GATA-binding factor 1 or GATA-1 (also termed Erythroid transcription factor) is the founding member of the GATA family of transcription factors. This protein is widely expressed throughout vertebrate species. In humans and mice, it is encoded by the GATA1 and Gata1 genes, respectively. These genes are located on the X chromosome in both species.[5][6]
GATA1 regulates the expression (i.e. formation of the genes' products) of an ensemble of genes that mediate the development of red blood cells and platelets. Its critical roles in red blood cell formation include promoting the maturation of precursor cells, e.g. erythroblasts, to red blood cells and stimulating these cells to erect their cytoskeleton and biosynthesize their oxygen-carrying components viz., hemoglobin and heme. GATA1 plays a similarly critical role in the maturation of blood platelets from megakaryoblasts, promegakaryocytes, and megakaryocytes; the latter cells then shed membrane-enclosed fragments of their cytoplasm, i.e. platelets, into the blood.[5][7]
In consequence of the vital role that GATA1 has in the proper maturation of red blood cells and platelets, inactivating mutations in the GATA1 gene (i.e. mutations that result in the production of no, reduced levels of, or a less active GATA1) cause X chromosome-linked anemic and/or bleeding diseases due to the reduced formation and functionality of red blood cells and/or platelets, respectively, or, under certain circumstances, the pathological proliferation of megakaryoblasts. These diseases include transient myeloproliferative disorder occurring in Down syndrome, acute megakaryoblastic leukemia occurring in Down syndrome, Diamond–Blackfan anemia, and various combined anemia-thrombocytopenia syndromes including a gray platelet syndrome-type disorder.[8][9][10]
Reduced levels of GATA1 due to reductions in the translation of GATA1 mRNA into its transcription factor product are associated with promoting the progression of myelofibrosis, i.e. a malignant disease that involves the replacement of bone marrow cells by fibrous tissue and extramedullary hematopoiesis, i.e. the extension of blood cell-forming cells to sites outside of the bone marrow.[11][12]
Gene
The human GATA1 gene is located on the short (i.e. "p") arm of the X chromosome at position 11.23. It is 7.74 kilobases in length, consists of 6 exons, and codes for a full-length protein, GATA1, of 414 amino acids as well as a shorter one, GATA1-S. GATA1-S lacks the first 83 amino acids of GATA1 and therefore consists of only 331 amino acids.[13][14][15] GATA1 codes for two zinc finger structural motifs, C-ZnF and N-ZnF, that are present in both GATA1 and GATA1-S proteins. These motifs are critical for both transcription factors' gene-regulating actions. N-ZnF is a frequent site of disease-causing mutations. Lacking the first 83 amino acids and therefore one of the two activation domains of GATA1, GATA1-S has significantly less gene-regulating activity than GATA1.[8][15]
Studies in Gata1-knockout mice, i.e. mice lacking the Gata1 gene, indicate that this gene is essential for the development and maintenance of blood-based and/or tissue-based hematological cells, particularly red blood cells and platelets but also eosinophils, basophils, mast cells, and dendritic cells. The knock-out mice die by day 11.5 of their embryonic development due to severe anemia that is associated with absence of cells of the red blood cell lineage, excessive numbers of malformed platelet-precursor cells, and an absence of platelets. These defects reflect the essential role of Gata-1 in stimulating the development, self-renewal, and/or maturation of red blood cell and platelet precursor cells. Studies using mice depleted of their Gata1 gene during adulthood show that: 1) Gata1 is required for the stimulation of erythropoiesis (i.e. increase in red blood cell formation) in response to stress and 2) Gata1-deficient adult mice invariably develop a form of myelofibrosis.[16][17]
GATA1 proteins
In both GATA1 and GATA1-S, C-ZnF (i.e. C-terminus zinc finger) binds to DNA-specific nucleic acid sequences sites viz., (T/A(GATA)A/G), on the expression-regulating sites of its target genes and in doing so either stimulates or suppresses the expression of these target genes. Their N-ZnF (i.e. N-terminus zinc fingers) interacts with an essential transcription factor-regulating nuclear protein, FOG1. FOG1 powerfully promotes or suppresses the actions that the two transcription factors have on most of their target genes. Similar to the knockout of Gata1, knockout of the mouse gene for FOG1, Zfpm1, causes total failure of red blood cell development and embryonic lethality by day 11.5. Based primarily on mouse studies, it is proposed that the GATA1-FOG1 complex promotes human erythropoiesis by recruiting and binding with at least two gene expression-regulating complexes, Mi-2/NuRD complex (a chromatin remodeler) and CTBP1 (a histone deacetylase) and three gene expression-regulating proteins, SET8 (a GATA1-inhibiting histone methyltransferase), BRG1 (a transcription activator), and Mediator (a transcription co-activator). Other interactions include those with: BRD3 (remodels DNA nucleosomes),[18][19][20] BRD4 (binds acetylated lysine residues in DNA-associated histone to regulate gene accessibility),[18] FLI1 (a transcription factor that blocks erythroid differentiation),[21][22] HDAC1 (a histone deacetylase),[23] LMO2 (regulator of erythrocyte development),[24] ZBTB16 (transcription factor regulating cell cycle progression),[25] TAL1 (a transcription factor),[26] FOG2 (a transcription factor regulator),[27] and GATA2 (Displacement of GATA2 by GATA1, i.e. the "GATA switch", at certain gene-regulating sites is critical for red blood development in mice and, presumably, humans).[17][28][29] GATA1-FOG1 and GATA2-FOG1 interactions are critical for platelet formation in mice and may similarly be critical for this in humans.[17]
