Three turns of the Calvin Cycle are required to produce a G3P molecule that can be utilized in the synthesis of glucose.
The synthesis of one glucose molecule requires two turns of the Calvin cycle. This process involves a series of reactions that convert carbon dioxide into glucose using the enzyme RuBisCO and other molecules in the pathway.
To produce one molecule of glucose, six molecules of G3P are required.
Six turns of the Calvin cycle are required to produce a molecule of glucose.
Two repeats of the Calvin Cycle are required to produce one glucose molecule.
Six turns of the Calvin Cycle are required to produce one glucose molecule.
The synthesis of one glucose molecule requires two turns of the Calvin cycle. This process involves a series of reactions that convert carbon dioxide into glucose using the enzyme RuBisCO and other molecules in the pathway.
To produce one molecule of glucose, six molecules of G3P are required.
Six turns of the Calvin cycle are required to produce a molecule of glucose.
Two repeats of the Calvin Cycle are required to produce one glucose molecule.
Six turns of the Calvin Cycle are required to produce one glucose molecule.
Six turns of the Calvin Cycle are required to produce one molecule of glucose.
during synthesis, ATP, excess get's stored as glucose. glucose store as starch
Oxygen is the atmospheric molecule required for the complete breakdown of glucose. This process, known as cellular respiration, occurs in the presence of oxygen to convert glucose into energy, carbon dioxide, and water.
When glucose is polymerized to form glycogen or starch, a water molecule is removed during each condensation reaction between glucose molecules. This process is known as dehydration synthesis.
dehydration synthesis, disaccharide
Six turns of the Calvin Cycle are required to produce one molecule of glucose.
Six molecules of G3P are required to produce one molecule of glucose during the Calvin cycle.