The c-Jun N-terminal kinase mediates the induction of oxidative stress and insulin resistance by palmitate and toll-like receptor 2 and 4 ligands in 3T3-L1 adipocytes.

Saturated fatty acids (SFAs) are known to induce inflammation and insulin resistance in adipocytes through toll-like receptor-4 (Tlr4) signaling, but the mechanisms are not well delineated. Furthermore, the potential roles of Tlr2 and the c-Jun N-terminal kinase (JNK) in inflammation in adipocytes have not been investigated. We demonstrated that palmitate, lipopolysaccharide (LPS), and the toll-like receptor-2 (Tlr2) agonist, zymosan A (ZymA), induced insulin resistance in a time- and dose-dependent manner in 3T3-L1 adipocytes. Corresponding with the reduction of insulin sensitivity was an increased expression of IL-6, as well as activation of the proinflammatory transcription factors, nuclear factor kappa B, and activator protein-1. Reactive oxygen species (ROS) accumulation was also observed in palmitate and Tlr agonist treated adipocytes. The JNK inhibitor, SP600125, attenuated insulin resistance mediated by SFA and Tlr agonists, which corresponded with a diminished proinflammatory response and reduced ROS accumulation. Collectively, these results demonstrated Tlr2 involvement in adipocyte inflammation and therefore implicated the receptor as a potential target for SFA. Moreover, activation of JNK also appeared to be essential to Tlr2-, as well as Tlr4-induced insulin resistance and oxidative stress.

Regulation of hepatic peroxisome proliferator-activated receptor alpha expression but not adiponectin by dietary protein in finishing pigs.

Soy protein regulates adiponectin and peroxisome proliferator-activated receptor alpha (PPARalpha) in some species, but the effect of dietary soy protein on adiponectin and PPARalpha in the pig has not been studied. Therefore, the objective of this study was to determine whether soya bean meal reduction or replacement influences serum adiponectin, adiponectin mRNA, serum metabolites and the expression of PPARalpha and other genes involved in lipid deposition. Thirty-three pigs (11 pigs per treatment) were subjected to one of three dietary treatments: (i) reduced crude protein (CP) diet containing soya bean meal (RCP-Soy), (ii) high CP diet containing soya bean meal (HCP-Soy) or (iii) high CP diet with corn gluten meal replacing soya bean meal (HCP-CGM) for 35 days. Dietary treatment had no effect on overall growth performance, feed intake or measures of body composition. There was no effect of dietary treatment on serum adiponectin or leptin. Dietary treatment did not affect the abundance of the mRNAs for adiponectin, PPARalpha, PPARgamma2, lipoprotein lipase or fatty acid synthase in adipose tissue. The mRNA expression of PPARalpha, PPARgamma2, lipoprotein lipase or fatty acid synthetase in loin muscle was not affected by dietary treatment. In liver tissue, the relative abundance of PPARalpha mRNA was greater (p < 0.05) in pigs fed the HCP-Soy diets when compared to pigs fed RCP-Soy or HCP-CGM diets. Hepatic mRNA expression of acyl-CoA oxidase or fatty acid synthase was not affected by dietary treatment. Western blot analysis indicated that hepatic PPARalpha protein levels were decreased (p < 0.05) in pigs fed the RCP-Soy diets when compared to pigs fed the HCP-Soy diets. These data suggest that increasing the soy protein content of swine diets increases hepatic expression of PPARalpha without associated changes in body composition.

Adipose triglyceride lipase protein abundance and translocation to the lipid droplet increase during leptin-induced lipolysis in bovine adipocytes.