Physiology and Pathology
GATA1 was first described as a transcription factor that activates the hemoglobin B gene in the red blood cell precursors of chickens.[30] Subsequent studies in mice and isolated human cells found that GATA1 stimulates the expression of genes that promote the maturation of precursor cells (e.g. erythroblasts) to red blood cells while silencing genes that cause these precursors to proliferate and thereby to self-renew.[31][32] GATA1 stimulates this maturation by, for example, inducing the expression of genes in erythroid cells that contribute to the formation of their cytoskeleton and that make enzymes necessary for the biosynthesis of hemoglobins and heme, the oxygen-carrying components of red blood cells. GATA1-inactivating mutations may thereby result in a failure to produce sufficient numbers of and/or fully functional red blood cells.[5] Also based on mouse and isolated human cell studies, GATA1 appears to play a similarly critical role in the maturation of platelets from their precursor cells. This maturation involves the stimulation of megakaryoblasts to mature ultimately to megakaryocytes which cells shed membrane-enclosed fragments of their cytoplasm, i.e. platelets, into the blood. GATA1-inactivating mutations may thereby result in reduced levels of and/or dysfunctional blood platelets.[5][7]
Reduced levels of GATA1 due to defective translation of GATA1 mRNA in human megakaryocytes is associated with myelofibrosis, i.e. the replacement of bone marrow cells by fibrous tissue. Based primarily on mouse and isolated human cell studies, this myelofibrosis is thought to result from the accumulation of platelet precursor cells in the bone marrow and their release of excessive amounts of cytokines that stimulate bone marrow stromal cells to become fiber-secreting fibroblasts and osteoblasts. Based on mouse studies, low GATA1 levels are also thought to promote the development of splenic enlargement and extramedullary hematopoiesis in human myelofibrosis disease. These effects appear to result directly from the over-proliferation of abnormal platelet precursor cells.[11][12][33][34]
The clinical features associated with inactivating GATA1 mutations or other causes of reduced GATA1 levels vary greatly with respect not only to the types of disease exhibited but also to disease severity. This variation depends on at least four factors. First, inactivating mutations in GATA1 cause X-linked recessive diseases. Males, with only one GATA1 gene, experience the diseases of these mutations while women, with two GATA1 genes, experience no or extremely mild evidence of these diseases unless they have inactivating mutations in both genes or their mutation is dominant negative, i.e. inhibiting the good gene's function. Second, the extent to which a mutation reduces the cellular levels of fully functional GATA1 correlates with disease severity. Third, inactivating GATA1 mutations can cause different disease manifestations. For example, mutations in GATA1's N-ZnF that interfere with its interaction with FOG1 result in reduced red blood cell and platelet levels whereas mutations in N-ZnF that reduce its binding affinity to target genes cause a reduction in red blood cells plus thalassemia-type and porphyria-type symptoms. Fourth, the genetic background of individuals can impact the type and severity of symptoms. For example, GATA1-inactivating mutations in individuals with the extra chromosome 21 of Down syndrome exhibit a proliferation of megakaryoblasts that infiltrate and consequentially directly damage liver, heart, marrow, pancreas, and skin plus secondarily life-threatening damage to the lungs and kidneys. These same individuals can develop secondary mutations in other genes that results in acute megakaryoblastic leukemia.[15][35]
Genetic disorders
GATA1 gene mutations are associated with the development of various genetic disorders which may be familial (i.e. inherited) or newly acquired. In consequence of its X chromosome location, GATA1 mutations generally have a far greater physiological and clinical impact in men, who have only one X chromosome along with its GATA1 gene, than woman, who have two of these chromosomes and genes: GATA1 mutations lead to X-linked diseases occurring predominantly in males.[15] Mutations in the activation domain of GATA1 (GATA1-S lacks this domain) are associated with the transient myeloproliferative disorder and acute megakaryoblastic leukemia of Down syndrome while mutations in the N-ZnF motif of GATA1 and GATA1-S are associated with diseases similar to congenital dyserythropoietic anemia, congenital thrombocytopenia, and certain features that occur in thalassemia, gray platelet syndrome, congenital erythropoietic porphyria, and myelofibrosis.[8]
Down syndrome-related disorders
Transient myeloproliferative disorder
