Mitochondrial Protein Extracts Research Articles

Mitochondrial DNA ligase III function is independent of Xrcc1.

Hamster EM9 cells, which lack Xrcc1 protein, have reduced levels of DNA ligase III and are defective in nuclear base excision repair. The Xrcc1 protein stabilizes DNA ligase III and may even play a direct role in catalyzing base excision repair. Since DNA ligase III is also thought to function in mitochondrial base excision repair, it seemed likely that mitochondrial DNA ligase III function would also be dependent upon Xrcc1. However, several lines of evidence indicate that this is not the case. First, western blot analysis failed to detect Xrcc1 protein in mitochondrial extracts. Second, DNA ligase III levels present in mitochondrial protein extracts from EM9 cells were indistinguishable from those seen in similar extracts from wild-type (AA8) cells. Third, the mitochondrial DNA content of both cell lines was identical. Fourth, EM9 cells displayed no defect in their ability to repair spontaneous mitochondrial DNA damage. Fifth, while EM9 cells were far more sensitive to the cytotoxic effects of ionizing radiation due to a defect in nuclear DNA repair, there was no apparent difference in the ability of EM9 and AA8 cells to restore their mitochondrial DNA to pre-irradiation levels. Thus, mitochondrial DNA ligase III function is independent of the Xrcc1 protein.

An alternate form of Ku80 is required for DNA end-binding activity in mammalian mitochondria.

Mammalian mitochondrial DNA end-binding activity is nearly indistinguishable from that of nuclear Ku. This observation led to the hypothesis that mitochondrial DNA end-binding activity is in part dependent upon Ku80 gene expression. To test this hypothesis, we assayed for Ku activity in mitochondrial extracts prepared from the xrs-5 hamster cell line that lacks Ku80 mRNA expression. Mitochondrial protein extracts prepared from this cell line lacked the DNA end-binding activity found in similar extracts prepared from wild-type cells. Azacytidine-reverted xrs-5 cells that acquired nuclear DNA end-binding activity also acquired mitochondrial DNA end-binding activity. Western blot analysis of human mitochondrial protein extracts using a monoclonal antibody specific for an N-terminal epitope of Ku80 identified a protein with an apparent molecular weight of 68 kDa. This mitochondrial protein was not detected by a monoclonal antibody specific for an epitope at the C-terminal end of Ku80. Consistently, while both the N- and C-terminal Ku80 monoclonal antibodies supershifted the nuclear DNA end-binding complex on an electrophoretic mobility shift assay, only the N-terminal monoclonal antibody supershifted the mitochondrial DNA end-binding complex. To confirm that the 68 kDa Ku protein was not a consequence of nuclear protein contamination of mitochondrial preparations, highly purified intact nuclei and mitochondria were treated with proteinase K which traverses the pores of intact nuclei but gains limited access into intact mitochondria. Ku80 in purified intact nuclei was sensitive to treatment with this protease, while the 68 kDa Ku protein characteristic of purified intact mitochondria was resistant. Further, immunocytochemical analysis revealed the co-localization of the N-terminal specific Ku80 monoclonal antibody with a mitochondrial-targeted green fluorescence protein. Mitochondrial localization of the C-terminal Ku80 monoclonal antibody was not observed. These data are consistent with the hypothesis that a C-terminally truncated form of Ku80 is localized in mammalian mitochondria where it functions in a DNA end-binding activity.

Single-nucleotide patch base excision repair of uracil in DNA by mitochondrial protein extracts#

