Wiskott–Aldrich syndrome

Wiskott–Aldrich syndrome (WAS) is a rare X-linked recessive disease characterized by eczema, thrombocytopenia (low platelet count), immune deficiency, and bloody diarrhea (secondary to the thrombocytopenia). It is also sometimes called the eczema-thrombocytopenia-immunodeficiency syndrome in keeping with Aldrich's original description in 1954. The WAS-related disorders of X-linked thrombocytopenia (XLT) and X-linked congenital neutropenia (XLN) may present with similar but less severe symptoms and are caused by mutations of the same gene.

Signs and symptoms
WAS occurs most often in males due to its X-linked recessive pattern of inheritance, affecting between 1 and 10 males per million. The first signs are usually petechiae and bruising, resulting from a low platelet count (i.e. thrombocytopenia). Spontaneous nose bleeds and bloody diarrhea are also common and eczema typically develops within the first month of life. Recurrent bacterial infections typically develop by three months of age. The majority of children with WAS develop at least one autoimmune disorder, and cancers (mainly lymphoma and leukemia) develop in up to a third of patients. Immunoglobulin M (IgM) levels are reduced, IgA and IgE are elevated, and IgG levels can be normal, reduced, or elevated. In addition to thrombocytopenia, WAS patients have abnormally small platelets (i.e. microthrombocytes) and ~30% also have elevated eosinophil counts (i.e. eosinophilia).

Pathophysiology
The microthrombocytes seen in WAS patients have only been observed in one other condition, ARPC1B deficiency. In both conditions the defective platelets are thought to be removed from circulation by the spleen and/or liver, leading to low platelet counts. WAS patients have increased susceptibility to infections, particularly of the ears and sinuses, and this immune deficiency has been linked to decreased antibody production and the inability of immune T cells to effectively combat infection.

Genetics
WAS is associated with mutations in a gene on the short arm of the X chromosome (Xp11.23) that was originally termed the Wiskott–Aldrich syndrome protein gene and is officially known as WAS (Gene ID: 7454). X-linked thrombocytopenia (XLT) is also linked to pathogenic variants in the WAS gene, although some variants tend to be more strongly associated with XLT versus others that are more associated with WAS. The rare disorder X-linked neutropenia has also been linked to a specific subset of WAS mutations.

The protein product of WAS is known as WASp. It contains 502 amino acids and is mainly expressed in hematopoietic cells (the cells in the bone marrow that develop into blood cells). The main function of WASp is to activate actin polymerization by serving as a nucleation-promoting factor (NPF) for the Arp2/3 complex, which generates branched actin filaments. Several proteins can serve as NPFs, and it has been observed that in WAS platelets the Arp2/3 complex functions normally, indicating that WASp is not required for its activation in platelets. In T-cells, WASp is important because it is known to be activated via T-cell receptor signaling pathways to induce cortical actin cytoskeleton rearrangements that are responsible for forming the immunological synapse.

The severity of the symptoms produced by pathogenic variants in the WAS gene generally correlates with their effects on WASp. Missense variants generally are associated with less severe disease than truncating variants that produce no protein due to nonsense-mediated decay. However, this correlation is not perfect, and sometimes the same variant can be seen both in XLT and in WAS (sometimes within two different members of the same family), a concept in genetics referred to as variable expressivity. Although autoimmune disease and malignancy may occur in both conditions, patients with loss of WASp are at higher risk. A defect in the CD43 molecule has also been found in WAS patients. CD43, a transmembrane sialoglycoprotein also known as a leukosialin, is part of a greater complex involved in T-cell activation and acts as a sensitive indicator of abnormal, malignant B cell populations. Defects in this molecule may be detrimental to WAS patients, who are at a much higher risk of autoimmune diseases that may be exacerbated in later-detected B-cell lymphomas.

