Previous studies have shown that the room temperature photocycle of the photoactive yellow protein (PYP) from Ectothiorhodospira halophila involves at least two intermediate species: I1, which forms in <10 ns and decays with a 200-micros lifetime to I2, which itself subsequently returns to the ground state with a 140-ms time constant at pH 7 (Genick et al. 1997. Biochemistry. 36:8-14). Picosecond transient absorption spectroscopy has been used here to reveal a photophysical relaxation process (stimulated emission) and photochemical intermediates in the PYP photocycle that have not been reported previously. The first new intermediate (I0) exhibits maximum absorption at approximately 510 nm and appears in =3 ps after 452 nm excitation (5 ps pulse width) of PYP. Kinetic analysis shows that I0 decays with a 220 +/- 20 ps lifetime, forming another intermediate (Idouble dagger0) that has a similar difference wavelength maximum, but with lower absorptivity. Idouble dagger0 decays with a 3 +/- 0.15 ns time constant to form I1. Stimulated emission from an excited electronic state of PYP is observed both within the 4-6-ps cross-correlation times used in this work, and with a 16-ps delay for all probe wavelengths throughout the 426-525-nm region studied. These transient absorption and emission data provide a more detailed understanding of the mechanistic dynamics occurring during the PYP photocycle.
To understand how the protein and chromophore components of a light-sensing protein interact to create a light cycle, we performed time-resolved spectroscopy on site-directed mutants of photoactive yellow protein (PYP). Recently determined crystallographic structures of PYP in the ground and colorless I2 states allowed us to design mutants and to study their photosensing properties at the atomic level. We developed a system for rapid mutagenesis and heterologous bacterial expression for PYP apoprotein and generated holoprotein through formation of a covalent thioester linkage with the p-hydroxycinnamic acid chromophore as found in the native protein. Glu46, replaced by Gln, is buried in the active site and hydrogen bonds to the chromophore's phenolate oxygen in the ground state. The Glu46Gln mutation shifted the ground state absorption maximum from 446 to 462 nm, indicating that the color of PYP can be fine-tuned by the alteration of hydrogen bonds. Arg52, which separates the active site from solvent in the ground state, was substituted by Ala. The smaller red shift (to 452 nm) of the Arg52Ala mutant suggests that electrostatic interactions with Arg52 are not important for charge stabilization on the chromophore. Both mutations cause interesting changes in light cycle kinetics. The most dramatic effect is a 700-fold increase in the rate of recovery to the ground state of Glu46Gln PYP in response to a change in pH from pH 5 to 10 (pKa = 8). Prompted by this large effect, we conducted a careful reexamination of pH effects on the wild-type PYP light cycle. The rate of color loss decreased about 3-fold with increasing pH from pH 5 to 10. The rate of recovery to the colored ground state showed a bell-shaped pH dependence, controlled by two pKa values (6.4 and 9.4). The maximum recovery rate at pH 7.9 is about 16 times faster than at pH 5. The effect of pH on Arg52Ala is like that on wild type except for faster loss of color and slower recovery. These kinetic effects of the mutations and the changes with pH demonstrate that both phases in PYP's light cycle are actively controlled by the protein component.
A phytochrome-like protein called Ppr was discovered in the purple photosynthetic bacterium Rhodospirillum centenum. Ppr has a photoactive yellow protein (PYP) amino-terminal domain, a central domain with similarity to phytochrome, and a carboxyl-terminal histidine kinase domain. Reconstitution experiments demonstrate that Ppr covalently attaches the blue light-absorbing chromophore p-hydroxycinnamic acid and that it has a photocycle that is spectrally similar to, but kinetically slower than, that of PYP. Ppr also regulates chalcone synthase gene expression in response to blue light with autophosphorylation inhibited in vitro by blue light. Phylogenetic analysis demonstrates that R. centenum Ppr may be ancestral to cyanobacterial and plant phytochromes.
