Cellular deconstruction of inflamed synovium defines diverse inflammatory phenotypes in rheumatoid arthritis

Zhang, Fan; Jonsson, Helena; Nathan, Aparna; Wei, Kevin; Millard, Nghia; Xiao, Qian; Gutiérrez‐Arcelus, María; Apruzzese, William; Watts, Gerald F. M.; Weisenfeld, Dana; Kang, Joyce B.; Rumker, Laurie; Mears, Joseph; Slowikowski, Kamil; Weinand, Kathryn; Orange, Dana E.; Rangel-Moreno, Javier; Geraldino‐Pardilla, Laura; Deane, Kevin D.; Tabechian, Darren; Ceponis, A; Firestein, Gary S.; Maybury, Mark; Sahbudin, Ilfita; Ben-Artzi, Ami; Mandelin, Arthur M.; Nerviani, Alessandra; Rivellese, Felice; Pitzalis, Costantino; Hughes, Laura B.; Horowitz, Diane; DiCarlo, Edward F.; Gravallese, Ellen M.; Moreland, Larry W.; Goodman, Susan M.; Perlman, Harris; Holers, V. Michael; Liao, Katherine P.; Filer, Andrew; Bykerk, Vivian P.; Rao, Deepak A.; Donlin, Laura T.; Anolik, Jennifer H.; Brenner, Michael B.; Raychaudhuri, Soumya; Albrecht, Jennifer S.; Barnas, Jennifer L.; Bathon, Joan M.; Boyle, David L.; Bridges, S. Louis; Campbell, Debbie; Carr, Hayley L.; Chicoine, Adam; Cordle, Andrew C.; Curtis, Michelle; Dunn, Patrick; Forbess, Lindsy; Gregersen, Peter K.; Guthridge, Joel M.; Ivashkiv, Lionel B.; Ishigaki, Kazuyoshi; James, Judith A.; Keras, Gregory; Korsunsky, Ilya; Lakhanpal, Amit; Lederer, James A.; Li, Zhihan J.; Li, Yuhong; McDavid, Andrew; Meednu, Nida; Mantel, Ian; McGeachy, Mandy J.; Raza, Karim; Reshef, Yakir; Ritchlin, Christopher T.; Robinson, William H.; Sakaue, Saori; Seifert, Jennifer; Smith, Melanie H.; Scheel‐Toellner, Dagmar; Utz, Paul J.; Weisman, Michael H.; Zhu, Zhu

doi:10.1101/2022.02.25.481990

Cited by 27 publications

(54 citation statements)

References 114 publications

(154 reference statements)

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“…We need to better understand the molecular mechanisms that underlie these early phases of disease such that intervention could prevent either transition from pre-RA to early RA, or early RA to established disease. Ultimately, this raises the idea of precision medicine whereby molecular signatures of early disease would facilitate earlier diagnosis and identify optimal therapeutic targets8 9 that can deliver remission or immune diversion potentially at a very early stage. This is consistent with the notion of prevention of tissue damage and long term will reduce the tissue reparative burden.…”

Section: Resultsmentioning

confidence: 99%

Unmet need in rheumatology: reports from the Advances in Targeted Therapies meeting, 2022

et al. 2023

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To detail the unmet clinical and scientific needs in the field of rheumatology. After a 2-year hiatus due to the SARS-CoV-2 pandemic, the 22nd annual international Advances in Targeted Therapies meeting brought together more than 100 leading basic scientists and clinical researchers in rheumatology, immunology, epidemiology, molecular biology and other specialties. Breakout sessions were convened with experts in five rheumatological disease-specific groups including: rheumatoid arthritis (RA), psoriatic arthritis, axial spondyloarthritis, systemic lupus erythematosus and connective tissue diseases (CTDs). In each group, experts were asked to identify and prioritise current unmet needs in clinical and translational research, as well as highlight recent progress in meeting formerly identified unmet needs. Clinical trial design innovation was emphasised across all disease states. Within RA, developing therapies and trials for refractory disease patients remained among the most important identified unmet needs and within lupus and spondyloarthritis the need to account for disease endotypes was highlighted. The RA group also identified the need to better understand the natural history of RA, pre-RA states and the need ultimately for precision medicine. In CTD generally, experts focused on the need to better identify molecular, cellular and clinical signals of early and undifferentiated disease in order to identify novel drug targets. There remains a strong need to develop therapies and therapeutic strategies for those with treatment-refractory disease. Increasingly it is clear that we need to better understand the natural history of these diseases, including their ‘predisease’ states, and identify molecular signatures, including at a tissue level, which can facilitate disease diagnosis and treatment. As these unmet needs in the field of rheumatic diseases have been identified based on consensus of expert clinicians and scientists in the field, this document may serve individual researchers, institutions and industry to help prioritise their scientific activities.

