Signals and receptors--the translocation machinery on the mitochondrial surface

A novel N-terminal domain may dictate the glucose response of Mondo proteins

Glucose is a fundamental energy source for both prokaryotes and eukaryotes. The balance between glucose utilization and storage is integral for proper energy homeostasis, and defects are associated with several diseases, e.g. type II diabetes. In vertebrates, the transcription factor ChREBP is a major component in glucose metabolism, while its ortholog MondoA is involved in glucose uptake. Both MondoA and ChREBP contain five Mondo conserved regions (MCRI-V) that affect their cellular localization and transactivation ability. While phosphorylation has been shown to affect ChREBP function, the mechanisms controlling glucose response of both ChREBP and MondoA remain elusive. By incorporating sequence analysis techniques, structure predictions, and functional annotations, we synthesized data surrounding Mondo family proteins into a cohesive, accurate, and general model involving the MCRs and two additional domains that determine ChREBP and MondoA glucose response. Paramount, we identified a conserved motif within the transactivation region of Mondo family proteins and propose that this motif interacts with the phosphorylated form of glucose. In addition, we discovered a putative nuclear receptor box in non-vertebrate Mondo and vertebrate ChREBP sequences that reveals a potentially novel interaction with nuclear receptors. These interactions are likely involved in altering ChREBP and MondoA conformation to form an active complex and induce transcription of genes involved in glucose metabolism and lipogenesis.

Evidence of an intact N-terminal translocation sequence of human mitochondrial adenylate kinase 4

Adenylate kinases are abundant nucleoside monophosphate kinases, which catalyze the phosphorylation of AMP by using ATP or GTP as phosphate donors. A previously cloned cDNA was named adenylate kinase 4 (AK4) based on its sequence similarity with known AKs but with no confirmed AK enzyme activity. In the present study the AK4 cDNA was expressed in Escherichia coli and the substrate specificity and kinetic properties of the recombinant protein were characterized. The enzyme catalyzed the phosphorylation of AMP, dAMP, CMP and dCMP with ATP or GTP as phosphate donors and AK4 also phosphorylated AMP with UTP as phosphate donor. The kinetic parameters of the enzyme were determined for AMP and dAMP with ATP as phosphate donor and for AMP with GTP as phosphate donor. AK4 showed its highest efficiency when phosphorylating AMP with GTP and a slightly lower efficiency for the phosphorylation of AMP with ATP. Among the three reactions for which kinetics were performed, dAMP was the poorest substrate. The AK4 mitochondrial localization was confirmed by expression of AK4 as a fusion protein with GFP in HeLa cells. The mitochondrial import sequence was shown to be located within the first N-terminal 11 amino acid residues, very close to the ATP-binding region of the enzyme. Import analysis suggested that the mitochondrial import sequence was not cleaved and thus the enzyme retained its activity upon entering the mitochondria. Site directed mutagenesis of amino acids Lys 4 and Arg 7 showed that these two residues were essential for mitochondrial import.

A co-translational model to explain the in vivo import of proteins into HeLa cell mitochondria

The dual signal approach, i.e. a mitochondrial signal at the N-terminus and an ER (endoplasmic reticulum) or a peroxisomal signal at the C-terminus of EGFP (enhanced green fluorescent protein), was employed in transfected HeLa cells to test for a co-translational import model. The signal peptide from OTC (ornithine transcarbamylase) or arginase II was fused to the N-terminus of EGFP, and an ER or peroxisomal signal was fused to its C-terminus. The rationale was that if the free preprotein remained in the cytosol, it could be distributed between the two organelles by using a post-translational pathway. The resulting fusion proteins were imported exclusively into mitochondria, suggesting that co-translational import occurred. Native preALDH (precursor of rat liver mitochondrial aldehyde dehydrogenase), preOTC and rhodanese, each with the addition of a C-terminal ER or peroxisomal signal, were also translocated only to the mitochondria, again showing that a co-translational import pathway exists for these native proteins. Import of preALDH(sp)-DHFR, a fusion protein consisting of the leader sequence (signal peptide) of preALDH fused to DHFR (dihydrofolate reductase), was studied in the presence of methotrexate, a substrate analogue for DHFR. It was found that 70% of the preALDH(sp)-DHFR was imported into mitochondria in the presence of methotrexate, implying that 70% of the protein utilized the co-translational import pathway and 30% used the post-translational import pathway. Thus it appears that co-translational import is a major pathway for mitochondrial protein import. A model is proposed to explain how competition between binding factors could influence whether or not a cytosolic carrier protein, such as DHFR, uses the co- or post-translational import pathway.

The N-terminal sequence directs import of mitochondrial alanine aminotransferase into mitochondria

Herein, we report cloning and subcellular localization of two alanine aminotransferase (ALT) isozymes, cALT and mALT, from liver of gilthead sea bream (Sparus aurata). CHO cells transfected with constructs expressing cALT or mALT as C- or N-terminal fusion with the enhanced green fluorescent protein (EGFP) showed that cALT is cytosolic, whereas mALT localized to mitochondria. Fusion of EGFP to mALT N-terminus or removal of amino acids 1-83 of mALT avoided import into mitochondria, supporting evidence that the mALT N-terminus contains a mitochondrial targeting signal. The amino acid sequence of mALT is the first reported for a mitochondrial ALT in animals.

Structural and guanosine triphosphate/diphosphate requirements for transit peptide recognition by the cytosolic domain of the chloroplast outer envelope receptor, Toc34

Toc34 is a transmembrane protein located in the outer envelope membrane of chloroplasts and involved in transit peptide recognition. The cytosolic region of Toc34 reveals 34% alpha-helical and 26% beta-strand structure and is stabilized by intramolecular electrostatic interaction. Toc34 binds both chloroplast preproteins and isolated transit peptides in a guanosine triphosphate- (GTP-) dependent mechanism. In this study we demonstrate that the soluble, cytosolic domain of Toc34 (Toc34deltaTM) functions as receptor in vitro and is capable to compete with the import of the preprotein of the small subunit (preSSU) of ribulose-1,5-bisphosphate carboxylase-oxygenase into chloroplasts in a GTP-dependent manner. We have developed a biosensor assay to study the interaction of Toc34deltaTM with purified preproteins and transit peptides. The results are compared with the interactions of both a full-size preprotein and the transit peptide of preSSU with the translocon of the outer envelope of chloroplasts (Toc complex) in situ. Several mutants of the transit peptide of preSSU were evaluated to identify amino acid segments that are specifically recognized by Toc34. We present a model of how Toc34 may recognize the transit peptide and discuss how this interaction may facilitate interaction and translocation of preproteins via the Toc complex in vivo.

Cloning and characterization of a 35-kDa mouse mitochondrial outer membrane protein MOM35 with high homology to Tom40

We have cloned a 35-kDa protein from a mouse cDNA library with a 25% overall amino acid identity to yTom40 and 27% identity to nTom40. This homolog toTom40 was named MOM35. It contains two possible start codons 36 amino acids apart from each other. Both the long and the short version of MOM35 can be imported in vitro into mouse mitochondria. The identified protein is imported into the outer mitochondrial membrane and comprises a trypsin-resistance pattern similar to that of nTom40. Tom40 of N. crassa, S. cerevisiae, and the protein identified herein contains a highly conserved region with possible physiological importance. Subsequent investigation has revealed that this region interacts specifically in vitro with preproteins proposed to be imported by a Tom40-dependent pathway.