A Novel Photoactive GAF Domain of Cyanobacteriochrome AnPixJ That Shows Reversible Green/Red Photoconversion

Narikawa, Rei; Fukushima, Yasuyuki; Ishizuka, Takami; Itoh, Shigeru; Ikeuchi, Masahiko

doi:10.1016/j.jmb.2008.05.035

Cited by 136 publications

(309 citation statements)

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“…Interestingly, the secondary chemical reaction requires only a few residues within the GAF domain (e.g., the protochromic triad or the second Cys), providing a powerful mechanism for evolution of CBCRs with distinct spectral properties. This work also provides a potential explanation for the spectral sensitivity of members of the red/green CBCR subfamily, proteins that typically exhibit a red/green photocycle, which is the opposite of that seen in green/red CBCRs (17,24). Such CBCRs also might change the bilin protonation state to induce changes in their absorption spectra.…”

Section: Discussionmentioning

confidence: 91%

“…S1C) (19,25). Such a second Cys is not found in CBCR subfamilies sensing green to red light (520-670 nm) (16,17), implicating other mechanisms allowing perception of green light by the intrinsically red-absorbing bilin chromophore.…”

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confidence: 93%

“…* Cyanobacteriochromes (CBCRs) are widespread cyanobacterial photosensors with phytochrome-related GAF domains (1,2,13,14). Although CBCRs also convert between two photostates via bilin photoisomerization at C15, they exhibit much more spectral diversity, with peak absorptions ranging from 330 to 680 nm and hence spanning the entire visible spectrum and near UV (13,(15)(16)(17)(18)(19)(20)(21)(22)(23)(24). CBCR subfamilies that sense light in the near-UV to blue region (330-470 nm) have been studied extensively.…”

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confidence: 99%

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Green/red cyanobacteriochromes regulate complementary chromatic acclimation via a protochromic photocycle

Hirose

Rockwell

Nishiyama

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Cyanobacteriochromes (CBCRs) are cyanobacterial members of the phytochrome superfamily of photosensors. Like phytochromes, CBCRs convert between two photostates by photoisomerization of a covalently bound linear tetrapyrrole (bilin) chromophore. Although phytochromes are red/far-red sensors, CBCRs exhibit diverse photocycles spanning the visible spectrum and the near-UV (330-680 nm). Two CBCR subfamilies detect near-UV to blue light (330-450 nm) via a "two-Cys photocycle" that couples bilin 15Z/15E photoisomerization with formation or elimination of a second bilincysteine adduct. On the other hand, mechanisms for tuning the absorption between the green and red regions of the spectrum have not been elucidated as of yet. CcaS and RcaE are members of a CBCR subfamily that regulates complementary chromatic acclimation, in which cyanobacteria optimize light-harvesting antennae in response to green or red ambient light. CcaS has been shown to undergo a green/red photocycle: reversible photoconversion between a green-absorbing 15Z state ( 15Z P g ) and a red-absorbing 15E state ( 15E P r ). We demonstrate that RcaE from Fremyella diplosiphon undergoes the same photocycle and exhibits light-regulated kinase activity. In both RcaE and CcaS, the bilin chromophore is deprotonated as 15Z P g but protonated as 15E P r . This change of bilin protonation state is modulated by three key residues that are conserved in green/red CBCRs. We therefore designate the photocycle of green/red CBCRs a "protochromic photocycle," in which the dramatic change from green to red absorption is not induced by initial bilin photoisomerization but by a subsequent change in bilin protonation state.light sensing | phycobiliprotein | signal transduction | spectral tuning | two-component signaling P hytochrome photosensors initially were discovered in plants and later found in cyanobacteria, nonoxygenic photosynthetic bacteria, nonphotosynthetic bacteria, fungi, and algae (1, 2). These photoreceptors bind linear tetrapyrrole (bilin) chromophores within a conserved GAF (cGMP phosphodiesterase/adenylyl cyclase/FhlA) domain via a covalent thioether linkage to a conserved Cys residue (Fig. S1A)(3-6). Upon illumination, phytochromes reversibly convert between a red-absorbing dark state and a far-red-absorbing photoproduct. This red/far-red photocycle is triggered by photoisomerization of the bilin 15,16-double bond between the 15Z and 15E configurations (7,8), with 15Z giving red absorption and 15E far-red absorption (4, 6, 9). In phytochromes, the conjugated π system of the bilin is protonated in both photostates, and this protonation is necessary to maintain the red and far-red absorption (10-12). Conserved GAF residues supply a hydrogen bond network to tune the chemical and spectral properties of the bilin (Fig. S1B).* Cyanobacteriochromes (CBCRs) are widespread cyanobacterial photosensors with phytochrome-related GAF domains (1,2,13,14). Although CBCRs also convert between two photostates via bilin photoisomerization at C15, they exhibit much more spe...

