Binding of proteolytically processed phospholipase D from Streptomyces chromofuscus to phosphatidylcholine membranes facilitates vesicle aggregation and fusion.

Ca(2+)-dependent phospholipase D is secreted from Streptomyces chromofuscus as an intact enzyme of 57 kDa (PLD(57)). Under certain growth conditions, PLD is proteolytically cleaved and activated to form PLD(42/20) (named for the apparent size of the peptides). The PLD(42) catalytic core and 20 kDa C-terminal domain remain tightly associated through noncovalent interactions. In the presence of Ba(2+) (to enhance protein binding to zwitterionic vesicles without hydrolysis of substrate), PLD(42/20), but not PLD(57), induces POPC vesicle leakiness as measured by entrapped CF leakage. PLD(42/20) also induces vesicle fusion (as measured by light scattering, fluorescence quenching, and cryo-TEM) under these conditions (1 mM POPC, 5 mM Ba(2+)); neither PLD(42) nor PLD(20) alone can act as a fusogen. For intact PLD(57) to cause CF leakiness, the soluble activator diC(4)PA must be present. However, even with diC(4)PA, PLD(57) does not induce significant vesicle fusion. In the absence of metal ions, all PLD forms bind to PC vesicles doped with 10 mol % PA. Again, only PLD(42/20) is fusogenic and causes aggregation and fusion on a rapid time scale. Taken together, these data suggest that activated PLD(42/20) inserts more readily into the lipid bilayer than other PLD forms and creates structures that allow bilayers to fuse. Cleavage of the PLD(57) by a secreted protease to generate PLD(42/20) occurs in the late stages of S. chromofuscus cell cultures. Production of this more active and fusogenic enzyme may play a role in nutrient scavenging in stationary phase cultures.     

Phospholipase D in homogenates from HL-60 granulocytes: implications of calcium and G protein control

Occupancy of chemotactic peptide receptors leads to rapid initiation of phospholipase D (PLD) activity in intact dimethylsulfoxide-differentiated HL-60 granulocytes (Pai, J.-K, Siegel, M.I., Egan, R.W., and Billah, M.M. (1988) J. Biol. Chem. 263, 12472). To gain further insight into the activation mechanisms, PLD has been studied in cell lysates from HL-60 granulocytes, using 1-0-alkyl-2-oleoyl-[32P]phosphatidylcholine (alkyl-[32P]PC), 1-0-[3H]alkyl-2-oleoyl-phosphatidylcholine [( 3H]alkyl-PC) and [14C]arachidonyl-phospholipids as substrates. In the presence of Ca2+ and GTP gamma S, post-nuclear homogenates degrade alkyl-[32P]PC to produce 1-0-alkyl-[32P]phosphatidic acid (alkyl-[32P]-PA), and in the presence of ethanol, also 1-0-alkyl-[32P]phosphatidylethanol (alkyl-[32P]PEt). By comparing the 3H/32P ratios of PA and PEt to that of PC, it is concluded that PA and PEt are formed exclusively by a PLD that catalyzes both hydrolysis and transphosphatidylation between PC and ethanol. Furthermore, PC containing either ester- or ether-linkage at the sn-1 position is degraded in preference to phosphatidylethanolamine and phosphatidylinositol by PLD in HL-60 cell homogenates. It is concluded that HL-60 granulocytes contain a PC-specific PLD that requires both Ca2+ and GTP for activation.     

Two uncommon phospholipase D isoenzymes from poppy seedlings (Papaver somniferum L.)

Phospholipase D (PLD) has been detected in seedlings of Papaver somniferum L. cv. Lazúr (Papaveraceae). Purification of the enzyme revealed the existence of two forms of PLD (named as PLD-A and PLD-B). The two enzymes strongly differ in their catalytic properties. The pH optima were found at pH 8.0 for PLD-A and at pH 5.5 for PLD-B. While both enzymes show hydrolytic activity toward phosphatidylcholine (PC) and phosphatidyl-p-nitrophenol (PpNP), PLD-B only was able to catalyze the exchange of choline in PC by glycerol. Both enzymes were activated by Ca(2+) ions with an optimum concentration of 10 mM. In contrast to PLDs from other plants, PLD-B was still more activated by Zn(2+) ions with an optimum concentration of 5 mM. The apparent molecular masses of PLD-A and PLD-B, derived from sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE), were estimated to be 116.4 and 114.1 kDa. N-terminal protein sequencing indicated N-terminal blockage in both cases. The isoelectric points were found to be 8.7 for PLD-A and 6.7 for PLD-B. Both enzymes were shown to be N-linked glycoproteins. This paper is the first report on PLD in poppy and indicates some important differences of the two enzyme forms to other PLDs known so far.     

