Glycated hemoglobin is not an accurate indicator of glycemia in rainbow trout.

Glycation occurs when glucose reacts non-enzymatically with proteins. This reaction depends upon time, ambient glucose concentration, and the molecular conformation of reactive amino acids. Little is known about protein glycation in fishes and the main objective of this study was to measure glycated hemoglobin (GHb) in rainbow trout, a glucose-intolerant species, under normoglycemic and hyperglycemic conditions. We also identified GHb isoforms in vivo and analyzed the structural environment surrounding potential glycation sites. Despite similar glycemia to healthy humans, GHb was an order of magnitude lower in rainbow trout (0.6%) compared with humans (6%) and was not affected by long-term hyperglycemia. Species differences in GHb appear to be related to differences in erythrocyte glucose, and differential expression and glycation of hemoglobin (Hb) isoforms may explain intraspecific differences in rainbow trout GHb. Computer analysis of glucose isomers (ringed-open and α- and ß-pyranoses) interacting with the ß-chain of rainbow trout HbI and HbIV, and human HbA did not reveal structural or energetic constraints for glucose binding (the initial step of glycation) for rainbow trout Hbs. Overall, there are significant differences between Hb glycation in humans and rainbow trout, and GHb does not appear to be an accurate indicator of glycemia over time in rainbow trout.

WITHDRAWN: Profiles in Comparative Endocrinology: Carl B. Schreck Howard Bern Lecturer, Annual Meeting of Society of Integrative and Comparative Endocrinology, Seattle, January 5, 2010.

This article has been withdrawn at the request of the editor. The Publisher apologizes for any inconvenience this may cause. The full Elsevier Policy on Article Withdrawal can be found at http://www.elsevier.com/locate/withdrawalpolicy.

Effects of exercise training on insulin-regulatable glucose-transporter protein levels in rat skeletal muscle.

Exercise training has been shown to enhance the ability of insulin to stimulate glucose uptake in responsive tissues. The purpose of this study was to determine the effects of exercise training on the levels of the insulin-regulatable glucose transporter (IRGT) in rat skeletal muscle. After 6 wk of voluntary running in exercise-wheel cages, male Sprague-Dawley rats were rested for approximately 27 h and fasted overnight before removal of plantaris and soleus muscles. The concentration of glucose transporters per unit of muscle protein or DNA was quantitated by immunoblotting with an anti-IRGT polyclonal antibody raised against a synthetic peptide. The IRGT protein was increased by 60% (141 +/- 14 vs. 229 +/- 24 counts/min [cpm]/25 micrograms protein, P less than 0.01) in plantaris muscle from exercise-trained rats compared with controls. Total protein yield, DNA content, and 5'-nucleotidase activity were not different in plantaris muscle from control and exercise-trained rats. In contrast, there was no significant increase in the IRGT protein in soleus muscle after training when data were expressed per unit of muscle protein (292 +/- 22 vs. 346 +/- 16 cpm/25 micrograms protein). These data indicate that the increase in the IRGT in plantaris muscle is a selective response to exercise training that does not reflect an overall increase in muscle protein. The changes in IRGT for these muscles with exercise training parallel changes observed in insulin-mediated glucose uptake. We propose that this increase in the total number of glucose transporters may be a major component of the increase in insulin-mediated glucose uptake that is observed with exercise training.

Interaction of insulin and exercise on glucose transport in muscle.

Glucose transport is the rate-limiting step for glucose utilization in muscle. In muscle and adipose tissue, glucose transport is acutely regulated by such factors as insulin and exercise. Translocation of glucose transporters (GLUT4) from an intracellular domain to the cell surface is the major mechanism for this regulation. Using immunocytochemistry, the intracellular distribution of GLUT4 under resting conditions is similar in adipocytes and myocytes. GLUT4 is concentrated in tubulovesicular structures either in the trans-Golgi region or in the cytosol, often close to the cell surface but not on the cell surface. After stimulation, cell surface GLUT4 labeling is increased by as much as 40-fold. GLUT4 is chronically regulated by altered gene expression. Neural and/or contractile activity regulates GLUT4 expression in muscle: 1) GLUT4 levels differ among muscles of different fiber type; 2) GLUT4 levels in muscle are increased with exercise training and decreased with denervation; and 3) cultured muscle cells, which lack an intact nerve supply, express very low levels of GLUT4. GLUT4 expression appears to be regulated in parallel with many oxidative enzymes in muscle, suggesting that there may be a unified developmental program that determines the overall metabolic properties of a particular muscle. Preliminary evidence suggests that impaired GLUT4 expression in muscle is not the primary defect associated with insulin resistance. Nevertheless, it is conceivable that the adaptive increase in muscle GLUT4 that is found with exercise training may have beneficial effects in insulin-resistant states such as non-insulin-dependent diabetes.

