Chemiosmotic generation of ATP is driven by a gradient of H+ ions (protons). These protons move from high to low concentration, and in the process, power a protein that phosphorylates ADP into ATP.
Chemisosmosis is generated by hydrogen ions passing through ATP synthases. The ATP synthase are the only patches of the membrane that are permeable to the hydrogen ions. The ATP synthase uses the flow of hydrogen ions to change ADP to ATP since enough energy is released by flow of hydrogen ions through the ATP synthase.
a difference in H+ concentration on the two sides of the mitochondrial membrane.
In cellular respiration, chemiosmotic generation of ATP is driven by oxidative phosphorylation.
the breakdown of glucose.
The chemiosmotic production of ATP through photophosphorylation in photosynthesis is closely related to the chemiosmotic production of ATP through oxidative phosphorylation in cellular respiration. Both processes utilize a proton gradient across a membrane to power the ATP synthase which phosphorylates ADP into ATP.
no
Chemiosmosis in the thylakoid membrane results in the synthesis of ATP during light reaction. Thylakoid membranes contain proteins. These proteins make use of light energy to drive electron transport chains. This generates a chemiosmotic potential across the thylakoid membrane and NADPH. The ATP synthase enzyme uses the chemiosmotic potential to make ATP during photo- phosphorylation.
Chemiosmotic phosphorylation
Mitochondria
The chemiosmotic production of ATP through photophosphorylation in photosynthesis is closely related to the chemiosmotic production of ATP through oxidative phosphorylation in cellular respiration. Both processes utilize a proton gradient across a membrane to power the ATP synthase which phosphorylates ADP into ATP.
both photosynthesis and respiration
The chemiosmotic hypothesis claims electron transport chains generate ATP indirectly, by the creation of a proton-motive force.
This process occurs during the light reactions of photosynthesis.
oxidative phosphorylation does not involve with the respiratory complex in the inner mitochondria membrane. Oxidative phosphorylation useful in generate the production of ATP from the proton gradient or proton motive force. Chemiosmotic coupling invilve the manner of ETC on how its create the proton gradient and the proton gradient is indirectly directed with the production of ATP.The proton gradient causes the conformational change of tigthly binding of ATP to open binding ATP .Then ATP can be released and be used to the metabolic cell needs and translocate the ATP to cytoplasm that can be used to phosphorylate substrate.
no
Chemiosmosis in the thylakoid membrane results in the synthesis of ATP during light reaction. Thylakoid membranes contain proteins. These proteins make use of light energy to drive electron transport chains. This generates a chemiosmotic potential across the thylakoid membrane and NADPH. The ATP synthase enzyme uses the chemiosmotic potential to make ATP during photo- phosphorylation.
Mitochondria.
Model Driven Generation
The light-dependent reactions take place on the thylakoid membranes in the chloroplasts. It takes place here because the membranes have the proteins for an electron transport chain as well as a natural barrier to make a chemiosmotic barrier that can be utilized by the ATP synthase to produce ATP.
Coupled reaction
It ends up in the chlorophyll. Also, the electron flow produces ATP and NADPH.