Table of Contents
- 1 How many molecules of ATP and Nadph are used in each turn of the Calvin cycle?
- 2 How many ATP and Nadph molecules are required for synthesis of one?
- 3 How many molecules of ATP and NADPH are required in the formation of two molecules of glucose how many Calvin cycles are required?
- 4 How many NADPH are used in c3 cycle?
- 5 How many ATP and NADPH are required for 2 Calvin cycles?
- 6 How many ATP are required to produce one molecule of RuBP?
How many molecules of ATP and Nadph are used in each turn of the Calvin cycle?
The Calvin cycle uses 18 ATP and 12 NADPH molecules to produce one glucose molecule.
How many ATP and Nadph are used in the second phase?
Stage 2: Reduction Six molecules of both ATP and NADPH are used. For ATP, energy is released with the loss of the terminal phosphate atom, converting it to ADP; for NADPH, both energy and a hydrogen atom are lost, converting it into NADP+.
How many ATP and Nadph are made in photosynthesis?
The diagram represents one complete turn of the cycle, with the net production of one molecule of Gal3P. The nine molecules of ATP and six molecules of NADPH come from the light reactions.
How many ATP and Nadph molecules are required for synthesis of one?
36 ATP, 24 NADPH, 12 Calvin cycles.
How many molecules of ATP and NADPH are used in the Calvin cycle quizlet?
In each turn of the cycle, there are three molecules of ATP and two molecules of NADPH are used.
How many ATP and NADPH are used in C4 cycle?
In the PEP-CK-type C4 photosynthesis, 0.6 ATP and 0.3 NADPH are estimated to be required per fixed CO2 in M cells during the C4 metabolic cycle.
How many molecules of ATP and NADPH are required in the formation of two molecules of glucose how many Calvin cycles are required?
So, calculating the basics we can see that to produce about 2 glucose molecules we need 36 ATP, 24 NADPH, as well as 12 turns of Calvin cycle, are required.
How many ATP and NADPH molecules are there?
24 ATP, 36 NADPH, 12 Calvin cycles.
How many ATP are used in photosynthesis?
Glucose combines with oxygen (oxidation), forming carbon dioxide, water and 38 molecules of ATP.
How many NADPH are used in c3 cycle?
144 NADPH, 216 ATP molecules are used in the Calvin cycle for the production of trioses required for the synthesis of 6 sucrose molecules.
How many molecules of ATP and Nadph are required in the formation of two molecules of glucose how many Calvin cycles are required?
How many molecules of ATP and Nadph are required in the formation of three molecules?
Therefore 9 ATP and 6 NADPH molecules are required for three turns of calvin cycle that will result in the formation of glyceraldehyde 3-phosphate.
How many ATP and NADPH are required for 2 Calvin cycles?
Hence, for two calvin cycles, total of 18 ATP molecules and 12 NADPH molecules are required. For every three turns, one molecule of G3P exits the cycle to form half molecule of glucose. For every six turns, two molecules of G3P exits the cycle to form one molecule of glucose.
How many ATP and NADPH are required to produce one molecule glucose?
To produce one molecule of glucose, two calvin cycles are required. Hence, for two calvin cycles, total of 18 ATP molecules and 12 NADPH molecules are required. For every three turns, one molecule of G3P exits the cycle to form half molecule of glucose. For every six turns, two molecules of G3P exits the cycle to form one molecule of glucose.
Why is rurubp regenerated in the Calvin cycle?
RuBP is thus regenerated to begin the cycle again. G3P produced by the Calvin cycle is the raw material used to synthesize glucose and other carbohydrates. The Calvin cycle uses 18 ATP and 12 NADPH molecules to produce one glucose molecule.
How many ATP are required to produce one molecule of RuBP?
Also, 3 ATP molecules are required to form ribulose bisphosphate (RuBP). To produce one molecule of glucose, two calvin cycles are required. Hence, for two calvin cycles, total of 18 ATP molecules and 12 NADPH molecules are required. For every three turns, one molecule of G3P exits the cycle to form half molecule of glucose.