Effects of voluntary exercise on bone mineral content in rats.

We used a voluntary running model to explore the relationship between average daily running distance and bone mineral status of rats. A total of 60 male Sprague-Dawley rats were randomly assigned at 6 weeks of age to a sedentary control group (n = 22) or to a group with unlimited access to a running wheel (n = 38). The running distance of exercising rats was monitored daily, and steady-state running levels ranged from 3.2 to 18.1 km/day. At the end of the experimental period, femora and tibiae were dissected and bone mineral content (BMC, g/cm) and bone mineral density (BMD, g/cm2) were measured by single-photon absorptiometry. Cross-sectional morphometry was examined by taking a transverse section of the femoral middiaphysis. Hindlimb percentage fat was significantly higher in controls than in runners (20.0 +/- 1.2 versus 11.1 +/- 0.6, p less than 0.001), and soleus mass was greater in runners than in controls (371 +/- 8.1 versus 320 +/- 0.8 mg, p less than 0.001). Femoral and tibial lengths, weights, and volumes were significantly higher in runners than in controls (p less than 0.005). BMC and BMD were higher in runners than in controls at all sites apart from the distal femur. Cross-sectional areas at the femoral midshaft were greater in running rats than in sedentary controls (6.26 +/- 0.1 versus 5.45 +/- 0.3 mm2, p less than 0.02), as was the polar moment of inertia (15.6 +/- 0.6 versus 12.7 +/- 0.2 mm4, p less than 0.05). No positive correlation was found between distance run and BMC, BMD, cross-sectional area, or polar moment of inertia.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of wheel running on glucose transporter (GLUT4) concentration in skeletal muscle of young adult and old rats.

We examined the effects of voluntary exercise on glucose transporter concentration in skeletal muscle from young adult and old female Long-Evans rats. Rats had free access to voluntary running wheels beginning at 4 months of age or remained sedentary. Exercising rats ran approximately 7.5, 6.2, 5.6 and 5.3 km/day during their 6th, 8th, 9th and 10th month of age, respectively. During the 23rd, 24th and 25th month of age running distance averaged 3.0, 2.8 and 2.4 km/day, respectively. At 10 and 25 months of age, glucose transporter protein concentration was assessed in epitrochlearis and flexor digitorum brevis muscles with a polyclonal antibody directed against the GLUT4 transporter isoform. GLUT4 protein concentration was not altered by the aging process (i.e., comparing 10- and 25-month-old rats) in either muscle type. Wheel running increased GLUT4 protein concentration by 45% in epitrochlearis muscles of 10-month-old rats relative to age-matched sedentary controls. The training-induced adaptation in GLUT4 protein was no longer present at age 25 months, probably because the running distance had declined by 50%. In the flexor digitorum brevis, exercise did not alter GLUT4 concentration at either 10 or 25 months, presumably due to insufficient recruitment of this muscle during wheel running as assessed by measurement of citrate synthase and hexokinase enzyme activities. Wheel running induced cardiac and soleus muscle hypertrophy in 10- and 25-month-old rats. In summary, voluntary wheel running can induce an increase in skeletal muscle GLUT4 protein concentration in adult rats. Older rats that run less exhibit cardiac and soleus muscle hypertrophy, but do not maintain an elevated GLUT4 protein concentration in the epitrochlearis muscle. Aging does not alter GLUT4 protein concentration in the epitrochlearis or FDB muscles.

Changes in cardiac energy metabolism during early development of female SHR.

