In vitro metabolic stability of iodinated obestatin peptides

Different iodinated mouse obestatin peptides have been characterized toward their in vitro stability in the main metabolic compartments plasma, liver and kidney. Using HPLC-UV for quantification, significant differences in the degradation kinetics of the iodinated peptides, arising from both enzymatic proteolysis and dehalogenation, were found when compared to the native, unmodified peptide. HPLC-MS/MS analysis demonstrated that the cleavage sites were dependent upon the biological matrix and the location of the amino acid residue incorporating the iodine atom(s). The degrading proteases were found to target peptide bonds further away from the iodine incorporation, while proteolytic cleavages of nearby peptide bonds were more limited. Diiodinated amino acid residue containing peptides were found to be more susceptible to deiodination than the mono-iodinated derivative. In plasma, the percentage of peptide degradation solely attributed to deiodinase activity after 20 min incubation reached up to 25% for 2,5-diiodo-H(19)-obestatin compared to 20% and only 3% for (3,5-diiodo-Y(16))- and (3-iodo-Y(16)) obestatin, respectively. Hence, our results demonstrate that the different iodinated peptides pose significantly different metabolization properties and thus, also different biological activities are expected for peptides upon iodination.     

In vitro metabolism of opioid tetrapeptide agonists in various tissues and subcellular fractions from rats

The metabolism of three mu-selective opioid tetrapeptide agonists, Tyr-D-Arg-Phe-Nva-NH(2) (TArPN), Tyr-D-Arg-Phe-Phe-NH(2) (TArPP), and Tyr-D-Ala-Phe-Phe-NH(2) (TAPP), was investigated in different rat tissues. High metabolic activity (<20% peptide remaining after 30 min) was found against the three peptides in the kidney homogenate and against TArPN in spleen homogenate. Low metabolic activity (>80% peptide remaining after 30 min) was found for all peptides in brain homogenate and plasma, and for TArPN and TArPP in blood. The other tissue homogenates, prepared from the small and large intestine, liver and lung, all exhibited intermediate metabolic activity (20-80% peptide remaining after 30 min) against the peptides. In all tissues investigated, the tetrapeptides were metabolized at the C-terminal amide by deamidation.A further in depth metabolic investigation was performed in subcellular fractions isolated from three tissues (small intestine, liver and kidney). In the liver, the deamidation was predominantly localized to the mitochondrial/lysosomal fraction, while hydrolysis at the N-terminal Tyr residue was the major metabolic pathway in the microsomal/brush-border membrane fraction from the kidney and small intestine.     

Metabolic stability of long-acting luteinizing hormone-releasing hormone antagonists

Long-acting luteinizing hormone-releasing hormone (LHRH) antagonists designed to be protease resistant consisted of a series of novel decapeptides structurally similar to LHRH. The aim of this study was to evaluate the in vitro metabolic stability of the LHRH decapeptides using pancreatin and homogenates models and identify the metabolites in rat liver homogenate for the purpose of illustrating the metabolic features of the decapeptides. The major metabolites in rat liver homogenate were identified by LC-ESI-MS(n). The half-lives of the 11 LHRH decapeptides were from 44 to 330?min in the pancreatin model. The half-lives of the five decapeptides in rat liver, kidney and lung homogenates were between 8 and 462?min. The most stable decapeptides were the LY616 and LY608 peptides with half-lives of 36?min in liver homogenate. Two major cleavage sites were found by analysing the metabolites of the LY618 peptide in rat liver homogenate, between the Pal(3)-Ser(4) and the Leu(7)-Ilys(8) peptide bonds. The major metabolites were produced via cleavages of peptide bonds at these sites, and further metabolic reactions such as hydroxylation, oxidative dechlorination, alcohol dehydration and isopropyl dealkylation were also observed.     