Acquired inactivating mutations in the activation domain of GATA1 are the apparent cause of the transient myeloproliferative disorder that occurs in individuals with Down syndrome. These mutations are frameshifts in exon 2 that result in the failure to make GATA1 protein, continued formation of GATA1-S, and therefore a greatly reduced ability to regulate GATA1-targeted genes. The presence of these mutations is restricted to cells bearing the trisomy 21 karyotype (i.e. extra chromosome 21) of Down syndrome: GATA1 inactivating mutations and trisomy 21 are necessary and sufficient for development of the disorder.[35] Transient myeloproliferative disorder consists of a relatively mild but pathological proliferation of platelet-precursor cells, primarily megakaryoblasts, which often show an abnormal morphology that resembles immature myeloblasts (i.e. unipotent stem cells which differentiate into granulocytes and are the malignant proliferating cell in acute myeloid leukemia). Phenotype analyses indicate that these blasts belong to the megakaryoblast series. Abnormal findings include the frequent presence of excessive blast cell numbers, reduced platelet and red blood cell levels, increased circulating white blood cell levels, and infiltration of platelet-precursor cells into the bone marrow, liver, heart, pancreas, and skin.[35] The disorder is thought to develop in utero and is detected at birth in about 10% of individuals with Down syndrome. It resolves totally within ~3 months but in the following 1–3 years progresses to acute megakaryoblastic leukemia in 20% to 30% of these individuals: transient myeloprolierative disorder is a clonal (abnormal cells derived from single parent cells), pre-leukemic condition and is classified as a myelodysplastic syndrome disease.[7][8][16][35]
Acute megakaryoblastic leukemia
Acute megakaryoblastic leukemia is a subtype of acute myeloid leukemia that is extremely rare in adults and, although still rare, more common in children. The childhood disease is classified into two major subgroups based on its occurrence in individuals with or without Down syndrome. The disease in Down syndrome occurs in 20% to 30% of individuals who previously had transient myeloproliferative disorder. Their GATA1 mutations are frameshifts in exon 2 that result in the failure to make GATA1 protein, continued formation of GATA1-S, and thus a greatly reduced ability to regulate GATA1-targeted genes. Transient myeloproliferative disorder is detected at or soon after birth and generally resolves during the next months but is followed within 1–3 years by acute megakaryoblastic leukemia.[7] During this 1-3 year interval, individuals accumulate multiple somatic mutations in cells bearing inactivating GATA1 mutations plus trisomy 21. These mutations are thought to result from the uncontrolled proliferation of blast cells caused by the GATAT1 mutation in the presence of the extra chromosome 21 and to be responsible for progression of the transient disorder to leukemia. The mutations occur in one or, more commonly, multiple genes including: TP53, RUNX1, FLT3, ERG, DYRK1A, CHAF1B, HLCS, CTCF, STAG2, RAD21, SMC3, SMC1A, NIPBL, SUZ12, PRC2, JAK1, JAK2, JAK3, MPL, KRAS, NRAS, SH2B3, and MIR125B2 which is the gene for microRNA MiR125B2.[7][36]
Diamond–Blackfan anemia
Diamond–Blackfan anemia is a familial (i.e. inherited) (45% of cases) or acquired (55% of cases) genetic disease that presents in infancy or, less commonly, later childhood as aplastic anemia and the circulation of abnormally enlarged red blood cells. Other types of blood cell and platelets circulate at normal levels and appear normal in structure. About half of affected individuals have various birth defects.[10] The disease is regarded as a uniformly genetic disease although the genes causing it have not been identified in ~30% of cases. In virtually all the remaining cases, autosomal recessive inactivating mutations occur in any one of 20 of the 80 genes encoding ribosomal proteins. About 90% of the latter mutations occur in 6 ribosomal protein genes viz., RPS19, RPL5, RPS26, RPL11, RPL35A, and RPS24.[8][10] However, several cases of familial Diamond–Blackfan anemia have been associated with GATA1 gene mutations in the apparent absence of a mutation in ribosomal protein genes. These GATA1 mutations occur in an exon 2 splice site or the start codon of GATA1, cause the production of the GATA1-S in the absence of the GATA1 transcription factor, and therefore are gene-inactivating in nature. It is proposed that these GATA1 mutations are a cause for Diamond Blackfan anemia.[8][15][16]
Combined anemia-thrombocytopenia syndromes
Certain GATA1-inactivatng mutations are associated with familial or, less commonly, sporadic X-linked disorders that consist of anemia and thrombocytopenia due to a failure in the maturation of red blood cell and platelet precursors plus other hematological abnormalities. These GATA1 mutations are identified by an initial letter identifying the normal amino acid followed by a number giving the position of this amino acid in GATA1, followed by a final letter identifying the amino acid substituted for the normal one. The amino acids are identified as V=valine; M=methionine; G=glycine; S=serine, D=aspartic acid; Y=tyrosine, R=arginine; W=tryptophan, Q=glutamine). These mutations and some key abnormalities they cause are:[8][16][37][38]
- V205M: familial disease characterized by severe anemia in fetuses and newborns; bone marrow has increased numbers of malformed platelet and red blood cell precursors.
