Summary The effects of exercise stress on erythrocyte β‐adrenergic receptor characteristics and plasma concentrations of adrenaline, noradrenaline and thyroid hormones were studied in Thoroughbred racehorses during rest and after exercise. Five minutes after a maximal speed race of 1200 ± 200 m (mean ± s.d.), both plasma adrenaline and noradrenaline concentrations increased with respect to basal values (from 2.48 ± 0.15 to 3.83 ± 0.27 and from 2.13 ± 0.11 to 3.53 ± 0.27 nmol/1 respectively). The increment of adrenaline was greater in high performance (HP) as compared to low performance (LP) horses (76.9 vs. 43.5%), in accordance with the contribution of the adrenal medulla in the sympathoadrenal response to exercise. Triiodothyronine (T3), but not thyroxine (T4) levels increased 5 min after exercise (from 55.6 ± 2.9 to 81 ± 3.7 ng/dl and from 0.67 ± 0.04 to 0.70 ± 0.05 pg/dl respectively). No differences were observed in basal values of thyroid hormones or in the percentage of T3 increment, when comparing HP vs. LP horses. Erythrocyte membranes obtained 5 min after racing showed decreased concentrations of β‐adrenergic receptors (β‐AR) and dissociation constant as compared to basal values (50.1 ± 7.0 vs. 95.7 ± 12.0 fmol/mg protein and 0.97 ± 0.24 vs. 2.04 ± 0.3 nmol/l respectively). This temporal pattern suggest that the observed changes in β‐AR characteristics could be mediated by catecholamines, but not by thyroid hormones, in this model. This down regulation of β‐AR may act as a protecting mechanism preventing the erythrocytes from the decrease in membrane fluidity known to be provoked by adrenergic agonists. The accomplished study showed that, in the Thoroughbred horse, there is a homeostatic response to race stress, characterised by a sudden increase in plasma catecholamines and T3 and a parallel decrease in β‐AR concentration on the erythrocyte membrane. In this way the racing horse could rapidly adjust its metabolism to the exercise stress, but at the same time override one possible undesirable side‐effect caused by these hormonal changes. Further studies will be required to establish performance‐related differences occurring in endocrine changes.
In the present work, cassava leaves were treated with 0.5 kg ammonia/kg dry matter at 78 degrees C and 30% moisture content in a 2-kg reactor. Protein extraction was carried out with a calcium hydroxide solution (pH 10) for 30 min at several temperatures (30 degrees C, 45 degrees C, 60 degrees C, 75 degrees C, and 90 degrees C) and solid/liquid ratios (1:10 and 1:15) in a thermostatized bath. Soluble protein content of the extracts was determined by Lowry's method. Dry substrate concentrations of 5%, 7.5%, and 10% and enzyme doses of 2 and 5 IU/g dry matter were used for the enzymatic hydrolysis in an orbital incubator at 50 degrees C and 100 rpm. Both cellulase and xylanase were used. Reducing sugars produced were determined with the dinitrosalicylic acid method. The highest protein extraction yield for the ammonia-treated leaves was 29.10%, which was 50% higher than with the untreated leaves (20%), and was obtained at 90 degrees C with a 1:10 solid/liquid ratio. The concentrate had a protein content of 36.35% and the amino acid profile was suitable for swine and poultry. The highest sugar yield was 54.72% with respect to theoretical and was obtained with 5% solids and an enzyme dose of 5 IU/g dry matter. This yield was 3.4 times higher than the yield of the untreated leaves (16.13%). These results indicate that cassava leaves have a great potential for animal feeding and ethanol production. Both protein extraction and sugar yields may be enhanced by optimizing the ammonia treatment.
We have previously shown that arginine vasopressin (AVP) causes a rapid (5-10 min) contractile response in cultured mesangial cells plated onto slippery substrata such as poly(hydroxyethyl methacrylate)-coated dishes. This contraction is associated with an increase in the levels of inositol trisphosphate (InsP3), diacylglycerol and prostaglandin E2 (PGE2). We now report that agents which are known to activate protein kinase C, i.e. phorbol 12-myristate 13-acetate (PMA) and oleolylacetylglycerol (OAG), also contract mesangial cells; however, the contractile response is slow to develop (15-30 min). The inactive phorbol ester, 4 alpha -phorbol 12,13-didecanoate, did not elicit contraction. PMA and OAG did not increase InsP3 release in mesangial cells. However, pretreatment of mesangial cells with PMA inhibited the formation of InsP3. This inhibition could not be explained by a reduction in AVP binding since PMA treatment did not influence the number or affinity of [3H]AVP binding sites in intact cells. PMA alone stimulated PGE2 production in mesangial cells to a degree similar to AVP. Contrary to what was seen with InsP3, pretreatment of cells with PMA before AVP had an additive effect on arachidonic acid release and PGE2 production. Thus, there is an apparent dissociation of phospholipase C activity from that of phospholipase A2.
We have studied the effects of the vasoactive agents phorbol 12-myristate 13-acetate (PMA) and vasopressin (VP) on phosphatidylcholine metabolism in cultured rat glomerular mesangial cells. PMA and VP stimulate the incorporation of [3H]choline into phosphatidylcholine and the release of [3H]choline into the culture medium. VP, but not PMA, also increases the release of phosphorylcholine into the medium. This suggests that PMA specifically stimulates phospholipase D, whereas VP stimulates phospholipases C and D. Experiments were also conducted to look for production of phosphatidic acid and diacylglycerol, products of phospholipase D- and C-mediated breakdown of phosphatidylcholine. Treatment of cells prelabeled with [3H]myristic acid for 2.5 min with PMA or VP increases the content of [3H]myristic acid in diacylglycerol and phosphatidic acid. A dual labeling study ([3H]myristic acid and [14C]arachidonic acid) suggests that phosphatidylcholine is an important source of diacylglycerol in cells treated with VP and PMA. When PMA or VP are added to [3H]myristic acid-labeled cells in the presence of ethanol, increased labeling of phosphatidylethanol is seen as early as 2.5 min. Desensitization of protein kinase C by overnight treatment of cells with PMA blocked subsequent VP-stimulated formation of phosphatidylethanol and release of [3H]choline. When cells were simultaneously treated with VP and PMA, additive effects on phosphatidylethanol formation and [3H]choline release were observed.
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