Proper regulation of lipid metabolism is critical for preventing the development of metabolic diseases. It is clear that leptin plays a critical role in the regulation of energy homeostasis by regulating energy intake. However, leptin can also regulate energy homeostasis by inducing lipolysis in adipocytes, but it is unclear how the major lipases are involved in leptin-stimulated lipolysis. Therefore, the objectives of this study were to determine if (1) leptin acts directly to induce lipolysis in bovine adipocytes, (2) the potential lipases involved in leptin-induced lipolysis in bovine adipocytes, and (3) increases translocation of adipose triglyceride lipase (ATGL) and hormone sensitive lipase (HSL) during leptin-stimulated lipolysis in bovine stromal vascular cell-derived adipocytes. As hypothesized, leptin induced a lipolytic response (P = 0.02) in isolated adipocytes which was accompanied by an increase in phosphorylation of signal transducer and activator of transcription (STAT)3 (P = 0.03), a well-documented secondary messenger of leptin, and ATGL protein abundance (P < 0.01). Protein abundance of STAT3, perilipin, HSL, and phosphorylation of HSL by PKA and AMPK were not altered during leptin-stimulated lipolysis (P > 0.05). Immunostaining techniques were employed to determine the location of HSL and ATGL. Both lipases translocated to the lipid droplet after 2 h of exposure to isoproterenol (P < 0.02). However, only ATGL was translocated to the lipid droplet during leptin-stimulated lipolysis (P = 0.04), indicating ATGL may be the active lipase in leptin-stimulated lipolysis. In summary, leptin stimulates lipolysis in bovine adipocytes. The lack of phosphorylated HSL and translocation of HSL to the lipid droplet during leptin-stimulated lipolysis suggest minimal activity by PKA. Interestingly, leptin-stimulated lipolysis is accompanied by an increase in ATGL protein abundance and translocation to the lipid droplet, indicating its involvement in leptin-stimulated lipolysis either due to an increase in protein abundance or through a novel lipolytic cascade.

Expression and cDNA cloning of porcine peroxisome proliferator-activated receptor gamma (PPARgamma).

Peroxisome proliferator-activated receptor gamma (PPARgamma) is a member of the PPAR subfamily of nuclear hormone receptors. In rodents and humans, expression of PPARgamma is predominantly found in adipose tissue where it regulates adipocyte differentiation and the expression of multiple adipocyte genes. The primary aim of this work was to clone the porcine PPARgamma cDNA and examine the regulation of gene expression in porcine subcutaneous adipose tissue. The porcine PPARgamma gene encodes a 1.8-kb mRNA transcript and shares 99, 96 and 97% amino acid sequence identity to the human, mouse and cow PPARgamma molecules, respectively. Both isoforms of PPARgamma (gamma1 and gamma2) are highly expressed in porcine adipose tissue. The gamma2 isoform is expressed in low abundance in porcine spleen, whereas the gamma1 isoform is highly expressed in spleen and lung and at a low abundance in several other tissues. Western blot analysis confirmed a high level of PPARgamma protein expression in porcine adipose tissue compared to other tissues. Both caloric restriction and fasting significantly reduced PPARgamma2 but not gamma1 mRNA and PPARgamma protein abundance in subcutaneous adipose tissue compared to ad-libitum fed controls. We provide the first evidence that PPARgamma is abundantly expressed in porcine subcutaneous adipose tissue, and that expression is regulated by caloric intake. Thus, PPARgamma may play an important role in adipogenesis and hormone action in porcine adipocytes.

Proinflammatory cytokines regulate myogenic cell proliferation and fusion but have no impact on myotube protein metabolism or stress protein expression.

The objective of the present study was to evaluate the effect of the proinflammatory cytokines, tumor necrosis factor-alpha (TNF-alpha) and interleukin-1-alpha (IL-1a), on myoblast proliferation and fusion and on myocyte protein metabolism and stress protein expression. Proliferation was suppressed (p < 0.05) by both cytokines, alone and in combination, and at lower concentrations, the suppression was additive. Likewise, fusion was retarded (p < 0.05) by these cytokines alone and in combination. Myosin synthesis was not altered acutely or chronically by TNF-alpha alone or by the combination of this cytokine with IL-1alpha. Chronic exposure to TNF-alpha did not alter total cellular protein synthesis, but exposure to IL-1alpha and the cytokine combination resulted in an increase (14% to 19%, p < 0.05) in synthesis. Neither total cellular protein nor myosin degradation were influenced by either cytokine alone or by the combination. There was no detectable induction, acutely or chronically, of any of the stress proteins evaluated (HSC70, HSP70, or HSP60). These data suggest that cytokines may alter muscle growth and development prenatally and postnatally and that the changes in muscle protein metabolism during periods of immune challenge are not direct effects of TNF-alpha or IL-1alpha.

