Discordant effects of Janus kinases inhibition ex-vivo on inflammatory responses in colonic compared to ileal mucosa.

BACKGROUND & AIMS: Janus kinase (JAK) inhibitors are used for treating inflammatory bowel diseases (IBD). We aimed to identify molecular effects of JAK inhibition in human intestinal mucosa, considering IBD location and phenotype. METHODS: Colonic and ileal explants from patients with ulcerative colitis (UC), Crohn's disease (CD), and non-IBD controls (NC) were assessed for phosphorylated signal transducers and activators of transcription (p-STAT) levels and Inflammatory genes expression panel in response to ex-vivo JAK inhibitor (tofacitinib). Cytokine production by lamina propria lymphocytes in response to tofacitinib was assessed. Human intestinal organoids were used to investigate JAK inhibitors' effects on iNOS expression. RESULTS: Explants were collected from 68 patients (UC=20; CD=20; NC=28). p-STAT1\3\5 inhibition rates varied, being higher in colonic compared to ileal explants. p-STAT1\3 inhibition rates negatively correlated with CRP levels. While significant alterations in 120 of 255 inflammatory genes were observed in colonic explants, only 30 were observed in ileal NC explants. In colonic explants from UC, significant alterations were observed in 5 genes, including NOS2. JAK inhibition significantly decreased Th1\Th2\Th17-related cytokine production from lamina propria lymphocytes. Various JAK inhibitors reduced IFN-γ-induced increase in iNOS expression in organoids. CONCLUSIONS: Site-specific anti-inflammatory effect of JAK inhibition by tofacitinib was noticed, whereby the colon was more robustly affected than the ileum. Ex-vivo response to tofacitinib is individual. JAK inhibition may attenuate inflammation by decreasing iNOS expression. Ex-vivo mucosal platforms may be a valuable resource for studying personalized drug effects in patients with IBD.

Human intestinal epithelial cells can internalize luminal fungi via LC3-associated phagocytosis.

Background: Intestinal epithelial cells (IECs) are the first to encounter luminal microorganisms and actively participate in intestinal immunity. We reported that IECs express the ß-glucan receptor Dectin-1, and respond to commensal fungi and ß-glucans. In phagocytes, Dectin-1 mediates LC3-associated phagocytosis (LAP) utilizing autophagy components to process extracellular cargo. Dectin-1 can mediate phagocytosis of ß-glucan-containing particles by non-phagocytic cells. We aimed to determine whether human IECs phagocytose ß-glucan-containing fungal particles via LAP. Methods: Colonic (n=18) and ileal (n=4) organoids from individuals undergoing bowel resection were grown as monolayers. Fluorescent-dye conjugated zymosan (ß-glucan particle), heat-killed- and UV inactivated C. albicans were applied to differentiated organoids and to human IEC lines. Confocal microscopy was used for live imaging and immuno-fluorescence. Quantification of phagocytosis was carried out with a fluorescence plate-reader. Results: zymosan and C. albicans particles were phagocytosed by monolayers of human colonic and ileal organoids and IEC lines. LAP was identified by LC3 and Rubicon recruitment to phagosomes and lysosomal processing of internalized particles was demonstrated by co-localization with lysosomal dyes and LAMP2. Phagocytosis was significantly diminished by blockade of Dectin-1, actin polymerization and NAPDH oxidases. Conclusions: Our results show that human IECs sense luminal fungal particles and internalize them via LAP. This novel mechanism of luminal sampling suggests that IECs may contribute to the maintenance of mucosal tolerance towards commensal fungi.

Anti-TNFα Treatment Impairs Long-Term Immune Responses to COVID-19 mRNA Vaccine in Patients with Inflammatory Bowel Diseases.

Patients with inflammatory bowel disease (IBD) treated with anti-tumor-necrosis factor-alpha (TNFα) exhibited lower serologic responses one-month following the second dose of the COVID-19 BNT162b2 vaccine compared to those not treated with anti-TNFα (non-anti-TNFα) or to healthy controls (HCs). We comprehensively analyzed long-term humoral responses, including anti-spike (S) antibodies, serum inhibition, neutralization, cross-reactivity and circulating B cell six months post BNT162b2, in patients with IBD stratified by therapy compared to HCs. Subjects enrolled in a prospective, controlled, multi-center Israeli study received two BNT162b2 doses. Anti-S levels, functional activity, specific B cells, antigen cross-reactivity, anti-nucleocapsid levels, adverse events and IBD disease score were detected longitudinally. In total, 240 subjects, 151 with IBD (94 not treated with anti-TNFα and 57 treated with anti-TNFα) and 89 HCs participated. Six months after vaccination, patients with IBD treated with anti-TNFα had significantly impaired BNT162b2 responses, specifically, more seronegativity, decreased specific circulating B cells and cross-reactivity compared to patients untreated with anti-TNFα. Importantly, all seronegative subjects were patients with IBD; of those, >90% were treated with anti-TNFα. Finally, IBD activity was unaffected by BNT162b2. Altogether these data support the earlier booster dose administration in these patients.