Glycosylation of LDL decreases its ability to interact with high-affinity receptors of human fibroblasts in vitro and decreases its clearance from rabbit plasma in vivo.

Incubation of human LDL in vitro at 37 degrees C for 48 h with [14C]glucose at concentrations from 5 to 200 mM resulted in a glycosylated LDL, containing 0.4-20 mol of glucose incorporated per apolipoprotein B of 250 000 daltons. The extent of glucose incorporated was proportional to the time of incubation and concentration of glucose. Glycosylation of LDL abolished its uptake and degradation by the high-affinity process for LDL in normal human skin fibroblasts. 125I-labeled glycosylated LDL was bound, internalized and degraded by the fibroblasts via a nonspecific low-affinity process. The 125I-labeled glycosylated LDL and 125I-labeled LDL were taken up and degraded at similar rates in a non-saturable, low-affinity process by peritoneal macrophages isolated from mice. When 125I-labeled glycosylated LDL or 125I-labeled LDL were injected into rabbits, the glycosylated LDL had a delayed plasma clearance in comparison to the LDL. The mean fractional catabolic rates were 0.67 day-1 and 1.70 day-1 for 125I-labeled glycosylated LDL and 125I-labeled LDL, respectively. The uptake and degradation of 125I-labeled LDL by human skin fibroblasts was decreased as the concentration of free carbohydrate, glucose, sucrose or sorbitol, in the medium was increased from 10 mM to 1 M. It is speculated that pathologic levels of plasma glucose in vivo could result in a decrease in LDL uptake as a result of glycosylation of LDL. A decrease in uptake of native or modified LDL in vivo could contribute to hypercholesterolemia and its pathophysiology.

The effect of dexamethasone on pyruvate kinase activity in primary cultures of hepatocytes.

Pyruvate kinase activity in primary cultures of hepatocytes isolated from a normal rat was maintained at a constant level similar to that found in vivo (14.0 +/- 2.8 units per mg of DNA) for over 6 days when both dexamethasone and insulin were included in the medium. Yet the pyruvate kinase activity decreased 50% when the cells were cultured for 2 days and 4 days, respectively, in the presence of either dexamethasone or insulin alone. A brief, 10 min incubation of hepatocytes in the presence of dexamethasone was sufficient to maintain the enzyme activity of cells subsequently cultured for 4 days in the presence of insulin. The optimal dexamethasone concentration was 1 microM. Three other glucocorticoids were able to maintain the pyruvate kinase activity in cells cultured in medium containing insulin. The presence of the protein synthesis inhibitors, actinomycin D or cyclohexamide in cells cultured in the presence of dexamethasone and insulin resulted in a 25% decrease in the pyruvate kinase activity. Therefore, it is suggested that the synergistic effect of glucocorticoids and insulin to maintain pyruvate kinase activity in primary cultures of hepatocytes is dependent upon the ability of these cells to maintain protein synthesis.

Dehydroisoandrosterone prevention of autoimmune disease in NZB/W F1 mice: lack of an effect on associated immunological abnormalities.

The effect of dietary dehydroisoandrosterone (DHA) on several immunological abnormalities associated with the development of systemic lupus erythematosus in New Zealand Black/New Zealand White F1 (NZB/W) female mice was examined. Despite the extraordinary benefits in prolonged survival and decreased synthesis of antibodies to double-stranded DNA obtained by adding DHA (0.4% w/v) to the diet fed to these mice (Lucas et al. (1985) J. Clin. Invest. 75, 2091-2093), remarkably small changes in the chemistry and function of the immune system were detected. DHA prevented the increases in spleen mass and in peritoneal cell number which occur with age in NZB/W female mice, but did not prevent the development of hypergammaglobulinemia. DHA did not affect peritoneal macrophage functions as measured by the phagocytosis of opsonized and non-opsonized sheep erythrocytes, or the zymosan-stimulated release of PGE2, 6-ketoPGF1 alpha, TXB2 and LTC4. In spleen, DHA delayed the loss of T-cell mitogenic responses until 5.5 months of age, but did not alter the spleen lymphocyte population.