Leptin expression is reduced with acute endotoxemia in the pig: correlation with glucose, insulin, and insulin-like growth factor-1 (IGF-1).

Leptin has been implicated in the regulation of anorexia associated with cachexia in rodents and humans. Regulation of leptin expression is under complex endocrine and metabolic control. To determine if leptin expression is regulated by acute inflammation and to define the endocrine and metabolic factor(s) that regulates leptin expression during acute inflammation, castrate male pigs (ad libitum fed, used as their own controls) were treated with saline (control period) and endotoxin (lipopolysaccharide [LPS] period). Frequent blood samples were collected to identify dynamic changes in hormones and metabolites that are known to regulate leptin expression. LPS caused fever and elevated plasma cortisol (p < 0.0004), tumor necrosis factor-alpha (TNF-alpha) (p < 0.0001), and plasma nonesterified fatty acids (NEFA) (p < 0.001) compared with control. Circulating insulin (p < 0.01), glucose (p < 0.003), and insulin-like growth factor-1 (IGF-1) (p < 0.0001), as well as adipose leptin mRNA abundance (p < 0.01), were profoundly reduced following LPS treatment compared with control. Our data indicate that during acute endotoxemia (1-10 h after injection), leptin gene expression is decreased compared with ad libitum fed animals and is more closely related to energy homeostasis than cytokine profiles in plasma.

Leptin expression in porcine adipose tissue is not increased by endotoxin but is reduced by growth hormone.

The physiologic response to infection includes reductions in tissue concentrations of anabolic growth factors as a means of reducing growth and conserving nutrients for immunologic processes. This repartitioning of nutrients is accompanied by anorexia, which has been linked to increased leptin expression. Furthermore, leptin and growth hormone (GH) concentrations are inversely related, with leptin being required for normal GH release. The objective of this study was to determine if pretreatment with GH would influence endotoxin-induced changes in leptin expression or attenuate endotoxin-induced reductions in serum insulin-like growth factor-1 (IGF-1) and IGF-1 expression in liver and longissimus muscle. In experiment 1, 40 pigs were assigned to four treatments (n = 10 per treatment) arranged as a 2x2 factorial with GH (s.c. injection, 2 mg 1 h before challenge and 2 mg 2 h after challenge) and endotoxin (single i.m. injection, 25 microg/kg body weight) as main effect variables. Pretreatment with GH resulted in a marked increase (p<0.001) in serum GH within 1 h that was sustained throughout the study. Endotoxin challenge reduced (p<0.003) serum IGF-1 independent of GH (GH x endotoxin, p>0.682), and reduced (p<0.05) IGF-1 expression in longissimus muscle but not liver. Leptin mRNA abundance was reduced 56% (p<0.005) by GH but was not affected by endotoxin (p>0.81). In experiment 2, 36 pigs (n = 12 per treatment) were either allowed ad libitum feed consumption with no injection or deprived of feed and injected twice with either saline or endotoxin 24 h apart. Feed deprivation reduced leptin expression (p<0.05). However, endotoxin did not change leptin expression but markedly increased (p<0.05) serum haptoglobin. These data indicate that changes in IGF-1 status in endotoxin-challenged pigs are independent of serum GH and that leptin expression is not increased by endotoxin challenge in the pig. These data also indicate a regulatory linkage between GH and leptin in vivo.

Growth hormone regulates leptin gene expression in bovine adipose tissue: correlation with adipose IGF-1 expression.

