Selective degradation of insulin within rat liver endosomes

To characterize the role of the endosome in the degradation of insulin in liver, we employed a cell-free system in which the degradation of internalized 125I-insulin within isolated intact endosomes was evaluated. Incubation of endosomes containing internalized 125I-insulin in the cell-free system resulted in a rapid generation of TCA soluble radiolabeled products (t1/2, 6 min). Sephadex G-50 chromatography of radioactivity extracted from endosomes during the incubation showed a time dependent increase in material eluting as radioiodotyrosine. The apparent Vmax of the insulin degrading activity was 4 ng insulin degraded.min-1.mg cell fraction protein-1 and the apparent Km was 60 ng insulin.mg cell fraction protein-1. The endosomal protease(s) was insulin-specific since neither internalized 125I-epidermal growth factor (EGF) nor 125I-prolactin was degraded within isolated endosomes as assessed by TCA precipitation and Sephadex G-50 chromatography. Significant inhibition of degradation was observed after inclusion of p-chloromercuribenzoic acid (PCMB), 1,10-phenanthroline, bacitracin, or 0.1% Triton X-100 into the system. Maximal insulin degradation required the addition of ATP to the cell-free system that resulted in acidification as measured by acridine orange accumulation. Endosomal insulin degradation was inhibited markedly in the presence of pH dissipating agents such as nigericin, monensin, and chloroquine or the proton translocase inhibitors N-ethylmaleimide (NEM) and dicyclohexylcarbodiimide (DCCD). Polyethylene glycol (PEG) precipitation of insulin-receptor complexes revealed that endosomal degradation augmented the dissociation of insulin from its receptor and that dissociated insulin was serving as substrate to the endosomal protease(s). The results suggest that as insulin is internalized it rapidly but incompletely dissociates from its receptor. Dissociated insulin is then degraded by an insulin specific protease(s) leading to further dissociation and degradation.     

IgG-dependent generation of platelet-activating factor by normal and low density human eosinophils

We have compared normal and low density human eosinophils for their ability to generate platelet activating factor (PAF) in response to IgG-dependent and nonimmunologic stimulation. After 45 min incubation with IgG-coated Sepharose beads the concentrations of cell-associated PAF recovered from normal density eosinophils were significantly greater than from low-density eosinophils or neutrophils. Moreover, eosinophils stimulated with calcium ionophore A23187 had a considerably greater capacity to generate PAF than had previously been described. Although the quantities of cell-associated PAF recovered from normal and low density eosinophils and neutrophils after A23187 stimulation were similar, the amounts of extracellular PAF recovered from both eosinophil populations were significantly greater than from neutrophils. The amounts of PAF recovered from the low density eosinophils may not reflect the full synthetic capacity of these cells, because PAF-turnover was found to be more rapid than that observed with normal density eosinophils. When exogenous [3H]PAF was added to the two stimulated eosinophil populations subsequent analysis of the [3H]PAF metabolites by DIOL-HPLC revealed that low density eosinophils incorporated PAF into the phosphatidylcholine (PC) pool more rapidly than did normal density eosinophils or neutrophils. Alkaline hydrolysis of the PC fraction from whole cell extracts followed by treatment with acetic anhydride resulted in all the PC-associated radioactivity being converted to [3H]PAF, confirming PAF incorporation to PC via this pathway. These findings suggest that the contribution of eosinophils to inflammatory processes through the generation of PAF may be greater than previously appreciated, and that Ig-mediated stimulation may be important in initiating generation of the mediator. Low density eosinophils, that are presumed to be similar to tissue eosinophils, may have a role in regulating PAF concentrations in tissues through their enhanced rate of metabolism.     

Expression cloning of a cDNA encoding M1/69-J11d heat-stable antigens

The differentiation Ag identified by the mAb M1/69 and J11d (commonly referred to as heat-stable Ag) are found in structurally heterogeneous forms on the surfaces of many types of murine hemopoietic cells. The extinction of expression of these antigens is associated with thymocyte maturation and Ig class switching in B cells, as well as terminal differentiation of macrophages. A cDNA encoding the M1/69-J11d peptide was cloned from a hemopoietic progenitor cell line by immunoselection of COS cells transfected with expression libraries. The cloned cDNA is a copy of a gene that is transcribed in M1/69-J11d+ lymphoid, myeloid, and erythroid cells. This gene could be responsible for the expression of all forms of the M1/69-J11d Ag, although there are homologous genes that may encode some forms of the Ag that are specifically expressed in bone marrow. The cloned cDNA encodes a surprisingly small peptide, predicted to contain only 30 amino acids after removal of a signal sequence and displacement of the C-terminal region by the glycosyl-phosphatidylinositol group that anchors the peptide to the cell surface. Almost all of the mass of the M1/69-J11d Ag accumulates through extensive N- and O-linked glycosylation at multiple sites in the short peptide. These carbohydrates are likely to execute the functions of M1/69-J11d Ag, which could be specialized to each cell type as a consequence of differential glycosylation.