Effects of acute hyperinsulinemia on insulin signal transduction and glucose transporters in ovine fetal skeletal muscle.

To test the effects of acute fetal hyperinsulinemia on the pattern and time course of insulin signaling in ovine fetal skeletal muscle, we measured selected signal transduction proteins in the mitogenic, protein synthetic, and metabolic pathways in the skeletal muscle of normally growing fetal sheep in utero. In experiment 1, 4-h hyperinsulinemic-euglycemic clamps were conducted in anesthetized twin fetuses to produce selective fetal hyperinsulinemia-euglycemia in one twin and euinsulinemia-euglycemia in the other. Serial skeletal muscle biopsies were taken from each fetus during the clamp and assayed by Western blot for selected insulin signal transduction proteins. Tyrosine phosphorylation of the insulin receptor, insulin receptor substrate-1, and the p85 subunit of phosphatidylinositol 3-kinase doubled at 30 min and gradually returned to control values by 240 min. Phosphorylation of extracellular signal-regulated kinase 1,2 was increased fivefold through 120 min of insulin infusion and decreased to control concentration by 240 min. Protein kinase B phosphorylation doubled at 30 min and remained elevated throughout the study. Phosphorylation of p70 S6K increased fourfold at 30, 60, and 120 min. In the second experiment, a separate group of nonanesthetized singleton fetuses was clamped to intermediate and high hyperinsulinemic-euglycemic conditions for 1 h. GLUT4 increased fourfold in the plasma membrane at 1 h, and hindlimb glucose uptake increased significantly at the higher insulin concentration. These data demonstrate that an acute increase in fetal plasma insulin concentration stimulates a unique pattern of insulin signal transduction proteins in intact skeletal muscle, thereby increasing pathways for mRNA translation, glucose transport, and cell growth.

Insulin-induced translocation of facilitative glucose transporters in fetal/neonatal rat skeletal muscle.

We examined the effect of insulin on fetal/neonatal rat skeletal muscle GLUT-1 and GLUT-4 concentrations and subcellular distribution by employing immunohistochemical analysis and subcellular fractionation followed by Western blot analysis. We observed that insulin did not alter total GLUT-1 or GLUT-4 concentrations or the GLUT-1 subcellular distribution in fetal/neonatal or adult skeletal muscle in 60 min. The basal and insulin-induced changes in subcellular distribution of GLUT-4 were different between the fetal/neonatal and adult skeletal muscle. Under basal conditions, sarcolemma-associated GLUT-4 was higher in the newborn compared with the adult, translating into a higher glucose transport. In contrast, insulin-induced translocation of GLUT-4 to the sarcolemma- and insulin-induced glucose transport was lower in the newborn compared with the adult. This age-related change results in enhanced basal glucose transport to fuel myocytic proliferation and differentiation while relatively curbing the insulin-dependent glucose transport in the newborn.

Aberrant insulin-induced GLUT4 translocation predicts glucose intolerance in the offspring of a diabetic mother.

We examined the long-term effect of in utero exposure to streptozotocin-induced maternal diabetes on the progeny that postnatally received either ad libitum access to milk by being fed by control mothers (CM/DP) or were subjected to relative nutrient restriction by being fed by diabetic mothers (DM/DP) compared with the control progeny fed by control mothers (CM/CP). There was increased food intake, glucose intolerance, and obesity in the CM/DP group and diminished food intake, glucose tolerance, and postnatal growth restriction in the DM/DP group, persisting in the adult. These changes were associated with aberrations in hormonal and metabolic profiles and alterations in hypothalamic neuropeptide Y concentrations. By use of subfractionation and Western blot analysis techniques, the CM/DP group demonstrated a higher skeletal muscle sarcolemma-associated (days 1 and 60) and white adipose tissue plasma membrane-associated (day 60) GLUT4 in the basal state with a lack of insulin-induced translocation. The DM/DP group demonstrated a partial amelioration of this change observed in the CM/DP group. We conclude that the offspring of a diabetic mother with ad libitum postnatal nutrition demonstrates increased food intake and resistance to insulin-induced translocation of GLUT4 in skeletal muscle and white adipose tissue. This in turn leads to glucose intolerance and obesity at a later stage (day 180). Postnatal nutrient restriction results in reversal of this adult phenotype, thereby explaining the phenotypic heterogeneity that exists in this population.

