NCBI Bookshelf. A service of the National Library of Medicine, National Institutes of Health.

Pagon RA, Adam MP, Ardinger HH, et al., editors. GeneReviews® [Internet]. Seattle (WA): University of Washington, Seattle; 1993-2017.

Cover of GeneReviews®

GeneReviews® [Internet].

Show details

GATA1-Related X-Linked Cytopenia

, MD, , PhD, , MD, PhD, and , MD, PhD.

Author Information

Initial Posting: ; Last Update: May 11, 2017.

Summary

Clinical characteristics.

GATA1-related cytopenia is characterized by thrombocytopenia and/or anemia ranging from mild to severe. One or more of the following may also be present: platelet dysfunction, mild β-thalassemia, neutropenia, and congenital erythropoietic porphyria (CEP) in males. Thrombocytopenia typically presents in infancy as a bleeding disorder with easy bruising and mucosal bleeding (e.g., epistaxis). Anemia ranges from minimal (mild dyserythropoiesis) to severe (hydrops fetalis requiring in utero transfusion). At the extreme end of the clinical spectrum, severe hemorrhage and/or erythrocyte transfusion dependence are life long; at the milder end, anemia and the risk for bleeding may decrease spontaneously with age. Heterozygous females may have mild to moderate symptoms such as menorrhagia.

Diagnosis/testing.

Diagnostic laboratory findings usually include macrothrombocytopenia (low number of platelets that are larger than normal) and/or anemia with red cell indices that may be micro-, normo- or macrocytic. Defects in platelet aggregation in response to agonists may be seen. In some cases electron microscopy reveals reduced numbers of platelet alpha granules and dysplastic features in platelets and megakaryocytes.

Management.

Treatment of manifestations: Platelet transfusions for moderate to severe epistaxis, gingival bleeding, or gastrointestinal bleeding; no specific treatment for mild symptoms (easy bruisability); erythrocyte transfusions when anemia is symptomatic (fatigue, tachycardia).

Prevention of primary manifestations: For severe cases, bone marrow transplantation (BMT) can be curative.

Surveillance: Monitoring complete blood counts (with frequency depending on disease severity) to inform supportive care; monitoring those undergoing repeated erythrocyte transfusions for iron overload.

Agents/circumstances to avoid: Those with thrombocytopenia should avoid antiplatelet agents including aspirin and nonsteroidal anti-inflammatory agents (e.g., ibuprofen). Those with thrombocytopenia and/or platelet aggregation defects should avoid contact sports or activities with a high risk of trauma.

Evaluation of relatives at risk: If a GATA1 pathogenic variant has been identified in the family, complete blood counts and molecular genetic testing of at-risk relatives can be offered. At-risk relatives who choose not to have molecular genetic testing should have complete blood counts to evaluate for thrombocytopenia, anemia, or neutropenia.

Genetic counseling.

GATA1-related cytopenia is inherited in an X-linked manner. If the mother of an affected male has a GATA1 pathogenic variant, the chance of transmitting it in each pregnancy is 50%. Affected males pass the pathogenic variant to all of their daughters and none of their sons. Testing for at-risk family members and prenatal testing for pregnancies at increased risk are possible once the pathogenic variant has been identified in the family.

Diagnosis

Suggestive Findings

GATA1-related cytopenia should be suspected in an individual with the following:

  • Thrombocytopenia and/or anemia ranging from mild to severe (including fetal hydrops)
  • One or more of the following:
  • Family history consistent with X-linked inheritance
  • No evidence of Wiskott-Aldrich syndrome (WAS), an X-linked disorder of microthrombocytopenia that can present with or without immunodeficiency

Note: 1) Initial testing should include complete blood count, examination of the blood smear, and bone marrow aspirate and biopsy to confirm that cytopenia results from ineffective hematopoiesis rather than peripheral destruction or sequestration. 2) Hematologic findings in GATA1-related cytopenia are variable and usually nonspecific (i.e., seen in numerous conditions and thus by themselves not indicative of a specific diagnosis). 3) Affected individuals are typically male; females will usually present with milder findings.

Establishing the Diagnosis

Male proband. The diagnosis of GATA1-related cytopenia is established in a male proband with cytopenia resulting from ineffective hematopoiesis by identification of a hemizygous pathogenic variant in GATA1 by molecular genetic testing (see Table 1).

Female proband. The diagnosis of GATA1-related cytopenia may be established in a female proband with hematopoietic cytopenias by identification of a pathogenic variant in GATA1 by molecular genetic testing (Table 1). A pattern of skewed X-inactivation would support the diagnosis. Note: This disorder is not usually first diagnosed in a family via a female proband.

Molecular testing approaches can include single-gene testing, use of a multi-gene panel, and more comprehensive genomic testing:

  • Single-gene testing. Sequence analysis of GATA1 is performed. Although no exon or whole-gene deletions or duplications have been reported as a cause of GATA1-related cytopenias, some laboratories offer gene-targeted deletion/duplication analysis if a pathogenic variant is not found.
  • A multi-gene panel that includes GATA1 and other genes of interest (see Differential Diagnosis) may be considered. Note: (1) The genes included in the panel and the diagnostic sensitivity of the testing used for each gene vary by laboratory and over time. (2) Some multi-gene panels may include genes not associated with the condition discussed in this GeneReview; thus, clinicians need to determine which multi-gene panel provides the best opportunity to identify the genetic cause of the condition at the most reasonable cost while limiting secondary findings. (3) Methods used in a panel may include sequence analysis, deletion/duplication analysis, and/or other non-sequencing based tests.
    For more information on multi-gene panels click here.
  • More comprehensive genomic testing (when available) including exome sequencing and genome sequencing may be considered. Such testing may provide or suggest a diagnosis not previously considered (e.g., mutation of a different gene or genes that results in a similar clinical presentation). For more information on comprehensive genome sequencing click here.

Table 1.

Molecular Genetic Testing Used in GATA1-Related Cytopenia

Gene 1Test MethodProportion of Probands with a Pathogenic Variant 2 Detectable by This Method
GATA1Sequence analysis 3, 422/22 5
Gene-targeted deletion/duplication analysis 6Unknown 7
1.
2.

See Molecular Genetics for information on allelic variants detected in this gene.

3.

Sequence analysis detects variants that are benign, likely benign, of uncertain significance, likely pathogenic, or pathogenic. Pathogenic variants may include small intragenic deletions/insertions and missense, nonsense, and splice site variants; typically, exon or whole-gene deletions/duplications are not detected. For issues to consider in interpretation of sequence analysis results, click here.

4.

Lack of amplification by PCR prior to sequence analysis can suggest a putative (multi)exon or whole-gene deletion on the X chromosome in affected males; confirmation requires additional testing by gene-targeted deletion/duplication analysis.

5.
6.

Gene-targeted deletion/duplication analysis detects intragenic deletions or duplications. Methods that may be used include: quantitative PCR, long-range PCR, multiplex ligation-dependent probe amplification (MLPA), and a gene-targeted microarray designed to detect single exon deletions or duplications.

7.

No data on detection rate of gene-targeted deletion/duplication analysis are available.

Clinical Characteristics

Clinical Description

Individuals with GATA1-related cytopenia have thrombocytopenia and/or anemia.