We investigated effects of hypertension and early development on myocardial energy metabolism as reflected by maximal enzyme activities, glucose transporter content, and endogenous substrates in female Wistar-Kyoto (WKY) rats and spontaneously hypertensive rats (SHR). Left ventricular hypertrophy and systolic hypertension were evident in SHR at 6 weeks of age and these differences increased at 14 and 22 weeks of age. 3-Hydroxyacyl-CoA dehydrogenase (HOAD) activity in the left ventricle was 18% lower in 6-week-old rats than both 14- and 22-week-old rats, but not different between WKY rats and SHR. Hexokinase activity was 15% lower in 6-week-old SHR than WKY rats and decreased progressively with age in both strains. Glucose transporter (GLUT) 1 content was nearly twofold greater in 6-week-old rats than both 14- and 22-week-old rats. We found no difference in citrate synthase activity or GLUT4 content among groups. Glycogen concentration was 44% lower in SHR than WKY rats, whereas triglyceride was slightly (16%) higher in SHR than WKY rats. Older animals had higher levels both glycogen and triglyceride than younger animals. We conclude that the left ventricle of both SHR and WKY rats may change from predominantly glucose to fatty acid oxidation for energy production during early development.

Voluntary running improves glucose tolerance and insulin resistance in female spontaneously hypertensive rats.

We evaluated the effects of voluntary exercise training on glucose metabolism and measures of insulin sensitivity in female spontaneously hypertensive rats (SHR). Age-matched Wistar-Kyoto rats (WKY) were used as normotensive controls. Exercising SHR were housed in running wheels for 8 weeks (SHRx8) or 16 weeks (SHRx16). At 22 weeks of age, we measured systolic blood pressure, performed oral glucose tolerance tests, and determined hexokinase activity and glucose transporter (GLUT) 4 content in skeletal muscle to assess intracellular glucose metabolism. Blood pressure was lower in WKY (139+/-12 mm Hg) than untrained SHR (216+/-13 mm Hg). Exercise training caused a reduction in blood pressure (-18 mm Hg) for SHRx8. After a brief (5-h) fast, serum glucose was lower in SHR that exercised compared with sedentary SHR, whereas insulin concentrations were identical between all SHR and WKY. Corresponding free fatty acids (FFA) were twofold higher in SHR than in WKY. In response to glucose, SHR demonstrated higher glucose and FFA responses, with exercise decreasing the glucose values in a dose-dependent manner. Although the insulin response was comparable in all groups, the glucose-to-insulin ratio was higher in SHR, indicating a relative insulin resistance for both glucose disposal and suppression of free fatty acids. Hexokinase activity and GLUT4 content were elevated 1.4- and 2.8-fold, respectively, in plantaris muscle of SHRx16, suggesting an improvement in the capacity for glucose transport and phosphorylation with exercise. These results provide evidence that voluntary running in female SHR lowers blood pressure and selectively increases glucose uptake and insulin action, but not suppression of FFA.

Metabolic, hemodynamic, and cardiac effects of captopril in young, spontaneously hypertensive rats.

Spontaneously hypertensive rats (SHR) demonstrate elevated blood pressure, cardiac hypertrophy, glucose intolerance, and insulin resistance compared with age-matched Wistar-Kyoto rats (WKY). We investigated concurrent effects of captopril on blood pressure, cardiac mass, myocardial enzyme activities, glucose tolerance, and insulin action in young male SHR. At 10 weeks of age, SHR were randomized into two groups, one receiving distilled water, the other a captopril solution (50 mg/kg body weight/day). We also examined age-matched WKY receiving distilled water. Blood pressure was measured by tail-cuff during the 4-week treatment period and oral glucose tolerance was tested at the end of treatment. Hearts were weighed and ventricular tissue was assayed for activities of 3-hydroxyacyl-CoA dehydrogenase, citrate synthase, and hexokinase. Growth rates were similar between captopril-treated and control SHR, but less than those of WKY. Captopril reduced blood pressure (134 +/- 8 v 177 +/- 8 mm Hg, P < .05) and left ventricular mass (-18%, P < .05) in SHR. Cardiac enzyme activities also changed with captopril treatment, reflecting an increased capacity for beta-oxidation of fatty acids and reduced potential for glucose phosphorylation in the left ventricle of SHR. Serum concentrations of glucose, insulin, and free fatty acids after a brief fast and in response to oral glucose were not different after captopril treatment, suggesting no improvement in insulin action or glucose tolerance. In summary, treatment of young male SHR with captopril reduces blood pressure and cardiac mass, and promotes a small but significant increase in cardiac capacity for oxidation of fatty acids and reduction of glucose phosphorylation. In contrast, metabolic effects of captopril on oral glucose tolerance and insulin action were not evident.

