Biochemical adaptations to training: implications for resisting muscle fatigue

Skeletal muscle activity is invariably associated with a decline in force-generating capacity (fatigue). The build-up of metabolic by-products such as intracellular H+ and inorganic phosphate (Pi) has been shown to be one of the potential mechanisms of muscle fatigue. The use of phosphorus magnetic resonance spectroscopy is a repeatable and useful tool to study the effect of pH and Pi on force development. When maximal exercise is preceded by submaximal exercise to reduce the starting muscle pH and increase Pi, the degree of muscle fatigue correlates more strongly with H2PO4- than pH or Pi alone. However, other studies in humans have found that H2PO4- does not always correlate well with fatigue. The use of ramp exercise protocols allow repeatable and sensitive measurement of changes in muscle metabolism in response to endurance training. Chronic electrical stimulation in dogs and endurance training in humans results in reduced pH and Pi changes at the same exercise intensities. This means that the effect of pH and Pi in depressing force development is reduced, which could partially explain the increased fatigue resistance seen following endurance training.     

Molecular cloning and immunological characterization of porcine kidney ferredoxin.

Porcine renodoxon is a kidney mitochondrial iron-sulfur protein (ISP) that functions to transfer electron to cytochromes P450 of the vitamin D pathway. A full-length cDNA clone to porcine renodoxin was isolated in the current investigation and used to study the protein's primary structure and immunological properties. The cysteine ligands for the iron-sulfur center, and the surface protein-binding and phosphorylation sites occupied identical positions in both porcine renodoxin and bovine adrenodoxin. Furthermore, porcine renodoxin was functionally indistinguishable from bovine adrenodoxin and the mature forms of both proteins had the same encoded length and shared approximately 91% sequence similarity. A synthetic peptide to the surface protein-binding region was used to demonstrate the antigenicity of the domain in both the porcine and the bovine ISPs. However, porcine renodoxin displayed only limited immunological identity to other regions of bovine adrenodoxin as measured by competitive enzyme-linked immunosorbent assay. Part of this immunological distinction was attributed to the COOH-terminal processing of porcine renodoxin, an action which negated expression of a COOH-terminal antigenic site that is present in bovine adrenodoxin. Other antigenic differences were linked to charged-residue substitutions that were located in predicted surface domains. The highest frequency of surface-residue substitutions in ferredoxin proteins was predicted for porcine renodoxin, which could provide a basis for understanding why the pig protein appears more antigenically divergent than other ferredoxins.