SEQUENTIAL DEGRANULATION OF THE TWO TYPES OF POLYMORPHONUCLEAR LEUKOCYTE GRANULES DURING PHAGOCYTOSIS OF MICROORGANISMS

doi:10.1083/jcb.58.2.249

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SEQUENTIAL DEGRANULATION OF THE TWO TYPES OF POLYMORPHONUCLEAR LEUKOCYTE GRANULES DURING PHAGOCYTOSIS OF MICROORGANISMS

Dorothy Ford Bainton ¹

¹ From the Department of Pathology, University of California at San Francisco, California 94122

The sequential discharge of neutrophilic polymorphonuclearleukocyte (PMN) granules—azurophils and specifics—wasinvestigated by electron microscopy and cytochemistry. Thusthe enzyme content of PMN phagocytic vacuoles was determinedat brief intervals after phagocytosis of bacteria, utilizingperoxidase as a marker enzyme for azurophil granules, and alkalinephosphatase for specifics. At 30 s, approximately half the phagocyticvacuoles were reactive for alkaline phosphatase, whereas nonecontained peroxidase. Peroxidase-containing vacuoles were rarelyseen at 1 min, but by 3 min, vacuoles containing both enzymeswere consistently present. Alkaline phosphatase was found inboth small and large vacuoles, whereas peroxidase was visibleonly in large ones. By 10 min, very big phagocytic vacuolescontaining considerable amounts of reaction product for bothenzymes were evident. These observations indicate that the twotypes of PMN granules discharge in a sequential manner, specificgranules fusing with the vacuole before azurophils. In an earlierpaper, we reported that the pH of phagocytic vacuoles dropsto 6.5 within 3 min and to $sim$ 4 within 7–15 min. Substancesknown to be present in specific granules (alkaline phosphatase,lysozyme, and lactoferrin) function best at neutral or alkalinepH, whereas most of those contained in azurophil granules (i.e.,peroxidase and the lysosomal enzymes) have pH optima in theacid range. Hence the sequence of granule discharge roughlyparallels the change in pH, thereby providing optimal conditionsfor coordinated activity of granule contents.

Submitted on January 29, 1973
Revised on March 30, 1973

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