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The kidney is an extremely heterogeneous organ, with morphological, physiological, and metabolic changes occurring from segment to segment along each nephron. To determine the heterogeneity that might exist within discrete anatomical segments of rabbit nephron, we developed a technique for making quantitative enzyme assays in serial samples, about 100 micron long, along identified segments of the nephron. Results for three enzymes in proximal convoluted and straight tubules show that adenylate kinase, an enzyme of high-energy phosphate metabolism, gradually decreases along the S1 and S2 segments of the proximal tubule, with no abrupt changes. Fructose bisphosphatase, a gluconeogenic enzyme, is high along the major portion of the proximal tubule but plummets along the final millimeter of S3. Conversely, phosphofructokinase, a glycolytic enzyme, is very low along the proximal tubule but increases sharply within the final millimeter. These data underscore the biochemical heterogeneity of the nephron, illustrating the enzyme levels may change markedly even within anatomically defined regions. They also suggest the importance of further studies of this type and demonstrate a practical means for such studies.

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We have noted two previously undescribed inositol polyphosphates in neutral methanol extracts from Swiss mouse 3T3 cells that were grown in [3H]inositol and stimulated with platelet-derived growth factor. They have been identified as 1-monomethylphosphoinositol 4,5-bisphosphate and 1-monomethylphosphoinositol 4-phosphate by comparison to a synthesized standard using HPLC chromatography, paper electrophoresis, and enzymatic dephosphorylation with inositol polyphosphate 5-phosphomonoesterase and intestinal alkaline phosphatase [orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1]. We propose that these compounds are formed by methanolysis of inositol 1,2-(cyclic)-4,5-trisphosphate and inositol 1,2-(cyclic)-4-bisphosphate present in the cells. Inositol cyclic phosphates did not react with neutral methanol in the absence of the cells, which are required for the methanolysis reaction. These findings suggest a role for inositol cyclic phosphates as reactive compounds that are added to as yet unidentified cellular acceptors.

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Phospholipase C cleaves phosphatidylinositol 4,5-bisphosphate to form both inositol 1,4,5-trisphosphate (Ins(1,4,5)P3) and inositol 1,2-cyclic 4,5-trisphosphate (cInsP3). The further metabolism of these inositol trisphosphates is determined by two enzymes: a 3-kinase and a 5-phosphomonoesterase. The first enzyme converts Ins(1,4,5)P3 to inositol 1,3,4,5-tetrakisphosphate (InsP4), while the latter forms inositol 1,4-bisphosphate and inositol 1,2-cyclic 4-bisphosphate from Ins(1,4,5)P3 and cInsP3, respectively. The current studies show that the 3-kinase is unable to phosphorylate cInsP3. Also, the 5-phosphomonoesterase hydrolyzes InsP4 with an apparent Km of 0.5-1.0 microM to form inositol 1,3,4-trisphosphate at a maximal velocity approximately 1/30 that for Ins(1,4,5)P3. The apparent affinity of the enzyme for the three substrates is InsP4 greater than Ins(1,4,5)P3 greater than cInsP3; however, the rate at which the phosphatase hydrolyzes these substrates is Ins(1,4,5)P3 greater than cInsP3 greater than InsP4. The 5-phosphomonoesterase and 3-kinase enzymes may control the levels of inositol trisphosphates in stimulated cells. The 3-kinase has a low apparent Km for Ins(1,4,5)P3 as does the 5-phosphomonoesterase for InsP4, implying that the formation and breakdown of InsP4 may proceed when both it and its precursor are present at low levels. Ins(1,4,5)P3 is utilized by both the 3-kinase and 5-phosphomonoesterase, while cInsP3 is utilized relatively poorly only by the 5-phosphomonoesterase. These findings imply that inositol cyclic trisphosphate may be metabolized slowly after its formation in stimulated cells.

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The phosphoinositides are minor phospholipids present in all eukaryotic cells. They are storage forms for messenger molecules that transmit signals across the cell membrane and evoke responses to extracellular agonists. The phosphoinositides break down to liberate messenger molecules or precursors of messenger molecules. Many different compounds are formed, although the functions of only a few are understood. Recent studies elaborating the pathways for formation of products from phosphoinositides and the factors controlling their metabolism are summarized here.

