High speed filming reveals protein changes during photosynthesis

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Photosynthesis is the primary source of energy for almost all life-on-earth. A new study, published in Nature, provide new insight into how evolution has optimized the light-driven movements of electrons in photosynthesis to achieve almost perfect overall efficiency.   

Almost all life on earth has the energy-transducing reactions of photosynthesis as their primary source of energy. These light-driven reactions occur in plants, algae and photosynthetic bacteria.

An X-ray structure of a protein provides scientists with a lot of information as to how they perform their biological task in a living cell.

X-ray films show structural changes within a protein
In this work scientists used a method called time-resolved X-ray crystallography to make a movie of structural changes within the protein responsible for the light-driven chemical reactions of photosynthesis. To achieve this scientists at the University of Gothenburg used a world-leading X-ray source in California (an X-ray free electron laser) to examine if structural rearrangements within photosynthetic proteins occur on the time-it-takes light to cross a hair of your head. Remarkably, these measurements showed that the protein changes structure on this time-scale.

Subtle movements in the protein were seen
Scientists at the University of Gothenburg observed that these movements were very subtle, with both the electron donor (a chemical group which absorbs light and releases an electron) and the electron acceptor (a chemical group which is located 2 nm away and which receives this electron) moving less than 0.03 nm (1 nm =  10-9 m or a millionth of a millimeter) in 300 ps (1 ps = 10-12 sec is called a picosecond and is a millionth of a millionth of a second).

The protein as a whole also changed structure very slightly in order to prevent the electron returning to where it began, which would otherwise make the reaction useless. These results are fundamental to how evolution has optimized energy transducing proteins over billions of years to allow them to perform redox reactions without energy being lost in the process.

–  Time-resolved crystallography studies of a photosynthetic protein from bacteria reveal how light-induced electron movements are stabilized by protein structural changes occurring on a time-scale of picoseconds, says Richard Neutze, professor at the University of Gothenburg.

At MAX IV Laboratory in Lund Sweden is building a beamline which will enable scientists to study how protein structural changes occur in other biologically important proteins using the same methods.

Contact:
Richard Neutze (Phone: (+46) 0738- 536622; email: richard.neutze@gu.se)

Gisela Brändén, universitetslektor vid institutionen för kemi och molekylärbiologi vid Göteborgs universitet. email: gisela.branden@gu.se
Petra Båth, postdok, email: petra.bath@gu.se

Article: Ultrafast structural changes within a photosynthetic reaction centre, Robert Dods et al., Nature (2020). https://doi.org/10.1038/s41586-020-3000-7

Photo:
Light causes an electron (e-) to move from one side of a photosynthetic reaction center to the other (red arrow). This movement of an electron stores energy across a biological membrane. The protein’s structure adjusts in response (moving regions marked in red).

Portrait of Richard Neutze.


Carina Eliasson
Pressansvarig kommunikatör
Göteborgs universitet
telefon: 031-786 98 73

e-post: carina.eliasson@science.gu.se

University of Gothenburg is one of the major universities in Europe, with about 47 500 students and a staff of 6 400. Its eight faculties offer training in the Creative Arts, Social Sciences, Natural Sciences, Humanities, Education, Information Technology, Business, Economics and Law, and Health Sciences. The University’s unique breadth in education and research provides an interdisciplinary environment conducive to collaboration with private enterprise and public institutions. The quality of the University has earned recognition in the form of numerous awards, including a Nobel Prize, and a steady stream of applicants at all levels.

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