Fatty acid synthesis

Last updated: November 01, 2022

Fatty acid synthesis

HMBP

HMBP

Glycolysis
Citric acid cycle
Electron transport chain and oxidative phosphorylation
Gluconeogenesis
Glycogen metabolism
Pentose phosphate pathway
Physiological changes during exercise
Amino acid metabolism
Nitrogen and urea cycle
Fatty acid synthesis
Fatty acid oxidation
Ketone body metabolism
Cholesterol metabolism
Essential fructosuria
Hereditary fructose intolerance
Galactosemia
Pyruvate dehydrogenase deficiency
Glucose-6-phosphate dehydrogenase (G6PD) deficiency
Lactose intolerance
Glycogen storage disease type I
Glycogen storage disease type II (NORD)
Glycogen storage disease type III
Glycogen storage disease type IV
Glycogen storage disease type V
Leukodystrophy
Metachromatic leukodystrophy (NORD)
Krabbe disease
Gaucher disease (NORD)
Niemann-Pick disease types A and B (NORD)
Niemann-Pick disease type C
Fabry disease (NORD)
Tay-Sachs disease (NORD)
Mucopolysaccharide storage disease type 1 (Hurler syndrome) (NORD)
Mucopolysaccharide storage disease type 2 (Hunter syndrome) (NORD)
Cystinosis
Hartnup disease
Alkaptonuria
Ornithine transcarbamylase deficiency
Phenylketonuria (NORD)
Cystinuria (NORD)
Homocystinuria
Maple syrup urine disease
Abetalipoproteinemia
Familial hypercholesterolemia
Hypertriglyceridemia
Hyperlipidemia
Disorders of carbohydrate metabolism: Pathology review
Disorders of fatty acid metabolism: Pathology review
Dyslipidemias: Pathology review
Glycogen storage disorders: Pathology review
Lysosomal storage disorders: Pathology review
Disorders of amino acid metabolism: Pathology review
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
Cytoskeleton and intracellular motility
Cell signaling pathways
Adrenoleukodystrophy (NORD)
Zellweger spectrum disorders (NORD)
Primary ciliary dyskinesia
Alport syndrome
Ehlers-Danlos syndrome
Osteogenesis imperfecta
Marfan syndrome
Vitamin C deficiency
Peroxisomal disorders: Pathology review
Nuclear structure
DNA structure
Transcription of DNA
Translation of mRNA
Gene regulation
Epigenetics
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
Lesch-Nyhan syndrome
Orotic aciduria
Adenosine deaminase deficiency
Xeroderma pigmentosum
Li-Fraumeni syndrome
Bloom syndrome
Fanconi anemia
McCune-Albright syndrome
Acute radiation syndrome
Purine and pyrimidine synthesis and metabolism disorders: Pathology review
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
Evolution and natural selection
Down syndrome (Trisomy 21)
Edwards syndrome (Trisomy 18)
Patau syndrome (Trisomy 13)
Fragile X syndrome
Huntington disease
Myotonic dystrophy
Friedreich ataxia
Turner syndrome
Klinefelter syndrome
Prader-Willi syndrome
Angelman syndrome
Beckwith-Wiedemann syndrome
Cri du chat syndrome
Williams syndrome
Alagille syndrome (NORD)
Achondroplasia
Polycystic kidney disease
Familial adenomatous polyposis
Hereditary spherocytosis
Multiple endocrine neoplasia
Neurofibromatosis
Tuberous sclerosis
von Hippel-Lindau disease
Albinism
Cystic fibrosis
Hemochromatosis
Sickle cell disease (NORD)
Alpha-thalassemia
Beta-thalassemia
Wilson disease
X-linked agammaglobulinemia
Hemophilia
Muscular dystrophy
Wiskott-Aldrich syndrome
Mitochondrial myopathy
Autosomal trisomies: Pathology review
Muscular dystrophies and mitochondrial myopathies: Pathology review
Miscellaneous genetic disorders: Pathology review

Transcript

Watch video only

Content Reviewers

Rishi Desai, MD, MPH

In addition to carbohydrates and proteins, lipids are the third main macromolecule we consume in our diet.

Fatty foods include red meat, dairy products, and even peanut butter.

And lipids come in many forms, including cholesterol, glycerol, phospholipids, and fatty acids.

Of these, fatty acids are the simplest form of lipids - they’re basically just long chains of carbon and hydrogen, that are grouped by length into short, medium, long and very long chain fatty acids.

