On the stabilization by fixation of configurational states in beef heart mitochondria

The energized configuration of the cristal membrane of beef heart mitochondria can be maintained only as long as oxygen is available for electron transfer. When the oxygen supply is exhausted, the membrane undergoes a transition to the nonenergized configuration. Since the exhaustion of the available oxygen supply is complete in 5–20 sec, it is impossible to apply the method of sedimenting the mitochondria prior to fixation for studying the energized configurational states of mitochondria. The direct addition of glutaraldehyde followed by osmium tetroxide to the mitochondrial suspension is the most effective way of freezing the configurational state of the cristal membrane. Fixation with glutaraldehyde appears to be complete within 1–2 sec even at 0°. Osmium tetroxide alone can also freeze the energized configuration by fixation but the concentration of the fixative is critical. The problem of capturing the configurational state applies not only to energized transitions (nonenergized to energized) but also to nonenergized transitions (orthodox to aggregated). The freezing by fixation of the cristal membrane in the aggregated configuration is best accomplished by the sequential use of glutaraldehyde and osmium tetroxide. When the levels of glutaraldehyde and osmium tetroxide are respectively too low or too high, the mitochondrion will undergo a transition from the aggregated to the orthodox configuration before fixation is complete. Light-scattering studies provide an independent method for monitoring configurational changes in mitochondria; these light-scattering measurements confirm that the conditions for fixation which lead to stabilization of the energized state as judged by electron microscopy, also show maintenance of configuration as judged by absence of light-scattering changes after the fixatives are introduced. Reagents used in negative staining will induce the geometrical form of the energized configuration of the mitochondrion even under nonenergizing conditions. These reagents are thus unsuitable for use in studies of configurational transitions in mitochondria.     

Microwave Hall mobility measurements on heavy beef heart mitochondria

The observed initial microwave Hall mobility values at 1·21 tesla of heavy beef heart mitochondria is at least six times greater than that observed for bovine serum albumin at similar resistivity values. The respiratory inhibitor cyanide significantly reduces the initial Hall mobility values for HBHM and for a preparation of HBHM cytochrome oxidase.The four enzymic complexes of the respiratory chain were partially or completely separated. Of these complexes cytochrome oxidase exhibits the largest microwave Hall mobility.The maximum hydration content of loosely bound water for freezedried preparations of cytochrome oxidase is 5% by weight; 60% of this hydration content is driven off by microwave power. Since the effective ac resistivity of the samples of cytochrome oxidase did not appreciably vary with changes in hydration content, the true resistivity of cytochrome oxidase has a value of the order 5×10³ ohm cm and possibly much lower.The electron transport pathway (as measured by Hall signal) of cytochrome oxidase is irreversibly damaged by prolonged exposure to microwave irradiation at 9·2 GHz. This is accompanied by the complete loss of capacity to oxidise ferrocytochromec. Such changes do not occur with HBHM or with the other respiratory complexes.There appears to be a direct relationship between observed Hall signals and the capacity of cytochrome oxidase to oxidize ferrocytochromec. There is a background signal which is not directly related to electron transport but which is dependent on the conformation of the cytochrome oxidase.The observed electronic parameters of cytochrome oxidase do not depend appreciably on its redox state.Acid denaturation of cytochrome oxidase drastically reduces the Hall signal, to include almost complete removal of the background signal. It also more than doubles ac resistivity.An electron tunnelling model is outlined.     

Studies on the regulation of pyruvate dehydrogenase in isolated beef heart mitochondria.

The regulation of the pyruvate dehydrogenase multienzyme complex of isolated beef heart mitochondria by a phosphorylation-dephosphorylation mechanism was investigated. From mitochondria incubated under conditions favoring either a protein kinasemediated inactivation or a phosphatase-mediated reactivation, the pyruvate dehydrogenase complex was extracted and partially purified. Incorporation of ³²P from [γ-³²P]ATP into the pyruvate dehydrogenase complex corresponded to the loss of enzymatic activity. Upon incubation of the mitochondria that were preincubated with [γ-³²P]ATP under metabolic conditions favoring the phosphatase reaction, the amount of radioactivity in the ³²P-labeled fraction decreased significantly with a concomitant increase in the pyruvate dehydrogenase activity. The estimated molecular weight of the ³²P-labeled fraction derived from the mitochondrial incubation was 41,000, corresponding to the reported molecular weight of the α-subunit of the pyruvate dehydrogenase portion of the multienzyme complex.     

The reactivity of -SH groups in the ADP/ATP carrier isolated from beef heart mitochondria

The emergence of the reactivity of -SH groups associated with conformation changes has been studied on the ADP/ATP carrier, is isolated in three different inhibitor-protein complexes. 1. The bongkrekate-protein complex incorporates approximately one molecular more of N-ethylmaleimide than the carboxyatractylate-protein complex. After extensive denaturation by dodecylsulfate in urea, both inhibitor complexes exhibit four reactive -SH groups per subunit. Thus one of four -SH groups per subunit has been unmasked in the bongkrekate-protein complex. 2. The interconversion from the bongkrekate-protein complex to the carboxyatractylate-protein complex is inhibited after the -SH groups have been blocked. 3. The protein complex isolated with the more easily dissociable atractylate, is used to demonstrate, by the emergence of the -SH groups, the transition into the m-state. This transition is specifically catalyzed by ADP and ATP. 4. Using 2,2'-dinitro-5,5'-dithiodibenzoate, the appearance of the -SH groups on transition from the c-state to the m-state can be followed spectrophotometrically. The specificity for the catalyzing nucleotides is identical with that for the transport. The Km for ADP and ATP is in the range of 1 microM. In conclusion, the thiol groups of the isolated ADP/ATP carrier behave as in the mitochondrial membrane. The unmasking of -SH groups is in full accordance with the concept of two conformational states (c and m).     

The uptake and extrusion of monovalent cations by isolated heart mitochondria

Summary The factors involved in the movement of monovalent cations across the inner membrane of the isolated heart mitochondrion are reviewed. The evidence suggests that the energy-dependent uptake of K⁺ and Na⁺ which results in swelling of the matrix is an electrophoretic response to a negative internal potential. There are no clear cut indications that this electrophoretic cation movement is carrier-mediated and possible modes of entry which do not require a carrier are examined. The evidence also suggests that the monovalent cation for proton exchanger (Na⁺ > K⁺) present in the membrane may participate in the energy-dependent extrusion of accumulated ions. The two processes, electrophoretic cation uptake (swelling) and exchange-dependent cation extrusion (contraction) may represent a means of controlling the volume of the mitochondrion within the functioning cell. A number of indications point to the possibility that the volume control process may be mediated by the divalent cations Ca⁺² and Mg⁺². Studies with mercurial reagents also implicate certain membrane thiol groups in the postulated volume control process.An invited article.