DNA-dependent RNA polymerases isolated from yeast mitochondria

Purified preparations of yeast mitochondria yield three species of DNA-dependent RNA polymerases. These enzymes have been separated and purified to homogeneity for analysis of their properties and for comparison with the properties of nuclear preparations of yeast RNA polymerases. Three enzymes have been separated by DEAE-Sephadex chromatography of each fraction. Both nuclear and mitochondrial preparations yield three components with nearly identical elution properties. The distributions of enzyme activity on DEAE-Sephadex chromatography differ with the three nuclear peaks, being found in ratios (uncorrected for the effect of increasing salt concentration) of 8:85:7 and the mitochondrial peaks in ratios of 8:32:60 at late log phase of growth under optimized conditions in which protease inhibitors and an antioxidant were included. The type of mitochondrial enzymes in 3-day-old cells differed from those grown to late logarithmic phase. It has been established that the enzymes of the mitochondrial preparation are associated with the membrane fraction. While extraction with 0.5 m KCl solubilizes considerable enzyme activity, greatly enhanced yields of enzyme MIII are obtained by addition of the antioxidant 2,6-di-t-butyl-4-hydroxymethyl phenol during enzyme extraction. Inhibition of protease activity has also been shown to have a major effect on the yield and distribution of enzymes obtained from mitochondrial preparations. The mitochondrial preparations of yeast polymerases are generally similar but not identical to corresponding nuclear polymerases in subunit molecular weights, inhibitor sensitivities, and in DNA template dependence. Comparative studies of nuclear and mitochondrial polymerases clearly establish that differences do exist among the isolated enzymes of these classes. It has not been ruled out to date that these enzymes may be derived in part or in total from the same cytoplasmic subunit pool, nor has it been established that any of these enzymes function in mitochondria in vivo.     

Analysis of yeast RNA polymerases with subunit-specific antibodies

Specific antibodies directed against each polypeptide component of yeast RNA polymerases A or B were prepared and their affinity spectrum determined by protein blot immunodetection. The majority of enzyme A or B subunits were specifically recognized by their respective antiserum. A direct correspondence was established between the polypeptides immunologically related in the three forms of RNA polymerases A, B, and C by reacting the different antibodies with enzymes subunits transferred to a nitrocellulose membrane. Subunit-specific antibodies and antibodies to native enzymes A and B were used to probe the activity of RNA polymerases A, B, and C. Based on DNA protection experiments, the largest subunit of enzymes A and B as well as the common subunit ABC23 appear to be involved in DNA binding.     

Synthesis of two DNA-dependent RNA polymerases in yeast

Specific activities of Saccharomyces cerevisiae RNA polymerases I and II were measured in cells growing under different nutrient conditions and throughout the mitotic cell cycle. The specific activity of RNA polymerase I (possibly the ribosomal polymerase) does not vary during the yeast cell cycle. In contrast the specific activity of RNA polymerase II (messenger polymerase) increases during the first third of the cycle and thereafter declines. The independent regulation of synthesis of these two enzymes is further emphasised by observations on the response to different nutrient conditions. Shifting cells from minimal to rich medium led to enhanced RNA polymerase I activity but very little change in activity of RNA polymerase II. Furthermore the activity of RNA polymerase I varies directly with change in growth rate whereas the activity of RNA polymerase II is approximately constant over a range of growth rates. From this data it is suggested: (i) The synthesis of these two enzymes is independently regulated; (ii) RNA polymerase I is synthesised continuously throughout the cycle whereas RNA polymerase II is synthesised periodically early in the cell cycle.     

