During protein integration into the endoplasmic reticulum, the N-terminal domain preceding the type I signal-anchor sequence is translocated through a translocon. By fusing a streptavidin-binding peptide tag to the N terminus, we created integration intermediates of multispanning membrane proteins. In a cell-free system, N-terminal domain (N-domain) translocation was arrested by streptavidin and resumed by biotin. Even when N-domain translocation was arrested, the second hydrophobic segment mediated translocation of the downstream hydrophilic segment. In one of the defined intermediates, two hydrophilic segments and two hydrophobic segments formed a transmembrane disposition in a productive state. Both of the translocating hydrophilic segments were crosslinked with a translocon subunit, Sec61α. We conclude that two translocating hydrophilic segment in a single membrane protein can span the membrane during multispanning topogenesis flanking the translocon. Furthermore, even after six successive hydrophobic segments entered the translocon, N-domain translocation could be induced to restart from an arrested state. These observations indicate the remarkably flexible nature of the translocon.
In topogenesis of membrane proteins on the endoplasmic reticulum, the orientation of the hydrophobic transmembrane (TM) segment is influenced by the charge of the flanking amino acid residues. We assessed the function of the positive charges downstream of the hydrophobic segment using synaptotagmin II. The positive charges were systematically replaced with non-charged residues. Although the original TM segment translocated the N terminus, the topology was inverted, depending on the mutations. Orientation was affected in mutants in which 6 Lys were shifted downstream, even when the 6 Lys were 25 residues from the hydrophobic segment. The Lys was functionally replaced by Arg, but not by Asp or Glu. The timing of action during polypeptide elongation indicated that the Lys functions at the ribosome exit sites. We suggest that the commitment of the TM segment to a particular orientation is influenced by far downstream parts of the polypeptide chain and that the positive charges are decoded after exiting the ribosome.
Positive charges of nascent chain facilitate membrane spanning of a marginally hydrophobic segment, even when separated by 70 residues from the segment. The segment is exposed to the lumen and then slides back into the membrane. They not only fix the hydrophobic segment in the membrane, but exert a much more dynamic action than previously realized.
Many proteins are translocated across and integrated into the endoplasmic reticulum membrane. The type I signal anchor sequence mediates the translocation of its preceding region through the endoplasmic reticulum membrane, but the source of the motive force has been unclear. Here, we characterized the motive force for N-terminal domain translocation using two probes. First, an Ig-like domain of the muscle protein titin (I27 domain) or its mutants were fused to the N termini, and translocation was examined in a cell-free translation system supplemented with rough microsomal membrane. The N-terminal translocation efficiencies correlated with the mechanical instabilities of the I27 mutants. When the I27 domain was separated from the signal anchor sequence by inserting a spacer, even the most unstable mutant stalled on the cytoplasmic side, whereas its downstream portion spanned the membrane. Proline insertion into the signal anchor sequence also caused a large translocation defect. Second, a streptavidin-binding peptide tag was fused to the N terminus. Titration of streptavidin in the translation system allowed us to estimate the translocation motive force operative on the tag. The motive force was decreased by the proline insertion into the signal anchor sequence as well as by separation from the signal anchor sequence. When the streptavidin-binding peptide tag was separated from the signal anchor, the proline insertion did not induce further deficits in the motive force for the tag. On the basis of the findings obtained by using these two independent techniques, we conclude that the signal sequence itself provides the motive force for N-terminal domain translocation within a limited upstream region.
Nascent polypeptide chains synthesized by membrane bound ribosomes are cotranslationally translocated through and integrated into the endoplasmic reticulum translocon. Hydrophobic segments and positive charges on the chain are critical to halt the ongoing translocation. A marginally hydrophobic segment, which cannot be inserted into the membrane by itself, can be a transmembrane segment depending on its downstream positive charges. In certain conditions, positive charges even 60 residues downstream cause the marginally hydrophobic segment to span the membrane by inducing the segment to slide back from the lumen. Here we systematically examined the effect of a core sugar chain on the fate of a marginally hydrophobic segment using a cell-free translation and translocation system. A sugar chain added within 12 residues upstream of the marginally hydrophobic segment prevents the sliding back and promotes forward movement of the polypeptide chain. The sugar chain apparently functions as a ratchet to keep the polypeptide chain in the lumen. We propose that the sugar chain is a third topology determinant of membrane proteins, in addition to a hydrophobic segment and positive charges of the nascent chain.
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