Cholesterol metabolism

Last updated: November 01, 2022

Cholesterol metabolism

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Gluconeogenesis
Glycogen metabolism
Amino acid metabolism
Fatty acid synthesis
Fatty acid oxidation
Ketone body metabolism
Cholesterol metabolism
Carbohydrates and sugars
Fats and lipids
Proteins
Cellular structure and function
Cell membrane
Selective permeability of the cell membrane
Extracellular matrix
Cell-cell junctions
Endocytosis and exocytosis
Osmosis
Resting membrane potential
Nernst equation
Cell signaling pathways
Cytoskeleton and intracellular motility
Nuclear structure
DNA structure
Transcription of DNA
Translation of mRNA
Amino acids and protein folding
Protein structure and synthesis
Nucleotide metabolism
DNA replication
Lac operon
DNA damage and repair
Cell cycle
Mitosis and meiosis
DNA mutations
Polymerase chain reaction (PCR) and reverse-transcriptase PCR (RT-PCR)
Gel electrophoresis and genetic testing
ELISA (Enzyme-linked immunosorbent assay)
Karyotyping
DNA cloning
Fluorescence in situ hybridization
Mendelian genetics and punnett squares
Hardy-Weinberg equilibrium
Inheritance patterns
Independent assortment of genes and linkage
Gene regulation
Epigenetics
Evolution and natural selection
Bacterial structure and functions
Free radicals and cellular injury
Necrosis and apoptosis
Ischemia
Hypoxia
Inflammation
Atrophy, aplasia, and hypoplasia
Hyperplasia and hypertrophy
Metaplasia and dysplasia
Oncogenes and tumor suppressor genes
Anticoagulants: Heparin
Anticoagulants: Warfarin
Anticoagulants: Direct factor inhibitors
Antiplatelet medications
Thrombolytics
Blood histology
Blood components
Blood groups and transfusions
Platelet plug formation (primary hemostasis)
Coagulation (secondary hemostasis)
Role of Vitamin K in coagulation
Clot retraction and fibrinolysis
Iron deficiency anemia
Beta-thalassemia
Alpha-thalassemia
Sideroblastic anemia
Anemia of chronic disease
Lead poisoning
Hemolytic disease of the newborn
Glucose-6-phosphate dehydrogenase (G6PD) deficiency
Autoimmune hemolytic anemia
Pyruvate kinase deficiency
Paroxysmal nocturnal hemoglobinuria
Sickle cell disease (NORD)
Hereditary spherocytosis
Aplastic anemia
Fanconi anemia
Megaloblastic anemia
Diamond-Blackfan anemia
Chronic leukemia
Acute leukemia
Microcytic anemia: Pathology review
Non-hemolytic normocytic anemia: Pathology review
Intrinsic hemolytic normocytic anemia: Pathology review
Extrinsic hemolytic normocytic anemia: Pathology review
Macrocytic anemia: Pathology review
Heme synthesis disorders: Pathology review
Coagulation disorders: Pathology review
Platelet disorders: Pathology review
Mixed platelet and coagulation disorders: Pathology review
Thrombosis syndromes (hypercoagulability): Pathology review
Lymphomas: Pathology review
Leukemias: Pathology review
Plasma cell disorders: Pathology review
Myeloproliferative disorders: Pathology review
Thymus histology
Spleen histology
Lymph node histology
Introduction to the immune system
Cytokines
Innate immune system
Complement system
T-cell development
B-cell development
MHC class I and MHC class II molecules
T-cell activation
B-cell activation, differentiation, and contraction
Cell-mediated immunity of CD4 cells
Cell-mediated immunity of natural killer and CD8 cells
Antibody classes
Somatic hypermutation and affinity maturation
VDJ rearrangement
Contracting the immune response and peripheral tolerance
B- and T-cell memory
Anergy, exhaustion, and clonal deletion
Vaccinations
Type I hypersensitivity
Type II hypersensitivity
Type III hypersensitivity
Type IV hypersensitivity

Flashcards

Cholesterol metabolism

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Questions

USMLE® Step 1 style questions USMLE

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A research study is performed to better understand the function of a molecule that leads to the stiffening of coronary arteries when found in high concentrations in rat models. An adrenal biopsy isolates the compound, with the chemical structure outlined below. Which of the following describes a critical cellular function of this molecule?  

