KLF2

1036516598ENSG00000127528ENSMUSG00000055148Q9Y5W3Q60843NM_016270NM_008452NP_057354NP_032478Krüppel-like Factor 2 (KLF2), also known as lung Krüppel-like Factor (LKLF), is a protein that in humans is encoded by the KLF2 gene on chromosome 19. It is a member of the Krüppel-like factor family of zinc finger transcription factors, and it has been implicated in a variety of biochemical processes in the human body, including lung development, embryonic erythropoiesis, epithelial integrity, T-cell viability, and adipogenesis. Krüppel-like Factor 2 (KLF2), also known as lung Krüppel-like Factor (LKLF), is a protein that in humans is encoded by the KLF2 gene on chromosome 19. It is a member of the Krüppel-like factor family of zinc finger transcription factors, and it has been implicated in a variety of biochemical processes in the human body, including lung development, embryonic erythropoiesis, epithelial integrity, T-cell viability, and adipogenesis. Erythroid Krüppel-like Factor (EKLF or KLF1) was the first Krüppel-like Factor discovered. It was found to be vitally important for embryonic erythropoiesis in promoting the switch from fetal hemoglobin (Hemoglobin F) to adult hemoglobin (Hemoglobin A) gene expression by binding to highly conserved CACCC domains. EKLF ablation in mouse embryos produces a lethal anemic phenotype, causing death by embryonic day 14, and natural mutations lead to β+ thalassemia in humans. However, expression of embryonic hemoglobin and fetal hemoglobin genes is normal in EKLF-deficient mice, and since all genes on the human β-globin locus exhibit the CACCC elements, researchers began searching for other Krüppel-like factors. KLF2, initially called lung Krüppel-like Factor due to its high expression in the adult mouse lung, was first isolated in 1995 by using the zinc finger domain of EKLF as a hybridization probe. By transactivation assay in mouse fibroblasts, KLF2 was also noticed to bind to the β-globin gene promoter containing the CACCC sequence shown to be the binding site for EKLF, confirming KLF2 as a member of the Krüppel-like Factor family. Since then, many other KLF proteins have been discovered. The main distinguishing feature of the KLF family is the presence of three highly conserved Cysteine2/Histidine2 zinc fingers of either 21 or 23 amino acid residues in length, located at the C-terminus of the protein. These amino acid sequences each chelate a single zinc ion, coordinated between the two cysteine and two histidine residues. These zinc fingers are joined by a conserved seven-amino acid sequence; TGEKP(Y/F)X. The zinc fingers enable all KLF proteins to bind to CACCC gene promoters, so although they may complete varied functions (due to lack of homology away from the zinc fingers), they all recognize similar binding domains. KLF2 also exhibits these structural features. The mRNA transcript is approximately 1.5 kilobases in length, and the 37.7 kDa protein contains 354 amino acids. KLF2 also shares some homology with EKLF at the N-terminus with a proline-rich region presumed to function as the transactivation domain. KLF2 was first discovered, and is highly expressed in, the adult mouse lung, but it is also expressed temporally during embryogenesis in erythroid cells, endothelium, lymphoid cells, the spleen, and white adipose tissue. It is expressed as early as embryonic day 9.5 in the endothelium. KLF2 has a particularly interesting expression profile in erythroid cells. It is minimally expressed in the primitive and fetal definitive erythroid cells, but is highly expressed in adult definitive erythroid cells, particularly in the proerythroblast and the polychromatic and orthochromatic normoblasts. Homologous recombination of embryonic stem cells was used to generate KLF2-deficient mouse embryos. Both vasculogenesis and angiogenesis were normal in the embryos, but they died by embryonic day 14.5 from severe hemorrhaging. The vasculature displayed defective morphology, with thin tunica media and aneurysmal dilation that led to rupturing. Aortic vascular smooth muscle cells failed to organize into a normal tunica media, and pericytes were low in number. These KLF2-deficient mice thus demonstrated the important role of KLF2 in blood vessel stabilization during embryogenesis. Due to embryonic lethality in KLF2-deficient embryos, it is difficult to examine the role of KLF2 in normal post-natal physiology, such as in lung development and function.