Leptin, the product of the ob gene, is secreted from white adipocytes and regulates food intake and whole-body energy metabolism. In rodents and humans, leptin gene expression is under complex endocrine and metabolic control, and is strongly influenced by energy balance. Growth hormone (GH) has myriad effects on adipose tissue metabolism. The primary aim of this study was to determine the ability of GH to regulate leptin mRNA expression in bovine adipose tissue in vitro and in vivo. Incubation of subcutaneous adipose tissue explants for 24 h with GH alone had no effect on bovine leptin gene expression, whereas high concentrations of insulin or dexamethasone (DEX) potently stimulated bovine leptin mRNA abundance. GH, in combination with high concentrations of insulin, DEX, or both, attenuated the ability of insulin or DEX to stimulate leptin expression in vitro. These data indicate that GH can indirectly regulate leptin expression in vitro by altering the adipose tissue response to insulin or DEX. We extended these studies to examine the ability of GH to regulate leptin expression in vivo, using young castrate male cattle treated with no hormone (control) or GH (200 micrograms/kg body weight per day) for 3 days. GH increased plasma GH and insulin concentrations, but not those of cortisol or non-esterified fatty acid (NEFA) concentrations. GH treatment increased adipose tissue leptin and IGF-1 mRNA concentrations (n=9, P>0.001). In addition, leptin abundance was highly correlated with adipose tissue IGF-1 mRNA in GH-treated animals (P>0.001). The timing of GH-induced changes in leptin gene expression preceded measurable GH effects on adiposity.

Cloning and expression of porcine adiponectin, and its relationship to adiposity, lipogenesis and the acute phase response.

Adiponectin is an adipocyte-derived hormone that has been implicated recently in the regulation of inflammation in immunocytes, and in lipid metabolism and glucose homeostasis in liver, skeletal muscle and adipocytes. However, information in non-rodent models is limited. We have cloned and sequenced the porcine adiponectin open reading frame and evaluated the regulation of adiponectin in vivo following lipopolysaccharide (LPS) or E. coli administration. The porcine sequence shares approximately 88, 86, 85 and 83% homology with the dog, human, cow and mouse adiponectin respectively, and 79-83% similarity with dog, human, cow and mouse proteins at the amino acid level, based on the translated porcine sequence and GenBank submissions for the other species. Relative serum adiponectin concentrations were not altered in pigs infused with E. coli, and mRNA expression in adipose tissue was not responsive to LPS. However, analysis of serum from very lean vs a substantially fatter genotype of pig indicated that relative circulating adiponectin concentrations are higher (P<0.01) in the lean pigs than in the fatter genotype, and that the difference is established relatively early in the growth curve. Also, incubating pig adipocytes for 6 h with recombinant pig adiponectin resulted in an approximately 30% reduction (P<0.05) in lipogenesis compared with adipocytes under basal conditions and with those incubated in the presence of insulin. This is the first report in any species that adiponectin antagonizes the incorporation of glucose carbon into lipid in the adipocyte, and provides additional evidence that adiponectin acts as an autocrine regulatory factor to regulate energy metabolism.

Regulation of PPARgamma but not obese gene expression by dietary fat supplementation.

Leptin, the product of the obese gene, and peroxisome proliferator activated receptor gamma (PPARgamma) are important regulators of energy metabolism, adipogenesis, and immune function. In rodent models, both genes seem to respond at the mRNA and/or protein levels to dietary fat consumption. To determine the effect(s) of dietary saturated and polyunsaturated fatty acids on the expression (mRNA abundance) of these genes, adipose tissue was obtained from pigs fed three different dietary fat sources. Corn-soybean meal diets containing no added fat (NO, control) or 10% beef tallow (BT), safflower oil (SO), or fish oil (FO) were fed ad libitum (n = 12) for 12 weeks. The abundance of obese, PPARgamma1, and PPARgamma2 mRNA was quantified relative to 18S rRNA using ribonuclease protection assays. The gain:feed ratio was improved (P < 0.05) 21% by all fats with a corresponding reduction (P < 0.05) in feed intake. Relative to pigs fed NO, serum total cholesterol was increased (P < 0.01) in pigs fed BT and triglyceride and nonesterified fatty acid concentrations were increased (P < 0.01) by all supplemental fats. Serum insulin was increased (P < 0.10) only by SO. Neither obese nor PPARgamma1 mRNA abundance were responsive to added fat (P > 0.15). However, the abundance of PPARgamma2 mRNA was increased fourfold by SO compared with the NO diet. These data indicate that the abundance of obese mRNA is independent of dietary fat consumption per se, whether saturated or unsaturated, when feed consumption is reduced due to greater dietary caloric density. Furthermore, we provide evidence that expression of the PPARgamma2 gene in porcine adipose tissue is selectively responsive to SO (presumably linoleic acid, 18:2n-6).

