Qr: journal:"J Photochem Photobiol B"
Showing 1 - 4 of 4 results
1.
Structural insights into photo-state-specific binding of affibody Aff6 to the photosensory core module of DrBphP.
Abstract:
Light-inducible heterodimerization systems offer precise, reversible control of protein interactions in living cells. Leveraging the high tissue-penetration of red/far-red light, the MagRed system, composed of a bacteriophytochrome Deinococcus radiodurans BphP (DrBphP) and its engineered affibody binder Aff6, achieves robust photoswitchable dimerization. This makes MagRed well-suited for in vivo and deep-tissue optogenetic application. However, the structural mechanism underlying Aff6's photo-state-specific recognition of DrBphP remains elusive. Here, we combine solution NMR spectroscopy, surface plasmon resonance (SPR), molecular docking and mutational analysis to elucidate the light-dependent interaction between a monomeric photosensory core module of DrBphP (DrBphP-PCMmono) and Aff6. We show that DrBphP-PCMmono alone is sufficient for light-inducible heterodimerization with Aff6, exhibiting a ∼ 23-fold affinity difference between the Pfr and Pr states. NMR titration reveals that Aff6 binds primarily to the PHY domain and the C-terminal region of the helical spine. Furthermore, docking and mutagenesis identify a key aromatic interaction (involving F327/H334 of DrBphP and F18 of Aff6) as the molecular basis for this conformational selectivity. Additionally, Aff6 binding stabilizes the Pfr state and retards the Pfr-to-Pr reversion of DrBphP-PCMmono. These findings not only provide critical structural insight into MagRed function but also establish a foundation for rationally engineering next-generation phytochrome-based optogenetic tools.
2.
Red/far-red light optogenetics: technological principles and biomedical applications.
Abstract:
As an interdisciplinary frontier integrating optical technologies and genetic principles, optogenetics enables precise spatiotemporal control of gene expression and neuronal activity via light-sensitive molecular assemblies, thereby driving transformative advancements in biomedical fields. Red/far-red light optogenetic tools, by virtue of the advantages of long wavelengths, have emerged as powerful platforms for deep-tissue manipulations for both basic researches and clinical applications. Although a number of in-depth studies on various red/far-red light optogenetic tools and their biomedical applications have been published, there has not yet been a comprehensive review that systematically summarizes the advancements of diverse researches on this type of optogenetics. This article systematically delineates the technology of red/far-red light optogenetics, focusing on the molecular mechanisms and biomedical applications of two core photoreceptor protein families: phytochromes and channelrhodopsins. Phytochromes distributed in plants, bacteria and fungi undergo reversible red/far-red light-driven conformational conversion, initiating downstream signaling cascades that support various optogenetic technologies. Channelrhodopsins, originally microalgal blue-light-gated cation channels, are engineered into red-shifted variants, enabling rapid and non-invasive red/far-red light-controlled neuronal excitability manipulation at precise spatiotemporal resolution. The representative case studies of applications of phytochromes-based optogenetic tools in gene editing, transcriptional regulation, light-gated drug delivery and deep tissue imaging and diagnosis; as well as applications of red-shifted channelrhodopsins-based optogenetic tools in spatiotemporally precise neuromodulation are discussed in detail. Moreover, the main technical challenges in the utilization of red/far-red light optogenetic tools are analyzed. With continuous advancements of wavelength-optimized actuators and closed-loop control architectures, red/far-red light optogenetic techniques are poised to drive multidisciplinary convergence, offering unprecedented tools for decoding cellular dynamics and accelerating therapeutic discoveries.
3.
Why is CarH photolytically active in comparison to other B12-dependent enzymes?
Abstract:
The discovery of naturally occurring B12-depedent photoreceptors has allowed for applications of cobalamins (Cbls) in optogenetics and synthetic biology to emerge. However, theoretical investigations of the complex mechanisms of these systems have been lacking. Adenosylcobalamin (AdoCbl)-dependent photoreceptor, CarH, is one example and it relies on daylight to perform its catalytic function. Typically, in enzymes employing AdoCbl as their cofactor, the Co-C5' bond activation and cleavage is triggered by substrate binding. The cleavage of the Co-C5' bond is homolytic resulting in radical pair formation. However, in CarH, this bond is instead activated by light. To explore this peculiarity, the ground and first excited state potential energy surfaces (PESs) were constructed using the quantum mechanics/molecular mechanics (QM/MM) framework and compared with other AdoCbl-dependent enzymes. QM/MM results indicate that CarH is photolytically active as a result of the AdoCbl dual role, acting as a radical generator and as a substrate. Photo-cleavage of the Co-C5' bond and subsequent H-atom abstraction is possible because of the specific orientation of the H-C4' bond with respect to the Co(II) center. Comparison with other AdoCbl-dependent enzymes indicate that the protein environment in the CarH active center alters the photochemistry of AdoCbl by controlling the stereochemistry of the ribose moiety.
4.
Photo-dynamics of photoactivated adenylyl cyclase TpPAC from the spirochete bacterium Turneriella parva strain H(T).
Abstract:
The photoactivated adenylyl cyclase TpPAC from the spirochete bacterium Turneriella parva was synthesized and the purified recombinant protein was characterized by biochemical and optical spectroscopic methods. TpPAC consists of a BLUF domain (BLUF = Blue Light sensor Using Flavin) and an adenylyl cyclase homology domain (CHD). A light induced cAMP cyclase activity of ≈ 53.3 nmolmg(-1)min(-1) was measured while in the dark the cyclase activity was approximately a factor of 240 lower. The photo-cycling dynamics of the BLUF domain of TpPAC was studied by absorption spectra, fluorescence quantum distribution, and fluorescence lifetime measurements. The quantum efficiency of BLUF domain signaling state formation was found to be ϕs ≈ 0.59. A three-component exponential recovery of the signaling state to the receptor state was observed with the time constants τrec,1 = 4.8s, τrec,2 = 34.2s, and τrec,3 = 293s at 21.3 °C. The protein thermal stability was studied by stepwise sample heating and cooling. An apparent TpPAC melting temperature of ϑm ≈ 46 °C was determined. The photo-degradation of TpPAC in the signaling state was studied by prolonged intense light exposure at 455 nm. An irreversible flavin photo-degradation was observed with quantum yield ϕD ≈ 8.7 × 10(-6).