The effect of retroviral transformation on DNA replication and DNA polymerase-gamma activity in chick embryo fibroblast mitochondria

Stability and Association with the Cytomatrix of Mitochondrial DNA in Spontaneously Immortalized Mouse Embryo Fibroblasts Containing or Lacking the Intermediate Filament Protein Vimentin

To extend previous observations demonstrating differences in number, morphology, and activity of mitochondria in spontaneously immortalized vim(+) and vim(-) fibroblasts derived from wild-type and vimentin knockout mice, some structural and functional aspects of mitochondrial genome performance and integrity in both types of cells were investigated. Primary Vim(+/+) and Vim(-/-) fibroblasts, which escaped terminal differentiation by immortalization were characterized by an almost twofold lower mtDNA content in comparison to that of their primary precursor cells, whereby the average mtDNA copy number in two clones of vim(+) cells was lower by a factor of 0.6 than that in four clones of vim(-) cells. However, during serial subcultivation up to high passage numbers, the vim(+) and vim() fibroblasts increased their mtDNA copy number 1.5- and 2.5-fold, respectively. While early-passage cells of the vim(+) and vim(-) fibroblast clones differed only slightly in the ratio between mtDNA content and mitochondrial mass represented by mtHSP70 protein, after ca. 300 population doublings the average mtDNA/mtmass ratio in the vim(+) and vim() cells was increased by a factor of 2 and 4.5, respectively. During subcultivation, both types of cells acquired the fully transformed phenotype. These findings suggest that cytoskeletal vimentin filaments exert a strong influence on the mechanisms controlling mtDNA copy number during serial subcultivation of immortalized mouse embryo fibroblasts, and that vimentin deficiency causes a disproportionately enhanced mtDNA content in high-passage vim(-) fibroblasts. Such a role of vimentin filaments was supported by the stronger retention potential for mtDNA and mtDNA polymerase (gamma) detected in vim(+) fibroblasts by Triton X-100 extraction of mitochondria and agaroseembedded cells. Moreover, although the vim(+) and vim(-) fibroblasts were equally active in generating free radicals, the vim(-) cells exhibited higher levels of immunologically detectable 8-oxoG and mismatch repair proteins MSH2 and MLH1 in their mitochondria. Because in vim(-) fibroblasts only one point mutation was detected in the mtDNA D-loop control region, these cells are apparently able to efficiently remove oxidatively damaged nucleobases. On the other hand, a number of large-scale mtDNA deletions were found in high-passage vim(-) fibroblasts, but not in low-passage vim(-) cells and vim(+) cells of both low and high passage. Large mtDNA deletions were also induced in young vim(-) fibroblasts by treatment with the DNA intercalator ethidium bromide, whereas no such deletions were found after treatment of vim(+) cells. These results indicate that in immortalized vim(-) fibroblasts the mitochondrial genome is prone to large-scale rearrangements, probably due to insufficient control of mtDNA repair and recombination processes in the absence of vimentin.

Precise sequence assignment of replication origin in the control region of chick mitochondrial DNA relative to 5' and 3' D-loop ends, secondary structure, DNA synthesis, and protein binding

The data reported identify for the first time the sequence of an avian mitochondrial heavy-strand replication origin, OH, located only about 12 nucleotides (nt) downstream from the conserved sequence block CSB-1, as well as the sequence of premature synthesis arrest of the 781 (+/-1) nt D-loop strand, only 6-7 nt downstream from a TAS-like (termination-associated) element. Both sites are associated with putative cruciform secondary structures. A major sequence-specific DNA-binding/cleavage site of a potential regulatory protein, the approximately 36-kDa aMDP1 (shown previously to stimulate mtDNA synthesis), is located about 90 nt upstream of OH. Correlated in vivo analysis of avian genome-length mtDNA replication provides missing evidence on the functional equivalence of D-loop origin with nascent initiation, and on the direction, asymmetry and temporal aspects of a full round of replication. The importance of the results to understanding the regulation of linked replication/transcription and the unusual sequence evolution of avian mtDNA is

A new chick mitochondrial DNA-binding protein exhibits sequence-specific interaction near heavy-strand replication origin: cleavage activity, stimulation of mtDNA synthesis, and enhancement in transformed fibroblasts

We have identified a new, double-strand-dependent, mtDNA-binding protein in chick embryo fibroblast (CEF) mitochondria (and inner-membrane-matrix preparations) which demonstrates both an exclusive specific affinity for the displacement loop (D-loop) control region of chick mtDNA and intramitochondrial levels that reflect corresponding changes in mtDNA replication activity both in vivo and in vitro. This approximately 36 kDa protein (designated aMDP1, avian mitochondrial DNA-binding protein 1) was identified by elution and renaturation following SDS-polyacrylamide gel electrophoresis and by direct isolation from specific mtDNA-protein complexes excised from mobility shift gels. Analysis of the entire 16.7-kb mt genome determined that a MDP1 mediates cleavage of chick mtDNA in vitro at three H- and two L-strand sequence-specific target sites located within a 90-bp A + T-rich genomic tract, theoretically capable of forming stable secondary structures, approximately 200 bases upstream from the H-strand origin (OH) of replication. Furthermore, gel-isolated aMDP1 relaxes supercoiled mtDNA, and exogenous addition of the protein, in a permeabilized in vitro system, preferentially stimulates the synthesis of H-strand sequences which hybridize to OH-containing fragments. Oncogenic transformation of CEF by Rous sarcoma viruses results in a threefold elevated level of aMDP1, directly correlating with a similarly increased level of mtDNA replication in vivo. Heterologous chick-human cross-competition experiments showed that aMDP1 also selectively interacts with human (HeLa) D-loop region mtDNA, possibly reflective of an evolutionary importance for aMDP1 interaction in the region. Functionally, we hypothesize that aMDP1 may operate in conjunction with other mtDNA-binding proteins, important in replication and transcription, by potentiating duplex unwinding either prior to or during an initial stage of H-strand synthesis. Together, these results suggest that aMDP1 is a good potential candidate for a nucleus-encoded regulatory protein which communicates with the mt genome during the replication process.