- G208S and D218G: familial disease characterized by severe bleeding, reduced number of circulating platelets which are malformed (i.e. enlarged), and mild anemia.
- D218Y: familial disease similar to but more severe that the disease cause by G209S and D218G mutations.
- R216W: characterized by a beta thalassemia-type disease, i.e. microcytic anemia, absence of hemoglobin B, and hereditary persistence of fetal hemoglobin; symptoms of congenital erythropoietic porphyria; mild to moderately severe thrombocytopenia with features of the gray platelet syndrome.
- R216Q: familial disease characterized by mild anemia with features of heterozygous rather than homozygous (i.e. overt) beta thalassemia; mild thrombocytopenia with features of the gray platelet syndrome.
- G208R: disease characterized by mild anemia and severe thrombocytopenia with malformed erythroblasts and megakaryoblasts in the bone marrow. Structural features of these cells were similar to those observed in congenital dyserythropoietic anemia.
- -183G>A: rare Single-nucleotide polymorphism (rs113966884[39]) in which the nucleotide adenine replaces guanine in DNA at the position 183 nucleotides upstream of the start of GATA1; disorder characterized as mild anemia with structural features in bone marrow red cell precursors similar to those observed in congenital dyserythropoietic anemia.
The Gray platelet syndrome is a rare congenital bleeding disorder caused by reductions or absence of alpha-granules in platelets. Alpha-granules contain various factors which contribute to blood clotting and other functions. In their absence, platelets are defective. The syndrome is commonly considered to result solely from mutations in the NBEAL2 gene located on human chromosome 3 at position p21. In these cases, the syndrome follows autosomal recessive inheritance, causes a mild to moderate bleeding tendency, and may be accompanied by a defect in the secretion of the granule contents in neutrophils. There are other causes for a congenital platelet alpha-granule-deficient bleeding disorder viz., the autosomal recessive disease of Arc syndrome caused by mutations in either the VPS33B (on human chromosome 15 at q26) or VIPAS39 (on chromosome 14 at q34); the autosomal dominant disease of GFI1B-related syndrome caused by mutations in GFI1B (located on human chromosome 9 at q34); and the disease caused by R216W and R216Q mutations in GATA1. The GATA1 mutation-related disease resembles the one caused by NBEAL2 mutations in that it is associated with the circulation of a reduced number (i.e. thrombocytopenia) of abnormally enlarged (i.e. macrothrombocytes), alpha-granule deficient platelets. It differs from the NBEAL2-induced disease in that it is X chromosome-linked, accompanied by a moderately severe bleeding tendency, and associated with abnormalities in red blood cells (e.g. anemia, a thalassemia-like disorder due to unbalanced hemoglobin production, and/or a porphyria-like disorder.[40][37] A recent study found that GATA1 is a strong enhancer of NBEAL2 expression and that the R216W and R216Q inactivating mutations in GATA1 may cause the development of alpha granule-deficient platelets by failing to stimulate the expression of NBDAL2 protein.[41] Given these differences, the GATA1 mutation-related disorder appears better classified as clinically and pathologically different than the gray platelet syndrome.[40]
GATA1 in myelofibrosis
Myelofibrosis is a rare hematological malignancy characterized by progressive fibrosis of the bone marrow, extramedullary hematopoiesis (i.e. formation of blood cells outside of their normal site in the bone marrow), variable reductions in the levels of circulating blood cells, increases in the circulating levels of the precursors to the latter cells, abnormalities in platelet precursor cell maturation, and the clustering of grossly malformed megakaryocytes in the bone marrow. Ultimately, the disease may progress to leukemia. Recent studies indicate that the megakaryocytes but not other cell types in rare cases of myelofibrosis have greatly reduced levels of GATA1 as a result of a ribosomal deficiency in translating GATA1 mRNA into GATA1 transcription factor. The studies suggest that these reduced levels of GATA1 contribute to the progression of myelofibrosis by leading to an impairment in platelet precursor cell maturation, by promoting extramedullary hematopoiesis, and, possibly, by contributing to its leukemic transformation.[12][33][34]
References
- 1 2 3 GRCh38: Ensembl release 89: ENSG00000102145 - Ensembl, May 2017
- 1 2 3 GRCm38: Ensembl release 89: ENSMUSG00000031162 - Ensembl, May 2017
- ↑ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
- ↑ "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
- 1 2 3 4 Katsumura KR, DeVilbiss AW, Pope NJ, Johnson KD, Bresnick EH (September 2013). "Transcriptional mechanisms underlying hemoglobin synthesis". Cold Spring Harbor Perspectives in Medicine. 3 (9): a015412. doi:10.1101/cshperspect.a015412. PMC 3753722. PMID 23838521.
