Mutational analysis of both subunits from rat mitochondrial processing peptidase.

Rat liver mitochondrial processing peptidase (MPP) is the primary peptidase that cleaves leader peptides from nuclearly encoded mitochondrial proteins following their transport from the cytosol to the mitochondrial matrix. This enzyme consists of two nonidentical subunits that have overall similarity to each other and share certain amino acid motifs. These include the putative metal-ion binding HFLEH motif in the beta-subunit and the HFLEK motif of the alpha-subunit, as well as a possibly helical amino acid stretch bearing a high concentration of negatively charged residues about 70 amino acids downstream of these motifs in both subunits. In order to achieve a better understanding of the role of certain amino acids in rat MPP, we performed site-directed mutagenesis on both of its subunits. Our results show that whereas both histidines and the glutamate of the HFLEH motif in the beta-subunit are crucial for MPP function, this holds true only for the glutamate in the related HFLEK motif in the alpha-subunit. In addition, functionally important negatively charged residues in the region 70 amino acids downstream occur only in the beta-subunit and not in the alpha-subunit. This indicates a functional asymmetry between the subunits, with the beta-subunit containing a majority of residues participating in the active center.

Folding, flavinylation, and mitochondrial import of 6-hydroxy-D-nicotine oxidase fused to the presequence of rat dimethylglycine dehydrogenase.

We analyzed the folding, covalent flavinylation, and mitochondrial import of the rabbit reticulocyte lysate-translated bacterial 6-hydroxy-D-nicotine oxidase (6-HDNO) fused to the mitochondrial targeting sequence of rat liver dimethylglycine dehydrogenase. Translation of 6-HDNO in FAD-supplemented reticulocyte lysate resulted in a protein that contained covalently incorporated FAD, exhibited enzyme activity, and was trypsin-resistant, a characteristic of the tight conformation of the holoenzyme. The attached mitochondrial presequence did not prevent folding, binding of FAD, or enzyme activity of the 6-HDNO moiety of the fusion protein (pre-6-HDNO). Pre-6-HDNO was imported into rat liver mitochondria and processed by the mitochondrial processing peptidase. Incubation of the trypsin-resistant pre-holo-6-HDNO protein with deenergized rat liver mitochondria demonstrated that upon contact with mitochondria, the protein was unfolded and became trypsin sensitive. Mitochondrial import assays showed that the unfolded pre-holo-6-HDNO with covalently attached FAD was imported into rat liver mitochondria. Inside the mitochondrion the holo-6-HDNO was refolded into the trypsin-resistant conformation. However, when pre-apo-6-HDNO was imported only part of the protein became trypsin resistant (approximately 20%). Addition of FAD and the allosteric effector glycerol 3-phosphate to apo-6-HDNO containing mitochondrial matrix was required to transform the protein into the trypsin-resistant conformation characteristic of holo-6-HDNO.

Rat liver mitochondrial processing peptidase. Both alpha- and beta-subunits are required for activity.

Most nuclearly encoded mitochondrial proteins are synthesized with an amino-terminal leader peptide that is cleaved by the mitochondrial processing peptidase (MPP). Purified rat liver MPP, like the Neurospora and yeast enzymes, consists of two nonidentical subunits, alpha (55 kDa) and beta (50 kDa). To confirm the functional authenticity of the recently cloned and sequenced cDNAs for the alpha- and beta-MPP subunits from rat liver and to study each subunit's participation in MPP activity, we have subcloned and expressed separately in Escherichia coli the mature sequence of each subunit as a fusion protein with the maltose-binding protein. After induction, about 80% of each expressed fusion protein was insoluble in aggregates or inclusion bodies, and 20% remained soluble in the supernatant. The fusion proteins in the soluble fraction were purified by affinity chromatography and treated with factor Xa, and the MPP subunits were purified to homogeneity. When mixed together, these subunits showed no activity, suggesting that they might be misfolded. Therefore, a reconstitution protocol was developed which consisted of denaturation in urea, dithiothreitol, and 2-mercaptoethanol, followed by renaturation by dilution and dialysis under reducing conditions. With this procedure, active MPP was recovered from the mixed subunits, and it could be demonstrated that both alpha- and beta-MPP subunits were necessary for activity. Reconstituted recombinant MPP resembled the native rat liver enzyme as judged by its molecular weight, its inhibition by EDTA, and its ability to process a variety of mitochondrial precursor proteins appropriately to either an intermediate or a mature form.

