Sea urchin mtDBP is a two-faced transcription termination factor with a biased polarity depending on the RNA polymerase.

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.

Regulation of the expression of the sea urchin mitochondrial D-loop binding protein during early development.

The Paracentrotus lividus mitochondrial D-loop binding protein (mtDBP) is a DNA-binding protein which is involved in the regulation of sea urchin mtDNA transcription. Immunoblots of Heparin Sepharose-bound proteins at selected early developmental stages, as well as electrophoretic mobility shift assay, show that mtDBP is present in the egg at a concentration of about 1 x 10(6) molecules/egg. Its level increases after fertilization of about twofold, remaining substantially unchanged between 16-h blastula stage and early pluteus stage and declines thereafter. The content of mtDBP mRNA, determined by RNase protection experiments, increases about sevenfold at the 16-h blastula stage compared to the egg. A considerable decrease occurs at the 40-h pluteus stage, which precedes that of the protein. These results suggest that the expression of mtDBP is regulated at transcriptional level up to blastula stage, while other factors, in addition to the level of the RNA, may control the content of this protein in the following stages of embryogenesis.

Identification of human GC-box-binding zinc finger protein, a new Krüppel-like zinc finger protein, by the yeast one-hybrid screening with a GC-rich target sequence.

A new human zinc finger DNA-binding protein was identified by using a yeast one-hybrid selection system. Two versions of the cDNA, encoding the same protein, were detected that differ for a 584 bp extension at the 5' region. Sequence analysis showed that the longer clone is a full length version containing part of the 5' untranslated region. The smaller version was fused in frame with the yeast GAL4 activation domain whereas the 5' region of the longer clone displayed a stop codon interrupting the fusion with the GAL4 domain. Nevertheless, this clone activated the yeast HIS3 reporter gene with the same efficiency as the smaller version. Sequence comparison of the derived protein with the database showed that it belongs to a family of zinc finger DNA-binding proteins which regulate the expression of genes involved in cell proliferation. Expression of the protein in an in vitro system, DNA-binding studies and genetic experiments identify this factor as a new zinc finger DNA-binding protein which binds GC-rich sequences and contains a domain probably functioning as a transcriptional activator. The new human protein identified in this study was therefore named GC-box-binding zinc finger protein).

In vivo mitochondrial DNA-protein interactions in sea urchin eggs and embryos.

Footprinting studies with the purine-modifying agent dimethyl sulphate were performed in Paracentrotus lividus eggs and embryos to analyze in vivo the interactions between protein and mitochondrial DNA. Footprinting in the small non-coding region and at the boundary between the ND5 and ND6 genes revealed two strong contact sites corresponding with the in vitro binding sequences of mitochondrial D-loop-Binding Protein (mtDBP). The analysis of the pause region of mtDNA replication showed a strong footprint corresponding with the binding site of the mitochondrial Pause region-Binding Protein-2 (mtPBP-2), but only a very weak signal at the binding site of the mitochondrial Pause region-Binding Protein-1 (mtPBP-1), which in vitro binds DNA with high efficiency. In vitro and in vivo analysis of the 3' end-region of the two rRNA genes showed no significant protein-DNA interactions, suggesting that, in contrast to mammals, the 3' ends of sea urchin mitochondrial rRNAs are not generated by a protein-dependent transcription termination event. These and other data support a model in which expression of mitochondrial genes in sea urchins is regulated post-transcriptionally. Footprinting at the five AT-rich consensus regions allowed the detection of a binding site in the non-coding region for an as-yet unidentified protein, mtAT-1BP. The occupancy of this site appears to be developmentally regulated, being detectable in the pluteus larval stage, but not in unfertilized eggs.

Multiple protein-binding sites in the TAS-region of human and rat mitochondrial DNA.

To study the molecular mechanisms responsible for the regulation of mitochondrial DNA copy number, in vivo and in organello dimethyl sulfate footprinting experiments in human fibroblasts and rat liver mitochondria were carried out. By this approach we identified in both species two specific protein binding sites in the 3' region of the displacement loop of mitochondrial DNA. One site contains the TAS-D element of human and rat mitochondrial DNA; the other covers TAS-C and TAS-B in human, whereas in rat it comprises part of TAS-B. We suggest that the protected sequences might be the site of action of protein factors involved in the premature termination of mitochondrial DNA heavy-strand synthesis.