Mammalian mitochondria contain several 16.5 kb circular DNAs (mtDNA) encoding electron transport chain proteins. Reactive oxygen species formed as byproducts from oxidative phosphorylation in these organelles can cause oxidative deamination of cytosine and lead to uracil in mtDNA. Upon mtDNA replication, these lesions, if unrepaired, can lead to mutations. Until recently, it was thought that there was no DNA repair in mitochondria, but lately there is evidence that some lesions are efficiently repaired in these organelles. In the study of nuclear DNA repair, the in vitro repair measurements in cell extracts have provided major insights into the mechanisms. The use of whole-cell extract based DNA repair methods has revealed that mammalian nuclear base excision repair (BER) diverges into two pathways: the single-nucleotide replacement and long patch repair mechanisms. Similar in vitro methods have not been available for the study of mitochondrial BER. We have established an in vitro DNA repair system supported by rat liver mitochondrial protein extract and DNA substrates containing a single uracil opposite to a guanine. Using this approach, we examined the repair pathways and the identity of the DNA polymerase involved in mitochondrial BER (mtBER). Employing restriction analysis of in vitro repaired DNA to map the repair patch size, we demonstrate that only one nucleotide is incorporated during the repair process. Thus, in contrast to BER in the nucleus, mtBER of uracil in DNA is solely accomplished by single-nucleotide replacement.

Mammalian mitochondrial extracts possess DNA end-binding activity.

Mammalian mitochondrial protein extracts possess DNA end-binding (DEB) activity. Protein binding to a 394 bp double-stranded DNA molecule was measured using an electrophoretic mobility shift assay. Mitochondrial DEB activity was highly specific for linear DNA. Inclusion of a vast excess of non-radioactive circular DNA did not disrupt binding to radioactive f394. In contrast, binding was abolished by the inclusion of linear competitor DNA. In mammals, nuclear DEB activity is due to Ku, a hetero-dimer composed of the Ku70 and Ku86 proteins. To determine whether mitochondrial DEB activity was also due to Ku, protein extracts were prepared from the Chinese hamster XR-V15B cell line, which lacks this protein. As anticipated, nuclear extracts prepared from these cells lacked DEB activity. In contrast, mitochondrial extracts prepared from these cells had wild-type levels of DEB activity, demonstrating that this latter activity is not a consequence of nuclear contamination. Although the nuclear and mitochondrial DEB activities are independent of each other, they are nevertheless closely related, since mitochondrial DEB activity was 'supershifted' by both anti-Ku70 and anti-Ku86 antisera. The nuclear DEB protein Ku plays an essential role in nuclear DNA double-strand break repair. The DEB activity described herein may therefore play a similar role in mitochondrial DNA repair.

The human DNA ligase III gene encodes nuclear and mitochondrial proteins.

We provide evidence that the human DNA ligase III gene encodes a mitochondrial form of this enzyme. First, the DNA ligase III cDNA contains an in-frame ATG located upstream from the putative translation initiation start site. The DNA sequence between these two ATG sites encodes an amphipathic helix similar to previously identified mitochondrial targeting peptides. Second, recombinant green fluorescent protein harboring this sequence at its amino terminus was efficiently targeted to the mitochondria of Cos-1 monkey kidney cells. In contrast, native green fluorescent protein distributed to the cytosol. Third, a series of hemagglutinin-DNA ligase III minigene constructs were introduced into Cos-1 cells, and immunocytochemistry was used to determine subcellular localization of the epitope-tagged DNA ligase III protein. These experiments revealed that inactivation of the upstream ATG resulted in nuclear accumulation of the DNA ligase III protein, whereas inactivation of the downstream ATG abolished nuclear localization and led to accumulation within the mitochondrial compartment. Fourth, mitochondrial protein extracts prepared from human cells overexpressing antisense DNA ligase III mRNA possessed substantially less DNA ligase activity than did mitochondrial extracts prepared from control cells. DNA end-joining activity was also substantially reduced in extracts prepared from antisense mRNA-expressing cells. From these results, we conclude that the human DNA ligase III gene encodes both nuclear and mitochondrial enzymes. DNA ligase plays a central role in DNA replication, recombination, and DNA repair. Thus, identification of a mitochondrial form of this enzyme provides a tool with which to dissect mammalian mitochondrial genome dynamics.

