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Cytochrome mitochondrial translocation

Intrinsic (mitochondrial) pathway of caspase activation is initiated by the permeabilization of the mitochondrial outer membrane by proapoptotic members of the Bcl-2 family, resulting in a release of cytochrome c and other proteins from the intermembrane space of mitochondria into the cytosol. Cytochrome c translocation to the cytosol may follow a number of possible mechanisms. However, once in the cytosol, cytochrome c binds to apoptosis protease activating factor (Apaf-1) and in the presence of dATP or ATP facilitates Apaf-1 oligomerization and the recruitment of procaspase-9. The formation of this caspase-activating complex, termed the apoptosome, results in the activation of procaspase-9, and this in turn cleaves and activates the effector caspase-3 and -7. Activated effector caspases cleave key substrates in the cell and produce the cellular and biochemical events characteristic for apoptosis [33-35]. [Pg.14]

FIGURE 9.1. Sequence of components of the mitochondrial electron transport chain. NADH-Q reductase spans the mitochondrial membrane with the Q site within the membrane and the NADH site on the matrix side of the membrane. Succinate-Q reductase has a Q site within the membrane and a succinate site on the matrix side of the membrane. Cytochrome c reductase is a membrane-bound enzyme with cytochrome c on the cystolic side of the membrane and cytochrome b in the membrane. Cytochrome c is soluble and found on the cystolic side of the membrane, while cytochrome oxidase translocates protons or electrons across the membrane. (Adapted from Ref. 3.)... [Pg.235]

Several different changes in mitochondria occur during apoptosis. These include a change in membrane potential (usually depolarization), increased production of reactive oxygen species, potassium channel activation, calcium ion uptake, increased membrane permeability and release of cytochrome c and apoptosis inducing factor (AIF) [25]. Increased permeability of the mitochondrial membranes is a pivotal event in apoptosis and appears to result from the formation of pores in the membrane the proteins that form such permeability transition pores (PTP) may include a voltage-dependent anion channel (VDAC), the adenine nucleotide translocator, cyclophilin D, the peripheral benzodiazepine receptor, hexokinase and... [Pg.610]

To explain how H+ transfer occurred across the membrane Mitchell suggested the protons were translocated by redox loops with different reducing equivalents in their two arms. The first loop would be associated with flavoprotein/non-heme iron interaction and the second, more controversially, with CoQ. Redox loops required an ordered arrangement of the components of the electron transport system across the inner mitochondrial membrane, which was substantiated from immunochemical studies with submitochondrial particles. Cytochrome c, for example, was located at the intermembranal face of the inner membrane and cytochrome oxidase was transmembranal. The alternative to redox loops, proton pumping, is now known to be a property of cytochrome oxidase. [Pg.97]

Fig. 1. Proposed mechanism of action of rituximab associated with the apoptosis pathway. Binding of rituximab with the CD20 antigen up-regulates the production of interleukin-10 (IL-10). The IL-10 autocrine loop down-regulates the expression of the bcl-2 protein, which inhibits the intrinsic pathway (or mitochondrial mediated pathway) of apoptosis. The mitochondrial pathway is induced by intracellular stress signals. The translocation of the bcl-2 protein into the mitochondria leads to the activation of caspase 9 via release of cytochrome c and apoptotic protease-activating factor 1. The other pathway, the extrinsic pathway (or death receptor mediated pathway) activates caspase 8. Subsequently, caspase 8 or 9 activates caspase 3, leading to programmed cell death (apoptosis). Fig. 1. Proposed mechanism of action of rituximab associated with the apoptosis pathway. Binding of rituximab with the CD20 antigen up-regulates the production of interleukin-10 (IL-10). The IL-10 autocrine loop down-regulates the expression of the bcl-2 protein, which inhibits the intrinsic pathway (or mitochondrial mediated pathway) of apoptosis. The mitochondrial pathway is induced by intracellular stress signals. The translocation of the bcl-2 protein into the mitochondria leads to the activation of caspase 9 via release of cytochrome c and apoptotic protease-activating factor 1. The other pathway, the extrinsic pathway (or death receptor mediated pathway) activates caspase 8. Subsequently, caspase 8 or 9 activates caspase 3, leading to programmed cell death (apoptosis).
In purple photosynthetic bacteria, electrons return to P870+ from the quinones QA and QB via a cyclic pathway. When QB is reduced with two electrons, it picks up protons from the cytosol and diffuses to the cytochrome bct complex. Here it transfers one electron to an iron-sulfur protein and the other to a 6-type cytochrome and releases protons to the extracellular medium. The electron-transfer steps catalyzed by the cytochrome 6c, complex probably include a Q cycle similar to that catalyzed by complex III of the mitochondrial respiratory chain (see fig. 14.11). The c-type cytochrome that is reduced by the iron-sulfur protein in the cytochrome be, complex diffuses to the reaction center, where it either reduces P870+ directly or provides an electron to a bound cytochrome that reacts with P870+. In the Q cycle, four protons probably are pumped out of the cell for every two electrons that return to P870. This proton translocation creates an electrochemical potential gradient across the membrane. Protons move back into the cell through an ATP-synthase, driving the formation of ATP. [Pg.340]

Cytochrome c from various sources consists of a single polypeptide chain of about a hundred amino acid residues. The protein is synthesized as apocytochrome c in the cell cytoplasm and then translocated across the outer mitochondrial membrane to its functional site on the cytoplasmic surface of the inner membrane.652 The heme is added during or after transport.653... [Pg.620]

Germain, M., Mathai, J. P., and Shore, G. C., 2002, BH-3-only BIK functions at the endoplasmic reticulum to stimulate cytochrome c release from mitochondria, J. Biol. Chem. 277, pp. 18053—18060 Gincel, D., Zaid, H., and Shoshan-Barmatz, V., 2001, Calcium binding and translocation by the voltage-dependent anion channel a possible regulatory mechanism in mitochondrial function, Biochem. J. 358, pp. 147-155... [Pg.499]

Fig. 5.3. The major components involved in mitochondrial NADH oxidation in facultative anaerobic mitochondria. In anaerobically functioning mitochondria, NADH is oxidized either by soluble enzymes (left) or by membrane-bound complexes of the electron-transport chain (middle). Under aerobic conditions, a classic respiratory chain is used to oxidize NADH (right). Proton translocation is indicated by H with arrows. Ovals represent the electron transporters RQ, UQ and cytochrome c (cyt. c), and electron transport is indicated by dashed arrows. The vertical bar represents a scale for the standard redox potentials in millivolts. Fum fumarate, NADH-DH NADH dehydrogenase, NADH-ECR soluble NADH enoyl-CoA reductase, RQH2 rhodoquinol, Succ succinate, UQH2 ubiquinol... Fig. 5.3. The major components involved in mitochondrial NADH oxidation in facultative anaerobic mitochondria. In anaerobically functioning mitochondria, NADH is oxidized either by soluble enzymes (left) or by membrane-bound complexes of the electron-transport chain (middle). Under aerobic conditions, a classic respiratory chain is used to oxidize NADH (right). Proton translocation is indicated by H with arrows. Ovals represent the electron transporters RQ, UQ and cytochrome c (cyt. c), and electron transport is indicated by dashed arrows. The vertical bar represents a scale for the standard redox potentials in millivolts. Fum fumarate, NADH-DH NADH dehydrogenase, NADH-ECR soluble NADH enoyl-CoA reductase, RQH2 rhodoquinol, Succ succinate, UQH2 ubiquinol...
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Mitochondrial cytochrome

Translocated

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