The use of a phospholipase A-less Escherichia coli mutant to establish the action of granulocyte phospholipase A on bacterial phospholipids during killing by a highly purified granulocyte fraction

Phospholipase A₂ present in a highly purified, potently bactericidal, fraction from rabbit granulocytes produces net bacterial phospholipid degradation during killing of a phospholipase A-less strain of Escherichia coli. In the wild-type parent strain phospholipid breakdown is caused not only by the action of phospholipase A₂ but also by phospholipase A₁, indicating activation of the most prominent phospholipase of E. coli. This activation occurs as soon as the bacteria are exposed to the granulocyte fraction. Phospholipid breakdown by both phospholipases A is dose dependent but reaches a plateau after 30–60 min and at higher concentrations of the fraction.Phospholipid degradation is accompanied in both strains by an increase in permeability to actinomycin D that is also dose dependent. Even though net hydrolysis of phospholipids is greater in the parent strain than in the mutant, the increase in permeability is the same in the two strains.The addition of 0.04 M Mg²⁺, after the effects on phospholipids and permeability have become manifest, initiates in both strains the restoration of insensitivity to actinomycin D, the net resynthesis of phospholipids, and the disappearance of monoacylphosphatides and the partial disappearance of free fatty acids that had accumulated. Loss of ability to multiply is not reversed by Mg²⁺ in either strain. Less than 5 μg of granulocyte fraction causes loss of viability of from 90 to 99% of $\text{1 × 10}{}^8$ microorganisms of both strains. However, at lower concentrations the parent strain is considerably more sensitive to the bactericidal effect of the granulocyte fraction than the mutant strain.     

The action of human and rabbit serum phospholipase A2 on Escherichia coli phospholipids

We have compared the properties of phospholipase A (E.C. 3.1.1.4) activity in whole human and rabbit serum toward the phospholipids of Escherichia coli. Using as substrate E. coli labeled during growth with either [1-(14)C]-palmitic acid or [1-(14)C]oleic acid, and then autoclaved to inactivate E. coli phospholipases and to render the labeled phospholipids accessible to exogenous phospholipases, we show that the deacylating activity in both human and rabbit serum is almost exclusively of the A(2) type. Rabbit serum is at least 20-fold more active than human serum. Activity in both sera is maximal at physiological Ca(2+) concentrations (2 mM) and is abolished by ethylenediaminetetraacetic acid. To examine hydrolysis of intact (unautoclaved) E. coli treated with 25% serum, use was made of a phospholipase A-deficient E. coli strain (E. coli S17), thereby eliminating the possible contribution of bacterial phospholipases to degradation. Human and rabbit serum are about equally bactericidal toward E. coli and cause comparable structural damage. However, only rabbit serum produces substantial hydrolysis of the phospholipids of intact E. coli S17. Heated (56 degrees C, 30 min) rabbit serum is non-bactericidal and retains phospholipase A(2) activity toward autoclaved, but not intact E. coli. The ability of heated serum to degrade phospholipids of intact E. coli S17 is restored, however, by adding 25% normal human serum, which is bactericidal. In this combination, doses of heated rabbit serum containing as much phospholipase A(2) activity (toward autoclaved E. coli) as is present in 25% unheated rabbit serum, produce roughly the same extent of hydrolysis of intact E. coli as does normal rabbit serum alone. Low doses with a phospholipase A(2) activity comparable to that of normal human serum elicit little or no hydrolysis. These findings indicate that hydrolysis of the phospholipids of intact E. coli S17 by serum occurs when: 1) the serum is bactericidal, and 2) when sufficient phospholipase A(2) is present. The difference in phospholipid hydrolysis that accompanies killing of E. coli by human or rabbit serum appears to reflect, therefore, the different amounts of phospholipase A(2) activity in the two sera. Phospholipid degradation is not required for the bactericidal action of serum. Bacterial phospholipid breakdown may be important, however, in the overall destruction and digestion of invading bacteria by the host.-Kaplan-Harris, L., J. Weiss, C. Mooney, S. Beckerdite-Quagliata, and P. Elsbach. The action of human and rabbit serum phospholipase A(2) on Escherichia coli phospholipids.     