Phosphohydrolase and transphosphatidylation reactions of two Streptomyces phospholipase D enzymes: covalent versus noncovalent catalysis

A kinetic comparison of the hydrolase and transferase activities of two bacterial phospholipase D (PLD) enzymes with little sequence homology provides insights into mechanistic differences and also the more general role of Ca(2+) in modulating PLD reactions. Although the two PLDs exhibit similar substrate specificity (phosphatidylcholine preferred), sensitivity to substrate aggregation or Ca(2+), and pH optima are quite distinct. Streptomyces sp. PMF PLD, a member of the PLD superfamily, generates both hydrolase and transferase products in parallel, consistent with a mechanism that proceeds through a covalent phosphatidylhistidyl intermediate where the rate-limiting step is formation of the covalent intermediate. For Streptomyces chromofuscus PLD, the two reactions exhibit different pH profiles, a result consistent with a mechanism likely to involve direct attack of water or an alcohol on the phosphorus. Ca(2+), not required for monomer or micelle hydrolysis, can activate both PLDs for hydrolysis of PC unilamellar vesicles. In the case of Streptomyces sp. PMF PLD, Ca(2+) relieves product inhibition by interactions with the phosphatidic acid (PA). A similar rate enhancement could occur with other HxKx(4)D-motif PLDs as well. For S. chromofuscus PLD, Ca(2+) is absolutely critical for binding of the enzyme to PC vesicles and for PA activation. That the Ca(2+)-PA activation involves a discreet site on the protein is suggested by the observation that the identity of the C-terminal residue in S. chromofuscus PLD can modulate the extent of product activation.     

Phosphorylation of caldesmon prevents its interaction with smooth muscle myosin

Caldesmon is known to bind to smooth muscle myosin. Ca2+/calmodulin-dependent phosphorylation of caldesmon completely blocks its interaction with myosin. Cleavage of caldesmon at its 2 cysteine residues by 2-nitro-5-thiocyanobenzoic acid (NTCB) occurs initially at one site to yield 108-kDa and 21.2-kDa peptides and subsequently at the second site within the 108-kDa peptide to yield 85-kDa and 23.5-kDa fragments. The 23.5-kDa peptide retains the ability to bind to myosin. The N-terminal (95 kDa) and C-terminal (42 kDa) chymotryptic peptides of caldesmon were isolated and digested with NTCB: the C-terminal actin- and calmodulin-binding peptide was not cleaved, indicating that it does not contain either of the cysteine residues, whereas the 95-kDa N-terminal peptide was cleaved at two sites to yield 56-kDa, 23.5-kDa, and 21.2-kDa fragments. The arrangement of NTCB fragments in caldesmon is, therefore: 21.2 kDa/23.5 kDa/85 kDa from N to C terminus. Digestion of phosphorylated caldesmon with NTCB suggested a single phosphorylation site in the 21.2-kDa peptide and three sites in the 23.5-kDa peptide. These results lead to the development of a model whereby caldesmon may cross-link actin to myosin and such cross-linking is blocked by phosphorylation of caldesmon. This mechanism may explain the formation of reversible "latch bridges" which permit force maintenance at low levels of myosin phosphorylation in intact smooth muscles.     

Two uncommon phospholipase D isoenzymes from poppy seedlings (Papaver somniferum L.)

Phospholipase D (PLD) has been detected in seedlings of Papaver somniferum L. cv. Lazúr (Papaveraceae). Purification of the enzyme revealed the existence of two forms of PLD (named as PLD-A and PLD-B). The two enzymes strongly differ in their catalytic properties. The pH optima were found at pH 8.0 for PLD-A and at pH 5.5 for PLD-B. While both enzymes show hydrolytic activity toward phosphatidylcholine (PC) and phosphatidyl-p-nitrophenol (PpNP), PLD-B only was able to catalyze the exchange of choline in PC by glycerol. Both enzymes were activated by Ca²⁺ ions with an optimum concentration of 10 mM. In contrast to PLDs from other plants, PLD-B was still more activated by Zn²⁺ ions with an optimum concentration of 5 mM. The apparent molecular masses of PLD-A and PLD-B, derived from sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE), were estimated to be 116.4 and 114.1 kDa. N-terminal protein sequencing indicated N-terminal blockage in both cases. The isoelectric points were found to be 8.7 for PLD-A and 6.7 for PLD-B. Both enzymes were shown to be N-linked glycoproteins. This paper is the first report on PLD in poppy and indicates some important differences of the two enzyme forms to other PLDs known so far.     