Differential BBB interactions of three ingestive peptides: obestatin, ghrelin, and adiponectin

Endogenous compounds, including ingestive peptides, can interact with the blood-brain barrier (BBB) in different ways. Here we used in vivo and in vitro techniques to examine the BBB permeation of the newly described satiety peptide obestatin. The fate of obestatin in blood and at the BBB was contrasted with that of adiponectin. By the sensitive multiple time-regression method, obestatin appeared to have an extremely fast influx rate to the brain whereas adiponectin did not cross the BBB. HPLC analysis, however, showed the obestatin result to be spurious, reflecting rapid degradation. Absence of BBB permeation by obestatin and adiponectin was in contrast to the saturable transport of human ghrelin reported previously. As a positive control, ghrelin showed saturable binding and endocytosis in RBE4 cerebral microvessel endothelial cells. By comparison, obestatin lacked specific binding and endocytosis, and the small amount internalized showed rapid intracellular degradation before the radioactivity was released by exocytosis. The differential interactions of obestatin, adiponectin, and ghrelin with the BBB illustrate their distinctive physiological interactions with the CNS.     

Metabolic stability of human parathyroid hormone peptide hPTH (1–34) in rat tissue homogenates: kinetics and products of proteolytic degradation

The present study aim to investigate the metabolic stability and degradation of cleavage sites of human parathyroid hormone peptide, hPTH (1–34), in rat tissue homogenate, and to identify the types of proteases involved in hPTH (1–34) processing degradation. The stability of hPTH (1–34) in rat kidney, lung and liver homogenates was evaluated by LC–ESI–MS, and the structures of the major degradation products were identified by MALDI–TOF MS and LC–ESI–MS/MS. The ability of protease inhibitors to inhibit hPTH (1–34) degradation was used to identify the class of proteases involved in the metabolism of hPTH (1–34). hPTH (1–34) peptide was readily degraded in rat kidney, liver, and lung homogenates, with half-lives of 5.7, 32.2, and 18.9 min, respectively. The degradation of hPTH (1–34) in each tissue can be inhibited by inhibitors of serine and metalloproteases. The major degradation products of hPTH (1–34) are similar in each tissue and suggest that hPTH (1–15) and hPTH (16–34) appear as the major degradation products. The degradation patterns of hPTH (1–34) incubated in rat kidney, liver and lung homogenates are largely overlapping, and a majority of the fragments are generated via cleavages at sites of Leu15–Asn16 peptide bond.     

Obestatin and ghrelin in obese and in pregnant women

We identified, through qPCR, receptor mRNA for a number of gut peptides in female human omental fat: the incretins, GIP and GLP-1, the orexigenic peptides PYY-Y1 and -Y2 and ghrelin, and the anorexigenic peptide obestatin. Four cohorts of women were examined: lean controls (BMI<23), obese (BMI>41), obese diabetic and term pregnant women. Human fat expressed receptor mRNAs for all six peptides. Pregnant women expressed roughly three times as much orphan GPR-39 receptor, a proposed obestatin receptor, than other women and less than half as much of the ghrelin receptor (GHSR-1a). An immunoblot probed with a GPR-39 selective antibody yielded a single band corresponding to the correct molecular weight (52 kDa) for the proposed obestatin receptor. Fluorescent immunohistochemistry of human fat employing the same antibody indicated the receptor protein was localized to the adipocyte cell membrane. The concentration of obestatin circulating in blood was measured in the same cohort of women and was significantly lower in obese and obese diabetic women compared to control.     

Obestatin is present in saliva: alterations in obestatin and ghrelin levels of saliva and serum in ischemic heart disease

Ghrelin and obestatin are a single gene products and are a multiple functional peptides that regulates energy homeostasis, and food intake. In the present work, we studied the secretion of ghrelin and its co-secreted peptide obestatin in 44 patients with ischemic heart disease with that of 27 healthy matched controls. Here we first conducted using an immunohistochemistry assay to screen whether human salivary glands have any obestatin immunoreactivity. Then, serum and saliva obestatin and acylated ghrelin levels were determined by using Radioimmunoassay. Our immunohistochemical analysis demonstrated that obestatin was localized in the striated and excretory duct of human salivary gland. We also report for the first time that obestatin, like ghrelin, is present in human salivary gland and saliva. No evidence of the role of obestatin or ghrelin saliva levels in the context of ischemic heart disease was found. Salivary ghrelin and obestatin levels are correlated in controls with the blood levels. Determination of salivary values could represent a non-invasive alternative to serum ones that can be useful in clinical practice.     

