Insulin reduces serum glycosylphosphatidylinositol phospholipase D levels in human type I diabetic patients and streptozotocin diabetic rats.

The enzyme glycosylphosphatidylinositol phospholipase D has a postulated role in the insulin-mimetic signaling pathway of glycosylphosphatidylinositol compounds. We have investigated enzyme activity in the serum of human type I diabetic patients and plasma and tissues of streptozotocin-induced diabetic rats following insulin administration. In the human diabetic patients serum enzyme activity fell by an average of 10.6% (SEM = 2.7; P = 0.008; n = 20) following administration of insulin. In addition serum enzyme activity appeared to be depleted by 27% (SEM = 8.8; P = 0.011; n = 10) compared to nondiabetic controls. In untreated diabetic rats plasma enzyme activity gradually increased 0.3-fold over a 6-week period (P < 0.001; n = 8), this increase was reversed and activity normalized when these animals were treated with insulin. Cloning of the rat glycosylphosphatidylinositol phospholipase D cDNA enabled confirmation of the liver as the principal organ of synthesis. Analysis of mRNA levels in the livers of the diabetic rats showed that gene expression was reduced in the insulin-treated animals compared to the noninsulin-treated controls by 0.7-fold (P = 0.004; n = 4). Tissue enzyme activity was also reduced in the insulin-treated rats; in skeletal muscle enzyme activity was 0.3-fold lower (P = 0.001; n = 4). Insulin therefore decreases glycosylphosphatidylinositol phospholipase D synthesis in diabetic animals resulting in decreased serum enzyme levels, suggesting a relationship between this enzyme and the function of insulin.

Mouse glycosylphosphatidylinositol-specific phospholipase D (Gpld1) characterization.

Glycosylphosphatidylinositol-specific phospholipase D (GPI-PLD) is an 110-kDa monomeric protein found in the circulation that is capable of degrading the GPI anchor utilized by dozens of cell-surface proteins in the presence of detergent. This protein is relatively abundant (5-10 microgram/ml in human serum), yet its sites of synthesis, gene structure, and overall function are unclear. It is our purpose to use the mouse system to determine its putative roles in lipid transport, pathogen control, and diabetes. We have isolated murine full-length cDNA for GPI-PLD from a pancreatic alpha cell library. The deduced amino acid sequence shows 74% homology to bovine and human GPI-PLD. There is a single structural gene (Gpld1) mapping to mouse Chromosome (Chr) 13, and among nine tissues, liver showed the greatest abundance of GPI-PLD mRNA. Genetic differences in serum GPI-PLD activity were seen among four mouse strains, and no correlation was seen between GPI-PLD activity and circulating levels of high density lipoproteins in these mice. This is the first report of map position and genetic regulation for Gpld1. This information will enable us to further study the expression and function of GPI-PLD in normal and pathological conditions.

Glycosylphosphatidylinositol-phospholipase D: a tool for glycosylphosphatidylinositol structural analysis.

Cleavage by the GPI-PLD provides definitive evidence of a minimal GPI structure: glucosamine-phosphatidylinositol. Unlike the case for PI-PLC, cleavage by the GPI-PLD is unaffected by acylation of the inositol ring. Thus the GPI-PLD provides an excellent simple enzymatic tool for analyzing the basic core structure of GPI anchors.

Activation of NADPH oxidase and phospholipase D in permeabilized human neutrophils. Correlation between oxidase activation and phosphatidic acid production.

A major function of human neutrophils (PMN) during inflammation is formation of oxygen radicals through activation of the respiratory burst enzyme, NADPH oxidase. Stimulus-induced production of both phosphatidic acid (PA) and diglyceride (DG) has been suggested to mediate oxidase activity; however, transductional mechanisms and cofactor requirements necessary for activation are poorly defined. We have utilized PMN permeabilized with Staphylococcus aureus alpha-toxin to elucidate the signal pathway involved in eliciting oxidase activity and to investigate whether PA or DG act as second messengers. PMN were permeabilized in cytoplasmic buffer supplemented with ATP and EGTA for 15 min before addition of NADPH and various cofactors. Oxidase activation was assessed by superoxide dismutase inhibitable reduction of ferricytochrome C; PA and DG levels were measured by radiolabeled product formation or by metabolite mass formation. Both superoxide (O2-) and PA formation were initiated by 10 microM GTP gamma S; addition of cytosolic levels of calcium ions (Ca2+, 120 nM) enhanced O2- and PA formation 1.5-2 fold. DG levels showed little change during these treatments. PA formation preceded O2- production and varying GTP gamma S levels had parallel effects on O2- and PA formation. However, while PA formation and oxidase activation occurred in tandem at Ca2+ levels of < 1 microM, higher calcium enhanced PA formation but inhibited O2- production. Removal of ATP completely blocked O2- production but had little effect on PA formation; in contrast, if ATP was replaced with ATP gamma S, parallel production of PA and O2- occurred in the absence of other cofactors. Finally, while inhibition of PA production by ethanol pretreatment led to inhibition of O2- formation in PMN treated with GTP gamma S alone, in cells stimulated with a combination of GTP gamma S and Ca2+, ethanol continued to inhibit PA formation but had no effect on O2- production. Our results do not support a role for DG in the signal transduction path leading to oxidase activation and, while we show a close correlation between oxidase activation and PA production under many physiologic conditions, we also demonstrate that PA is not sufficient to induce oxidase activation and O2- formation can occur when PA production is inhibited.