The accessibility of particular Leishmania tropica promastigote (extracellular) and amastigote (intracellular) membrane molecules might be related to the relative abilities of the two stages to induce host immune responses. To examine the exposure of membrane antigens on resident macrophage-susceptible promastigotes and resident macrophage-resistant amastigotes, both stages were analyzed by polyacrylamide gel electrophoresis and immunoblotting after specific labeling and extraction procedures. Protein compositional studies, using metabolic labeling of promastigotes and amastigotes, demonstrated that both forms possessed numerous endogenously synthesized proteins. In addition, a marked difference was revealed in the external exposure of promastigote and amastigote membrane constituents when analyzed by 125I surface labeling or Western blot analysis. Whereas nine promastigote proteins were intensely to moderately iodinated, only one amastigote membrane component was similarly labeled (9.5K band). Western blot analyses with serum from a rabbit immunized with a mixture of both L. tropica stages indicated that the majority of promastigote molecules accessible to 125I may also react with immune serum. However, Western blots of extracted amastigotes identified several bands not seen on radiographs and thus not accessible to 125I. The external exposure of these amastigote molecules was confirmed in that immune serum adsorbed with viable, intact amastigotes was no longer reactive with amastigote extracts. Further, by Western blot analyses of sodium dodecyl sulfate- but not Nonidet P-40-extracted amastigotes, three amastigote-specific membrane antigens not previously observed with nonionic detergent extraction methods were identified. The autofluorographic pattern of amastigotes intrinsically labeled with N-[3H]acetylglucosamine, an amino sugar which is incorporated into membrane carbohydrates, was in excellent agreement with the pattern of antigens reactive with antibody in Western blots. Thus, with these cell surface labeling and extraction methods, promastigote and amastigote membranes were shown to be significantly different. Amastigotes possessed several membrane-associated molecules, but few appeared to be either accessible or reactive with 125I. Moreover, the majority of molecules not reactive with 125I, but reactive with antibodies, may be glycosylated. These observations are discussed relative to the ability of amastigotes both to survive within the degradative milieu of macrophage phagolysosomes and to evade host immune reactivity.