GATA3

4HC7, 4HC9, 4HCA262514462ENSG00000107485ENSMUSG00000015619P23771P23772NM_001002295NM_002051NM_008091NM_001355110NM_001355111NM_001355112NP_001002295NP_002042NP_032117NP_001342039NP_001342040NP_001342041GATA3 is a transcription factor that in humans is encoded by the GATA3 gene. Studies in animal models and humans indicate that it controls the expression of a wide range of biologically and clinically important genes. GATA3 is a transcription factor that in humans is encoded by the GATA3 gene. Studies in animal models and humans indicate that it controls the expression of a wide range of biologically and clinically important genes. The GATA3 transcription factor is critical for the embryonic development of various tissues as well as for inflammatory and humoral immune responses and the proper functioning of the endothelium of blood vessels. GATA3 haploinsufficiency (i.e. lose of one or the two inherited GATA3 genes) results in a congenital disorder termed the Barakat syndrome. Current clinical and laboratory research is focusing on determining the benefits of directly or indirectly blocking the action of GATA3 in inflammatory and allergic diseases such as asthma. It is also proposed to be a clinically important marker for various types of cancer, particularly those of the breast. However, the role, if any, of GATA3 in the development of these cancers is under study and remains unclear. The GATA3 gene is located close to the end of the short arm of chromosome 10 at position p14. It consists of 8 exons, and codes for two variants viz., GATA3, variant 1, and GATA3, variant 2. Expression of GATA3 may be regulated in part or at times by the antisense RNA, GATA3-AS1, whose gene is located close to the GATA3 gene on the short arm of chromosome 10 at position p14. Various types of mutations including point mutations as well as small- and large-scale deletional mutations cause an autosomal dominant genetic disorder, the Barakat syndrome (also termed hypoparathyroidism, deafness, and renal dysplasia syndrome). The location of GATA3 borders that of other critical sites on chromosome 10, particularly a site located at 10p14-p13. Mutations in this site cause the congenital disorder DiGeorge syndrome/velocardiofacial syndrome complex 2 (or DiGeorge syndrome 2). Large-scale deletions in GATA3 may span into the DiGeorge syndrome 2 area and thereby cause a complex syndrome with features of the Barakat syndrome combined with some of those of the DiGeorge syndrome 2. Knockout of both GATA3 genes in mice is fatal: these animals die at embryonic days 11 and 12 due to internal bleeding. They also exhibit gross deformities in the brain and spine as well as aberrations in fetal liver hematopoiesis. GATA3 variant 1 is a linear protein consisting of 444 amino acids. GATA3 variant 2 protein is an identically structured isoform of, but 1 amino acid shorter than, GATA3 variant 1. Differences, if any, in the functions of these two variants have not been reported. With respect to the best studied variant, variant 1, but presumably also variant 2, one of the zinc finger structural motifs, ZNF2, is located at the protein's C-terminus and binds to specific gene promoter DNA sequences to regulate the expression of the genes controlled by these promoters. The other zinc finger, ZNF1, is at the protein's N-terminus and interacts with various nuclear factors, including Zinc finger protein 1 (i.e. ZFPM1, also termed Friends of GATA1 ) and ZFPM2 (i.e. FOG-2), that modulate GATA3's gene-stimulating actions. The GATA3 transcription factor regulates the expression of genes involved in the development of various tissues as well as genes involved in physiological as well as pathological humoral inflammatory and allergic responses. GATA3 belongs to the GATA family of transcription factors. Gene-deletion studies in mice indicate that Gata3 (mouse gene equivalent to GATA3) is critical for the embryonic development and/or function of various cell types (e.g. fat cells, neural crest cells, lymphocytes) and tissues (e.g. kidney, liver, brain, spinal cord, mammary gland). Studies in humans implicate GATA3 in the following: Inactivating mutations in one of the two parental GATA3 genes cause the congenital disorder of hypoparathyroidism with sensorineural deafness and kidney malformations, i.e. the Barakat syndrome. This rare syndrome may occur in families or as a new mutation in an individual from a family with no history of the disorder. Mutations in GATA3 cause variable degrees of hypoparathyroidism, deafness, and kidney disease birth defects because of 1) individual differences in the penetrance of the mutation, 2) a sporadic, and as yet unexplained, association with malformation of uterus and vagina, and 3) mutations which extend beyond the GATA3 gene into chromosomal areas where mutations are responsible for developing other types of abnormalities which are characteristics of the DeGeorge syndrome 2. The Barakat syndrome is due to a haploinsufficiency in GATA3 levels, i.e. levels of the transcription factor that are insufficient for the normal development of the cited tissues during embryogenesis. Mouse studies indicate that inhibiting the expression of GATA3 using antisense RNA methods suppresses allergic inflammation. The protein is overexpressed in the afflicted tissues of individuals with various forms of allergy including asthma, rhinitis, nasal polyps, and atopic eczema. This suggests that it may have a role in promoting these disorders. In a phase IIA clinical study of individuals suffering allergen-induced asthma, inhalation of Deoxyribozyme ST010, which specifically inactivates GATA3 messenger RNA, for 28 days reduced early and late immune lung responses to inhaled allergen. The clinical benefit of inhibiting GATA3 in this disorder is thought to be due to interfering with the function of Group 2 ILCs and Th2 cells by, for example, reducing there production of IL-4, IL-13, and especially IL-5. Reduction in these eosinophil-stimulating interleukins, it is postulated, reduces this cells ability to promote allergic reactivity and responses. For similar reasons, this treatment might also prove to be clinical useful for treating other allergic disorders.