Distribution of obestatin and ghrelin in human tissues: immunoreactive cells in the gastrointestinal tract, pancreas, and mammary glands.

Obestatin and ghrelin are two peptides derived from the same prohormone. It is well established that ghrelin is produced by endocrine cells in the gastric mucosa. However, the distribution of human obestatin immunoreactive cells is not thoroughly characterized. A polyclonal antibody that specifically recognizes human obestatin was produced. Using this antibody and a commercial antibody vs ghrelin, the distribution of obestatin and ghrelin immunoreactive cells was determined in a panel of human tissues using immunohistochemistry. The two peptides were detected in the mucosa of the gastrointestinal tract, from cardia to ileum, and in the pancreatic islets. Interestingly, epithelial cells in the ducts of mammary glands showed distinct immunoreactivity for both ghrelin and obestatin. By double immunofluorescence microscopy, it was shown that all detected cells were immunoreactive for both peptides. Furthermore, the subcellular localization of obestatin and ghrelin was essentially identical, indicating that obestatin and ghrelin are stored in the same secretory vesicles.     

A comparison of aroclor 1254-induced and uninduced rat liver microsomes to human liver microsomes in phenytoin O-deethylation, coumarin 7-hydroxylation, tolbutamide 4-hydroxylation, S-mephenytoin 4'-hydroxylation, chloroxazone 6-hydroxylation and testosterone 6beta-hydroxylation

Aroclor 1254-induced rat liver homogenate supernatant (liver S-9) is routinely used as an exogenous metabolic activation system for the evaluation of mutagenicity of xenobiotics. The purpose of this study is to evaluate whether results obtained with Aroclor 1254-induced liver microsomes would be relevant to human. Aroclor 1254-induced and uninduced rat liver microsomes were compared to human liver microsomes in the metabolism of substrates which are known to be selectively metabolized by the major human cytochrome P450 (CYP) isoforms. The activities studied and the major CYP isoforms involved were as follows: phenacetin O-deethylation (CYP1A2); coumarin 7-hydroxylation, (CYP2A6); tolbutamide 4-hydroxylation (CYP2C9), S-mephenytoin 4'-hydroxylation (CYP2C19); dextromethorphan O-demethylation (CYP2D6); chloroxazone 6-hydroxylation (CYP2E1); and testosterone 6beta-hydroxylation (CYP3A4). We found that both induced and uninduced rat liver microsomes were active in all the pathways studied with the exception of coumarin 7-hydroxylation. Coumarin 7-hydroxylation was observed with human liver microsomes but not the rat liver microsomes. Aroclor-1254 was found to induce all activities measured, with the exception of coumarin 7-hydroxylation. Dextromethorphan O-deethylation activity was higher in the rat liver microsomes than the human liver microsomes. Testosterone 6beta-hydroxylation activity was found to be similar between the human liver microsomes and the induced rat liver microsomes. Our results suggest that experimental data obtained with Aroclor 1254-induced rat liver microsomes may not always be relevant to human.     

Brain processing of hemorphin-7 peptides in various subcellular fractions from rats

Hemorphins are multifunctional peptides derived from hemoglobin or blood processing. They have been found at high levels within the central nervous system where they have a direct effect on neuronal cells via peptidergic receptors. As relatively few studies have examined their metabolic stability in the brain, such investigation was performed to locate the cellular distribution of enzymatic activity against these peptides. High-performance liquid chromatography (HPLC) combined with electrospray ionisation mass spectrometry (ESI-MS) allows identification of degradation products resulting from incubation of hemorphin-7 peptides (LVV-hemorphin-7, VV-hemorphin-7 and hemorphin-7) with subcellular fractions isolated from rat brain tissue. Metabolic activities were found against the three peptides in brain homogenate and subcellular fractions with the highest metabolic activity (<3% peptide remaining after 10 min) observed in the microsomal fraction which processed hemorphin-7 peptides mainly into N-terminal fragments (giving LVVH5) suggesting action of brain-membrane enzymes with C-terminal specificity. Incubation of the ACE inhibitor captopril (0.2 μM) with microsomal fraction, together with LVVH7, decreased the processing of LVVH7 to form LVVH5 by 85%.     

