Arkwright et al1 are to be complimented for their review on autoimmunity in human primary immunodeficiency diseases. While they emphasized the role of opportunistic infections, which are common in primary immunodeficiency (PID) states in the development of autoimmune disorders, we would like to draw attention to a completely different pathogenic pathway. Indeed, the apparent paradox of immunodeficiency and autoimmunity coexisting in the same patient is not a real one. Recently, Candotti et al2 pointed out that many components of the immune system have complex functions, which often play both positive and negative roles.

In order to illustrate this point, we would like to report on 2 cases of severe combined immunodeficiency (SCID) with autoimmune diseases. SCID was not mentioned in Arkwright et al's review as a predisposing condition to autoimmunity. Furthermore, at this young age, opportunistic infections do not seem to be related to the autoimmune phenomena. In both cases, stem cell transplantation corrected both the immunodeficiency and the autoimmune conditions.

The first patient is a 2-month-old boy whose condition was diagnosed as Omenn syndrome. Genetic analysis revealed a 1886C>T mutation in RAG1. At diagnosis he had extended erythrodermia with scaling on his entire body. He also had no hair on his scale or body as is described in Omenn syndrome. Immunophenotyping from peripheral blood showed CD3 93%, CD20 2%, CD4 28%, and CD8 68%. Proliferation studies revealed marked decreased response to various mitogens. Immunoglobulin levels were very low for IgA, IgG, and IgM, whereas the IgE level was increased to 74 IU. Skin biopsy was compatible with Omenn syndrome. No melanocytes were seen at that time. The patient, aged 2 months, received haploidentical peripheral stem cell transplants from his father. This was done using T-cell depletion by positive selection of CD34 cells by immunomagnetic beads. Conditioning included busulphan 16 mg/kg, cyclophosphamide 200 mg/kg, fludarabine 200 mg/m,2 and anti-thymocyte globulin (ATG) (fresenius) 25 mg/kg. No graft-versus-host disease prophylaxis was given after transplantation. After rejecting the graft, he received his second haploidentical transplants with T-cell depletion from his mother. Conditioning included anti-CD3 (OKT3) and thiotepa 7 mg/kg. Engraftment occurred on day +9 with complete donor chimerism. Gradually, the erythrodermia subsided and he was noted to have fair skin with white hair and white eyelashes—a picture that resembled vitiligo. No other signs of graft-versus-host disease (GVHD) were seen, and there were no gut or liver manifestations. Skin biopsy was compatible with vitiligo with melanocytes and no evidence of GVHD. Later, focal hyperpigmentation on exposed portions of his body (face, hands, and legs) started to appear with coalescence of those focal pigmentations into complete repigmentation thereafter. Also, focal pigmentation appeared on the scale, with brown hair arising from those spots later. A biopsy done from areas of pigmentation and depigmentation showed melanocytes on pigmented areas and a lack of them on the depigmented areas. Neonatal autoimmune disorder not related to maternal disease is very rare.3 Because vitiligo is an immunologic phenomena caused by activated T cells,4 we hypothesized that a T-cell–mediated autoimmune process caused the disappearance of melanocytes and vitiligo. This was corrected by stem cell transplantation, causing elimination of the autoreactive T cells that are common in Omenn syndrome.5 Now, 18 months after transplantation, he has brown hands and his lower legs and face are spotted with brown hair, whereas the rest of his body is only spotted by pigmentation.

The second patient was diagnosed at the age of 11 months as suffering from SCID with no T cells but with B and natural killer (NK) cells (T-B+NK+) resulting from IL-7 receptor alpha deficiency. The mutation found was a g-to-a base substitution causing a splice-site mutation at position −1 of intron 2 leading to complete skipping of exon 3. At diagnosis she had fever and diarrhea caused most probably by viral disease. Later, she developed severe thrombocytopenia (5000/mm3) with wet purpura. Bone marrow aspiration revealed increased number of megakaryocytes compatible with the diagnosis of idiopathic thrombocytopenia purpura (ITP) with no response to intravenous immunoglobulin (IVIG) and pulse steroids. Allogeneic bone marrow transplantation from a matched-sibling donor without conditioning or GVHD prophylaxis was performed. Two weeks after transplantation there was a gradual increase in thrombocyte numbers until full recovery. We concluded that this patient's ITP was corrected by allogeneic bone marrow transplantation.

