The IL-2RG R328X nonsense mutation allows partial STAT-5 phosphorylation and defines a critical region involved in the leaky-SCID phenotype.

In addition to their detection in typical X-linked severe combined immunodeficiency, hypomorphic mutations in the interleukin (IL)-2 receptor common gamma chain gene (IL2RG) have been described in patients with atypical clinical and immunological phenotypes. In this leaky clinical phenotype the diagnosis is often delayed, limiting prompt therapy in these patients. Here, we report the biochemical and functional characterization of a nonsense mutation in exon 8 (p.R328X) of IL2RG in two siblings: a 4-year-old boy with lethal Epstein-Barr virus-related lymphoma and his asymptomatic 8-month-old brother with a Tlow B+ natural killer (NK)+ immunophenotype, dysgammaglobulinemia, abnormal lymphocyte proliferation and reduced levels of T cell receptor excision circles. After confirming normal IL-2RG expression (CD132) on T lymphocytes, signal transducer and activator of transcription-1 (STAT-5) phosphorylation was examined to evaluate the functionality of the common gamma chain (γc ), which showed partially preserved function. Co-immunoprecipitation experiments were performed to assess the interaction capacity of the R328X mutant with Janus kinase (JAK)3, concluding that R328X impairs JAK3 binding to γc . Here, we describe how the R328X mutation in IL-2RG may allow partial phosphorylation of STAT-5 through a JAK3-independent pathway. We identified a region of three amino acids in the γc intracellular domain that may be critical for receptor stabilization and allow this alternative signaling. Identification of the functional consequences of pathogenic IL2RG variants at the cellular level is important to enable clearer understanding of partial defects leading to leaky phenotypes.

Complement factor 5 (C5) p.A252T mutation is prevalent in, but not restricted to, sub-Saharan Africa: implications for the susceptibility to meningococcal disease.

Complement C5 deficiency (C5D) is a rare primary immunodeficiency associated with recurrent infections, particularly meningitis, by Neisseria species. To date, studies to elucidate the molecular basis of hereditary C5D have included fewer than 40 families, and most C5 mutations (13 of 17) have been found in single families. However, the recently described C5 p.A252T mutation is reported to be associated with approximately 7% of meningococcal disease cases in South Africa. This finding raises the question of whether the mutation may be prevalent in other parts of Africa or other continental regions. The aim of this study was to investigate the prevalence of C5 p.A252T in Africa and other regions and discuss the implications for prophylaxis against meningococcal disease. In total, 2710 samples from healthy donors within various populations worldwide were analysed by quantitative polymerase chain reaction (qPCR) assay to detect the C5 p.A252T mutation. Eleven samples were found to be heterozygous for p.A252T, and nine of these samples were from sub-Saharan African populations (allele frequency 0·94%). Interestingly, two other heterozygous samples were from individuals in populations outside Africa (Israel and Pakistan). These findings, together with data from genomic variation databases, indicate a 0·5-2% prevalence of the C5 p.A252T mutation in heterozygosity in sub-Saharan Africa. Therefore, this mutation may have a relevant role in meningococcal disease susceptibility in this geographical area.

Genetics of Graves' Disease: Special Focus on the Role of TSHR Gene.

As most autoimmune diseases, inherited predisposition to Graves' disease (GD) is polygenic with the main contributory genes being located in the HLA region. Also, as in other autoimmune diseases, family linkage, candidate gene association, and GWAS studies have identified an expanding number of predisposing genes (CTLA4, CD40, PTPN22...) and 2 of them, TG and TSHR, are thyroid specific. In spite of this expanding number of associated genes, it has been estimated that all together they account for only a 20% of the heritability of GD. TSHR is of special interest as it codes for the target of TSHR stimulating antibodies (TSAbs), which are unequivocally pathogenic and an exception in autoimmunity by being stimulating rather than neutral, blocking, or cytotoxic. This is surprising because the generation of stimulating TSHR antibodies by immunisation of laboratory animals has been remarkably difficult, suggesting an underlying mechanism that favours stimulating over neutral or blocking anti-TSHR antibodies must be operating in GD patients. Besides, after HLA, TSHR is the gene most tightly associated to GD. The TSHR polymorphisms conferring susceptibility are located in the unusually large intron 1. Two mechanisms have been already put forward to explain its association with GD. According to one, the risk alleles determine an increase in the expression of TSHR mRNA splice variants that code for a soluble form of the receptor. The wider distribution of soluble TSHR would favour its immunogenicity and the development of an autoimmune response to it. It does not explain why it becomes immunogenic, as immunogenicity and distribution are not necessarily connected, nor why the immune response focus to the production of stimulating antibodies. According to the second mechanism proposed, the risk alleles determine a lower TSHR expression in the thymus and this would favour the escape of more TSHR reactive T cells, that is, central tolerance failure. The unexpected finding that thymocytes express TSHR and that TSAbs stimulate them lead to postulate that this would accelerate their egress from the thymus and a less efficient deletion of the TSHR self-reactive T cells. It can be envisaged that these autoreactive T cells may enhance the production of TSHR-Abs in the germinal centres of the thyroid draining lymph nodes, especially of those capable of further stimulating the egress of autoreactive T cells from the thymus. This mechanism, which does not exclude the former, provides and insight of the way in which TSAbs are favoured over neutral or blocking antibodies. Finally this would explain the frequent finding of thymic hyperplasia in GD patients.