DNA-helicase activity from sea urchin mitochondria.

As a step toward the characterization of the main components of mitochondrial DNA replication apparatus in sea urchin, we report the identification of a DNA-helicase activity in Paracentrotus lividus mitochondria. The activity was detected in a protein fraction obtained by fractionating on DEAE-Sephacel a lysate of gradient purified mitochondria from paracentrotus lividus eggs. The mitochondrial helicase unwound, in the presence of ATP and Mg++, a 39-base oligonucleotide annealed to single-stranded M13mp18 (+) DNA. Its direction of movement is 3' to 5' with respect to the single stranded portion of the partial duplex DNA substrate. This polarity is similar to that exhibited by the Escherichia coli rep helicase and by the helicase from bovine brain mitochondria. These features suggest that the sea urchin mitochondrial helicase could function in enabling the polymerization of the H-strand during mitochondrial DNA replication.

Purification and characterization of a mitochondrial DNA-binding protein that binds to double-stranded and single-stranded sequences of Paracentrotus lividus mitochondrial DNA.

A mitochondrial protein, able to specifically bind two double-stranded homologous sequences of sea-urchin mitochondrial DNA, has been partially purified from Paracentrotus lividus eggs. This protein, present at a low concentration, is a polypeptide of 40 kDa. One of the binding sequences, located in the main non-coding region, contains the replication origin of the mitochondrial DNA H-strand. By a combination of band-shift, DNase footprinting, and modification interference analyses with homologous and heterologous probes we identified YCYYATCAN(A/T)RC as the minimum sequence required for the binding. The protein also shows a single-stranded DNA-binding activity, as it is able to specifically interact with one of the strands of the binding sites. These features are consistent with a function of the protein in the modulation of sea-urchin mitochondrial DNA replication during the development stages.

Distinctive pattern and translational control of mitochondrial protein synthesis in rat brain synaptic endings.

Mitochondrial gene expression has been investigated in synaptic endings from rat cerebral cortex isolated at various stages during the postnatal development and maturation of the animal. The pattern of the mitochondrial translation products labeled in vitro in rat brain synaptosomes revealed some distinctive features when compared with the pattern observed in a rat fibroblast cell line, the most remarkable being the apparent absence of labeling of the ND5 product. This absence contrasted with the presence in synaptosomes of an amount of ND5 mRNA comparable with that found in the rat fibroblast cell line. The rate of mitochondrial protein synthesis per unit amount of mtDNA in brain synaptosomes showed a characteristic reproducible burst at 10-13 days after birth, thereafter declining sharply in the 3rd week to reach a level that remained constant over a 2-year period. The postnatal burst of mitochondrial protein synthesis coincided with a sharp increase in cytochrome c oxidase activity, pointing to a phase of rapid assembly of respiratory complexes. A comparison of the levels of mitochondrial mRNAs with the corresponding rates of protein synthesis during the animal development and maturation showed a lack of correlation. These observations, together with the apparent lack of translation of the ND5 mRNA, indicate that translational control plays a major role in the regulation of gene expression in rat brain synaptic mitochondria.

Quantitation of mitochondrial RNA species during rat liver development: the concentration of cytochrome oxidase subunit I (CoI) mRNA increases at birth.

A quantitative study on the concentration of mitochondrial DNA and two species of mtRNA, the ribosomal (16S rRNA) and messenger (CoI mRNA) has been carried out in rat liver between -3 and 14 days of age. The cellular content of mitochondrial DNA begins to increase at one day of life and goes up linearly until 14 days of age. The cellular level of 16S rRNA and CoI mRNA changes during development: the 16S rRNA increases linearly after birth, whereas CoI mRNA shows a peak at birth and thereafter remains more or less constant. The concentration of 16S rRNA per mitochondrial DNA molecule remains substantially unchanged during development, whereas that of CoI mRNA increases before birth and, at birth, reaches values higher than in adults. These results support an independent regulation of mitochondrial rRNA and mRNA level in rat liver mitochondria during development.