Fragment analogs as better mimics of obestatin

Obestatin is a twenty three amino acid peptide produced in the stomach by post translational modification of the preproghrelin gene. Since its discovery in 2005, many studies have shown that obestatin reduces feed intake and gain in body weight in rodents. Studies from our laboratory have shown the N-terminal thirteen residues mimic obestatin the best and residues 6–18 reduce epididymal fat significantly in adult male mice. In this study we have tried to increase the efficacy of these fragments. As an initial step, we have substituted G(8) with α-aminoisobutyricacid(Aib,U) and F(5) with cyclohexylalanine(Cha) in the N-terminal peptide to obtain two modified peptides and modified the middle fragment (residues 6–18) by substituting both the glycine residues at position 3 and 8 with α-aminoisobutyricacid(U). The rationale being, unusual amino acids could protect the peptides from immediate degradation and Aib would also induce secondary structure in these unstructured peptides. The N-terminal fragment with the G(8)U substitution fared the best. It reduced food intake, gain in body weight, levels of cholesterol and triglycerides in the blood, epididymal and perirenal fat in adult male mice similar to that of obestatin. The middle fragment with G(3,8)U double substitution was the second best.     

Interaction of human substantia nigra neuromelanin with lipids and peptides

Neuromelanin was isolated from human substantia nigra using different procedures. In the pigment isolated by any of these procedures a peptide component covalently bound to the melanic structure was found, as shown by treatment with reagents known to eliminate noncovalently bound proteins. The amino acid content of such a peptide component was reproducible and corresponded to approximately 15% of the neuromelanin weight. Neuromelanin also showed the ability to absorb specifically lipid molecules, approximately 20% of its weight, and among these lipids cholesterol was identified, constituting approximately 5% of the total lipid mixture. A synthetic melanin, incubated with putamen homogenate, bound tissue peptides with an amino acid content quite close to that of neuromelanin. The same synthetic melanin adsorbed a lower amount of lipids from the putamen homogenate compared with neuromelanin. The sulfur content of neuromelanin was also reproducible even using different isolation procedures. A nonpigmented tissue like corpus callosum was used as a control and extracted by the method used for neuromelanin isolation; a total elimination of tissue components was found, thus demonstrating the capability of the reported procedures to isolate neuromelanin alone. The presence of a peptide component in the neuromelanin structure and the selective affinity for lipid molecules suggest new aspects of the functional role and metabolic pathway of neuromelanin.     

Expression of obestatin and ghrelin in papillary thyroid carcinoma

Ghrelin and obestatin are two peptide hormones with opposing roles in the control of appetite: orexigenic and anorexigenic, respectively. Loss of appetite is a common, serious complication of many forms of malignancy. The goals of this study were to investigate: (i) whether there are differences in ghrelin and obestatin peptide expression in thyroid tissues from a series of papillary carcinoma cases and normal controls, and (ii) whether there are correlations between tissue ghrelin and obestatin levels in series of papillary carcinoma cases and normal controls. Immunohistochemical analysis showed that in sections of benign human thyroid tissue, anti-ghrelin antibody reacted with intense staining in colloid-filled follicles. In benign thyroid tissues, colloids displayed plentiful dispersion in comparison with papillary microcarcinomas, whereas colloids in malignant thyroid tissues were uncommon. We found markedly lower tissue ghrelin levels in thyroid tissue of patients with papillary carcinomas, compared with normal thyroid tissues (P = 0.001). Immunohistochemical analysis also showed that obestatin in papillary carcinoma stained positively to various degrees. Obestatin tissue levels in papillary carcinomas tended to be slightly higher than those in normal thyroid tissue, but this was not statistically significant (P = 0.29). We also report that thyroid tissue of patients with Hashimoto’s thyroiditis produced ghrelin and obestatin at similar levels as in normal thyroid tissue, even though colloid in Hashimoto’s disease is scarce. We conclude that depressed expression of ghrelin, but not obestatin, is specific to papillary carcinoma, and this difference might constitute a diagnostic tool to differentiate papillary carcinoma from normal thyroid tissue. We currently do not know how these peptides are regulated and what factors are involved in papillary carcinoma, which inhibit the expression of ghrelin but not obestatin. This issue warrants further studies.     

