A protein kinase was located in the cytosol of pea mesophyll cells. The protein kinase phosphorylates, in an ATP-dependent manner, chloroplast-destined precursor proteins but not precursor proteins, which are located to plant mitochondria or plant peroxisomes. The phosphorylation occurs on either serine or threonine residues, depending on the precursor protein used. We demonstrate the specific phosphorylation of the precursor forms of the chloroplast stroma proteins ferredoxin (preFd), small subunit of ribulose-bisphosphate-carboxylase (preSSU), the thylakoid localized light-harvesting chlorophyll a/b-binding protein (preLHCP), and the thylakoid lumen-localized proteins of the oxygen-evolving complex of 23 kDa (preOE23) and 33 kDa (preOE33). In the case of thylakoid lumen proteins which possess bipartite transit sequences, the phosphorylation occurs within the stroma-targeting domain. By using single amino acid substitution within the presequences of preSSU, preOE23, and preOE33, we were able to tentatively identify a consensus motif for the precursor protein protein kinase. This motif is (P/G)X n (R/K)X n (S/ T)X n (S*/T*), were n ؍ 0 -3 amino acids spacer and S*/T* represents the phosphate acceptor. The precursor protein protein kinase is present only in plant extracts, e.g. wheat germ and pea, but not in a reticulocyte lysate. Protein import experiments into chloroplasts revealed that phosphorylated preSSU binds to the organelles, but dephosphorylation seems required to complete the translocation process and to obtain complete import. These results suggest that a precursor protein protein phosphatase is involved in chloroplast import and represents a so far unidentified component of the import machinery. In contrast to sucrose synthase, a cytosolic marker protein, the precursor protein protein kinase seems to adhere partially to the chloroplast surface. A phosphorylation-dephosphorylation cycle of chloroplast-destined precursor proteins might represent one step, which could lead to a specific sorting and productive translocation in plant cells.Chloroplasts and mitochondria contain their own genome; however, the vast majority of their proteins is encoded in the nucleus and synthesized in the cytosol. In general these proteins carry NH 2 -terminal targeting domains which direct them to the proper organelle in a posttranslational event. Whereas some knowledge about the components and mechanisms which are involved in the recognition and translocation of the precursors on the organellar surface has accumulated (Hirsch et al., 1994;Schnell et al., 1994;Gray and Row, 1995;Soll, 1995), almost nothing is known about the events which take place in the cytosol, after the precursor emerges from the ribosome and before binding to the chloroplast. A loosely folded precursor, however, seems to be a prerequisite for membrane translocation. In all import systems aggregation of highly hydrophobic membrane proteins and premature folding has to be prevented. To attain or maintain such an import-competent, soluble conformation,...