- ↑ Caiulo A, Nicolis S, Bianchi P, Zuffardi O, Bardoni B, Maraschio P, Ottolenghi S, Camerino G, Giglioni B (Feb 1991). "Mapping the gene encoding the human erythroid transcriptional factor NFE1-GF1 to Xp11.23". Human Genetics. 86 (4): 388–90. doi:10.1007/bf00201840. PMID 1999341. S2CID 20747016.
- 1 2 3 4 5 Gruber TA, Downing JR (August 2015). "The biology of pediatric acute megakaryoblastic leukemia". Blood. 126 (8): 943–9. doi:10.1182/blood-2015-05-567859. PMC 4551356. PMID 26186939.
- 1 2 3 4 5 6 7 Fujiwara T (June 2017). "GATA Transcription Factors: Basic Principles and Related Human Disorders". The Tohoku Journal of Experimental Medicine. 242 (2): 83–91. doi:10.1620/tjem.242.83. PMID 28566565.
- ↑ "Entrez Gene: GATA1 GATA binding protein 1 (globin transcription factor 1)".
- 1 2 3 Da Costa L, O'Donohue MF, van Dooijeweert B, Albrecht K, Unal S, Ramenghi U, Leblanc T, Dianzani I, Tamary H, Bartels M, Gleizes PE, Wlodarski M, MacInnes AW (October 2017). "Molecular approaches to diagnose Diamond–Blackfan anemia: The EuroDBA experience". European Journal of Medical Genetics. 61 (11): 664–673. doi:10.1016/j.ejmg.2017.10.017. hdl:2318/1676982. PMID 29081386.
- 1 2 Verrucci M, Pancrazzi A, Aracil M, Martelli F, Guglielmelli P, Zingariello M, Ghinassi B, D'Amore E, Jimeno J, Vannucchi AM, Migliaccio AR (November 2010). "CXCR4-independent rescue of the myeloproliferative defect of the Gata1low myelofibrosis mouse model by Aplidin". Journal of Cellular Physiology. 225 (2): 490–9. doi:10.1002/jcp.22228. PMC 3780594. PMID 20458749.
- 1 2 3 Song MK, Park BB, Uhm JE (March 2018). "Understanding Splenomegaly in Myelofibrosis: Association with Molecular Pathogenesis". International Journal of Molecular Sciences. 19 (3): 898. doi:10.3390/ijms19030898. PMC 5877759. PMID 29562644.
- ↑ "GATA1 GATA binding protein 1 [Homo sapiens (human)] - Gene - NCBI".
- ↑ "Genatlas sheet".
- 1 2 3 4 5 Shimizu R, Yamamoto M (August 2016). "GATA-related hematologic disorders". Experimental Hematology. 44 (8): 696–705. doi:10.1016/j.exphem.2016.05.010. PMID 27235756.
- 1 2 3 4 Crispino JD, Horwitz MS (April 2017). "GATA factor mutations in hematologic disease". Blood. 129 (15): 2103–2110. doi:10.1182/blood-2016-09-687889. PMC 5391620. PMID 28179280.
- 1 2 3 Katsumura KR, Bresnick EH (April 2017). "The GATA factor revolution in hematology". Blood. 129 (15): 2092–2102. doi:10.1182/blood-2016-09-687871. PMC 5391619. PMID 28179282.
- 1 2 Lamonica JM, Deng W, Kadauke S, Campbell AE, Gamsjaeger R, Wang H, Cheng Y, Billin AN, Hardison RC, Mackay JP, Blobel GA (May 2011). "Bromodomain protein Brd3 associates with acetylated GATA1 to promote its chromatin occupancy at erythroid target genes". Proceedings of the National Academy of Sciences of the United States of America. 108 (22): E159-68. doi:10.1073/pnas.1102140108. PMC 3107332. PMID 21536911.
- ↑ Gamsjaeger R, Webb SR, Lamonica JM, Billin A, Blobel GA, Mackay JP (Jul 2011). "Structural basis and specificity of acetylated transcription factor GATA1 recognition by BET family bromodomain protein Brd3". Molecular and Cellular Biology. 31 (13): 2632–40. doi:10.1128/MCB.05413-11. PMC 3133386. PMID 21555453.
- ↑ Stonestrom AJ, Hsu SC, Jahn KS, Huang P, Keller CA, Giardine BM, Kadauke S, Campbell AE, Evans P, Hardison RC, Blobel GA (Feb 2015). "Functions of BET proteins in erythroid gene expression". Blood. 125 (18): 2825–34. doi:10.1182/blood-2014-10-607309. PMC 4424630. PMID 25696920.,
- ↑ Lahiri K, Dole MG, Vidwans AS, Kamat J, Kandoth P (Apr 1989). "Acute glomerulonephritis". Journal of Tropical Pediatrics. 35 (2): 92. doi:10.1093/tropej/35.2.92. PMID 2724402.
