STAT3 mutations in the hyper-IgE syndrome.

BACKGROUND: The hyper-IgE syndrome (or Job's syndrome) is a rare disorder of immunity and connective tissue characterized by dermatitis, boils, cyst-forming pneumonias, elevated serum IgE levels, retained primary dentition, and bone abnormalities. Inheritance is autosomal dominant; sporadic cases are also found. METHODS: We collected longitudinal clinical data on patients with the hyper-IgE syndrome and their families and assayed the levels of cytokines secreted by stimulated leukocytes and the gene expression in resting and stimulated cells. These data implicated the signal transducer and activator of transcription 3 gene (STAT3) as a candidate gene, which we then sequenced. RESULTS: We found increased levels of proinflammatory gene transcripts in unstimulated peripheral-blood neutrophils and mononuclear cells from patients with the hyper-IgE syndrome, as compared with levels in control cells. In vitro cultures of mononuclear cells from patients that were stimulated with lipopolysaccharide, with or without interferon-gamma, had higher tumor necrosis factor alpha levels than did identically treated cells from unaffected persons (P=0.003). In contrast, the cells from patients with the hyper-IgE syndrome generated lower levels of monocyte chemoattractant protein 1 in response to the presence of interleukin-6 (P=0.03), suggesting a defect in interleukin-6 signaling through its downstream mediators, one of which is STAT3. We identified missense mutations and single-codon in-frame deletions in STAT3 in 50 familial and sporadic cases of the hyper-IgE syndrome. Eighteen discrete mutations, five of which were hot spots, were predicted to directly affect the DNA-binding and SRC homology 2 (SH2) domains. CONCLUSIONS: Mutations in STAT3 underlie sporadic and dominant forms of the hyper-IgE syndrome, an immunodeficiency syndrome involving increased innate immune response, recurrent infections, and complex somatic features.

First-in-human topical microbiome transplantation with Roseomonas mucosa for atopic dermatitis.

The underlying pathology of atopic dermatitis (AD) includes impaired skin barrier function, susceptibility to Staphylococcus aureus skin infection, immune dysregulation, and cutaneous dysbiosis. Our recent investigation into the potential role of Gram-negative skin bacteria in AD revealed that isolates of one particular commensal, Roseomonas mucosa, collected from healthy volunteers (HVs) improved outcomes in mouse and cell culture models of AD. In contrast, isolates of R. mucosa from patients with AD worsened outcomes in these models. These preclinical results suggested that interventions targeting the microbiome could provide therapeutic benefit for patients with AD. As a first test of this hypothesis in humans, 10 adult and 5 pediatric patients were enrolled in an open-label phase I/II safety and activity trial (the Beginning Assessment of Cutaneous Treatment Efficacy for Roseomonas in Atopic Dermatitis trial; BACTERiAD I/II). Treatment with R. mucosa was associated with significant decreases in measures of disease severity, topical steroid requirement, and S. aureus burden. There were no adverse events or treatment complications. We additionally evaluated differentiating bacterial metabolites and topical exposures that may contribute to the skin dysbiosis associated with AD and/or influence future microbiome-based treatments. These early results support continued evaluation of R. mucosa therapy with a placebo-controlled trial.

TNF overproduction impairs epithelial staphylococcal response in hyper IgE syndrome.

Autosomal dominant hyper IgE syndrome (AD-HIES), or Job's syndrome, is a primary immune deficiency caused by dominant-negative mutations in STAT3. Recurrent Staphylococcus aureus skin abscesses are a defining feature of this syndrome. A widely held hypothesis that defects in peripheral Th17 differentiation confer this susceptibility has never been directly evaluated. To assess the cutaneous immune response in AD-HIES, we induced suction blisters in healthy volunteers (HVs) and patients with AD-HIES and then challenged the wound with lethally irradiated bacteria. We show that cutaneous production of IL-17A and IL-17F was normal in patients with AD-HIES. Overproduction of TNF-α differentiated the responses in AD-HIES from HVs. This was associated with reduced IL-10 family signaling in blister-infiltrating cells and defective epithelial cell function. Mouse models of AD-HIES recapitulated these aberrant epithelial responses to S. aureus and involved defective epithelial-to-mesenchymal transition (EMT) rather than a failure of bacterial killing. Defective responses in mouse models of AD-HIES and primary keratinocyte cultures from patients with AD-HIES could be reversed by TNF-α blockade and by drugs with reported modulatory effects on EMT. Our results identify these as potential therapeutic approaches in patients with AD-HIES suffering S. aureus infections.

Safety, tolerability, QTc evaluation, and pharmacokinetics of single and multiple doses of enzastaurin HCl (LY317615), a protein kinase C-beta inhibitor, in healthy subjects.

The safety, tolerability, and pharmacokinetics of orally administered enzastaurin were evaluated in 2 placebo-controlled, dose escalation studies in healthy subjects. In the first human dose study, single doses (2-400 mg) were evaluated, with 22 subjects receiving enzastaurin. The mean half-lives of enzastaurin and its metabolites ranged from approximately 12 to 40 hours. The longer half-life of the major circulating and pharmacologically active metabolite allowed once-a-day dosing and predicted that steady state would be achieved within 2 weeks of daily oral dosing in all subjects. In the multiple-dose study, daily doses (25-400 mg) were examined, with 24 subjects receiving at least 1 dose. The most common adverse events related to enzastaurin were headache, sleepiness, diarrhea, and nausea. No clinically significant changes in QTc intervals were observed. Overall, enzastaurin was well tolerated in healthy subjects, and the planned maximum dose was achieved in both studies.

Effects of enzastaurin and its metabolites on the QT interval in cancer patients.

Preclinical and interim results from a clinical pharmacology study in patients with cancer indicated that enzastaurin might have the potential to prolong the QT. Rather than undertake a formal thorough QT study, the effect of enzastaurin on the QT was assessed by combining the QT corrected for heart rate (QTc) intervals from 3 clinical pharmacology studies totaling 85 patients with cancer receiving multiple therapeutic or supratherapeutic doses of enzastaurin. Neither a placebo nor an active control was used. Serial, replicate, time-matched electrocardiograms were collected during a no-drug baseline day and when enzastaurin and its major active metabolite, LSN326020, had achieved steady state. Plasma concentrations of enzastaurin and LSN326020 were determined at each electrocardiogram point to enable concentration-QT analyses. The cross-study analysis showed that enzastaurin resulted in a statistically significant prolongation of the QTc at therapeutic and supratherapeutic doses. At an enzastaurin maximum plasma concentration (Cmax ) of 3660 nmol/L, the predicted QTc using Fridericia's formula (QTcF) interval and its 90% confidence interval was 17.72 milliseconds (16.52-18.92 milliseconds). Likewise, at an LSN326020 Cmax value of 1718 nmol/L, the predicted QTcF interval was 20.23 milliseconds (18.72-21.74 milliseconds). The concentration-QTcF slopes for enzastaurin and LSN326020 were positive and statistically significantly different from zero (all P < .05).