Characterization of an oligopeptide transporter in renal lysosomes.

Renal lysosomes play a major role in catabolism of plasma proteins. Final products of this catabolism include dipeptides and tripeptides that must be exported to the cytosol for hydrolysis. The aim of the present study was to determine whether an oligopeptide transporter is present in the renal lysosomal membrane that could mediate this export. The existence of an oligopeptide transporter was probed with the uptake of glycylglutamine (Gly-Gln) by membrane vesicles prepared from renal lysosomes. Kinetic analysis showed the presence of a single transporter with a K(m) of 8.77 mM for the uptake of Gly-Gln. The Gly-Gln uptake was energized by the imposition of an inwardly directed proton gradient (pH(out) 5.0/pH(in) 7.3) and membrane potential (outside positive/inside negative) resulting in overshoot. The Gly-Gln uptake was inhibited by the presence of dipeptides and tripeptides, but not amino acids. Western blot analysis of lysosomal membrane proteins with Pept-1 (an oligopeptide transporter) antibody as the probe showed the presence of an immunoreactive protein. This immunoreaction was abolished when the antiserum was preabsorbed with the Pept-1 epitope (0.5 microg/ml). In conclusion, the present data show the existence of a low-affinity dipeptide transporter in the renal lysosomal membrane that appears to belong to the Pept family of transporters. The function of this transporter appears to be to prevent accumulation of dipeptides in renal lysosomes.

Inverse alterations of BCKA dehydrogenase activity in cardiac and skeletal muscles of diabetic rats.

Rat cardiac and skeletal muscles, which have been used as model tissues for studies of regulation of branched-chain alpha-keto acid (BCKA) oxidation, vary greatly in the activity state of their BCKA dehydrogenase. In the present experiment, we have investigated whether they also vary in response of their BCKA dehydrogenase to a metabolic alteration such as diabetes and, if so, to investigate the mechanism that underlies the difference. Diabetes was produced by depriving streptozotocin-treated rats of insulin administration for 96 h. The investigation of BCKA dehydrogenase in the skeletal muscle (gastrocnemius) showed that diabetes 1) increased its activity, 2) increased the protein and gene expressions of all of its subunits (E(1)alpha, E(1)beta, E(2)), 3) increased its activity state, 4) decreased the rate of its inactivation, and 5) decreased the protein expression of its associated kinase (BCKAD kinase) without affecting its gene expression. In sharp contrast, the investigation of BCKA dehydrogenase in the cardiac muscle showed that diabetes 1) decreased its activity, 2) had no effect on either protein or gene expression of any of its subunits, 3) decreased its activity state, 4) increased its rate of inactivation, and 5) increased both the protein and gene expressions of its associated kinase. In conclusion, our data suggest that, in diabetes, the protein expression of BCKAD kinase is downregulated posttranscriptionally in the skeletal muscle, whereas it is upregulated pretranslationally in the cardiac muscle, causing inverse alterations of BCKA dehydrogenase activity in these muscles.

Functional and molecular expression of intestinal oligopeptide transporter (Pept-1) after a brief fast.

