Elisa Melón-Ardanaz

Ulcerative colitis and Crohn's disease are chronic inflammatory intestinal diseases with perplexing heterogeneity in disease manifestation and response to treatment. While the molecular basis for this heterogeneity remains uncharacterized, single-cell technologies allow us to explore the transcriptional states within tissues at an unprecedented resolution which could further understanding of these complex diseases. Here, we apply single-cell RNA-sequencing to human inflamed intestine and show that the largest differences among patients are present within the myeloid compartment including macrophages and neutrophils. Using spatial transcriptomics in human tissue at single-cell resolution (CosMx Spatial Molecular Imaging) we spatially localize each of the macrophage and neutrophil subsets identified by single-cell RNA-sequencing and unravel further macrophage diversity based on their tissue localization. Finally, single-cell RNA-sequencing combined with single-cell spatial analysis reveals a strong communication network involving macrophages and inflammatory fibroblasts. Our data sheds light on the cellular complexity of these diseases and points towards the myeloid and stromal compartments as important cellular subsets for understanding patient-to-patient heterogeneity.

Abstract The gastrointestinal tract is a multi-organ system crucial for efficient nutrient uptake and barrier immunity. Advances in genomics and a surge in gastrointestinal diseases 1,2 has fuelled efforts to catalogue cells constituting gastrointestinal tissues in health and disease 3 . Here we present systematic integration of 25 single-cell RNA sequencing datasets spanning the entire healthy gastrointestinal tract in development and in adulthood. We uniformly processed 385 samples from 189 healthy controls using a newly developed automated quality control approach (scAutoQC), leading to a healthy reference atlas with approximately 1.1 million cells and 136 fine-grained cell states. We anchor 12 gastrointestinal disease datasets spanning gastrointestinal cancers, coeliac disease, ulcerative colitis and Crohn’s disease to this reference. Utilizing this 1.6 million cell resource (gutcellatlas.org), we discover epithelial cell metaplasia originating from stem cells in intestinal inflammatory diseases with transcriptional similarity to cells found in pyloric and Brunner’s glands. Although previously linked to mucosal healing 4 , we now implicate pyloric gland metaplastic cells in inflammation through recruitment of immune cells including T cells and neutrophils. Overall, we describe inflammation-induced changes in stem cells that alter mucosal tissue architecture and promote further inflammation, a concept applicable to other tissues and diseases.

Irritable bowel syndrome (IBS) is a disorder of brain-gut interaction characterised by abdominal pain and changes in bowel habits. In the diarrhoea subtype (IBS-D), altered epithelial barrier and mucosal immune activation are associated with clinical manifestations. We aimed to further evaluate plasma cells and epithelial integrity to gain understanding of IBS-D pathophysiology. One mucosal jejunal biopsy and one stool sample were obtained from healthy controls and IBS-D patients. Gastrointestinal symptoms, stress, and depression scores were recorded. In the jejunal mucosa, RNAseq and gene set enrichment analyses were performed. A morphometric analysis by electron microscopy quantified plasma cell activation and proximity to enteric nerves and glycocalyx thickness. Immunoglobulins concentration was assessed in the stool. IBS-D patients showed differential expression of humoral pathways compared to controls. Activation and proximity of plasma cells to nerves and IgG concentration were also higher in IBS-D. Glycocalyx thickness was lower in IBS-D compared to controls, and this reduction correlated with plasma cell activation, proximity to nerves, and clinical symptoms. These results support humoral activity and loss of epithelial integrity as important contributors to gut dysfunction and clinical manifestations in IBS-D. Additional studies are needed to identify the triggers of these alterations to better define IBS-D pathophysiology.

The use of single-cell technologies for clinical applications requires disconnecting sampling from downstream processing steps. Early sample preservation can further increase robustness and reproducibility by avoiding artifacts introduced during specimen handling. We present FixNCut, a methodology for the reversible fixation of tissue followed by dissociation that overcomes current limitations. We applied FixNCut to human and mouse tissues to demonstrate the preservation of RNA integrity, sequencing library complexity, and cellular composition, while diminishing stress-related artifacts. Besides single-cell RNA sequencing, FixNCut is compatible with multiple single-cell and spatial technologies, making it a versatile tool for robust and flexible study designs.

BACKGROUND AND AIMS: Tofacitinib, a Janus kinase inhibitor, is approved for the treatment of moderate-to-severe ulcerative colitis. Nonetheless, 40-60% of patients will not respond adequately. The mechanisms underlying responses to tofacitinib remain unknown. METHODS: We applied single-cell and/or bulk RNA analysis to biopsies (n = 23 and 63, respectively) from ulcerative colitis patients (n = 31) before and after tofacitinib treatment. Response was assessed using endoscopic and clinical criteria. In vitro-derived macrophages and primary intestinal fibroblasts were used to validate our findings. RESULTS: Forty percent of patients responded to tofacitinib. Responders exhibited higher baseline JAK-STAT activity, while non-responders had increased baseline NF-kB pathway activation. Response was associated with significant changes in the abundance and/or activation of immune, epithelial, and stromal cells and the downregulation of S100A9, FCGR3A, MMP12 in resident macrophages. In contrast, non-responders showed a significant increase in the number and activation of macrophages and fibroblasts following tofacitinib treatment, including upregulation of MMP9, IL1B, IL6, CXCL1, CXCL8, and S100A9 compared to baseline. In monocyte-derived macrophages tofacitinib drove the hyperactivation of macrophages in response to lipopolysaccharide, but not TNF or IFNγ. This effect is dependent on the inhibition of IL-10 signaling, which is abundantly induced in response to LPS, but not to TNF or IFNγ. In contrast, cultured fibroblasts, which produced no IL-10 regardless of the stimuli, showed no hyperactivation when pre-treated with tofacitinib. CONCLUSIONS: We conclude that resistance to tofacitinib is mediated by the hyperactivation of myeloid cells and we identify IL-10-dependent macrophages as one cellular subset contributing to this resistance.