Synthesis and intracellular transport of mitochondrial matrix proteins in rat liver: studies in vivo and in vitro

Cloning and some novel characteristics of mitochondrial Hsp70 from Chinese hamster cells

The cDNA for Chinese hamster mitochondrial Hsp70 (mHsp70) was cloned and sequenced using a polymerase chain reaction probe based on conserved regions in the Hsp70 family of proteins. The encoded protein consists of 679 amino acids which includes a N-terminal mitochondrial targeting sequence of 46 amino acids. The mHsp70 protein contains several sequence signatures that are characteristics of prokaryotic and eukaryotic organellar Hsp70 homologs. In a phylogenetic tree based on Hsp70 sequences, it branches with the gram-negative proteobacteria, supporting the endosymbiotic origin of mitochondria from this group of prokaryotes. The mHsp70 cDNA was transcribed and translated in vitro and its import into isolated rat heart mitochondria was examined. The precursor mHsp70 was converted into a mature form of lower molecular mass (approximately 71 kDa) which became resistant to trypsin digestion. The import of mHsp70 into mitochondria was not observed in the presence of an uncoupler of energy metabolism or when the N-terminal presequence was lacking. The cDNA for mHsp70 was expressed in Escherichia coli and a polyclonal antibody to the purified recombinant protein was raised. The antibody shows no cross-reactivity to recombinant cytosolic Hsp70 protein and in 2-D gel blots it reacted specifically with the mHsp70 protein only. In immunofluorescence experiments, the antibody predominantly labeled mitochondria, and the observed labeling pattern was identical to that seen with a monoclonal antibody to the mitochondrial Hsp60 chaperonin. The affinity-purified antibody to mHsp70 was also employed to examine the subcellular distribution of the protein by cryoelectron microscopy and the immunogold-labeling technique. In these experiments, in addition to mitochondria, labeling with mitochondrial Hsp70 antibody was also observed on the plasma membrane and in unidentified cytoplasmic vesicles and granules. These studies raise the possibility that similar to the Hsp60 chaperonin and a number of other mitochondrial proteins, mHsp70 may have an extramitochondrial role.

Protein import into subsarcolemmal and intermyofibrillar skeletal muscle mitochondria. Differential import regulation in distinct subcellular regions

To date, no studies have described the import of proteins in mitochondria obtained from skeletal muscle. In this tissue, mitochondria consist of the functionally and biochemically distinct intermyofibrillar (IMF) and subsarcolemmal (SS) subfractions, which are localized in specialized cellular compartments. This mitochondrial heterogeneity in muscle could be due, in part, to differential rates of protein import. To evaluate this possibility, the import of precursor malate dehydrogenase and ornithine carbamyltransferase proteins was investigated in isolated IMF and SS mitochondria in vitro. Import of these was 3-4-fold greater in IMF compared with SS mitochondria as a function of time. This could account for the higher malate dehydrogenase enzyme activity in IMF mitochondria. Divergent import rates in IMF and SS mitochondria likely result from a differential reliance on various components of the import pathway. SS mitochondria possess a greater content of the molecular chaperones hsp60 and Grp75, yet import is lower than in IMF mitochondria. On the other hand, adriamycin inhibition studies illustrated a greater reliance on acidic phospholipids (i.e. cardiolipin) for the import process in SS mitochondria. Matrix ATP levels were 3-fold higher in IMF mitochondria, but experiments in which ATP depletion was performed with atractyloside and oligomycin illustrated a dissociation between import rates and levels of ATP. In contrast, a close relationship was found between the rate of ATP production (i.e. mitochondrial respiration) and protein import. When respiratory rates in IMF and SS mitochondria were equalized, import rates in both subfractions were similar. These data indicate that 1) import rates are more closely related to the rate of ATP production than the steady state ATP level, 2) import into IMF and SS mitochondrial subfractions is regulated differently, and 3) mitochondrial heterogeneity within a cell type can be due to differences in the rates of protein import, suggesting that this step is a potentially regulatable event in determining the final mitochondrial phenotype.