Implication of Ca2+-Dependent Protein Tyrosine Phosphorylation in Carbachol-Induced Phospholipase D Activation in Rat Pheochromocytoma PC12 Cells

Abstract: The mechanism for carbachol (CCh)-induced phospholipase D (PLD) activation was investigated in [³H]palmitic acid-labeled pheochromocytoma PC12 cells with respect to the involvement of protein tyrosine phosphorylation and Ca²⁺. PLD activity was assessed by measuring the formation of [³H]phosphatidylbutanol in the presence of 0.3% butanol. Pretreatment of cells with the tyrosine kinase inhibitors herbimycin A, genistein, and tyrphostin inhibited PLD activation by CCh. Western blot analysis revealed several apparent tyrosine-phosphorylated protein bands (111, 91, 84, 74, 65–70, 44, and 42 kDa) in PC12 cells treated with CCh. Phosphorylation of the 111-, 91-, 84-, and 65–70-kDa proteins peaked within 1 min, and their time-dependent changes seemingly correlated with that of PLD activation. Others (74, 44^MAPK, and 42^MAPK kDa) were phosphorylated rather slowly, and maximal tyrosine phosphorylation was observed at 2 min. Herbimycin A inhibited PLD activity and tyrosine phosphorylation of four proteins (111, 91, 84, and 65–70 kDa) in a preincubation time- and concentration-dependent fashion. In Ca²⁺-free buffer, CCh-induced [³H]phosphatidylbutanol formation and protein tyrosine phosphorylation were abolished. A Ca²⁺ ionophore, A23187, caused PLD activation and tyrosine phosphorylation of four proteins of 111, 91, 84, and 65–70 kDa only in the presence of extracellular Ca²⁺. Extracellular Ca²⁺ dependency for CCh-induced PLD activation was well correlated with that for tyrosine phosphorylation of the four proteins listed above, especially the 111-kDa protein. These results suggest that Ca²⁺-dependent protein tyrosine phosphorylation is closely implicated in CCh-induced PLD activation in PC12 cells.     

Ca2+-dependent proteolysis of the Ah receptor

We previously reported (J. Biol. Chem. (1986) 261, 6352-6465) that the photoaffinity ligand for the Ah receptor, [125I]-2-azido-3-iodo-7,8-dibromodibenzo-p-dioxin, upon incubation with the liver cytosol fraction from C57BL/6 mice, labeled in a 1:1 ratio two peptides that had apparent molecular masses of 95 and 70 kDa and similar proteolytic fragmentation patterns. In the cytosolic fraction of Hepa 1 cells, a cloned murine hepatoma cell line, the product of photoaffinity labeling is almost exclusively a 95-kDa peptide which is rapidly hydrolyzed by a Ca2+-dependent proteinase to a 70-kDa peptide as well as other fragments. Thus, the ligand binding unit of the Ah receptor in C57BL/6 mouse liver and Hepa 1 cell is a 95-kDa peptide, and the 70-kDa fragment is a proteolytic artifact. The Ca2+-dependent proteinase which hydrolyzes the 95-kDa peptide has the properties of calpain II: (i) an absolute requirement for Ca2+, with maximal activity at 0.5 to 1.0 mM Ca2+; (ii) a pH optimum of 7.5 to 8.0; (iii) inhibition by EDTA, iodoacetamide, leupeptin and L-trans-epoxysuccinylleucylamido(4-guanidino)butane, but not by soybean trypsin inhibitor, aprotinin, or phenylmethanesufonyl fluoride. Upon chromatographic separation of the liver cytosol of C57BL/6 mice on DEAE-Sephacel, Ca2+-dependent proteinase activity (using casein or the labeled 95-kDa peptide as substrates) elutes with 0.25 M NaCl, and a specific proteinase inhibitor elutes with 0.15 M NaCl. Ca2+-dependent proteinase activity that hydrolyzes the 95-kDa peptide is found in the liver cytosols of several mammalian species.     

