Phosphatidylcholine and phosphatidylethanolamine enhance the activity of the mammalian mitochondrial endonuclease in vitro

The purified endonuclease of bovine heart mitochondria extensively degrades a variety of DNA templates in vitro but shows a remarkably strong preference to nick within one specific evolutionarily conserved sequence block of 12 consecutive guanine residues which resides just upstream from the heavy strand origin of mitochondrial DNA replication (Low, R. L., Cummings, O. W., and King, T. C. (1987) J. Biol. Chem. 262, 16164-16170). If the enzyme serves to provide an important nicking function at this site in vivo, then mitochondrial factors likely exist which further enhance the enzyme's recognition of this locus and prevent cleavage at other less favored sites. In this study, we report that specific membrane phospholipids appear to exert such effects in vitro. In standard endonuclease assays, low levels of phosphatidylcholine or phosphatidylethanolamine (0.5 mM) stimulate the purified enzyme activity 10-20-fold. However, at moderate levels (20-40 mM), these phospholipids largely inhibit widespread degradation of duplex DNA while still allowing site-specific nicking at the conserved guanine target in the mitochondrial genome. These findings suggest that an interaction of the endonuclease with major lipid components of the inner membrane could be an important determinant of the enzyme's specificity for mitochondrial DNA.     

Protein binding to a single termination-associated sequence in the mitochondrial DNA D-loop region.

A methylation protection assay was used in a novel manner to demonstrate a specific bovine protein-mitochondrial DNA (mtDNA) interaction within the organelle (in organello). The protected domain, located near the D-loop 3' end, encompasses a conserved termination-associated sequence (TAS) element which is thought to be involved in the regulation of mtDNA synthesis. In vitro footprinting studies using a bovine mitochondrial extract and a series of deleted mtDNA templates identified a approximately 48-kDa protein which binds specifically to a single TAS element also protected within the mitochondrion. Because other TAS-like elements located in close proximity to the protected region did not footprint, protein binding appears to be highly sequence specific. The in organello and in vitro data, together, provide evidence that D-loop formation is likely to be mediated, at least in part, through a trans-acting factor binding to a conserved sequence element located 58 bp upstream of the D-loop 3' end.     

Mapping of mitochondrial DNA of individual sheep and goats: Rapid evolution in the D loop region

Mitochondrial DNA (mtDNA) from sheep and goat was compared by restriction endonuclease analysis and heteroduplex mapping in the electron microscope. The fragment patterns produced by endonuclease Hae III from three individual sheep and two goat mtDNAs all differed from each other. The three sheep mtDNAs had identical Eco RI and Hind III fragments, but the two goat mtDNA patterns differed from each other as well as from sheep mtDNA. We estimate that each sheep mtDNA differs from each other by 0.5–1% of its nucleotide sequences, the two goat mtDNAs by 1–2%, and there is a 6–11% sequence difference between sheep and goat mtDNAs. We have mapped the Eco RI and Hind III sites of goat and sheep mtDNA and determined the positions of the D loop, which marks the replication origin, relative to the restriction map. The D loops are at homologous positions on the mtDNAs from both species, but the goat D loop is only 75% as long as the sheep D loop. Regions with a high degree of sequence divergence occur at both ends of the D loop. We suggest that a duplication of about 150 base pairs has occurred in the region where the sheep and goat D loops differ in length. We discuss mtDNA evolution in terms of divergence of isolated “mitochondrial DNA clones.”     

Complete sequence of bovine mitochondrial DNA conserved features of the mammalian mitochondrial genome

We present here the complete 16,338 nucleotide DNA sequence of the bovine mitochondrial genome. This sequence is homologous to that of the human mitochondrial genome (Anderson et al., 1981) and the genes are organized in virtually identical fashion. The bovine mitochondrial protein genes are 63 to 79% homologous to their human counterparts, and most of the nucleotide differences occur in the third positions of codons. The minimum rate of base substitution that accounts for the nucleotide differences in the codon third positions is very high: at least 6 × 10^?9 changes per position per year. The bovine and human mitochondrial transfer RNA genes exhibit more interspecies variation than do their cytoplasmic counterparts, with the “TΨC” loop being the most variable part of the molecule. The bovine 12 S and 16 S ribosomal RNA genes, when compared with those from human mitochondrial DNA, show conserved features that are consistent with proposed secondary structure models for the ribosomal RNAs. Unlike the pattern of moderate-to-high homology between the bovine and human mitochondrial DNAs found over most of the genome, the DNA sequence in the bovine D-loop region is only slightly homologous to the corresponding region in the human mitochondrial genome. This region is also quite variable in length, and accounts for the bulk of the size difference between the human and bovine mitochondrial DNAs.     