Absence of mitochondrial beta-adrenoceptors in guinea pig myocardium: evidence for tissue disparity

1. Binding sites in guinea pig myocardial tissue labelled by (-)-[125I] cyanopindolol (CYP) were investigated using differential centrifugation and autoradiographic techniques. Autoradiographs of myocardial sections (0.1 microns) indicated (-)-[125I]CYP binding to sarcolemmal membrane. A low density of binding sites was observed to mitochondria. 2. Binding studies were performed in subcellular fractions. The density of binding sites in the mitochondrial fraction (36.1 +/- 9.4 fmol/mg protein) was less than 10% that in the sarcolemmal membrane (371.7 +/- 38.2 fmol/mg protein). The beta 1/beta 2-adrenoceptor subtype ratio in the mitochondrial fraction (83.3/16.7) was similar to that in the sarcolemmal fraction (87.1/12.9). 3. Ouabain (100 microM), in the presence of sodium azide (0.4 mM), inhibited a Na+K+ stimulated ATPase activity (1.0 +/- 0.2 mumol Pi/mg protein/hr reduction), indicating a low but significant level of sarcolemmal contamination of the mitochondrial fraction. 4. The study showed beta-adrenoceptors in guinea pig heart are located primarily on the sarcolemmal membrane of myocardium. No evidence was obtained for beta-adrenoceptors over mitochondria, as has been suggested in other tissues and species, but that this binding was to sarcolemmal inclusions in the mitochondrial fraction.

Sequential up-regulation of thyroid hormone beta receptor, ornithine transcarbamylase, and carbamyl phosphate synthetase mRNAs in the liver of Rana catesbeiana tadpoles during spontaneous and thyroid hormone-induced metamorphosis

During both spontaneous and thyroid hormone (TH)-induced metamorphosis, the Rana catesbeiana tadpole undergoes postembryonic developmental changes in its liver which are necessary for its transition from an ammonotelic larva to a ureotelic adult. Although this transition ultimately results from marked increases in the activities and/or de novo synthesis of the urea cycle enzymes, the precise molecular means by which TH exerts this tissue-specific response are presently unknown. Recent reports, using RNA from whole Xenopus laevis tadpole homogenates and indirect means of measuring TH receptor (TR) mRNAs, suggest a correlation between the up-regulation of TR beta-mRNAs and the general morphological changes occurring during amphibian metamorphosis. To assess whether or not this same relationship exists in a TH-responsive tissue, such as liver, we isolated and characterized a cDNA clone containing the complete nucleotide sequence for a R. catesbeiana urea cycle enzyme, ornithine transcarbamylase (OTC), as well as a genomic clone containing a portion of the hormone-binding domain of a R. catesbeiana TR beta gene. Through use of these homologous sequences and a heterologous cDNA fragment encoding rat carbamyl phosphate synthetase (CPS), we directly determined the relative levels of the TR beta, OTC, and CPS mRNAs in liver from spontaneous and TH-induced tadpoles. Our results establish that TH affects an up-regulation of mRNAs for its own receptor prior to up-regulating CPS and OTC mRNAs. Moreover, results with cultured tadpole liver demonstrate that TH, in the absence of any other hormonal influence, can affect an up-regulation of both the TR beta and OTC mRNAs.

Polyamines are sufficient to drive the transport of the precursor of ornithine carbamoyltransferase into rat liver mitochondria: possible effect on mitochondrial membranes

The polyamines spermidine, spermine and putrescine, by themselves, at physiological concentrations, induce the transport of the precursor of ornithine carbamoyltransferase into isolated rat liver mitochondria. The presence of polyamines in the transport medium results in the approach of both mitochondrial membranes, suggesting a possible role of these molecules in the transport of the precursor of ornithine carbamoyltransferase into mitochondria, by the formation and/or stabilization of mitochondrial structures involved in the transport system.

Expression in Escherichia coli of functional precursor to the rat liver mitochondrial enzyme, ornithine carbamyl transferase. Precursor import and processing in vitro

cDNA encoding the full-length cytosolic precursor of rat liver ornithine carbamyl transferase, a mitochondrial matrix enzyme, was inserted into pKK223-3 and expressed under the control of the tac promoter. Following transformation of E. coli strain JM105 and induction by isopropylthiogalactoside, a polypeptide was synthesized which reacted with antibody against ornithine carbamyl transferase and co-migrated in SDS-polyacrylamide gels with authentic enzyme precursor (pOCT, Mr = 40,000 kDa); it constituted approximately 0.1% of total E. coli protein. pOCT was synthesized in vitro by coupled transcription-translation of the recombinant plasmid in an E. coli S30 extract; upon subsequent addition of purified rat liver or heart mitochondria, the precursor was imported and processed to mature form. Synthesis of pOCT in a bacterial system, therefore, results in production of a functional precursor polypeptide which does not require additional cytosolic factors from eukaryotic cells to support its uptake and processing by mitochondria in vitro.

