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 flbroblast (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 ~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 aMDP1 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, ~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 crosscompetition 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. © 1992.