Separation and purification of a potent bactericidal/permeability-increasing protein and a closely associated phospholipase A2 from rabbit polymorphonuclear leukocytes. Observations on their relationship.

Two antibacterial proteins from rabbit polymorphonuclear leukocytes, a potent bactericidal cationic protein that increases the envelope permeability of susceptible gram-negative bacteria and a phospholipase A2, have been purified to near homogeneity by ion exchange, gel filtration, and hydrophobic interaction chromatography. The apparently noncatalytic bactericidal/permeability-increasing protein has an approximate molecular weight of 50,000 and is isoelectric at pH 9.5 to 10.0. The molecular properties, including amino acid composition, and the antibacterial potency and specificity of this rabbit leukocyte protein and of the bactericidal/permeability-increasing protein from human granulocytes that we have recently purified (J. Biol. Chem. 253, 2664-2672, 1978) are closely similar. Both proteins kill several strains of Escherichia coli and Salmonella typhimurium. Rough strains are more sensitive than smooth strains. All gram-positive bacterial species tested are insensitive to high concentrations of either rabbit or human protein. The phospholipase A2, purified by hydrophobic interaction chromatography on phenyl-Sepharose, ran as a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular weight of 14,000 and had a specific enzymatic activity comparable to that of purified phospholipases A2 from other sources. Separation of the phospholipase A2 from the bactericidal/permeability-increasing protein has no noticeable effect on the bactericidal and permeability-increasing activities of the purified bactericidal protein, but removes the ability of the phospholipase A2 to hydrolyze the phospholipids of intact Escherichia coli. Upon recombination of the phospholipase A2 with the bactericidal/permeability-increasing protein, the phospholipase A2 regains its activity toward the phospholipids of intact E. coli suggesting that these two antibacterial leukocyte proteins act in concert.     

Reversible envelope effects during and after killing of Escherichia coli W by a highly-purified rabbit polymorphonuclear leukocyte fraction

The effects of a highly-purified, potently bactericidal fraction from rabbit polymorphonuclear leukocytes on the envelope of Escherichia coli (W) have been examined. This leukocyte fraction has equally enriched bactericidal, permeability-increasing and phospholipase A₂ activities, and is essentially devoid of lysozyme, myeloperoxidase and protease activities (Weiss, J., Franson, R.C., Beckerdite, S., Schmeidler, K. and Elsbach, P. (1975) J. Clin. Invest. 55, 33–42). Rapid killing of E. coli by this fraction is accompanied by two almost immediate alterations in the bacterial envelope: (1) a discrete increase in envelope permeability (measured by inhibition of bacterial leucine incorporation by normally impermeant actinomycin D), and, (2) hydrolysis of ¹⁴C-labeled fatty acid-prelabeled E. coli phospholipids. Both envelope effects are promptly reversed during further incubation at 37 °C, but not at 0 °C, with 40 mM Mg²⁺. Reversal is also produced by Ca²⁺ (40 mM) and trypsin (200 μg/ml), but 200 mM K⁺ causes only partial recovery and Na⁺ and hyperosmolar sucrose are ineffective. Upon addition of Mg²⁺, phospholipid degradation ceases abruptly and the labeled products of hydrolysis (free fatty acids and lysocompounds) disappear with a corresponding reaccumulation of radioactive diacylphosphatides. The time course of resynthesis of phospholipids coincides with that of restoration of the permeability barrier. Higher concentrations of the leukocyte fraction and prolonged incubation increase both the extent of phospholipid degradation and the time required for reversal of both envelope effects. These findings suggest that both the initiation of the increased permeability and its reversal are linked to respectively the breakdown and resynthesis of major E. coli membrane phospholipids, and thus depend on the fact that the biochemical apparatus of E. coli remains capable of biosynthesis despite loss of viability.Treatment of E. coli, exposed to the leukocyte fraction, with albumin results in extracellular sequestration of the products of hydrolysis and also restores the permeability barrier to actinomycin D, suggesting that the accumulation of lytic products of lipid hydrolysis within the bacterial envelope, rather than the loss of phospholipids per se, causes increased permeability.     