Males

  • Males typically present in infancy with a bleeding disorder:
    • Affected individuals have easy bruising and mucosal bleeding (e.g., epistaxis).
    • Physical examination may reveal petechiae, ecchymoses, or splenomegaly.
    • Excessive hemorrhage and/or bruising can occur either spontaneously or after trauma or surgery.
  • Anemia, the other major clinical problem in males with this disorder, ranges from minimal with only mild dyserythropoiesis [Freson et al 2001] to severe hydrops fetalis requiring in utero transfusions [Nichols et al 2000].
  • Splenomegaly is commonly present in one form of GATA1-related disease (see Genotype-Phenotype Correlations). Typically, no other physical anomalies are present.

Laboratory findings in males

  • Complete blood count showing the following:
    • Platelet counts are usually low (10-100 x 103/µL), but vary considerably with specific pathogenic variants. Normal counts have also been reported (150-400 x 103/µL), including individuals with a germline pathogenic variant resulting in a truncated protein (GATA-1s; see Molecular Genetics, Pathogenic variants) causing congenital anemia [Hollanda et al 2006, Sankaran et al 2012]. The platelets are typically larger than normal (macrothrombocytopenia).
    • Anemia (hematocrit 16%-35%; normal: 35%-45%) may be present; the severity varies with the specific pathogenic variant. Red cell indices are normochromic but may be mildly microcytic (75-79 fL) or macrocytic (101-103 fL) (normal: 80-99 fL).
    • Significant persistent neutropenia (0.5-2.8 x 103/µL; normal 1.9-8.0 x 103/µL) was observed in one family with a specific GATA1 pathogenic variant [Hollanda et al 2006]; findings were variable in families with other GATA1 variants [Sankaran et al 2012, Zucker et al 2016].
    Note: Thrombocytopenia, anemia, and neutropenia are usually defined as two standard deviations below values observed in the normal population.
  • Peripheral blood smear that may show the following:
    • Some platelets that are larger and more spherical than the typical discoid morphology. Platelets may be pale, reflecting reduced granularity.
    • Variation in erythrocyte size and shape and hypochromia, reflecting low hemoglobin content
    • Decreased neutrophils with abnormal morphology; this rare finding was reported in one family with an unusual germline pathogenic variant resulting in a truncated protein (GATA-1s; discussed in Molecular Genetics, Pathogenic variants) [Hollanda et al 2006].
  • Bone marrow biopsy that may show the following:
    • Hyper- or hypocellularity
    • Increased or decreased numbers of megakaryocytes
    • Small, dysplastic megakaryocytes with signs of incomplete maturation
    • Dyserythropoiesis
    • Hypocellularity of erythroid and granulocytic lineages
    • Mild to moderate reticulin fibrosis [Åström et al 2015]
  • Platelet function abnormalities. Defects in platelet aggregation in response to agonists (e.g., ristocetin, adenosine diphosphate, epinephrine, or collagen) occur in some cases [Thompson et al 1977, Freson et al 2001, Balduini et al 2004, Hollanda et al 2006]. These studies can be normal in some affected individuals.
  • Electron microscopy. Findings in some cases include reduced numbers of platelet alpha granules and dysplastic features in megakaryocytes and platelets.
  • In subtypes associated with globin chain imbalance, findings consistent with mild hemolysis, including mild reticulocytosis, elevated LDH, and low haptoglobin, may be present. In addition, HbA2 and HbF may be elevated.
    Definitions of terms used to describe this disorder

    Thrombocytopenia. Reduced platelet count

    Macrothrombocytopenia. Thrombocytopenia with large platelets

    Dyserythropoiesis. Impaired production and maturation of erythrocytes (red blood cells)

    Thalassemia. An inherited form of anemia associated with unbalanced globin chain synthesis

    Hemoglobin. The oxygen-carrying compound of red blood cells, made up of heme, α-globin, and β-globin. β-thalassemia is associated with decreased β-globin synthesis in red blood cells.

Findings in heterozygous females. Females may manifest platelet abnormalities [White 2007] and mild to moderate symptoms such as menorrhagia or easy bruising, presumably related to the proportion of relevant cells that contain the pathogenic GATA1 variant on the active X chromosome [Nichols et al 2000; Raskind et al 2000; Balduini et al 2004; Del Vecchio et al 2005; Raskind, unpublished observations].

  • Platelet counts may be normal or mildly to moderately decreased [Nichols et al 2000]; this may depend on the nature of the pathogenic variant or other (either genetic or environmental) modifiers.
  • Morphologic abnormalities of platelets can be detected by electron microscopy [White 2007] and in some instances on peripheral blood smears [Tubman et al 2007].
  • Two distinct platelet morphologies can be observed on peripheral blood smear, reflecting mosaicism secondary to random X-chromosome inactivation.

Course and prognosis. The long-term course in both males and females depends on disease severity:

  • At the extreme end of the clinical spectrum, severe hemorrhage and/or erythrocyte transfusion dependence are life long.
  • At the milder end, the risk for bleeding may spontaneously decrease with age, despite continued thrombocytopenia [Mehaffey et al 2001, Del Vecchio et al 2005].
  • Some affected individuals may be recognized only after incidental findings of mild to moderate cytopenias on blood count analysis. These individuals have a good prognosis.

Genotype-Phenotype Correlations

Table 2 outlines the relationship between specific GATA1 pathogenic variants and associated phenotypic features.

Table 2.

Genotype-Phenotype Correlations

Pathogenic Variant 1Platelet Phenotype 2Platelet AggregationRed Cell PhenotypeOther FeaturesReferences
p.Val205Met
Large
Not studied
Dyserythropoietic, fetal hydrops
Cryptorchidism 3Nichols et al [2000]
p.Gly208Ser
Large
DecreasedNormalMehaffey et al [2001] 4, 5
p.Gly208Arg↓↓
Large
Not studied
Dyserythropoietic
Cryptorchidism in proband but also in 2 sibs with wild type GATA1 3Del Vecchio et al [2005], Kratz et al [2008] 4, 5
p.Arg216Gln
Large
Normal, but prolonged bleeding timeMild β-thalassemia, mild anemiaSplenomegalyThompson et al [1977], Raskind et al [2000], Yu et al [2002], Balduini et al [2004], Hughan et al [2005], Tubman et al [2007], Campbell et al [2013], Ǻström et al [2015]
p.Arg216TrpNot reportedMild β-thalassemiaCongenital erythropoietic porphyria, splenomegalyHindmarsh [1986], Phillips et al [2007], Ged et al [2009], Campbell et al [2013]
p.Asp218Gly
Large
DecreasedDyserythropoiesis without anemiaFreson et al [2001], White [2007], White et al [2007]
p.Asp218Tyr↓↓
Large
Not studiedSevere anemiaPlatelets in carrier female expressed only wild type alleleFreson et al [2002]
p.Ter414ArgextTer42
Large
Not studiedNormalLu(a-b-) red cellsSingleton et al [2013]
332G>CNormal counts, but dysplastic megakaryocytesDecreasedMacrocytic anemia of variable severityNeutropeniaHollanda et al [2006]
p.Val74LeuNormal or ↓Not studiedMacrocytic anemia of variable severitySankaran et al [2012]
c.220+1delGNormalNot studiedAnemiaSankaran et al [2012]
c.220G>CNormalNot studiedMacrocytic anemiaKlar et al [2014]
p.Met1_Cys83delNot studiedAnemiaParrella et al [2014]
1.

See Table 4 for details.

2.

Decreased platelet alpha granules are observed in all affected males studied.

3.

Cryptorchidism has been reported in several males with GATA1 pathogenic variants [Nichols et al 2000, Del Vecchio et al 2005]. Although Gata1 is expressed in mouse testis, knockout of Gata1 in Sertoli cells within the testis had no effect, suggesting that Gata1 is not essential for Sertoli cell function [Lindeboom et al 2003]. The independent segregation of cryptorchidism and GATA1 pathogenic variants in one of the two families [Del Vecchio et al 2005], in conjunction with the mouse data, make the mechanistic relationship between GATA1 pathogenic variants and cryptorchidism unclear at this point.

