Abstract
Rap1A, a low molecular weight guanosine triphosphate-binding protein (LMWG), has been shown previously by us to be associated with purified cytochrome b from stimulated human neutrophils. In the present studies, we show that Rap1A is also associated with affinity-purified cytochrome b from unstimulated neutrophils and use specific anti-Rap1 peptide antibodies to biochemically and immunocytochemically determine the subcellular distribution of Rap1A in resting and activated human neutrophils. Analysis of the subcellular fractionation of unstimulated cells by Western blotting of isopycnic sucrose density gradient fractions with anti-Rap1 peptide antibodies indicated that Rap1A colocalized with cytochrome b in the plasma membrane as well as in the specific granule membranes and that it was translocated, along with cytochrome b, to the plasma membrane when the cells were stimulated with phorbol myristate acetate (PMA). No evidence for a cytosolic localization of Rap1A was found in our studies; however, if the cells were disrupted by sonication, rather than N2 cavitation, a fraction of the Rap1A was released from the membrane. Electron microscopy of thin sections of cryofixed, molecular-distillation dried neutrophils labeled with anti-Rap1 antibody alone or double-labeled with anti-Rap1 and anti- cytochrome b peptide antibodies confirmed our biochemical localization, and quantitation showed that more than half of the specific granule- associated Rap1A was translocated to the plasma membrane in PMA- stimulated cells. Ultrastructural analysis of neutrophils phagocytosing Staphylococcus aureus also demonstrated the translocation of Rap1A with cytochrome b. Approximately 70% of the total Rap1A labeling was associated with the phagolysosomal membrane, the site of assembly of the superoxide-generating system. The colocalization and cotranslocation of Rap1A with cytochrome b in resting and activated neutrophils is consistent with a functional association of these two molecules in the intact cell and provides further evidence for a role of this LMWG in the structure or function of the neutrophil superoxide- generating system.
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