Novel and atypical splicing mutation in a compound heterozygous UNC13D defect presenting in Familial Hemophagocytic Lymphohistiocytosis triggered by EBV infection.

Familial Hemophagocytic Lymphohistiocytosis type 3 (FHL3) is a genetic disorder caused by mutations in UNC13D gene, coding the granule priming factor Munc13-4 that intervenes in NK and T cell cytotoxic function. Here we report the case of a 17-month-old girl with prolonged symptomatic EBV infectious mononucleosis and clinical symptoms of hemophagocytic syndrome. In vitro functional analysis pointed to a degranulation defect. The genetic analysis of UNC13D gene identified initially a heterozygous mutation (c.753+1G>T) in the donor splice-site that resulted in exon 9 skipping (maternal allele). Mutations in other genes were considered, but additional analysis of UNC13D cDNA revealed in the paternal allele a heterozygous transition from G to A (c.2448-13G>A) at the 3' acceptor splice-site in intron 25, generating a new acceptor splice-site that leads to a frameshift and a premature STOP codon. Allele specific amplification of the cDNA confirmed the absence of a functional mRNA from the paternal allele. This case illustrates an atypical compound heterozygous UNC13D mutation affecting the RNA splicing that generates a typical FHL3 phenotype.

Copy number variation in chemokine superfamily: the complex scene of CCL3L-CCL4L genes in health and disease.

Genome copy number changes (copy number variations: CNVs) include inherited, de novo and somatically acquired deviations from a diploid state within a particular chromosomal segment. CNVs are frequent in higher eukaryotes and associated with a substantial portion of inherited and acquired risk for various human diseases. CNVs are distributed widely in the genomes of apparently healthy individuals and thus constitute significant amounts of population-based genomic variation. Human CNV loci are enriched for immune genes and one of the most striking examples of CNV in humans involves a genomic region containing the chemokine genes CCL3L and CCL4L. The CCL3L-CCL4L copy number variable region (CNVR) shows extensive architectural complexity, with smaller CNVs within the larger ones and with interindividual variation in breakpoints. Furthermore, the individual genes embedded in this CNVR account for an additional level of genetic and mRNA complexity: CCL4L1 and CCL4L2 have identical exonic sequences but produce a different pattern of mRNAs. CCL3L2 was considered previously as a CCL3L1 pseudogene, but is actually transcribed. Since 2005, CCL3L-CCL4L CNV has been associated extensively with various human immunodeficiency virus-related outcomes, but some recent studies called these associations into question. This controversy may be due in part to the differences in alternative methods for quantifying gene copy number and differentiating the individual genes. This review summarizes and discusses the current knowledge about CCL3L-CCL4L CNV and points out that elucidating their complete phenotypic impact requires dissecting the combinatorial genomic complexity posed by various proportions of distinct CCL3L and CCL4L genes among individuals.

Copy number variation in the CCL4L gene is associated with susceptibility to acute rejection in lung transplantation.

Lung transplantation (LT) has become an accepted therapy for selected patients with advanced lung disease. One of the main limitations to successful LT is rejection of the transplanted organ where chemokines are pivotal mediators. Here, we test the relationship between copy number variation (CNV) in the CCL4L chemokine gene and rejection risk in LT patients (n=161). Patients with no acute rejection showed a significantly lower mean number of CCL4L copies than patients that showed acute rejection (1.66 vs 1.96, P=0.014), with an even greater number of gene copies seen in patients with more than one episode of acute rejection (1.66 vs 2.30, P=0.001). Additionally, patients with > or =2 CCL4L copies had a significantly higher risk of acute rejection compared with patients that had 0-1 CCL4L copies (odds ratio 2.65; 95% confidence interval, 1.33-5.28; P=0.0046). A combined analysis of CCL4L CNV and the rs4796195 CCL4L single nucleotide polymorphism demonstrated that the effect of CCL4L copy number in acute rejection is mainly because of the number of copies of the CCL4L1 allelic variant. This finding constitutes the first report of CNV as a correlate factor in allograft rejection.

