Tuesday, December 20, 2022

A small structural change but a large biochemical effect – Structure of a bacteriophytochrome in two states revealed

Peer-Reviewed Publication

UNIVERSITY OF JYVÄSKYLÄ - JYVÄSKYLÄN YLIOPISTO

Phytochrome structures shown in dark and illuminated states 

IMAGE: PHYTOCHROME STRUCTURES SHOWN IN DARK AND ILLUMINATED STATES view more 

CREDIT: HEIKKI TAKALA

Scientist have revealed both dark adapted and light-activated structures of a red photosensory protein, phytochrome. According to the results of the study, almost non-existent structural changes in the regulatory domains can cause large changes elsewhere. The study is published in Nature Communications.

“Nobody has succeeded in this before”

Plants and bacteria adapt to light environment by using various photoreceptor proteins. Phytochromes are a group of photoreceptors that respond to red and far-red light. The function of phytochromes have been studied extensively. Still, their full and biologically relevant structures have remained elusive.

Now, full-length structures of a model bacterial phytochrome, DrBphP, from Deinococcus radiodurans have been revealed in two activity states. “Although many groups have tried, nobody has succeeded to solve a crystal structure of a full-length phytochrome,” explains docent Heikki Takala from the University of Jyväskylä. “We therefore decided to apply cryo-electron microscopy to this model phytochrome.”

Light-triggered structural changes revealed by cryogenic electron microscopy

An international team, including the groups of Dr. Heikki Takala and Prof. Janne Ihalainen from the University of Jyväskylä, have now successfully uncovered the structure of DrBphP. By using single particle cryo-electron microscopy (cryo-EM), they found out that the structure of the full-length phytochrome is symmetrical and relatively well-defined dimer in the dark-adapted state. However, when illuminated with red light, its output histidine kinase module becomes asymmetrical and less defined.

Unlike predicted in previous studies, the light-induced structural changes in the photosensory module were small but amplified only at the output module. “These results show that almost non-existent structural changes in the regulatory domains can cause large changes elsewhere, giving valuable information about signal propagation and allostery in sensory proteins“, concludes Prof. Janne Ihalainen, one of the senior scientists in the team.

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