Liver composition and lipid metabolism in NZB/W F1 female mice fed dehydroisoandrosterone.

The beneficial effects obtained with dehydroisoandrosterone (DHA) feeding in the treatment of murine systemic lupus erythematosus are similar to those obtained with caloric restriction or with dietary manipulation of essential fatty acid availability. In this study, the fatty acid composition of selected tissues was examined in NZB/W F1 mice fed a diet containing 0.4% DHA. The effect of the DHA diet on liver composition and the activity of key hepatic enzymes involved in fatty acid synthesis and glucose metabolism was also investigated. The content of the essential fatty acid, arachidonate, was decreased in plasma cholesteryl esters and liver and kidney phospholipids in mice fed the DHA diet, yet no significant decrease in arachidonate content was observed in plasma phospholipid. The most striking change in both plasma and liver phospholipid was an increase in palmitic acid and a decrease in stearic acid, which could result from a decreased ability for fatty acid elongation. The liver mass was dramatically increased in the mice fed DHA, primarily from parenchymal cell hypertrophy, and contained little lipid. Significant changes in the activities of malic enzyme, glucose-6-phosphate dehydrogenase and pyruvate kinase, similar to those changes which occur with fasting, were observed during the initial adaptation to the DHA diet. The pyruvate kinase activity remained low, suggesting a decrease in liver glycolysis. These results are consistent with the concept that diets containing DHA result in an altered metabolism with a decreased dependence on carbohydrate metabolism and an increased metabolism of lipids.

Increased expression of an endopeptidase (gamma-EGE/IDE) hydrolyzing beta-endorphin during differentiation and maturation of bone marrow macrophages.

The presence and regulated expression of peptidase activity is a powerful mechanism with the potential to terminate or alter receptor recognition, cell membrane signal transduction, and physiological responses of immune cells to exogenous opioid peptides. In this study, the expression of an endopeptidase that hydrolyzes beta-endorphin to gamma-endorphin and other peptide products was investigated during in vitro differentiation and maturation of recombinant granulocyte-macrophage colony-stimulating factor (rGM-CSF) -derived, bone marrow-derived macrophages. In freshly isolated intact isolated mouse bone marrow cells the rate of beta-endorphin hydrolysis is undetectable (<0.1 nmol beta-endorphin hydrolyzed/h/10[6] cells). However, total intracellular beta-endorphin hydrolytic activity was increased significantly to 20.0 +/- 1.7 nmol/h/10(6) cells in the mature mouse macrophages derived in vitro by culture with rGM-CSF. rGM-CSF-derived macrophages expressed significantly higher levels of both protein and mRNA for the major beta-endorphin endopeptidase, gamma-endorphin-generating enzyme/insulin-degrading enzyme (gamma-EGE/IDE). Moreover, this enzymatic activity appears to be responsible for cleavage of exogenous beta-endorphin by intact rGM-CSF-derived macrophages or peritoneal macrophages to generate gamma-endorphin and other peptide products.

Measurement of gluconeogenesis and pyruvate recycling in the rat liver: a simple analysis of glucose and glutamate isotopomers during metabolism of [1,2,3-(13)C3]propionate.

Simple equations that relate glucose and glutamate 13C-NMR multiplet areas to gluconeogenesis and pyruvate recycling during metabolism of [1,2,3-(13)C3]propionate are presented. In isolated rat livers, gluconeogenic flux was 1.2 times TCA cycle flux and about 40% of the oxaloacetate pool underwent recycling to pyruvate prior to formation of glucose. The 13C spectra of glucose collected from rats after gastric versus intravenous administration of [1,2,3-(13)C3]propionate indicated that pyruvate recycling was slightly higher in vivo (49%) while glucose production was unchanged. This indicates that a direct measure of gluconeogenesis and pyruvate recycling may be obtained from a single 13C-NMR spectrum of blood collected after oral administration of enriched propionate.

Anti-CD3 activation of human CD4+ T cells increases expression of the intracellular beta-endorphin endopeptidase (IDE/gamma-EpGE).