4.

No response to splenectomy and/or steroids

5.

Decreased bleeding episodes with age, despite persistence of thrombocytopenia

For further information on murine and in vitro experiments involving GATA-1, see Molecular Genetics, Pathogenic variants.

Nomenclature

Until pathogenic variants in GATA1 were shown to underlie this heterogeneous disorder, a variety of terms were coined for the different clinical presentations. The first term used was X-linked thrombocytopenia with thalassemia (XLTT) [Raskind et al 2000]. Other terms used in the past and still in the current literature are ‘familial dyserythropoietic anemia and thrombocytopenia’ [Nichols et al 2000, Del Vecchio et al 2005] and ‘X-linked macrothrombocytopenia’ [Freson et al 2001].

To describe individuals with a clinical diagnosis of Diamond-Blackfan anemia in whom GATA1 pathogenic variants are identified and ribosomal protein variants are absent, the authors suggest the phrase ‘variant DBA associated with pathogenic variant of GATA1.’

Prevalence

GATA1-related cytopenia is rare; the prevalence is not known. To date, hematopoietic disease caused by inherited pathogenic variants in GATA1 has been reported in 22 families [Nichols et al 2000, Freson et al 2001, Mehaffey et al 2001, Freson et al 2002, Yu et al 2002, Balduini et al 2004, Del Vecchio et al 2005, Hughan et al 2005, Phillips et al 2005, Hollanda et al 2006, Sankaran et al 2012, Singleton et al 2013, Hermans et al 2014, Klar et al 2014, Parrella et al 2014, Åström et al 2015, Di Pierro et al 2015, Zucker et al 2016].

GATA1 pathogenic variants may be more common than previously appreciated, particularly in persons with mild, unexplained thrombocytopenia/‘gray platelet syndrome’ present since birth [Tubman et al 2007] or individuals with congenital hypoplastic anemia/Diamond-Blackfan anemia with no ribosomal protein pathogenic variants [Sankaran et al 2012].

Differential Diagnosis

GATA1-related cytopenia must be distinguished from other acquired and inherited thrombocytopenias and platelet function abnormalities [Balduini & Savoia 2004, Drachman 2004] (see Table 3). Algorithms exist to help differentiate among these disorders [Drachman 2004, Noris et al 2004].

Because of its X-linked mode of inheritance and association with thrombocytopenia, Wiskott-Aldrich syndrome (WAS) can be confused with GATA1-related cytopenia. Distinguishing features of WAS include small platelets, eczema (~80%), and immunodeficiency, although individuals with milder pathogenic variants may manifest with microthrombocytopenia only.

In GATA1-related cytopenia, platelets are usually large and may be hypogranular. Relatively common congenital causes of macrothrombocytopenia that could potentially be confused with GATA1-related disorders are described in Table 3.

Table 3.

Etiology and Characteristics of Other Inherited Syndromes of Macrothrombocytopenia

NameGeneMode of InheritanceFeatures
Bernard-Soulier syndrome
(OMIM 231200)
GP1BA
GP1BB
GP9
AR 1
  • Severely defective ristocetin-induced platelet agglutination
  • Severe bleeding disorder
MYH9-related syndromesMYH9AD
  • Neutrophil inclusions
  • Hearing loss, cataract, or renal defects variably present
Mediterranean thrombocytopenia
(OMIM 153670)
GP1BAAD
  • Dysmegakaryo-cytopoiesis
Paris-Trousseau thrombocytopenia
(OMIM 188025)
See footnote 2AD
  • Cardiac and facial abnormalities
  • Intellectual disability
Jacobsen syndrome
(OMIM 147791)
22q11.2 deletion syndromeSee footnote 3AD
  • Facial and cardiac abnormalities
  • Intellectual disability
  • Psychiatric disorders
Gray platelet syndrome
(OMIM 139090)
NBEAL2
GATA1 4
See footnote 5
  • Pale platelets
  • Reduced or absent α-granules
1.

Heterozygotes may have mild disease.

2.

Paris-Trousseau thrombocytopenia and Jacobsen syndrome are contiguous gene deletion syndromes.

3.
4.

One person with an X-linked form of this syndrome was found to have a GATA1 pathogenic variant [Wechsler et al 2002, Tubman et al 2007] (see Genetically Related Disorders).

5.

Most cases of GPS are simplex (i.e., a single occurrence in a family), but sibships with unaffected, often consanguineous parents consistent with an autosomal recessive mode of inheritance and families with apparent autosomal dominant or X-linked transmission have been reported [reviewed in Nurden & Nurden 2007].

Management

Evaluations Following Initial Diagnosis

To establish the extent of disease and needs in an individual diagnosed with GATA1-related cytopenia, the following are recommended:

  • Complete blood count and examination of the peripheral smear to assess the degree of cytopenia(s)
  • Detailed history of age at which hematologic disease was manifest
  • Documentation of abnormal/unexpected bleeding episodes and platelet counts obtained at the time of the episodes to help determine whether platelet function is abnormal and whether disease severity has changed over time
    Note: Platelet aggregation studies may also be useful to identify functional abnormalities that predict a greater risk of bleeding for any given platelet count, but studies can be difficult to interpret when platelet counts are lower than 100,000/μL.
  • Consultation with a clinical geneticist and/or genetic counselor

Treatment of Manifestations

Individuals with GATA1-related cytopenia are treated supportively.

Thrombocytopenia. Individuals with moderate to severe epistaxis, gingival bleeding, or gastrointestinal bleeding should receive platelet transfusions. Transfusion requirements vary from person to person as bleeding can be related to quantitative and/or qualitative platelet defects.

  • For individuals with thrombocytopenia and/or platelet aggregation defects, DDAVP treatment may be helpful for short-term management of mild to moderate bleeding.
  • Individuals who are only mildly symptomatic (easy bruisability without mucosal or more severe bleeding) do not require specific treatment.
  • There is no evidence that splenectomy is beneficial in people with GATA1-related disease, although this treatment may be considered if splenomegaly is severe. Although splenectomy may improve the cytopenias, platelet dysfunction will not be improved.

Anemia. Erythrocyte transfusions are indicated when anemia is symptomatic (fatigue, tachycardia).

  • Iron overload and the development of alloantibodies may limit chronic transfusion therapy.
  • Extended pre-transfusion red blood cell phenotyping and matching for minor erythrocyte antigens in individuals receiving frequent transfusions can reduce the risk of alloimmunization.

Neutropenia. Individuals with neutropenia who present with fever should be evaluated promptly with a physical examination, complete blood count, and blood culture and should receive appropriate parenteral antibiotics.

Bone marrow transplantation (BMT). For severe cases, BMT can be curative [Hollanda et al 2006, Phillips et al 2007, Parrella et al 2014].

  • BMT should be considered in individuals with severe phenotypes of GATA1-related cytopenia, particularly if an HLA-matched donor is available.
  • While BMT may offer a cure, clinical experience with BMT in this disease is limited and families must be counseled on the significant risks and morbidity associated with BMT.

Prevention of Primary Manifestations

The only definitive cure for GATA1-related cytopenia is bone marrow transplantation.

Prevention of Secondary Complications

Individuals with thrombocytopenia and/or platelet aggregation defects should receive a platelet transfusion prior to surgical or invasive dental procedures.