The intestinal oligopeptide transporter, cloned as Pept-1, has major roles in the assimilation of dietary proteins and absorption of peptidomimetic medications. The initial aim of the present experiment was to investigate whether the functional expression of this transporter is affected by dietary intake. Functional expression was determined as the rate of uptake of glycylglutamine (Gly-Gln) by brush-border membrane vesicles (BBMVs) prepared from the jejunum of fed and fasted rats. Surprisingly, the rate of dipeptide uptake was greatly increased after 1 day of fasting. The subsequent aim of the experiment became the investigation of the mechanism of this alteration in transport, which showed that 1 day of fasting increased (1) the maximal Gly-Gln uptake (Vmax) by twofold without changing the Km of Gly-Gln uptake by BBMVs, (2) the amount of intestinal oligopeptide transporter (Pept-1) protein by threefold in the brush-border membrane, and (3) the abundance of Pept-1 mRNA by threefold in the intestinal mucosa. We conclude that 1 day of fasting increases dipeptide transport in rat intestine by increasing the population of Pept-1 in the brush-border membrane. The mechanism appears to be an increase in Pept-1 gene expression.

Hormonal regulation of oligopeptide transporter pept-1 in a human intestinal cell line.

The intestinal oligopeptide transporter (cloned as Pept-1) has major roles in protein nutrition and drug therapy. A key unstudied question is whether expression of Pept-1 is hormonally regulated. In this experiment, we investigated whether insulin has such a role. We used a human intestinal cell monolayer (Caco-2) as the in vitro model of human small intestine and glycylglutamine (Gly-Gln) as the model substrate for Pept-1. Results showed that addition of insulin at a physiological concentration (5 nM) to incubation medium greatly stimulates Gly-Gln uptake by Caco-2 cells. This stimulation was blocked when genistein, an inhibitor of tyrosine kinase, was added to incubation medium. Studies of the mechanism of insulin stimulation showed the following. 1) Stimulation occurred promptly (30-60 min) after exposure to insulin. 2) There was no significant change in the Michaelis-Menten constant of Gly-Gln transport, but there was a nearly twofold increase in its maximal velocity. 3) Insulin effect persisted even when Golgi apparatus, which is involved in trafficking of newly synthesized Pept-1, was dismantled. 4) However, there was complete elimination of insulin effect by disruption of microtubules involved in trafficking of preformed Pept-1. 5) Finally, with insulin treatment, there was no change in Pept-1 gene expression, but the amount of Pept-1 protein in the apical membrane was increased. In conclusion, the results show that insulin, when it binds to its receptor, stimulates Gly-Gln uptake by Caco-2 cells by increasing the membrane population of Pept-1. The mechanism appears to be increased translocation of this transporter from a preformed cytoplasmic pool.

Mechanism of dipeptide stimulation of its own transport in a human intestinal cell line.

The initial objective of this study was to investigate whether the presence of dipeptide in the culture medium stimulates the uptake of dipeptide by a human intestinal cell line that expresses the oligopeptide transporter (Pept-1). The results showed that addition of glycylsarcosine (Gly-Sar) for 24 hr to the culture medium significantly increased the rate of glycylglutamine (Gly-Gln) uptake by Caco-2 cells. Furthermore, this stimulation in transport was also observed when Cefadroxil (beta-lactam antibiotic) instead of Gly-Gln was used as a probe but did not occur when Gly-Sar was added to the culture medium for only 2 hr or when Gly-Sar was substituted by a corresponding mixture of glycine plus sarcosine. The subsequent objective of the study was to investigate the mechanism of stimulation in transport described earlier. The results showed that the addition of Gly-Sar for 24 hr to the culture medium: (1) increased the Vmax of Gly-Gln transport by two-fold without affecting its Km, (2) increased the protein mass of Pept-1 by more than two-fold, (3) increased the abundance of Pept-1 mRNA by three-fold, and (4) had no effect on Gly-Gln transport when an inhibitor of trans-Golgi network (brefeldin) was added to the culture medium, but still increased the abundance of Pept-1 mRNA. In conclusion, the results show that dipeptides stimulate their own transport by increasing the membrane population of Pept-1. The molecular mechanism appears to be an increase in expression of the gene encoding Pept-1. A therapeutic application of the present results is that if bioavailability of orally administered peptidomimetic drugs is limited, patients may be tried on a high-protein diet to enhance their absorption.

Posttranscriptional alterations in protein masses of hepatic branched-chain keto acid dehydrogenase and its associated kinase in diabetes.