Acylation of monoacylglycerophosphoethanolamine in the inner and outer membranes of the envelope of an Escherichia coli K12 strain and its phospholipase A-deficient mutant

The site of the Escherichia coli envelope of the conversion of 1-acylglycero-3-phosphoethanolamine to diacylglycerophosphoethanolamine was explored, using two K12 strains with a wild-type phospholipid-degradative apparatus and a K12 mutant lacking detectable phospholipase A₁ and A₂ activity.Experiments with various radioactively labeled substrates show that acylation by crude envelope preparations as well as isolated inner and outer membranes of parent and mutant strains involves neither exogenous fatty acids nor a transacylation reaction with added monoacylglycerophosphoethanolamine. Furthermore, acylation exhibits no absolute requirement for added ATP and coenzyme A.Specific activity of acylating activity is the same in inner membrane preparations of parent and mutant strain and in outer membrane preparations of the mutant deficient in phospholipase A. Although clearly evident, net diacylglycerophosphoethanolamine formation by outer membranes of the parent strain, however, was about 6-fold less. This lower conversion may be attributed to activation during incubation of phospholipases A within the outer membrane, resulting in breakdown of the diacylcompound formed.Reacylation of lysophospholipids formed in the E. coli envelope by the action of endogenous or exogenous phospholipases A provides the organism with the potential of biochemically inexpensive repair and modification of the envelope phospholipids. Moreover, major phospholipids hydrolyzed in the outer membrane of E. coli can be resynthesized in the same location, without need for the transport of the products of hydrolysis to the lipid biosynthetic apparatus associated with the cytoplasmic membrane.     

Stimulation of phospholipase A2 activity by oxygen-derived free radicals in isolated brain capillaries

An exogenous free radical generating system added to isolated brain capillaries induces degradation of phospholipids. This inductive effect reflects increased phospholipase activities as measured by fatty acid composition of various phospholipid fractions. The correlation of phospholipid degradation with stimulation of phospholipases was further investigated by using cationic amphiphilic agents, which are known to be phospholipase A2 inhibitors. The breakdown of phospholipids was inhibited by the pretreatment of isolated capillaries with these drugs.     

Isolation and characterization of a phospholipase A2 from an inflammatory exudate.

Sterile peritoneal exudates produced in rabbits injected with 1% glycogen contain a phospholipase A activity in a cell-free supernatant fraction that hydrolyzed a synthetic phospholipid (1,2-diacyl-sn-glycero-3-phospho-ethanolamine) and phospholipids of autoclaved Escherichia coli. This phospholipase activity (phosphatidylacylhydrolase EC 3.1.1.4) exhibited an apparent bimodal pH optimum (pH 6.0 and pH 7.5) and was Ca(2+)-dependent; Mg(2+) and monovalent cations (Na(+) and K(+)) did not substitute for Ca(2+) in the reaction; EDTA was a potent inhibitor. The phospholipase hydrolyzed 1-[1-(14)C]palmitoyl-2-acyl-sn-glycero-3-phosphoethanolamine to form only radio-active lysophosphatidylethanolamine as the product, indicating that the enzyme had phospholipase A(2) specificity. The phospholipase A(2) was purified 302-fold by two successive chromatographic steps on carboxymethyl Sephadex. Gel filtration (Sephadex G75) of the purified enzyme resulted in a single peak of biological activity with a molecular weight of approximately 14,800. The same estimate of molecular weight was obtained by SDS-polyacrylamide gel electrophoresis, which yielded a single band. Polyacrylamide gel electrophoresis of this fraction at pH 4.3 revealed a single protein band migrating beyond lysozyme, with the dye front, suggesting that this protein was more basic than lysozyme (pI 10.5). The enzymatic and physical-chemical characteristics of this soluble enzyme were remarkably similar to a recently described phospholipase A(2) of rabbit polymorphonuclear leukocytes derived from glycogen-induced peritoneal exudates. The possible origin and physiological role of this soluble enzyme are discussed.     