Individuals with neutropenia should be counseled regarding their increased risk of infection. They should avoid crowds and contact with individuals who have communicable diseases. When febrile, those who are severely neutropenic (absolute neutrophil count <500/µL) should seek medical attention; typically blood cultures are obtained and parenteral antibiotics are administered to avoid the possibility of life-threatening sepsis.

Surveillance

Depending on the phenotype of the disease, complete blood counts should be monitored so that supportive care can be provided as needed. Individuals with mild cytopenias require infrequent monitoring (yearly), while those with severe cytopenias who require transfusions should have complete blood counts monthly or as indicated by clinical signs and symptoms.

Individuals undergoing repeated erythrocyte transfusions should be monitored for iron overload and managed appropriately with iron chelation therapy.

Agents/Circumstances to Avoid

Individuals with thrombocytopenia should avoid antiplatelet agents including aspirin and nonsteroidal anti-inflammatory agents (e.g., ibuprofen).

Individuals with thrombocytopenia and/or platelet aggregation defects should be advised to avoid contact sports or activities with a high risk of trauma.

Individuals with significant neutropenia should avoid crowds and close contact with persons who have a communicable disease to minimize risk of infection.

Individuals with significant splenomegaly should avoid contact sports, which involve increased risk for traumatic splenic rupture.

Evaluation of Relatives at Risk

It is appropriate to evaluate apparently asymptomatic at-risk relatives of an affected individual in order to identify as early as possible those who would benefit from prompt initiation of treatment and preventive measures.

Evaluations can include:

  • Molecular genetic testing for the familial GATA1 pathogenic variant;
  • A screening complete blood count to evaluate for thrombocytopenia, anemia, or neutropenia.
    Note: Platelet, erythrocyte, and neutrophil counts can vary significantly in individuals with GATA1 pathogenic variants; normal results do not rule out the possibility that the relative has a GATA1 pathogenic variant.

See Genetic Counseling for issues related to testing of at-risk relatives for genetic counseling purposes.

Therapies Under Investigation

Search ClinicalTrials.gov for access to information on clinical studies for a wide range of diseases and conditions. Note: There may not be clinical trials for this disorder.

Other

Unlike immune-mediated platelet disorders such as immune thrombocytopenic purpura, GATA1-related thrombocytopenia does not respond to steroid or immunoglobulin therapy.

Supplemental erythropoietin therapy is unlikely to be effective because the anemia is secondary to ineffective erythropoiesis, not erythropoietin deficiency.

Genetic Counseling

Genetic counseling is the process of providing individuals and families with information on the nature, inheritance, and implications of genetic disorders to help them make informed medical and personal decisions. The following section deals with genetic risk assessment and the use of family history and genetic testing to clarify genetic status for family members. This section is not meant to address all personal, cultural, or ethical issues that individuals may face or to substitute for consultation with a genetics professional. —ED.

Mode of Inheritance

GATA1-related cytopenia is inherited in an X-linked manner.

Risk to Family Members

Parents of a male proband

  • The father of an affected male will not have the disorder nor will he be hemizygous for the GATA1 pathogenic variant; therefore, he does not require further evaluation/testing.
  • In a family with more than one affected individual, the mother of an affected male is an obligate heterozygote (carrier). If a woman has more than one affected son and no other affected relatives and if the pathogenic variant cannot be detected in her leukocyte DNA, she has germline mosaicism (evidence of germline mosaicism has not been observed).
  • If a male is the only affected family member (i.e., a simplex case), the mother may be a heterozygote (carrier) or the affected male may have a de novo GATA1 pathogenic variant, in which case the mother is not a carrier. Because very few families with GATA1 pathogenic variants have been described to date, the frequency of de novo pathogenic variants is not known.

Sibs of a male proband. The risk to sibs depends on the genetic status of the mother:

  • If the mother of the proband has a GATA1 pathogenic variant, the chance of transmitting it in each pregnancy is 50%.
    • Males who inherit the pathogenic variant will be affected.
    • Females who inherit the pathogenic variant will be heterozygous and will usually not be affected, but may have reduced hematocrits and platelet counts to a variable degree. Large platelets may also be present and those with the globin chain imbalance subtype may have splenomegaly and slightly decreased β-globin synthesis.
  • If the proband represents a simplex case (i.e., a single occurrence in a family) and if the GATA1 pathogenic variant cannot be detected in the leukocyte DNA of the mother, the risk to sibs is slightly greater than that of the general population (though still <1%) because of the theoretic possibility of maternal germline mosaicism.

Offspring of a proband. Affected males transmit the GATA1 pathogenic variant to:

  • All of their daughters, who will be carriers (heterozygotes) and will usually not be affected (see Clinical Description);
  • None of their sons.

Other family members. The proband's maternal aunts may be at risk of being heterozygotes (carriers) for the pathogenic variant and the aunts’ offspring, depending on their gender, may be at risk of being heterozygotes (carriers) for the pathogenic variant or of being affected.

Heterozygote (Carrier) Detection

Molecular genetic testing of at-risk female relatives to determine their genetic status is most informative if the pathogenic variant has been identified in the proband.

Note: Females who are heterozygotes (carriers) for this X-linked disorder may develop clinical findings related to the disorder (see Clinical Description).

Related Genetic Counseling Issues

See Management, Evaluation of Relatives at Risk for information on evaluating at-risk relatives for the purpose of early diagnosis and treatment.

Family planning

  • The optimal time for determination of genetic risk, clarification of carrier status, and discussion of the availability of prenatal testing is before pregnancy.
  • It is appropriate to offer genetic counseling (including discussion of potential risks to offspring and reproductive options) to young adults who are affected, are carriers, or are at risk of being carriers.

DNA banking is the storage of DNA (typically extracted from white blood cells) for possible future use. Because it is likely that testing methodology and our understanding of genes, allelic variants, and diseases will improve in the future, consideration should be given to banking DNA of affected individuals.

Prenatal Testing and Preimplantation Genetic Diagnosis

Once the GATA1 pathogenic variant has been identified in an affected family member, prenatal testing for a pregnancy at increased risk and preimplantation genetic diagnosis for GATA1-related cytopenia are possible.

Resources

GeneReviews staff has selected the following disease-specific and/or umbrella support organizations and/or registries for the benefit of individuals with this disorder and their families. GeneReviews is not responsible for the information provided by other organizations. For information on selection criteria, click here.

  • Platelet Disorder Support Association (PDSA)
    133 Rollins Avenue
    #5
    Rockville MD 20852
    Phone: 877-528-3538 (toll-free); 301-770-6636
    Fax: 301-770-6638
    Email: pdsa@pdsa.org
  • Medline Plus

Molecular Genetics

Information in the Molecular Genetics and OMIM tables may differ from that elsewhere in the GeneReview: tables may contain more recent information. —ED.

Table A.

GATA1-Related X-Linked Cytopenia: Genes and Databases

GeneChromosome LocusProteinLocus SpecificHGMD
GATA1Xp11​.23Erythroid transcription factorGATA1 @ LOVDGATA1

Data are compiled from the following standard references: gene from HGNC; chromosome locus, locus name, critical region, complementation group from OMIM; protein from UniProt. For a description of databases (Locus Specific, HGMD) to which links are provided, click here.

Table B.

OMIM Entries for GATA1-Related X-Linked Cytopenia (View All in OMIM)

300367THROMBOCYTOPENIA, X-LINKED, WITH OR WITHOUT DYSERYTHROPOIETIC ANEMIA; XLTDA
305371GATA-BINDING PROTEIN 1; GATA1
314050THROMBOCYTOPENIA WITH BETA-THALASSEMIA, X-LINKED; XLTT

Gene structure. GATA1 has six exons, although the first exon is non-coding and is not counted in some of the literature. For a detailed summary of gene and protein information, see Table A, Gene.