Regulation of adipsin and body composition in the monosodium glutamate (MSG)-treated mouse.

Changes in food intake, serum adipsin, and obesity were evaluated in the MSG-treated mouse. In Experiment 1, mice treated with MSG had 50% lower serum adipsin and over 2-fold higher percentage of body fat than the lean controls. Both feeding caffeine and restricting intake normalized serum adipsin and caused weight loss, but did not normalize the percentage of body fat. No additional effect was gained by feeding isoproterenol or ephedrine in combination with caffeine. In Experiment 2, we separated the direct effect of caffeine from the associated depression in intake using a paired feeding design, and also determined the effects of selected adrenergic agents and somatotropin (S). Somatotropin increased weight gain and reduced the percentage of body fat in healthy and obese mice, and tended to lower serum adipsin. Caffeine clearly depressed intake, caused weight loss, and increased serum adipsin, but similar results were achieved by restricting intake. None of the adrenergic drugs tested changed serum adipsin. Ephedrine depressed food intake and caused weight loss, but reduced the percentage of body fat only at the highest dietary concentration (2000 mg per kg of diet). Phenylephrine reduced weight gain without a concomitant effect on the percentage of body fat, and isoproterenol did not influence weight gain or body fat.

Physiological response to acute endotoxemia in swine: effect of genotype on energy metabolites and leptin.

Certain high lean gain swine genotypes have greater sensitivity to pathogen and nonpathogen stressors evident by reduced productivity and increased mortality during disease stress or in suboptimal production environments. Saline (control) and an immunologic challenge (LPS; 25 microg lipopolysaccharide/kg BW) were administered to three genetic populations (each pig used as its own control): high lean (H), moderate lean terminal cross (MT), and moderate lean maternal cross (MM). LPS induced anorexia, and significantly increased body temperature and circulating TNF-alpha, cortisol, and NEFA in all genotypes (P < 0.0004). LPS reduced circulating glucose, insulin, and IGF-1 in all genotypes (P < 0.05). The LPS-induced hypoglycemia was significantly greater in MM versus MT and H pigs (P < 0.03). The hypoinsulinemia was significantly greater in MM versus H pigs (P < 0.02). MM pigs recovered from hypoinsulinemia slower than MT pigs (P < 0.03). Control insulin was higher in H versus MT pigs (P < 0.08), but relative to basal, the insulin response to LPS was similar. Plasma haptoglobin response to LPS was lower for MM versus MT and H pigs (P < 0.02), and tended to be lower in MT versus H pigs (P < 0.09). LPS treatment caused similar decreases in plasma IGF-1 concentrations among genotypes. Ten hours after LPS treatment, leptin mRNA abundance in adipose tissue was significantly reduced (relative to control) in MM and H pigs (P < 0.02) but not in MT pigs (P > 0.05). Physiological differences in leptin, a potent regulator of food intake and energy metabolism, may be important factors in the genetic variation in sensitivity to environmental stress.

Regulation of metabolism and growth during immune challenge: an overview of cytokine function.

Commercially reared food animals encounter serial pathogenic and nonpathogenic immune challenges throughout production. Because of the diversion of nutrients away from growth in support of immune-related processes, immune challenge is considered a major obstacle to animals' achieving their genetic potential for growth or efficiency of gain. Scientists now recognize that many metabolic processes respond directly or indirectly to proinflammatory cytokines. This cytokine-mediated "reprogramming" of metabolism is a homeorhetic mechanism that ensures an adequate supply of nutrients for proliferation of lymphocyte and macrophage populations, antibody production, and hepatic synthesis of acute phase proteins. Proinflammatory cytokines have been linked to altered nutrient uptake and utilization. Anabolic processes are interrupted, and companion catabolic activities are amplified. Furthermore, cytokines may influence prenatal growth and development, and to the extent that postnatal proliferation and differentiation of myogenic and adipogenic cells contribute to postnatal growth, cytokine regulation of these events may ultimately influence growth. The following discussion is an overview of the impact of immune challenge and proinflammatory cytokines on metabolism and growth.

