Nucleotide sequence variants of Rattus norvegicus mitochondrial DNA

Restriction fragment length polymorphism (RFLP) analysis provides evidence for a high degree of homology of mitochondrial DNAs from rat hepatomas versus normal rat livers

Where differences have been reported between tumor and normal mitochondrial DNA (mtDNA), they have generally involved limited modifications of the genome (Taira et al., Nucleic Acids Res. 11:1635, 1983; Shay and Werbin, Mutat. Res. 186:149, 1987). However, Corral et al. (Nucleic Acids Res. 16:10935, 1988; 17:5191, 1989) observed recombination between cytochrome oxidase subunit I (COI) and NADH dehydrogenase subunit 6 (ND6), two genes normally on opposite sides of the circular mitochondrial genome. In rat hepatoma mtDNA COI and ND6 were reported to be separated by only 230 base pairs (Corral et al., 1988, 1989). We have performed RFLP analysis on mtDNA from normal rat livers and rat hepatomas, using COI and ND6 probes. Additional experiments compared end-labeled DNA fragments produced by EcoRI and HindIII digestion of mtDNA. These studies failed to provide any evidence for genetic recombination in rat hepatoma mtDNA, even in the same cell line used by Corral et al. Rather, they support the conclusion that mtDNA from tumor and normal tissues exhibits a low degree of heterogeneity.

Size distributions of circular molecules in plant mitochondrial DNAs

Some physicochemical properties of the mitochondrial DNAs (mtDNA) from plants of flax, broad bean and mung bean, and from tissue culture cells of jimson weed, soybean, petunia and tobacco were determined. Circular molecules were observed in electron microscope preparations of each mtDNA. In soybean, petunia, broad bean and mung bean mtDNAs, the circular molecules had a continuous distribution of lengths (ranges between 1 to 36 kb, and 1 to 126 kb), heavily skewed toward smaller molecules. Eighty-six percent of the flax circular molecules were from 27 to 54 kb in size, and 78% of the jimson weed circular molecules were from 4 to 15 kb. Replicative forms of 1.2-1.6 kb circular molecules were observed in electron microscope preparations of broad bean mtDNA.

Structural basis for restriction-site polymorphism at the albumin locus in inbred strains of rats

Two types of variant EcoRI restriction enzyme patterns of albumin-gene DNA fragments are found in different inbred strains of rats and reflect allelic polymorphism. The structural basis of the two allelic forms has been analyzed by mapping the EcoRI fragments using cloned albumin cDNA probes corresponding to the 5' or 3' end of the rat albumin mRNA and different genomic subclones. Additional restriction fragment length polymorphism has been detected using the restriction endonucleases HindIII and MspI. The results suggest that the two allelic variants differ from each other by multiple cleavage-site variations (base-pair substitutions) and by an insertion or deletion of DNA sequences. An extensive DNA sequence variation appears to exist between the two forms of the albumin gene; we have estimated that as much as 4% of the nucleotides in this region varied between the two alleles. All of this genetic variation is found in the intervening sequences of the gene and has no phenotypic manifestation.

Structural variants of the alpha-fetoprotein gene in different inbred strains of rat

Two structural variants of the rat alpha-fetoprotein (AFP) gene have been detected in different inbred strains of rats by EcoRI or HindIII restriction enzyme cleavage of cellular DNA, agarose gel electrophoresis and Southern blot hybridization using 32P-labeled cloned rat AFP cDNA probes. The type I AFP gene variant is characteristic of the Sprague-Dawley strain, and type II is found in Buffalo rats. These variants appear to represent two different allelic forms of the rat AFP gene since they are inherited in a normal Mendelian fashion when Sprague-Dawley and Buffalo rats are crossed. The mapping results suggest that the two allelic variants differ from each other by multiple cleavage site variations (base pair substitutions) and by an insertion or deletion of DNA sequences. An extensive sequence variation appears to exist between the two forms of the rat AFP gene; we have estimated that as much as 2.7% of the nucleotides in this region vary between the two alleles.