Expression of nuclear genes encoding the urea cycle enzymes, carbamoyl-phosphate synthetase I and ornithine carbamoyl transferase, in rat liver and intestinal mucosa

RNA dot-blot, quantitative electron microscope immunocytochemistry, and electrophoretic immunoblotting techniques were employed to investigate the expression of carbamoyl-phosphate synthetase I (CPS) and ornithine carbamoyl transferase (OCT) genes in rat liver and intestinal mucosa. Comparing only those cell types in the two tissues which express these enzymes, we show that the concentration of CPS and OCT in hepatocyte mitochondria is 2.3-times and 1.2-times greater, respectively, than in intestinal epithelial cell mitochondria. As a percentage of total tissue protein, however, liver homogenates contain 10-20 times more CPS and 5-10 times more OCT than is found in intestinal mucosa. These relatively large differences in enzyme protein levels between the two tissues are not reflected by differences in their mRNA levels. As a percentage of total translational activity in vitro (based on incorporation of [35S]methionine), total liver mRNA directed synthesis of about twice as much precursor CPS (pCPS) and precursor OCT (pOCT) than did equivalent amounts of mRNA from intestinal mucosa. The ratio of pCPS and pOCT mRNA levels between the two tissues (2:1, liver:intestinal mucosa) was confirmed by dot-blot and Northern hybridizations employing specific cDNA probes. The sizes of the respective mRNAs were the same for the two tissues: about 6000 residues for pCPS mRNA and about 1700 residues for pOCT mRNA.

The precursor to ornithine carbamyl transferase is transported to mitochondria as a 5S complex containing an import factor

The precursor to ornithine carbamyl transferase (Mr = 40,000) was synthesized in a rabbit reticulocyte lysate system and purified by immunoaffinity chromatography. Import of purified precursor by isolated mitochondria depended upon the presence of import factor(s) in fresh reticulocyte lysate. Velocity sedimentation analyses indicated that import factor binds to precursor to form a 5S complex (approximately 90 kDa); in this form, precursor was efficiently imported by isolated mitochondria. The ability of the 5S complex to deliver precursor into mitochondria was not affected by pretreatment with high concentrations of RNase. Import factor did not bind to mitochondria in the absence of precursor; upon binding of precursor to mitochondria in the presence of import factor, subsequent transmembrane uptake of precursor did not require the continued presence of additional lysate components.

Expression of carbamoyl-phosphate synthetase I mRNA in Reuber hepatoma H-35 cells. Regulation by glucocorticoid and insulin

Reuber hepatoma H-35 cells actively synthesize the urea cycle enzyme, carbamoyl-phosphate synthetase I. Treatment of H-35 cells with dexamethasone (0.14 microM), however, enhanced synthesis of the enzyme (as measured by incorporation of [35S]methionine) by 4-5-fold. Insulin (0.18 microM) completely inhibited dexamethasone-dependent stimulation of enzyme synthesis. In vitro translation and cDNA hybridization assays were employed to measure effects of dexamethasone plus or minus insulin on levels of mRNA encoding the biosynthetic precursor of carbamoyl-phosphate synthetase I (pCPS) in Reuber H-35 cells. Both measurements yielded similar results: dexamethasone increased pCPS mRNA levels by 4-5-fold and insulin suppressed this response, but only by 50%. Specific cDNA hybridization assays also demonstrated that Reuber H-35 cells, even after hormone treatments, contain only very low levels of albumin mRNA, and no detectable ornithine carbamoyl-transferase mRNA.

In vitro synthesis and assembly of a 68 kDa outer mitochondrial membrane protein from rat liver

Outer mitochondrial membrane was purified from rat liver. Its constituent proteins were analyzed by SDS-polyacrylamide gel electrophoresis and by electrophoretic immunoblotting employing antibodies raised against total outer mitochondrial membrane. Anti-outer mitochondrial membrane antiserum reacted with only one polypeptide (15 kDa) in rough microsomes, whereas no immunological cross-reactivity was observed with other mitochondrial compartments (intermembrane space, inner membrane, or matrix) or with lysosomes or total cytosol. The antiserum was employed to characterize precursors of outer mitochondrial membrane proteins synthesized in vitro in a rabbit reticulocyte cell-free system. One product (a 68 kDa polypeptide designated OMM-68) bound efficiently to mitochondria in vitro but did not interact with either dog pancreas or rat liver microsomes, either co-translationally or post-translationally. OMM-68 was synthesized exclusively by the membrane-free class of polyribosomes. Attachment of precursor OMM-68 to mitochondria was not accompanied by processing of the polypeptide to a different size.