An upstream regulator and downstream target of phospholipase D1 activity during pheromone response in Saccharomyces cerevisiae

Phospholipase D1 (PLD1), which is the product of the SPO14 gene, has been shown to play a role in the process of polarized cell growth (PCG) during the pheromone response in Saccharomyces cerevisiae. PLD1 hydrolyzes phosphatidylcholine to produce phosphatidic acid (PA) and a free choline headgroup. This study investigated the interactions of PLD1 and PA with two proteins known to be involved in the cellular signaling leading to PCG in yeast, the small GTPase Cdc42p and the PAK family kinase Ste20p. Constitutively activated Cdc42p stimulates PLD1 activity. Protein-lipid binding blots confirmed the specific binding of Ste20p to the PLD1 product, PA. Finally, kinase activity assays provided evidence for the stimulation of Ste20p by PA. These findings highlight the important interactions among PLD1, Cdc42p and Ste20p during PCG in S. cerevisiae.     

Isolation of extracellular 28- and 42-kilodalton beta-1,3-glucanases and comparison of three beta-1,3-glucanases produced by Bacillus circulans IAM1165.

Bacillus circulans IAM1165 produces three major extracellular beta-1,3-glucanases (molecular masses, 28, 42, and 91 kDa) during the stationary phase of growth. The 28- and 42-kDa enzymes were purified to homogeneity from the culture supernatant in this study. The properties of these two enzymes were examined, together with those of the 91-kDa enzyme previously isolated. The enzymatic properties of the 28- and 42-kDa beta-1,3-glucanases closely resemble each other. The enzymes belong to a category of endo type 1,3-beta-D-glucan glucanohydrolases. The enzymes were active at pH 4.0 to 7.0. The optimum temperature of the reactions was 60 degrees C when laminarin (a soluble beta-1,3-glucan) was used as the substrate at pH 7.0. The enzymes hydrolyzed barley glucan and lichenan (beta-1,3-1,4-glucans) more effectively than laminarin. Of the three enzymes, the 42-kDa enzyme lysed fungal cell walls the most effectively.     

Rapid protein kinase C-dependent activation of phospholipase D leads to delayed 1,2-diglyceride accumulation

We have shown previously that the major source of diglyceride (DG) formed following muscarinic receptor (mAChR) stimulation of 1321N1 astrocytoma cells is phosphatidylcholine (PC) rather than the phosphoinositides (Martinson, E. A., Goldstein, D., and Brown, J. H. (1989) J. Biol. Chem. 264, 14748-14754). We have also noted that there is a delay of several minutes before significant DG accumulation is observed. In the present work, we examine the time course and mechanism of PC hydrolysis in response to mAChR stimulation. Treatment of 1321N1 cells with carbachol results in increases in radiolabeled choline, phosphatidic acid (PA) and phosphatidylethanol (PEt), metabolites that are products of phospholipase D (PLD) action on PC. These products are all formed within 15 s of mAChR stimulation and reach a plateau within 30-60 s. The time course of PEt formation suggests that PLD is no longer activated after several minutes of mAChR stimulation. Thus there is a discrepancy between the rapid and transient activation of PLD and the delayed accumulation of DG. It appears that most of the DG is formed through the action of PLD, since propranolol (which inhibits the conversion of PA to DG) and down-regulation of protein kinase C (which prevents activation of PLD by carbachol) both markedly inhibit DG production. Using a protocol in which cells are stimulated with carbachol for only one minute (a period during which PLD and PA formation are maximally activated), we show that DG mass continues to increase following removal of agonist. We suggest that the rapid and transient activation of PLD results in delayed accumulation of DG due to the relatively slow conversion of PA to DG by PA phosphatase.     

Interaction of CPa-1 with the manganese-stabilizing protein of photosystem II: identification of domains cross-linked by 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide.

