A 30-year-old woman presents to her physician for her annual checkup. She has diabetes mellitus, type 1 and takes insulin regularly. She reports no incidents of elevated or low blood sugar and that she is feeling energetic and ready to face the morning every day. Her vital signs and physical are normal. On the way home from her checkup she stops by the pharmacy and picks up her prescription of insulin. Later that night she takes a dose. What is the signaling mechanism associated with this medication?

Increased concentration intracellular cAMP

Increased permeability of the cell membrane to negatively charged molecules

Rapid and direct upregulation of enzyme transcription

Increased permeability of the cell membrane to positively charged molecules

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

An experimental compound added to a protein disrupts both alpha helices as well as beta-pleated sheets. Which of the following has the experimental compound affected?

Hydrogen bonds between amino acids

Ionic bonds between amino acids

Covalent peptide bonds between amino acids

Disulfide bonds between amino acids

The primary structure of the protein

An investigator is studying a hereditary defect in the mitochondrial enzyme succinyl-CoA synthetase. In addition to succinate, the reaction catalyzed by this enzyme produces a molecule that is utilized as an energy source for protein translation. This molecule is also required for which of the following conversion reactions?

Oxaloacetate to phosphoenolpyruvate

Glucose-6-phosphate to 6-phosphogluconolactone

Fructose-6-phosphate to fructose-1,6-bisphosphate

A 24-year-old man comes to the physician because of chronic fatigue and generalized weakness after exertion. His legs feel stiff after walking long distances and he has leg cramps after climbing stairs. His symptoms are always relieved by rest. Urine dipstick shows 3+ blood and urinalysis is negative for RBCs. Baseline venous lactate and serum ammonia levels are collected, after which a blood pressure cuff is attached to the upper right arm. The patient is asked to continuously pump his right arm with the cuff inflated and additional venous samples are collected at 2-minute intervals. Analysis of the venous blood samples shows that, over time, serum ammonia levels increase and venous lactate levels remain stable. A biopsy of the right gastrocnemius muscle will most likely show which of the following?

Subsarcolemmal periodic acid–Schiff-positive deposits

Intrafascicular CD8+ lymphocytic infiltration

Endomysial fibrosis with absent dystrophin

Intermyofibrillar proliferation of mitochondria

Perivascular CD4+ lymphocytic infiltrate

A 16-year-old boy comes to the physician because of muscle weakness and cramps for 5 months. He becomes easily fatigued and has severe muscle pain and swelling after 15 minutes of playing basketball with his friends. The symptoms improve after a brief period of rest. After playing, he sometimes also has episodes of reddish-brown urine. There is no family history of serious illness. Serum creatine kinase concentration is 950 U/L. Urinalysis shows: Blood 2+ Protein negative Glucose negative RBC negative WBC 1–2/hpf Which of the following is the most likely underlying cause of this patient's symptoms?

Medium-chain acyl-CoA dehydrogenase deficiency

Low levels of triiodothyronine and thyroxine

Glycogen structure and metabolism overview for USMLE Step 3: High-Yield Biochemistry Lessons

Glycogen Structure - The Body's Sugar Stash

Function: Main storage form of glucose in animals, found primarily in liver and skeletal muscle.
Structure: Large, branched polymer of glucose residues.
- Linear chains: Glucose units linked by $α-1,4$ glycosidic bonds.
- Branch points: Occur every 8-12 residues, created by $α-1,6$ glycosidic bonds.

Glycogen structure: alpha-1,4 and alpha-1,6 bonds

Advantage: Branching creates many non-reducing ends, allowing for rapid synthesis and degradation to maintain glucose homeostasis.

⭐ Glycogenolysis and synthesis occur at the non-reducing ends, allowing for rapid glucose release from multiple points simultaneously.

Glycogenesis - Building the Branchies

Activation: Glucose is converted to Glucose-1-Phosphate (G1P) and then activated by UTP to form UDP-Glucose.
- Enzyme: UDP-glucose pyrophosphorylase.
Elongation (Rate-Limiting): Glycogen synthase adds UDP-glucose to the non-reducing end of a glycogen primer, forming linear $α-1,4$ glycosidic bonds.
Branching: Branching enzyme (amylo-$α-1,4$ → $α-1,6$-transglucosidase) transfers a segment of a linear chain to create an $α-1,6$ branch point.
- This increases glycogen solubility and the number of terminal residues for rapid synthesis or degradation.

⭐ Insulin stimulates glycogenesis by activating protein phosphatase, which dephosphorylates and activates glycogen synthase.

Glycogenolysis - Tapping the Reserve

Primary Goal: Maintain blood glucose homeostasis (liver) & provide immediate fuel for glycolysis (muscle).
Key Enzymes:
- Glycogen Phosphorylase: Rate-limiting enzyme. Cleaves α-1,4 glycosidic bonds using inorganic phosphate ($P_i$) to release Glucose-1-Phosphate. Requires Vitamin B6 (PLP) as a cofactor.
- Debranching Enzyme: Possesses two distinct catalytic activities:
  - 4-α-D-glucanotransferase: Transfers 3 glucose residues from a limit branch to the non-reducing end of another chain.
  - α-1,6-glucosidase: Hydrolyzes the single remaining α-1,6 bond to release free glucose.
Regulation:
- Activation: Glucagon (liver), Epinephrine (liver & muscle) via ↑cAMP.
- Inhibition: Insulin via protein phosphatase activation.

⭐ Muscle lacks Glucose-6-Phosphatase. Thus, muscle glycogen provides ATP for the muscle itself and cannot directly contribute to blood glucose levels.

Hormonal Regulation - Metabolic Master Control

Insulin (Well-fed state): High insulin/glucagon ratio promotes glycogen storage (dephosphorylation).
- Activates protein phosphatase, which dephosphorylates key enzymes.
- ↑ Glycogen Synthase activity (active when dephosphorylated).
- ↓ Glycogen Phosphorylase activity (inactive when dephosphorylated).
Glucagon & Epinephrine (Fasting/Stress): Low insulin/glucagon ratio promotes glycogenolysis (phosphorylation).
- Activate PKA via cAMP (Glucagon, β-receptors) or Ca²⁺/PKC (α₁-receptors).
- ↓ Glycogen Synthase activity.
- ↑ Glycogen Phosphorylase activity.

⭐ Muscle lacks glucagon receptors; its glycogenolysis responds to epinephrine but not glucagon. Muscle glycogen is for local use, not blood glucose maintenance.

Hormonal regulation of glycogen metabolism

High‑Yield Points - ⚡ Biggest Takeaways

Glycogen, the primary storage form of glucose, resides mainly in the liver and skeletal muscle.

Liver glycogen maintains blood glucose homeostasis; muscle glycogen serves as a local energy reserve.

Structurally, it has α-1,4 glycosidic bonds (linear) and α-1,6 glycosidic bonds (branch points).

Key enzymes: Glycogen synthase (synthesis) and glycogen phosphorylase (degradation).

Insulin stimulates synthesis; glucagon and epinephrine stimulate breakdown.

Branching increases solubility and creates numerous non-reducing ends for rapid glucose mobilization.

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