Nucleotide sequence of a Xenopus laevis mitochondrial DNA fragment containing the D-loop, flanking tRNA genes and the apocytochrome b gene

Extensive corrections of the nucleotide sequence of the Xenopus laevis mitochondrial (mt) displacement (D) loop and surrounding genes [Wong et al., Nucl. Acids Res. 11 (1983) 4977-4995] are reported, including addition of two stretches of nucleotides and 60 scattered modifications. The additional sequences presented here correspond to the apocytochrome b gene, the tRNAGlu gene and part of URF6. This allows us to propose a conformational model for the X. laevis apocytochrome b protein and also permits comparisons with mammalian mtDNA. The D-loop sequence is poorly conserved except for sequences involved in the regulation of the mt genome (conserved sequence blocks and the DNA polymerase stop sequences). On the other hand, all genes show marked conservation both of their nucleotide sequence and their respective location on the mt genome. Organization of the genetic information described for mammalian mtDNA also holds for the X. laevis mtDNA. This result strongly suggests that all animal vertebrate mtDNAs have followed the same evolutionary pathway.     

Yeast mitochondrial DNA mutators with deficient proofreading exonucleolytic activity.

The MIP1 gene which encodes yeast mitochondrial DNA polymerase possesses in its N-terminal region the three motifs (Exo1, Exo2 and Exo3) which characterize the 3'-5' exonucleolytic domain of many DNA polymerases. By site directed mutagenesis we have substituted alanine or glycine residues for conserved aspartate residues in each consensus sequence. Yeast mutants were therefore generated that are capable of replicating mitochondrial DNA (mtDNA) and exhibit a mutator phenotype, as estimated by the several hundred-fold increase in the frequency of spontaneous mitochondrial erythromycin resistant mutants. By overexpressing the mtDNA polymerase from the GAL1 promoter as a major 140 kDa polypeptide, we showed that the wild-type enzyme possesses a mismatch-specific 3'-5' exonuclease activity. This activity was decreased by approximately 500-fold in the mutant D347A; in contrast, the extent of DNA synthesis was only slightly decreased. The wild-type mtDNA polymerase efficiently catalyses elongation of singly-primed M13 DNA to the full-length product. However, the mutant preferentially accumulates low molecular weight products. These data were extended to the two other mutators D171G and D230A. Glycine substitution for the Cys344 residue which is present in the Exo3 site of several polymerases generates a mutant with a slightly higher mtDNA mutation rate and a slightly lower 3'-5' exonucleolytic activity. We conclude that proofreading is an important determinant of accuracy in the replication of yeast mtDNA.     

Length and restriction site heteroplasmy in the mitochondrial DNA of american shad (alosa sapidissima)

Restriction endonuclease analysis was used to assess mitochondrial DNA (mtDNA) variation in American shad (Alosa sapidissima) collected from 14 rivers ranging from Florida to Quebec. Two types of heteroplasmy were observed, one involving a major length polymorphism and the other a single restriction site. Shad mtDNA occurred in two principal size classes, 18.3 and 19.8 kb. Of 244 shad examined, 30 were heteroplasmic and carried both size classes of mtDNA in varying proportions; the remainder were homoplasmic for the smaller size class of mtDNA. The large mtDNA variant occurred most frequently at the southern end of the range, and except for two individuals from Nova Scotia, was not detected among shad from rivers north of the Delaware. In contrast, ten shad heteroplasmic for a SalI restriction site originated from rivers ranging from South Carolina to Nova Scotia. DNA mapping and hybridization experiments indicated that the length polymorphism is in the D-loop-containing region and consists of a tandemly repeated 1.5-kb DNA sequence occurring in two and three copies, respectively, in the two major size classes of shad mtDNA. Continuous length variation up to approximately 40 bp occurs among copies of the repeat both within and among individuals. Restriction site data support the conclusion that both forms of heteroplasmy in shad mtDNA have originated more than once.     

Ovine mitochondrial DNA: restriction enzyme analysis, mapping and sequencing data

Restriction endonuclease fragment patterns of mitochondrial DNA (mtDNA) in sheep were analysed with 11 enzymes. Four breeds (Merinolandschaf, Rhoenschaf, Schwarzkoepfiges Fleischschaf and Skudde) of domestic sheep and European Mouflon were examined. A restriction map with 28 cleavage sites of seven enzymes was established. KpnI and PstI do not cut ovine mtDNA. Two EcoRI fragments of Merinolandschaf, Rhoenschaf and Mouflon each were cloned and partially sequenced. Intraspecific nucleotide sequence differences within 1.101 kb ranged from 0.09 to 0.27%. Hybridization analysis with a fragment of porcine mtDNA along with sequencing data from cloned fragments was used for orientation of the restriction map along the bovine sequence. Ovine mtDNA sequences encompassing parts of the Cyt.b-, ND5-, CoIII- and ATPase6 genes were compared with the corresponding sequences of the bovine mtDNA.     

