Probing the environment of signal-anchor sequences during topogenesis in the endoplasmic reticulum.

Signal sequences for insertion of protein into the mammalian endoplasmic reticulum orient themselves in the translocon on the basis of their flanking charges. It has recently been shown that hydrophobic N-terminal signals initially insert head-on before they invert their orientation to translocate the C-terminus. The rate of inversion is reduced with the increasing hydrophobicity of the signal due to an increased affinity for the initial bound state at the translocon. To probe the environment of the signal while its orientation is determined, different hydrophobic residues were inserted at various positions throughout a uniform oligoleucine signal sequence and the constructs were expressed in transfected COS-7 cells. The resulting topologies revealed a strikingly symmetric position dependence specifically for bulky aromatic amino acids, reflecting the structure of a lipid bilayer. Maximal N-translocation was observed when the guest residues were placed at the N- or C-terminus of the hydrophobic sequence or in the very center, corresponding to the positions of highest expected affinity of the signal sequence as a membrane-spanning helix for the bilayer. The results support the model that during topogenesis in vivo the signal sequence is exposed to the lipid membrane.

Topogenesis of membrane proteins at the endoplasmic reticulum.

Most eukaryotic membrane proteins are cotranslationally integrated into the endoplasmic reticulum membrane by the Sec61 translocation complex. They are targeted to the translocon by hydrophobic signal sequences, which induce the translocation of either their N- or their C-terminal sequence. Signal sequence orientation is largely determined by charged residues flanking the apolar sequence (the positive-inside rule), folding properties of the N-terminal segment, and the hydrophobicity of the signal. Recent in vivo experiments suggest that N-terminal signals initially insert into the translocon head-on to yield a translocated N-terminus. Driven by a local electrical potential, the signal may invert its orientation and translocate the C-terminal sequence. Increased hydrophobicity slows down inversion by stabilizing the initial bound state. In vitro cross-linking studies indicate that signals rapidly contact lipids upon entering the translocon. Together with the recent crystal structure of the homologous SecYEbeta translocation complex of Methanococcus jannaschii, which did not reveal an obvious hydrophobic binding site for signals within the pore, a model emerges in which the translocon allows the lateral partitioning of hydrophobic segments between the aqueous pore and the lipid membrane. Signals may return into the pore for reorientation until translation is terminated. Subsequent transmembrane segments in multispanning proteins behave similarly and contribute to the overall topology of the protein.