multicomponent complex F1-ATPase. We have not identified the other protein. These results indicate that hsp60 can function in the folding and assembly of mitochondrial proteins encoded by both mitochondrial and nuclear genes.

A mitochondrial chaperonin: genetic, biochemical, and molecular characteristics

Mitochondria contain a matrix-localized protein complex composed of subunits homologous to the E.coli protein groEL. As with groEL in E.coli, the nuclear gene coding for the mitochondrial protein is essential for cell survival and the accumulation of the protein is elevated at heat shock-inducing temperatures. Biochemical analyses of wild type and mutant yeast strains have shown that this protein, hsp60, is required for the correct folding and assembly of newly imported, mitochondrially-targeted proteins. There is evidence suggesting a mandatory interaction between hsp60 and many imported, as well as mitochondrially-synthesized, proteins. The implications of these and other data are discussed.

Identification and metabolic characterization of the Zea mays mitochondrial homolog of the Escherichia coli groEL protein

We have characterized an abundant mitochondrial protein from Zea mays and have shown it to be structurally and metabolically indistinguishable from a previously described Tetrahymena thermophila and Saccharomyces cerevisiae mitochondrial protein, referred to as hsp60, which is homologous to the groEL protein of Escherichia coli. This Z. mays protein, which we also refer to as hsp60, was found to be antigenically quite distinct from the chloroplast Rubisco-binding protein, another groEL homolog. Using an antiserum directed against the T. thermophila hsp60, we determined that the relative concentration of Z. mays hsp60 was two to four times higher in mitochondria isolated from tissues of early developmental stages than that found in mitochondria isolated from more adult tissues. Given the known and suggested roles of the other members of the groEL family of proteins, our results suggest that the Z. mays hsp60 may play an important role in mitochondrial biogenesis during early plant development.

Identification of a cDNA coding for the SerH3 surface protein of Tetrahymena thermophila

We have identified a Tetrahymena thermophila cDNA-containing plasmid (pC6) which hybridizes to a 1.47-kB RNA whose changes in cellular concentration parallel the changes in synthetic rate of a major cell surface protein. From a molecular and genetic analysis of strains expressing the gene (SerH3) encoding this protein, and of strains expressing immunologically distinct alleles of this gene, we conclude that pC6 encodes a portion of the SerH3 allele.

Mitochondrial heat-shock protein hsp60 is essential for assembly of proteins imported into yeast mitochondria

A nuclear encoded mitochondrial heat-shock protein hsp60 is required for the assembly into oligomeric complexes of proteins imported into the mitochondrial matrix. hsp60 is a member of the 'chaperonin' class of protein factors, which include the Escherichia coli groEL protein and the Rubisco subunit-binding protein of chloroplasts.

Characterization of the yeast HSP60 gene coding for a mitochondrial assembly factor

The hsp60 protein isolated from the protozoan Tetrahymena thermophila is induced in response to heat stress and is a member of an immunologically conserved family represented in Escherichia coli and in mitochondria of plants and animals. We report here the cloning and characterization of a nuclear gene, HSP60, which codes for the hsp60 homologue from the yeast Saccharomyces cerevisiae. Nucleotide sequence analysis revealed that yeast hsp60 is related to the groEL protein of E. coli and the RUBISCO-binding protein (RBP) of chloroplasts. HSP60 was found to be the genetic locus of the conditional-lethal mutation described by Cheng et al., which at non-permissive temperature is defective in the assembly of several different multisubunit complexes in mitochondria. These data are consistent with the hypothesis that the groEL-related proteins serve an evolutionarily conserved function as accessory factors facilitating the folding and/or association of individual subunits of multimeric protein complexes.

A highly evolutionarily conserved mitochondrial protein is structurally related to the protein encoded by the Escherichia coli groEL gene

We recently reported that a Tetrahymena thermophila 58-kilodalton (kDa) mitochondrial protein (hsp58) was selectively synthesized during heat shock. In this study, we show that hsp58 displayed antigenic similarity with mitochondrially associated proteins from Saccharomyces cerevisiae (64 kDa), Xenopus laevis (60 kDa), Zea mays (62 kDa), and human cells (59 kDa). Furthermore, a 58-kDa protein from Escherichia coli also exhibited antigenic cross-reactivity to an antiserum directed against the T. thermophila mitochondrial protein. The proteins from S. cerevisiae and E. coli antigenically related to hsp58 were studied in detail and found to share several other characteristics with hsp58, including heat inducibility and the property of associating into distinct oligomeric complexes. The T. thermophila, S. cerevisiae, and E. coli macromolecular complexes containing these related proteins had similar sedimentation characteristics and virtually identical morphologies as seen with the electron microscope. The distinctive properties of the E. coli homolog to T. thermophila hsp58 indicate that it is most likely the product of the groEL gene.