Leptin alters antibody isotype in the pig in vivo, but does not regulate cytokine expression or stimulate STAT3 signaling in peripheral blood monocytes in vitro.

Although leptin modulates immunological pathways in some species, the role of leptin as a regulator of immunocyte function in the pig has not been studied. Therefore, the primary objective of this study was to determine whether leptin influences specific immunocyte response variables in the pig in vivo or in vitro. Fifteen pigs (five pigs per treatment) were 1) injected with recombinant human leptin and allowed to consume feed ad libitum, 2) injected with vehicle and allowed to consume feed ad libitum, or 3) injected with vehicle and limit-fed to the intake of the leptin-injected group. All the pigs also were injected with the antigen, Limulus hemocyanin, on d 0 and 15 of the experiment. Exogenous leptin decreased (P < 0.05) daily feed intake and antigen-specific immunoglobulin (Ig) G1, but had no effect on lymphocyte proliferation or antigen-specific IgG2. In a second series of experiments, peripheral blood mononuclear cells (PBMC) were isolated from venous blood to determine the effect of stimulation with the polyclonal mitogen, concanavalin A (ConA), on the long form of the leptin receptor (Ob-Rl) mRNA abundance, and to determine whether leptin altered mitogen-induced proliferation, cytokine production, or signal transducer and activator of transcription 3 (STAT3) activation. Leptin had no effect on the proliferation of PBMC or on cytokine mRNA abundance or secretion. The abundance of Ob-Rl mRNA was decreased (P < 0.05) in response to stimulation with ConA. Constitutive STAT3 DNA binding was evident in mobility shift assays, but was not altered by either leptin or serum deprivation. These data indicate that leptin modifies antibody isotypes in the pig, and that Ob-Rl expression is downregulated in response to polyclonal mitogens in porcine PBMC. The constitutive activation of STAT3, coupled with the absence of leptin-inducible binding, indicates an alternative signaling pathway for leptin in pig PBMC.

Expression of stress proteins in porcine tissues: developmental changes and effect of immunological challenge.

Immunoblot procedures were used to evaluate stress protein (SP) expression in developing and suckling piglet and in growing pigs challenged immunologically with bacterial lipopolysaccharide (LPS). The constitutively expressed 70-kDa SP (HSC70) and HSP60 were detected in the whole fetus at 30 d of development and in cardiac and skeletal muscle, liver, and lung at 50, 80, and 109 d. Expression of HSP60 was higher (P < or = .03) postnatally in cardiac and skeletal muscle and in lung, whereas HSC70 expression increased (P < or = .01) only in skeletal muscle. The stress-inducible 70-kDa SP (HSP70) was detected in skeletal muscle samples collected 4 d postnatally in two of the four piglets sampled. However, this SP was not detected in samples collected 18 d postnatally. In the LPS challenge study, HSP70 was detected only in liver and intestinal mucosa, and an unidentified protein of approximately 130 kDa was evident in liver and tissue. Expression of HSP70 in liver was not affected by LPS but doubled (P < or = .01) in the jejunal mucosa. Furthermore, although faintly evident in the mucosa of spiral colon of control pigs, HSP70 was clearly increased (P < = .01) in that of challenged pigs. Liver concentrations of the immunoreactive 130-kda protein were not influenced by LPS. The data presented herein indicate that tissue concentration of specific SP change in vivo with development age and that an immunological challenge increases the concentration of specific SP in some tissues.

The affinity of ractopamine, clenbuterol, and L-644,969 for the beta-adrenergic receptor population in porcine adipose tissue and skeletal muscle membrane.

