A scientist is trying to design a drug to modulate cellular metabolism in the treatment of obesity. Specifically, he is interested in understanding how fats are processed in adipocytes in response to different energy states. His target is a protein within these cells that catalyzes catabolism of an energy source. The products of this reaction are subsequently used in gluconeogenesis or β-oxidation. Which of the following is true of the most likely protein that is being studied by this scientist?

It is stimulated by epinephrine

It is inhibited by acetylcholine

A 2-month-old Middle Eastern female infant from a consanguinous marriage presents with seizures, anorexia, failure to thrive, developmental delay, and vomiting and fatigue after eating. Blood work demonstrated levels of methylmalonic acid nearly 500 times normal levels. A carbon-14 propionate incorporation assay was performed on the fibroblasts of the patient and compared to a healthy, normal individual. Little to none of the radiolabeled carbons of the propionate appeared in any of the intermediates of the Krebs cycle. Which of the following reactions is not taking place in this individual?

Methylmalonyl-CoA --> Succinyl-CoA

Acetyl-CoA + CO2 --> Malonyl-CoA

Propionyl-CoA --> Methylmalonyl-CoA

Acetyl-CoA + Oxaloacetate --> Citrate

During normal respiration in the lungs, oxygen is absorbed into the bloodstream and carbon dioxide is released. The oxygen is used in cells as the final electron acceptor during oxidative phosphorylation, and carbon dioxide is generated during each turn of the tricarboxylic citric acid cycle (TCA). Which of the following steps in the TCA cycle represents the first decarboxylation reaction that generates carbon dioxide?

Isocitrate to alpha ketoglutarate

Alpha-ketoglutarate to Succinyl-CoA

Fatty acid oxidation (beta-oxidation) for USMLE Step 1: High-Yield Biochemistry Lessons

FA Activation & Transport - The Cellular Taxi Service

Activation (Cytoplasm): Fatty acids (FAs) are primed for oxidation by Fatty Acyl-CoA Synthetase, converting them to Fatty Acyl-CoA. This costs 2 ATP equivalents.
Transport (Mitochondria): The carnitine shuttle transports long-chain fatty acids (LCFAs) across the inner mitochondrial membrane. 📌 CARnitine drives the CARnage of fats.

⭐ The rate-limiting enzyme is Carnitine Palmitoyltransferase I (CPT-I). It's inhibited by Malonyl-CoA (from FA synthesis), preventing simultaneous synthesis and breakdown.

Carnitine Shuttle for Fatty Acid Transport into Mitochondria

β-Oxidation Pathway - The Spiral Staircase

Mitochondrial beta-oxidation: Four enzymatic steps

A recurring four-step sequence in the mitochondrial matrix that shortens fatty acyl-CoA chains by two carbons per cycle, yielding key energy precursors.

The Four Steps (Mnemonic: 📌 "O-H-O-T"):
- Oxidation by Acyl-CoA Dehydrogenase.
- Hydration by Enoyl-CoA Hydratase.
- Oxidation by β-Hydroxyacyl-CoA Dehydrogenase.
- Thiolysis by Thiolase.

⭐ Each turn of the spiral generates 1 FADH₂, 1 NADH, and 1 Acetyl-CoA. The process repeats until the entire chain is converted to Acetyl-CoA units.

Energy Yield - Cashing in the Chips

Each round of β-oxidation of a saturated fatty acid produces 1 FADH₂, 1 NADH, and 1 Acetyl-CoA.
The total ATP yield for a $C_{2n}$ fatty acid can be calculated by the formula: $14n - 6$.
- Example (Palmitate, C16; n=8): $(8 imes 10 ext{ ATP}) + (7 imes 2.5 ext{ ATP}) + (7 imes 1.5 ext{ ATP}) - 2 ext{ ATP} = extbf{106}$ ATP net yield.

⭐ Odd-chain fatty acids produce propionyl-CoA in the final round, which can be converted to succinyl-CoA and enter the TCA cycle, making it glucogenic.

Regulation & Odd Chains - Rules & Exceptions

Rate-Limiting Step: Carnitine Palmitoyltransferase I (CPT-I).
- Inhibition: Malonyl-CoA (from FA synthesis) allosterically inhibits CPT-I.
- Hormonal Control: ↑Insulin/glucagon ratio → ↑Malonyl-CoA → ↓β-oxidation.
Odd-Chain Fatty Acids: Final product is Propionyl-CoA (3C), not Acetyl-CoA.

⭐ Vitamin B12 deficiency causes methylmalonic acidemia & aciduria, leading to neurological deficits from abnormal myelin synthesis.

Clinical Correlates - When the Engine Fails

Defects in β-oxidation impair energy production during fasting, leading to a classic triad:
- Hypoketotic hypoglycemia: ↓ glucose with inappropriately low ketones.
- Hepatomegaly and liver dysfunction (↑ LFTs).
- Skeletal myopathy, rhabdomyolysis, and cardiomyopathy.
Medium-Chain Acyl-CoA Dehydrogenase (MCAD) Deficiency:
- Most common defect; presents at 2 months to 2 years.
- Triggers: fasting, infection (e.g., gastroenteritis).
- Labs: ↑ C8-C10 acylcarnitines, dicarboxylic aciduria.
Carnitine Deficiency:
- Impairs long-chain fatty acid transport into mitochondria.
- 📌 CARnitine = CARnage of muscle & heart (weakness, cardiomyopathy).

⭐ During fasting, lack of acetyl-CoA from β-oxidation stalls both ketogenesis and gluconeogenesis (pyruvate carboxylase needs acetyl-CoA), causing the hallmark hypoketotic hypoglycemia.

High-Yield Points - ⚡ Biggest Takeaways

Beta-oxidation occurs in the mitochondria, breaking down fatty acids into acetyl-CoA.

The carnitine shuttle (CPT1) is the rate-limiting step for transporting long-chain fatty acids into the mitochondria.

MCAD deficiency is the most common genetic defect, presenting with hypoketotic hypoglycemia and lethargy.

Each round yields 1 FADH₂, 1 NADH, and 1 acetyl-CoA.

Inhibited by malonyl-CoA and a high NADH/NAD⁺ ratio.

Odd-chain fatty acids yield propionyl-CoA, requiring biotin and B12 for metabolism.

VLCFAs are initially oxidized in peroxisomes.

Continue reading on Oncourse

CONTINUE READING — FREE

or get the app

App Store|Google Play

Fatty acid oxidation (beta-oxidation)