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Cleavage of polyphosphoinositides in vitro by phospholipase C results in formation of both cyclic and noncyclic inositol phosphates. We have now isolated the cyclic product of phosphatidylinositol 4,5-bisphosphate cleavage, inositol 1,2(cyclic)-4,5-triphosphate [cIns(1:2,4,5)P3], from thrombin-treated platelets. We found 0.2-0.4 nmol of cIns-(1:2,4,5)P3 per 10(9) platelets at 10 sec after thrombin; none was found in unstimulated platelets or in platelets 10 min after thrombin addition. We conclude that cIns(1:2,4,5)P3 is a major product of polyphosphoinositide metabolism in thrombin-stimulated platelets.

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The phosphoinositides are metabolized by phospholipase C in response to hormone or agonist stimulation in many cell types to produce diglyceride and water-soluble inositol phosphates. We have recently shown that the phospholipase C reaction products include cyclic phosphate esters of inositol. One of these, inositol 1, 2-cyclic 4,5-trisphosphate, is active in promoting Ca2+ mobilization in platelets and in inducing changes in conductance in Limulus photoreceptors similar to those produced by light (Wilson, D. B., Connolly, T. M., Bross, T. E., Majerus, P. W., Sherman, W. R., Tyler, A., Rubin, L. J., and Brown, J. E. (1985) J. Biol. Chem. 260, 13496-13501. In the current study, we have examined the metabolism of the inositol phosphates. We find that both cyclic and non-cyclic inositol trisphosphates are metabolized by inositol 1,4,5-trisphosphate 5-phosphomonoesterase, to inositol 1,2-cyclic bisphosphate and inositol 1,4-bisphosphate, respectively. However, the apparent Km of the enzyme for the cyclic substrate is approximately 10-fold higher than for the non-cyclic substrate. These inositol bisphosphates are more slowly degraded to inositol 1,2-cyclic phosphate and inositol 1-phosphate, respectively. Inositol 1,2-cyclic phosphate is then hydrolyzed to inositol 1-phosphate, which in turn is degraded to inositol and inorganic phosphate by inositol 1-phosphate phosphatase. The human platelet inositol 1,2-cyclic phosphate hydrolase enzyme and a similar rat kidney hydrolase do not utilize the cyclic polyphosphate esters of inositol as substrates. These results suggest that the inositol cyclic phosphates and the non-cyclic inositol phosphates are metabolized separately by phosphatases to cyclic and non-cyclic inositol monophosphates. The cyclic monophosphate is then converted to inositol 1-phosphate by a cyclic hydrolase. We suggest that the enzymes that metabolize the inositol phosphates may serve to regulate cellular responses to these compounds.

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Cleavage of the polyphosphoinositides, catalyzed by phospholipase C purified from ram seminal vesicles, produces phosphorylated inositols containing cyclic phosphate esters (Wilson, D. B., Bross, T. E., Sherman, W. R., Berger, R. A., and Majerus, P. W. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 4013-4017). In the present study we describe the isolation and characterization of inositol 1:2-cyclic 4-bisphosphate and inositol 1:2-cyclic 4,5-trisphosphate, the two cyclic phosphate products of phospholipase C catalyzed cleavage of phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate, respectively. We established the structures of these two cyclic compounds through 18O labeling of phosphate moieties, phosphomonoesterase digestion, and fast atom bombardment-mass spectrometry. We examined the physiological effects of these compounds in two systems: saponin-permeabilized platelets loaded with 45Ca2+ and intact Limulus photoreceptors. Both inositol 1:2-cyclic 4,5-trisphosphate and the noncyclic inositol 1,4,5-trisphosphate, but not inositol 1:2-cyclic 4-bisphosphate, release 45Ca2+ from permeabilized platelets in a concentration-dependent manner. Injection of inositol 1:2-cyclic 4,5-trisphosphate into Limulus ventral photoreceptor cells induces both a change in membrane conductance and a transient increase in intracellular calcium ion concentration similar to those induced by light. We injected inositol 1,4,5-trisphosphate and inositol 1:2-cyclic 4,5-trisphosphate into the same photoreceptor cell and found that the cyclic compound is approximately five times more potent than the noncyclic compound in stimulating a conductance change. We speculate that inositol 1:2-cyclic 4,5-trisphosphate may function as a second messenger in stimulated cells.

