Ronald J. Hessler scite author profile

American Journal of Physiology-Cell Physiology

Smolen

Transue

et al. 1997

Phospholipase D (PLD) activation in stimulated neutrophils results in the conversion of membrane phosphatidylcholine (PC) to phosphatidic acid (PA). This change in membrane phospholipid composition has two potentially positive effects on degranulation. It 1) replaces a nonfusogenic phospholipid with a fusogenic one and 2) increases the potential for interactions between membranes and the annexins. Modeling neutrophil degranulation, we examined the effect of PLD (Streptomyces chromofuscus) hydrolysis on the aggregation and fusion of liposomes in the presence and absence of annexin I. We found that PLD-mediated conversion of PC to PA lowered the [Ca2+] required for fusion. Annexin I increased the rate of fusion in the presence of PA, although it did not lower threshold [Ca2+], which remained above the physiological range. However, after hydrolysis by PLD, annexin I lowered the [Ca2+] required for aggregation by almost three orders of magnitude, to near physiological concentrations. These studies indicate that the activation of PLD and the production of PA may play a role in annexin-mediated membrane-membrane apposition.

Identification of glyceraldehyde-3-phosphate dehydrogenase as a Ca2+-dependent fusogen in human neutrophil cytosol

Hessler

Brock

et al. 1998

The membrane fusion events observed during neutrophil degranulation are important aspects of the immunoregulatory system. In an attempt to understand the regulation of granuleplasma membrane fusion, we have begun characterizing human neutrophil cytosol for fusion activity, finding that 50% of the fusogenic activity could be attributed to members of the annexin family of proteins. The major non-annexin fusion activity (25% of the total cytosolic activity) was enriched by ion exchange chromatography after depletion of annexins by Ca 2؉ -dependent phospholipid affinity chromatography. The fusion activity co-purified with a 10,14-kDa dimer identified as leukocyte L1 (which was non-fusogenic), along with an approximately 36-kDa protein. This protein was identified as glyceraldehyde-3-phosphate dehydrogenase (GAPDH) by amino-terminal sequencing, and the fusion activity was verified using commercially available GAPDH. GAPDH may play an important role in degranulation because it is as potent as annexin I on a mass basis and may constitute up to 25% of the total cytosolic fusion activity of the neutrophil. J.

PLA2 promotes fusion between PMN-specific granules and complex liposomes

Transue

Harsh

et al. 1996

Neutrophil stimulation results in the activation of a variety of phospholipases, including phospholipase A2 (PLA2), which releases arachidonic acid from the 2 position of membrane phospholipids, leaving a lysophospholipid. Because arachidonic acid is known to be a potent fusogen in vitro, we examined the effect of metabolism by PLA2 on the fusion of complex liposomes (liposomes prepared with a phospholipid composition similar to that found in neutrophil plasma membrane). We observed that PLA2 augmented the fusion of complex liposomes with each other as well as with specific granules isolated from human neutrophils, lowering the Ca2+ requirement for fusion by three orders of magnitude. Furthermore, although lysophospholipids inhibited fusion, the incorporation of arachidonic acid into liposome membranes overcame the inhibitory effects of the lysophospholipids. Thus with PLA2 and annexins we were able to obtain fusion of complex liposomes at concentrations of Ca2+ that are close to physiological. Our data suggest that the activation of PLA2 and the generation of arachidonic acid may be the major fusion-promoting event mediating neutrophil degranulation.

Effect of calcium on phenothiazine inhibition of neutrophil degranulation

Hessler

1995

The phenothiazines are known to be potent inhibitors of calmodulin and have been used as probes for examining calmodulin-dependent cellular functions. We report here that the characteristics of phenothiazine inhibition of exocytosis in neutrophils more closely resemble their interaction with the annexins in vitro. Ca(2+)-dependent aggregation of liposomes mediated by either annexin I or annexin II was inhibited by the phenothiazines. Inhibition of liposome aggregation was not caused by interference with the binding of annexins to phospholipids. Rather, the phenothiazines increased the concentration of Ca2+ required for aggregation. Likewise, in neutrophils permeabilized with streptolysin O, inhibition of degranulation by phenothiazines could be overcome by increasing [Ca2+]. These results suggest that inhibition by phenothiazines of neutrophil degranulation is secondary to the ability of these compounds to inhibit membrane-membrane contact promoted by the annexins.