Purification of FKBP-70, a novel immunophilin from Saccharomyces cerevisiae, and cloning of its structural gene, FPR3.

A novel protein, belonging to the yeast family of FKBPs (FK-binding proteins), FKBP-70, was isolated from Saccharomyces cerevisiae by its interaction with the immunosuppressive agent FK-520. Its structural gene, FPR3, was cloned and the protein expressed and purified from Escherichia coli. This third member of the FKBP family in yeast is homologous to the other FKBPs at its carboxy terminus, showing conserved ligand binding and proline isomerase regions. It is, however, a longer acidic protein with several potential nuclear targeting sequences and a region of homology to nucleolins. Yeast strains deleted for FPR3, as well as a triple deletion mutant of this family of genes, FPR1, FPR2 and FPR3, are viable under normal conditions of growth, indicating that the FPR genes are not essential for life.

Identification of a 45-kDa protein at the protein import site of the yeast mitochondrial inner membrane.

Import of proteins into mitochondria involves the cooperation of protein translocation systems in the outer and inner membranes. We have identified a 45-kDa protein at the protein import site of the yeast mitochondrial inner membrane. This 45-kDa protein could be crosslinked to a partly translocated precursor, which cannot be imported across the inner membrane when the matrix is depleted of ATP. In addition, an antibody against this protein strongly inhibited protein import into right-side-out inner-membrane vesicles. The 45-kDa protein accounts for only 0.1% of mitochondrial protein and appears peripherally attached to the outer face of the inner membrane. The properties of this protein suggest that it is a component of the protein import system of the mitochondrial inner membrane.

Sequential action of mitochondrial chaperones in protein import into the matrix.

Translocation and folding of proteins imported into mitochondria are mediated by two matrix-localized chaperones, mhsp70 and hsp60. In order to investigate whether these chaperones act sequentially or in parallel, we studied their interaction with newly imported precursor proteins in isolated yeast mitochondria by coimmunoprecipitation. All precursors bound transiently to mhsp70. Release from mhsp70 required hydrolysis of ATP and did not immediately generate a tightly folded protein. For example, after imported mouse dihydrofolate reductase (a soluble monomeric enzyme) had been released from mhsp70, folding to a protease resistant conformation occurred only after a lag and was much slower than the release. Under standard import conditions, no significant association of DHFR with hsp60 could be detected. Similarly, newly imported hsp60 subunit was released from mhsp70 as an incompletely folded, unassembled intermediate which accumulated at low temperature and assembled to hsp60 14-mer at higher temperature in an ATP-dependent manner. Mas2p (the larger subunit of the MAS-encoded processing protease) first bound to mhsp70, then to hsp60, and only then assembled with its partner subunit, Mas1p. We propose that ATP-dependent release from mhsp70 is insufficient to cause folding of imported proteins and that assembly of hsp60 and Mas2p requires sequential, ATP-dependent interactions with mhsp70 and hsp60.