Effect of body weight gain on insulin sensitivity after retirement from exercise training.

The objectives of this study were to determine how long increased insulin sensitivity, elicited by exercise training, persists after the end of training and what the effect of weight gain is on this retention. Exercise-trained (ET) rats ran voluntarily in freely rotating wheel cages, and insulin sensitivity was assessed by oral glucose tolerance tests (OGTT) and insulin suppression tests (IST). After training, ET rats were retired for 1, 3, or 7 days (R1, R3, or R7). Initial OGTT and IST studies indicated that sensitivity to insulin-induced glucose uptake was increased in ET rats compared with sedentary control (C) rats and was progressively lost with retirement: ET greater than R1 and R3 greater than R7 and C rats, and this reaction was generally associated with a rapid gain in body weight. Subsequent IST tests were performed on C and R7 rats fed laboratory chow or a hypocaloric diet consisting of equal parts of cellulose and chow for 7 days before the test. The results of these tests showed that steady-state serum glucose (SSSG) levels averaged 165 +/- 12 mg/dl for chow-fed C rats and 172 +/- 11 mg/dl for chow-fed R7 rats that gained body weight at rates twice those of C rats. Chow-fed R7 rats, gaining weight at rates comparable to C rats, had SSSG levels of 104 +/- 6 mg/dl. C and R7 rats fed the hypocaloric diet had SSSG values of 102 +/- 6 and 59 +/- 4 mg/dl, respectively. Muscle glycogen levels were comparable in all groups, and liver glycogen was lower in C and R7 rats fed the hypocaloric diet.(ABSTRACT TRUNCATED AT 250 WORDS)

Variations in running activity and enzymatic adaptations in voluntary running rats.

The running behavior and biochemical markers of oxidative and glycolytic activities associated with voluntary running activity were studied in male Sprague-Dawley rats after 6 wk of training in exercise wheel cages. Twenty-four-hour recordings of running activity were used to quantify the number of individual running bouts, their duration and running speed, and the distance run per day. We then established three categories of voluntary running activity based on the mean distance run per day during the last 3 wk of training: low-activity runners averaged 2-5 km/day, medium runners 6-9 km/day, and high runners greater than 11 km/day. Each group demonstrated an intermittent, nocturnal running pattern, at relatively high intensities, with a similar mean running speed for all groups (avg approximately 45 m/min). Differences in total distance run per day were the result of variations in both the number and duration of individual running bouts. Specifically, high runners (n = 7) had 206 +/- 30 individual running bouts per 24 h, each lasting 87 +/- 7 s; medium runners (n = 7) 221 +/- 22 running bouts, lasting 47 +/- 5 s; and low runners (n = 7) 113 +/- 7 bouts, each lasting 40 +/- 7 s. Voluntary running depressed the rate of body weight gain compared with sedentary control rats, despite an increased food and water intake for all runners. Furthermore, drinking activity was temporally associated with running periods.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of denervation or unweighting on GLUT-4 protein in rat soleus muscle.

The purpose of this study was to test the hypothesis that the decreased capacity for glucose transport in the denervated rat soleus and the increased capacity for glucose transport in the unweighted rat soleus are related to changes in the expression of the regulatable glucose transporter protein in skeletal muscle (GLUT-4). One day after sciatic nerve sectioning, when decreases in the stimulation of soleus 2-deoxyglucose (2-DG) uptake by insulin (-51%, P less than 0.001), contractions (-29%, P less than 0.05), or insulin and contractions in combination (-40%, P less than 0.001) were observed, there was a slight (-18%, NS) decrease in GLUT-4 protein. By day 3 of denervation, stimulation of 2-DG uptake by insulin (-74%, P less than 0.001), contractions (-31%, P less than 0.001), or the two stimuli in combination (-59%, P less than 0.001), as well as GLUT-4 protein (-52%, P less than 0.001), was further reduced. Soleus muscle from hindlimb-suspended rats, which develops an enhanced capacity for insulin-stimulated glucose transport, showed muscle atrophy similar to denervated soleus but, in contrast, displayed substantial increases in GLUT-4 protein after 3 (+35%, P less than 0.05) and 7 days (+107%, P less than 0.001). These results indicate that altered GLUT-4 expression may be a major contributor to the changes in insulin-stimulated glucose transport that are observed with denervation and unweighting. We conclude that muscle activity is an important factor in the regulation of GLUT-4 expression in skeletal muscle.