The key enzyme regulating oxidation of branched-chain keto acids (BCKAs) is BCKA dehydrogenase (BCKAD). We have previously shown that an increase in the activity of this enzyme accounts for the increased oxidation of leucine in the liver of diabetic rats. In the present experiment, we have investigated the mechanisms responsible for this increase in enzyme activity. These studies were performed 96 hours after the withdrawal of insulin therapy in rats made diabetic by an injection of streptozotocin. Diabetes increased the activity state (83% versus 97%, p < .01) as well as the total activity (78 versus 112 nmol/min/mg protein, p < .01) of BCKAD. The increase in the activity state was due to a 60% fall in the BCKAD kinase activity, which was the result of a 50% decrease in its protein mass. A coordinated increase (50%-70%) in protein mass of each BCKAD subunit (E1 alpha, E1 beta, and E2) accounted for the increase in the total activity of BCKAD. We conclude that diabetes increases the hepatic BCKAD activity by increasing its protein mass and also by decreasing that of its associated kinase. These alterations appear to occur posttranscriptionally, since diabetes had no effect on the gene expressions of BCKAD subunits (E1 alpha, E1 beta, and E2) or BCKAD kinase.

An active mechanism for completion of the final stage of protein degradation in the liver, lysosomal transport of dipeptides.

Accumulation of products of proteolysis (e.g. dipeptides) in lysosomes may have pathological consequences. In the present experiment we have investigated the existence of a dipeptide transporter in a membrane preparation of liver lysosomes using Gly-3H-Gln as the probe. The results showed that (a) there was transport of Gly-Gln into an osmotically reactive space inside the lysosomal membrane vesicles; (b) transport was stimulated by acidification (pH 5.0) of the external medium; (c) there was a coupling between transport of protons and Gly-Gln with a stoichiometry of 1:1; (d) the presence of both acidic pH and membrane potential was necessary for uphill transport of Gly-Gln; (e) a single transporter with a Km of 4.67 mM mediated the uptake of Gly-Gln; and (f) Gly-Gln uptake was inhibited by dipeptides and tripeptides but not by amino acids. The results suggest the presence of a low affinity proton-coupled oligopeptide transporter in the liver lysosomal membrane which mediates transfer of dipeptides from a region of low dipeptidase activity (intralysosome) to a region of high dipeptidase activity (cytosol). In this manner, the transporter provides an active mechanism for completion of the final stage of protein degradation.

H(+)-glycyl-L-proline cotransport in brush-border membrane vesicles of eel (Anguilla anguilla) intestine.

A plasma membrane H(+)-glycyl-L-proline (Gly-L-Pro) cotransport mechanism has been identified in isolated eel intestinal brush-border membrane vesicles (BBMV) by both measuring radiolabeled Gly-L-Pro uptake and monitoring Gly-L-Pro-dependent H+ influx with the pH-sensitive dye acridine orange. The application of an inside negative membrane potential resulted in increasing Gly-L-Pro uptake, as well as the application of inwardly directed H+ gradient (although only when an inside negative membrane potential was present). Furthermore, vesicular H+ influx was found specifically associated with the presence of Gly-L-Pro in the extravesicular medium. The carrier-mediated nature of H(+)-Gly-L-Pro cotransport was assessed, and its concentration that yielded one-half maximal Gly-L-Pro influx was approximately 1.30 mM when measured by either radioactive or fluorescent tracers. Different dipeptides strongly inhibited Gly-L-Pro uptake by eel intestinal BBMV, as well as the cephalosporin antibiotic cephalexin, suggesting that dipeptide molecules and cephalosporin antibiotics may share a common transport system in eel intestinal BBMV.

Electrogenic, proton-coupled, intestinal dipeptide transport in herbivorous and carnivorous teleosts.