In this study, increased expression of an endopeptidase hydrolyzing beta-endorphin (beta-Ep) to gamma-endorphin (gamma-Ep, beta-Ep1-17) was observed upon immobilized anti-CD3 stimulated activation of human peripheral blood CD4+ T cells (hCD4+ T cells). Although freshly isolated hCD4+ T cells are devoid of significant beta-Ep endopeptidase activity ( < 0.1 nmol h(-1) 10(6) cells (-1)), activation of these cells with immobilized anti-CD3 results in a time dependent appearance of beta-Ep endopeptidase activity which reaches a maximal value of 17.4+/-0.48 nmol h(-1) 10(6) cells(-1) after 48 h of culture. Significant up-regulation of both mRNA encoding IDE/gamma-EpGE and immunoreactive protein are observed in anti-CD3 stimulated hCD4+ T cells, indicating transcription and translation of IDE/gamma-EpGE may be elevated. No significant hydrolysis of exogenous beta-Ep is observed with intact hCD4+ T cells whether quiescent or activated or from preparations of hCD4+ T cell membranes. Therefore, this activity appears to be intracellular. Immunoreactive IDE/gamma-EpGE is detected inside activated hCD4+ T cells. Analysis of metabolites generated upon hydrolysis of beta-Ep with lysed activated hCD4+ T cell preparations identified the presence of: beta-Ep1-18, beta-Ep2-18, beta-Ep1-17, beta-Ep2-17, beta-Ep18-31, beta-Ep19-31, beta-Ep1-13, beta-Ep2-13, beta-Ep18-26, and beta-Ep20-31 as major metabolites and the majority of these are consistent with beta-Ep hydrolytic activity attributable to IDE/gamma-EpGE.

Expression of G alpha i2 mimics several aspects of LPS priming in a murine macrophage-like cell line.

Priming of macrophages with low concentrations of lipopolysaccharide (LPS) enhances the ability of substances that act through heterotrimeric G proteins to stimulate immune cell functions. Although LPS-induced alterations in the expression and functions of G proteins of the alpha i family have been reported in hematopoietic cells, their effects on subsequent steps in LPS priming of macrophages have not been defined. To study the role of G alpha i2 in priming of macrophages by LPS, we expressed a mutant, activated form of alpha i2 (alpha i2Q205L) in P388D1 cells, and compared its effects on PAF-dependent C alpha signalling and arachidonic acid release to those in cells treated with LPS. In control P388D1 cells, treatment with LPS (100 ng/ml) for 1 hr increased the amount of alpha i2 protein 2-fold. Both LPS treatment and expression of alpha i2Q205L increased the rate of PAF-induced C alpha influx across the cell membrane and arachidonic acid release, although neither altered release of C alpha from intracellular stores by PAF. Expression of alpha i2Q205L is sufficient to mimic the effects of LPS on the PAF-induced C alpha i signal and enhanced arachidonic acid release. Consequently, although increasing the expression of alpha i2 may not be the sole mechanism by which LPS enhances signalling by PAF, increased alpha i2 expression can account for the alterations in PAF-induced C alpha i regulation, and arachidonic acid release in LPS-primed P388D1 cells.

In vivo effects of lipopolysaccharide on hepatic free-NAD(P)(+)-linked redox states and cytosolic phosphorylation potential in 48-hour-fasted rats.

This study was performed to determine the magnitude and time of onset of in vivo changes in hepatic bioenergetics in response to a sublethal dose of lipopolysaccharide (LPS), a bacterial endotoxin. Male rats (48-hour-fasted) were administered an intraperitoneal injection of LPS (5 mg/kg body weight) or vehicle alone, and the livers were freeze-clamped 5, 30, or 180 minutes or 24 hours later. Liver tissue was extracted with perchloric acid, and the metabolites necessary to calculate NAD(+)- and NADP(+)-linked redox states and the cytosolic phosphorylation potential were measured. There was no significant difference in hepatic cytosolic phosphorylation potential between LPS and control groups at any of the times investigated. This indicated that the ability of the liver to synthesize adenosine triphosphate (ATP) was not compromised under the conditions of the study. No changes in hepatic redox states were observed 5 or 30 minutes after LPS treatment. Three hours after LPS treatment, hepatic cytosolic and mitochondrial free-[NAD+]/[NADH] redox states and the cytosolic free-[NADP+]/[NADPH] redox state were more oxidized. By 24 hours, only NAD(+)-linked redox states were more oxidized than the time-matched controls. Hepatic urea content was elevated at both 3 and 24 hours, compatible with an increased rate of urea synthesis as a consequence of increased amino acid metabolism, whereas hepatic beta-hydroxybutyrate and total ketone bodies were decreased 24 hours after LPS treatment, indicating decreased hepatic ketogenesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Methionine enkephalin metabolism by murine macrophage ectopeptidase(s).

