Metal-ion-center assembly of ferredoxin and plastocyanin in isolated chloroplasts.

Abstract: Most chloroplastic proteins are cytosolically synthesized and posttranslationally transported to their proper locations.' Two examples of this group of proteins are ferredoxin and plastocyanin, both of which are metal-containing components of the photosynthetic electron-transport chain.The import process for these two proteins includes the insertion of the metal ions to produce the holo forms of the proteins. We show here that in vitro translated precursor. proteins of ferredoxin and plastocyanm are synthesize… Show more

“…By contrast, holoplastocyanin was barely detectable in paa1-1 and paa1-3, and apoplastocyanin accumulated instead ( Figure 8A, untreated). Treatment with ascorbate and KCN, which converts holoplastocyanin to forms of apoplastocyanin with different electrophoretic mobilities on native gels (Li et al, 1990), indicated that the wild-type plants had much higher contents of plastocyanin polypeptides ( Figure 8A, ascorbate/KCN treated), a finding that was confirmed by denaturing SDS-PAGE ( Figure 8B). This difference was not apparent in the untreated samples separated on the native gel ( Figure 8A, untreated), presumably because the anti-plastocyanin antibody detected apoplastocyanin much more efficiently than holoplastocyanin.…”

“…might be explained by a lack of functional plastocyanin. To assess this possibility, thylakoid lumen proteins from wild-type and paa1 plants were subjected to native gel electrophoresis (Li et al, 1990) to separate holoplastocyanin (containing Cu) and apoplastocyanin (lacking Cu). In wild-type plants, plastocyanin was present predominantly in the holo form ( Figure 8A, untreated).…”

“…Because the chloroplast protein import machinery has a strong unfolding capacity (Guera et al, 1993;America et al, 1994), proteins such as plastocyanin are thought to acquire their cofactors after import into the organelle (for review, see Merchant and Dreyfuss, 1998). De novo cofactor insertion into plastocyanin was observed after in vitro translocation into the lumen (Li et al, 1990). The plastocyanin polypeptide is unstable in Chlamydomonas reinhardtii grown in Cu-deficient medium (Merchant and Bogorad, 1986;Li and Merchant, 1995), and under these conditions, a cytochrome c 6 is induced that functionally replaces plastocyanin.…”

PAA1, a P-Type ATPase of Arabidopsis, Functions in Copper Transport in Chloroplasts

“…By contrast, holoplastocyanin was barely detectable in paa1-1 and paa1-3, and apoplastocyanin accumulated instead ( Figure 8A, untreated). Treatment with ascorbate and KCN, which converts holoplastocyanin to forms of apoplastocyanin with different electrophoretic mobilities on native gels (Li et al, 1990), indicated that the wild-type plants had much higher contents of plastocyanin polypeptides ( Figure 8A, ascorbate/KCN treated), a finding that was confirmed by denaturing SDS-PAGE ( Figure 8B). This difference was not apparent in the untreated samples separated on the native gel ( Figure 8A, untreated), presumably because the anti-plastocyanin antibody detected apoplastocyanin much more efficiently than holoplastocyanin.…”

“…might be explained by a lack of functional plastocyanin. To assess this possibility, thylakoid lumen proteins from wild-type and paa1 plants were subjected to native gel electrophoresis (Li et al, 1990) to separate holoplastocyanin (containing Cu) and apoplastocyanin (lacking Cu). In wild-type plants, plastocyanin was present predominantly in the holo form ( Figure 8A, untreated).…”

“…Because the chloroplast protein import machinery has a strong unfolding capacity (Guera et al, 1993;America et al, 1994), proteins such as plastocyanin are thought to acquire their cofactors after import into the organelle (for review, see Merchant and Dreyfuss, 1998). De novo cofactor insertion into plastocyanin was observed after in vitro translocation into the lumen (Li et al, 1990). The plastocyanin polypeptide is unstable in Chlamydomonas reinhardtii grown in Cu-deficient medium (Merchant and Bogorad, 1986;Li and Merchant, 1995), and under these conditions, a cytochrome c 6 is induced that functionally replaces plastocyanin.…”

PAA1, a P-Type ATPase of Arabidopsis, Functions in Copper Transport in Chloroplasts

“…Because the copper-requiring step in the biosynthesis of plastocyanin (i.e. formation of a stable holoprotein) is compartmentalized in the lumen of the thylakoid membrane (15,18), we cannot definitively conclude that partitioning of copper between the regulator (in the cytosol or nucleus) and plastocyanin (in the lumen) is set by their own relative cellular stoichiometries and affinities for copper. Distribution of copper between the regulator and plastocyanin might, for example, be determined by the affinities and directionalities of intracellular copper-transporting systems.…”

In Vivo Competition between Plastocyanin and a Copper-Dependent Regulator of the Chlamydomonas reinhardtii Cytochrome c₆ Gene

“…The importance of Fe-S clusters for photosynthesis stimulated early studies in the assembly of these metal cofactors in chloroplasts using nuclear-encoded, imported ferredoxin as a model protein (Takahashi et al 1986;Li et al 1990). By adding 35 S-labeled cysteine to lysed spinach chloroplasts, it was shown that cysteine is the source of sulfur for the ½2Fe-2S cluster of ferre-doxin (Takahashi et al 1991b).…”

Genome Analysis of Chlamydomonas reinhardtii Reveals The Existence of Multiple, Compartmentalized Iron–Sulfur Protein Assembly Machineries of Different Evolutionary Origins