The structural organization of photosystem II proteins has been investigated by use of the zero-length protein cross-linking reagent 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide and monoclonal and polyclonal antibody reagents. Photosystem II membranes were treated with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide which cross-links amino groups to carboxyl groups which are in van der Waals contact. This treatment did not affect the oxygen evolution rates of these membranes and increased the retention of oxygen evolution after CaCl2 washing. Analysis of the proteins cross-linked by this treatment indicated that two cross-linked species with apparent molecular masses of 95 and 110 kDa were formed which cross-reacted with antibodies against both the 33-kDa manganese-stabilizing protein and the chlorophyll protein CPa-1. Cleavage of the 110-kDa cross-linked species with cyanogen bromide followed by N-terminal sequence analysis was used to identify the peptide fragments of CPa-1 and the manganese-stabilizing protein which were cross-linked. Two cyanogen bromide fragments were identified with apparent molecular masses of 50 and 25 kDa. N-Terminal sequence analysis of the 50-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa fragment of CPa-1 and the intact manganese-stabilizing protein. This strongly suggests that the manganese-stabilizing protein is cross-linked to the large extrinsic loop domain of CPa-1. N-Terminal analysis of the 25-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa peptide of CPa-1 and the N-terminal 8-kDa peptide of the manganese-stabilizing protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of interfacial binding in the activation of Streptomyces chromofuscus phospholipase D by phosphatidic acid

The Streptomyces chromofuscus phospholipase D (PLD) cleavage of phosphatidylcholine in bilayers can be enhanced by the addition of the product phosphatidic acid (PA). Other anionic lipids such as phosphatidylinositol, oleic acid, or phosphatidylmethanol do not activate this PLD. This allosteric activation by PA could involve a conformational change in the enzyme that alters PLD binding to phospholipid surfaces. To test this, the binding of intact PLD and proteolytically cleaved isoforms to styrene divinylbenzene beads coated with a phospholipid monolayer and to unilamellar vesicles was examined. The results indicate that intact PLD has a very high affinity for PA bilayers at pH >/= 7 in the presence of EGTA that is weakened as Ca(2+) or Ba(2+) are added to the system. Proteolytically clipped PLD also binds tightly to PA in the absence of metal ions. However, the isolated catalytic fragment has a considerably weaker affinity for PA surfaces. In contrast to PA surfaces, all PLD forms exhibited very low affinity for PC interfaces with an increased binding when Ba(2+) was added. All PLD forms also bound tightly to other anionic phospholipid surfaces (e.g. phosphatidylserine, phosphatidylinositol, and phosphatidylmethanol). However, this binding was not modulated in the same way by divalent cations. Chemical cross-linking studies suggested that a major effect of PLD binding to PA.Ca(2+) surfaces is aggregation of the enzyme. These results indicate that PLD partitioning to phospholipid surfaces and kinetic activation are two separate events and suggest that the Ca(2+) modulation of PA.PLD binding involves protein aggregation that may be the critical interaction for activation.     

Hepatitis B virus p25 precore protein accumulates in Xenopus oocytes as an untranslocated phosphoprotein with an uncleaved signal peptide.

We have analyzed the translocation of hepatitis B virus (HBV) precore (PC) proteins by using Xenopus oocytes injected with a synthetic PC mRNA. The PC region is a 29-amino-acid sequence that precedes the 21.5-kDa HBV capsid or core (C) protein (p21.5) and directs the secretion of core-related proteins. The first 19 PC amino acids provide a signal peptide that is cleaved with the resultant translocation of a 22.5-kDa species (p22.5), in which the last 10 PC residues precede the complete p21.5 C polypeptide. Most p22.5 is matured to 16-20 kDa species by carboxyl-terminal proteolytic cleavage prior to secretion. Here we show that some four unexpected PC proteins of 24 to 25 kDa are produced in addition to the secretion products described above. Protease protection and membrane cosedimentation experiments reveal that all PC proteins behave as expected for proteins that are translocated into the lumen of the endoplasmic reticulum except for the single largest PC protein (p25), which is not translocated. Like p21.5, p25 is a phosphoprotein that localizes to the oocyte cytosol and nucleus, and protease digestion studies suggest that the two molecules have similar two-domain structures. Radiosequencing of immobilized p25 demonstrates that it contains the intact PC signal peptide and represents the unprocessed translation product of the entire PC/C locus. Thus, while many HBV PC protein molecules are correctly targeted to intracellular membranes and translocated, a significant fraction of these molecules can evade translocation and processing.     

