Reversible binding of long-chain fatty acids to purified FAT, the adipose CD36 homolog.

Transport of long-chain fatty acids into rat adipocytes was previously shown to be inhibited by the reactive derivative sulfosuccinimidyl oleate consequent to its binding to a membrane protein FAT, which is homologous to CD36. In this report, the ability of the purified protein to bind native fatty acids was investigated. CD36 was isolated from rat adipocytes by phase partitioning into Triton X-114 followed by chromatography on DEAE and then on wheat germ agglutinin. Fatty acid binding was determined by incubating CD36, solubilized in buffer containing 0.1 Triton X-100, with fatty acids at 37 degrees C, and then by adsorbing the unbound ligand with Lipidex 1,000 at 0 degrees C. Bovine serum albumin was used as a positive control and gelatin, a protein that does not bind fatty acids, as a negative control. Measurements with albumin yielded reproducible binding values which were not altered by the presence of 0.1% Triton X-100. Under the same conditions, gelatin yielded reproducibly negative measurements that did not differ significantly from zero. CD36 bound various long-chain fatty acids at low ligand to protein ratios. Warming the protein-FA-Lipidex mixture to 37 degrees C removed the FA off the protein. Thus, binding was reversible and distinct from the palmitoylation of the protein known to occur on an extracellular domain. Comparison of the predicted secondary sequence of CD36 with that of human muscle fatty acid binding protein suggested that a potential binding site for the fatty acid on CD36 may exist in its extracellular segment between residues 127 and 279.

Neural control of glucose uptake by skeletal muscle after central administration of NMDA.

Intracerebroventricular injection of N-methyl-D-aspartate (NMDA) produces hyperglycemia and increases whole body glucose uptake. The purpose of the present study was to determine in rats which tissues are responsible for the elevated rate of glucose disposal. NMDA was injected intracerebroventricularly, and the glucose metabolic rate (Rg) was determined for individual tissues 20-60 min later using 2-deoxy-D-[U-14C]glucose. NMDA decreased Rg in skin, ileum, lung, and liver (30-35%) compared with time-matched control animals. In contrast, Rg in skeletal muscle and heart was increased 150-160%. This increased Rg was not due to an elevation in plasma insulin concentrations. In subsequent studies, the sciatic nerve in one leg was cut 4 h before injection of NMDA. NMDA increased Rg in the gastrocnemius (149%) and soleus (220%) in the innervated leg. However, Rg was not increased after NMDA in contralateral muscles from the denervated limb. Data from a third series of experiments indicated that the NMDA-induced increase in Rg by innervated muscle and its abolition in the denervated muscle were not due to changes in muscle blood flow. The results of the present study indicate that 1) central administration of NMDA increases whole body glucose uptake by preferentially stimulating glucose uptake by skeletal muscle, and 2) the enhanced glucose uptake by muscle is neurally mediated and independent of changes in either the plasma insulin concentration or regional blood flow.

Denervation increases clenbuterol sensitivity in muscle from young rats.

Clenbuterol has been shown to ameliorate denervation-induced atrophy and, therefore, clearly has therapeutic potential in the treatment of muscle wasting conditions in man. Previous studies have used dosages in rats which would be unacceptable in clinical practice, but the present results show that denervated muscle has a greater sensitivity to the drug than innervated or cardiac muscle. Fiber hypertrophy and an increase in protein and RNA content could be observed in denervated muscles but not in innervated muscles at a dose of 10 micrograms/kg body weight. When considered on a metabolic body weight basis, the effective dose in rats and the "safe" dose in man are surprisingly comparable. The observations imply that there is good reason to suppose that clenbuterol could be effective in ameliorating similar wasting conditions in man.

Attenuated responses of muscle protein synthesis to fasting and insulin in adult female rats.

One-year-old adult female rats were fasted for 12 or 36 h followed by a 30-min infusion of insulin. The responses of the fractional rate of protein synthesis (Ks) in the individual muscles (measured in vivo) to fasting were small and mostly nonsignificant. After 12 h of fasting, only the epitrochlearis muscle (ET) showed a significant decrease in Ks, and, even after 36 h of fasting, a significant decrease in Ks was seen in only ET, extensor digitorum longus, and tensor fasciae latae (TFL). After the 36-h fast, infusion of insulin restored the fed Ks in all muscles except TFL. The fiber-type composition of the individual muscles appeared to influence the muscles' responsiveness to the fasting, since the highly glycolytic TFL was the most sensitive (particularly after 36 h of fasting), whereas the highly oxidative adductor longus and soleus muscles were unaffected by either fasting or insulin. In a second experiment, refeeding of fasted adult rats also had little effect on Ks, consistent with the low sensitivity to fasting shown by the first experiment. The parallel results in the two experiments confirmed that the low responsiveness to fasting and insulin infusion in these adult rats was not a result of failure to absorb in "fed" animals or insufficient levels of insulin during insulin infusions. In contrast, a third experiment showed that muscle protein synthesis in the gastrocnemius muscle from young adult (5-mo-old) female rats was significantly reduced after only 12 h of fasting.