Purification and Characterization of a Mitochondrial Thymine Glycol Endonuclease from Rat Liver

Mitochondrial DNA is exposed to oxygen radicals produced during oxidative phosphorylation. Accumulation of several kinds of oxidative lesions in mitochondrial DNA may lead to structural genomic alterations, mitochondrial dysfunction, and associated degenerative diseases. The pyrimidine hydrate thymine glycol, one of many oxidative lesions, can block DNA and RNA polymerases and thereby exert negative biological effects. Mitochondrial DNA repair of this lesion is important to ensure normal mitochondrial DNA metabolism. Here, we report the purification of a novel rat liver mitochondrial thymine glycol endonuclease (mtTGendo). By using a radiolabeled oligonucleotide duplex containing a single thymine glycol lesion, damage-specific incision at the modified thymine was observed upon incubation with mitochondrial protein extracts. After purification using cation exchange, hydrophobic interaction, and size exclusion chromatography, the most pure active fractions contained a single band of approximately 37 kDa on a silver-stained gel. MtTGendo is active within a broad KCl concentration range and is EDTA-resistant. Furthermore, mtTGendo has an associated apurinic/apyrimidinic-lyase activity. MtTGendo does not incise 8-oxodeoxyguanosine or uracil-containing duplexes or thymine glycol in single-stranded DNA. Based upon functional similarity, we conclude that mtTGendo may be a rat mitochondrial homolog of the Escherichia coli endonuclease III protein.

Double strand break rejoining by mammalian mitochondrial extracts.

DNA end-joining was measured by incubating linearized plasmid DNA with mitochondrial protein extracts. A spectrum of end-joined molecules ranging from re-circularized monomer to dimer and higher molecular weight forms was observed. The DNA end-joining reaction required ATP and Mg2+, and was inhibited by sodium chloride. Both cohesive- and blunt-ended DNA molecules were end-joined, although the former were more efficient substrates. Molecular analysis of rejoined molecules revealed that >95% of the linearized DNA were precisely end-joined. The few imprecisely end-joined molecules recovered, sustained deletions that spanned direct repeat sequences. The deletions observed are strikingly similar to those present in mitochondrial genomes of patients with Kearns-Sayre or Pearson syndromes, certain ophthalmic myopathies and the aged. These results suggest that mammalian mitochondria possess a DNA double strand break repair activity similar to that seen in the nucleus, and that this repair pathway may play a role in the generation of mitochondrial DNA deletions associated with a number of human pathologies.

Antisense repression of the mitochondrial NADH-binding subunit of complex I in transgenic potato plants affects male fertility

Mitochondrial respiratory chain complex I is a large multi-subunit enzyme composed of both organellar and nuclear encoded proteins. To investigate the role of the nuclear encoded components, expression of the gene for the 55 kDa NADH-binding subunit of complex I was disturbed by antisense repression in transgenic potato plants. The antisense construct driven by the CaMV 35S promoter decreases the steady-state mRNA levels of transcripts for the 55 kDa subunit to 33% of the wild type levels. Quantities of the 55 kDa protein in mitochondrial protein extracts are lowered to about 50% in these plants. Transgenic plants show normal vegetative growth and tuber formation, but pollen maturation is found to be disturbed. The reduced male fertility of the transgenic 55 kDa antisense plants may be caused by an insufficient mitochondrial respiratory chain, impaired by the decreased expression of the NADH-binding component of mitochondrial complex I.

Trypanosoma brucei gBP21: AN ARGININE-RICH MITOCHONDRIAL PROTEIN THAT BINDS TO GUIDE RNA WITH HIGH AFFINITY

RNA editing in Trypanosoma brucei is a mitochondrial RNA processing reaction that results in the insertion and deletion of uridylate residues into otherwise untranslatable mRNAs. The process is directed by guide RNAs which function to specify the edited sequence. RNA editing in vitro requires mitochondrial protein extracts and guide RNAs have been identified as part of high molecular weight ribonucleoprotein complexes. Within the complexes, the RNAs are in close contact with several mitochondrial proteins and here we describe the isolation and cloning of a gRNA-interacting polypeptide from Trypanosoma brucei. The protein was named gBP21 for guide RNA-binding protein of 21 kDa. gBP21 shows no homology to proteins in other organisms, it is arginine-rich and binds to gRNA molecules with a dissociation constant in the nanomolar range. The protein does not discriminate for differences in the primary structures of gRNAs and thus likely binds to higher order structural features common to all gRNA molecules. gBP21 binding does not perturb the overall structure of gRNAs but the gRNA/gBP21 ribonucleoprotein complex is more stable than naked guide RNAs. Although the protein is arginine-rich, the free amino acid or an arginine-rich peptide were not able to inhibit the association to the RNAs. In contrast, the gRNA-gBP21 complex formation was sensitive to potassium and ammonium cations, thus indicating a contribution of ionic contacts to the binding.