Pathogenic variants. Most germline GATA1 variants associated with cytopenias are missense variants. These variants cluster in exon 4 amino acid residues 205, 208, 216, and 218 within the amino-terminal zinc finger domain. They either affect erythroid transcription factor (GATA-1) binding to DNA or interaction of GATA-1 with its essential cofactor, friend of GATA (FOG)-1 [Nichols et al 2000, Freson et al 2001, Mehaffey et al 2001, Freson et al 2002, Yu et al 2002, Balduini et al 2004, Del Vecchio et al 2005].

A pathogenic variant in exon 2 of GATA1 that alters splicing was found in one family with anemia and neutropenia [Hollanda et al 2006]. Similar variants have been identified in several families with Diamond-Blackfan anemia without pathogenic ribosomal protein variants [Sankaran et al 2012, Parrella et al 2014, Klar et al 2014, Zucker et al 2016] and unpublished studies by several groups. These variants result in the exclusive production of an amino-truncated isoform of GATA-1, termed GATA-1s (for GATA-1 short; also discussed in Genetically Related Disorders). In the context of Down syndrome (DS, trisomy 21), somatic variants resulting in the production of only GATA-1s are associated with leukemia and transient myeloproliferative disorder (TMD) [Wechsler et al 2002]; however, the same GATA1 variants present in the germline of persons who do not have DS cause cytopenia but not leukemia [Hollanda et al 2006]. In mice, analogous variants increase the proliferative capacity of embryonic megakaryocyte precursors but produce a minimal hematopoietic phenotype in adults [Li et al 2005].

Cis element variants affecting GATA-1 binding to target genes have also been implicated in red cell production or function. For example, Africans frequently carry a variant in the Duffy antigen/chemokine receptor (DARC) gene promoter that disrupts GATA-1 binding [Tournamille et al 1995]. This leads to the common African Duffy negative red cell phenotype, which confers resistance to Plasmodium vivax malaria.

Congenital erythropoietic porphyria (CEP) can also be caused by variants in the promoter region of the gene encoding the heme synthetic enzyme uroporphyrinogen III synthase, where GATA-1 normally binds [Solis et al 2001].

X-linked sideroblastic anemia (XLSA) typically results from partial loss-of-function missense variants in the erythroid-specific heme biosynthesis protein 5-aminolevulinate synthase 2 (ALAS2). Variants in the GATA binding site located in a transcriptional enhancer element in ALAS2 have been identified in several pedigrees with XLSA [Campagna et al 2014, Kaneko et al 2014].

As a master regulator of erythrocyte and megakaryocyte/platelet development, GATA1 both activates and represses hundreds of genes in each of these lineages. Presumably, different missense variants in GATA1 cause distinct phenotypes by altering the expression of specific subsets of target genes. These pathogenic variants could affect GATA1 DNA binding, interactions with cofactors, or both. Both of these properties of the GATA zinc fingers have been mapped by structural studies. However, recent analysis of GATA1 pathogenic variants in murine complementation systems showed that structural studies and in vitro examination of purified recombinant proteins did not always accurately elucidate the effects of variants, and in vivo studies are required [Campbell et al 2013]. Specifically, p.Arg216Gln and p.Arg216Trp variants that impaired DNA binding in vitro did not measurably affect in vivo target gene occupancy. Instead, diminished TAL1 complex recruitment to GATA-1 target genes was implicated. Thus, establishing genotype-phenotype relationships in GATA1-associated anemias and thrombocytopenias presents a complex but worthwhile challenge that will likely elucidate general concepts of transcription factor function and human disease.

Table 4.

GATA1 Pathogenic Variants Discussed in This GeneReview

DNA Nucleotide Change
(Alias 1)
Predicted Protein ChangeReference Sequences
c.2T>Cp.Met1_Cys83del 2NM_002049​.3
NP_002040​.1
c.220G>C 3p.Val74Leu
c.220+1delG 4
c.613G>Ap.Val205Met
c.622_623delGGinsTC
(622_623GG>TC)
p.Gly208Ser
c.622G>Cp.Gly208Arg
c.647G>Ap.Arg216Gln 5
c.646C>Tp.Arg216Trp
(332G>C) 6
c.652G>Tp.Asp218Tyr
c.653A>Gp.Asp218Gly
c.1240T>Cp.Ter414ArgextTer42 7

Note on variant classification: Variants listed in the table have been provided by the authors. GeneReviews staff have not independently verified the classification of variants.

Note on nomenclature: GeneReviews follows the standard naming conventions of the Human Genome Variation Society (www​.hgvs.org). See Quick Reference for an explanation of nomenclature.

See Table 2 for genotype-phenotype correlations.

1.

Variant designation that does not conform to current naming conventions

2.

Obliterates initiation codon; alternative initiation Met84 residue is used, resulting in lack of full length cDNA [Parrella et al 2014].

3.

Alternation of the last nucleotide of exon 2; predicted to affect splicing [Sankaran et al 2012]

4.

Exon skipping and frame shift are predicted because the deletion affects the canonic splice donor site [Sankaran et al 2012].

5.

Also reported in one family with ‘gray platelet syndrome’ (see Genetically Related Disorders)

6.

Pathogenic variant alias reported in Hollanda et al [2006]

7.

Pathogenic variant in stop codon 414 results in addition of 41 amino acids and use of new stop codon at residue 42 [Singleton et al 2013].

Normal gene product. GATA1 encodes a nuclear protein of 413 amino acid residues that contains two zinc fingers and an acidic amino terminal domain that can function as a transcriptional activator [Ferreira et al 2005, Lowry & Mackay 2006]. The C-terminal zinc finger is responsible for DNA binding activity for most or all target genes and the N-terminal zinc finger plays a role in stabilization of GATA-1 binding to DNA at a subset of target sites containing duplicated or palindromic GATA-1 motifs [Ohneda & Yamamoto 2002]. The N-f is also critical for binding of GATA-1 to numerous partner proteins, including FOG1, an essential factor required for many GATA-1 functions [Tsang et al 1997, Fox et al 1999]. GATA-1 is expressed in hematopoietic lineages and in Sertoli cells of testis. Gene targeting studies in mice indicate that GATA-1 is essential for the development of erythrocyte, megakaryocyte, mast cell, and eosinophil lineages. It is not known whether individuals with inherited GATA1 pathogenic variants have defects in the latter two cell lineages.

Abnormal gene product. All pathogenic variants are missense variants, indels, nonsense variants, or splice site substitutions resulting in the production of an abnormal protein. Missense variants in N-f affect its ability to bind either GATA1 sites in DNA, the cofactor FOG1, or both. Splice site variants result in a short form of the protein, GATA-1s. Mice genetically engineered to express GATA-1s show prenatal anemia and megakaryocyte proliferation, but newborn and adult mice display no hematopoietic abnormalities [Li et al 2005]. The functions of these abnormal proteins and their relationship to disease phenotypes are discussed in Genotype-Phenotype Correlations and in Table 2.

Cancer and Benign Tumors

Two hematopoietic disorders in children with Down syndrome (DS) associated with acquired (somatic) pathogenic variants in exon 2 of GATA1 are transient myeloproliferative disorder (TMD) and acute megakaryoblastic leukemia (M7 subtype, DS-AMKL) [Wechsler et al 2002, Elagib et al 2003, Waltzer et al 2003, Ahmed et al 2004, Creutzig et al 2005, Crispino 2005a, Crispino 2005b, Muntean et al 2006, Roy et al 2009, Roberts et al 2013].