In both herbivorous tilapia (Oreochromis mossambicus) and carnivorous rockfish (Sebastes caurinus) intestinal and pyloric cecal brush-border membrane vesicles (BBMV), [14C]glycylsarcosine ([14C]Gly-Sar) uptake was stimulated by a transmembrane proton gradient. A transmembrane K(+)-diffusion potential (inside negative) stimulated [14C]Gly-Sar uptake above that observed with short-circuited vesicles, whereas an inwardly directed Na+ gradient in both fishes had no effect on peptide uptake. In tilapia, [14C]Gly-Sar influx occurred by the combination of 1) a high-affinity, saturable, proton gradient-dependent carrier system [Kt [concentration that equals one-half of maximum influx (Jmax)] = 0.56 +/- 0.08 mM; Jmax = 1,945.0 +/- 174.6 pmol.mg protein-1.10 s-1]; 2) a low-affinity, nonsaturable (within 1-10 mM), proton gradient-dependent carrier system (nonsaturable carrier-mediated transport component = 4,514.0 +/- 28.1 pmol.mg protein-1.10 s-1.mM-1); and 3) a diffusional component accounting for < 10% of total influx within the concentration range tested. Influx (10 s) of 1-10 mM [14C]Gly-Sar in tilapia intestine was significantly (P < 0.01) inhibited by 10 mM diethylpyrocarbonate, a specific inhibitor of proton-coupled peptide transport systems. [14C]Gly-Sar influx into tilapia BBMV showed cis-inhibition and trans-stimulation by Gly-Pro, suggesting that [14C]Gly-Sar and Gly-Pro shared the same mucosal peptide transporter in fish. These observations strongly suggest that intestinal transport of peptides in herbivorous and carnivorous fishes is proton gradient dependent, electrogenic, sodium independent, and qualitatively resembles the peptide transport paradigm proposed for mammals.

Basolateral dipeptide transport by the intestine of the teleost Oreochromis mossambicus.

Transport characteristics of [14C]glycylsarcosine ([14C]Gly-Sar) were measured in herbivorous tilapi (Oreochromis mossambicus) intestinal basolateral membrane vesicles (BLMV) purified with Percoll gradient centrifugation. Specific activity of the vesicle Na(+)-K(+)-adenosinetriphos- phatase was increased 12-fold, whereas specific activity of the brush-border enzyme alkaline phosphatase was enriched only by 0.8-fold. [14C]Gly-Sar uptake was stimulated by increasing concentrations of extravesicular protons rather than by a transmembrane proton gradient. A transmembrane K+ diffusion potential (inside negative) did not stimulate [14C]Gly-Sar uptake above that observed with short-circuited vesicles. An inwardly directed Na+ gradient had no effect on peptide uptake. Kinetic analysis of basolateral transport rate revealed that the transport occurred by a saturable process conforming to Michaelis-Menten kinetics [Kt [concentration of [14C]Gly-Sar that yielded one-half of maximal influx (Jmax)] = 13.27 +/- 3.80 mM, Jmax = 15,155 +/- 3,096 pmol.mg protein-1.6 s-1]. The basolateral transporter was insensitive to diethylpyrocarbonate (DEP), a specific inhibitor of proton-coupled peptide transport systems. [14C]Gly-Sar influx into tilapia BLMV showed cis-inhibition by several other dipeptides, suggesting that the [14C]Gly-Sar transporter was shared by other peptides too. These observations strongly suggest that the basolateral intestinal dipeptide transporter in herbivorous fishes is distinctly different from either the high- or low-affinity brush-border transporter. It is proton dependent, electroneutral, sodium independent and accepts a wide variety of dipeptides.