Localization of the yeast RNA polymerase I-specific subunits

The spatial distribution of four subunits specifically associated to the yeast DNA-dependent RNA polymerase I (RNA pol I) was studied by electron microscopy. A structural model of the native enzyme was determined by cryo-electron microscopy from isolated molecules and was compared with the atomic structure of RNA pol II Delta 4/7, which lacks the specific polypeptides. The two models were aligned and a difference map revealed four additional protein densities present in RNA pol I, which were characterized by immunolabelling. A protruding protein density named stalk was found to contain the RNA pol I-specific subunits A43 and A14. The docking with the atomic structure showed that the stalk protruded from the structure at the same site as the C-terminal domain (CTD) of the largest subunit of RNA pol II. Subunit A49 was placed on top of the clamp whereas subunit A34.5 bound at the entrance of the DNA binding cleft, where it could contact the downstream DNA. The location of the RNA pol I-specific subunits is correlated with their biological activity.     

On the phosphorylation of yeast RNA polymerases A and B

In exponentially growing cells, RNA polymerase B is exclusively form BI enzyme with several phosphorylated subunits: B220, B23 and possibly B44.5. In RNA polymerase A an average of fifteen phosphate groups are distributed on the five phosphorylated subunits: A190 (6), A43 (4), A34.5 (2), A23 (1-2) and A19 (1-2). Phosphorylation of enzyme A by a yeast protein kinase in vitro adds less than 1 mol phosphate/mol enzyme but occurs essentially at the physiological sites, as shown by a comparison of the peptide patterns obtained by limited proteolysis of subunits 32P-labelled in vivo and in vitro. No evidence was found in favor of a modulation of RNA polymerase activity in vitro or in vivo via phosphorylation.     

Two additional common subunits, ABC10 alpha and ABC10 beta, are shared by yeast RNA polymerases.

Yeast nuclear RNA polymerases are multisubunit enzymes that contain in common some small subunits. We show that the smallest, a 10-kDa component of three enzymes (A10, B10, and C10), is heterogeneous. In each case, it can be resolved into two distinct polypeptides (alpha and beta) by reverse-phase chromatography. A10 alpha, B10 alpha, and C10 alpha were indistinguishable on the basis of their electrophoretic and chromatographic behaviors, characteristic silver staining, and tryptic peptide analysis. All three polypeptides are blocked at their amino termini. By the same criteria, A10 beta, B10 beta, and C10 beta were also indistinguishable. The amino-terminal sequence of A10 beta and C10 beta corresponded to that of subunit B10 recently cloned by Woychik and Young (Woychik, N. A., and Young, R. A. (1990) J. Biol. Chem. 265, 17816-17819). Thus, the three forms of RNA polymerase share two additional and distinct polypeptides, ABC10 alpha and ABC10 beta, that therefore can be considered bona fide subunits of these enzymes. Interestingly, these two subunits bind zinc.     

Phosphorylation of yeast DNA-dependent RNA polymerases in vivo and in vitro. Isolation of enzymes and identification of phosphorylated subunits.

Yeast DNA-dependent RNA polymerases I, II, and III are phosphorylated in vivo. Yeast cells were grown continuously in 32Pi and the RNA polymerases were isolated by a new procedure which allows the simultaneous purification of these enzymes from small quantities (35 to 60 g) of cells. Each of the RNA polymerases was phosphorylated. The following phosphorylated polymerase polypeptides were identified: polymerase I subunits of 185,000, 44,000, 36,000, 24,000, and 20,000 daltons; a polymerase II subunit of 24,000 daltons; and polymerase III subunits of 24,000 and 20,000 daltons. The incorporated 32P was acid-stable but base-labile. Phosphoserine and phosphothreonine were identified after partial acid hydrolysis of purified [32P]polymerase I. A yeast protein kinase that co-purifies with polymerase I during part of the isolation procedure was partially purified and characterized. This protein kinase phosphorylates the subunits of the purified polymerases that are phosphorylated in vivo and, in addition, a polymerase I subunit of 48,000 daltons and a polymerase II subunit of 33,500 daltons. Phosphorylation of the purified enzymes with this protein kinase had no substantial effect on polymerase activity in simple assays using native yeast DNA as a template. Preincubation of purified polymerase I with acid or alkaline phosphatase also had no detectable effect on polymerase activity.