Faculty Bibliography

Tissues of prostatic origin representing variable phenotypes were tested for reactivity to the prostate cancer specific mouse monoclonal antibody PD-41. Avidin biotin immunoperoxidase was applied on formalin-fixed, paraffin-embedded tissue sections of 15 benign prostatic hyperplasia (BPH), 23 prostatic intraepithelial neoplasia (PIN), 14 untreated primary adenocarcinoma, 35 diethylstilbestrol (DES) treated tumors, 50 lymph node and 11 bone metastases. Specimens were stratified according to the percentage of tumor cells expressing PD-41 antigen and degree of staining intensity, and correlated with PIN grade, Gleason score, flow cytometry (FCM) measured DNA ploidy, and reactivity to other antibodies. In PIN, 4 specimens (17.4%) showed reactivity in a significant number of cells while a few cells were reactive in most cases. PD-41 was significantly reactive (>5% of tumor cells) in 88% of nodal metastases and in 73% of bone metastases in contrast to 49% reactivity in primary tumors (p=0.0003). There was a tendency of increased antigen expression in hormonally treated primary tumors. In addition, involutional and metaplastic changes in hormonally treated cases were reactive in many instances. Semi-quantitative evaluation of PD-41 reactivity showed a statistically significant correlation with Gleason score in primary tumors (p=0.007) and in lymph node metastases (p=0.009). Moreover, the PD-41 antibody reacted in metastatic lesions that failed to express both prostatic acid phosphatase and prostate specific antigen. These data suggest that monoclonal antibody PD-41 merits further investigation to evaluate its potential diagnostic, prognostic and therapeutic role in prostate cancer

Phospholipases A2 (PLA-2) are conserved enzymes that can vary widely in their activity toward certain biological targets. Activity of PLA-2 toward Escherichia coli treated with the bactericidal/permeability-increasing protein (BPI) of granulocytes has been detected only in 'Group II' PLA-2 (lacking Cys11-Cys77) and correlates with overall basicity and the presence of a cluster of basic amino acids within a variable surface region near the NH2 terminus (including residues 6, 7, 10, 11, and 15). We now show that of five pancreatic PLA-2 ('Group I' enzymes) tested from different species of mammals, the human enzyme that is most basic both globally (pI 8.7) and locally (Arg-6, Lys-7, and Lys-10) is active toward BPI-treated E. coli (approximately 1-2% activity of the most active Group II PLA-2) whereas the other four PLA-2 are essentially inactive (less than 0.1%). The cDNA of the pig pancreatic PLA-2 (pI 6.4; Arg-6, Ser-7, Lys-10) has been modified by site-specific mutagenesis and the wild-type and mutant PLA-2 have been expressed in and purified from either E. coli or Saccharomyces cerevisiae to determine more precisely the structural determinants of PLA-2 activity toward BPI-treated E. coli. The single substitution of lysine (or arginine) for Ser-7 transformed the pig pancreatic PLA-2 into an active enzyme toward BPI-treated E. coli possessing 25-50% the activity of the human PLA-2. Additional modifications to increase global basicity (increase in net charge up to +4) caused a further (up to 2-fold) increase in activity. All mutant PLA-2 still containing Ser-7 possessed little or no activity toward BPI-treated E. coli. Changes in activity toward BPI-treated E. coli were accompanied by parallel changes in enzyme binding to this target. In contrast, substitution of lysine (or arginine) for Ser-7 caused little or no alteration of enzyme activity toward either autoclaved E. coli or egg yolk lipoproteins indicating no major effects on the catalytic properties of the PLA-2. This study demonstrates directly the role of NH2-terminal basic residues in the action of PLA-2 on BPI-treated E. coli and suggests that these properties mainly facilitate PLA-2 binding to this biological target

Escherichia coli ingested by PMN are promptly growth arrested but undergo limited destruction. We have studied bacterial phospholipid hydrolysis as a possible limiting factor in the disassembly of ingested E. coli, comparing the fates, during phagocytosis by rabbit peritoneal exudate PMN, of three isogenic strains, differing in their content of the pldA gene encoding the principal E. coli phospholipase A (PLA), i.e., pldA-, pldA+, pldA (the latter strain bearing the pldA gene in a multicopy plasmid resulting in a 20-fold increase in PLA content). Ingestion and growth inhibition (greater than 99% within 15 min) were the same for the three strains, but phospholipid degradation differed according to bacterial PLA content: pldA up to 60%, pldA+ up to 30%, and pldA- up to 20%. Since the pldA- strain has no activatable PLA, phospholipid degradation in this strain demonstrates the action of a PMN PLA. Added PLA2-rich ascitic fluid (AF) or purified AF PLA2 increased the rate and extent of degradation of the pldA- strain, provided the enzyme was added before ingestion was complete. 125I-AF-PLA2 binds to both E. coli and PMN and thus can enter the vacuole during phagocytosis. Although up to 50-fold more AF-PLA2 than the PLA2 content of the PMN could be loaded into the PMN in this way, degradation of pldA- E. coli did not exceed 30%. Increased phospholipid degradation had no effect on the degradation of bacterial macromolecules. In contrast, bacterial disassembly manifest as structural disorganization, release of bacterial protein derived material, and inhibition of protein synthesis were markedly enhanced when greater than 50% of prelabelled bacterial phospholipids were degraded. These findings reveal a link between envelope phospholipid degradation and overall bacterial destruction, suggesting therefore that factors limiting PLA action limit the destruction of E. coli ingested by PMN

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