Dipeptide transport by crustacean hepatopancreatic brush-border membrane vesicles

Epithelial brush-border membrane vesicles (BBMVs) of lobster (Homarus americanus) hepatopancreas were formed by a Mg2+ precipitation technique. In these BBMVs, [14C]glycylsarcosine ([14C]Gly-Sar) uptake was stimulated by a transmembrane proton gradient. transmembrane K+ diffusion potential (inside negative) stimulated [14C]Gly-Sar uptake above that observed with short-circuited vesicles, while an inwardly directed Na+ gradient had no stimulatory effect on peptide uptake. [14C]Gly-Sar influx (over 10 s) occurred by a low-affinity, saturable, proton-gradient-dependent carrier system (Kt=5.90±0.13 mmol l-1, Jmax=4662±487 pmol mg-1 protein 10 s-1; mean ± s.e.m., N=3). This carrier exhibited a high-affinity proton binding site (KH=235±25 nmol l-1; pK=6.6) and an apparent 1H+:1Gly-Sar transport stoichiometry. Influx of 0.1 mmol l-1 [14C]Gly-Sar into lobster hepatopancreatic BBMVs was significantly (P<0.01) cis-inhibited by 10 mmol l-1 diethylpyrocarbonate and by a variety of other dipeptides (10 mmol l-1), suggesting a broad transport specificity. These observations strongly suggest that transport of peptides into crustacean hepatopancreas is proton-gradient-dependent and electrogenic, qualitatively resembling the peptide transport paradigm proposed for fish and mammals.

Invertebrate gut diverticula are nutrient absorptive organs.

Physiological mechanisms of gastrointestinal absorption and secretion of organic and inorganic solutes among invertebrates remain severely underinvestigated. In this review we briefly discuss some of the physical and biological forces affecting solute transfer across epithelial cells and membranes of vertebrate and invertebrate guts. Next, we present some features of the described processes for sugar and amino acid transport in the tubular portion of gastrointestinal tracts of three major invertebrate groups: echinoderms, molluscs, and arthropods. A detailed discussion follows of recent nutrient transport studies using purified epithelial brush-border membrane vesicles of two invertebrate gut diverticula, the crustacean hepatopancreas and the starfish pyloric cecum. Lastly, transepithelial nutrient and ion transport studies of crustacean hepatopancreatic epithelial cell monolayers, grown in primary culture and mounted in flux chambers, are used to demonstrate the nature of absorption and secretion of solutes by this organ and to show the general applicability of these methods to structurally complex invertebrate organs.

Oviductal vein resection affects pregnancy rates in sheep.

Progesterone is delivered locally via the oviductal vein to the cranial uterine horn ipsilateral to the ovary bearing the corpus luteum. Removal of the oviductal vein reduces this local delivery of progesterone. The objective of this experiment was to determine if local delivery of progesterone via the oviductal vein is necessary for embryo survival. Twenty-five nulliparous ewes were bred at estrus to fertile rams. On day 4 following breeding, ewes were randomly assigned to one of two treatment groups: oviductal vein resection (n = 11) or sham operated controls (n = 14). Following midventral laparotomy, the oviductal vein was isolated, ligated and removed. In the sham surgery control ewes, the oviductal vein was isolated, sutures were placed around the vein but were left unsecured. Following surgery, ewes were returned to the flock. Jugular venous blood samples were collected daily for 25 days after surgery and every third day until day 68 post breeding. On day 85 post breeding, ewes were laparotomized again to confirm pregnancy and location of the fetus. Blood samples were analyzed for progesterone via radioimmunoassay. The proportion of ewes pregnant in the oviductal vein resected groups were greater (p less than or equal to .08) than in the control, sham surgery group. Transuterine migration of embryos occurred in 2/4 pregnant, sham operated control ewes whereas migration occurred in 0/8 of the pregnant, oviductal vein resected ewes. Patterns of progesterone secretion differed (p less than or equal to .001) between pregnant and nonpregnant ewes across the entire sampling period. During maternal recognition of pregnancy, days 13 to 21 after breeding, overall mean jugular venous concentrations of progesterone were lower (p less than or equal to .05) in the oviductal vein resected ewes and patterns of secretion tended to differ (p less than or equal to .09) between oviductal vein resected and sham operated control ewes. It is concluded that oviductal vein resection increases pregnancy rates in nulliparous ewes and this may be due to a reduction in the local delivery of an inhibitor of embryo survival, possibly progesterone, or by maintaining the appropriate uterine environment conducive to a successful pregnancy.