Cyanobacteriochromes (CBCRs) are diverse biliprotein photosensors distantly related to the red/far-red photoreceptors of the phytochrome family. There are several subfamilies of CBCRs, displaying varied spectral responses spanning the entire visible region. Tlr0924 belongs to the DXCF subfamily that utilizes the Cys residue in a conserved Asp-Xaa-Cys-Phe (DXCF) motif to form a second covalent linkage to the chromophore, resulting in a blue-absorbing dark state. Photoconversion leads to elimination of this linkage, resulting in a green-absorbing photoproduct. Tlr0924 initially incorporates phycocyanobilin (PCB) as a chromophore, exhibiting a blue/orange photocycle, but slowly isomerizes PCB to phycoviolobilin (PVB) to yield a blue/green photocycle. Ultrafast transient absorption spectroscopy was used to study both forward and reverse reaction photodynamics of the recombinant GAF domain of Tlr0924. Primary photoproducts were identified, as were subsequent intermediates at 1 ms. PCB and PVB population photodynamics were decomposed using global target analysis. PCB and PVB populations exhibit similar and parallel photocycles in Tlr0924, but the PVB population exhibits faster excited-state decay in both reaction directions. On the basis of longer time analysis, we show that the photochemical coordinate (15,16-isomerization) and second-linkage coordinate (elimination or bond formation at C10) are separate processes in both directions.
Cyanobacteriochromes (CBCRs) are cyanobacterial photoreceptors distantly related to phytochromes. Like phytochromes, CBCRs photointerconvert between two photostates that accompany photoisomerization of their bilin chromophores. While phytochromes typically exhibit red/far-red photocycles, CBCR photocycles are much more diverse, spanning the near-ultraviolet and the entire visible region. All CBCRs described to date have a conserved Cys residue covalently attached to the linear tetrapyrrole (bilin) chromophore; two CBCR subfamilies also exploit a second thioether linkage to the chromophore for detection of near-ultraviolet to blue light. Here, we present the photodynamic analysis of the insert-Cys CBCR NpF2164g3, a representative of the second class of two-cysteine CBCRs. Using broadband transient absorption pump-probe spectroscopy, we characterize the primary (100 fs to 10 ns) and secondary (10 ns to 1 ms) photodynamics in both directions, examining photodynamics over nine decades of time. Primary isomerization dynamics occur on a ~10 ps time scale for both forward and reverse reactions. In contrast to previous studies on Tlr0924, a representative of the other class of two-cysteine CBCRs, formation and elimination of the second linkage are slower than the 1 ms experimental range probed here. These results extend our understanding of dual-cysteine CBCR photocycles in the phytochrome superfamily.
This Note presents a simple and flexible ns-to-ms transient absorption spectrometer based on pulsed light emitting diode (LED) technology that can be incorporated into existing ultrafast transient absorption spectrometers or operate as a stand-alone instrument with fixed-wavelength laser sources. The LED probe pulses from this instrument exhibit excellent stability (∼0.5%) and are capable of producing high signal-to-noise long-time (>100 ns) transient absorption signals either in a broadband multiplexed (spanning 250 nm) or in tunable narrowband (20 ns) operation. The utility of the instrument is demonstrated by measuring the photoinduced ns-to-ms photodynamics of the red/green absorbing fourth GMP phosphodiesterase/adenylyl cyclase/FhlA domain of the NpR6012 locus of the nitrogen-fixing cyanobacterium Nostoc punctiforme.
Rhodopsin is a kinetically stable protein constituting >90% of rod outer segment disk membrane protein. To investigate the bilayer contribution to rhodopsin kinetic stability, disk membranes were systematically disrupted by octyl-β-D-glucopyranoside. Rhodopsin kinetic stability was examined under subsolubilizing (rhodopsin in a bilayer environment perturbed by octyl-β-D-glucopyranoside) and under fully solubilizing conditions (rhodopsin in a micelle with cosolubilized phospholipids). As determined by DSC, rhodopsin exhibited a scan-rate-dependent irreversible endothermic transition at all stages of solubilization. The transition temperature (T(m)) decreased in the subsolubilizing stage. However, once the rhodopsin was in a micelle environment there was little change of the T(m) as the phospholipid/rhodopsin ratio in the mixed micelles decreased during the fully solubilized stage. Rhodopsin thermal denaturation is consistent with the two-state irreversible model at all stages of solubilization. The activation energy of denaturation (E(act)) was calculated from the scan rate dependence of the T(m) and from the rate of rhodopsin thermal bleaching at all stages of solubilization. The E(act) as determined by both techniques decreased in the subsolubilizing stage, but remained constant once fully solubilized. These results indicate the bilayer structure increases the E(act) to rhodopsin denaturation.
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