Ectopeptidases which hydrolyze opioid and other neuropeptides have been identified in brain, kidney and intestine. In this study, identification of the enzymes metabolizing the opioid peptide methionine enkephalin (YGGFM) in murine macrophages was undertaken. Incubation of methionine enkephalin with intact murine peritoneal macrophages results in five products identified as Y, F, FM, GFM and GGFM by amino acid analysis and peptide microsequencing after fractionation by HPLC. The spectrum of metabolites results from at least two distinct aminopeptidase activities. The enzyme hydrolyzing YGGFM to GGFM is identified as the membrane-anchored aminopeptidase N (ApN; EC 3.4.11.2) based on its substrate specificity and inhibitor profile. A distinct bestatin and amastatin sensitive aminopeptidase catalyzes hydrolysis of GGFM to GFM. The macrophage ApN protein has a larger mass and is antigenically distinct from murine kidney ApN, which is suggested to result from glycosylation differences rather than expression of a distinct protein. The ApN catalytic activity and mRNA levels are increased in thioglycollate-elicited as compared to resident peritoneal macrophages. RT-PCR analysis identified a 0.7 kb fragment of the ApN coding sequence which was identical in mouse kidney and thioglycollate-elicited peritoneal macrophages and which has 89% identity with the corresponding rat kidney ApN cDNA sequence.

Essential fatty acid deficiency in critically ill surgical patients.

Plasma fatty acid profiles of 33 critically ill surgical patients receiving fat-free parenteral nutrition were examined at weekly intervals up to 28 days. While plasma total fatty acid concentration remained relatively constant and within the normal range, marked compositional alterations were apparent. Levels of linoleate (18:2 omega 6), the major essential fatty acid in man, fell below normal values (754 +/- 259 micrograms/ml) in 67 percent of patients within 1 week after cessation of oral intake. Decreases in other omega 6 unsaturated fatty acids, derived from linoleate, were also apparent. In contrast, gradual increases were observed in levels of endogenously synthesized fatty acids, palmitate (16:0), palmitoleate (16:1) and oleate (18:1 omega 9). A fatty acid unique to essential fatty acid deficiency, 5,8,11 eicosatrienoate (20:3 omega 9), appeared in 25 percent of the patients during the first week and in all patients by the third week of study. Considering the rapid appearance and progression of these biochemical changes, early initiation of linoleate supplementation appears justified to forestall the development of related clinical sequelae.

Dietary alteration of translatable mRNA sequences coding for rat liver pyruvate kinase.

Poly(A+) RNA (RNA containing a polyadenylic acid sequence) was isolated from individual livers of rats fed standard lab chow, fasted, or fasted and refed a high carbohydrate diet. The level of functional mRNA coding for pyruvate kinase was assayed using a rabbit reticulocyte in vitro translation system. The total 35S incorporation into newly synthesized liver pyruvate kinase was measured and compared to 35S incorporation into albumin, total trichloroacetic acid-precipitated proteins, and released polypeptide chains. The relative level of mRNA coding for liver pyruvate kinase decreases almost 60% upon fasting and increases approximately 15-fold upon refeeding with a high carbohydrate diet for 24 h. These observed changes in the amount of mRNA coding for liver pyruvate kinase agree with the previously reported changes in the relative rates of liver pyruvate kinase synthesis measured in vivo during these dietary stresses. Thus, it is suggested that the alterations in the amount of pyruvate kinase in liver in response to these dietary stresses primarily result from alteration in the amount of functional mRNA coding for the enzyme.