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Platelets, and a variety of other cells, rapidly hydrolyze the phosphoinositides in response to stimulation by agonists. One of the products of hydrolysis of phosphatidylinositol 4,5-diphosphate is inositol 1,4,5-trisphosphate, which recently has been suggested to mediate intracellular Ca2+ mobilization. We have found that human platelets contain an enzyme that degrades inositol 1,4,5-trisphosphate. We have isolated this soluble enzyme and find that it hydrolyzes the 5-phosphate of inositol 1,4,5-trisphosphate (Km = 30 microM, Vmax = 5.3 microM/min/mg of protein). The products of the reaction are inositol 1,4-diphosphate and phosphate. The apparent molecular weight of the enzyme is 38,000 as determined both by gel filtration and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence and absence of 2-mercaptoethanol. This enzyme is specific for inositol 1,4,5-trisphosphate. Other water soluble inositol phosphates as well as phosphorylated sugars are not hydrolyzed, while the only inositol containing phospholipid hydrolyzed is phosphatidylinositol 4,5-diphosphate at a rate less than 1% that for inositol 4,5-trisphosphate. The inositol 1,4,5-trisphosphate 5-phosphomonoesterase requires Mg2+ for activity and is inhibited by Ca2+, Ki = 70 microM. Li+, up to 40 mM, has no effect on enzyme activity. The duration and magnitude of any inositol 1,4,5-trisphosphate response in stimulated platelets may be determined by the activity of this enzyme.

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Previous studies have shown that metabolism of phosphatidylinositol by phospholipase C produces a mixture of two water-soluble products: inositol 1-phosphate and inositol 1,2-(cyclic)phosphate. In the present study, we demonstrate that the water-soluble products of phosphatidylphosphoinositol (polyphosphoinositide) cleavage by purified ram seminal vesicle phospholipase C enzymes also contain cyclic phosphates. Inositol cyclic phosphates were detected by 18O labeling. In the presence of acid, cyclic phosphates are rapidly hydrolyzed to phosphomonoesters, and when the hydrolysis is carried out in H2 18O, the resultant phosphomonoesters will contain 18O. The 18O content of the phosphomonoesters was measured following alkaline phosphatase treatment and conversion of the inorganic phosphate to a volatile derivative for gas chromatography/mass spectrometry. Inositol cyclic phosphates were found in the phospholipase C cleavage products of all three phosphoinositides, but the ratio of cyclic to noncyclic product was found to decrease in the order phosphatidylinositol greater than phosphatidylinositol 4-phosphate greater than phosphatidylinositol 4,5-bisphosphate. The formation of myo-inositol 1,2(cyclic)-4-bisphosphate was further substantiated by anion-exchange HPLC of the water-soluble products of [32P]phosphatidylinositol 4-phosphate metabolism by phospholipase C. Two peaks were detected one of which, on acid treatment, incorporated 18O from H2 18O into phosphate groups, consistent with this peak containing the cyclic phosphate product. These results suggest that polyphosphoinositide breakdown in stimulated cells may occur via a cyclic phosphate intermediate, as has been described for phosphatidylinositol. These cyclic phosphates contain a reactive bond that may play a role in phosphoinositide-derived signal transduction.

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Sheep seminal vesicles contain two immunologically distinct phospholipase C (PLC) enzymes that can hydrolyze phosphatidylinositol (PI) (Hofmann, S.L., and Majerus, P.W. (1982) J. Biol. Chem. 257, 6461-6469). One of these enzymes (PLC-I) has been purified to homogeneity; the second (PLC-II) has been purified 2600-fold from a crude extract of seminal vesicles. In the present study we have compared the ability of these purified enzymes to hydrolyze PI, phosphatidylinositol 4-phosphate (PI-4-P), and phosphatidylinositol 4,5-diphosphate (PI-4,5-P2). Using radiolabeled substrates in small unilamellar phospholipid vesicles of defined composition, the two enzymes were found to hydrolyze all three of the phosphoinositides. Hydrolysis of all three phosphoinositides by both enzymes was stimulated by Ca2+; however, in the presence of EGTA only the polyphosphoinositides were hydrolyzed. The two enzymes displayed substrate affinities in the order PI greater than PI-4-P greater than PI-4,5-P2, and maximum hydrolysis rates in the order PI-4,5-P2 greater than PI-4-P greater than PI. When present in the same vesicles, PI and the polyphosphoinositides competed for a limiting amount of either enzyme. Inclusion of phosphatidylcholine into vesicles containing the phosphoinositides resulted in greater inhibition of PI hydrolysis than polyphosphoinositide hydrolysis. When all three phosphoinositides were present in vesicles mimicking the cytoplasmic leaflet of cell membranes, there was preferential hydrolysis of the polyphosphoinositides over PI. We conclude that a single phospholipase C can account for the hydrolysis of all three phosphoinositides seen during agonist-induced stimulation of secretory cells. The cytoplasmic Ca2+ concentration and phospholipid composition of the membrane, however, may influence the relative rate of hydrolysis of the three phosphoinositides.

