Abhijit Mukhopadhyay scite author profile

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.

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Delivery of drugs and macromolecules to mitochondria☆

Mukhopadhyay

Weiner

2007

Advanced Drug Delivery Reviews

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Mitochondria is where the bulk of the cell's ATP is produced. Mutations occur to genes coding for members of the complexes involved in energy production. Some are a result of damages to nuclear coded genes and others to mitochondrial coded genes. This review describes approaches to bring small molecules, proteins and RNA/DNA into mitochondria. The purpose is to repair damaged genes as well as to interrupt mitochondrial function including energy production, oxygen radical formation and the apoptotic pathway.

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Precursor Protein Is Readily Degraded in Mitochondrial Matrix Space if the Leader Is Not Processed by Mitochondrial Processing Peptidase

Mukhopadhyay

Yang

Wei

et al. 2007

Journal of Biological Chemistry

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It is not known why leader peptides are removed by the mitochondrial processing peptidase after import into the matrix space. The leaders of yeast aldehyde dehydrogenase (pALDH) and malate dehydrogenase were mutated so that they would not be processed after import. The recombinant nonprocessed precursor of yeast pALDH possessed a similar specific activity as the corresponding mature form but was much less stable. The nonprocessed pALDH was transformed into a yeast strain missing ALDHs. The transformed yeast grew slowly on ethanol as the sole carbon source showing that the nonprocessed precursor was functional in vivo. Western blot analysis showed that the amount of precursor was 15-20% of that found in cells transformed with the native enzyme. Pulse-chase experiments revealed that the turnover rate for the nonprocessed precursor was greater than that of the mature protein indicating that the nonprocessed precursor could have been degraded. By using carbonyl cyanide m-chlorophenylhydrazone, we showed that the nonprocessed precursor was degraded in the matrix space. The nonprocessed precursor forms of precursor yeast malate dehydrogenase and rat liver pALDH also were degraded in the matrix space of HeLa cell mitochondria faster than their corresponding mature forms. In the presence of o-phenanthroline, an inhibitor of mitochondrial processing peptidase, the wild type precursor was readily degraded in the matrix space. Collectively, this study showed that the precursor form is less stable in the matrix space than is the mature form and provides an explanation for why the leader peptide is removed from the precursors.The vast majority of mitochondrial matrix space proteins are nuclear encoded and synthesized as precursor proteins with an extension of amino acids at their N-terminal end that functions as a mitochondrial import signal sequence (1, 2). After import, the leader sequence is removed by the action of a protease, the mitochondrial processing peptidase (3-6). It is not known why it is necessary for the leader to be removed. It was shown that pre-fumarase was less active than its mature form (7). In contrast, the recombinantly expressed rat liver pALDH 4 had essentially the same specific activity as the mature form of the enzyme, but the precursor was thermally less stable than was the mature form (8). It appears that in some cases removing the leader might produce a more stable mature protein.Deletion of the mitochondrial processing peptidase was lethal to aerobically growing yeast (9). This implies that in vivo it is necessary to convert some, if not all, of the precursor proteins to their mature counterpart. It is not known what is the fate of a precursor protein should it remained unprocessed. Recently, however, investigators found that the leaders cleaved by MPP are degraded to smaller fragments by two protease enzymes present in plant mitochondria and chloroplast (10). These enzymes are not reported to be found in yeast or mammalian cells. While studying structure/functional relationships of leader sequ...

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Location of the Actual Signal in the Negatively Charged Leader Sequence Involved in the Import into the Mitochondrial Matrix Space

Mukhopadhyay¹,

Heard²,

Hammen

et al. 2003

Journal of Biological Chemistry

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Proteins destined for the mitochondrial matrix space have leader sequences that are typically present at the most N-terminal end of the nuclear-encoded precursor protein. The leaders are rich in positive charges and usually deficient of negative charges. This observation led to the acid-chain hypothesis to explain how the leader sequences interact with negatively charged receptor proteins. Here we show using both chimeric leaders and one from isopropyl malate synthase that possesses a negative charge that the leader need not be at the very N terminus of the precursor. Experiments were performed with modified non-functioning leader sequences fused to either the native or a non-functioning leader of aldehyde dehydrogenase so that an internal leader sequence could exist. The internal leader is sufficient for the import of the modified precursor protein. It appears that this leader still needs to form an amphipathic helix just like the normal N-terminal leaders do. This internal leader could function even if the most N-terminal portion contained negative charges in the first 7-11 residues. If the first 11 residues were deleted from isopropyl malate synthase, the resulting protein was imported more successfully than the native protein. It appears that precursors that carry negatively charged leaders use an internal signal sequence to compensate for the non-functional segment at the most N-terminal portion of the protein.

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Dust exposure and pulmonary inflammation in Standardbred racehorses fed dry hay or haylage: A pilot study

Olave

Ivester

Couëtil

et al. 2021

The Veterinary Journal

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