Regulation of phospholipase D in HL-60 granulocytes. Activation by phorbol esters, diglyceride, and calcium ionophore via protein kinase- independent mechanisms

It has recently been demonstrated that the chemotactic peptide N-formyl-Met-Leu-Phe activates phospholipase D (PLD) in dimethyl sulfoxide-differentiated HL-60 granulocytes to produce phosphatidic acid (PA) and, in the presence of ethanol, phosphatidylethanol (PEt) (Pai, J.-K., Siegel, M. I., Egan, R. W., and Billah, M. M. (1988) J. Biol. Chem. 263, 12472-12477). We now report that biologically active phorbol esters, a cell-permeable diacylglycerol, 1-oleoyl-2-acetylglycerol (OAG), and calcium ionophore A23187 are also potent inducers of PLD in these HL-60 granulocytes. HL-60 granulocytes have been selectively labeled in 1-O-alkyl-2-acyl-sn-glycero-3-phosphocholine (alkyl-PC) with 32P by incubating the cells with alkyl-[32P]lyso-phosphatidylcholine (PC). When these labeled cells are treated with phorbol 12-myristate 13-acetate (PMA), phorbol 12,13-dibutyrate, OAG, or A23187, alkyl-[32P]PA is formed. Because cellular ATP has not been labeled with 32P, the formation of alkyl-[32P]PA conclusively demonstrates PLD activation by these agents. In the presence of 0.5% ethanol, phorbol esters, OAG, and A23187 also induce formation of alkyl-[32P]PEt, demonstrating that the activated PLD catalyzes transphosphatidylation between the phosphatidyl moiety of the alkyl-[32P]PC and ethanol. Formation of alkyl-[32P]PA and alkyl-[32P]PEt in response to these various agents occurs in a time- and dose-dependent manner and exhibits differential Ca2+ requirements. Based on experiments with both [3H]alkyl-PC and alkyl-[32P]PC, it is concluded that alkyl-PA and alkyl-PEt formed in response to PMA, OAG, or A23187 are derived exclusively from PLD action on alkyl-PC. Furthermore, subthreshold concentrations of PMA (0.5-2.0 nM) or OAG (1.0-25 microM) combined with subthreshold levels of A23187 (15-60 nM) induce the formation of alkyl-[32P]PA and alkyl-[32P]PEt, suggesting that receptor-mediated activation of PLD might involve cooperative interactions between Ca2+ and diglyceride. Although PLD is activated by agents that also activate protein kinase C, the protein kinase C inhibitor, K252a, inhibits PMA-induced protein phosphorylation but causes only partial inhibition of PLD activation. We conclude that phorbol esters, OAG, and A23187 activate PLD in HL-60 granulocytes via protein kinase-independent as well as protein kinase-dependent mechanisms.     

Purification and characterization of two alpha-keto ester reductases from Streptomyces thermocyaneoviolaceus IFO 14271

Two NADPH-dependent alpha-keto ester reductases (Streptomyces thermocyaneoviolaceus keto ester reductase, STKER-II and -III) were purified from S. thermocyaneoviolaceus IFO 14271, one of thermophilic actinomycetes. The molecular masses of native STKER-II and -III were estimated to be 60 kDa and 70 kDa by gel filtration chromatography, respectively. These enzymes were both homodimers, with 29-kDa and 30-kDa subunit molecular masses based on SDS polyacrylamide gel electrophoresis. STKER-II and -III were stable from pH 7.0 to 10.0 and pH 5.5 to 9.0, respectively. Ethyl 3-methyl-2-oxobutanoate was reduced by both enzymes isolated to the corresponding (R)-hydroxy ester with excellent enantiomeric excess. STKER-III showed high stereoselectivity for the reduction of bulky substrates, while the selectivity of the STKER-II-catalyzed reduction was low except for ethyl 3-methyl-2-hydrox-ybutanoate. Both enzymes had small Km values toward aliphatic keto esters having a long alkyl chain.     

Processing of synthetic pro-islet amyloid polypeptide (proIAPP) 'amylin' by recombinant prohormone convertase enzymes, PC2 and PC3, in vitro.

Islet amyloid polypeptide (IAPP), amylin, is the constituent peptide of pancreatic islet amyloid deposits which form in islets of Type 2 diabetic subjects. Human IAPP is synthesized as a 67-residue propeptide in islet beta-cells and colocalized with insulin in beta-cell granules. The mature 37-amino acid peptide is produced by proteolysis at pairs of basic residues at the C- and N-termini of the mature peptide. To determine the enzymes responsible for proteolysis and their activity at the potential cleavage sites, synthetic human proIAPP was incubated (0.5-16 h) with recombinant prohormone convertases, PC2 or PC3 at appropriate conditions of calcium and pH. The products were analysed by MS and HPLC. Proinsulin was used as a control and was cleaved by both recombinant enzymes resulting in intermediates. PC3 was active initially at the N-terminal-IAPP junction and later at the C-terminus, whereas initial PC2 activity was at the IAPP-C-terminal junction. Processing at the basic residues within the C-terminal flanking peptide rarely occurred. There was no evidence for substantial competition for the processing enzymes when the combined substrates proinsulin and proIAPP were incubated with both PC2 and PC3. As proinsulin cleavage is sequential in vivo (PC3 active at the B-chain-C-peptide junction, followed by PC2 at A chain-C-peptide junction), these data suggest that proteolysis of proIAPP and proinsulin is coincident in secretory granules and increased proinsulin secretion in diabetes could be accompanied by increased production of proIAPP.     