TMD, found in up to 10% of infants with DS, usually resolves spontaneously; however, TMD confers a markedly increased risk for DS-AMKL [Wechsler et al 2002, Ahmed et al 2004, Crispino 2005a, Crispino 2005b, Hitzler & Zipursky 2005]. The acquired exon 2 variants lead to premature arrest of translation and reinitiation of protein synthesis at the downstream methionine codon at position 83, and result in the production of GATA-1 short isoform (GATA-1s) that lacks the amino-terminal activation domain. Some splice site variants also result in generation of GATA-1s. Two novel GATA1 variants involving internal deletions of either amino acids 77-199 or 74-88 were identified in six individuals with TMD [Toki et al 2013]. How GATA1 variants synergize with trisomy 21 to promote DS-AMKL is unknown.

One individual with severe anemia and thrombocytopenia caused by a pathogenic missense variant in GATA1 (p.Val205Met) developed myelodysplastic syndrome 18 years after a failed bone marrow transplantation. It is not clear whether the MDS with a clonal deletion of 20q was due to the underlying disease caused by the pathogenic variant of GATA1, bone marrow transplant associated toxicity, or both [Authors, unpublished data].

References

Literature Cited

  • Ahmed M, Sternberg A, Hall G, Thomas A, Smith O, O'Marcaigh A, Wynn R, Stevens R, Addison M, King D, Stewart B, Gibson B, Roberts I, Vyas P. Natural history of GATA1 mutations in Down syndrome. Blood. 2004;103:2480–9. [PubMed: 14656875]
  • Åström M, Hahn-Strömberg V, Zetterberg E, Vedin I, Merup M, Palmblad J. X-linked thrombocytopenia with thalassemia displays bone marrow reticulin fibrosis and enhanced angiogenesis: comparisons with primary myelofibrosis. Am J Hematol. 2015;90:E44–8. [PubMed: 25421114]
  • Balduini CL, Pecci A, Loffredo G, Izzo P, Noris P, Grosso M, Bergamaschi G, Rosti V, Magrini U, Ceresa IF, Conti V, Poggi V, Savoia A. Effects of the R216Q mutation of GATA-1 on erythropoiesis and megakaryocytopoiesis. Thromb Haemost. 2004;91:129–40. [PubMed: 14691578]
  • Balduini CL, Savoia A. Inherited thrombocytopenias: molecular mechanisms. Semin Thromb Hemost. 2004;30:513–23. [PubMed: 15497094]
  • Campagna DR, de Bie CI, Schmitz-Abe K, Sweeney M, Sendamarai AK, Schmidt PJ, Heeney MM, Yntema HG, Kannengiesser C, Grandchamp B, Niemeyer CM, Knoers NV, Swart S, Marron G, van Wijk R, Raymakers RA, May A, Markianos K, Bottomley SS, Swinkels DW, Fleming MD. X-linked sideroblastic anemia due to ALAS2 intron 1 enhancer element GATA-binding site mutations. Am J Hematol. 2014;89:315–9. [PMC free article: PMC3943703] [PubMed: 24166784]
  • Campbell AE, Wilkinson-White L, Mackay JP, Matthews JM, Blobel GA. Analysis of disease-causing GATA1 mutations in murine gene complementation systems. Blood. 2013;121:5218–27. [PMC free article: PMC3695365] [PubMed: 23704091]
  • Creutzig U, Reinhardt D, Diekamp S, Dworzak M, Stary J, Zimmermann M. AML Patients with Down syndrome have a high cure rate with AML-BFM therapy with reduced dose intensity. Leukemia. 2005;19:1355–60. [PubMed: 15920490]
  • Crispino JD. GATA1 in normal and malignant hematopoiesis. Semin Cell Dev Biol. 2005a;16:137–47. [PubMed: 15659348]
  • Crispino JD. GATA1 mutations in Down syndrome: implications for biology and diagnosis of children with transient myeloproliferative disorder and acute megakaryoblastic leukemia. Pediatr Blood Cancer. 2005b;44:40–4. [PubMed: 15390312]
  • Del Vecchio GC, Giordani L, De Santis A, De Mattia D. Dyserythropoietic anemia and thrombocytopenia due to a novel mutation in GATA-1. Acta Haematol. 2005;114:113–6. [PubMed: 16103636]
  • Di Pierro E, Russo R, Karakas Z, Brancaleoni V, Gambale A, Kurt I, Winter SS, Granata F, Czuchlewski DR, Langella C, Iolascon A, Cappellini MD. Congenital erythropoietic porphyria linked to GATA1-R216W mutation: challenges for diagnosis. Eur J Haematol. 2015;94:491–7. [PubMed: 25251786]
  • Drachman JG. Inherited thrombocytopenia: when a low platelet count does not mean ITP. Blood. 2004;103:390–8. [PubMed: 14504084]
  • Elagib KE, Racke FK, Mogass M, Khetawat R, Delehanty LL, Goldfarb AN. RUNX1 and GATA-1 coexpression and cooperation in megakaryocytic differentiation. Blood. 2003;101:4333–41. [PubMed: 12576332]
  • Ferreira R, Ohneda K, Yamamoto M, Philipsen S. GATA1 function, a paradigm for transcription factors in hematopoiesis. Mol Cell Biol. 2005;25:1215–27. [PMC free article: PMC548021] [PubMed: 15684376]
  • Fox AH, Liew C, Holmes M, Kowalski K, Mackay J, Crossley M. Transcriptional cofactors of the FOG family interact with GATA proteins by means of multiple zinc fingers. EMBO J. 1999;18:2812–22. [PMC free article: PMC1171362] [PubMed: 10329627]
  • Freson K, Devriendt K, Matthijs G, Van Hoof A, De Vos R, Thys C, Minner K, Hoylaerts MF, Vermylen J, Van Geet C. Platelet characteristics in patients with X-linked macrothrombocytopenia because of a novel GATA1 mutation. Blood. 2001;98:85–92. [PubMed: 11418466]
  • Freson K, Matthijs G, Thys C, Marien P, Hoylaerts MF, Vermylen J, Van Geet C. 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. Hum Mol Genet. 2002;11:147–52. [PubMed: 11809723]
  • Ged C, Moreau-Gaudry F, Richard E, Robert-Richard E, de Verneuil H. Congenital erythropoietic porphyria: mutation update and correlations between genotype and phenotype. Cell Mol Biol (Noisy-le-grand) 2009;55:53–60. [PubMed: 19268002]
  • Hermans C, De Waele L, Van Geet C, Freson K. Novel GATA1 mutation in residue D218 leads to macrothrombocytopenia and clinical bleeding problems. Platelets. 2014;25:305–7. [PubMed: 23971719]
  • Hindmarsh JT. The porphyrias: recent advances. Clin Chem. 1986;32:1255–63. [PubMed: 3521939]
  • Hitzler JK, Zipursky A. Origins of leukaemia in children with Down syndrome. Nat Rev Cancer. 2005;5:11–20. [PubMed: 15630411]
  • Hollanda LM, Lima CS, Cunha AF, Albuquerque DM, Vassallo J, Ozelo MC, Joazeiro PP, Saad ST, Costa FF. An inherited mutation leading to production of only the short isoform of GATA-1 is associated with impaired erythropoiesis. Nat Genet. 2006;38:807–12. [PubMed: 16783379]
  • Hughan SC, Senis Y, Best D, Thomas A, Frampton J, Vyas P, Watson SP. Selective impairment of platelet activation to collagen in the absence of GATA1. Blood. 2005;105:4369–76. [PubMed: 15701726]
  • Kaneko K, Furuyama K, Fujiwara T, Kobayashi R, Ishida H, Harigae H, Shibahara S. Identification of a novel erythroid-specific enhancer for the ALAS2 gene and its loss-of-function mutation which is associated with congenital sideroblastic anemia. Haematologica. 2014;99:252–61. [PMC free article: PMC3912954] [PubMed: 23935018]
  • Klar J, Khalfallah A, Arzoo PS, Gazda HT, Dahl N. Recurrent GATA1 mutations in Diamond-Blackfan anaemia. Br J Haematol. 2014;166:949–51. [PubMed: 24766296]
  • Kratz CP, Niemeyer CM, Karow A, Volz-Fleckenstein M, Schmitt-Gräff A, Strahm B. Congenital transfusion-dependent anemia and thrombocytopenia with myelodysplasia due to a recurrent GATA1(G208R) germline mutation. Leukemia. 2008;22:432–4. [PubMed: 17713552]
