Human mitochondrial termination factor is a DNA-binding protein that acts as a transcription termination factor. Six repeats occur in human mTERF, that also are present in numerous plant proteins.
This entry represents the mitochondrial/chloroplastic transcription termination factors (MTERFs). In humans four MTERFs have been identified (MTERF1-4). MTERF1 was first identified as a factor responsible for terminating heavy strand transcription at a specific site at the leu-tRNA, thereby modulating the ratio of mitochondrial ribosomal RNA to mRNA [ (PUBMED:2752429) ]. Later, MTERF1 was found to stimulate transcriptional initiation [ (PUBMED:19366610) ] and appeared to be in the control of mitochondrial replication pausing [ (PUBMED:17884915) ]. From a structural study, it binds to dsDNA containing the termination sequence and unwinds the DNA molecule, promoting base eversion, which is critical for transcription termination [ (PUBMED:20550934) ].
GO process:
regulation of transcription, DNA-templated (GO:0006355)
The role of lineage-specific gene family expansion in the evolution of eukaryotes.
Genome Res. 2002; 12: 1048-59
Display abstract
A computational procedure was developed for systematic detection of lineage-specific expansions (LSEs) of protein families in sequenced genomes and applied to obtain a census of LSEs in five eukaryotic species, the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe, the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster, and the green plant Arabidopsis thaliana. A significant fraction of the proteins encoded in each of these genomes, up to 80% in A. thaliana, belong to LSEs. Many paralogous gene families in each of the analyzed species are almost entirely comprised of LSEs, indicating that their diversification occurred after the divergence of the major lineages of the eukaryotic crown group. The LSEs show readily discernible patterns of protein functions. The functional categories most prone to LSE are structural proteins, enzymes involved in an organism's response to pathogens and environmental stress, and various components of signaling pathways responsible for specificity, including ubiquitin ligase E3 subunits and transcription factors. The functions of several previously uncharacterized, vastly expanded protein families were predicted through in-depth protein sequence analysis, for example, small-molecule kinases and methylases that are expanded independently in the fly and in the nematode. The functions of several other major LSEs remain mysterious; these protein families are attractive targets for experimental discovery of novel, lineage-specific functions in eukaryotes. LSEs seem to be one of the principal means of adaptation and one of the most important sources of organizational and regulatory diversity in crown-group eukaryotes. [Supplemental material is available online at ftp://ncbi.nlm.nih.gov/pub/aravind/expansions, and http://www.genome.org.]
Sea urchin mtDBP is a two-faced transcription termination factor with a biased polarity depending on the RNA polymerase.
Nucleic Acids Res. 2001; 29: 4736-43
Display abstract
The sea urchin mitochondrial displacement (D)-loop binding protein mtDBP has been previously identified and cloned. The polypeptide (348 amino acids) displays a significant homology with the human mitochondrial transcription termination factor mTERF. This similarity, and the observation that the 3' ends of mitochondrial RNAs coded by opposite strands mapped in correspondence of mtDBP-binding sites, suggested that mtDBP could function as transcription termination factor in sea urchin mitochondria. To investigate such a role we tested the capability of mtDBP bound to its target sequence in the main non-coding region to affect RNA elongation by mitochondrial and bacteriophage T3 and T7 RNA polymerases. We show that mtDBP was able to terminate transcription bidirectionally when initiated by human mitochondrial RNA polymerase but only unidirectionally when initiated by T3 or T7 RNA polymerases. Time-course experiments indicated that mtDBP promotes true transcription termination rather than transcription pausing. These results indicate that mtDBP is able to function as a bipolar transcription termination factor in sea urchin mitochondria. The functional significance of such an activity could be linked to the previously proposed dual role of the protein in modulating mitochondrial DNA transcription and replication.
Cloning and characterisation of mtDBP, a DNA-binding protein which binds two distinct regions of sea urchin mitochondrial DNA.
Nucleic Acids Res. 1999; 27: 1890-9
Display abstract
The cDNA for the sea urchin mitochondrial D-loop-binding protein (mtDBP), a 40 kDa protein which binds two homologous regions of mitochondrial DNA (the D-loop region and the boundary between the oppositely transcribed ND5 and ND6 genes), has been cloned. Four different 3'-untranslated regions have been detected that are related to each other in pairs and do not contain the canonical polyadenylation signal. The in vitro synthesised mature protein (348 amino acids), deprived of the putative signal sequence, binds specifically to its DNA target sequence and produces a DNase I footprint identical to that given by the natural protein. mtDBP contains two leucine zippers, one of which is bipartite, and two small N- and C-terminal basic domains. A deletion mutation analysis of the recombinant protein has shown that the N-terminal region and the two leucine zippers are necessary for the binding. Furthermore, evidence was provided that mtDBP binds DNA as a monomer. This rules out a dimerization role for the leucine zippers and rather suggests that intramolecular interactions between leucine zippers take place. A database search has revealed as the most significative homology a match with the human mitochondrial transcription termination factor (mTERF), a protein that also binds DNA as a monomer and contains three leucine zippers forming intramolecular interactions. These similarities, and the observation that mtDBP-binding sites contain the 3'-ends of mtRNAs coded by opposite strands and the 3'-end of the D-loop structure, point to a dual function of the protein in modulating sea urchin mitochondrial DNA transcription and replication.
The human mitochondrial transcription termination factor (mTERF) is a multizipper protein but binds to DNA as a monomer, with evidence pointing to intramolecular leucine zipper interactions.
EMBO J. 1997; 16: 1066-79
Display abstract
The human mitochondrial transcription termination factor (mTERF) cDNA has been cloned and expressed in vitro, and two alternative precursors of the protein have been imported into isolated mitochondria and processed to the mature protein. The precursors contain a mitochondrial targeting sequence, and the mature mTERF (342 residues) exhibits three leucine zippers, of which one is bipartite, and two widely spaced basic domains. The in vitro synthesized mature protein has the expected specific binding capacity for a double-stranded oligonucleotide containing the tridecamer sequence required for directing termination, and produces a DNase I footprint very similar to that produced by the natural protein. However, in contrast to the latter, it lacks transcription termination-promoting activity in an in vitro system, pointing to another component(s) being required for making mTERF termination-competent. A detailed structure-function analysis of the recombinant protein and mutagenized versions of it by band shift assays has demonstrated that both basic domains and the three leucine zipper motifs are necessary for DNA binding. Furthermore, a variety of tests have shown that both the recombinant and the natural mTERF bind to DNA as a monomer, arguing against a dimerization role for the leucine zippers, and rather pointing, together with the results of mutagenesis experiments, to intramolecular leucine zipper interactions being required to bring the two basic domains in close register with the mTERF target DNA sequence.