Differences in insulin-induced glucose uptake and enzyme activity in running rats.

To evaluate the relationship between enhanced insulin action and level of exercise training, in vivo glucose uptake was assessed in the absence of added insulin and during insulin-stimulated conditions for three activity levels of voluntarily trained rats (low 2-5 km/day, medium 6-9 km/day, high 11-16 km/day). After rats rested for 24 h and fasted overnight, glucose uptake was estimated by comparing steady-state serum glucose (SSSG) levels at low insulin (SSSI) concentrations achieved during an insulin suppression test. In the absence of added insulin, SSSI averaged approximately 20 microU/ml and glucose uptake was similar for high runners and younger weight-matched controls. However, with insulin added to sustain SSSI at approximately 35 microU/ml, SSSG was significantly reduced in all runners (P less than 0.02), with the lowest value attained in high runners. Fasting serum triglycerides were also reduced in all runners (P less than 0.05), with the lowest values seen in medium and high runners. The concentration of glycogen in liver and select skeletal muscles at the start of the study was not different between trained and control rats, suggesting that enhanced insulin-stimulated glucose uptake was not the result of lower glycogen levels. In addition, glycogen synthase and succinate dehydrogenase activities in biceps femoris muscle were only elevated for high runners, but glycogen synthase activity was not enhanced in plantaris muscle and was decreased in soleus muscle. These findings indicate that enhanced insulin-stimulated glucose uptake and reduced serum triglyceride concentrations induced in exercise-trained rats at varying activity levels are dissociated from changes in glycogen synthase and oxidative enzyme activity for skeletal muscle.

Glucose transporters and maximal transport are increased in endurance-trained rat soleus.

Voluntary wheel running induces an increase in the concentration of the regulatable glucose transporter (GLUT4) in rat plantaris muscle but not in soleus muscle (K. J. Rodnick, J. O. Holloszy, C. E. Mondon, and D. E. James. Diabetes 39: 1425-1429, 1990). Wheel running also causes hypertrophy of the soleus in rats. This study was undertaken to ascertain whether endurance training that induces enzymatic adaptations but no hypertrophy results in an increase in the concentration of GLUT4 protein in rat soleus (slow-twitch red) muscle and, if it does, to determine whether there is a concomitant increase in maximal glucose transport activity. Female rats were trained by treadmill running at 25 m/min up a 15% grade, 90 min/day, 6 days/wk for 3 wk. This training program induced increases of 52% in citrate synthase activity, 66% in hexokinase activity, and 47% in immunoreactive GLUT4 protein concentration in soleus muscles without causing hypertrophy. Glucose transport activity stimulated maximally with insulin plus contractile activity was increased to roughly the same extent (44%) as GLUT4 protein content in soleus muscle by the treadmill exercise training. In a second set of experiments, we examined whether a swim-training program increases glucose transport activity in the soleus in the presence of a maximally effective concentration of insulin. The swimming program induced a 44% increase in immunoreactive GLUT4 protein concentration. Glucose transport activity maximally stimulated with insulin was 62% greater in soleus muscle of the swimmers than in untrained controls. Training did not alter the basal rate of 2-deoxyglucose uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of aerobic exercise on energy metabolism in the hypertensive rat heart.

