The immunopathological landscape of human pre-TCRα deficiency: From rare to common variants

We describe humans with rare biallelic loss-of-function PTCRA variants impairing pre-α T cell receptor (pre-TCRα) expression. Low circulating naive αβ T cell counts at birth persisted over time, with normal memory αβ and high γδ T cell counts. Their TCRα repertoire was biased, which suggests that noncanonical thymic differentiation pathways can rescue αβ T cell development. Only a minority of these individuals were sick, with infection, lymphoproliferation, and/or autoimmunity. We also report that 1 in 4000 individuals from the Middle East and South Asia are homozygous for a common hypomorphic PTCRA variant. They had normal circulating naive αβ T cell counts but high γδ T cell counts. Although residual pre-TCRα expression drove the differentiation of more αβ T cells, autoimmune conditions were more frequent in these patients compared with the general population.

IgA deficiency destabilizes homeostasis toward intestinal microbes and increases systemic immune dysregulation

The ability of most patients with selective immunoglobulin A (IgA) deficiency (SIgAD) to remain apparently healthy has been a persistent clinical conundrum. Compensatory mechanisms, including IgM, have been proposed, yet it remains unclear how secretory IgA and IgM work together in the mucosal system and, on a larger scale, whether the systemic and mucosal anti-commensal responses are redundant or have unique features. To address this gap in knowledge, we developed an integrated host-commensal approach combining microbial flow cytometry and metagenomic sequencing (mFLOW-Seq) to comprehensively define which microbes induce mucosal and systemic antibodies. We coupled this approach with high-dimensional immune profiling to study a cohort of pediatric patients with SIgAD and household control siblings. We found that mucosal and systemic antibody networks cooperate to maintain homeostasis by targeting a common subset of commensal microbes. In IgA-deficiency, we find increased translocation of specific bacterial taxa associated with elevated levels of systemic IgG targeting fecal microbiota. Associated features of immune system dysregulation in IgA-deficient mice and humans included elevated levels of inflammatory cytokines, enhanced follicular CD4 T helper cell frequency and activation, and an altered CD8 T cell activation state. Although SIgAD is clinically defined by the absence of serum IgA, the symptomatology and immune dysregulation were concentrated in the SIgAD participants who were also fecal IgA deficient. These findings reveal that mucosal IgA deficiency leads to aberrant systemic exposures and immune responses to commensal microbes, which increase the likelihood of humoral and cellular immune dysregulation and symptomatic disease in patients with IgA deficiency.

IgA deficiency destabilizes immunological homeostasis towards intestinal microbiota and increases the risk of systemic immune dysregulation

Mammals produce large quantities of mucosal and systemic antibodies that maintain the intestinal barrier, shape the intestinal microbiome and promote lifelong mutualism with commensal microbes. Here, we developed an integrated host-commensal approach combining microbial flow cytometry and 16S rRNA gene sequencing to define the population of microbes that induce mucosal and systemic antibodies with CyTOF analysis in pediatric selective Immunoglobulin A (IgA) deficient and household control siblings to determine the impacts of IgA deficiency on host cellular immune phenotype. In healthy controls, mucosal secretory IgA and IgM antibodies coat an overlapping subset of microbes, predominantly Firmicutes and Proteobacteria. Serum IgG antibodies target a similar consortium of fecal microbes, revealing connections between mucosal and systemic antibody networks. Furthermore, we find broad systemic immune dysregulation in a subset of children and mice lacking IgA, including enhanced IgG targeting of fecal microbiota, elevated levels of inflammatory and allergic cytokines and alterations in T cell activation state. Thus, IgA tunes systemic interactions between the host and commensal microbiota. Understanding how IgA affects baseline immune tone has implications for predicting and preventing autoimmune, inflammatory and allergic diseases, as well as providing improved prognostic guidance to patients with IgA deficiency.

Supported by CHOP Microbiome Pilot Grant K08AI135091 Burroughs Wellcome Fund, the American Academy of Allergy, Asthma, and Immunology, the Immune Deficiency Foundation, the Primary Immune Deficiency Treatment Consortium and Chan Zuckerberg Initiative

Dysregulation of CD8+ T cell function in the setting of altered cytokine signaling due to inborn errors of immunity

A key outcome of chronic antigenic stimulation in the setting of sustained inflammation is the development of CD8+ T cell exhaustion. However, the relative roles of inflammation and antigen stimulation on T cell dysfunction remain unclear. Inborn errors of immunity (IEIs) provide an opportunity to study the effect of genetic alterations in signaling pathways on immune function. Here, we focus on an IEI resulting from genetically amplified cytokine signaling: gain-of-function mutations in STAT3 (STAT3 GOF). STAT3 signals downstream of multiple inflammatory cytokines (e.g., IL-6 and IL-27) and we used STAT3 GOF as a genetic mimic of chronic inflammation. To assess how amplified STAT3 signaling impacts immune cell subset distribution and activation status, PBMCs from STAT3 GOF patients and age-matched healthy controls were profiled via mass cytometry (CyTOF). This revealed altered states of CD8+ T cell activation including increased expression of immunoregulatory receptors (e.g., PD-1 and CD39). STAT3 GOF CD8+ T cells also showed impaired cytokine production and reduced proliferative capacity. Bulk RNA sequencing of naïve STAT3 GOF CD8+ T cells identified an exhausted-like transcriptional profile. Quantitation of metabolic function shows alterations in glucose use and oxidative phosphorylation in STAT3 GOF. Our studies suggest that inflammation alone may directly impair CD8+ T cell function. Understanding the mechanisms by which inflammation impacts T cell function may identify components of T cell dysregulation that can be targeted therapeutically in these rare patients, as well as those with more common inflammatory diseases (e.g., obesity) with shared aspects of T cell dysfunction.

Supported by CHOP Research Institute, The Primary Immune Deficiency Treatment Consortium (PIDTC) and Immune Deficiency Foundation (IDF). 

Deep immune profiling of MIS-C demonstrates marked but transient immune activation compared to adult and pediatric COVID-19

Pediatric COVID-19 following SARS-CoV-2 infection is associated with fewer hospitalizations and often milder disease than in adults. A subset of children, however, present with Multisystem Inflammatory Syndrome in Children (MIS-C) that can lead to vascular complications and shock, but rarely death. The immune features of MIS-C compared to pediatric COVID-19 or adult disease remain poorly understood. We analyzed peripheral blood immune responses in hospitalized SARS-CoV-2 infected pediatric patients (pediatric COVID-19) and patients with MIS-C. MIS-C patients had patterns of T cell-biased lymphopenia and T cell activation similar to severely ill adults, and all patients with MIS-C had SARS-CoV-2 spike-specific antibodies at admission. A distinct feature of MIS-C patients was robust activation of vascular patrolling CX3CR1+ CD8+ T cells that correlated with the use of vasoactive medication. Finally, whereas pediatric COVID-19 patients with acute respiratory distress syndrome (ARDS) had sustained immune activation, MIS-C patients displayed clinical improvement over time, concomitant with decreasing immune activation. Thus, non-MIS-C versus MIS-C SARS-CoV-2 associated illnesses are characterized by divergent immune signatures that are temporally distinct from one another and implicate CD8+ T cells in the clinical presentation and trajectory of MIS-C.