‘Searching for molecules’ flow at the level of cytoB flow at the level of cytome B6f using optical and paramedical (Q84325): Difference between revisions
Jump to navigation
Jump to search
(Removed claim: summary (P836): Photosynthesis is a European Union for the purposes of the European Parliament and of the Council of the European Union.In this process, the application of Cyclic and linear intervals of CO2 into organic forms.Where the molecular mechanisms of regulation between CET and LET remarly unknown, cytochrome (cite) B6f complex is written to be a key point of it.Hypotassise that a newly DISCOVERED metastatic radiate of cyt B6f provides means for KINET...) |
(Created claim: summary (P836): Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesise that a newly discovered metastable radical interm...) |
||||||||||||||
| Property / summary | |||||||||||||||
Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesise that a newly discovered metastable radical intermediate of cyt b6f provides means for kinetic control to balance between LET and CET. From this perspective, we will seek to unravel structural basis and dynamics of interaction between cyt b6f and its Plausible CET protein partners, define the sequence of electron transfer steps that engage cyt b6f into CET and describe thermodynamic basis for control of CET. This will provide fundamentals for understanding regulation of photosynthesis, as a step towards development of enhanced photosynthetic organisms to increase efficiency in plant production. (English) | |||||||||||||||
| Property / summary: Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesise that a newly discovered metastable radical intermediate of cyt b6f provides means for kinetic control to balance between LET and CET. From this perspective, we will seek to unravel structural basis and dynamics of interaction between cyt b6f and its Plausible CET protein partners, define the sequence of electron transfer steps that engage cyt b6f into CET and describe thermodynamic basis for control of CET. This will provide fundamentals for understanding regulation of photosynthesis, as a step towards development of enhanced photosynthetic organisms to increase efficiency in plant production. (English) / rank | |||||||||||||||
Normal rank | |||||||||||||||
| Property / summary: Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesise that a newly discovered metastable radical intermediate of cyt b6f provides means for kinetic control to balance between LET and CET. From this perspective, we will seek to unravel structural basis and dynamics of interaction between cyt b6f and its Plausible CET protein partners, define the sequence of electron transfer steps that engage cyt b6f into CET and describe thermodynamic basis for control of CET. This will provide fundamentals for understanding regulation of photosynthesis, as a step towards development of enhanced photosynthetic organisms to increase efficiency in plant production. (English) / qualifier | |||||||||||||||
point in time: 14 October 2020
| |||||||||||||||
Revision as of 12:36, 14 October 2020
Project in Poland financed by DG Regio
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | ‘Searching for molecules’ flow at the level of cytoB flow at the level of cytome B6f using optical and paramedical |
Project in Poland financed by DG Regio |
Statements
3,499,570.0 zloty
0 references
3,499,570.0 zloty
0 references
100.0 percent
0 references
1 December 2018
0 references
30 November 2021
0 references
UNIWERSYTET JAGIELLOŃSKI
0 references
Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesize that a newly discovered metastable radical intermediate of cyt b6f provides means for kinetic control to balance between LET and CET. From this perspective, we will seek to unravel structural basis and dynamics of interaction between cyt b6f and its plausible CET protein partners, define the sequence of electron transfer steps that engage cyt b6f into CET and describe thermodynamic basis for control of CET. This will provide fundamentals for understanding regulation of photosynthesis, as a step towards development of enhanced photosynthetic organisms to increase efficiency in plant production. (Polish)
0 references
Photosynthesis is a crucial energy conserving process supporting life on earth. In this process, accommodation of cyclic and linear electron flow (CET and LET, respectively) secures efficiency of reduction of CO2 into organic form. While molecular mechanisms of regulation between CET and LET remain largely unknown, cytochrome (cyt) b6f complex is considered to be a key point of it. We hypothesise that a newly discovered metastable radical intermediate of cyt b6f provides means for kinetic control to balance between LET and CET. From this perspective, we will seek to unravel structural basis and dynamics of interaction between cyt b6f and its Plausible CET protein partners, define the sequence of electron transfer steps that engage cyt b6f into CET and describe thermodynamic basis for control of CET. This will provide fundamentals for understanding regulation of photosynthesis, as a step towards development of enhanced photosynthetic organisms to increase efficiency in plant production. (English)
14 October 2020
0 references
Identifiers
POIR.04.04.00-00-5B54/17
0 references