Femtosecond time-resolved absorbance measurements were used to probe the subpicosecond primary events of the photoactive yellow protein (PYP), a 14-kD soluble photoreceptor from Ectothiorhodospira halophila. Previous picosecond absorption studies from our laboratory have revealed the presence of two new early photochemical intermediates in the PYP photocycle, I(0), which appears in =3 ps, and I(0)(double dagger), which is formed in 220 ps, as well as stimulated emission from the PYP excited state. In the present study, kinetic measurements at two excitation wavelengths (395 nm and 460 nm) on either side of the PYP absorption maximum (446 nm) were undertaken using 100-fs pump and probe pulses. Global analysis over a range of probe wavelengths yielded time constants of 1.9 ps for the photochemical formation of the I(0) intermediate via the PYP excited state, and 3.4 ps for the repopulation of the ground state from the excited state. In addition to these pathways, 395 nm excitation also initiated an alternative route for PYP excitation and photochemistry, presumably involving a different excited electronic state of the chromophore. No photochemical intermediates formed before I(0) were observed. Based on these data, a quantum yield of 0.5-0.6 for I(0) formation was determined. The structural and mechanistic aspects of these results are discussed.
To understand in atomic detail how a chromophore and a protein interact to sense light and send a biological signal, we are characterizing photoactive yellow protein (PYP), a water-soluble, 14 kDa blue-light receptor which undergoes a photocycle upon illumination. The active site residues glutamic acid 46, arginine 52, tyrosine 42, and threonine 50 form a hydrogen bond network with the anionic p-hydroxycinnamoyl cysteine 69 chromophore in the PYP ground state, suggesting an essential role for these residues for the maintenance of the chromophore's negative charge, the photocycle kinetics, the signaling mechanism, and the protein stability. Here, we describe the role of T50 and Y42 by use of site-specific mutants. T50 and Y42 are involved in fine-tuning the chromophore's absorption maximum. The high-resolution X-ray structures show that the hydrogen-bonding interactions between the protein and the chromophore are weakened in the mutants, leading to increased electron density on the chromophore's aromatic ring and consequently to a red shift of its absorption maximum from 446 nm to 457 and 458 nm in the mutants T50V and Y42F, respectively. Both mutants have slightly perturbed photocycle kinetics and, similar to the R52A mutant, are bleached more rapidly and recover more slowly than the wild type. The effect of pH on the kinetics is similar to wild-type PYP, suggesting that T50 and Y42 are not directly involved in any protonation or deprotonation events that control the speed of the light cycle. The unfolding energies, 26.8 and 25.1 kJ/mol for T50V and Y42F, respectively, are decreased when compared to that of the wild type (29.7 kJ/mol). In the mutant Y42F, the reduced protein stability gives rise to a second PYP population with an altered chromophore conformation as shown by UV/visible and FT Raman spectroscopy. The second chromophore conformation gives rise to a shoulder at 391 nm in the UV/visible absorption spectrum and indicates that the hydrogen bond between Y42 and the chromophore is crucial for the stabilization of the native chromophore and protein conformation. The two conformations in the Y42F mutant can be interconverted by chaotropic and kosmotropic agents, respectively, according to the Hofmeister series. The FT Raman spectra and the acid titration curves suggest that the 391 nm form of the chromophore is not fully protonated. The fluorescence quantum yield of the mutant Y42F is 1.8% and is increased by an order of magnitude when compared to the wild type.
