Abstract
A spectral, immunochemical, and proteolytic characterization of native 120-kilodalton (kD) phytochrome from Cucurbita pepo L. is presented and compared with that previously reported for native 124-kD phytochrome from Avena sativa. The molecule was partially purified ( approximately 200-fold) in the phytochrome-far red-absorbing form (Pfr) in the presence of the protease inhibitor, phenylmethylsulfonyl fluoride, using a modification of the procedure initially developed to purify 124-kD Avena phytochrome. The spectral properties of the preparations obtained are indistinguishable from those described for 124-kD Avena phytochrome, including a Pfr lambda(max) at 730 nanometers, a spectral change ratio (DeltaA(r)/DeltaA(fr)) of 1.05, and negligible dark reversion of Pfr to the red-absorbing form (Pr) in the presence or absence of sodium dithionite. This lack of dark reversion in vitro contrasts with observations that Cucurbita phytochrome, like phytochrome from most other dicotyledons, exhibits substantial dark reversion in vivo. Ouchterlony double immunodiffusion analysis with polyclonal antibodies indicates that 120-kD Cucurbita phytochrome is immunologically dissimilar to 124-kD Avena phytochrome. However, despite this dissimilarity, immunoblot analyses of proteolytic digests have identified at least three spatially separate epitopes that are common to both phytochromes. Using endogeneous protease(s), a peptide map for Cucurbita phytochrome has been constructed and the role that specific domains play in the overall structure of the photoreceptor has been examined. One domain near the NH(2) terminus is critical to the spectral integrity of the molecule indicating that this domain plays a structural role analogous to that of a domain near the NH(2) terminus of Avena phytochrome. Proteolytic removal of this domain occurs preferentially in Pr and its removal shifts the Pfr lambda(max) to 722 nm, increases the spectral change ratio to 1.3, and substantially enhances the dark reversion rate. The apparent conservation of this domain among evolutionarily divergent plant species and its involvement in a conformational change upon photoconversion makes it potentially relevant to the mechanism(s) of phytochrome action. Preliminary evidence from gel filtration studies suggests that the 55-kD chromophoreless COOH-terminal region of the polypeptide contains a domain responsible for dimerization of phytochrome monomers.