EGLN1 gene

The EGLN1 gene, often known as PHD2, provides instructions for making an enzyme called prolyl hydroxylase domain 2 (PHD2). The PHD2 enzyme interacts with a protein called hypoxia-inducible factor 2-alpha (HIF-2α). This protein is one part (subunit) of a larger HIF protein complex that plays a critical role in the body's ability to adapt to changing oxygen levels. HIF controls several important genes involved in cell division, the formation of new blood vessels, and the production of red blood cells. It is the major regulator of a hormone called erythropoietin, which controls red blood cell production.


Normal Function
The EGLN1 gene, often known as PHD2, provides instructions for making an enzyme called prolyl hydroxylase domain 2 (PHD2). The PHD2 enzyme interacts with a protein called hypoxia-inducible factor 2-alpha . This protein is one part (subunit) of a larger HIF protein complex that plays a critical role in the body's ability to adapt to changing oxygen levels. HIF controls several important genes involved in cell division, the formation of new blood vessels, and the production of red blood cells. It is the major regulator of a hormone called erythropoietin, which controls red blood cell production.
The PHD2 enzyme's primary job is to target HIF-2α to be broken down (degraded) so it does not build up when it is not needed. When enough oxygen is available, the PHD2 enzyme is highly active to stimulate the breakdown of HIF-2α. However, when oxygen levels are lower than normal (hypoxia), the PHD2 enzyme becomes less active. As a result, HIF-2α is degraded more slowly, leaving more HIF available to stimulate the formation of new blood vessels and red blood cells. These activities help maximize the amount of oxygen that can be delivered to the body's organs and tissues.
Studies suggest that the EGLN1 gene is involved in the body's adaptation to high altitude. At higher altitudes, such as in mountainous regions, air pressure is lower and less oxygen enters the body through the lungs. Over time, the body compensates for the lower oxygen levels by changing breathing patterns and producing more red blood cells and blood vessels.
Researchers suspect that the EGLN1 gene may also act as a tumor suppressor gene because of its role in regulating cell division and other processes through its interaction with HIF. Tumor suppressors prevent cells from growing and dividing too fast or in an uncontrolled way, which could lead to the development of a tumor.

Familial erythrocytosis
At least 10 mutations in the EGLN1 gene have been found to cause familial erythrocytosis, an inherited condition characterized by an increased number of red blood cells and an elevated risk of abnormal blood clots. When familial erythrocytosis results from EGLN1 gene mutations, it is often designated ECYT3.
Some EGLN1 gene mutations change single protein building blocks (amino acids) in the PHD2 enzyme, while others lead to the production of an abnormally short version of the enzyme. Any of these genetic changes disrupt the enzyme's ability to interact with HIF-2α and target it for destruction. Consequently, HIF accumulates in cells even when adequate oxygen is available. The presence of extra HIF leads to the production of red blood cells when no more are needed, resulting in an excess of these cells in the bloodstream.
At least one of the known EGLN1 gene mutations has been associated with both familial erythrocytosis and a tumor called a paraganglioma in the same individual. Paragangliomas are noncancerous (benign) tumors of the nervous system. The mutation, written as His374Arg or H374R, replaces the amino acid histidine with the amino acid arginine at position 374 in the PHD2 enzyme. This genetic change alters the interaction between the PHD2 enzyme and HIF-2α, which leads to the production of excess red blood cells. However, it is unclear how the mutation may be associated with the development of paragangliomas.

Chromosomal Location
Cytogenetic Location: 1q42.2, which is the long (q) arm of chromosome 1 at position 42.2