BACKGROUND AND PURPOSE: In order to explore the possible effects of physical therapy interventions on people with hypertension, we evaluated the effects of aerobic exercise training on myocardial energy metabolism in an animal model of hypertension. SUBJECTS: We used 36 female spontaneously hypertensive rats (rats with genetically induced hypertension) and 12 normotensive Wistar-Kyoto rats. METHODS: The normotensive rats were sedentary and formed the CONsed group. The spontaneously hypertensive rats were randomly divided into 3 experimental groups (12 rats per group). Hypertensive rats that were sedentary formed the HTNsed group, those that received 8 weeks of exercise training formed the HTNx8 group, and those that received 16 weeks of exercise training formed the HTNx16 group. We measured systolic blood pressure, heart wet weight, maximal activities of cardiac energy metabolism enzymes, glucose transporter content, and total concentrations of protein, glycogen, and triglyceride. RESULTS: Systolic blood pressure was greater than 200 mm Hg in the CONsed group at the time of testing. Exercise training modestly (approximately 11-18 mm Hg) lowered blood pressure in the HTNx8 and HTNx16 groups. Fatty acid enzyme activity was greater in the CONsed group than in HTNsed and HTNx8 groups, but activity was roughly equivalent between the CONsed group and the HTNx16 group. Glucose enzyme activity was greater in the HTNx16 group than in the CONsed group and HTNsed group. Intracellular glycogen concentration was greater in the HTNx8 group than in HTNsed group. CONCLUSION AND DISCUSSION: Results of this study suggest that aerobic exercises may help to normalize cardiac energy metabolism in mammals with hypertension.

Alterations in glucose and protein metabolism in animals subjected to simulated microgravity.

Reduction of physical activity due to disease or environmental restraints, such as total bed rest or exposure to spaceflight, leads to atrophy of skeletal muscle and is frequently accompanied by alterations in food intake and the concentration of metabolic regulatory hormones such as insulin. Hindlimb suspension of laboratory rats, as a model for microgravity, also shows marked atrophy of gravity dependent muscles along with a reduced gain in body weight. Suspended rats exhibit enhanced sensitivity to insulin-induced glucose uptake when compared with normal control rats and resistance to insulin action when compared with control rats matched similarly for reduced body weight gain. These changes are accompanied by decreased insulin binding and tyrosine kinase activity in soleus but not plantaris muscle, unchanged glucose uptake by perfused hindlimb and decreased sensitivity but not responsiveness to insulin-induced suppression of net proteolysis in hindlimb skeletal muscle. These findings suggest that loss of insulin sensitivity during muscle atrophy is associated with decreased insulin binding and tyrosine kinase activity in atrophied soleus muscle along with decreased sensitivity to the effects of insulin on suppressing net protein breakdown but not on enhancing glucose uptake by perfused hindlimb.

Differential effects of anesthetics on electrical properties of the rainbow trout (Oncorhynchus mykiss) heart.

We compared electrocardiographic signals in hatchery-reared, non-spinally-transected, immature rainbow trout (Oncorhynchus mykiss Walbaum) under clove oil (25 ppm), tricaine methanesulfonate (tricaine, 60 ppm), and benzocaine (108 ppm) general anesthesia (35 min, 14 degrees C). For all 3 anesthetics, the mean heart rate (HR) and QRS amplitude did not differ, and QRS duration and QT interval were independent of HR. Heart rate variability (HRV) was significantly (4-fold, P=0.032) higher under benzocaine than under clove oil and tricaine, but did not differ between clove oil and tricaine. QRS duration differed between groups (P<0.001, F=121); benzocaine anesthesia resulted in longer QRS complexes compared to clove oil (P<0.001) and tricaine (P<0.001) anesthesia, and QRS complexes under clove oil were longer than those under tricaine (P<0.001). High HRV and QRS amplitude variation with benzocaine were associated with HR oscillations as anesthetic exposure time increased, and suggest benzocaine toxicity which may influence cardiac function studies. Similar clove oil and tricaine ECG patterns suggest comparable autonomic effects, and maintenance of myocardial excitability. Given its low cost, ease of use, and similar ECG profiles to tricaine, clove oil is a viable alternative for studies of cardiac function in anesthetized rainbow trout.

Morphometric and biochemical characteristics of ventricular hypertrophy in male rainbow trout (Oncorhynchus mykiss).