Mammalian Mitochondria Possess Homologous DNA Recombination Activity

Mitochondrial protein extracts from normal and immortalized mammalian somatic cells catalyze homologous recombination of plasmid DNA substrates. Mitochondrial homologous recombination activity required exogenous adenosine triphosphate, although substantial activity remained when non-hydrolyzable analogs were used instead. There was no requirement for added nucleoside triphosphates, and the reaction was not inhibited by dideoxyadenosine triphosphate or aphidicolin. The majority of recombinant plasmid molecules result from a conservative process, indicating that nuclease-mediated strand-annealing is not responsible for the mitochondrial homologous recombination activity. Affinity-purified anti-recA antibodies inhibited the reaction, suggesting that activity is dependent on a mammalian mitochondrial homolog of the bacterial strand-transferase protein. The presence of homologous recombination activity within mammalian mitochondrial extracts suggests that this process is involved in mitochondrial DNA repair.

Experimental verification of the secondary structures of guide RNA-pre-mRNA chimaeric molecules in Trypanosoma brucei.

RNA editing in kinetoplastid organisms is an RNA-processing reaction that adds and deletes U nucleotides at specific sites in mitochondrial pre-mRNAs. The edited sequence is specified by guide RNAs and the processing presumably occurs within a high-molecular-mass ribonucleoprotein complex containing several enzymatic activities. Although the mechanism is not currently known, potential intermediates or by-products of the editing process are chimaeric RNAs where guide (g) RNAs are covalently attached, via their non-encoded U-tail, to their cognate pre-mRNAs. We determined the secondary structures of three different ATPase 6 chimaeras of Trypanosoma brucei using a set of structure-sensitive chemical and enzymatic probes. The experiments revealed a bipartite domain structure consisting of a gRNA/pre-mRNA interaction hairpin and an independently folding mRNA stem/loop in all three RNAs. The connecting U-tail was a determinant for the length of the interaction stems with the oligo(U) nucleotides base pairing to internal gRNA sequences. The probed structures have calculated delta G27o values of -92 kJ/ mol to -134 kJ/mol, somewhat less stable than the predicted minimal free energy structures and support previously proposed models for the interaction between gRNAs and pre-mRNAs. Optical melting studies indicated additional, higher order structural features for all three molecules with four defined melting transition between 10 degrees C and 90 degrees C. A comparison of CD spectra in the absence and presence of mitochondrial protein extracts demonstrated no gross structural changes of the RNA structures induced by the association with polypeptides.

RNA Editing Is Required for Efficient Excision of tRNAPhe from Precursors in Plant Mitochondria

RNA editing corrects a 4C-A69 mismatch to a conventional 4T-A69 Watson-Crick base pair in the acceptor stem of the mitochondrially encoded tRNAPhe in plants. In vitro processing of edited and unedited Oenothera tRNA Phe precursor RNAs with pea mitochondrial protein extracts shows a significant effect of this RNA-editing event on the efficiency of 5' and 3' processing. While mature tRNA molecules are rapidly generated by in vitro processing from edited precursors, the formation of mature tRNAs from unedited pre-tRNAs is considerably reduced. Primer extension analyses of in vitro processing products show that processing at both 5' and 3' termini is governed by the RNA-editing event. Investigation of edited and unedited precursor RNAs by lead cleavage experiments reveals differences in the higher order structures of the pre-tRNAs. The differing conformations are most likely responsible for the altered processing efficiencies of edited and unedited precursor molecules. RNA editing of the tRNAPhe precursors is thus a prerequisite for efficient excision of the mature tRNAPhe in vitro. Hence RNA editing might be involved in regulating the amount of mature tRNAPhe in the steady state RNA pool of mitochondria in higher plants.