Diagnosis
The diagnosis can be made on the basis of clinical findings, the peripheral blood smear, and low immunoglobulin levels. Typically, IgM levels are low, IgA levels are elevated, and IgE levels may be elevated; paraproteins are occasionally observed. Skin immunologic testing (allergy testing) may reveal hyposensitivity. Individuals with Wiskott–Aldrich syndrome however are at higher risk for severe food allergies. Not all patients have a positive family history of the disorder; new mutations do occur. Often, leukemia may be suspected on the basis of low platelets and infections, and bone marrow biopsy may be performed. Decreased levels of WASp are typically observed. The current gold standard for diagnosis is DNA sequence analysis, which can detect WAS and the related disorders XLT and XLN in 95% of patients and carriers.

Classification
Jin et al. (2004) employ a numerical grading of severity: This score, which ranges from 0 to 5, may have clinical utility for predicting disease severity. Those with higher WAS scores (e.g., 5) at younger ages (e.g., age less than 5 years old), are thought to be at highest risk for increased morbidity and mortality related to their condition. As individuals can develop more WAS-related symptoms (e.g. autoimmune disease, malignancy) with age, one's WAS score can increase over time. A lower WAS score may be more compatible with conservative management versus higher WAS scores that may favor intervention with treatments such as hematopoietic stem cell transplant.

Treatment
Hematopoietic stem cell transplant

Treatment of Wiskott–Aldrich syndrome depends on the severity of the disease. WAS is primarily a disorder of the blood-forming tissues, so in cases of severe disease (WAS score 3–5) the only widely available curative treatment currently available is a hematopoietic stem cell transplant (HCT). In this procedure stem cells are harvested from umbilical cord blood, bone marrow, or peripheral blood following treatment with medications that cause stem cells to leave the bone marrow and circulate systemically. The best outcomes are with HLA-identical or similar donors (often siblings). In cases of milder disease the potential benefits of HCT (>90% probability of cure if transplant occurs before age two) must be considered in the context of non-trivial risks presented by the procedure itself and the potential need for lifelong immunosuppression to prevent graft-versus-host disease. Generally outcomes are better if HCT occurs prior to the development of autoimmune disease or malignancy, however there are risks associated with chemotherapy (needed to make room for the new stem cells) especially in young infants (risk of a second cancer, or infertility).

Bleeding complications

Otherwise WAS treatment is focused on managing symptoms and preventing complications. The greatest mortality risk in WAS before age 30 is from bleeding so aspirin and other nonsteroidal anti-inflammatory drugs that may interfere with already compromised platelet function should generally be avoided. Circumcision, as well as elective surgeries, should generally be deferred in males with thrombocytopenia until after HCT if possible. Protective helmets can help protect children from life-threatening intracranial hemorrhage (brain bleed) which could result from head injuries. Patients may require platelet transfusions when there is extreme bloodloss (such as during surgery) or for very low platelets splenectomy (removal of the spleen) may also be lifesaving. However, splenectomy is generally considered palliative and is not universally recommended in WAS because it can increase the risk of life-threatening infections. Post-splenectomy patients will require lifelong antibiotic prophyllaxis to prevent infections. Study of eltrombopag, a thrombopoietic agent used to increase platelets in immune thrombocytopenic purpura (ITP), in WAS concluded that although it increased platelet numbers it failed to increase platelet activation in most patients. It has since been proposed the eltrombopag may be used to bridge to HCT in patients with severe thrombocytopenia to normalize platelet numbers without transfusions and decrease bleeding events. Anemia from bleeding may require iron supplementation or blood transfusion. Regular surveillance of blood counts is recommended.