We examined the morphometric and biochemical effects of ventricular hypertrophy in male rainbow trout (Oncorhynchus mykiss) during sexual maturation. Our investigation focused on characterizing the growth of ventricular layers, on cardiomyocyte dimensions (length, cross-sectional area and cell volume) and on the activities of enzymes involved in intermediary metabolism. Relative ventricle mass (100 x ventricle mass/body mass) increased by as much as 2.4-fold during sexual maturation [as defined by an increasing gonadosomatic index (100 x gonad mass/body mass)], and this resulted in an increased proportion of epicardium relative to endocardium. Ventricular enlargement was associated with increased length (+31 %) and transverse cross-sectional area (+83 %) of cardiomyocytes, which resulted in an expansion of up to 2.2-fold in mean myocyte volume (from 1233 to 2751 micron3). These results indicate that sexual maturation induces ventricular enlargement through myocyte hypertrophy. Cell length and cross-sectional area were similar in both myocardial layers, and myocytes were elliptical rather than circular in transverse cross section. Ventricular hypertrophy did not alter transverse cell shape, perhaps reflecting the maintenance of short diffusion distances for small molecules as cells hypertrophy. Myocyte hypertrophy could not account entirely for the sevenfold range of ventricle masses from different-sized fish, indicating that myocyte hyperplasia contributes substantially to ventricular growth as trout grow. Measurements of the maximal activities of metabolic enzymes demonstrated that ventricular hypertrophy was associated with (1) higher epicardial but not endocardial activities of citrate synthase (by 23 %) and beta-hydroxyacyl-CoA dehydrogenase (by 20 %); (2) lower activities of hexokinase (by 50 %) in both layers, and (3) no change in lactate dehydrogenase or pyruvate kinase activities, which were also similar between layers. These results suggest that the energetic needs of the hypertrophied trout ventricle may be met through increased reliance on fatty acid oxidation, particularly by the endocardium, but decreased reliance on glucose as a metabolic fuel in both layers.

Structural and biochemical analyses of cardiac ventricular enlargement in cold-acclimated striped bass.

We examined effects of temperature acclimation on ultrastructural characteristics of cardiac myocytes and maximal activities of metabolic enzymes in cardiac tissue of striped bass (Morone saxatilis). Ventricular mass and ventricular mass divided by body weight were significantly increased (29% and 40%, respectively) in animals acclimated to cold (5 degrees C) vs. warm temperatures (25 degrees C). Mean myocyte diameter was increased at cold temperature (3.47 +/- 0.14 vs. 2.98 +/- 0.08 microns), which is sufficient to explain the increase in ventricular mass. Ventricular enlargement did not alter volume densities of mitochondria, myofibrils, protein concentration, or citrate synthase activity. Thus total volume of mitochondria and myofibrils increased proportionately with cardiac mass in cold animals. Activities of hexokinase (34%) and carnitine palmitoyltransferase (42%) increased in cold animals, suggesting positive compensation and increased aerobic capacity for utilization of glucose and fatty acids for energy production. Enlargement of the ventricle and an increased capacity for ATP production in striped bass may help compensate for kinetic constraints at cold temperatures and maintain circulatory support to oxidative axial musculature for swimming activity.

Cold acclimation increases carnitine palmitoyltransferase I activity in oxidative muscle of striped bass.

The effect of thermal acclimation on the activity of carnitine palmitoyltransferase I (CPT I), the rate-limiting enzyme for beta-oxidation of long-chain fatty acids, was determined in oxidative red muscle of striped bass (Morone saxatilis) acclimated at 5 or 25 degrees C. As observed in mammalian tissues, malonyl-CoA potently inhibited CPT I activity of mitochondria. Inhibition by malonyl-CoA required inclusions of both bovine serum albumin (BSA) and palmitoyl-CoA in the reaction media. Because BSA binds long-chain fatty acyl-CoAs, this observation suggests that free fatty acyl-CoAs may disrupt mitochondrial membranes and affect the CPT I protein. Cold acclimation increased citrate synthase activity 1.6-fold and total CPT activity 2-fold in homogenates of red muscle; free carnitine increased 62%, and specific activity of CPT I in mitochondria increased 2-fold. No differences were observed between cold- and warm-acclimated fish in substrate-binding properties of CPT I at an assay temperature of 15 degrees C, as judged by the Michaelis constant (Km) for carnitine (0.11 +/- 0.02 vs. 0.13 +/- 0.02 mM) or inhibition of CPT I, as determined by the half-maximal inhibition concentration (IC50) for malonyl-CoA (0.14 +/- 0.05 vs. 0.09 +/- 0.03 microM). Thermal sensitivity of CPT I (Q10 = 2.91 +/- 0.12 vs. 3.02 +/- 0.20) and preference of CPT I for different long-chain fatty acyl-CoA substrates (16:1-CoA = 16:0-CoA > 18:1-CoA) were not altered by thermal acclimation.(ABSTRACT TRUNCATED AT 250 WORDS)