Identification of the functional site in the mosquito larvicidal binary toxin of Bacillus sphaericus 1593M by site-directed mutagenesis

To study the mode of action of the binary toxin (51- and 42-kDa) of Bacillus sphaericus, amino acid residues were substituted at selected sites of the N- and C-terminal regions of both peptides. Bioassay results of the mutant binary toxins tested against mosquito larvae, Culex quinquefasciatus, revealed that most of the substitutions made on both peptides led to either decrease or total loss of the activity. Furthermore, receptor binding studies carried out for some of the mutants of the 42-kDa peptide showed mutations in N- and C-terminal regions of the 42-kDa peptide did not affect the binding of the binary toxin to brush border membrane vesicles of mosquito larvae. One of the mutants having a single amino acid substitution at the C-terminal region ((312)R) of the 42-kDa peptide completely abolished the biological activity, implicating the role of this residue in membrane pore formation. These results indicate the importance of the C-terminal region of the 42-kDa of binary toxin, in general, and particularly the residue (312)R for biological activity against mosquito larvae.     

Phospholipase D catalyzes phospholipid metabolism in chemotactic peptide-stimulated HL-60 granulocytes

There exists circumstantial evidence for activation of phospholipase D (PLD) in intact cells. However, because of the complexity of phospholipid remodeling processes, it is essential to distinguish PLD clearly from other phospholipases and phospholipid remodeling enzymes. Therefore, to establish unequivocally PLD activity in dimethyl sulfoxide-differentiated HL-60 granulocytes, to demonstrate the relative contribution of PLD to phospholipid turnover, and to validate the hypothesis that the formation of phosphatidylethanol is an expression of PLD-catalyzed transphosphatidylation, we have developed methodologies to label HL-60 granulocytes in 1-O-alkyl-2-acyl-sn-glycero-3-phosphocholine (alkyl-PC) with 32P without labeling cellular ATP. These methodologies involve (a) synthesis of alkyl-lysoPC containing 32P by a combination of enzymatic and chemical procedures and (b) incubation of HL-60 granulocytes with this alkyl-[32P] lysoPC which enters the cell and becomes acylated into membrane-associated alkyl-[32P]PC. Upon stimulation of these 32P-labeled cells with the chemotactic peptide, N-formyl-Met-Leu-Phe (fMLP), alkyl-[32P]phosphatidic acid (alkyl-[32P]PA) is formed rapidly. Because, under these conditions, cellular ATP has not been labeled with 32P, alkyl-[32P]PA must be formed via PLD-catalyzed hydrolysis of alkyl-[32P]PC at the terminal phosphodiester bond. This result conclusively demonstrates fMLP-induced activation of PLD in HL-60 granulocytes. These 32P-labeled HL-60 granulocytes have also been stimulated in the presence of ethanol to produce alkyl-[32P]phosphatidylethanol (alkyl-[32P]PEt). Formation of alkyl-[32P]PEt parallels that of alkyl-[32P]PA with respect to time course, fMLP concentration, inhibition by a specific fMLP antagonist (t-butoxycarbonyl-Met-Leu-Phe), and Ca2+ concentration. These results strongly support the hypothesis that in HL-60 granulocytes, PEt is formed via PLD-catalyzed transphosphatidylation. Moreover, using HL-60 granulocytes double-labeled by incubation with [3H]alkyl-lysoPC and alkyl-[32P]lysoPC, it has been established that the early (30 s) appearance of alkyl-PA is due primarily to PLD, not phospholipase C as previously thought, and that alkyl-PEt is formed exclusively by PLD. These results constitute the first direct evidence for receptor-linked activation of PLD, leading to the generation of PA and PEt in an intact cell system.