Differential effects of mutations in the chromophore pocket of recombinant phytochrome on chromoprotein assembly and Pr-to-Pfr photoconversion.

Site-directed mutagenesis was performed with the chromophore-bearing N-terminal domain of oat phytochrome A apoprotein (amino acid residues 1-595). Except for Trp366, which was replaced by Phe (W366F), all the residues exchanged are in close proximity to the chromophore-binding Cys321 (i.e. P318A, P318K, H319L, S320K, H322L and the double mutant L323R/Q324D). The mutants were characterized by their absorption maxima, and the kinetics of chromophore-binding and the Pr-->Pfr conversion. The strongest effect of mutation on the chromoprotein assembly, leading to an almost complete loss of the chromophore binding capability, was found for the exchanges of His322 by Leu (H322L) and Pro318 by Lys (P318K), whereas a corresponding alanine mutant (P318A) showed wild-type behavior. The second histidine (H319) is also involved in chromophore fixation, as indicated by a slower assembly rate upon mutation (H319L). For the other mutants, an assembly process very similar to that of the wild-type protein was found. The light-induced Pr-->Pfr conversion kinetics is altered in the mutations H319L and S320K and in the double mutant L323R/Q324D, all of which exhibited a significantly faster I700 decay and accelerated Pfr formation. P318 is also involved in the Pr-->Pfr conversion, the millisecond steps (formation of Pfr) being significantly slower for P318A. Lacking sufficient amounts of W366F, assembly kinetics could not be determined in this case, while the fully assembled mutant underwent the Pr-->Pfr conversion with kinetics similar to wild-type protein.

Recombinant phytochrome of the moss Ceratodon purpureus: heterologous expression and kinetic analysis of Pr-->Pfr conversion.

The phytochrome-encoding gene Cerpu;PHY;2 (CP2) of the moss Ceratodon purpureus was heterologously expressed in Saccharomyces cerevisiae as a polyhistidine-tagged apoprotein and assembled with phytochromobilin (P phi B) and phycocyanobilin (PCB). Nickel-affinity chromatography yielded a protein fraction containing approximately 80% phytochrome. The holoproteins showed photoreversibility with both chromophores. Difference spectra gave maxima at 644/716 nm (red-absorbing phytochrome [Pr]/far-red-absorbing phytochrome [Pfr]) for the PCB adduct, and 659/724 nm for the P phi B-adduct, the latter in close agreement with values for phytochrome extracted from Ceratodon itself, implying that P phi B is the native chromophore in this moss species. Immunoblots stained with the antiphytochrome antibody APC1 showed that the recombinant phytochrome had the same molecular size as phytochrome from Ceratodon extracts. Further, the mobility of recombinant CP2 holophytochrome on native size-exclusion chromatography was similar to that of native oat phytochrome, implying that CP2 forms a dimer. Kinetics of absorbance changes during the Pr-->Pfr photoconversion of the PCB adduct, monitored between 620 and 740 nm in the microsecond range, revealed the rapid formation of a red-shifted intermediate (I700), decaying with a time constant of approximately 110 microseconds. This is similar to the behavior of phytochromes from higher plants when assembled with the same chromophore. When following the formation of the Pfr state, two major processes were identified (with time constants of 3 and 18 ms) that are followed by slow reactions in the range of 166 ms and 8 s, respectively, albeit with very small amplitudes.

Chromophore incorporation, Pr to Pfr kinetics, and Pfr thermal reversion of recombinant N-terminal fragments of phytochrome A and B chromoproteins.

N-Terminal apoprotein fragments of oat phytochrome A (phyA) of 65 kDa (amino acids 1-595) and potato phyB of 66 kDa (1-596) were heterologously expressed in Escherichia coli and in the yeasts Saccharomyces cerevisiae and Pichia pastoris, and assembled with phytochromobilin (PthetaB; native chromophore) and phycocyanobilin (PCB). The phyA65 apoprotein from yeast showed a monoexponential assembly kinetics after an initial steep rise, whereas the corresponding apoprotein from E. coli showed only a slow monoexponential assembly. The phyB66 apoprotein incorporated either chromophore more slowly than the phyA65s, with biexponential kinetics. With all apoproteins, PthetaB was incorporated faster than PCB. The thermal stabilities of the Pfr forms of the N-terminal halves are similar to those known for the full-length recombinant phytochromes: oat phyA65 Pfr is highly stable, whereas potato phyB66 Pfr is rapidly converted into Pr. Thus, neither the C-terminal domain nor homodimer formation regulates this property. Rather, it is a characteristic of the phytochrome indicating its origin from mono- or dicots. The Pr to Pfr kinetics of the N-terminal phyA65 and phyB66 are different. The primary photoproduct I700 of phyA65-PCB decayed monoexponentially and the PthetaB analogue biexponentially, whereas the phyB66 I700 decayed monoexponentially irrespective of the chromophore incorporated. The formation of Pfr from Pr is faster with the N-terminal halves than with the full-length phytochromes, indicating an involvement of the C-terminal domain in the relatively slow protein conformational changes.