Intraspecific nucleotide sequence variability surrounding the origin of replication in human mitochondrial DNA

We have cloned the major noncoding region of human mitochondrial DNA (mtDNA) from 11 human placentas. Partial nucleotide sequences of five of these clones have been determined and they share a maximum of 900 bp around the origin of H-strand replication. Alignment of these sequences with others previously determined has revealed a striking pattern of nucleotide substitutions and insertion/deletion events. The level of sequence divergence significantly exceeds the reported estimates of divergence in coding regions. Two particularly hypervariable regions have also been defined. More than 96% of the base changes are transitions, and length alterations have occurred exclusively by addition or deletion of mono-or dinucleotide segments within serially repeating stretches. This region of the mitochondrial genome, which contains the initiation sites for replication and transcription, is the least conserved among species with respect to both sequence and length (Anderson et al., 1981; Walberg and Clayton, 1981). Despite this overall lack of primary sequence conservation, several consistencies appear among the available mammalian mtDNA sequences within this region. Between species, a conserved linear array of characteristic stretches exists which nonetheless differ in primary sequence. Among humans, several conserved blocks of nucleotides appear within domains deleted from the mtDNA of other species. These observations are consistent with both a species-specificity of nucleotide sequence, and a preservation of the necessary genetic functions among species. This provides a model for the evolution of protein-nucleic acid interactions in mammalian mitochondria.

Eco RI restriction-site polymorphism of the albumin gene in different inbred strains of rat

Two types of variant EcoRI restriction enzyme patterns of albumin-gene DNA fragments have been detected in different rat strains by agarose gel electrophoresis and Southern blot hybridization using 32P-labeled cloned rat albumin cDNA probes. The type I albumin gene variant is characteristic of the Sprague-Dawley strain, and type II is found in Buffalo rats. The occurrence of these variants is interpreted as the result of simple allelic polymorphism because they are inherited in a normal Mendelian fashion when crossing Sprague-Dawley and Buffalo rats. The distribution of the two genetic variants in various inbred strains of rat suggests that type I represents the original or ancestral form of the albumin gene and that type II appeared spontaneously during laboratory breeding.

Drosophila mitochondrial DNA: a novel gene order

Part of the replication origin-containing A+T-rich region of the Drosophila yakuba mtDNA molecule and segments on either side of this region have been sequenced, and the genes within them identified. The data confirm that the small and large rRNA genes lie in tandem adjacent to that side of the A+T-rich region which is replicated first, and establish that a tRNAval gene lies between the two rRNA genes and that URF1 follows the large rRNA gene. The data further establish that the genes for tRNAile, tRNAgln, tRNAf-met and URF2 lie in the order given, on the opposite side of the A+T-rich region to the rRNA genes and, except for tRNAgln, are contained in the opposite strand to the rRNA, tRNAval and URF1 genes. This is in contrast to mammalian mtDNAs where all of these genes are located on the side of the replication origin which is replicated last, within the order tRNAphe, small (12S) rRNA, tRNAval, large (16S) rRNA, tRNAleu, URF1, tRNAile, tRNAgln, tRNAf-met and URF2, and, except tRNAgln, are all contained in the same (H) strand. In D. yakuba URF1 and URF2, the triplet AGA appears to specify an amino acid, which is again different from the situation found in mammalian mtDNAs, where AGA is used only as a rare termination codon.

Nucleotide sequence of Rattus norvegicus mitochondrial DNA that includes the genes for tRNAile, tRNAgln and tRNAf-met

The nucleotide sequence of a segment of mtDNA from Rattus norvegicus (rat) which contains the genes for tRNAile, tRNAgln and tRNAf-met has been determined. A detailed comparison has been made between this sequence and the corresponding sequences of mouse, human and bovine mtDNAs with regard to the primary and secondary structure of the tRNA genes, the regions connecting the tRNA genes, and the regions flanking the tRNA genes which code for the carboxyl terminus of URF-1 and the amino terminus of URF-2. No differences were found in the nucleotide sequences of the genes for tRNAile, tRNAgln and tRNAf-met in mtDNAs from three different female lines of rats (SASCO-1, SASCO-2 and Wild-UT) that differ by substitutions of 0.8% to 1.8% of their total nucleotides.