- ↑ Starck J, Cohet N, Gonnet C, Sarrazin S, Doubeikovskaia Z, Doubeikovski A, Verger A, Duterque-Coquillaud M, Morle F (Feb 2003). "Functional cross-antagonism between transcription factors FLI-1 and EKLF". Molecular and Cellular Biology. 23 (4): 1390–402. doi:10.1128/MCB.23.4.1390-1402.2003. PMC 141137. PMID 12556498.
- ↑ Watamoto K, Towatari M, Ozawa Y, Miyata Y, Okamoto M, Abe A, Naoe T, Saito H (Dec 2003). "Altered interaction of HDAC5 with GATA-1 during MEL cell differentiation". Oncogene. 22 (57): 9176–84. doi:10.1038/sj.onc.1206902. PMID 14668799. S2CID 24491249.
- ↑ Osada H, Grutz G, Axelson H, Forster A, Rabbitts TH (Oct 1995). "Association of erythroid transcription factors: complexes involving the LIM protein RBTN2 and the zinc-finger protein GATA1". Proceedings of the National Academy of Sciences of the United States of America. 92 (21): 9585–9. Bibcode:1995PNAS...92.9585O. doi:10.1073/pnas.92.21.9585. PMC 40846. PMID 7568177.
- ↑ Labbaye C, Quaranta MT, Pagliuca A, Militi S, Licht JD, Testa U, Peschle C (Sep 2002). "PLZF induces megakaryocytic development, activates Tpo receptor expression and interacts with GATA1 protein". Oncogene. 21 (43): 6669–79. doi:10.1038/sj.onc.1205884. PMID 12242665.
- ↑ Goardon N, Lambert JA, Rodriguez P, Nissaire P, Herblot S, Thibault P, Dumenil D, Strouboulis J, Romeo PH, Hoang T (Jan 2006). "ETO2 coordinates cellular proliferation and differentiation during erythropoiesis". The EMBO Journal. 25 (2): 357–66. doi:10.1038/sj.emboj.7600934. PMC 1383517. PMID 16407974.
- ↑ Holmes M, Turner J, Fox A, Chisholm O, Crossley M, Chong B (Aug 1999). "hFOG-2, a novel zinc finger protein, binds the co-repressor mCtBP2 and modulates GATA-mediated activation". The Journal of Biological Chemistry. 274 (33): 23491–8. doi:10.1074/jbc.274.33.23491. PMID 10438528.
- ↑ Fujiwara Y, Browne CP, Cunniff K, Goff SC, Orkin SH (Oct 1996). "Arrested development of embryonic red cell precursors in mouse embryos lacking transcription factor GATA-1". Proceedings of the National Academy of Sciences of the United States of America. 93 (22): 12355–8. Bibcode:1996PNAS...9312355F. doi:10.1073/pnas.93.22.12355. PMC 37995. PMID 8901585.
- ↑ Campbell AE, Wilkinson-White L, Mackay JP, Matthews JM, Blobel GA (Jun 2013). "Analysis of disease-causing GATA1 mutations in murine gene complementation systems". Blood. 121 (26): 5218–27. doi:10.1182/blood-2013-03-488080. PMC 3695365. PMID 23704091.
- ↑ Evans T, Reitman M, Felsenfeld G (Aug 1988). "An erythrocyte-specific DNA-binding factor recognizes a regulatory sequence common to all chicken globin genes". Proceedings of the National Academy of Sciences of the United States of America. 85 (16): 5976–80. Bibcode:1988PNAS...85.5976E. doi:10.1073/pnas.85.16.5976. PMC 281888. PMID 3413070.
- ↑ Welch JJ, Watts JA, Vakoc CR, Yao Y, Wang H, Hardison RC, Blobel GA, Chodosh LA, Weiss MJ (Nov 2004). "Global regulation of erythroid gene expression by transcription factor GATA-1". Blood. 104 (10): 3136–47. doi:10.1182/blood-2004-04-1603. PMID 15297311.
- ↑ Cheng Y, Wu W, Kumar SA, Yu D, Deng W, Tripic T, King DC, Chen KB, Zhang Y, Drautz D, Giardine B, Schuster SC, Miller W, Chiaromonte F, Zhang Y, Blobel GA, Weiss MJ, Hardison RC (Dec 2009). "Erythroid GATA1 function revealed by genome-wide analysis of transcription factor occupancy, histone modifications, and mRNA expression". Genome Research. 19 (12): 2172–84. doi:10.1101/gr.098921.109. PMC 2792182. PMID 19887574.
