The antibacterial properties of secreted phospholipases A(2).

There is a considerable body of evidence to support the antibacterial properties of the group IIa phospholipase A(2) as an important physiological function. This enzyme is able to act as an acute phase protein and may be part of the innate defence system of the body, acting in concert with other antibacterial proteins and peptides. The enzyme is most effective against Gram-positive bacteria whereas penetration of the lipopolysaccharide coat of Gram-negative bacteria requires bactericidal/permeability-increasing protein (BPI) as an additional permeabilizing factor. The global cationic nature of this protein (pI>10.5) appears to facilitate penetration of the anionic bacterial cell wall. In addition, the considerable preference of the enzyme for anionic phospholipid interfaces provides specificity toward anionic bacterial membranes as opposed to zwitterionic eucaryotic cell membranes.

Bacterial cell membrane hydrolysis by secreted phospholipases A(2): a major physiological role of human group IIa sPLA(2) involving both bacterial cell wall penetration and interfacial catalysis.

The ability of human group IIa secreted phospholipase A(2) (human sPLA(2)) to hydrolyse the phospholipid membrane of whole cell suspensions of Gram-positive bacteria is demonstrated in real time using a continuous fluorescence displacement assay. Micrococcus luteus is used as a model system and demonstrates an almost absolute specificity for this human enzyme compared with porcine pancreatic and Naja naja venom sPLA(2)s. This specificity is due to selective penetration of the highly cationic human sPLA(2)50%) phospholipid hydrolysis was observed and this was confirmed by electrospray mass spectrometry that allowed the identification of several molecular species of phosphatidylglycerol as the targets for hydrolysis. However, the bactericidal activity of the human enzyme under these assay conditions was low, highlighting the capacity of the organism to survive a major phospholipid insult. In addition to pure enzyme, the human sPLA(2) activity in tears was demonstrated using M. luteus as substrate. In comparison to M. luteus, cell suspensions of Staphylococcus aureus were highly resistant to hydrolysis by human sPLA(2) as well as to the pancreatic and venom enzymes. Treatment of this organism with the specific cell wall protease lysostaphin resulted in a dramatic enhancement in cell membrane phospholipid hydrolysis by all three sPLA(2)s. Overall, the results highlight the potential of the human sPLA(2) as a selective antimicrobial agent against Gram-positive bacteria in vivo because this enzyme is essentially inactive against mammalian plasma membranes. However, the enzyme will be most effective in combination with other antimicrobial agents that enhance the permeability of the bacterial cell wall and where potentiation of the effectiveness of other antibiotics would be expected.

Monoacylglycerol binding to human serum albumin: evidence that monooleoylglycerol binds at the dansylsarcosine site.

The binding of monoacylglycerides of long-chain fatty acids to human serum albumin has been examined using monooleoylglycerol as the ligand. Binding was investigated using changes in tryptophan fluorescence and also the displacement of a variety of well-studied fluorescent ligands from human serum albumin (HSA). Monooleoylglycerol caused a decrease in fluorescence from tryptophan-214 when measured at 350 nm while oleic acid had no effect on fluorescence at this wavelength and did not compete with monooleoylglycerol. In contrast, oleic acid caused an increase in fluorescence at 330 nm whereas monooleoylglycerol did not affect fluorescence intensity at this wavelength. These results suggest that these two ligands do not bind to the same site on HSA. From competition studies using dansylglycine, dansylsarcosine, 11-(dansylamino)-undecanoic acid and 1-anilino-8-naphthalenesulfonic acid it was proposed that monooleoylglycerol binds at the dansylsarcosine site (site II) of HSA. Monooleoylglycerol was a competitive inhibitor of dansylsarcosine binding with a Kd of about 2.5 microM whereas oleic acid was not competitive with dansylsarcosine binding.

Inhibition of secreted phospholipases A2 by annexin V. Competition for anionic phospholipid interfaces allows an assessment of the relative interfacial affinities of secreted phospholipases A2.