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Using quantitative methods, citrate synthase (CS), fumarase, beta-hydroxyacyl-coenzyme A (CoA) dehydrogenase (beta OAC), 3-keto-acid CoA transferase (KCT), malic dehydrogenase (MDH), and malic enzyme were measured in seven defined parts of the nephron and in thin limb and papilla areas dissected from freeze-dried microtome sections of rat kidney. The results not only show a wide range of activity along the nephron for each of the enzymes, but that the proportions between the enzymes vary markedly among the different parts of the nephron. This suggests the existence of major regional differences in the capacity to oxidize specific metabolites. The ratio between two citrate cycle enzymes, fumarase and CS, was 4- or 5-fold higher in proximal segments than in the glomerulus or thin limb areas. The ratio between beta OAC (an enzyme of fatty acid oxidation) and CS was 3- to 5-fold higher in the middle proximal segments than in glomeruli or thin limb and papilla areas. The key enzyme for ketone body metabolism, KCT, was essentially confined to the thick tubule segments. Malic enzyme, in contrast to the other five enzymes, was highest in the proximal straight segments. New methods, sufficiently sensitive for this histochemical study, are described for malic enzyme and 3-keto-acid CoA transferase.

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Mutagenesis followed by suicide with highly radioactive tritiated arachidonic acid has been used to select for mouse fibrosarcoma (HSDM1C1) cells defective in eicosanoid precursor uptake. Survivors of the selection were screened by replica plating and autoradiographic assay of [3H]arachidonate esterification; a mutant cell line, EPU-1, was established. EPU-1 cells contain one-third as much arachidonate as normal HSDM1C1 cells. The mutant lacks arachidonate-specific acyl-CoA synthetase, which accounts for decreased arachidonate uptake. EPU-1 exhibits enhanced turnover of arachidonoyl- but not linoleoyl-phosphatidylcholine. Bradykinin-induced arachidonate release and prostaglandin E2 synthesis are decreased in EPU-1. Thus, arachidonoyl-CoA synthetase is required for arachidonate homeostasis in HSDM1C1 cells.

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RHC 80267 inhibits diglyceride lipase activity in microsomes from canine platelets (1). Chau and Tai (2) reported that RHC 80267 prevents the transient accumulation of monoglyceride in thrombin-stimulated human platelets, while leaving arachidonate release unimpaired. In contrast, we find that while the drug inhibits both diglyceride lipase (I50 = 15 microM) and monoglyceride lipase (I50 = 11 microM) activities in platelet microsomes, it is ineffective when added to intact platelets. The transient intermediates in the diglyceride lipase pathway, 1,2-diglyceride and 2-monoglyceride, both accumulated after thrombin stimulation of intact platelets treated with RHC 80267, and arachidonate release was not inhibited. We conclude that RHC 80267 cannot be used to evaluate the diglyceride lipase pathway in intact platelets.

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We have developed an essential fatty acid-deficient cell line from a parental cell line, HSDM1C1, which metabolizes arachidonic acid to prostaglandin E2 (PGE2). This cell line, designated EFD-1, is depleted of arachidonate, is unable to synthesize PGE2 in response to bradykinin, and has changes in fatty acid composition characteristic of tissues from animals with essential fatty acid deficiency. Within 15 min of repletion by arachidonate, the ability to synthesize PGE2 is restored. Linoleate also is able to restore PGE2 synthesis, indicating that deficient cells contain both the rate-limiting delta 6 desaturase enzyme and the delta 5 desaturase enzyme, which are required to form arachidonate. When parental cells are incubated in lipid-free medium, there is rapid induction of the ability to convert linoleate to arachidonate. Arachidonate prevents this induction, suggesting that icosanoid precursor availability controls the rate of arachidonate formation.

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