Maternal inheritance of deleted mitochondrial DNA in a family with mitochondrial myopathy

Skeletal muscles from a mother and her daughter both with chronic progressive ophthalmoplegia were analyzed. Histological and biochemical analyses of their muscle samples showed typical features of this type of mitochondrial myopathy. Southern blot analysis revealed that, in both patients, there were two species of mitochondrial DNA (mtDNA): normal one and partially deleted one. The sizes of the deletion were different; the mutant mtDNAs from the mother and the daughter had about 2.5- and 5-kilobase deletions, respectively. The two mutant mtDNAs shared a common deleted region of 1.2-kilobase. However, both the start and the end of deletion were different between them, implying a novel mode of inheritance. This is the first report that the mutant mtDNA is responsible for the maternal inheritance of a human disease.     

Nucleotide sequence variation is frequent in the mitochondrial DNA displacement loop region of individual human tumor cells

The mitochondrial DNA (mtDNA) displacement loop (D-loop) regions of 76 various tumor cell lines were examined to investigate the existence of a specific relationship between a somatic mtDNA sequence and initiation and/or progression of a tumor. Based on molecular cloning-sequencing analysis, a nucleotide sequence in the D-loop region in each cell line was found to be homoplasmic. Several site-specific nucleotide variations were found in stomach and liver tumor cell lines more frequently than those in other tumor cell lines. Subsequently, 20 pairs of noncancerous and cancerous parts from stomach and liver tumor tissues were examined. In the liver tumor tissue, 80% of the noncancerous parts exhibited slightly higher heterogeneity than the corresponding cancerous parts. Several site-specific nucleotide variations found in 76 tumor cell lines were also detected in noncancerous or cancerous parts of stomach and liver tumor tissues. However, it remains unclear why the mtDNA D-loop sequence is homoplasmic in each tumor cell line. The data indicate that mtDNA exhibits heterogeneity even in the noncancerous part and a slight decrease in heterogeneity during tumorigenesis and/or tumor progression. Homoplasmy of the mtDNA population in the tumor cell line would be acquired in the cloning process of establishing a cell line. Site-specific nucleotide substitutions might not be directly involved in the tumorigenesis process.     

Efficient site-specific cleavage by RNase MRP requires interaction with two evolutionarily conserved mitochondrial RNA sequences.

RNase MRP is a site-specific endonuclease that processes primer mitochondrial RNA from the leading-strand origin of mitochondrial DNA replication. Using deletional analysis and saturation mutagenesis, we have determined the substrate requirements for cleavage by mouse mitochondrial RNase MRP. Two regions of sequence homology among vertebrate mitochondrial RNA primers, conserved sequence blocks II and III, were found to be critical for both efficient and accurate cleavage; a third region of sequence homology, conserved sequence block I, was dispensable. Analysis of insertion and deletion mutations within conserved sequence block II demonstrated that the specificity of RNase MRP accommodates the natural sequence heterogeneity of conserved sequence block II in vivo. Heterologous assays with human RNase MRP and mutated mouse mitochondrial RNA substrates indicated that sequences essential for substrate recognition are conserved between mammalian species.     

A family of repetitive palindromic sequences found in Neurospora mitochondrial DNA is also found in a mitochondrial plasmid DNA

Neurospora mtDNA contains a repetitive, 18 nucleotide palindromic sequence (5'-CCCTGCAGTACTGCAGGG-3') that contains two closely spaced PstI sites (CTGCAG) in the arms of the palindrome (Yin, S., Heckman, J., and RajBhandary, U. L. (1981) Cell 26, 325-332). In the present study, DNA sequence analysis was carried out to determine whether PstI palindromes are present in an apparently distinct genetic element, the 3.6-kilobase mitochondrial plasmid from Neurospora crassa strain Mauriceville-1c (FGSC 2225). The plasmid contains a cluster of closely spaced PstI sites extending over a 0.4-kilobase region (Collins, R. A., Stohl, L. L., Cole, M. D., and Lambowitz, A. M. (1981) Cell 24, 443-452). The DNA sequence shows that the cluster consists of eight PstI sites organized in five palindromic elements. Two of the elements are identical with the canonical sequence found in mtDNA, whereas the remaining three elements differ from the canonical sequence by a few nucleotides. The occurrence of the PstI palindromes in two otherwise unrelated DNA species is consistent with the hypothesis that they are related to mobile DNA sequences that either propagate or were once capable of propagating within mitochondria.