Fragments of obestatin as modulators of feed intake, circulating lipids, and stored fat

Obestatin, shown to reduce feed intake and gain in body weight in rodents, is a very attractive candidate to be used against obesity. In this study, we aimed to investigate the relationship between the primary structure and activity of obestatin. Also of interest to us is a peptide of minimal length that closely mimics obestatin. Towards the same, we synthesized rodent obestatin and three overlapping fragments spanning residues 1-13, 6-18, and 11-23 of obestatin. These peptides subsequent to purification and characterization were tested upon adult male mice for their ability to reduce feed intake and gain in body weight. The N-terminal peptide (residues 1-13) mimicked obestatin the closest. The middle fragment (residues 6-18) significantly reduced epididymal fat without much altering feed intake or body weight.     

Chronic treatment with a stable obestatin analog significantly alters plasma triglyceride levels but fails to influence food intake; fluid intake; body weight; or body composition in rats

Obestatin (OB(1-23) is a 23 amino acid peptide encoded on the preproghrelin gene, originally reported to have metabolic actions related to food intake, gastric emptying and body weight. The biological instability of OB(1-23) has recently been highlighted by studies demonstrating its rapid enzymatic cleavage in a number of biological matrices. We assessed the stability of both OB(1-23) and an N-terminally PEGylated analog (PEG-OB(1-23)) before conducting chronic in vivo studies. Peptides were incubated in rat liver homogenate and degradation monitored by LC-MS. PEG-OB(1-23) was approximately 3-times more stable than OB(1-23). Following a 14 day infusion of Sprague-Dawley rats with 50 nmol/kg/day of OB(1-23) or a N-terminally PEGylated analog (PEG-OB(1-23)), we found no changes in food/fluid intake, body weight and plasma glucose or cholesterol between groups. Furthermore, morphometric liver, muscle and white adipose tissue (WAT) weights and tissue triglyceride concentrations remained unaltered between groups. However, with stabilized PEG-OB(1-23) we observed a 40% reduction in plasma triglycerides. These findings indicate that PEG-OB(1-23) is an OB(1-23) analog with significantly enhanced stability and suggest that obestatin could play a role in modulating physiological lipid metabolism, although it does not appear to be involved in regulation of food/fluid intake, body weight or fat deposition.     

Obestatin induction of early-response gene expression in gastrointestinal and adipose tissues and the mediatory role of G protein-coupled receptor, GPR39