The ability of annexins, particularly annexin 1 (lipocortin 1), to inhibit phospholipase A2 (PLA2) is well known and a substrate depletion mechanism is now widely accepted as the explanation for most inhibitory studies. In this investigation we have examined the substrate depletion mechanism of annexin V using a variety of phospholipid substrates and secreted PLA2's (sPLA2). The results suggest that the term interfacial competition best describes the inhibitory effect of annexin V although the overall inhibitory process remains one of substrate sequestration by the annexin. We have utilised the competitive nature of the interaction of enzyme and annexin V for a phospholipid interface as a means of quantifying the relative affinity of sPLA2's for anionic phospholipid vesicles. The results highlight the very high affinity of the human non-pancreatic sPLA2 for such vesicles (Kd<<10-(10) M) while the Naja naja venom PLA2 and porcine pancreatic sPLA2 showed lower affinities. Hydrolysis of mixed vesicles containing phosphatidylserine and phosphatidylcholine by the venom and pancreatic enzymes were differentially inhibited by annexin V. This difference must reflect the preference of both annexin V and the pancreatic enzyme for an anionic phospholipid interface. In contrast, the venom enzyme is able to readily hydrolyse phosphatidylcholine domains that would be minimally affected by annexin V. Annexin V was an effective inhibitor of cardiolipin hydrolysis by the pancreatic PLA2, however the inhibition was of a more complex nature than seen with other phospholipids tested. Overall the results highlight the ability of annexin V to inhibit phospholipid hydrolysis by sPLA2's by an interfacial competition (substrate depletion) mechanism. The effectiveness of annexin V as an apparent inhibitor depends on the nature of the enzyme and the phospholipid substrate.

Cardiolipin hydrolysis by human phospholipases A2. The multiple enzymatic activities of human cytosolic phospholipase A2.

The ability of mammalian phospholipases A2 (PLA2) to hydrolyse cardiolipin (diphosphatidylglycerol) was monitored with a fluorescent displacement assay which allows the use of natural phospholipid substrates. The mammalian enzymes used were porcine pancreatic (Group I) secretory PLA2 (sPLA2), human non-pancreatic (Group II) sPLA2 and human cytosolic PLA2 (cPLA2). High activity was observed with porcine pancreas sPLA2 whereas the human sPLA2 demonstrated only minimal activity with this substrate. In comparison, sPLA2 from Naja naja venom (Group I) also showed only modest activity with this substrate. Since many lipases possess PLA1 activity, a representative enzyme from Rhizopus arrhizus was also assessed for its ability to hydrolyse cardiolipin which proved to be a good substrate for this fungal lipase. In all cases dilysocardiolipin was the major product while some monolyso intermediate was detected after chromatographic separation. Human cPLA2 was unable to hydrolyse cardiolipin at a significant rate, however, both monolysocardiolipin and dilysocardiolipin, which are prepared by the PLA2-catalysed hydrolysis of cardiolipin, were good substrates providing a further example of the extensive lysophospholipase activity of this enzyme. Moreover, cardiolipin that was initially hydrolysed in situ with either excess porcine pancreatic PLA2 or R. arrhizus lipase (PLA1) was subsequently hydrolysed by human cPLA2. One explanation of this result is that human cPLA2 is able to hydrolyse both 1-acyl and 2-acyl-lysophospholipids. (c) 1998 Elsevier Science B.V.

Inhibition of human cytosolic phospholipase A2 by human annexin V.

The ability of annexins, particularly annexin 1 (lipocortin 1), to inhibit phospholipase A2 (PLA2) is well known and a substrate depletion mechanism is now widely accepted as the explanation for most inhibitory studies. However, there are only a very limited number of reported studies involving annexins and the high-molecular-mass cytosolic PLA2 (cPLA2). In this study we have examined the effect of human recombinant annexin V, a potentially abundant cytosolic protein, on the ability of human recombinant cPLA2 to hydrolyse a variety of phospholipid substrates. The results show clearly that, under the conditions of our study, annexin V can inhibit cPLA2 activity by a mechanism of substrate depletion and that this inhibition is dependent on the nature of the phospholipids and the concentration of Ca2+ ions in the assay. The hydrolysis of 1-stearoyl 2-arachidonyl phosphatidylcholine by cPLA2 was not significantly affected by annexin V over a range of Ca2+ concentrations (1 microM-2.5 mM), a result that presumably reflects the zwitterionic nature of the phospholipid and the known inability of annexins to bind to such interfaces. In contrast, the hydrolysis of dioleoyl phosphatidylglycerol, which is an effective anionic phospholipid substrate for this enzyme, and more significantly that of 1-stearoyl 2-arachidonyl phosphatidic acid, were readily inhibited by annexin V, although these effects were Ca2+-dependent. The Ca2+ concentrations required for inhibition in the assay system in vitro are greater than those associated with Ca2+-stimulated events within the cell, suggesting that a role for annexin V in regulating cPLA2 activity might not involve a substrate depletion mechanism in vivo unless factors in addition to Ca2+ and phospholipids contribute to the binding of annexin V to cell membranes.