Protein phosphorylation in Streptomyces albus.

The phosphorylated proteins of Streptomyces albus, radioactively labeled with [32P]orthophosphate have been analyzed by gel electrophoresis and autoradiography. More than 10 protein species were found to be phosphorylated. With [32P]ATP as substrate cell free extracts phosphorylated endogenous proteins in vitro which were predominantly phosphorylated in vivo. From cell extract which exhibited active phosphorylated in vitro, a protein kinase has been partially purified. The kinase activity was identified in fractions corresponding to a 90 kDa protein.

Some properties of DNA-dependent RNA polymerase from Streptomyces granaticolor.

RNA nucleotidyltransferase from Streptomyces granaticolor was purified and some of its properties were investigated. The temperature optimum of the enzyme is 35 degrees C, pH optimum 7.8-8.4. Antibodies against the beta subunit of the enzyme from Bacillus subtilis immunologically cross-react with the beta subunit of the enzyme from S. granaticolor. Antibodies against the beta' subunit of the enzyme from B. subtilis immunologically cross-react with both beta and beta' subunits of the enzyme from S. granaticolor.

Induction of beta-D-glucosidase in Streptomyces granaticolor.

beta-D-glucosidase in Streptomyces granaticolor is an inducible enzyme. Methyl-beta-D-glucoside or cellobiose, added to a glycerol-containing medium, are most suitable inducers. The activity of beta-D-glucosidase in a culture fully induced by cellobiose is 50 times higher than the basal level of the enzyme. beta-D-glucosidase is an intracellular enzyme, whose inducibility differ with culture age and reaches its maximum in a 10-h-old mycelium. The enzyme synthesis begins 2 h after the addition of the induced and reaches its maximum after a 10-h-induction.

Purification of DNA-dependent RNA polymerase from Streptomyces granaticolor.

RNA nucleotidyltransferase (EC 2.7.7.6) of Streptomyces granaticolor was purified by precipitation with polymin P and ammonium sulphate, affinity chromatography on DNA- cellulose and gell filtration on Biogel A 1.5 m. SDS-polyacrylamide gel electrophoresis revealed 8 protein bands of molar mass ranging from 37 to 130 kg/mol. Proteins of molar mass of 130 and 120 kg/mol were identified to be beta and beta subunits, respectively. The role of other subunits of the enzyme is discussed.

Activity of beta-galactosidase in soil continuously supplemented with lactose.

The microflora of the chernozem soil mineralized 62% of the lactose retained on a column consisting of three 10-g layers of the soil at a daily flow of 48 mg of the sugar. Only 45% of the sugar was mineralized when the daily flow was 136 mg. The highest value of the beta-galactosidase activity in the system of heterocontinuous cultivation was two-fold with respect to batch cultivation. At a higher sugar concentration the enzyme activity in steady state was the same in the whole soil column. This value was reached first in the middle layer of the soil. At a lower concentration of the flowing sugar in steady state the highest enzyme activity was detected in the middle layer of the soil. In the upper layer the enzyme activity was one half, in the lower layer it began to decrease after reaching its maximum after 4 d of the incubation.

Utilization of glucose and celloboise by the microflora of soil enriched with cellulose.

The ability of soil microflora to utilize glucose or celloboise was found to depend on previous incubation of the soil with glucose, celloboise or cellulose. Glucose was utilized more rapidly than cellobiose in soil preincubated with glucose or cellobiose. The opposite situation was observed in soil preincubated with cellulose. In the presence of a mixture of both sugars the rate of utilization of one of them was decreased by the second and this decrease could be characterized as competitive inhibition. Glucose accumulated in the medium during utilization of cellobiose alone in soil preincubated with cellulose. This phenomenon was not observed during the utilization of cellobiose in soil preincubated with glucose or cellobiose.