In summary, we reported on 2 infants with SCID and autoimmune disorders. Both conditions were corrected by stem cell transplantation. As is stated in Candotti et al's paper, immunodeficiency and autoimmunity are not opposites. Indeed, mixed pictures could happen. Either way, stem cell transplantation is probably the correct solution for both problems.

Schuster et al's letter questioning our definition of autoimmunity focuses in on the fundamental impetus for our review.1-1 They are correct when they quote that autoimmune disease is conventionally defined as a clinical syndrome caused by the activation of T cells or B cells, or both, in the absence of an ongoing infection or other discernible cause.1-2However, in patients with autoimmunity associated with defined primary immunodeficiency diseases (PIDs), advances in our understanding of the disease pathogenesis means that this definition has been superseded. Autoimmunity occurring in PIDs, although associated with immune self-destruction, is not usually triggered by immune intolerance to self-antigens. Autoimmune responses to self-antigens may contribute to ongoing inflammation, but the primary trigger is generally the inability of an inherently defective immune system to eradicate persisting foreign microbial antigens. The basic principles underlying the wide-spread tissue destruction in hemophagocytic lymphohistiocytosis (HLH) syndromes, where defined underlying defects in the immune system allows intercurrent Epstein-Barr virus (EBV) infection or other factors to trigger uncontrolled lymphocyte-initiated macrophage activation, are no different to those seen in other autoimmune conditions associated with PID.1-3 At the moment, we lack the knowledge to explain the underlying immune mechanism(s) in many autoimmune disorders,1-4 but there is no doubt that better understanding of the basis of autoimmunity in PID will provide a framework for rethinking fundamental concepts as well as treatment strategies for these conditions.1-5 1-6 

In their letter, Elhasid et al rightly point out that autoimmune phenomena may develop in some cases of severe combined immunodeficiency (SCID). As detailed in our review,1-1 autoimmune phenomena are well recognized in Omenn syndrome. Certain mutations in theRAG gene result in incomplete blockage of T-lymphocyte development. Dysfunctional T-cell clones may cause inflammation in any tissue of the body, but especially in the skin, liver, bone marrow, and brain.1-7 Other formes frustes of SCID with aberrant T-lymphocyte development, often presenting in older children or adults as common variable immunodeficiency, may also be associated with clinically significant autoimmunity.1-1,1-3 1-8 In contrast, in children with classical SCID in whom no T lymphocytes are present, clinical features suggestive of autoimmunity are more likely to be due to the direct consequences of infections, as the complete lack of T lymphocytes prevents the development of an autoimmune response. Elhasid et al's second patient with TB+NK+ SCID developed a consumptive thrombocytopenia that did not respond to steroids or high-dose intravenous immunoglobulin (IVIG) therapy, but the patient did finally respond to matched-sibling bone marrow transplantation. Considering the temporal relationship to the other symptoms of viral infection, it is likely that rather than the thrombocytopenia being ITP, it was directly caused by the virus infection. As emphasized in our review, immunomodulation and treatment of infection is often a better treatment strategy than immunosuppression alone in children with primary immunodeficiency and suspected autoimmune phenomena, as immunosuppression may exacerbate the underlying infectious disease and result in increased morbidity and mortality.

Finally, as stated in our review and reiterated by Elhasid et al, in children with an underlying PID, autoimmunity and the inability to effectively eradicate infection should both be viewed as features of dysregulated immunity. Correcting the underlying immunodeficiency by stem cell transplantation often corrects both clinical problems. Although stem cell transplantation had in the past been considered, but not often used, as a possible treatment option for autoimmunity where no underlying primary immunodeficiency can be found, advances in the safety and effectiveness of this therapy have recently lead to a revival in interest in this treatment modality.1-9 

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