Fatty acids can also combine with glycerol to make triacylglycerides, which is made of 3 fatty acids attached to a glycerol molecule, and is the main storage form of fat in our body.

Now, short and medium-chain fatty acids are primarily obtained from the diet, but the liver and fat cells can synthesize long chain fatty acids.

This occurs by combining lots of 2-carbon molecules, called acetyl-coenzyme A or acetyl-CoA, into a single 16-carbon, long chain fatty acid called palmitoyl-coenzyme A, or palmitoyl-CoA.

Palmitoyl-CoA can then serve as a precursor to even longer chain fatty acids.

To make palmitoyl-CoA, acetyl-CoA provides the carbon atoms, and nicotinamide adenine dinucleotide phosphate, or NADPH provides the hydrogen atoms.

As it turns out, most of the acetyl-CoA used to make fatty acids comes from carbohydrate metabolism - specifically glucose, which is a 6-carbon sugar molecule.

After eating a glucose-rich dinner, like cake and cookies, glucose levels in the blood rise quickly.

In response, the pancreas secretes insulin, a hormone which makes our cells take in and process a lot more glucose.

Inside the cells, glucose can enter glycolysis where it’s broken down into two 3-carbon pyruvate molecules, and that yields a bit of energy in the form of adenosine triphosphate - or ATP.

Pyruvate then moves into the mitochondria, and is converted to acetyl-CoA by an enzyme called pyruvate dehydrogenase.

Inside the mitochondria, acetyl CoA enters the citric acid cycle by combining with a molecule called oxaloacetate, to form citrate.

Citrate can then continue in the citric acid cycle, which generates electron carriers that can join the electron transport chain and oxidative phosphorylation.

All of this leads to the formation of a lot more ATP.

So the math is simple - more glucose, more ATP.

Well, ATP inhibits some enzymes in the citric acid cycle, slowing it down overall, and that means that extra acetyl-CoA can be used to make fatty acids instead.

However, the enzymes required for fatty acid synthesis are all in the cytoplasm, so in order to start fatty acid synthesis, acetyl-CoA needs to get out of the mitochondria.

Unfortunately, acetyl-CoA cannot cross the mitochondrial membrane - so to get to the cytoplasm, it combines with oxaloacetate to form citrate, just as it would to enter the citric acid cycle.

So when there’s a lot of ATP around, citrate crosses the mitochondrial membrane and enters the cytoplasm.

In the cytoplasm, an enzyme called citrate lyase, cleaves citrate back into acetyl-CoA and oxaloacetate.

This process of conversion and reconversion is called the citrate shuttle.

In the meantime, oxaloacetate is recycled and goes back into the mitochondria so it can be available the next incoming acetyl-CoA.

But we have another problem; oxaloacetate can’t cross the membrane either.

So an enzyme called malic enzyme, converts oxaloacetate into pyruvate, forming NADPH from NADP+ in the process.

Now, pyruvate can cross the mitochondrial membrane, and an enzyme called pyruvate carboxylase converts it back into oxaloacetate, which can begin a new cycle.

High levels of acetyl-CoA also increase the activity of pyruvate carboxylase, so that oxaloacetate is made available.

With acetyl-CoA in the cytoplasm, all we need to begin fatty acid synthesis is NADPH to provide the hydrogens.

Some of that NADPH is generated by malic enzyme when it converts oxaloacetate to pyruvate.

And the rest comes from the metabolism of the excess glucose in a pathway called the pentose-phosphate pathway.

Once there’s enough NADPH, acetyl-CoA can begin its journey towards palmitoyl-CoA.

Ok, so first, a carboxyl group is added to acetyl-CoA by an enzyme called acetyl-CoA carboxylase, converting it to the 3-carbon malonyl-CoA.

This enzyme requires 3 cofactors, which can be easily remembered with the mnemonic, ABC.

“A” is for ATP, “B” is for biotin, or vitamin B7, and “C” is for carbon dioxide, or CO2, which is the carboxyl group source.

Key Takeaways

Fatty acids are one of the essential forms of energy storage. The biosynthesis of fatty acids is a multi-step process in the cytoplasm, mainly of the liver and fat cells. The process takes place in three major steps: the citrate shuttle, acetyl-CoA carboxylase (the rate-limiting step), and fatty acid synthase complex.