A normal mitochondrial protein is selectively synthesized and accumulated during heat shock in Tetrahymena thermophila

We have identified and purified a 58-kilodalton protein of Tetrahymena thermophila whose synthesis during heat shock parallels that of the major heat shock proteins. This protein, hsp58, was found in both non-heat-shocked as well as heat-shocked cells; however, its concentration in the cell increased approximately two- to threefold during heat shock. The majority of hsp58 in both non-heat-shocked and heat-shocked cells was found by both cell fractionation studies and immunocytochemical techniques to be mitochondrially associated. During heat shock, the additional hsp58 was found to selectively accumulate in mitochondria. Nondenatured hsp58 released from mitochondria of non-heat-shocked or heat-shocked cells sedimented in sucrose gradients as a 20S to 25S complex. We suggest that this protein may play a role in mitochondria analogous to the role the major heat shock proteins play in the nucleus and cytosol.

A heat shock-induced, polymerase III-transcribed RNA selectively associates with polysomal ribosomes in Tetrahymena thermophila

Tetrahymena thermophila cells, subjected to a heat shock-inducing temperature, manifest a number of translationally regulated changes during the course of a continuous heat shock treatment. One particular change, the resumption of translation of mRNAs coding for normal cellular proteins, was found to correlate with a polysomal ribosome association not found prior to heat shock. A low molecular weight RNA (ca. 270 nucleotides), whose rapid accumulation was induced by heat shock, became quantitatively associated with polysomal ribosomes during that time when normal cell protein synthesis became reestablished. We estimated that there were one or two of these RNAs per ribosome uniformly distributed throughout the polysomal ribosome population. The gene (or genes) coding for this RNA were found to be transcribed by polymerase III.

Effect of heat shock on ribosome structure: appearance of a new ribosome-associated protein

After a nonlethal but heat shock protein-inducing hyperthermic treatment, ribosomes isolated from Tetrahymena thermophila contained an additional 22-kilodalton protein (p22). When maximally ribosome associated, this protein was found to be on the small subunit in a 1:1 stoichiometric ratio with other ribosomal proteins. Using an antiserum directed against the purified 22-kilodalton protein, we found that non-heat-shocked and heat-shocked cells contain identical amounts of this protein, the only difference being that in the stressed cells p22 is entirely ribosome bound, whereas in the unstressed cells p22 has little or no detectable ribosome association. Because the two-dimensional electrophoretic properties of p22 showed no alterations after heat shock, this change in state of ribosome-p22 interaction does not appear to be caused by a chemical modification of p22. When not strongly ribosome associated, p22 is not found free in the cytoplasm. During that time in heat shock when p22 is first becoming ribosome associated, it is found preferentially on polysomal ribosomes. Subsequently, all ribosomes, whether polysome bound or not, obtain a bound p22. The functional significance of this association is discussed.

No heat shock protein synthesis is required for induced thermostabilization of translational machinery

For Tetrahymena thermophila cells to survive at 43 degrees C, a normally lethal temperature, they require a pretreatment which either elicits the synthesis of heat shock proteins or one which brings about a change in the translational machinery of the cell such that is is not inactivated when transferred to 43 degrees C. In this report I present evidence showing that the latter modification can occur in the complete absence of protein synthesis, indicating that heat shock protein production is not required for the induced thermostabilization of the translational machinery.

Induction of acquired thermotolerance in Tetrahymena thermophila: effects of protein synthesis inhibitors

When Tetrahymena thermophila cells growing at 30 degrees C are shifted to either 40 or 43 degrees C, the kinetics and extent of induction of heat shock mRNAs in both cases are virtually indistinguishable. However, the cells shifted to 40 degrees C show a typical induction of heat shock protein (HSP) synthesis and survive indefinitely (100% after 24 h), whereas those at 43 degrees C show an abortive synthesis of HSPs and die (less than 0.01% survivors) within 1 h. Cells treated at 30 degrees C with the drugs cycloheximide or emetine, at concentrations which are initially inhibitory to protein synthesis and cell growth but from which cells can eventually recover and resume growth, are after this recovery able to survive a direct shift from 30 to 43 degrees C (ca. 70% survival after 1 h). This induction of thermotolerance by these drugs is as efficient in providing thermoprotection to cells as is a prior sublethal heat treatment which elicits the synthesis of HSPs. However, during the period when drug-treated cells recover their protein synthesis ability and simultaneously acquire the ability to subsequently survive a shift to 43 degrees C, none of the major HSPs are synthesized. The ability to survive a 1-h, 43 degrees C heat treatment, therefore, does not absolutely require the prior synthesis of HSPs. But, as extended survival at 43 degrees Celsius depends absolutely on the ability of cells to continually synthesize HSPs, it appears that a prior heat shock as well as the recovery from protein synthesis inhibition elicits a change in the protein synthetic machinery which allows the translation of HSP mRNAs at what would otherwise be a nonpermissive temperature for protein synthesis.

