The Function of LCAT
Central enzyme in the extracellular metabolism of plasma lipoproteins. Synthesized mainly in the liver and secreted into plasma where it converts cholesterol and phosphatidylcholines (lecithins) to cholesteryl esters and lysophosphatidylcholines on the surface of high and low density lipoproteins (HDLs and LDLs) (PubMed:10329423, PubMed:19065001, PubMed:26195816). The cholesterol ester is then transported back to the liver. Has a preference for plasma 16:0-18:2 or 18:O-18:2 phosphatidylcholines (PubMed:8820107). Also produced in the brain by primary astrocytes, and esterifies free cholesterol on nascent APOE-containing lipoproteins secreted from glia and influences cerebral spinal fluid (CSF) APOE- and APOA1 levels. Together with APOE and the cholesterol transporter ABCA1, plays a key role in the maturation of glial-derived, nascent lipoproteins. Required for remodeling high-density lipoprotein particles into their spherical forms (PubMed:10722751).
Protein names
Recommended name:
Phosphatidylcholine-sterol acyltransferaseAlternative name(s):
Lecithin-cholesterol acyltransferasePhospholipid-cholesterol acyltransferase
- RS11574514 (LCAT) ??
- RS4986970 (LCAT) ??
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Top Gene-Substance Interactions
LCAT Interacts with These Diseases
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Substances That Increase LCAT
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Substances That Decrease LCAT
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Advanced Summary
complete LCAT deficiency More than 70 mutations in the LCAT gene have been identified in people with complete LCAT deficiency, a disorder that primarily causes corneal clouding and kidney problems. Individuals with complete LCAT deficiency have mutations in both copies of the LCAT gene in each cell. Most of these mutations change single amino acids in the LCAT enzyme sequence. Others add or delete small amounts of genetic material in the LCAT gene. The mutations either prevent the production of LCAT or impair both alpha-LCAT and beta-LCAT activity, reducing the enzyme's ability to attach cholesterol to lipoproteins. Impairment of this mechanism for reducing cholesterol in the body leads to cholesterol deposits in the corneas, kidneys, and other tissues and organs. These deposits cause the signs and symptoms of complete LCAT deficiency. fish-eye disease At least 18 mutations in the LCAT gene have been identified in people with fish-eye disease, also called partial LCAT deficiency. This disorder causes clouding of the clear covering of the eyes (corneas). Individuals with fish-eye disease have mutations in both copies of the LCAT gene in each cell. Most of these mutations change single protein building blocks (amino acids) in the LCAT sequence. The mutations impair alpha-LCAT activity, reducing the enzyme's ability to attach cholesterol to HDL. Impairment of this mechanism for reducing cholesterol in the body leads to cholesterol deposits in the corneas that gradually cause them to become cloudy. other disorders People with one LCAT gene mutation in each cell may have an increased risk of atherosclerosis, which is an accumulation of cholesterol-rich fatty deposits and scar-like tissue in the lining of the arteries that can impede blood flow and lead to heart attacks, strokes, and other health problems. A single LCAT gene mutation likely reduces alpha-LCAT activity and binding of cholesterol to HDL, leading to less efficient transport of cholesterol from the blood and resulting in the development of atherosclerosis. Atherosclerosis also occurs in some people with fish-eye disease or complete LCAT deficiency. However, because atherosclerosis is very common in the general population and both fish-eye disease and complete LCAT deficiency are very rare, it is difficult to determine whether affected individuals are at increased risk of atherosclerosis.
The LCAT gene provides instructions for making an enzyme called lecithin-cholesterol acyltransferase (LCAT). This enzyme plays a role in removing cholesterol from the blood and tissues. Cholesterol is a waxy, fat-like substance that is produced in the body and obtained from foods that come from animals (particularly egg yolks, meat, poultry, fish, and dairy products). The body needs this substance to build cell membranes, make certain hormones, and produce compounds that aid in fat digestion. Too much cholesterol, however, increases a person's risk of developing heart disease, and can also lead to buildup of cholesterol in other tissues. The LCAT enzyme helps transport cholesterol out of the blood and tissues by a process called cholesterol esterification. This process results in a form of cholesterol that is more efficiently carried by molecules called lipoproteins, which transport the cholesterol to the liver. Once in the liver, the cholesterol is redistributed to other tissues or removed from the body. The enzyme has two major functions, called alpha- and beta-LCAT activity. Alpha-LCAT activity helps attach cholesterol to a lipoprotein called high-density lipoprotein (HDL). Beta-LCAT activity helps attach cholesterol to other lipoproteins called very low-density lipoprotein (VLDL) and low-density lipoprotein (LDL).
Conditions with Increased Gene Activity
Condition | Change (log2fold) | Comparison | Species | Experimental variables | Experiment name |
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Conditions with Decreased Gene Activity
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Technical
The following transcription factors affect gene expression:
Tissue specificity:
Detected in blood plasma (PubMed:3458198, PubMed:8820107, PubMed:10222237). Detected in cerebral spinal fluid (at protein level) (PubMed:10222237). Detected in liver (PubMed:3797244, PubMed:3458198). Expressed mainly in brain, liver and testes.
Gene Pathways:
Enzyme Regulation:
APOA1 is the most potent activator in plasma. Also activated by APOE, APOC1 and APOA4.
Molecular Function:
- Apolipoprotein A-I Binding
- Phosphatidylcholine-Sterol O-Acyltransferase Activity
- Phospholipase A2 Activity
Biological Processes:
- Cholesterol Esterification
- Cholesterol Homeostasis
- Cholesterol Metabolic Process
- Cholesterol Transport
- High-Density Lipoprotein Particle Remodeling
- Lipoprotein Biosynthetic Process
- Lipoprotein Metabolic Process
- Phosphatidylcholine Biosynthetic Process
- Phosphatidylcholine Metabolic Process
- Phospholipid Metabolic Process
- Regulation Of High-Density Lipoprotein Particle Assembly
- Reverse Cholesterol Transport
- Very-Low-Density Lipoprotein Particle Remodeling
- Response To Copper Ion
- Response To Glucocorticoid