Evidence for Multiple Mechanisms for Membrane Binding and Integration via Carboxyl-Terminal Insertion Sequences
Subcellular localization of proteins with carboxyl-terminal insertion sequences requires the molecule be both targeted to and integrated into the correct membrane. The mechanism of membrane integration of cytochrome b5 has been shown to be promiscuous, spontaneous, nonsaturable, and independent of membrane proteins. Thus endoplasmic reticulum localization for cytochrome b5 depends primarily on accurate targeting to the appropriate membrane. Here direct comparison of this mechanism with that of three other proteins integrated into membranes via carboxyl-terminal insertion sequences [vesicle-associated membrane protein 1(Vamp1), polyomavirus middle-T antigen, and Bcl-2] revealed that, unlike cytochrome b5, membrane selectivity for these molecules is conferred at least in part by the mechanisms of membrane integration. Bcl-2 membrane integration was similar to that of cytochrome b5 except that insertion into lipid vesicles was inefficient. Unlike cytochrome b5 and Bcl-2, Vamp1 binding to canine pancreatic microsomes was saturable, ATP-dependent, and abolished by mild trypsin treatment of microsomes. Surprisingly, although the insertion sequence of polyomavirus middle-T antigen was sufficient to mediate electrostatic binding to membranes, binding did not lead to integration into the bilayer. Together these results demonstrate that there are at least two different mechanisms for correct membrane integration of proteins with insertion sequences, one mediated primarily by targeting and one relying on factors in the target membrane to mediate selective integration. Our results also demonstrate that, contrary to expectation, hydrophobicity is not sufficient for insertion sequence-mediated membrane integration. We suggest that the structure of the insertion sequence determines whether or not specific membrane-bound receptor proteins are required for membrane integration.
Kinetic Analysis of YPD1-Dependent Phosphotransfer Reactions in the Yeast Osmoregulatory Phosphorelay System
In Saccharomyces cerevisiae, the histidine-containing phosphotransfer (HPt) protein YPD1 transfers phosphoryl groups between the three different response regulator domains of SLN1, SSK1, and SKN7 (designated R1, R2, and R3, respectively). Together these proteins form a branched histidine-aspartic acid phosphorelay system through which cells can respond to hyperosmotic and other environmental stresses. The in vivo order of phosphotransfer reactions is believed to proceed from SLN1-R1 to YPD1 and then subsequently to SSK1-R2 or SKN7-R3. The individual phosphoryl transfer reactions between YPD1 and the response regulator domains have been examined kinetically. A maximum forward rate constant of 29 s(-)(1) was determined for the reaction between SLN1-R1 approximately P and YPD1 with a K(d) of 1.4 microM for the SLN1-R1 approximately P.YPD1 complex. In the subsequent reactions, phosphotransfer from YPD1 to SSK1-R2 is very rapid (160 s(-)(1)) and is strongly favored over phosphotransfer to SKN7-R3. Phosphotransfer reactions between YPD1 and SLN1-R1 or SKN7-R3 were reversible. In contrast, no reverse transfer from SSK1-R2 approximately P to YPD1 was observed. These findings are consistent with the notion that SSK1 is constitutively phosphorylated under normal osmotic conditions. In addition, we have examined the roles of several conserved amino acid residues surrounding the phosphorylatable histidine (H64) of YPD1 using phosphoryl transfer reactions involving YPD1 mutants. With respect to phosphoryl transfer from SLN1-R1 approximately P, only one YPD1 mutant (K67A) exhibited an increase in K(d) and thus affects binding of YPD1 to SLN1-R1 approximately P, whereas other mutants (R90A, Q86A, and G68Q) showed a decrease in phosphoryl transfer rate. Only the G68Q-YPD1 mutant was significantly affected in phosphotransfer to SSK1-R2 ( approximately 680-fold decrease in rate in comparison to wild-type). This is the first report of a kinetic analysis of a eukaryotic "two-component" histidine-aspartic acid phosphotransfer system, enabling a comparison of the transfer rates and binding constants to the few bacterial systems that have been studied this way.
Two-component regulatory systems that utilize a multistep phosphorelay mechanism often involve a histidine-containing phosphotransfer (HPt) domain. These HPt domains serve an essential role as histidinephosphorylated protein intermediates during phosphoryl transfer from one response regulator domain to another. In Saccharomyces cerevisiae, the YPD1 protein facilitates phosphoryl transfer from a hybrid sensor kinase, SLN1, to two distinct response regulator proteins, SSK1 and SKN7. Because the phosphorylation state largely determines the functional state of response regulator proteins, we have carried out a comparative study of the phosphorylated lifetimes of the three response regulator domains associated with SLN1, SSK1, and SKN7 (R1, R2, and R3, respectively). The isolated regulatory domains exhibited phosphorylated lifetimes within the range previously observed for other response regulator domains (i.e., several minutes to several hours). However, in the presence of YPD1, we found that the half-life of phosphorylated SSK1-R2 was dramatically extended (almost 200-fold longer than in the absence of YPD1). This stabilization effect was specific for SSK1-R2 and was not observed for SLN1-R1 or SKN7-R3. Our findings suggest a mechanism by which SSK1 is maintained in its phosphorylated state under normal physiological conditions and demonstrate an unprecedented regulatory role for an HPt domain in a phosphorelay signaling system. Two-component signal transduction systems in prokaryotic and eukaryotic organisms regulate cellular responses to environmental changes (6, 11). In their simplest form, these regulatory pathways involve an autophosphorylating transmembrane histidine kinase and a cytoplasmic response regulator that is phosphorylated on an aspartic acid residue. Modified and expanded versions of two-component regulatory pathways requiring multiple phosphoryl transfer reactions between several phosphodonor and phosphoreceiver domains have also been identified (1,6,25,27). Some of the more complex phosphorelay systems that have been described thus far include a hybrid sensor kinase (that also contains a phosphoaspartate receiver domain), a histidine-containing phosphotransfer (HPt) protein, and one or more response regulator proteins (4,5,7,8,14,29,34). HPt domains serve a dual purpose as a phosphoreceiver and phosphodonor in order to shuttle phosphoryl groups between two or more response regulator domains. It has also been suggested that the presence of HPt domains and use of multistep phosphorelay systems provide for additional points of regulation of signaling pathways (1, 11).In most cases, response regulator proteins are activated upon phosphorylation. Hence, the intrinsic lifetime of the phosphorylated state of a response regulator is an important factor in determining the duration of the cellular response. Phosphorylated half-lives ranging from seconds for CheY and CheB (10, 37) to several hours for OmpR and Spo0F (13, 40) have been observed. In addition to the intrinsic phosphatase activity of the respon...
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