Mitochondrial DNA polymorphism in a maternal lineage of Holstein cows

Two mitochondrial genotypes are shown to exist within one Holstein cow maternal lineage. They were detected by the appearance of an extra Hae III recognition site in one genotype. The nucleotide sequence of this region has been determined and the genotypes are distinguished by an adenine/guanine base transition which creates the new Hae III site. This point mutation occurs within an open reading frame at the third position of a glycine codon and therefore does not alter the amino acid sequence. The present pattern of genotypes within the lineage demands that multiple shifts between genotypes must have occurred within the past 20 years with the most rapid shift taking place in no more than 4 years and indicates that mitochondrial DNA polymorphism can occur between maternally related mammals. The process that gave rise to different genotypes in one lineage is clearly of fundamental importance in understanding intraspecific mitochondrial polymorphism and evolution in mammals. Several potential mechanisms for rapid mitochondrial DNA variation are discussed in light of these results.

Mitochondrial DNA sequences of primates: tempo and mode of evolution

We cloned and sequenced a segment of mitochondrial DNA from human, chimpanzee, gorilla, orangutan, and gibbon. This segment is 896 bp in length, contains the genes for three transfer RNAs and parts of two proteins, and is homologous in all 5 primates. The 5 sequences differ from one another by base substitutions at 283 positions and by a deletion of one base pair. The sequence differences range from 9 to 19% among species, in agreement with estimates from cleavage map comparisons, thus confirming that the rate of mtDNA evolution in primates is 5 to 10 times higher than in nuclear DNA. The most striking new finding to emerge from these comparisons is that transitions greatly outnumber transversions. Ninety-two percent of the differences among the most closely related species (human, chimpanzee, and gorilla) are transitions. For pairs of species with longer divergence times, the observed percentage of transitions falls until, in the case of comparisons between primates and non-primates, it reaches a value of 45. The time dependence is probably due to obliteration of the record of transitions by multiple substitutions at the same nucleotide site. This finding illustrates the importance of choosing closely related species for analysis of evolutionary process. The remarkable bias toward transitions in mtDNA evolution necessitates the revision of equations that correct for multiple substitutions at the same site. With revised equations, we calculated the incidence of silent and replacement substitutions in the two protein-coding genes. The silent substitution rate is 4 to 6 times higher than the replacement rate, indicating strong functional constraints at replacement sites. Moreover, the silent rate for these two genes is about 10% per million years, a value 10 times higher than the silent rate for the nuclear genes studied so far. In addition, the mean substitution rate in the three mitochondrial tRNA genes is at least 100 times higher than in nuclear tRNA genes. Finally, genealogical analysis of the sequence differences supports the view that the human lineage branched off only slightly before the gorilla and chimpanzee lineages diverged and strengthens the hypothesis that humans are more related to gorillas and chimpanzees than is the orangutan.

Novel features of animal mtDNA evolution as shown by sequences of two rat cytochrome oxidase subunit II genes

The sequence of the region of the mitochondrial genome that encodes cytochrome oxidase subunit II (COII) has been determined for each of two closely related rat species, Rattus norvegicus and R. rattus. Comparison of the two sequences shows that 94.4% of the nucleotide substitutions are silent. The occurrence of this high proportion of silent substitutions leads us to propose that the rapid evolution of mtDNA relative to nuclear DNA is due only to silent changes and that amino acid-altering substitutions accumulate in nuclear and mtDNA at comparable rates. Other novel features of the nucleotide substitution pattern in the rat COII gene are a high transition/transversion ratio (8.0:1) and a strong bias toward C in equilibrium T transitions in the light strand. Comparison of the R. norvegicus COII sequence with the bovine and human sequences show that there may be selective constraints on some silent positions within the gene and that its rate of evolution may be different in different mammalian lineages.

Polymorphisms of mitochondrial DNAs in Norway rats (Rattus norvegicus): cleavage site variations and length polymorphism of restriction fragments

Extensive polymorphism was found in mitochondrial DNAs (mtDNAs) of Norway rats (Rattus norvegicus). The restriction endonuclease cleavage patterns of mtDNAs of laboratory rats, wild rats, tumor cells, and culture cells were compared. The polymorphism is defined by two criteria; one is cleavage site variation and the other is length polymorphism of restriction fragments. The cleavage site variation may be caused by point mutation, and the length polymorphism by sequence deletions or insertions. At least five types, types A-E, were identified by cleavage site variations, and two groups, a and b, were identified by length polymorphism of one HpaII fragment, Hpa5. All types except type C belonged to either group-a or group-b, whereas both groups were found in type C. Differentiation of polymorphic Norway rat mtDNA types and the experimental use of the polymorphism are discussed.