The affinities (Ki) with which ractopamine (RA), clenbuterol (CB), and L-644,969 (L6) bind the beta-adrenoceptor populations of adipose tissue (middle and outer subcutaneous [SQ] layers) and longissimus (LM) and semitendinosus (ST) muscle were determined. Within a given agonist, Ki values (nanomolar) were similar among tissues, except for RA, which had a higher (P < or = .05) affinity (lower Ki) for middle SQ adipose tissue than for outer SQ adipose and both muscles. For all tissues, binding affinities were greatest for CB (126), followed by L6 (350) and RA (856, exclusive of middle SQ adipose). The data indicate that both adipose and muscle tissues are targets of CB, RA, and L6 in vivo, and that tissue preferences of the agonists cannot be established from affinity data alone. The relatively constant affinity of the agonists for the various tissues examined implies that if tissue preferences exist, the efficiency with which postreceptor events are invoked by these agonists is the determining factor.

(-)-[3H]-dihydroalprenolol binding to beta-adrenergic receptors in porcine adipose tissue and skeletal muscle membrane preparations.

We have characterized binding of (-)-[3H]dihydroalprenolol (DHA) to the beta-adrenergic receptor population in membrane from longissimus and semitendinosus muscles and subcutaneous adipose tissue (middle and outer layers) of pigs weighing 100 to 120 kg at slaughter. Linearity of specific binding with increasing membrane protein concentration was confirmed for muscle and adipose tissue. Specific binding was saturable; the beta-receptor population showed a high affinity for the radioligand. Half-maximal binding was achieved at similar concentrations of the tracer (.48 to .73 nM) in all tissues. Maximal binding (B max) per milligram of protein for skeletal muscle was approximately half of that for adipose tissue (P < or = .05) and was greater (P < or = .05) in membrane from the middle than in membrane from the outer layer of adipose tissue. Adipocyte membrane preparations yielded Kd estimates similar to those obtained with adipose tissue, but Bmax values were greater (P < or = .05). Kinetic rate constants were estimated and used to calculate the Kd for comparison to that derived from nonlinear regression analysis of Scatchard plots. Association (k1) and dissociation (k2) estimates were similar between tissues and the resulting Kd values were comparable to those derived from equilibrium data. Stereospecificity of binding was verified using the (-) and (+) isomers of the beta-adrenergic agonist isoproterenol; selectivity for the (-) form ranged from 8- to 19-fold. Overall, the most notable differences among tissues were in receptor density expressed per milligram of protein. Kinetic rate constants, Kd estimates, and the degree of selectivity for (-)-isoproterenol were similar.

Beta-adrenergic receptor subtypes that mediate ractopamine stimulation of lipolysis.

Ractopamine HCl is an beta-adrenergic receptor (betaAR) ligand that was recently approved for use in swine to enhance carcass leanness. The RR stereoisomer of ractopamine is the most active of the four stereoisomers exhibiting the highest affinity and signaling response. The RR isomer exhibits selective activation of the porcine beta2AR, which might limit the lipolytic response to ractopamine because the betaAR is the predominant subtype in swine adipocytes and may mediate most of the lipolytic response. Therefore, we determined the betaAR subtypes that mediate the lipolytic response to ractopamine in swine adipocytes. In order to confirm the predominant role of the beta1AR in porcine adipocytes, isoproterenol-stimulated lipolysis was inhibited by increasing doses of subtype-selective antagonists. Inhibition curves were biphasic using beta1AR antagonists (CGP 20712A and bisoprolol) and curve analysis indicated that both beta1AR an beta2AR contributed to lipolysis with 50 to 60% of the response coming from the beta1AR. Inhibition with the beta2AR antagonist clenbuterol revealed only one class of betaAR that closely approximated the kinetics of the beta1AR. When the RR isomer of ractopamine was the lipolytic agent, similar results to isoproterenol were observed, except that the estimated contribution of the beta1AR was 38%. That beta2AR antagonists did not detect a contribution of the beta2AR to lipolysis may indicate that the beta1AR masked the response to the beta2AR. Dose titration with the RR isomer in the presence of a saturating concentration of beta1AR or beta2AR antagonists indicated that each subtype was present in sufficient quantities to stimulate lipolysis near maximally. Data indicate that both the beta1AR and beta2AR are functionally linked to lipolysis in swine adipocytes and that ractopamine activates each subtype. The RR isomer of ractopamine stimulated adenosine 3',5'-cyclic phosphate accumulation with equal efficacy to isoproterenol through the cloned porcine beta2AR, but was only 35% as efficacious through the cloned porcine beta1AR. These data confirm the beta2AR selectivity of the RR stereoisomer, but suggest the partial agonism through the beta1AR is sufficient to activate lipolysis through both subtypes in swine adipocytes.