Obestatin was identified as a brain/gut peptide hormone encoded by the ghrelin gene and found to interact with the G protein-coupled receptor, GPR39. We investigated target cells for obestatin based on induction of an early-response gene c-fos in different tissues. After ip injection of obestatin, c-fos staining was found in the nuclei of gastric mucosa, intestinal villi, white adipose tissues, hepatic cords, and kidney tubules. Immunohistochemical analyses using GPR39 antibodies further revealed cytoplasmic staining in these tissues. In cultured 3T3-L1 cells, treatment with obestatin, but not motilin, induced c-fos expression. In these preadipocytes, treatment with obestatin also stimulated ERK1/2 phosphorylation. Because phenotypes of GPR39 null mice are partially consistent with a role of GPR39 in mediating obestatin actions, we hypothesized that inconsistencies on the binding of iodinated obestatin to GPR39 are due to variations in the bioactivity of iodinated obestatin. We obtained monoiodoobestatin after HPLC purification and demonstrated its binding to jejunum, stomach, ileum, pituitary, and white adipose tissue. Furthermore, human embryonic kidney 293T cells transfected with plasmids encoding human or mouse GPR39 or a human GPR39 isoform, but not the ghrelin receptor, exhibited high-affinity binding to monoiodoobestatin. Binding studies using jejunum homogenates and recombinant GPR39 revealed obestatin-specific displacement curves. Furthermore, treatment with obestatin induced c-fos expression in gastric mucosa of wild-type, but not GPR39 null, mice, underscoring a mediating role of this receptor in obestatin actions. The present findings indicate that obestatin is a metabolic hormone capable of binding to GPR39 to regulate the functions of diverse gastrointestinal and adipose tissues.     

Catabolism of rat growth hormone-releasing factor(1-29) amide in rat serum and liver.

Clinical and veterinary uses of growth hormone-releasing factor [GRF(1- 29)NH2] require the design of analogs that are resistant to proteolysis by serum and liver degrading enzymes. This study investigated rat GRF(1-29)NH2 processing in serum and liver homogenate by means of high pressure liquid chromatography (HPLC). Synthetic rGRF(1-29)NH2 (30 microM) was incubated (0-120 min, 37 degrees C) in serum (49 +/- 8 mg prot./ml). The rGRF(1-29)NH2 (10 microM) was also incubated (0-120 min, 37 degrees C) with liver homogenate (200 +/- 6 micrograms prot./ml). Time course studies of rGRF(1-29)NH2 disappearance showed apparent half-lives of 18 +/- 4 min and 13 +/- 3 min in serum and liver homogenate, respectively. This was accompanied by the appearance of degradation products that were all less hydrophobic than the native peptide. In the serum, two major metabolites were detected and isolated by preparative HPLC. Combined results of amino acid analysis, sequencing, and chromatography with synthetic homologs revealed the presence of rGRF(1-20)OH and (3-20)OH. A small amount of rGRF(12-29)NH2, coeluting with rGRF(3-20)OH, was also found by sequencing. In the liver, rGRF(1-18)OH, (3-18)OH, and (1-10)OH were identified. The peptide bond Ala2-Asp3 (DPP IV cleavage site) was hydrolyzed in both serum and liver. Other tissue-specific cleavage sites were Arg11-Arg12 and Arg20-Lys21 (trypsin-like cleavage site) in the serum, and Tyr10-Arg11 and Tyr18-Ala19 (chymotrypsin-like cleavage site) in the liver.(ABSTRACT TRUNCATED AT 250 WORDS)     

Treadmill exercise reduces obestatin concentrations in rat fundus and small intestine

Ghrelin and obestatin both are orexigenic/anorexigenic peptides which are secreted from gastrointestinal tracts (fundus submucosa cells). Obestatin is a 23 amino acid peptide recently isolated from rat stomach, is encoded by the same gene that encodes ghrelin. It has been suggested that ghrelin/obestatin stimulate growth hormone release and have opposite actions on food intake. Distribution and biological activity of obestatin and its role in energy balance were studied in rodents. The purpose of the present study was to investigate fundus and intestine obestatin concentrations and selected hormonal responses to a treadmill exercise running program. Fourteen adult Wistar male rats (12-14 weeks old, 235-250 g) were used for this study. Animals were divided into control (n = 7) and training (n = 7) groups. Training group was given exercise on a motor-driven treadmill at 25 m/min (0% grade) for 60 min/day, 5 days/week for 6 weeks. Rats were sacrificed 48 h after the last session of exercise fundus, small intestine, and liver were excised, immediately washed in ice-cold saline, and frozen in liquid nitrogen for determination of obestatin and ATP concentrations and liver glycogen content. Plasma was collected for glucose, growth hormone (GH), insulin, and cortisol measurements. Total obestatin concentrations were significantly (P < 0.045, P < 0.032, respectively) low in trained rat fundus and intestine at rest. Fundus and intestine ATP content remained unchanged. Liver glycogen content was significantly (P < 0.039) higher in trained rats. Changes in plasma total obestatin, glucose, insulin, cortisol levels were not significant. Plasma GH concentrations was significantly (P < 0.001) higher in trained animals when compared with control rats. The data indicate that moderate treadmill exercise was able to reduce fundus and small intestine total obestatin concentrations and this reduction was accompanied with a higher plasma GH and liver glycogen content in trained rats. Exercise training might modulate fundus and intestine total obestatin levels via an improvement of energy source and a negative feedback action of GH on this peptide.     