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Section: Discussionmentioning

confidence: 91%

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confidence: 93%

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confidence: 99%

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Green/red cyanobacteriochromes regulate complementary chromatic acclimation via a protochromic photocycle

Hirose

Rockwell

Nishiyama

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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“…One class comprises the phytochromes and the related cyano(bacterio)chromes, which have the lyase function integrated into the apo-protein (24,(45)(46)(47)(48)(49). The other autocatalytically assembling chromoprotein is the core-membrane linker of phycobilisomes, ApcE (55).…”

Section: Discussionmentioning

confidence: 99%

Catalytic Mechanism of S-type Phycobiliprotein Lyase

Kupka¹,

Zhang

et al. 2009

Journal of Biological Chemistry

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We now show that CpcS1 binds PCB and PEB rapidly with bi-exponential kinetics (38/119 and 12/8300 ms, respectively). Chromophore binding to the lyase is reversible and much faster than the spontaneous, but low fidelity chromophore addition to the apo-protein in the absence of the lyase. This indicates kinetic control by the enzyme, which then transfers the chromophore to the apo-protein in a slow (tens of minutes) but stereo-and regioselectively corrects the reaction. This mode of action is reminiscent of chaperones but does not require ATP. The amino acid residues Arg-18 and Arg-149 of the lyase are essential for chromophore attachment in vitro and in Escherichia coli, mutations of His-21, His-22, Trp-75, Trp-140, and Arg-147 result in reduced activity (<30% of wild type in vitro). Mutants R147Q and W69M were active but had reduced capacity for PCB binding; additionally, with W69M there was loss of fidelity in chromophore attachment. Imidazole is a noncompetitive inhibitor, supporting a bilin-binding function of histidine. Evidence was obtained that CpcS1 also catalyzes exchange of C-␤84-bound PCB in biliproteins by PEB.Phycobiliproteins are a homologous family of light-harvesting proteins present in cyanobacteria, red algae, and cryptophytes that absorb light in the spectral region between the chlorophyll absorption maxima at ϳ430 and ϳ680 nm: they contain linear tetrapyrroles (phycobilins) of which 1-4 are covalently attached to the subunits by thioether bonds to conserved cysteines (1-4). The chromophores are derived from heme by oxidative ring-opening and subsequent reduction (5) and then attached post-translationally. The correct attachment of most chromophores is catalyzed by lyases. Three phylogenetically unrelated types of lyases have been characterized in cyanobacteria (6). They are specific for certain binding sites and chromophores (7-16), but the reaction mechanisms are still unclear. A chaperone-like action has been proposed for E/Ftype lyases that catalyze chromophore attachment to Cys-84 of ␤-subunits of phyco(erythro)cyanins (17, 18). A more highly evolved function is suggested, however, by concomitant isomerizing reactions catalyzed by certain lyases (12,19,20), and by the finding that most lyases can bind the chromophore and then transfer it to the acceptor protein (15,21).Chromophore binding is particularly pronounced with the S-type lyases. CpcS1 from Nostoc PCC7120 6 rapidly forms an adduct with phycocyanobilin (PCB), 7 and the latter can be transferred in a much slower reaction to cysteine 84 of the ␤-subunits of phycocyanin (CpcB) or phycoerythrocyanin (PecB), suggesting that PCB-CpcS1 is an intermediate of the enzymatic reaction (21). Model reactions of PCB with nucleophiles resulted in the formation of addition products in which the chromophore is isomerized and which are also substrates for a CpcS1-catalzed chromophore transfer to the apo-proteins (20). We now report chromophore binding kinetics obtained by stopped-flow techniques, and identification of functional amino acid residues f...

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“…Curiously, two of these subfamilies feature opposite photocycles: green/red CBCRs have a green-absorbing 15Z dark (ground) state and red-absorbing 15E photoproduct (2), but red/green CBCRs instead have a red-absorbing 15Z dark state and green-absorbing 15E photoproduct (14). The other two subfamilies, insert-Cys and DXCF CBCRs, both make use of additional conserved cysteine residues and typically exhibit a 15Z dark state sensitive to shorter wavelengths (near-UV to blue) and a 15E photoproduct absorbing at longer wavelengths from blue to orange (3,11,12,15).…”

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confidence: 99%