Effect of dietary energy source and immunological challenge on growth performance and immunological variables in growing pigs.

Forty-eight growing pigs (23 kg BW) were assigned to four treatments (n = 12) arranged as a 2 x 2 factorial. Dietary energy source (conventional [CON] vs high-oil corn [HOC]), with or without an immunological challenge (IC) regimen constituted main effects. The IC regimen consisted of injection of endotoxin (E. coli lipopolysaccharide [LPS]) and vaccination for porcine respiratory and reproductive syndrome (PRRS). Growth performance data were collected over a 5-wk period and are presented as prechallenge (d 1 to 14; d 1 was the 1st d of the study), challenge (d 15 to 21), and postchallenge (d 22 to 36) periods, and overall. Overall, the pigs fed HOC consumed less feed (P < .11) and gained more efficiently (P < .03). During the immunological challenge period, ADG was depressed 21% and feed intake 15% (P < .01). The IC resulted in lower (P < .01) serum alpha-1-acid glycoprotein (AGP) concentrations on d 22, and the magnitude of the reduction was greater in the pigs fed the CON diet (energy source x immune challenge, P < .10). Serum AGP concentrations remained lower (P < .08) in challenged pigs on d 36. Immunoreactive prostaglandin concentrations were higher (55%, P < .08) in the pigs fed HOC immediately following the IC period (d 22). The data reported herein indicate that the performance of pigs fed HOC is satisfactory, and that feeding HOC does not compromise growth performance during or after an immunological challenge.

Porcine somatotropin improves growth in finishing pigs without altering calpain 3 (p94) or alpha-actin mRNA abundance and has a differential effect on calpastatin transcription products.

The objective of this study was to determine whether the improvements in growth and efficiency of gain achieved by recombinant porcine somatotropin (pST) are associated with altered expression of the p94, calpastatin, or alpha-actin genes in porcine longissimus (LD) muscle. Forty-eight barrows (initial 64.2 to 67.4 kg BW) were assigned to four treatments (n = 12) arranged as a 2 x 2 factorial in a randomized complete block design. Factors were duration of treatment (3 or 6 wk) and pST administration (0 or 3 mg x pig(-1) x d(-1)). Plasma samples were obtained 24 h after the first pST injection and at the end of the each treatment period for assays of selected variables. The LD samples were obtained at 3 and 6 wk of pST treatment. Northern blot analysis of calpastatin expression in LD muscle revealed three distinct transcription products of approximately 8.5 (CPST I), 5.5 (CPST II), and 2.5 (CPST III) kb; CPST II was reduced (P < .02) 33 and 61% by pST at 3 and 6 wk, respectively, whereas CPST I and III were not influenced (P > .12). Neither alpha-actin nor p94 was responsive to pST injection. As expected, pST resulted in higher (50%, P < .02) plasma insulin within 24 h and one- and twofold higher (P < .01) concentrations at 3 and 6 wk, respectively. Glucose was increased (P < .01) at 3 (15%) and 6 (10%) wk, whereas urea nitrogen was reduced (32 to 36%, P < .01). The efficacy of pST was evident in that ADG was improved (P < .01) 11 to 13% independent of time. Likewise, feed intake was reduced (P < .01) 10 to 11% and gain: feed improved (P < .01) approximately 26% for pigs receiving pST independent of time. These data indicate that the enhanced muscle growth achieved by pST is not associated with altered expression of p94 or alpha-actin, or an increase in the abundance of any calpastatin transcription product.