Phospholipid metabolism by phagocytic cells. Phospholipases A2 associated with rabbit polymorphonuclear leukocyte granules

Polymorphonuclear leukocytes obtained from sterile peritoneal exudates in rabbits contain two phospholipid-splitting activities (phosphatidylacylhydrolases EC 3.1.1.4), one most active at pH 5.5 and the other between pH 7.2 and 9.0. Hydrolysis of phospholipid was demonstrated using Escherichia coli labeled during growth with [1-(14)C]oleate and then autoclaved to inactivate E. coli phospholipases and to increase the accessibility of the microbial phospholipid substrates. The acid and alkaline phospholipase activities are both membrane bound, calcium dependent, and heat stable, and they appear to be specific for the 2-acyl position of phospholipids. Evidence was also obtained suggesting that the E. coli envelope phospholipids with oleate in position 2 are more readily degraded than those with palmitate. The two activities are associated with azurophilic as well as specific granules (obtained by zonal centrifugation) and with phagosomes (isolated after ingestion of paraffin particles by the granulocytes). Phospholipase A activities at pH 5.5 and pH 7.5 degrade the two major phospholipids of E. coli, phosphatidylethanolamine and phosphatidylglycerol, to the same extent, but the phospholipase activity at acid pH does not hydrolyze micellar dispersions of phosphatidylethanolamine. By contrast, phospholipase A(2) activity at pH 7.5 degrades both types of phosphatidylethanolamine substrates. Heparin and chondroitin sulfate inhibit phospholipase activity at pH 5.5 but have little effect on activity at pH 7.5. All detergents tested inhibited phospholipase activity, and both activities are inhibited by reaction products, free fatty acid and lysophosphatidylethanolamine. This product inhibition is only partially prevented by addition of albumin. Supernatant fractions of granulocyte homogenates contain a heat-labile inhibitor of granule phospholipase activity at pH 7.5. Boiling the fraction not only removes the inhibition but actually results in stimulation of hydrolysis at pH 7.5 as well as pH 5.5. These granule-associated phospholipase A activities of polymorphonuclear leukocytes differ in several of their properties from granule or lysosomal phospholipases of other phagocytic cells.     

1-14C]oleate-labeled autoclaved yeast: a membranous substrate for measuring phospholipase A2 activity in vitro

Radiolabeled, autoclaved yeast were tested as a substrate for mammalian phospholipase A2 activity because the only other membranous substrate used for this purpose, autoclaved Escherichia coli, totally lacks a major mammalian phospholipid, phosphatidylcholine. Candida albicans were grown in the presence of [1-14C]oleate and then autoclaved. Sixty three percent of the incorporated label was in yeast phospholipid, and more than 95% of that was in the 2-acyl position. The distribution of label in the yeast phospholipids (phosphatidylcholine and -ethanolamine, -serine + -inositol, and phosphatidic acid corresponded closely to the chemical distribution of phosphorus in those phospholipids. Snake venom (Naja naja) and human synovial fluid phospholipase A2 hydrolyzed yeast phospholipid exclusively to release 14C-labeled fatty acid. When 50-60% of the yeast phospholipid was hydrolyzed, the radioactive fatty acids as determined by gas-liquid chromatographic analysis were predominantly oleate (45%) and linoleate (greater than 54%). Hydrolysis of yeast phospholipid by both enzymes was near-linear with protein and time under conditions of optimal pH (neutral-alkaline) and Ca2- (1-5 mM) previously reported for optimal hydrolysis of autoclaved E. coli phospholipid. N. naja phospholipase A2 showed less preference for phosphatidylethanolamine than -choline as liposomes or yeast phospholipid as compared to human synovial fluid phospholipase A2 which clearly preferred phosphatidylethanolamine to -choline as a liposome or yeast phospholipid. These results illustrate that radiolabeled phospholipids of autoclaved yeast, enriched in phosphatidylcholine, are readily hydrolyzed by snake venom and human nonpancreatic phospholipases A2 and may, therefore, be useful in the measurement of in vitro enzymatic activity.     