Infections and autoimmune disease

For patients with frequent infections, intravenous immunoglobulins (IVIG) or subcutaneous immunoglobulins can be regularly scheduled to boost the immune system. Adequacy of IVIG replacement can be assessed via periodic lab draws. WAS patients with immune system compromise may benefit from antibiotic prophylaxis, for example by taking trimethoprim-sulfamethoxazole to prevent Pneumocystis jirovecii-related pneumonia. Similarly, prophylactic antibiotic use may also be considered in patients with recurrent bacterial sinus or lung infections. When there are signs or symptoms of an infection, prompt and thorough evaluation is important including blood cultures to guide therapy (often IV antibiotics). Live vaccines (such as MMR or rotavirus) should be avoided during routine childhood vaccination. Inactivated vaccines may be given safely but may not provide protective levels of immunity. Eczema is generally treated with topical steroids, and if chronic skin infections exacerbate eczema an antibiotic may also be given. Autoimmune disease is managed with judicious use of appropriate immunosuppressants.

Gene therapy

For severely affected males without an HLA-matched donor, studies of correcting Wiskott–Aldrich syndrome with gene therapy using a lentivirus are underway. Proof-of-principle for successful hematopoietic stem cell gene therapy has been provided for patients with Wiskott–Aldrich syndrome. In July 2013 the Italian San Raffaele Telethon Institute for Gene Therapy (HSR-TIGET) reported that three children with Wiskott–Aldrich syndrome showed significant improvement (improved platelet counts, immune functiona, and clinical symptoms) 20–30 months after being treated with a genetically modified lentivirus. In April 2015 results from a follow-up British and French trial six out of seven individuals showed improvement of immune function and clinical symptoms an average of 27 months after treatment with gene therapy. Importantly, neither study showed evidence of leukemic proliferation following treatment, a complication of early attempts at gene therapy using a retroviral vector. It is unknown why these gene therapies did not restore normal platelet numbers, but gene therapy treatment was still associated with transfusion-independence and a significant reduction in bleeding events. A version of this treatment, OTL-103, is being developed by Orchard Therapeutics and is undergoing Phase I/II clinical trials.

Prognosis
Outcomes from Wiskott–Aldrich syndrome are variable and depend on how severely an individual is affected (the WAS score may be used to assess disease severity). The milder end of the disease spectrum associated with the WAS gene is referred to as X-linked neutropenia or X-linked thrombocytopenia, and the latter is thought to have a normal life expectancy with reports of minimally affected males surviving into their seventh decade without treatment. Traditionally however Wiskott–Aldrich syndrome has been associated with premature death from causes including bleeding, infections, or malignancy. Wiskott–Aldrich syndrome is a condition with variable expressivity, meaning that even within the same family some may exhibit only chronic thrombocytopenia while others experience severe, life-threatening complications of Wiskott–Aldrich syndrome in infancy or childhood. Given symptoms often progress with age, it is challenging to predict how affected a newly diagnosed infant will eventually be. There is some genotype-phenotype correlation, with most individuals with X-linked thrombocytopenia having missense variants in the WAS gene versus 86.5% of those that make no WAS protein having the classic Wiskott–Aldrich syndrome phenotype. Overall the prognosis for individuals with Wiskott–Aldrich syndrome has improved considerably over the past decades due to earlier diagnoses and more access to treatments.

Epidemiology
The estimated incidence of Wiskott–Aldrich syndrome in the United States is one in 250,000 live male births. While still a rare disease, this makes it more common than many genetic immunodeficiency syndromes such as hyper-IgM syndrome or SCID, which have an estimated incidence of about one in 1,000,000 live births, and Wiskott–Aldrich syndrome is thought to account for 1.2% of all inherited immunodeficiencies in the United States. WAS occurs worldwide and is not known to be more common in any particular ethnic group.

History
The syndrome is named after Dr. Alfred Wiskott (1898–1978), a German pediatrician who first noticed the syndrome in 1937, and Dr. Robert Anderson Aldrich (1917–1998), an American pediatrician who described the disease in a family of Dutch-Americans in 1954. Wiskott described three brothers with a similar disease, whose sisters were unaffected. In 2006, a German research group analyzed family members of Wiskott's three cases, and surmised they probably shared a novel frameshift mutation of the first exon of the WASp gene.