An organism lives solely on Acetate. It has a normal Kreb’s Cycle. Its Electron Transport Chain accepts H from NADH at the first of 3 H pumps and H from FADH at the third of the 3 hydrogen pumps. Therefore, how many ATP does it produce per acetate molecule? 

 

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**Krebs Cycle Diagram Explanation** This diagram illustrates the Krebs Cycle, also known as the Citric Acid Cycle or TCA Cycle, which is a key metabolic pathway occurring in the mitochondria of cells. It plays a crucial role in the production of energy through the oxidation of acetate, derived from carbohydrates, fats, and proteins, into carbon dioxide. **Key Components:** 1. **Acetyl CoA Entry:** The cycle begins when Acetyl CoA donates two carbon atoms, entering the cycle to combine with a four-carbon molecule, forming a six-carbon compound (6C). 2. **Carbon Dioxide Release:** As the cycle progresses, two molecules of carbon dioxide (CO₂) are released. This conversion reduces the six-carbon compound to a five-carbon (5C) and subsequently to a four-carbon (4C) compound. 3. **Energy Carriers:** - **NAD⁺ and FAD:** These are coenzymes that undergo reduction to form NADH + H⁺ and FADH₂ by accepting electrons (symbolized by 2H). - **ATP Production:** Energy is directly synthesized in the form of ATP (adenosine triphosphate), which is the primary energy currency of the cell. 4. **Regeneration:** The cycle regenerates the four-carbon compound to ensure the process is continuous, allowing Acetyl CoA to enter again. 5. **Mitochondrial Context:** The background image represents the mitochondria, indicating where the Krebs cycle occurs within the cell. This cycle is essential for cellular respiration, providing energy for various biological processes by producing ATP and reducing equivalents (NADH and FADH₂) used in the electron transport chain.