Dual loss of p110δ PI3-kinase and SKAP (KNSTRN) expression leads to combined immunodeficiency and multisystem syndromic features.

BACKGROUND: We previously reported a novel syndrome characterized by combined immunodeficiency associated with severe developmental defects-subsequently known as Roifman-Chitayat syndrome (RCS; OMIM 613328). Linkage analysis identified 2 disease-associated loci. OBJECTIVES: We sought to identify the genetic defect in these patients and characterize their immunologic cellular abnormalities. METHODS: Genetic, immunologic, protein, and cellular functional analyses were used to identify and characterize patient genetic deficiencies and aberrant patient cell behavior. RESULTS: Deleterious variants were found at both loci identified by linkage analysis: a homozygous stop codon in PI3-kinase p110δ (PIK3CD) and a homozygous frame shift mutation in SKAP (KNSTRN), both ablating protein expression. Patients with RCS display aberrant B-cell development, similar to p110δ-deficient mice, but also aberrant T-cell spreading, cell-cell interaction, and migration. Patients also display significant developmental abnormalities not seen in p110δ knockouts (eg, optic nerve atrophy and skeletal anomalies) that we ascribe to loss of SKAP. Aberrant SKAP expression can prolong anaphase and this may contribute to developmental defects. However, we also identified microtubule-associated protein 4 microtubule-binding protein as a novel SKAP-binding partner and show that it undergoes relocalization in patient T cells, with associated areas of aberrant microtubule hyperstabilization, likely contributing not only to the altered properties of RCS lymphoid cells but also to developmental defects. CONCLUSIONS: The complex RCS presentation, with combined developmental and immunologic defects, is associated with a combined deficiency of 2 genes products, PI3-kinase p110δ and SKAP, both of which appear to play a significant role in the disease.

The effects of RelB deficiency on lymphocyte development and function.

Multiple receptors that control cell growth and inflammation activate the NFκB pathway that comprises of two pathways. Dysfunction of the classical pathway leads to impaired adaptive and innate immunity in humans. In contrast the exact role of the alternative NFκB pathway mediated by RelB in humans remains largely elusive. We have recently identified deleterious mutations in RelB in patients with combined immunodeficiency and autoimmunity. We studied here the biological effects of RelB deficiency on the immune system. We show that the thymus in this patient is dysplastic and consequently new thymus emigrants are rare and there is an accumulation of CD45 RO(+) T cells with an increase in CD62L(+) central memory cells. The TCR repertoire of these cells appears skewed with selective clonal expansion. In vitro responses to T cell mitogens were markedly depressed and so were PHA induced IL2 and IFNγ production. In addition, the TH1 promoting T bet and STAT1 were reduced. In contrast, hyper-activation was seen in response to anti-CD3 and CD28. T cell dependent antibody responses were low to absent in all patients. We found that BAFF-R was reduced and CD40 signaling aberrant. Critically, CD27(+) memory cells were absent. We have shown here for the first time the role of RelB on lymphocyte development in humans. In the absence of RelB, B cells development is arrested, resulting in poor production of immunoglobulins and specific antibodies. T cell maturation in the thymus appears altered with reduced output and production of a skewed T cell repertoire with expansion of clones which are likely the cause of the autoimmune features observed in these patients.