Starved Tetrahymena thermophila cells that are unable to mount an effective heat shock response selectively degrade their rRNA

Tetrahymena thermophila cells that had been shifted from log growth to a non-nutrient medium (60 mM Tris) were unable, during the first few hours of starvation, to mount a successful heat shock response and were killed by what should normally have been a nonlethal heat shock. An examination of the protein synthetic response of these short-starved cells during heat shock revealed that whereas they were able to initiate the synthesis of heat shock proteins, it was at a much reduced rate relative to controls and they quickly lost all capacity to synthesize any proteins. Certain pretreatments of cells, including a prior heat shock, abolished the heat shock inviability of these starved cells. Also, if cells were transferred to 10 mM Tris rather than 60 mM Tris, they were not killed by the same heat treatment. We found no abnormalities in either heat shock or non-heat shock mRNA metabolism in starved cells unable to survive a sublethal heat shock when compared with the response of those cells which can survive such a treatment. However, selective rRNA degradation occurred in the nonsurviving cells during the heat shock and this presumably accounted for their inviability. A prior heat shock administered to growing cells not only immunized them against the lethality of a heat shock while starved, but also prevented rRNA degradation from occurring.

Characterization of a cycloheximide-resistant Tetrahymena thermophila mutant which also displays altered growth properties

A cycloheximide-resistant strain of Tetrahymena thermophila, expressing a mutant chx-B gene (Ares and Bruns, Genetics 90:463-474, 1978), displayed very different temperature-dependent growth characteristics than either wild-type cells or another cycloheximide-resistant strain expressing a different mutant gene. Whereas wild-type cells showed an immediate decline in ribosome translocation rates when shifted from 30 to 38 or 40 degrees C, this mutant strain (X-8) showed no such decline. These results directly correlated with the growth rate differences we found for these cells at these temperatures. By genetic analysis, we showed that the phenotype of cycloheximide resistance cosegregated with the ability to grow rapidly at 40 degrees C. Analyses, both direct and indirect, suggested that a number of functional and structural characteristics of the ribosomes from strain X-8 cells are most likely conformationally different from those of wild-type ribosomes.

Regulation of ribosome phosphorylation and antibiotic sensitivity in Tetrahymena thermophila: A correlation

Tetrahymena thermophila cells transferred from growth medium into a dilute salt (starvation) medium shortly (approximately 6-8 hrs) become more resistant to the in vivo inhibitory effects of the antibiotics cycloheximide, tetracycline and emetine. They also be come more sensitive to the inhibitory effects of paromomycin and anisomycin. By comparing ribosomes from growing and starved cells we have found that for at least two of these drugs differences between growing cell and starved cell ribosomes exist with respect to drug-ribosome interactions. In addition, we found that isolated monosomic ribosomes from starved cells are more resistant to thermal denaturation than are monosomic ribosomes from growing cells. The kinetics of all these changes following transfer of growing cells to starvation medium is the same and correlates with a change in the extent of phosphorylation of a single small subunit ribosomal protein. As judged by our in vitro assays, enzymatic removal of this phosphate converts "starved cell" ribosomes into "growing cell" ribosomes. We have extended these studies to show that the phenomenon of drug adaptation in Tetrahymena, at least with respect to cycloheximide, is associated with this ribosome phosphorylation.

Ribosome biosynthesis in Tetrahymena thermophila. IV. Regulation of ribosomal RNA synthesis in growing and growth arrested cells

Three parameters involved in the production of new ribosomal RNA (rRNA) were measured in Tetrahymena thermophilia: (i) the rate of synthesis of the rRNA precursor, (ii) the rate of processing of the RNA precursor and rRNA intermediates and (iii) the efficiency of utilization of the rRNA precursor in producing mature ribosomal RNA. These parameters were measured in cells in exponential growth and in cells starved in a dilute salt solution. Growing cells synthesize rRNA 20 times faster and process rRNA precursors and intermediates 10 to 15 times more rapidly than do starved cells. Both utilize their rRNA precursors with an efficiency of one in converting them to mature rRNA.

