Phospholipase Reaction

Although extraction of lipids from membranes can be induced in atomic force apparatus (Leckband et al., 1994) and biomembrane force probe (Evans et al., 1991) experiments, spontaneous dissociation of a lipid from a membrane occurs very rarely because it involves an energy barrier of about 20 kcal/mol (Cevc and Marsh, 1987). However, lipids are known to be extracted from membranes by various enzymes. One such enzyme is phospholipase A2 (PLA2), which complexes with membrane surfaces, destabilizes a phospholipid, extracts it from the membrane, and catalyzes the hydrolysis reaction of the srir2-acyl chain of the lipid, producing lysophospholipids and fatty acids (Slotboom et al., 1982 Dennis, 1983 Jain et al., 1995). SMD simulations were employed to investigate the extraction of a lipid molecule from a DLPE monolayer by human synovial PLA2 (see Eig. 6b), and to compare this process to the extraction of a lipid from a lipid monolayer into the aqueous phase (Stepaniants et al., 1997). 

Phosphatidylcholine Apply phospholipase C solution as a band, dry, apply sample solution to enzyme band, stop reaction with hydrochloric acid vapor. sn-l,2-Digly-cerides are produced. [43]... 

LY311727 is an indole acetic acid based selective inhibitor of human non-pancreatic secretory phospholipase A2 (hnpsPLA2) under development by Lilly as a potential treatment for sepsis. The synthesis of LY311727 involved a Nenitzescu indolization reaction as a key step. The Nenitzescu condensation of quinone 4 with the p-aminoacrylate 39 was carried out in CH3NO2 to provide the desired 5-hydroxylindole 40 in 83% yield. Protection of the 5-hydroxyl moiety in indole 40 was accomplished in H2O under phase transfer conditions in 80% yield. Lithium aluminum hydride mediated reduction of the ester functional group in 41 provided the alcohol 42 in 78% yield. 

Hormonal factors and other stimuli by activating phospholipase C-(3 or -y isoforms stimulate the breakdown of phosphatidylinositol 4,5-bisphosphate to inositol 1,4,5-trisphosphate and diacylglycerol, a reaction called PI response. 

Figure 45-6. Interaction and synergism between antioxidant systems operating in the lipid phase (membranes) of the cell and the aqueous phase (cytosol). (R-,free radical PUFA-00-, peroxyl free radical of polyunsaturated fatty acid in membrane phospholipid PUFA-OOH, hydroperoxy polyunsaturated fatty acid in membrane phospholipid released as hydroperoxy free fatty acid into cytosol by the action of phospholipase Aj PUFA-OH, hydroxy polyunsaturated fatty acid TocOH, vitamin E (a-tocopherol) TocO, free radical of a-tocopherol Se, selenium GSH, reduced glutathione GS-SG, oxidized glutathione, which is returned to the reduced state after reaction with NADPH catalyzed by glutathione reductase PUFA-H, polyunsaturated fatty acid.)...

Immunologic abnormahties (eg, transfusion reactions, the presence in plasma of warm and cold antibodies that lyse red blood cells, and unusual sensitivity to complement) also fall in this class, as do toxins released by various infectious agents, such as certain bacteria (eg, Clostridium). Some snakes release venoms that act to lyse the red cell membrane (eg, via the action of phospholipases or proteinases). 

Prior to being able to study the function and mechanism of an enzyme, it is essential that suitable assays be available to monitor enzyme activity toward different substrates and to determine the kinetic parameters kcat and Km for the reactions. A brief overview of the known assays for the evaluation of PLCB(. activity is thus appropriate. The ideal assay for a phospholipase C would utilize a phospholipid substrate, not an analogue with a modified headgroup or side chains. Such an assay should be sensitive to minimize the quantities of enzyme and substrates that would be required, and it should be convenient to implement so that analyses may be readily performed. 

Hough E, Hansen S (1994) Structural aspects of phospholipase C from Bacillus cereus and its reaction mechanism. In Woolley P, Petersen SB (eds) Lipases. Their structure, biochemistry and application. University Press, Cambridge, Cambridge, p 95... 

Phosphoinositase C (i.e. phosphoinositide-specific phospholipase C [PLC]) enzymes are found in the vast majority of mammalian cells. Molecular cloning of these enzymes, analysis of their predicted amino acid sequences and immunological cross-reactivity indicate that at least three major forms of the enzyme exist PLC-/I, -8 and -y. Each of these enzyme types is encoded by a distinct gene. More recent experiments using the polymerase chain reaction and molecular cloning have revealed even greater enzyme di-... 

Figure 6.16. Hydrolysis of phosphatidylcholine by phospholipase A2. This reaction yields two important products arachidonic acid and lyso-PAF.

Methods used to demonstrate the existence of membrane phospholipid asymmetry, such as chemical labelling and susceptibility to hydrolysis or modification by phospholipases and other enzymes, are rmsuitable for dynamic studies because the rates of chemical and biochemical reactions are of a different order compared to the transmembrane translocahon of the phospholipids. Indirect methods have therefore been developed to measure the translocation rate which are consequent on the loss of membrane phospholipid asymmetry. Thus time scales appropriate to rates of lipid scrambling under resting conditions or when the forces preserving the asymmetric phospholipid distribution are disturbed can be monitored. Generally the methods rely on detecting the appearance of phosphatidylserine on the surface of cells. Methods of demonstrating Upid translocation in mammalian cells has been the subject of a recent review (Bevers etal., 1999). 

The principle underlying such a messenger system is discussed in Chapters 3 and 12.) The flux-generating step is the reaction catalysed by the phospholipase indicated by the broader arrow in the above sequence. 

Enzyme Ei is the phospholipase A, for which there is an excess of substrate in the plasma membrane i.e. a zero order process. (Eor details of this process, see Chapter 11). E, is a phosphatase, which catalyses a first order process. In fact, IP2 can be hydrolysed to produce IPi which is further hydrolysed to produce free inositol. The latter is salvaged by using it to re-form phosphatidylinositol in the phospholipid synthetic pathway and then phosphorylated to prodnce PIP2 (Chapter 11, Eigure 11.21). These reactions are not jnst of biochemical interest bnt are involved in the treatment of bipolar disease a mental disorder. 

Figure 12.19 Phosphatidylinositol bisphosphate cycle and treatment of bipolar disease. The metal ion lithium inhibits inositol monophosphate phosphatases and, therefore, inhibits the flux from IP3 to inositol, so that the concentration of the latter decreases. This can restrict formation of phosphatidylinositol the bisphosphate (PIP ) so that the amount in the membrane decreases and the phospholipase no longer catalyses a zero order reaction. The extent of the decrease in the IP3 concentration will depend on how far the process is removed from zero order. This may explain the well-known variability in the response of patients to lithium which is probably dependent on the patient taking the precise dose of the drug (Chapter 14).

In summary, the release of nenrotransmitter from a presynaptic neurone into a synaptic cleft occurs via the process of exocytosis, which is regulated by the increase in Ca " ion concentration in the presynaptic terminal. The increase in Ca " ion concentration is achieved by release of Ca " ions by opening of the Ca ion channel in the endoplasmic reticulum, which is controlled by the concentration of IP3. Failure to release inositol from the inositol phosphates reduces the free inositol concentration, which interferes in the synthesis of PIP2. The phospholipase no longer catalyses a zero order reaction. Consequently, sufficient IP3 to activate the ion channel is released in the presynaptic neurone, so that less nenrotransmitter is released into the synaptic cleft (Figure 12.19). 

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