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Section: Resultsmentioning

confidence: 99%

Unmet need in rheumatology: reports from the Advances in Targeted Therapies meeting, 2022

et al. 2023

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“…The future studies involving larger stratified patient cohorts will be essential to link synovial cell composition to variation in therapeutic response. Furthermore, such studies might contribute to the cell subtype-based and molecular pathway-based patient stratification across and within different clinical types of inflammatory arthritis 85 .…”

Section: Discussionmentioning

confidence: 99%

A reference single-cell map of freshly dissociated human synovium in inflammatory arthritis with an optimized dissociation protocol for prospective synovial biopsy collection

Edalat

Gerber

Houtman

et al. 2022

Preprint

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Single-cell RNA-sequencing is advancing our understanding of synovial pathobiology in inflammatory arthritis. Here, we optimized the protocol for dissociation of synovial biopsies and created a comprehensive reference single-cell atlas of fresh human synovium in inflammatory arthritis. We derived our protocol from the published dissociation method for cryopreserved synovium (Donlin L. et al. Arthritis Res. Ther. 2019) with modifications to enrich synovial cells and minimize cell loss. These modifications enabled consistently high cell yield and viability, thereby minimizing the rate of synovial tissue sample dropout. Our single-cell atlas of the human synovium comprised more than 100000 unsorted single-cell profiles from 27 synovia of patients with inflammatory arthritis. Synovial cells formed ten lymphoid, 14 myeloid and 17 stromal cell clusters, including IFITM2+ synovial neutrophils. We identified lining SOD2highSAA1+SAA2+ and transitional SERPINE1+COL5A3+ synovial fibroblasts, exhibiting gene signatures linked to cartilage breakdown (SDC4) and extracellular matrix remodelling (LOXL2, TGFBI, TGFB1), respectively. We uncovered synovial endothelial cell diversity and broadened the transcriptional characterization of tissue-resident FOLR2+ COLEC12+ and SLC40A1+ synovial macrophages, inferring their extracellular matrix sensing and iron recycling activities. Our research brings an efficient synovium dissociation protocol for prospectively collected fresh synovial biopsies and expands the knowledge about human synovium composition in inflammatory arthritis.

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“…Multimodal data integrations provide additional biological perspectives, through the combination of proteomics (CITE-seq), epigenetics (multiome), or spatial locations (ST), in addition to transcriptomics, which can reveal novel immunological or disease-driven insights. A very recent study with a collaborative effort from AMP (Accelerating Medicines Partnership) RA/SLE network used CITE-seq to reveal 10 distinct stromal populations and emphasized which of these populations are expanded in a particular patient group ( 35 ). Using three-dimensional spatial transcriptomics, Vickovic et al.…”

Section: Fibroblasts Play Important Roles In Different Inflammatory D...mentioning

confidence: 99%

“…demonstrated that in-depth stratification of RA synovial biopsies based on single-cell multimodal integrative analysis combined with covarying neighborhood analysis can associate cellular heterogeneity to stratified RA synovial phenotypes. Specifically, RA synovial heterogeneity was classified into six distinct subgroups or “cell type abundance phenotypes” (CTAPs) based on major cell-type abundance ( 35 ): 1) endothelial, fibroblast, and myeloid cells, 2) fibroblasts, 3) T cells and fibroblasts, 4) T and B cells, 5) T and myeloid cells, and 6) myeloid cells. Three of the CTAPs have associations with fibroblast and their immune interaction abundances suggesting that different patients, even with the same disease, have different tissue phenotypes at the core of their pathology, and accordingly, different molecules to be targeted for therapy.…”

Section: Future Directionsmentioning

confidence: 99%

Single-cell computational machine learning approaches to immune-mediated inflammatory disease: New tools uncover novel fibroblast and macrophage interactions driving pathogenesis

2023

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Recent advances in single-cell sequencing technologies call for greater computational scalability and sensitivity to analytically decompose diseased tissues and expose meaningful biological relevance in individual cells with high resolution. And while fibroblasts, one of the most abundant cell types in tissues, were long thought to display relative homogeneity, recent analytical and technical advances in single-cell sequencing have exposed wide variation and sub-phenotypes of fibroblasts of potential and apparent clinical significance to inflammatory diseases. Alongside anticipated improvements in single cell spatial sequencing resolution, new computational biology techniques have formed the technical backbone when exploring fibroblast heterogeneity. More robust models are required, however. This review will summarize the key advancements in computational techniques that are being deployed to categorize fibroblast heterogeneity and their interaction with the myeloid compartments in specific biological and clinical contexts. First, typical machine-learning-aided methods such as dimensionality reduction, clustering, and trajectory inference, have exposed the role of fibroblast subpopulations in inflammatory disease pathologies. Second, these techniques, coupled with single-cell predicted computational methods have raised novel interactomes between fibroblasts and macrophages of potential clinical significance to many immune-mediated inflammatory diseases such as rheumatoid arthritis, ulcerative colitis, lupus, systemic sclerosis, and others. Third, recently developed scalable integrative methods have the potential to map cross-cell-type spatial interactions at the single-cell level while cross-tissue analysis with these models reveals shared biological mechanisms between disease contexts. Finally, these advanced computational omics approaches have the potential to be leveraged toward therapeutic strategies that target fibroblast-macrophage interactions in a wide variety of inflammatory diseases.

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Cellular deconstruction of inflamed synovium defines diverse inflammatory phenotypes in rheumatoid arthritis

Cited by 27 publications

References 114 publications

Unmet need in rheumatology: reports from the Advances in Targeted Therapies meeting, 2022

Unmet need in rheumatology: reports from the Advances in Targeted Therapies meeting, 2022

A reference single-cell map of freshly dissociated human synovium in inflammatory arthritis with an optimized dissociation protocol for prospective synovial biopsy collection

Single-cell computational machine learning approaches to immune-mediated inflammatory disease: New tools uncover novel fibroblast and macrophage interactions driving pathogenesis

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