Transcript

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Cholesterol is a lipid molecule that helps maintain the structure of cell membranes, and is a precursor to steroid hormones, bile acids, and vitamin D.

As it turns out, we make most of our cholesterol ourselves, but some comes through the diet.

Cholesterol synthesis, also called the mevalonate pathway, happens in the smooth endoplasmic reticulum of a cell.

It begins with 2 acetyl-CoA molecules getting joined together by the enzyme acetyl-CoA acyl-transferase.

The result is a 4-carbon molecule called acetoacetyl-CoA and then a free CoA molecule.

Next, the enzyme HMG-CoA synthase combines acetoacetyl-CoA and acetyl-CoA to form a 6-carbon molecule called 3-hydroxy-3-methylglutaryl CoA, or HMG-CoA - so 3 acetyls and the an free CoA molecule.

Then, an enzyme called HMG-CoA reductase reduces HMG-CoA into mevalonate, by removing a CoA-SH and a water molecule.

This step with HMG-CoA reductase is the rate-limiting step of cholesterol synthesis.

In other words, the rate of this reaction determines the overall rate of cholesterol synthesis - it’s like the slowest step in the assembly line for a factory.

Now, cholesterol synthesis is regulated by a trio of proteins - sterol regulatory element binding protein - or SREBP and two others that just go by SCAP and INSIG-1.

Let’s say that cholesterol levels drop because there’s less cholesterol coming into the cell from the diet.

In that situation, INSIG-1 falls off of SREBP, like pulling a pin from a grenade, and the SREBP-SCAP complex then gets cleaved by cellular enzymes.

The cleaved SREBP floats into the nucleus, and binds to the sterol regulatory element on the DNA.

When it binds, it increases expression of the genes encoding HMG-CoA reductase.

That leads to more HMG-CoA reductase, which speeds up endogenous cholesterol synthesis.

Once HMG-CoA reductase has made the 6 carbon mevalonate, it then undergoes a number of additional enzyme-mediated transformations before it becomes cholesterol.

First, the enzyme mevalonate-5-kinase uses adenosine triphosphate, or ATP, to phosphorylate mevalonate, creating mevalonate-5-phosphate.

Then, phosphomevalonate kinase uses another ATP to phosphorylate mevalonate-5-phosphate, making mevalonate pyrophosphate.

Finally, mevalonate pyrophosphate decarboxylase removes a carboxyl group from it, forming a 5 carbon molecule called isopentenyl pyrophosphate.

Next, geranyl transferase condenses 3 of these isopentenyl pyrophosphate molecules to form a 15 carbon molecule called farnesyl pyrophosphate.

Then, the enzyme squalene synthase condenses two molecules of farnesyl pyrophosphate to form a 30 carbon molecule called squalene.

Squalene is pretty cool, it’s the last linear precursor to cholesterol and it’s also what helps sharks float. Yep - you heard that right.

Okay next, an enzyme called oxidosqualene cyclase converts linear squalene molecule into a structure with rings - a process called cyclization.

The result is our first sterol intermediate, called lanosterol.

From there, there are 19 steps of successive modifications, like molding a lump of clay into a beautiful bowl; that convert lanosterol first into 27 carbon 7-dehydrocholesterol, and then finally into 27 carbon cholesterol!

Key Takeaways

Cholesterol is a lipid molecule that helps to synthesize hormones, cell membrane integrity, and other important compounds. Cholesterol is synthesized in the smooth endoplasmic reticulum of cells throughout the body, but mainly in the liver. This reaction's rate-limiting step is the reduction of HMG CoA to mevalonate, which is done by HMG-CoA reductase.

Some of the cholesterol in the blood is derived from food. Dietary cholesterol is found in animal products, such as meat, poultry, fish, and dairy products. In the bloodstream, cholesterol is transported and attached to proteins called lipoproteins, which carry it to the cells that need it.