Clifford V. Harding

Liposome-encapsulated antigens are processed in lysosomes, recycled, and presented to T cells

Antigen processing requires intracellular antigen catabolism to generate immunogenic peptides that bind to class II MHC molecules (MHC-II) for presentation to T-cells. We now provide direct evidence that these peptides are produced within dense lysosomes, as opposed to earlier endocytic compartments. The protein antigen hen egg lysozyme was targeted to endosomes or lysosomes by encapsulating it in liposomes of different membrane composition. Acid-sensitive liposomes released their contents in early endosomes, whereas acid-resistant liposomes sequestered their contents from potential endosomal processing events and released their contents only after delivery to lysosomes. Antigen encapsulated in acid-resistant liposomes was processed in a chloroquine-sensitive manner and presented more efficiently than soluble antigen or antigen encapsulated in acid-sensitive liposomes. Thus, peptides may be recycled from lysosomes, transported to endosomes to bind MHC-II, and then expressed at the cell surface.

Effects of pH and polysaccharides on peptide binding to class II major histocompatibility complex molecules.

The binding of immunogenic peptides to class II major histocompatibility molecules was examined at various pH values. We studied binding of peptides containing residues 52-61 from hen egg lysozyme (HEL) to I-Ak on fixed peritoneal macrophages or to solubilized affinity-purified I-Ak. Optimum binding occurred at pH 5.5-6.0 with accelerated kinetics relative to pH 7.4; equilibrium binding was also higher at pH 5.5-6.0 than at 7.4. Similar enhancement at pH 5-6 was observed for the binding of hemoglobin-(64-76) to I-Ek and of ribonuclease-(41-61) to I-Ak. In contrast, the binding of HEL-(34-45) to I-Ak was minimally enhanced at acid pH. Dissociation of cell-associated or purified peptide-I-Ak complexes was minimal between pH 5.5 and 7.4, with increased dissociation only at or below pH 4.0 [HEL-(46-61)] or pH 5.0 [HEL-(34-45)]. Thus, optimum peptide binding occurs at pH values similar to the endosomal environment, where the complexes appear to be formed during antigen processing. In addition, we examined the effect of a number of polysaccharides on the binding of peptide to I-Ak. None of these competed with the HEL peptide 125I-labeled YE52-61 for binding to I-Ak. [3H]Dextran also failed to bind purified I-Ak. Polysaccharides do not appear to bind to class II major histocompatibility complex molecules, which explains the T-cell independence of polysaccharide antigens.

Mechanisms of Antigen Processing

Using MAb and monovalent Fab probes and saponin permeabilization we have demonstrated that PEC and TA3 B lymphoma-hybridoma cells contain a significant intracellular pool of Ia. At least in TA3 cells, this intracellular pool was independent of protein synthesis. In PEC, adherence caused redistribution of Ia with disappearance of the intracellular pool. Endocytosis of Ia occurred in both TA3 and PEC, and internalized Ia reached a plateau level corresponding in size to the total intracellular Ia pool revealed by saponin treatment. These results suggest that intracellular Ia is largely in a recycling pool derived from the plasma membrane by endocytosis. Subcellular fractionation studies suggest that Ia processing occurs in endosomes similar to those involved in transferrin processing. Antigen processing by TA3 cells was found to be unaffected by cycloheximide. In contrast, antigen processing by adherent PEC was markedly inhibited by cycloheximide, despite the fact that they maintained surface Ia and were still capable of presenting antigen peptides. This suggests that an important intracellular Ia processing step or antigen processing step was blocked in these cells. Adherent PEC may contain less recycling Ia, making protein synthesis the major source for intracellular Ia and the availability of intracellular Ia sensitive to cycloheximide. Alternatively, the inhibition of antigen processing by cycloheximide in PEC may reflect depletion of enzymes or other factors involved in antigen processing. Proteins and polysaccharides may interfere with the events that result in the formation of an immunogenic Ia-peptide complex. We had previously documented that peptides compete for the binding site of Ia molecules. We discussed here a second form of interference by polysaccharides and microbial products. These materials did not compete or interfere with the binding and presentation of processed peptides by Ia. Rather, their presence inside the macrophage inhibited MHC-dependent presentation of immunogenic proteins by inhibiting intracellular steps in antigen processing. This intracellular interference with antigen presentation can be of major importance in the presentation of complex mixtures of protein and carbohydrates.

Transferrin recycling in reticulocytes: pH and iron are important determinants of ligand binding and processing

Iron uptake by rat reticulocytes is blocked by 20 mM NH4Cl, while 125I-diferric transferrin (Tf) uptake is relatively unaffected. At pH 5.0 both apo- and diferric Tf bind with high affinity; at pH 7.4 diferric Tf binds avidly, but apoTf binds very poorly. The dissociation rate (4 degrees C) of diferric Tf is extraordinarily slow at pH 5.0 (extrapolated t 1/2 = 32 hrs) and faster at pH 7.4 (t 1/2 = 101 min). At pH 5.0 apoTf also dissociates slowly (t 1/2 = 205 min), but at pH 7.4 apoTf exhibits a much faster dissociation rate (t 1/2 = 62 min). 20 mM NH4Cl slows the release of Tf from cells at 37 degrees C, but the rate of externalization of ligand is unaffected. Ligand dissociation at 37 degrees involves both externalization of receptor-ligand complexes and receptor-ligand separation; the NH4Cl effect may result from an increased fraction of externalized Tf in the diferric form which may dissociate more slowly. Receptor-mediated movement of Tf through acid intracellular compartments provides a mechanism to remove iron from Tf and for apoTf to remain receptor-bound for externalization to the cell surface and subsequent dissociation.

Pathways of antigen processing

Separate pathways exist for the processing of antigens to be presented by MHC class I and class II molecules. We are beginning to determine the subcellular location of certain events in both pathways.