Population structure in copy number variation and SNPs in the CCL4L chemokine gene.

The recent description of a large amount of copy number variation (CNV) in the human genome has extended the concept of genome diversity. In this study we integrate the analysis of CNV and single nucleotide polymorphisms (SNPs) in the human CCL4L chemokine gene. CCL4L is a nonallelic copy of CCL4/MIP-1beta chemokine and displays a CNV that also includes the CCL3L gene, a nonallelic copy of CCL3/MIP-1alpha. This CNV and two functionally relevant CCL4L SNPs (rs4796195 and rs3744595) have been recently associated to HIV pathology in three independent studies. We have quantified the CCL4L copy number and genotyped both SNPs in samples from HGDP-CEPH Diversity Panel. A strong correlation between CCL4L CNV and one of the SNPs analyzed is found, whereas no significant linkage disequilibrium is found between the two SNPs despite their close distance (647 bp), suggesting a recent appearance of the second SNP when the diversity in the first one and CNV had already been generated. The present study points out that in genes with CNV, it may be a key issue to combine the assessment of gene copy number with the genotyping of relevant SNPs to understand the phenotypic impact of genome variation in the immune response.

The chemokine network. II. On how polymorphisms and alternative splicing increase the number of molecular species and configure intricate patterns of disease susceptibility.

In this second review on chemokines, we focus on the polymorphisms and alternative splicings and on their consequences in disease. Because chemokines are key mediators in the pathogenesis of inflammatory, autoimmune, vascular and neoplastic disorders, a large number of studies attempting to relate particular polymorphisms of chemokines to given diseases have already been conducted, sometimes with contradictory results. Reviewing the published data, it becomes evident that some chemokine genes that are polymorphic have alleles that are found repeatedly, associated with disease of different aetiologies but sharing some aspects of pathogenesis. Among CXC chemokines, single nucleotide polymorphisms (SNPs) in the CXCL8 and CXCL12 genes stand out, as they have alleles associated with many diseases such as asthma and human immunodeficiency virus (HIV), respectively. Of CC chemokines, the stronger associations occur among alleles from SNPs in CCL2 and CCL5 genes and a number of inflammatory conditions. To understand how chemokines contribute to disease it is also necessary to take into account all the isoforms resulting from differential splicing. The first part of this review deals with polymorphisms and the second with the diversity of molecular species derived from each chemokine gene due to alternative splicing phenomena. The number of molecular species and the level of expression of each of them for every chemokine and for each functionally related group of chemokines reaches a complexity that requires new modelling algorithms akin to those proposed in systems biology approaches.

The chemokine network. I. How the genomic organization of chemokines contains clues for deciphering their functional complexity.

Chemokines are a superfamily of small structurally related cytokines that have evolved to form a complex network of proteins that typically regulate leucocyte traffic but also carry very diverse sets of immune and non-immune functions. Two general features of cytokines, redundancy and promiscuity, are particularly prominent in chemokines. In part, these properties result from repeated processes of gene duplication and diversification, which has led to the present complex genomic map of chemokines, which contains cases of non-allelic isoforms, copy number polymorphisms and classical allelic variation. This genomic complexity is compounded with pre-translational and post-translational mechanisms resulting in a complex network of proteins whose essential functions are maintained, constituting a remarkable case of robustness reminiscent of crucial metabolic pathways. This reflects the adaptation of a system under strong evolutive pressure, supporting the concept that the chemokine system is essential for the coordination, regulation and fine-tuning of the type of immune response. In this first review, we analyse currently available data on the chemokine superfamily, focusing on its complex genomic organization. Genes encoding essential inflammatory chemokines are grouped into defined chromosomal locations as clusters and miniclusters that, from the genetic point of view, can be considered single entities given their overall functions (many ligands of a cluster bind to a few shared receptors). We will try to interpret this genomic organization of chemokines in relation to the main functions acquired by each individual member or by each cluster. In a second review, we shall focus on the relationship of chemokine variability and disease susceptibility.