Deacylating phospholipases play essential roles in numerous biological events, requiring tight control of hydrolytic activity. Most cells, unless stimulated or perturbed, exhibit little phospholipid turnover. Activation of phospholipases A (PLA) is usually triggered by membrane perturbing conditions or agents. Some activators indiscriminately activate any PLA, others are highly specific. Our studies concern an activator that is a potent bactericidal protein with membrane-perturbing properties, isolated from polymorphonuclear leukocytes (PMN), that is only cytotoxic for gram-negative bacteria and primarily responsible for the fate of several gram-negative bacterial species, ingested and killed by the PMN. It is this protein that activates the hydrolysis of the phospholipids of the killed bacteria (E. coli) by three PLA: 1) an E. coli PLA, the pldA gene product; 2) a PLA2 of PMN; 3) a soluble PLA2 in the extracellular fluid of an inflammatory exudate. However, this activator protein does not trigger the action of many other PLA2, all members of a highly conserved class of PLA. Our structural studies (including genetic engineering) of both responsive and non-responsive PLA2 have revealed that the amino acid composition and sequence of the NH2-terminal alpha-helix of the PLA2 molecule are major determinants of the ability of the PMN protein to activate a given PLA2. Our results provide another demonstration that these important enzymes have diverged during evolution to perform different biological functions.