Relation between binding and the action of phospholipases A2 on Escherichia coli exposed to the bactericidal/permeability-increasing protein of neutrophils

Exposure of Escherichia coli to the bactericidal/permeability-increasing protein (BPI) of neutrophils renders the bacterial phospholipids susceptible to hydrolysis by only a few of numerous phospholipases A2 tested. To explore further the determinants of hydrolysis we measured the binding of 125I-labeled phospholipase A2 to E. coli in the presence and absence of BPI. Phospholipases A2 from Aqkistrodon piscivorus piscivorus venom and pig pancreas neither degraded nor bound to BPI-treated E. coli. In contrast, the phospholipases A2 from Aqkistrodon halys blomhoffii and Aqkistrodon halys palas venoms actively hydrolyzed the phospholipids of BPI-treated E. coli: they also bound to E. coli in the presence but not in the absence of BPI. Carbamylation of lysines of the A.h. blomhoffii phospholipase A2 progressively reduced binding in parallel with reduced phospholipid hydrolysis. Both binding and hydrolysis increased with increasing BPI dose. However, maximal binding occurred at 25% of the BPI dose that produced optimal hydrolysis. Thus, binding may be necessary but is not sufficient for maximal BPI-mediated phospholipid hydrolysis. Comparison of the NH2-terminal amino sequences of the active and inactive phospholipase A2 suggests that this portion of the phospholipase A2 molecule plays a role in BPI-independent binding and hydrolysis.     

Structural and functional properties of a phospholipase A2 purified from an inflammatory exudate

The cell-free supernatant of sterile inflammatory peritoneal exudates contains a phospholipase A2 that participates in the digestion of Escherichia coli killed by polymorphonuclear leukocytes or by the purified bactericidal/permeability increasing protein (BPI) of these cells. This phospholipase A2 has been purified, and the sequence of the NH2-terminal 39 amino acids has been determined and compared with sequences of both BPI-responsive and BPI-nonresponsive phospholipases A2 from snake venoms and mammalian pancreas. The high concentration and location of basic residues in the NH2-terminal region is a common feature of BPI-responsive phospholipases A2 and may characterize those phospholipases A2 participating in inflammatory events.     

Effect of ethylenediaminetetraacetate on phospholipids and outer membrane function in Escherichia coli.

Treatment of Escherichia coli K-12 strain S15, containing a normal amount of phospholipase A, with ethylenediaminetetraacetate (EDTA) resulted in an increase in sensitivity of the organism to actinomycin D. Strain S17, a mutant deficient in both detergent-resistant phospholipase A and detergent-sensitive phospholipase A, was considerably less sensitive to the antibiotic after the treatment. Both strains released lipopolysaccharide after EDTA treatment, indicating that this outer membrane component alone is not the barrier to actinomycin in these organisms. The phospholipase A-deficient strain released less alkaline phosphatase, a periplasmic enzyme. EDTA treatment of S15 resulted in the accumulation of free fatty acids, indicative of phospholipase A activation. Cells briefly treated with EDTA regained the barrier to actinomycin when incubated in growth media, and the cessation of the accumulation of free fatty acids was in approximate temporal agreement with restoration of the barrier. Cells in which phospholipase A was activated by brief exposure to EDTA synthesized relatively more phosphatidylethanolamine than did untreated cells in the initial period after dilution into growth media. These experiments suggest that the EDTA-induced loss of outer membrane barrier function of E. coli K-12 is mediated through the activation of phospholipase A.     

The phospholipid-dependence of uridine diphosphate glucuronyltransferase. Reactivation of phospholipase A-inactivated enzyme by phospholipids and detergents

Specific degradation of the phospholipid membrane of guinea-pig liver microsomal fraction with phospholipase A inactivated glucuronyltransferase. The inactivation was reversed by phosphatidylcholine and mixed microsomal phospholipid micelles at concentrations similar to those present in intact microsomal preparations. The other commonly occurring phospholipids did not reactivate phospholipase A-treated enzyme. Since the mixed microsomal phospholipids consisted mainly of phosphatidylcholine, it is concluded that the reactivation by phospholipids is phosphatidylcholine-specific. Reactivation was also achieved by low concentrations of the cationic detergents cetylpyridinium chloride and cetyltrimethylammonium bromide. Higher concentrations of these detergents inactivated the glucuronyltransferase activity of intact and phospholipase A-treated microsomal fractions. Anionic detergents were potent inactivators of the glucuronyltransferase activity of untreated and phospholipase A-treated microsomal fractions, whereas non-ionic detergents had little effect on the activity of either preparation. Measurements of the zeta-potentials of the micellar species used in this study showed that no obvious relationship existed between the zeta-potentials and the ability to reactivate glucuronyltransferase. However, high positive or negative zeta-potentials were correlated with the ability of the amphipathic compound to inactivate glucuronyltransferase.     