Raman spectroscopic and light-induced kinetic characterization of a recombinant phytochrome of the cyanobacterium Synechocystis.

A phytochrome-encoding cDNA from the cyanobacterium Synechocystis has been heterologously expressed in Escherichia coli and reconstituted into functional chromoproteins by incubation with either phycocyanobilin (PCB) or phytochromobilin (PPhiB). These materials were studied by Raman spectroscopy and nanosecond flash photolysis. The Raman spectra suggest far-reaching similarities in chromophore configuration and conformation between the Pfr forms of Synechocystis phytochrome and the plant phytochromes (e.g. phyA from oat), but some differences, such as torsions around methine bridges and in hydrogen bonding interactions, in the Pr state. Synechocystis phytochrome (PCB) undergoes a multistep photoconversion reminiscent of the phyA Pr --> Pfr transformation but with different kinetics. The first process resolved is the decay of an intermediate with red-shifted absorption (relative to parent state) and a 25-micros lifetime. The next observable intermediate grows in with 300 (+/-25) micros and decays with 6-8 ms. The final state (Pfr) is formed biexponentially (450 ms, 1 s). When reconstituted with PPhiB, the first decay of this Synechocystis phytochrome is biexponential (5 and 25 micros). The growth of the second intermediate is slower (750 micros) than that in the PCB adduct whereas the decays of both species are similar. The formation of the Pfr form required fitting with three components (350 ms, 2.5 s, and 11 s). H/D Exchange in Synechocystis phytochrome (PCB) delays, by an isotope effect of 2.7, both growth (300 micros) and decay rates (6-8 ms) of the second intermediate. This effect is larger than values determined for phyA (ca. 1.2) and is characteristic of a rate-limiting proton transfer. The formation of the Pfr state of the PCB adduct of Synechocystis phytochrome shows a deuterium effect similar as phyA (ca. 1.2). Activation energies of the second intermediate in the range 0-18 degrees C are 44 (in H2O/buffer) and 48 kJ mol-1 (D2O), with essentially identical pre-exponential factors.

Large-scale generation of affinity-purified recombinant phytochrome chromopeptide.

Two different yeast expression systems, Pichia pastoris and Hansenula polymorpha, are compared for their capability to express in functional form the 65 kDa N-terminal portion of oat phytochrome A (phyA, spanning amino acids 1-595). The front half of phytochrome was selected for this investigation because it exhibits a greater stability than the full-length protein, and it harbors full spectroscopic and kinetic properties of phytochrome, allowing an exact proof of the functional integrity of the recombinant material. In the comparison between the two expression systems used, special emphasis was given to optimizing the yield of the expression and to improving the quality of the expressed material with respect to the proportion of functional protein. From identical volumes of cell culture, H. polymorpha synthesized between 8- and 10-fold more functional protein than P. pastoris. Following the observation by Wu and Lagarias (Proc. Natl. Acad. Sci. USA 93, 8989-8994, 1996) that P. pastoris endogenously produces the chromophore of phytochrome, phytochromobilin (P phi B) in significant amounts that leads to formation of spectrally active phytochrome during expression, the invention of an alternative high-yield expression system was strongly demanded. A His6-tag was attached to the C-terminus of the recombinant protein, which allows for a convenient and efficient purification and selects the full-length proteins over translationally truncated peptides. Fully reconstituted chromoproteins showed an A660/A280 ratio of > 1.2, indicating the high degree of reconstitutable apoprotein obtained by this procedure. The assembly between apoprotein and the chromophore phycocyanobilin when followed time-resolved yielded a time constant (tau obs) of 35 s. The lambda max values of the red-(Pr) and the far red-absorbing (Pfr) forms of phytochrome (665 and 729 nm) of the recombinant 65 kDa chromopeptide, reconstituted with P phi B are nearly identical to those of native full-length oat phytochrome. The kinetic parameters of the affinity-purified 65 kDa phytochrome chromoprotein for the Pr-->I700--> -->Ptr conversion are compared to those of the recombinant 65 kDa chromoprotein, lacking the His-tag and to wild-type oat phytochrome. Referring to wild-type phytochrome allows determination of whether the recombinant material has lost spectral properties during the purification procedure. The decay of the primary intermediate (I700) occurs with nearly the same time constant for the His-tagged chromoprotein and for the reference (110 and 90 microseconds, respectively). The formation of the Ptr form was fitted with three exponentials in both the His-tagged and the reference chromoprotein with the middle component being slightly smaller and the longest component being remarkably larger for the His-tagged protein (1.5, 10 and 300 ms) than for the reference (1.4, 18 and 96 ms). This selective slowing down of the long kinetic component in the millisecond time range may be indicative of stronger interactions between protein domains involving the C-terminus that in the His-tagged form exhibits increased polarity.