Protein synthesis in adult skeletal muscle after tenotomy: responses to fasting and insulin infusion.

Muscle growth was established in specific muscles in the hindlimb of adult female rats by tenotomy of the gastrocnemius muscle. Seven days after surgery there was an increase in the wet weight of the soleus (Sol) and plantaris (P) muscles and a decrease in that of the gastrocnemius (G) muscle from the tenotomized limb compared with the respective control muscles from the contralateral limb from the same animal. In all three muscles there was a significant increase in the fractional rate of protein synthesis (ks) in the muscles from the tenotomized limb above the rate of the respective control muscles. In contrast, the extensor digitorum longus (EDL) muscle showed no change in wet weight or ks 7 days after tenotomy of G. Fasting for 12 or 36 h had no significant effect on ks in G, P, or Sol muscles from either the control or tenotomized limbs. In EDL from the control limb, both fasting periods resulted in a significant decrease in ks, although this effect was not seen in the EDL from the tenotomized limbs of the same animals. A subsequent 30-min insulin infusion was similarly ineffectual in G, P, and Sol, with its only effect evident in the EDL from the control limb, where it was sufficient to reverse the decreased ks resulting from the fasting, even though after 36 h fasting the reversal was only partial.

Responses of protein synthesis in different skeletal muscles to fasting and insulin in rats.

The rate of protein synthesis (Ks) was measured in nine skeletal muscles from young rats (100 g body wt) after fasting and subsequent insulin infusion. An overnight fast (12 h) resulted in a fall in Ks in all muscles, but this ranged from a small nonsignificant decrease in soleus (Sol) to one-half of the fed rate in tensor fascia latae (TFL). After fasting for 36 h, Ks was significantly reduced in all muscles, although there was still a range apparent between different muscles. The response of the individual muscles to fasting was related to fiber type composition, and, in particular, the responses of the commonly studied Sol were characteristic of the highly oxidative fiber composition rather than being peculiar to Sol itself. The magnitude of the increase in Ks during an infusion of insulin (0.5 h) in the 12-h fasted rats was proportional to the magnitude of the initial response to fasting and these changes were largely reflected in changes in the rate of synthesis expressed per unit RNA (KRNA). After 36 h of fasting, Ks in the muscles responded little to the insulin stimulus, and a similar small effect on KRNA, compared with that in the 12-h fasted animals, suggests an apparent insensitivity to insulin after this longer fasting period.

Fiber-type composition of nine rat muscles. I. Changes during the first year of life.

There are few data available that describe the changes in fiber-type profiles with age in a range of muscles; thus fiber-type profiles and areas were determined in nine muscles of female rats from weaning to 1 yr. The results not only demonstrated the difference in fiber-type composition, size, and hence functional area in the various muscles examined but also illustrated the changes in these parameters with age. In particular, it was clear that two ends of a spectrum of fiber compositions are represented in the muscles studied: tensor fasciae latae, mainly fast-twitch glycolytic at one end and soleus (and adductor longus), mainly slow-twitch oxidative at the other; the remaining muscles were mostly dominated by fast-twitch fibers of a variety of metabolic types. Aging resulted in an increase in fiber area that was most dramatic in fast-twitch glycolytic fibers. Changes in fiber type with age were noted in all muscles, but the exact nature of the developmental changes appeared muscle specific.

Fiber-type composition of nine rat muscles. II. Relationship to protein turnover.

Rates of protein synthesis in vivo and fiber-type composition were measured in nine limb muscles of female rats at ages ranging from weaning to 1 yr. In all muscles, there was a decline in protein synthesis with increasing age, mostly as a result of a fall in the RNA content. Rates of protein breakdown and growth were determined in six muscles and these also declined with age. Regression analysis of the data for all ages showed that protein synthesis was correlated with the content of slow oxidative fibers but not with the relative proportions of fast glycolytic to fast oxidative glycolytic fibers.