Protein Translocases

Chaperones. Figure 2 The multiple roles of BiP in the biogenesis of the secretory proteins. BiP, immunoglobulin heavy chain binding protein ER, endoplasmic reticulum ERAD, ER-associated degradation ERj, resident ER protein with J-domain Sec61, core subunit of the protein translocase UPR, unfolded protein response that involves several signal transduction pathways that are activated in order to increase the biosynthetic capacity and decrease the biosynthetic burden of the ER... 

Chaddock, A., Mant, A., Karnauchov, I., Brink, S., Herrmann, R., Klosgen, R., and Robinson, C. (1995). A new type of signal peptide central role of a twin-arginine motif in transfer signals for the ApH-dependent thylakoidal protein translocase. EMBO J. 

Prinz, W., Spiess, C., Ehrmann, M., Schierle, C., and Beckwith, J. (1996). Targeting of signal sequenceless proteins for export in Escherichia coli with altered protein translocase. EMBO J. 15, 5209-5217. 

Substrate availability to the cell is affected by the supply of raw materials from the environment. The plasma membranes of cells incorporate special and often specific transport proteins (translocases) or pores that permit the entry of substrates into the cell interior. Furthermore pathways in eukaryotic cells are often compartmentalized within cytoplasmic organelles by intracellular membranes. Thus we find particular pathways associated with the mitochondria, the lysosomes, the peroxisomes, the endoplasmic reticulum for example. Substrate utilization is limited therefore by its localization at the site of need within the cell and a particular substrate will be effectively concentrated within a particular organelle. The existence of membrane transport mechanisms is crucial in substrate delivery to, and availability at, the site of use. 

Mokranjac D, Sichting M, Neupert W, Hell (2003b) Timl4, a novel key component of the import motor of the TIM23 protein translocase of mitochondria. EMBO J 22 4945-4956... 

A different kind of enzyme, translocase [80700-39-6], which transfers a fragment of NAD to the protein—synthesis factor (elongation factor 2), is catalyzed by diphtheria toxin, thereby inhibiting protein synthesis (43). In tumor cells, the rate of protein synthesis is 100 to 1000 times more sensitive to diphtheria toxin than the analogous process in normal cells (41) therefore, diphtheria toxin is selectively toxic to tumor cells. 

The mechanisms involved in the establishment of lipid asymmetry are not well understood. The enzymes involved in the synthesis of phospholipids are located on the cytoplasmic side of microsomal membrane vesicles. Translocases (flippases) exist that transfer certain phospholipids (eg, phosphatidylcholine) from the inner to the outer leaflet. Specific proteins that preferentially bind individual phospholipids also appear to be... 

Eipi (Wheelock etal., 1991) Eipil (Huang and Komuniecki, 1997) E3BP, E3-binding protein (p45) E3 ER, enoyl CoA reductase (Duran etal. 1993, 1998) AAT, adenine nucleotide translocase a-tubulin. UE, unembryonated egg L1, first-stage larva L2, second-stage larva L3, third-stage larva M, adult muscle ... 

There are several hypotheses for a specific mechanism by which ONOO- can control the open state of the PTPC. Briefly the PTPC is regulated by primary constituents of the pore, including the inner membrane adenine nucleotide translocase (ANT) and the outer membrane protein voltage-dependent anion channel (VDAC or porin). The VDAC-ANT complex can bind to signaling proteins that modulate permeability transition, such as pro-apoptotic Bax (which opens the pore) and anti-apoptotic Bcl-2... 

In many eukaryotic plasma membranes, PS resides in the inner leaflet (Schroit and Zwaal, 1991 Zachowski, 1993). This transbilayer distribution of membrane hpids is not a static situation but a result of balance between the inward and outward translocation of phospholipids across the membranes. Recent studies showed that the transbilayer lipid asymmetry is regulated by several lipid transporter proteins, such as aminophospholipid translocase (Daleke and Lyles, 2000), ATP-binding cassette transporter family (van Helvoort et al, 1996 Klein et al, 1999), and phospholipid scramblase (Zhou et al, 1997 Zhao et al, 1998). An increment of intracellular due to cell activation, cell injury, and apoptosis affects the activities of these transporters, resulting in exposure of PS (Koopman et al, 1994 Verhoven et al, 1995) and PE (Emoto et al, 1997) on the cell surface. 

Figure 7.11 Mechanism of transport of long-chain fatty adds across the inner mitochondrial membrane as fatty acyl carnitine. CRT is the abbreviation for carnitine palmitoyl transferase. CPT-I resides on the outer surface of the inner membrane, whereas CPT-II resides on the inner side of the inner membrane of the mitochondria. Transport across the inner membrane is achieved by a carrier protein known as a translocase. FACN - fatty acyl carnitine, CN - carnitine. Despite the name, CRT reacts with long-chain fatty acids other than palmitate. CN is transported out of the mitochondria by the same translocase.

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