Purification and characterization of an a type phospholipase from potato and its effect on potato mitochondria

A potato (Solanum tuberosum) phospholipid acyl-hydrolase, which - in the pH range 7.5 to 8.5—is at least 10,000 times more effective with phospholipids than with galactolipids, has been purified and characterized. It is a soluble enzyme readily distinguished from a neutral lipid lipase and a third lipid acyl-hydrolase which, while acting on phospholipid, shows a decided preference for glyceryl monoolein. The phospholipase in question has a pH optimum of 8.5, is stimulated by Ca²⁺ at pH above 7.5 and inhibited by Ca²⁺ at lower pH, is not dependent on detergents although stimulated by Triton X-100 to a moderate extent, and remains very active at temperatures close to zero. The phospholipids of intact potato mitochondria are highly susceptible to degradation by potato phospholipase, and it is suggested that this enzyme is involved in the extensive lipid breakdown which occurs in fresh potato slices following cutting, and in the deterioration of mitochondria during their preparation and aging.     

Protection from nonfreezing cold injury by quinacrine, a phospholipase inhibitor

A recent study from our laboratory indicated additional tissue injury during rewarming of a cooled rabbit leg. Oxygen-derived free radicals were believed to play a role in such "rewarming injury." Since free radicals may attack membrane phospholipids, we analyzed the phospholipid composition in the leg tissue during cooling and rewarming. Our results indicated significant breakdown of membrane phospholipids, particularly phosphatidylcholine and phosphatidylethanolamine, with a corresponding accumulation of lysophosphatidylcholine and nonesterified fatty acids. Quinacrine, a phospholipase inhibitor, was able to preserve membrane phospholipids during rewarming of the cooled leg. Rewarming of cooled tissue was also accompanied by additional tissue injury, as evidenced by the increased release of lactic acid dehydrogenase and creatine kinase, as well as enhanced lipid peroxidation, as evidenced by increased malonaldehyde formation. Quinacrine reduced the release of these intracellular enzymes and decreased lipid peroxidation, suggesting its efficacy as a therapeutic agent against hypothermic injury.     

Phospholipid transfer proteins: Mechanism of action

Phospholipid transfer proteins are generally localized in the cytosolic fraction of cells and are capable of catalyzing the flux of phospholipid molecules among membranes. Artificial membranes also participate in protein-catalyzed phospholipid movements. In this review the major phospholipid transfer proteins are discussed with respect to their phospholipid substrate specificity and the contributions of membrane physical properties to this process. The phenomenon of net transfer of phospholipids is described. The use of various kinetic approaches to the study of these catalysts is reviewed. A detailed consideration of the distinct phospholipid binding and membrane interaction domains of one phospholipid transfer protein is presented. Finally, some recent applications of phospholipid transfer proteins to the examination of membrane structure and function and further directions for the continued research activity with this class of proteins are summarized.     

Origin and fate of the lysophosphatidylethanolamine in a chain-forming mutant (envC) of Escherichia coli

The role of phospholipid metabolism in the functioning of the bacterial envelope was investigated in the chain-forming Escherichia coli envC. Lysophosphatidylethanolamine (LPE) which accumulated in this strain during growth was identified as the product of phosphatidylethanolamine (PE) hydrolysis by a phospholipase A1, i.e. 2-acylLPE. Isotopically labelled LPE transferred into intact mutant and parent cells by liposome/bacteria interaction was rapidly reacylated to PE. However, in envC the final PE/LPE ratio was lower than that in the parent, thus showing that the fate of LPE is modified. Crude cell extracts degraded LPE to a lesser extent in envC than in the parent but were unable to promote reacylation activity under our experimental conditions. In both strains, the lysophospholipase activity was neither calcium-dependent nor inhibited by the SH-group inhibitors pHMB or pCMPS, and hydrolysed 1-acylLPE as well as 2-acylLPE. These results indicate the existence of a deacylation-reacylation cycle in E. coli and show that this cycle is perturbed in envC cells, especially at the lysophospholipase step.     

