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The HFE H63D is a single-nucleotide polymorphism in the HFE gene (c.187C>G, rs1799945), which results in the substitution of a histidine for an aspartic acid at amino acid position 63 of the HFE protein (p.His63Asp). HFE participates in the regulation of iron absorption. [1] [2] [3] Homozygous H63D variant can occasionally be the cause of ...
There are five types of hereditary hemochromatosis: type 1, 2 (2A, 2B), 3, 4 [9] and 5, [10] all caused by mutated genes. Hereditary hemochromatosis type 1 is the most frequent, and uniquely related to the HFE gene. It is most common among those of Northern European ancestry, in particular those of Celtic descent. [11]
The gene involved with patients diagnosed with type 3 hemochromatosis is TFR2 ( or HFE3). HFE (not the same as HFE3) is most often the cause of hereditary hemochromatosis. [ 14 ] The HFE gene provides instructions for producing a protein that is located on the surface of cells, primarily liver and intestinal cells.
The disease-causing genetic variant most commonly associated with hemochromatosis is p. C282Y. [ 14 ] About 1/200 of people of Northern European origin have two copies of this variant; they, particularly males, are at high risk of developing hemochromatosis. [ 15 ]
Iron overload (also known as haemochromatosis or hemochromatosis) is the abnormal and increased accumulation of total iron in the body, leading to organ damage. [1] The primary mechanism of organ damage is oxidative stress, as elevated intracellular iron levels increase free radical formation via the Fenton reaction.
Juvenile hemochromatosis can be caused by inheriting two mutated copies , one from each parent, of the genes for the proteins hemojuvelin (HFE2/HJV) or hepcidin (HAMP), and the disease can be subdivided into hemochromatosis types 2A and 2B according to which gene/protein is affected. [2] [3]
Section of liver stained with Perls Prussian blue, showing iron accumulations (blue) consistent with homozygous genetic hemochromatosis. Perls's method is used to indicate "non-heme" iron in tissues such as ferritin and hemosiderin, [6] the procedure does not stain iron that is bound to porphyrin forming heme such as hemoglobin and myoglobin. [2]
Four novel alternative genetic codes were discovered in bacterial genomes by Shulgina and Eddy using their codon assignment software Codetta, and validated by analysis of tRNA anticodons and identity elements; [3] these codes are not currently adopted at NCBI, but are numbered here 34-37, and specified in the table below. The standard code