We studied the kinetics of proton uptake and release by photoactive yellow protein (PYP) from Ectothiorhodospira halophila in wild type and the E46Q and E46A mutants by transient absorption spectroscopy with the pH-indicator dyes bromocresol purple or cresol red in unbuffered solution. In parallel, we investigated the kinetics of chromophore protonation as monitored by the rise and decay of the blue-shifted state I(2) (lambda(max) = 355 nm). For wild type the proton uptake kinetics is synchronized with the fast phase of I(2) formation (tau = 500 micros at pH 6.2). The transient absorption signal from the dye also contains a slower component which is not due to dye deprotonation but is caused by dye binding to a hydrophobic patch that is transiently exposed in the structurally changed and partially unfolded I(2) intermediate. This conclusion is based on the wavelength, pH, and concentration dependence of the dye signal and on dye measurements in the presence of buffer. SVD analysis, moreover, indicates the presence of two components in the dye signal: protonation and dye binding. The dye binding has a rise time of about 4 ms and is coupled kinetically with a transition between two I(2) intermediates. In the mutant E46Q, which lacks the putative internal proton donor E46, the formation of I(2) is accelerated, but the proton uptake kinetics remains kinetically coupled to the fast phase of I(2) formation (tau = 100 micros at pH 6.3). For this mutant the protein conformational change, as monitored by the dye binding, occurs with about the same time constant as in wild type but with reduced amplitude. In the alkaline form of the mutant E46A the formation of the I(2)-like intermediate is even faster as is the proton uptake (tau = 20 micros at pH 8.3). No dye binding occurred in E46A, suggesting the absence of a conformational change. In all of the systems proton release is synchronized with the decay of I(2). Our results support mechanisms in which the chromophore of PYP is protonated directly from the external medium rather than by the internal donor E46.
There are previously two known intermediates (I1 and I2) in the room-temperature photocycle of the photoactive yellow protein (PYP) from Ectothiorhodospira halophila. The three-dimensional structures of ground-state PYP and of I2 have shown that light-induced conformational changes are localized to the active site. Previous site-specific mutagenesis studies of PYP in our laboratories have characterized two active site mutants (Glu46Gln and Arg52Ala). We now report the construction and characterization of a mutant at a third active site position (Met100Ala) in order to establish the role of this residue in the photocycle. Met100Ala PYP has an absorption spectrum which is very similar to wild-type (WT) PYP, but exhibits very different kinetic properties. At pH 7.0, the light-induced bleaching reaction (I2 formation) has a half-life <1 microseconds and the recovery in the dark has a half-life of 5.5 min, as compared with half-lives of 100 microseconds and 140 ms for the same reactions in WT PYP. The slow rate of recovery from I2 for Met100Ala results in the accumulation of the bleached intermediate even under room light illumination. These results are qualitatively similar to what has been observed with the Arg52Ala mutant of PYP, and with WT PYP in the presence of alcohols or urea, and suggest that Met100 acts to stabilize the ground state of the protein. The midpoint for guanidine denaturation confirms this. The slow recovery of I2 in the Met100Ala mutant has allowed us to obtain direct evidence that this intermediate species is also photoactive and can be returned to the ground state by a 365 nm laser flash, with kinetics (half-life = 160 microseconds; k = 6300 s-1) which are 6 orders of magnitude faster than dark recovery. This implies that chromophore reisomerization limits the rate of conversion of I2 to the ground state in PYP. Met100 is in van der Waals contact with the chromophore in the I2 state, and we suggest that the sulfur atom catalyzes cis-trans isomerization in WT PYP.
Acid/base titrations of wild-type PYP and mutants, either in buffer or in the presence of chaotropes such as thiocyanate, establish the presence of four spectral forms including the following: a neutral form (446-476 nm), an acidic form (350-355 nm), an alkaline form (430-440 nm), and an intermediate wavelength form (355-400 nm). The acidic species is formed by protonation of the oxyanion of the para-hydroxy-cinnamyl cysteine chromophore as a secondary result of acid denaturation (with pK(a) values of 2.8-5.4) and often results in precipitation of the protein, and in the case of wild-type PYP, eventual hydrolysis of the chromophore thioester bond at pH values below 2. Thus, the large and complex structural changes associated with the acidic species make it a poor model for the long-lived photocycle intermediate, I(2), which undergoes more moderate structural changes. Mutations at E46, which is hydrogen-bonded to the chromophore, have only two spectral forms accessible to them, the neutral and the acidic forms. Thus, an intact E46 carboxyl group is essential for observation of either intermediate or alkaline wavelength forms. The alkaline form is likely to be due to ionization of E46 in the folded protein. We postulate that the intermediate wavelength form is due to a conformational change that allows solvent access to E46 and formation of a hydrogen-bond from a water molecule to the carboxylic acid group, thus weakening its interaction with the chromophore. Increasing solvent access to the intermediate spectral form with denaturant concentration results in a continuously blue-shifted wavelength maximum.
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