Identification, characterization, and resolution of the in vivo phosphorylated form of the D1 photosystem II reaction center protein.

The chloroplast-encoded D1 protein of oxygenic photosynthetic organisms is a component of the photosystem II reaction center. Previously, we detected an electrophoretic variant of D1 which was generated in vivo in granal-localized reaction centers in a light dependent manner (Callahan, F.E., Ghirardi, M.L., Sopory, S.K., Mehta, A.M., Edelman, M., and Mattoo, A.K. (1990) J. Biol. Chem. 265, 15357-15360). In the present study, we identify this modified form as phosphorylated D1. The in vivo phosphorylation occurs on a threonine residue(s) localized within 1 kDa from the N terminus and is identical to the phosphorylation of D1 catalyzed in vitro by a redox-regulated thylakoid-bound protein kinase. While virtually all of the D1 protein present in thylakoids can be phosphorylated in vitro, the steady-state level of phosphorylated D1 in vivo varies with light intensity and did not exceed 20% of the total D1 under the conditions of this study.

Formation of a photoreversible phycocyanobilin-apophytochrome adduct in vitro.

Avena seedlings grown in the presence of the plant tetrapyrrole synthesis inhibitor 4-amino-5-hexynoic acid contain less than 10% of the spectrally detectable phytochrome levels found in untreated seedlings, but continue to accumulate phytochrome apoprotein (Elich, T. D., and Lagarias, J. C. (1988) Plant Physiol. 88, 747-751). Using such tetrapyrrole-deficient seedlings, we have previously reported that phycocyanobilin, the cleaved prosthetic group of C-phycocyanin, can be incorporated into phytochrome in vivo to yield spectrally active holoprotein (Elich, T. D., McDonagh, A. F., Palma, L. A., and Lagarias, J. C. (1988) J. Biol. Chem. 264, 183-189). Here we show that addition of phycocyanobilin to soluble extracts of inhibitor-treated seedlings results in a rapid increase in spectrally active phytochrome holoprotein. The newly formed photoactive species displays a blue-shifted absorbance difference spectrum similar to that observed in the previous in vivo studies. The increase in spectral activity is consistent with conversion of all of the preexisting phytochrome apoprotein to functionally active holoprotein. The formation of a covalent phycocyanobilin-apophytochrome adduct is shown by an increase in Zn2+-dependent bilin fluorescence of the phytochrome polypeptide. A photoreversible, covalent adduct with a similar optical spectrum also forms when immunopurified apophytochrome is incubated with phycocyanobilin. ATP, reduced pyridine nucleotides, or other cofactors are not required for adduct formation. When biliverdin IX alpha is substituted for phycocyanobilin, no spectrally active covalent adduct is produced. These results indicate that an A-ring ethylidene-containing bilatriene is required for post-translational covalent attachment of bilin to apophytochrome and that apophytochrome may be the bilin C-S lyase which catalyzes bilin attachment.

Phytochrome chromophore biosynthesis. Treatment of tetrapyrrole-deficient Avena explants with natural and non-natural bilatrienes leads to formation of spectrally active holoproteins.

Etiolated Avena seedlings grown in the presence of 4-amino-5-hexynoic acid, an inhibitor of 5-aminolevulinic acid synthesis in plants, contain less than 10% of the spectrally detectable levels of phytochrome found in untreated seedlings (Elich, T.D., and Lagarias, J.C. (1988) Plant Physiol. 88, 747-751). In this study, incubation of explants from such seedlings with [14C]biliverdin IX alpha led to rapid covalent incorporation of radiolabel into a single 124-kDa polypeptide in soluble protein extracts. Immunoprecipitation experiments confirmed that this protein was phytochrome. Parallel experiments were performed with four unlabeled linear tetrapyrroles, the naturally occurring biliverdin IX alpha isomer, two non-natural isomers, biliverdin XIII alpha and biliverdin III alpha, and phycocyanobilin-the cleaved prosthetic group of the light-harvesting antenna protein C-phycocyanin. In all cases, except for the III alpha isomer of biliverdin, a time-dependent recovery of photoreversible phytochrome was observed. The newly formed phytochrome obtained after incubation with biliverdin IX alpha exhibited spectral characteristics identical with those of the native protein. In contrast, the spectral properties of phytochromes formed during incubation with biliverdin XIII alpha and phycocyanobilin differed significantly from those of the native chromoprotein. These results indicate that biliverdin IX alpha is an intermediate in the biosynthesis of the phytochrome chromophore and that phytochromes with prosthetic groups derived from bilatrienes having non-natural D-ring substituents are photochromic.