  • Li Z, Godinho FJ, Klusmann JH, Garriga-Canut M, Yu C, Orkin SH. Developmental stage-selective effect of somatically mutated leukemogenic transcription factor GATA1. Nat Genet. 2005;37:613–9. [PubMed: 15895080]
  • Lindeboom F, Gillemans N, Karis A, Jaegle M, Meijer D, Grosveld F, Philipsen S. A tissue-specific knockout reveals that Gata1 is not essential for Sertoli cell function in the mouse. Nucleic Acids Research. 2003;31:5405–12. [PMC free article: PMC203309] [PubMed: 12954777]
  • Lowry JA, Mackay JP. GATA-1: one protein, many partners. Int J Biochem Cell Biol. 2006;38:6–11. [PubMed: 16095949]
  • Mehaffey MG, Newton AL, Gandhi MJ, Crossley M, Drachman JG. X-linked thrombocytopenia caused by a novel mutation of GATA-1. Blood. 2001;98:2681–8. [PubMed: 11675338]
  • Muntean AG, Ge Y, Taub JW, Crispino JD. Transcription factor GATA-1 and Down syndrome leukemogenesis. Leuk Lymphoma. 2006;47:986–97. [PubMed: 16840187]
  • Nichols KE, Crispino JD, Poncz M, White JG, Orkin SH, Maris JM, Weiss MJ. Familial dyserythropoietic anaemia and thrombocytopenia due to an inherited mutation in GATA1. Nat Genet. 2000;24:266–70. [PubMed: 10700180]
  • Noris P, Pecci A, Di Bari F, Di Stazio MT, Di Pumpo M, Ceresa IF, Arezzi N, Ambaglio C, Savoia A, Balduini CL. Application of a diagnostic algorithm for inherited thrombocytopenias to 46 consecutive patients. Haematologica. 2004;89:1219–25. [PubMed: 15477207]
  • Nurden AT, Nurden P. The gray platelet syndrome: Clinical spectrum of the disease. Blood Rev. 2007;21:21–36. [PubMed: 16442192]
  • Ohneda K, Yamamoto M. Roles of hematopoietic transcription factors GATA-1 and GATA-2 in the development of red blood cell lineage. Acta Haematol. 2002;108:237–45. [PubMed: 12432220]
  • Parrella S, Aspesi A, Quarello P, Garelli E, Pavesi E, Carando A, Nardi M, Ellis SR, Ramenghi U, Dianzani I. Loss of GATA-1 full length as a cause of Diamond-Blackfan anemia phenotype. Pediatr Blood Cancer. 2014;61:1319–21. [PMC free article: PMC4684094] [PubMed: 24453067]
  • Phillips JD, Steensma DP, Pulsipher MA, Spangrude GJ, Kushner JP. Congenital erythropoietic porphyria due to a mutation in GATA1: the first trans-acting mutation causative for a human porphyria. Blood. 2007;109:2618–21. [PMC free article: PMC1852202] [PubMed: 17148589]
  • Phillips JD, Steensma DP, Spangrude GJ, Kushner JP. Congenital erythropoietic porphyria, beta-thalassemia intermedia and thrombocytopenia due to a GATA1 mutation. Blood. 2005;106:515A.
  • Raskind WH, Niakan KK, Wolff J, Matsushita M, Vaughan T, Stamatoyannopoulos G, Watanabe C, Rios J, Ochs HD. Mapping of a syndrome of X-linked thrombocytopenia with Thalassemia to band Xp11-12: further evidence of genetic heterogeneity of X-linked thrombocytopenia. Blood. 2000;95:2262–8. [PubMed: 10733494]
  • Roberts I, Alford K, Hall G, Juban G, Richmond H, Norton A, Vallance G, Perkins K, Marchi E, McGowan S, Roy A, Cowan G, Anthony M, Gupta A, Ho J, Uthaya S, Curley A, Rasiah SV, Watts T, Nicholl R, Bedford-Russell A, Blumberg R, Thomas A, Gibson B, Halsey C, Lee PW, Godambe S, Sweeney C, Bhatnagar N, Goriely A, Campbell P, Vyas P. GATA1-mutant clones are frequent and often unsuspected in babies with Down syndrome: identification of a population at risk of leukemia. Blood. 2013;122:3908–17. [PMC free article: PMC3995281] [PubMed: 24021668]
  • Roy A, Roberts I, Norton A, Vyas P. Acute megakaryoblastic leukaemia (AMKL) and transient myeloproliferative disorder (TMD) in Down syndrome: a multi-step model of myeloid leukaemogenesis. British Journal of Haematology. 2009;147:3–12. [PubMed: 19594743]
  • Sankaran VG, Ghazvinian R, Do R, Thiru P, Vergilio JA, Beggs AH, Sieff CA, Orkin SH, Nathan DG, Lander ES, Gazda HT. Exome sequencing identifies GATA1 mutations resulting in Diamond-Blackfan anemia. J Clin Invest. 2012;122:2439–43. [PMC free article: PMC3386831] [PubMed: 22706301]
  • Singleton BK, Roxby DJ, Stirling JW, Spring FA, Wilson C, Poole J, Anstee DJ. A novel GATA1 mutation (Stop414Arg) in a family with the rare X-linked blood group Lu(a-b-) phenotype and mild macrothrombocytic thrombocytopenia. Br J Haematol. 2013;161:139–42. [PubMed: 23278136]
  • Solis C, Aizencang GI, Astrin KH, Bishop DF, Desnick RJ. Uroporphyrinogen III synthase erythroid promoter mutations in adjacent GATA1 and CP2 elements cause congenital erythropoietic porphyria. J Clin Invest. 2001;107:753–62. [PMC free article: PMC208941] [PubMed: 11254675]
  • Thompson AR, Wood WG, Stamatoyannopoulos G. X-linked syndrome of platelet dysfunction, thrombocytopenia, and imbalanced globin chain synthesis with hemolysis. Blood. 1977;50:303–16. [PubMed: 871527]
  • Toki T, Kanezaki R, Kobayashi E, Kaneko H, Suzuki M, Wang R, Terui K, Kanegane H, Maeda M, Endo M, Mizuochi T, Adachi S, Hayashi Y, Yamamoto M, Shimizu R, Ito E. Naturally occurring oncogenic GATA1 mutants with internal deletions in transient abnormal myelopoiesis in Down syndrome. Blood. 2013;121:3181–4. [PubMed: 23440243]
  • Tournamille C, Colin Y, Cartron JP, Le Van Kim C. Disruption of a GATA motif in the Duffy gene promoter abolishes erythroid gene expression in Duffy-negative individuals. Nat Genet. 1995;10:224–8. [PubMed: 7663520]
  • Tsang AP, Visvader JE, Turner CA, Fujiwara Y, Yu C, Weiss MJ, Crossley M, Orkin SH. FOG, a multitype zinc finger protein, acts as a cofactor for transcription factor GATA-1 in erythroid and megakaryocytic differentiation. Cell. 1997;90:109–19. [PubMed: 9230307]
  • Tubman VN, Levine JE, Campagna DR, Fleming MD, Neufeld EJ. X-linked gray platelet syndrome due to a GATA1 Arg261Gln mutation. Blood. 2007;109:3297–9. [PubMed: 17209061]
  • Waltzer L, Ferjoux G, Bataille L, Haenlin M. Cooperation between the GATA and RUNX factors Serpent and Lozenge during Drosophila hematopoiesis. EMBO J. 2003;22:6516–25. [PMC free article: PMC291817] [PubMed: 14657024]
  • Wechsler J, Greene M, McDevitt MA, Anastasi J, Karp JE, Le Beau MM, Crispino JD. Acquired mutations in GATA1 in the megakaryoblastic leukemia of Down syndrome. Nat Genet. 2002;32:148–52. [PubMed: 12172547]
  • White JG. Platelet pathology in carriers of the X-linked GATA-1 macrothrombocytopenia. Platelets. 2007;18:620–7. [PubMed: 18041654]
  • White JG, Nichols WL, Steensma DP. Platelet pathology in sex-linked GATA-1 dyserythropoietic macrothrombocytopenia II. Cytochemistry. Platelets. 2007;18:436–50. [PubMed: 17763153]
  • Yu C, Niakan KK, Matsushita M, Stamatoyannopoulos G, Orkin SH, Raskind WH. X-linked thrombocytopenia with thalassemia from a mutation in the amino finger of GATA-1 affecting DNA binding rather than FOG-1 interaction. Blood. 2002;100:2040–5. [PMC free article: PMC2808424] [PubMed: 12200364]
  • Zucker J, Temm C, Czader M, Nalepa G. A Child With Dyserythropoietic Anemia and Megakaryocyte Dysplasia Due to a Novel 5'UTR GATA1s Splice Mutation. Pediatr Blood Cancer. 2016;63:917–21. [PMC free article: PMC5138049] [PubMed: 26713410]

