News Release

Novel photoreceptor sheds light on how cyanobacteria see color

Scientists highlight diversity and editability in photosensitive molecules

Peer-Reviewed Publication

Tokyo Metropolitan University

Molecular plasticity of cyanobacteriochromes.

image: 

Molecular plasticity of cyanobacteriochromes. 

(left) Scientists have discovered a new CBCR binding PVB (pink) in a family of photoreceptors usually binding PCB (blue). (right) The new CBCR binding PVB (pink) can switch between two differently absorbing states (two curves), giving it sensitivity to green and teal light (top). When three amino acid residues are modified in the CBCR, PVB is isomerized to PCB (blue), changing the nature of the absorbing states completely.

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Credit: Tokyo Metropolitan University

Tokyo, Japan – Scientists from Tokyo Metropolitan University have identified a new photoreceptor in cyanobacteria with a modification in part of its structure which makes it sensitive to green/teal light. The photoreceptor belongs in a family usually sensitive to red/green light in the environment. They identified the parts of its amino acid structure responsible for this behavior; editing them helped restore sensitivity to red and green light, a remarkable example of molecular “plasticity” in action.

 

Cyanobacteria, also known as blue-green algae, are phenomenally important players in shaping the natural world as we know it. They are the first organisms on Earth known to have produced oxygen, using light to break down water molecules. The same chemical process is a distant relative of the photosynthesis seen in plants. The chemical apparatus that helps such processes in cyanobacteria are known as cyanobacteriochromes (CBCRs), cyanobacteria-specific photoreceptors; these are amino acid-based constructs which make them sensitive not only to the amount, but the color of light in the surroundings, helping them acclimate to convert energy as efficiently as possible.

But how exactly do cyanobacteria tell apart color? In the case of CBCRs, they bind a chemical containing a chemical group known as a linear tetrapyrrole. There is a vast range of linear tetrapyrrole pigments, with a color response determined by the length of the cloud of “conjugated” electrons running along. For example, phycocyanobilin (PCB), a blue pigment, will be bound by a CBCR and help it respond to red or green light, switching reversibly between two different absorbing states depending on the ratio of red and green light in the environment. On the other hand, CBCR binding phycoviolobilin (PVB), a pink pigment, will respond to violet or yellow light in a similar way. Interestingly, PCB and PVB are an “isomer” pair, in that they share the same chemical composition, but with double bonds at different positions, drastically switching its color. The way in which pigments bind to CBCRs is remarkably sensitive to its specific structure, as determined by its amino acid sequence, but the ways in which different pigment/CBCR pairs give rise to a whole myriad of responses to light is not yet fully understood.

Now, a team of researchers led by Associate Professor Rei Narikawa from Tokyo Metropolitan University have uncovered another piece of the puzzle, discovering a new CBCR from the family of photoreceptors which should be sensitive to red and green light. Uniquely, this CBCR binds PVB, the pink pigment, and responds to green or teal light. Given the differences with normal PVB binding CBCRs, the team concluded that the pigment was bound to the CBCR in a new, different way. By analyzing the structure carefully, they also identified three key amino acid residues which they determined to be key to this unusual response. Having modified them, the newly edited CBCR could induce the PVB to become PCB again (the blue pigment), restoring sensitivity to red and green light.

The work highlights the remarkable diversity and “plasticity” of CBCRs, the ability to be molded or changed, expanding our understanding of how cyanobacteria can “see” the world in color.

This work was supported by JSPS KAKENHI Grant Number JP22H02587425 and the TMU Research Fund for Young Scientists from Tokyo Metropolitan University.


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