- 1 2 Yang N, Park S, Cho MS, Lee M, Hong KS, Mun YC, Seong CM, Huh HJ, Huh J (July 2018). "GATA1 Expression in BCR/ABL1-negative Myeloproliferative Neoplasms". Annals of Laboratory Medicine. 38 (4): 296–305. doi:10.3343/alm.2018.38.4.296. PMC 5895858. PMID 29611379.
- 1 2 Gilles L, Arslan AD, Marinaccio C, Wen QJ, Arya P, McNulty M, Yang Q, Zhao JC, Konstantinoff K, Lasho T, Pardanani A, Stein B, Plo I, Sundaravel S, Wickrema A, Migliaccio A, Gurbuxani S, Vainchenker W, Platanias LC, Tefferi A, Crispino JD (April 2017). "Downregulation of GATA1 drives impaired hematopoiesis in primary myelofibrosis". The Journal of Clinical Investigation. 127 (4): 1316–1320. doi:10.1172/JCI82905. PMC 5373858. PMID 28240607.
- 1 2 3 4 Gamis AS, Smith FO (November 2012). "Transient myeloproliferative disorder in children with Down syndrome: clarity to this enigmatic disorder". British Journal of Haematology. 159 (3): 277–87. doi:10.1111/bjh.12041. PMID 22966823. S2CID 37593917.
- ↑ Seewald L, Taub JW, Maloney KW, McCabe ER (September 2012). "Acute leukemias in children with Down syndrome". Molecular Genetics and Metabolism. 107 (1–2): 25–30. doi:10.1016/j.ymgme.2012.07.011. PMID 22867885.
- 1 2 Balduini CL, Savoia A (December 2012). "Genetics of familial forms of thrombocytopenia". Human Genetics. 131 (12): 1821–32. doi:10.1007/s00439-012-1215-x. PMID 22886561. S2CID 14396101.
- ↑ Russo R, Andolfo I, Gambale A, De Rosa G, Manna F, Arillo A, Wandroo F, Bisconte MG, Iolascon A (September 2017). "GATA1 erythroid-specific regulation of SEC23B expression and its implication in the pathogenesis of congenital dyserythropoietic anemia type II". Haematologica. 102 (9): e371–e374. doi:10.3324/haematol.2016.162966. PMC 5685218. PMID 28550189.
- ↑ "Rs113966884 RefSNP Report - DBSNP - NCBI".
- 1 2 Nurden AT, Nurden P (July 2016). "Should any genetic defect affecting α-granules in platelets be classified as gray platelet syndrome?". American Journal of Hematology. 91 (7): 714–8. doi:10.1002/ajh.24359. PMID 26971401. S2CID 27009005.
- ↑ Wijgaerts A, Wittevrongel C, Thys C, Devos T, Peerlinck K, Tijssen MR, Van Geet C, Freson K (April 2017). "The transcription factor GATA1 regulates NBEAL2 expression through a long-distance enhancer". Haematologica. 102 (4): 695–706. doi:10.3324/haematol.2016.152777. PMC 5395110. PMID 28082341.
Further reading
- Ohneda K, Yamamoto M (2003). "Roles of hematopoietic transcription factors GATA-1 and GATA-2 in the development of red blood cell lineage". Acta Haematologica. 108 (4): 237–45. doi:10.1159/000065660. PMID 12432220. S2CID 29966039.
- Gurbuxani S, Vyas P, Crispino JD (Jan 2004). "Recent insights into the mechanisms of myeloid leukemogenesis in Down syndrome". Blood. 103 (2): 399–406. doi:10.1182/blood-2003-05-1556. PMID 14512321.
- Muntean AG, Ge Y, Taub JW, Crispino JD (Jun 2006). "Transcription factor GATA-1 and Down syndrome leukemogenesis". Leukemia & Lymphoma. 47 (6): 986–97. doi:10.1080/10428190500485810. PMID 16840187. S2CID 12179485.
- Trainor CD, Evans T, Felsenfeld G, Boguski MS (Jan 1990). "Structure and evolution of a human erythroid transcription factor". Nature. 343 (6253): 92–6. Bibcode:1990Natur.343...92T. doi:10.1038/343092a0. PMID 2104960. S2CID 4339810.
- Zon LI, Tsai SF, Burgess S, Matsudaira P, Bruns GA, Orkin SH (Jan 1990). "The major human erythroid DNA-binding protein (GF-1): primary sequence and localization of the gene to the X chromosome". Proceedings of the National Academy of Sciences of the United States of America. 87 (2): 668–72. Bibcode:1990PNAS...87..668Z. doi:10.1073/pnas.87.2.668. PMC 53326. PMID 2300555.
- Martin DI, Tsai SF, Orkin SH (Mar 1989). "Increased gamma-globin expression in a nondeletion HPFH mediated by an erythroid-specific DNA-binding factor". Nature. 338 (6214): 435–8. Bibcode:1989Natur.338..435M. doi:10.1038/338435a0. PMID 2467208. S2CID 4361486.