In Vitro Metabolic Stability of Exendin-4: Pharmacokinetics and Identification of Cleavage Products

The aim of this study was to investigate the metabolic stability and cleavage sites of exendin-4 in rat tissue homogenates, as well as to identify the types of proteases involved in exendin-4 degradation. The stability of exendin-4 in kidney and liver homogenates from rats was evaluated using liquid chromatography-electrospray ionization mass spectrometry (LC-ESI-MS) with gradient elution. Furthermore, we used a combination of matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) and LC-ESI-MS/MS to identify the structures of the major degradation products of exendin-4, and peptidase inhibitors were used to characterize exendin-4 degradation in rat liver and kidney homogenates and to identify the proteases involved in exendin-4 metabolism. Exendin-4 had a half-life of 7.8 and 100.9 min in the kidney and liver homogenate, respectively. The enzymes most likely to be involved in the degradation of exendin-4 were aminopeptidases, serineproteases, and metalloproteases. Exendin-4(15-39) and exendin-4(16-39) were the predominant direct exendin-4 metabolites in the kidney, and the main product of exendin-4 metabolism in the liver was exendin-4(12-39). Our results indicated that the metabolism of exendin-4 involved an initial endoproteolytic cleavage and subsequent exoproteolytic digestion. The degradation of exendin-4 in the kidney and liver homogenates followed distinct patterns, and the primary cleavage sites of exendin-4 degradation in rat kidney homogenates were located after AA-14, and -15, whereas those in rat liver homogenates were located after AA-11.     

Secretion of apolipoproteins in very low density and high density lipoproteins by perfused rat liver

The incorporation of labeled amino acids into the peptides of very low density lipoproteins (VLDL) and high density lipoproteins (HDL) secreted by perfused rat liver was studied using a Ringer-albumin solution in the perfusate in place of serum to diminish exchange of peptides between VLDL and HDL. Among the lipoproteins, the greatest release of protein, greatest incorporation of amino acid, and highest specific activity were found in VLDL. After separation of the delipidated peptides by electrophoresis on polyacrylamide gel, the incorporation into VLDL peptides was found to be 5-10 times as great as into HDL peptides. There was virtually no incorporation into the peptides of low density lipoproteins (LDL). Approximately 25% of the radioactivity incorporated into perfusate VLDL failed to enter the 13% polyacrylamide gel. The remaining radioactivity was distributed primarily among three peptide bands; one, found in the upper portion of the gel, contained 45% of the total, most of the remainder being found in two rapidly migrating bands. These three peptides appear to approximate those of human apo-C in relative electrophoretic mobility. Most of the HDL peptide radioactivity entering the running gel was found in a band that migrates slightly faster than the main VLDL band. A portion of the radioactivity of this major HDL band did not enter the running gel unless beta-mercaptoethanol was present. Greater separation of these two bands by polyacrylamide gel electrophoresis for 24 hr confirmed that the major bands in VLDL and in HDL were different. The rapidly moving peptides of HDL were found to contain very little radioactivity. Determination of the intensity of staining of carrier-free perfusate VLDL and HDL peptides produced a pattern similar to the incorporation of labeled amino acids. It is concluded that the rapidly moving peptides, which may contain activators of lipoprotein lipase, are only secreted as part of the VLDL.