Genomic and metabolic preparation of muscle in sockeye salmon Oncorhynchus nerka for spawning migration.

Prolonged endurance exercise and fasting are two major metabolic challenges facing Pacific salmon during spawning migrations that often occur over 1,000 km. Because both prolonged exercise and fasting stimulate the oxidation of lipids, particularly in heavily recruited tissues such as muscle, we sought to investigate the regulatory mechanisms that establish and maintain the capacity for substrate oxidation at four separate locations during the final 750 km of nonfeeding migration in sockeye salmon Oncorhynchus nerka. Transcript levels of multiple genes encoding for important regulators of lipid, carbohydrate, and protein oxidation as well as the activity of several important enzymes involved in lipid and carbohydrate oxidation were examined in red and white muscle. We found in both muscle types that the messenger RNA (mRNA) expression of carnitine palmitoyltransferase I isoforms, peroxisome proliferator-activated receptors α and ß, and adenosine monophosphate-activated protein kinase ß1 were all significantly higher at the onset compared to later stages of nonfeeding migration. However, the activities of ß-hydroxyacyl-CoA dehydrogenase and citrate synthase were higher only early in migration and only in red muscle. Later in the migration and as muscle lipid stores were greatly depleted, the mRNA levels of hexokinase I and aspartate aminotransferase increased in white muscle. Overall, at the onset of migration, high transcript and metabolic enzyme activity levels in skeletal muscle of sockeye salmon may help support the high rates of lipid oxidation needed for endurance swimming. Furthermore, we suggest that the muscle capacity to use carbohydrates and proteins may be adjusted throughout migration on an as-needed basis to fuel burst exercise through very difficult hydraulic passages in the river and perhaps during mating activities.

Changes in HIF-1α protein, pyruvate dehydrogenase phosphorylation, and activity with exercise in acute and chronic hypoxia.

Exercise under acute hypoxia elicits a large increase in blood lactate concentration ([La](b)) compared with normoxic exercise. However, several studies in humans show that with the transition to chronic hypoxia, exercise [La](b) returns to normoxic levels. Although extensively examined over the last decades, the muscle-specific mechanisms responsible for this phenomenon remain unknown. To assess the changes in skeletal muscle associated with a transition from acute to chronic hypoxia, CD-1 mice were exposed for 24 h (24H), 1 wk (1WH), or 4 wk (4WH) to hypobaric hypoxia (equivalent to 4,300 m), exercised under 12% O(2), and compared with normoxic mice (N) at 21% O(2). Since the enzyme pyruvate dehydrogenase (PDH) plays a major role in the metabolic fate of pyruvate (oxidation vs. lactate production), we assessed the changes in its activity and regulation. Here we report that when run under hypoxia, 24H mice exhibited the highest blood and intramuscular lactate of all groups, while the 1WH group approached N group values. Concomitantly, the 24H group exhibited the lowest PDH activity, associated with a higher phosphorylation (inactive) state of the Ser(232) residue of PDH, a site specific to PDH kinase-1 (PDK1). Furthermore, protein levels of PDK1 and its regulator, the hypoxia inducible factor-1α (HIF-1α), were both elevated in the 24H group compared with N and 1WH groups. Overall, our results point to a novel mechanism in muscle where the HIF-1α pathway is desensitized in the transition from acute to chronic hypoxia, leading to a reestablishment of PDH activity and a reduction in lactate production by the exercising muscles.

Chronic hypoxia- and cold-induced changes in cardiac enzyme and gene expression in CD-1 mice.

BACKGROUND: In mammals, environmental challenges often result in physical and metabolic cardiac remodeling (i.e., hypertrophy and a shift from lipid to carbohydrate oxidation). While chronic hypoxia and cold are both known to elicit cardiac changes, little is known about their combined effects. METHODS: To investigate the cumulated effects of these two stressors on cardiac physiology, CD-1 mice were exposed for 4 weeks to normoxia/normothermia, hypoxia, cold, or combined hypoxic-cold. We assessed physical characteristics, left ventricular activities of fatty acid catabolic enzymes short-chain ß-hydroxyacyl-CoA dehydrogenase (SCHAD) and medium-chain acyl-CoA dehydrogenase, and mRNA levels of Acadm, muscle- and liver-type carnitine palmitoyltransferase (Cpt-1ß, Cpt-1α), and the transcriptional regulator PPARα. RESULTS: 1) Chronic hypoxia reduced SCHAD activity without physical remodeling or mRNA changes; 2) chronic cold lead to reduced SCHAD activity in hypertrophied left ventricles and lowered right ventricular Cpt-1α mRNA (compared to chronic hypoxia); and 3) despite causing hypertrophy of both ventricles, chronic exposure to combined hypoxic-cold did not induce significant metabolic remodeling. GENERAL SIGNIFICANCE: In response to environmental challenges, cardiac muscles 1) show distinct physical and metabolic remodeling, 2) respond to two stressors simultaneously but not additively, and 3) maintain an adult metabolic phenotype with long-term exposure to environmentally realistic hypoxic-cold.

Genome duplication events have led to a diversification in the CPT I gene family in fish.

The enzyme carnitine palmitoyltransferase (CPT) I is a major regulator of mitochondrial fatty acid oxidation in vertebrates. Numerous genome duplication events throughout evolution have given rise to three (in mammals) or multiple (in fish) genetically and functionally different isoforms of this enzyme. In particular, these isoforms represent a diversification of kinetic and regulatory properties stemming from mutations at the genomic and proteomic levels. Phylogenetic reconstructions reveal a comprehensive view of the CPT I family in vertebrates and genomic modifications leading to structural changes in proteins and functional differences between tissues and taxa. In a model fish species (rainbow trout), the presence of five CPT I isoforms suggests repeated duplication events in bony fishes and salmonids. Subsequently, an array of nucleotide and amino acid substitutions in the isoforms may contribute to a tissue-specific and a previously observed species-specific difference in the IC(50) for malonyl-CoA. Moreover, all five isoforms are expressed in trout at the mRNA level in skeletal muscle, heart, liver, kidney, and intestine. In general, transcript levels of the beta-isoforms were higher in muscle tissues, while levels of the alpha-isoforms were higher in other tissues. Rainbow trout also exhibit developmental plasticity in relative mRNA expression of CPT I isoforms from fry to juvenile to adult stage. Thus the evolution of CPT I has resulted in a very diverse family of isoforms. These differences represent a degree of specificity in the ability of species to regulate function at the protein and tissue levels, which, in turn, may allow for precise control of lipid oxidation in individual tissues during physiological perturbations.