In a study of secretory protein precursors, formation of a protease-resistant ribosome–membrane junction, currently thought to define the pathway of the translocating nascent chain, was observed to be precursor- and stage-dependent. Analysis of the binding of early intermediates indicated that the nascent chain was bound to the membrane independent of the ribosome, and that the binding was predominately electrostatic. The membrane topology of the signal sequence was determined as a function of the stage of translocation, and was found to be identical for all assayed intermediates. Unexpectedly, the hydrophobic core of the signal sequence was observed to be accessible to the cytosolic face of the membrane at stages of translocation immediately after targeting as well as stages before signal sequence cleavage. Removal of the ribosome from bound intermediates did not disrupt subsequent translocation, suggesting that the active state of the protein-conducting channel is maintained in the absence of the bound ribosome. A model describing a potential mode of regulation of the ribosome–membrane junction by the nascent chain is presented.