Amino acid sequence of a basic Agkistrodon halys blomhoffii phospholipase A2. Possible role of NH2-terminal lysines in action on phospholipids of Escherichia coli

A basic (pI = 10.2) phospholipase A2 of the venom of the snake Agkistrodon halys blomhoffii is one of a few phospholipases A2 capable of hydrolyzing the phospholipids of Escherichia coli killed by a bactericidal protein purified from human or rabbit neutrophil granules. We have shown that modification of as many as 4 mol of lysine per mole of the phospholipase A2, either by carbamylation or by reductive methylation [Forst, S., Weiss, J., & Elsbach, P. (1982) J. Biol. Chem. 257, 14055-14057], had no effect on catalytic activity toward extracted E. coli phospholipids or the phospholipids of autoclaved E. coli. In contrast, modification of 1 mol of lysine per mole of enzyme substantially reduced activity toward the phospholipids of E. coli killed by the neutrophil protein. To explore further the role of lysines in the function of this phospholipase A2, we determined the amino acid sequence of the enzyme and the incorporation of [14C]cyanate into individual lysines when, on average, 1 lysine per molecule of enzyme had been carbamylated. After incorporation of approximately 1 mol of [14C]cyanate per mole of protein, the phospholipase A2 was reduced, alkylated, and exhaustively carbamylated with unlabeled cyanate. The amino acid sequence was determined of the NH2-terminal 33 amino acids of the holoprotein and of peptides isolated after digestion with trypsin and Staphylococcus aureus V-8 protease. The protein contains 122 amino acid residues, 17 of which are lysines. The NH2-terminal region is unique among more than 30 phospholipases A2 previously sequenced because of its high content of basic residues (His-1, Arg-6, and Lys-7, -10, -11, and -15).(ABSTRACT TRUNCATED AT 250 WORDS)     

Increased expression of phospholipase D1 in the brains of scrapie-infected mice

Mitochondrial dysfunction and free radical-induced oxidative damage are critical factors in the pathogenesis of neurodegenerative diseases. Recently, phospholipid breakdown by phospholipase D (PLD) has been recognized as an important signalling pathway in the nervous system. Here, we examined the expression of PLD and alteration of membrane phospholipid in scrapie brain. We have found that protein expression and enzyme activity of PLD1 were increased in scrapie brains compared with controls; in particular, there was an increase in the mitochondrial fraction. PLD1 in mitochondrial membranes from scrapie brains, but not from control brains, was tyrosine phosphorylated. Furthermore, the concentration of mitochondrial phospholipids such as phosphatidylcholine and phosphatidylethanolamine was increased and the content of phosphatidic acid, a product of PLD activity, was up-regulated in the mitochondrial membrane fractions. Immunohistochemically, PLD1 immunoreactivity was significantly increased in activated astrocytes in both cerebral cortex and hippocampus of scrapie brains. Taken together, these results suggest that PLD activation might induce alterations in mitochondrial lipids and, in turn, mediate mitochondrial dysfunction in the brains of scrapie-infected mice.     

Characterization of the interaction of phospholipase A(2) with phosphatidylcholine-phosphatidylglycerol mixed lipids

The first requirement in the hydrolysis of phospholipid bilayers by phospholipase A(2) is the interaction of the enzyme with the bilayer surface. The catalytic ability of phospholipase A(2) has been shown to be extremely sensitive to the topology of the bilayer to which it binds and hydrolyzes. Phospholipid bilayer properties and composition such as unsaturation, charge, and the presence of reaction products are known regulators of the catalytic activity of phospholipase A(2) toward the phospholipids and influences the binding of enzyme to the membrane. We show in this paper that the effect of increased anionic lipid results in enhanced binding that can be described quantitatively in terms of a simple phenomenological model. However, the interaction with anionic lipid does not singularly dominate the thermodynamics of binding, nor can the lag phase observed in the time course of hydrolysis of large unilamellar vesicles simply be the result of limited interaction between the enzyme and the bilayer. Furthermore, we show that phospholipase A(2) from Akgistrodon piscivorus piscivorus can exist in at least two bilayer-bound states and that the absence of a fluorescence change upon mixing the enzyme with lipid bilayers does not necessarily indicate the absence of an interaction.