Ribosome biosynthesis in Tetrahymena thermophila. III. Regulation of ribosomal RNA degradation in growing and growth arrested cells

We have measured the turnover rate of ribosomal RNA in exponentially growing Tetrahymena thermophila cells, cells entering the plateau phase of growth, and nutrient-deprived (starved) cells. Ribosomal RNA is stable in cells in early log phase growth but it begins to turnover as the cells begin a deceleratory growth phase prior to entering a plateau state. Likewise, rRNA in cells transferred from early log phase growth to a starvation medium begins to be degraded immediately upon starvation. In both cases the degradation of rRNA exhibits biphasic kinetics. A rapid initial exponential degradation with a half time of nine and one-half hours lasting for six hours is followed by a slower exponential degradation with a half-life of 35 hours. When starved cells are transferred to fresh growth medium turnover of rRNA ceases. The evidence presented suggests that the alteration in degradation rate is a regulated process which is most likely independent of the cell cycle.

Cycloheximide resistance can be mediated through either ribosomal subunit

Two cycloheximide-resistant mutants of Tetrahymena thermophila were analyzed to determine the site of their cycloheximide resistance. The mutations in both strains had been previously shown to be genetically dominant and located at separate loci (denoted Chx-A and Chx-B). Strains carrying these mutations were readily distinguished by the extent to which they were resistant to the drug. The homozygous double mutant was more resistant than either single mutant. Cell-free extracts of wild type and of the three mutant strains, assayed for protein synthetic activity by both runoff of natural mRNA and poly(U)-dependent phenylalanine polymerization, demonstrated that in vitro the mutants were all more resistant than the wild type. Further fractionation of the cell-free systems into ribosomes and supernates localized cycloheximide resistance to the ribosome for both Chx-A and Chx-B homozygotes. Ribosome dissociation and pairwise subunit mixing in the in vitro system indicated that ribosome resistance was conferred by the 60S subunit from one strain whereas resistance in the other strain was mediated through the 40S subunit. This was further confirmed by reconstruction of all four cycloheximide-resistance "phenotypes" by mixing ribosomal subunits from appropriate strains. This finding suggests that the mechanisms by which these mutations confer resistance to cycloheximide are different.

Nonidentity of ribosomal structural proteins in growing and starved Tetrahymena

We have examined the ribosomal structural proteins isolated from vegetatively growing Tetrahymena pyriformis and from cells that had been starved of all nutrients for 24 h. Reproducible, nonartifactual differences in protein complement, primarily associated with the large ribosomal subunit, were found. The kinetics of change in ribosomal protein complement were followed both in refed and in newly starved cells. Furthermore, attempts at correlating a certain protein "phenotype" with a particular functional state of the ribosome were made. It was concluded that the alterations seen could not be correlated with a specific stage in the normal ribosome cycle. We did show, however, that the change in protein complement could occur as a result of altering preexisting ribosomes. In addition, we showed that the change correlates with a decrease in growth rate rather than being caused by the starvation conditions themselves. Speculations as to the functional significance of the protein changes are presented.

Ribosome biosynthesis in Tetrahymena pyriformis. Regulation in response to nutritional changes

Ribosome contents of growing and 12-h-starved Tetrahymena pyriformis (strain B) were compared. These studies indicate that (a) starved cells contain 74% of the ribosomes found in growing cells, (b) growing cells devote 20% of their protein synthetic activity to ribosomal protein production, and (c) less than 3% of the protein synthesized in starved cells is ribosomal protein. Ribosome metabolism was also studied in starved cells which had been refed. For the first 1.5 h after refeeding, there is no change in ribosome number per cell. Between 1.5 and 2 h, there is an abrupt increase in rate of ribosome accumulation but little change in rate of cell division. By 3.5 h, the number of ribosomes per cell has increased to that found in growing cells. At this time, the culture begins to grow exponentially at a normal rate. During the first 2 h after refeeding, cells devote 30-40% of their protein synthetic activity to ribosomal protein production. We estimate that the rate of ribosomal protein synthesis per cell increases at least 80-fold during the first 1-1.5 h after refeeding, reaching the level found in exponentially growing cells. This occurs before any detectable change in ribosome number per cell. The transit time for the incorporation of these newly synthesized proteins into ribosomes is from 1 to 2 h during early refeeding, whereas in exponentially growing cells it is less than 30 min. The relationship between ribosomal protein synthesis and ribosome accumulation is discussed.