In vitro translocation of bacterial secretory proteins and energy requirements

The recent establishment ofin vitro assay systems has made biochemical studies on the process of membrane translocation of secretory proteins possible. This review summarizes what we have learned, using thesein vitro systems, concerning the biochemical process of protein translocation, with special reference to energy requirements. Both ATP and the protonmotive force participate in the translocation reaction. The requirement of ATP is obligatory, whereas that of the protonmotive force differs, in terms of its level, with the secretory protein species. The possible roles of ATP and the protonmotive force in protein translocation are discussed with special reference to the function of SecA, an essential component of the secretory machinery. The effect of positive charges, which precede or follow the hydrophobic domain of signal peptides, on translocation is also discussed.     

Suppression of an Escherichia coli secAts mutant by a gene cloned from Staphylococcus carnosus

Escherichia coli mutant MM52 (secA(ts)) was transformed with a cosmid library from Staphylococcus carnosus, and a recombinant cosmid (pBO23) allowing growth at the non-permissive temperature (42 degrees C) was isolated. pBO23 also restored the growth defects of E. coli mutants IQ85 (secY(ts)) and IT41 (lep(ts)). Nucleotide sequencing revealed that the DNA fragment responsible for the suppression effect codes for a S. carnosus protein highly homologous to the ribosomal protein L13 of E. coli. The staphylococcal L13 protein was efficiently incorporated into E. coli ribosomes. Possible explanations for the effect of this polypeptide on the growth of temperature-sensitive E. coli secretion mutants are discussed.     

Transmembrane Coordination of Preprotein Recognition and Motor Coupling by the Mitochondrial Presequence Receptor Tim50

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Major coat proteins of bacteriophage Pf3 and M13 as model systems for Sec-independent protein transport

Abstract: The membrane insertion of bacteriophage coat proteins occurs independent of the Sec-translocase of Escherichia coli . Detailed study of the Pf3 and M13 coat proteins has elucidated two fundamental mechanisms of how proteins invade the membrane, most likely by direct interaction with the lipid bilayer. The Sec-independent translocation of amino-terminal regions across the inner membrane is limited to a short length and a small number of charged residues. Protein regions that contain several charged residues are efficiently translocated across the membrane when these regions are flanked by two adjacent hydrophobic segments interacting synergistically. The relevance of these findings for the membrane insertion mechanism of multispanning membrane proteins is discussed.     

Oligodendrocyte-derived transcellular signaling regulates axonal energy metabolism

The unique morphology and functionality of central nervous system (CNS) neurons necessitate specialized mechanisms to maintain energy metabolism throughout long axons and extensive terminals. Oligodendrocytes (OLs) enwrap CNS axons with myelin sheaths in a multilamellar fashion. Apart from their well-established function in action potential propagation, OLs also provide intercellular metabolic support to axons by transferring energy metabolites and delivering exosomes consisting of proteins, lipids, and RNAs. OL-derived metabolic support is crucial for the maintenance of axonal integrity; its dysfunction has emerged as an important player in neurological disorders that are associated with axonal energy deficits and degeneration. In this review, we discuss recent advances in how these transcellular signaling pathways maintain axonal energy metabolism in health and neurological disorders.     

Novel insights into Parkin-mediated mitochondrial dysfunction and neuroinflammation in Parkinson's disease

Mutations in PRKN cause the second most common genetic form of Parkinson's disease (PD)—a debilitating movement disorder that is on the rise due to population aging in the industrial world. PRKN codes for an E3 ubiquitin ligase that has been well established as a key regulator of mitophagy. Together with PTEN-induced kinase 1 (PINK1), Parkin controls the lysosomal degradation of depolarized mitochondria. But Parkin's functions go well beyond mitochondrial clearance: the versatile protein is involved in mitochondria-derived vesicle formation, cellular metabolism, calcium homeostasis, mitochondrial DNA maintenance, mitochondrial biogenesis, and apoptosis induction. Moreover, Parkin can act as a modulator of different inflammatory pathways. In the current review, we summarize the latest literature concerning the diverse roles of Parkin in maintaining a healthy mitochondrial pool. Moreover, we discuss how these recent discoveries may translate into personalized therapeutic approaches not only for PRKN-PD patients but also for a subset of idiopathic cases.