- Mouthon MA, Bernard O, Mitjavila MT, Romeo PH, Vainchenker W, Mathieu-Mahul D (Feb 1993). "Expression of tal-1 and GATA-binding proteins during human hematopoiesis". Blood. 81 (3): 647–55. doi:10.1182/blood.V81.3.647.647. PMID 7678994.
- Zon LI, Yamaguchi Y, Yee K, Albee EA, Kimura A, Bennett JC, Orkin SH, Ackerman SJ (Jun 1993). "Expression of mRNA for the GATA-binding proteins in human eosinophils and basophils: potential role in gene transcription". Blood. 81 (12): 3234–41. doi:10.1182/blood.V81.12.3234.3234. PMID 8507862.
- Tsang AP, Visvader JE, Turner CA, Fujiwara Y, Yu C, Weiss MJ, Crossley M, Orkin SH (Jul 1997). "FOG, a multitype zinc finger protein, acts as a cofactor for transcription factor GATA-1 in erythroid and megakaryocytic differentiation". Cell. 90 (1): 109–19. doi:10.1016/S0092-8674(00)80318-9. PMID 9230307. S2CID 2085524.
- Rekhtman N, Radparvar F, Evans T, Skoultchi AI (Jun 1999). "Direct interaction of hematopoietic transcription factors PU.1 and GATA-1: functional antagonism in erythroid cells". Genes & Development. 13 (11): 1398–411. doi:10.1101/gad.13.11.1398. PMC 316770. PMID 10364157.
- Freson K, Devriendt K, Matthijs G, Van Hoof A, De Vos R, Thys C, Minner K, Hoylaerts MF, Vermylen J, Van Geet C (Jul 2001). "Platelet characteristics in patients with X-linked macrothrombocytopenia because of a novel GATA1 mutation". Blood. 98 (1): 85–92. doi:10.1182/blood.V98.1.85. PMID 11418466.
- Mehaffey MG, Newton AL, Gandhi MJ, Crossley M, Drachman JG (Nov 2001). "X-linked thrombocytopenia caused by a novel mutation of GATA-1". Blood. 98 (9): 2681–8. doi:10.1182/blood.V98.9.2681. PMID 11675338.
- Crawford SE, Qi C, Misra P, Stellmach V, Rao MS, Engel JD, Zhu Y, Reddy JK (Feb 2002). "Defects of the heart, eye, and megakaryocytes in peroxisome proliferator activator receptor-binding protein (PBP) null embryos implicate GATA family of transcription factors". The Journal of Biological Chemistry. 277 (5): 3585–92. doi:10.1074/jbc.M107995200. PMID 11724781.
- Freson K, Matthijs G, Thys C, Mariën P, Hoylaerts MF, Vermylen J, Van Geet C (Jan 2002). "Different substitutions at residue D218 of the X-linked transcription factor GATA1 lead to altered clinical severity of macrothrombocytopenia and anemia and are associated with variable skewed X inactivation" (PDF). Human Molecular Genetics. 11 (2): 147–52. doi:10.1093/hmg/11.2.147. PMID 11809723.
- Molete JM, Petrykowska H, Sigg M, Miller W, Hardison R (Jan 2002). "Functional and binding studies of HS3.2 of the beta-globin locus control region". Gene. 283 (1–2): 185–97. doi:10.1016/S0378-1119(01)00858-7. PMID 11867225.
- Hirasawa R, Shimizu R, Takahashi S, Osawa M, Takayanagi S, Kato Y, Onodera M, Minegishi N, Yamamoto M, Fukao K, Taniguchi H, Nakauchi H, Iwama A (Jun 2002). "Essential and instructive roles of GATA factors in eosinophil development". The Journal of Experimental Medicine. 195 (11): 1379–86. doi:10.1084/jem.20020170. PMC 2193540. PMID 12045236.
External links
- Genecards
- GeneReviews/NCBI/NIH/UW entry on GATA1-Related X-Linked Cytopenia
- Geneatlas
- Infobiogen
- Nextbio
- FactorBook GATA1
Other types of GATA2 mutations cause the over-expression of the GATA2 transcription factor. This overexpression is associated with the development of non-familial AML. Apparently, the GATA2 gene's expression level must be delicately balanced between deficiency and excess in order to avoid life-threatening disease.[1][2]
- ↑ Mir MA, Kochuparambil ST, Abraham RS, Rodriguez V, Howard M, Hsu AP, Jackson AE, Holland SM, Patnaik MM (April 2015). "Spectrum of myeloid neoplasms and immune deficiency associated with germline GATA2 mutations". Cancer Medicine. 4 (4): 490–9. doi:10.1002/cam4.384. PMC 4402062. PMID 25619630.
- ↑ Katsumura KR, Bresnick EH (April 2017). "The GATA factor revolution in hematology". Blood. 129 (15): 2092–2102. doi:10.1182/blood-2016-09-687871. PMC 5391619. PMID 28179282.