Catenated oligomeric circular DNA molecules from mitochondria of malignant and normal mouse and rat tissues

Complete mtDNA sequences of two millipedes suggest a new model for mitochondrial gene rearrangements: duplication and nonrandom loss

We determined the complete mitochondrial DNA (mtDNA) sequences of the millipedes Narceus annularus and Thyropygus sp. (Arthropoda: Diplopoda) and identified, in both genomes, all 37 genes typical for metazoan mtDNA. The arrangement of these genes is identical in the two millipedes, but differs from others found in arthropod mtDNAs in the location of at least four genes or gene blocks. This novel gene arrangement is unusual for animal mtDNA in that genes with identical transcriptional polarities are clustered in the genome, and the two clusters are separated by two noncoding regions. The only exception to this pattern is the gene for cysteine tRNA, which is located in the part of the genome that otherwise contains all genes with the opposite transcriptional polarity. We suggest that a mechanism involving complete mtDNA duplication followed by the loss of genes, predetermined by their transcriptional polarity and location in the genome, could generate this gene arrangement from the one ancestral for arthropods. The proposed mechanism has important implications for phylogenetic inferences that are drawn on the basis of gene arrangement comparisons.

Complex mitochondrial DNA in animal thyroids. A comparative study

1. The frequency of circular dimers and catenanes was determined in thyroid mitochondrial DNA (mtDNA) from rabbits, mice, pigs, sheep and cattle. 2. The mtDNA from freshly removed thyroids was isolated by buoyant density centrifugation in ethidium bromide/CsCl gradients after DNAase treatment of the mitochondrial pellet. Typically, more than 90% of the recovered mtDNA was found in the lower band, indicating a low rate of nicking during isolation. A sample of the total mtDNA (upper and lower bands) was examined by electron microscopy after preparation by the aqueous protein film technique. 3. The frequency of circular dimers generally ranged from 0.1 to 0.3%. However, in an mtDNA sample from cow thyroid, the frequency of circular dimers was 0.6% (0.9% if circular dimers occuring in catenanes are included(, differing significantly from the frequency of these forms in bull thyroid, 0.1%. A small but significant variability also occurred in the frequency of catenanes ranging from 2 to 8% in the different groups; this variation is within the limits usually observed in normal tissues. 4. These observations indicate that thyroids, like other normal tissues examined so far, have a low content of circular dimers. A high frequency of these forms seems to be the trademark of some genetically and physiologically abnormal cells such as certain established cell lines, virus-transformed cells and malignant or otherwise pathological tissues.

An electron microscope study of mitochondrial DNA in spontaneous human tumours and chemically induced animal tumours

MtDNA was extracted by a phenol method from transplanted and primary DAB induced hepatomata in male Wistar rats, normal rat liver, spontaneous human tumours (2 Wilm's tumours, one neuroblastoma and one adrenal carcinoma), as well as 2 specimens of normal human kidney, BNU induced "leukaemias" in mice and CHO fibroblasts in monolayer culture. The proportion of monomers, catenated dimers and oligomers, open dimers and small circles was determined by electron microscopy of the fractions comprising lower and middle DNA bands in a CsCl-EthBr gradient. Tumours were compared where possible with their normal tissue of origin. Open dimers were found in 2 Wilm's tumours and their attached "normal-looking" kidney tissue but not in normal, non-malignant kidney or any other tissue studied. In Wilm's tumours, the occurrence of open dimers is far from being an all-or-none phenomenon. Malignancy produced little change in the relative proportions of catenated dimers and oligomers in the tissues studied. Small circles were found associated with mtDNA from every tissue. Tumour mtDNA was not more heterogeneous in length than monomers from the corresponding normal tissue, neither was the mean length of tumour mtDNA significantly different from its corresponding normal mtDNA.