Suggested Reading

  • Balduini CL, De Candia E, Savoia A. Why the disorder induced by GATA1 Arg216Gln mutation should be called "X-linked thrombocytopenia with thalassemia" rather than "X-linked gray platelet syndrome". Blood. 2007;110:2770–1. [PMC free article: PMC1988927] [PubMed: 17881640]
  • Ciovacco WA, Raskind WH, Kacena MA. Human phenotypes associated with GATA-1 mutations. Gene. 2008;427:1–6. [PMC free article: PMC2601579] [PubMed: 18930124]
  • de Waele L, Freson K, Louwette S, Thys C, Wittevrongel C, de Vos R, Debeer A, van Geet C. Severe gastrointestinal bleeding and thrombocytopenia in a child with an anti-GATA1 autoantibody. Pediatr Res. 2010;67:314–9. [PubMed: 19924028]
  • Hamlett I, Draper J, Strouboulis J, Iborra F, Porcher C, Vyas P. Characterization of megakaryocyte GATA1-interacting proteins: the corepressor ETO2 and GATA1 interact to regulate terminal megakaryocyte maturation. Blood. 2008;112:2738–49. [PMC free article: PMC2556610] [PubMed: 18625887]
  • Millikan PD, Balamohan SM, Raskind WH, Kacena MA. Inherited thrombocytopenia due to GATA1 mutations. Semin Thromb Hemost. 2011;37:682–9. [PubMed: 22102271]

Chapter Notes

Author History

Stella T Chou, MD (2006-present)
Melissa A Kacena, PhD (2006-present)
Jessica Kirk, BS; Yale University School of Medicine (2006-2011)
Wendy H Raskind, MD, PhD (2006-present)
Mitchell J Weiss, MD, PhD (2006-present)

Acknowledgments

This work was supported in part by NIH grants NCRR RR025760 and RR025761 (MAK), NIH K08 HL093290 and R01 DK100854 (STC), NIH P30 DK090969 (MJW, STC), P30 DK0724429 (MAK), NIAMS R03 AR055269 (MAK), NIAMS R01 AR060332 (MAK), NIA R01 AG046246 (MAK) and by the American Society of Hematology Scholar Award (STC).

Revision History

  • 11 May 2017 (ha) Comprehensive update posted live
  • 17 April 2014 (me) Comprehensive update posted live
  • 22 March 2011 (me) Comprehensive update posted live
  • 30 March 2007 (cd) Revision: prenatal testing clinically available
  • 21 February 2007 (cd) Revision: clinical testing available
  • 22 November 2006 (me) Review posted to live Web site
  • 10 August 2006 (whr) Original submission
Copyright © 1993-2017, University of Washington, Seattle. GeneReviews is a registered trademark of the University of Washington, Seattle. All rights reserved.

GeneReviews® chapters are owned by the University of Washington. Permission is hereby granted to reproduce, distribute, and translate copies of content materials for noncommercial research purposes only, provided that (i) credit for source (http://www.genereviews.org/) and copyright (© 1993-2017 University of Washington) are included with each copy; (ii) a link to the original material is provided whenever the material is published elsewhere on the Web; and (iii) reproducers, distributors, and/or translators comply with the GeneReviews® Copyright Notice and Usage Disclaimer. No further modifications are allowed. For clarity, excerpts of GeneReviews chapters for use in lab reports and clinic notes are a permitted use.

For more information, see the GeneReviews® Copyright Notice and Usage Disclaimer.

For questions regarding permissions or whether a specified use is allowed, contact: ude.wu@tssamda.

Bookshelf ID: NBK1364PMID: 20301538

Views

  • PubReader
  • Print View
  • Cite this Page
  • Disable Glossary Links

Related information

  • MedGen
    Related information in MedGen
  • OMIM
    Related OMIM records
  • PMC
    PubMed Central citations
  • PubMed
    Links to PubMed
  • Gene
    Locus Links

Similar articles in PubMed

  • Review Diamond-Blackfan Anemia[GeneReviews®. 1993]
    Review Diamond-Blackfan Anemia
    Clinton C, Gazda HT. GeneReviews®. 1993
  • Review Congenital Erythropoietic Porphyria[GeneReviews®. 1993]
    Review Congenital Erythropoietic Porphyria
    Erwin A, Balwani M, Desnick RJ, Porphyrias Consortium of the NIH-Sponsored Rare Diseases Clinical Research Network. GeneReviews®. 1993
  • Review WAS-Related Disorders[GeneReviews®. 1993]
    Review WAS-Related Disorders
    Chandra S, Bronicki L, Nagaraj CB, Zhang K. GeneReviews®. 1993
  • Review Fanconi Anemia[GeneReviews®. 1993]
    Review Fanconi Anemia
    Mehta PA, Tolar J. GeneReviews®. 1993
  • Review Hemophilia B[GeneReviews®. 1993]
    Review Hemophilia B
    Konkle BA, Huston H, Nakaya Fletcher S. GeneReviews®. 1993
See reviews...See all...

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...