The Characterization of a Mitochondrial Acyl Carrier Protein Isoform Isolated from Arabidopsis thaliana

A cDNA clone was isolated from an Arabidopsis leaf cDNA library that shared a high degree of protein sequence identity with mitochondrial acyl carrier proteins (mtACPs) isolated from Neurospora crassa and bovine heart muscle. The cDNA encoded an 88-amino acid mature protein that was preceded by a putative 35-amino acid presequence. In vitro protein import studies have confirmed that the presequence specifically targets this protein into pea mitochondria but not into chloroplasts. These studies indicated that pea mitochondria were not only able to import and process the precursor protein but also possessed the ability to acylate the mature protein. The mitochondrial localization of this protein, mtACP-1, was confirmed by western blot analysis. Arabidopsis mitochondrial protein extracts contained two cross-reacting bands that comigrated with the mature mtACP-1 and acylated mtACP-1 proteins. The acylated form of mtACP-1 was approximately 4 times more abundant than the unacylated form and appeared to be localized predominantly in the mitochondrial membrane where the unacylated mtACP-1 was present mostly in the matrix fraction. A chloroplast fatty acid synthase system was used, and mtACP-1 was able to function as a cofactor for fatty acid synthesis. However, predominantly short- and medium-chain fatty acids were produced in fatty acid synthase reactions supplemented with mtACP-1, suggesting that mtACP-1 may be causing premature fatty acid chain termination.

Light-induced increases in the glycine decarboxylase multienzyme complex from pea leaf mitochondria

The rates of mitochondrial glycine oxidation estimated by CO 2-release and glycine-bicarbonate exchange activities in fully greened tissues are approximately 10 times greater than those of etiolated pea leaves and potato tuber mitochondria. The release of CO 2 from glycine in intact mitochondria isolated from dark-grown and nonphotosynthetic tissues was sensitive to inhibitors of mitochondrial electron transport, glycine transport, and glycine decarboxylase activities. The CO 2-release and glycine-bicarbonate exchange activities in crude mitochondrial protein extracts from light-grown versus dark-grown tissues exhibited light/dark ratios of 12 and 21, respectively. This suggests that the differences in capacity to oxidize glycine reside with the glycine decarboxylase enzyme complex itself. The complex is composed of four subunit enzymes, the P, H, T, and L proteins, which can be isolated individually and reconstituted into the active enzyme. The activities of P and T proteins were at least 10 times higher in fully greened pea leaves than in the etiolated tissue, while the H and L protein activities were four times higher in these same tissues. The levels of P and T proteins detected immunochemically were substantially lower in total mitochondrial extracts prepared from leaves of dark-grown pea seedlings. Labeling of whole pea seedlings and in vitro protein synthesis with isolated mitochondria indicated that the entire glycine decarboxylase enzyme complex is cytoplasmically synthesized and therefore encoded by the nucleus. Polypeptides synthesized from total leaf polyadenylated mRNA isolated from leaves of both the dark-grown and light-treated peas indicated the presence of P protein. This implies that translatable messages for this enzyme are present at some level throughout leaf development.

Induced transcription-dependent synthesis of mitochondrial reduced nicotinamide-adenine dinucleotide dehydrogenase in Drosophila.

Salivary glands of Drosophila hydei recovering from an anaerobic treatment show a significant increase in apparent Vmax of mitochondrial NADH dehydrogenase. This increase in Vmax is based on an increase in enzyme molecules resulting from synthesis de novo in the cytoplasm, as indicated by the inhibition by cycloheximide of both the increase in apparent Vmax and the increase in amino acid incorporation into enzyme fractions. The increase in enzyme activity is also inhibited by actinomycin D, which is in support of previous data indicating a casual relationship between transcription in puff 4-81B in the polytene chromosomes and an increase in apparent Vmax of the enzyme. Gel electrophoresis of mitochondrial protein extracts revealed three protein fractions with NADH dehydrogenase activity. All three fractions showed increased activity as well as increased amino acid labelling in glands recovering from anaerobiosis compared with control glands. The data suggest that the increase in mitochondrial NADH dehydrogenase activity in salivary glands recovering from an anaerobic treatment depends on increased gene transcription.