Calvin Cycle Overview

The Calvin-Benson Cycle consists of three main phases that work together to produce sugars from carbon dioxide. It all begins when the enzyme RuBisCO captures CO₂ and attaches it to a 5-carbon molecule called RuBP (ribulose bisphosphate), creating a 6-carbon intermediate that quickly breaks down.

In Phase 1 (Carbon Fixation), CO₂ enters the cycle and combines with RuBP. This creates a short-lived intermediate that breaks down into 3-PGA $3-phosphoglycerate$, a 3-carbon molecule. For every three CO₂ molecules that enter, six 3-PGA molecules are formed.

Phase 2 (Reduction) uses energy from ATP and NADPH (produced during the light reactions) to convert 3-PGA into G3P $glyceraldehyde 3-phosphate$. This requires both the phosphate from ATP and the hydrogen from NADPH to reduce the molecules. Out of six G3P molecules produced, one can exit the cycle to form glucose or other compounds.

Remember This: For every three CO₂ molecules fixed by RuBisCO, only one G3P molecule (3 carbons) can leave the cycle as product, while the remaining five G3P molecules must be recycled to regenerate RuBP.

Phase 3 (Regeneration) uses the remaining five G3P molecules and more ATP to rebuild the three original RuBP molecules, allowing the cycle to continue capturing more carbon dioxide.

Calvin Cycle Energy Flow

The Calvin Cycle is essentially a carbon-fixing factory that runs on the energy captured during the light reactions. When CO₂ combines with RuBP $a 5-carbon molecule$, it initiates a series of reactions that transform carbon dioxide into usable sugar.

The pathway requires precise energy inputs at specific steps. First, ATP provides energy to convert the 3-carbon compounds $3-PGA$ into 1,3-bisphosphoglycerate. Then, NADPH donates high-energy electrons and hydrogen to create G3P $glyceraldehyde 3-phosphate$, which is the first stable product of photosynthesis.

For every six G3P molecules produced, one can exit to form glucose $a 6-carbon sugar$ while the other five remain in the cycle. These five G3P molecules (containing 15 carbon atoms total) are rearranged using additional ATP energy to regenerate three RuBP molecules (each with 5 carbons), completing the cycle.

Pro Tip: Think of the Calvin Cycle as a carbon assembly line where for every three turns of the cycle, you get enough carbon atoms $3 × CO₂ = 3 carbons$ to build half of a glucose molecule (which requires 6 carbons total).