Project description:Xenium spatial transcriptomic profiling of mouse lung following pharmacologic inhibition of lactate transport during fibrotic remodeling

Project description:Idiopathic pulmonary fibrosis (IPF) is a progressive, fatal lung disease that develops in response to chronic epithelial injury. Unlike injury-induced homeostatic lung repair during which fibroblasts undergo apoptosis and clearance, the lungs of IPF patients continue to accumulate apoptosis-resistant, pro-fibrotic, extracellular matrix-producing fibroblasts. Here, we show that prevention of PDGFRα+ fibroblast apoptosis by conditional BCL-2 expression leads to the emergence and persistence of senescent, pro-fibrotic fibroblasts along with enduring, pathologic fibrotic lung remodeling. Additionally, spatial transcriptomic studies of human IPF lungs confirmed the presence of senescent, BCL-2 expressing α-smooth muscle actin+ myofibroblasts in fibrotic regions. Of translational significance, selective BCL-2 inhibition with ABT-199 in fibrotic mice re-engaged the apoptotic pathway in fibroblasts, reduced senescence, and promoted fibrosis resolution and lung regeneration. Our findings suggest that sustained BCL-2 expression in fibroblasts prevents homeostatic lung repair, drives persistent fibrosis and is a therapeutically relevant target to reverse persistent pulmonary fibrosis.

Project description:To spatially contextualize and extend disease-associated cellular states, we generated Xenium spatial transcriptomics data from FFPE lung tissue of 38 participants spanning the COPD disease spectrum. Four tissue microarrays (TMA1–TMA4) were profiled using a custom 480-gene Xenium panel. These data capture the in situ organization of inflammatory, regenerative, and remodeling cell states and reveal spatially localized niches and patterns of cell–cell communications relevant to COPD pathology. This dataset provides high-resolution spatial context for characterizing microenvironmental structure and cell–cell interactions in COPD lung tissue.

Project description:Fibrosis, the replacement of healthy tissue with collagen-rich matrix, can occur following injury in almost every organ. Mouse lungs follow stereotyped sequences of fibrogenesis-to-resolution after bleomycin injury, and we reasoned that profiling post-injury histological progression could uncover pro- vs. anti-fibrotic features with functional value for human fibrosis. We mapped spatiotemporally-resolved transformations in lung extracellular matrix (ECM) architecture to spatially-resolved, multi-omic data. First, we charted stepwise trajectories of matrix aberration vs. resolution using unsupervised machine learning, denoting a reversible transition in uniform-to-disordered histological architecture. Single-cell sequencing along these trajectories identified temporally-enriched “ECM-secreting” (Csmd1+) and “pro-resolving” (Cd248+) fibroblasts, for which Visium inferred divergent histological signatures and spatial-transcriptional “neighborhoods”. Critically, pro-resolving fibroblast instillation helped ameliorate fibrosis in vivo. Further, fibroblast neighborhood-associated moieties, Serpine2 and Pi16, functionally modulated human lung fibrosis ex vivo. Spatial phenotyping of idiopathic pulmonary fibrosis further uncovered analogous fibroblast subtypes and neighborhoods in human disease. Collectively, these findings establish an atlas of pro-/anti-fibrotic factors underlying lung matrix architecture and implicate fibroblast-centered moieties in modulating fibrotic progression vs. resolution.

Project description:Fibrosis, the replacement of healthy tissue with collagen-rich matrix, can occur following injury in almost every organ. Mouse lungs follow stereotyped sequences of fibrogenesis-to-resolution after bleomycin injury, and we reasoned that profiling post-injury histological progression could uncover pro- vs. anti-fibrotic features with functional value for human fibrosis. We mapped spatiotemporally-resolved transformations in lung extracellular matrix (ECM) architecture to spatially-resolved, multi-omic data. First, we charted stepwise trajectories of matrix aberration vs. resolution using unsupervised machine learning, denoting a reversible transition in uniform-to-disordered histological architecture. Single-cell sequencing along these trajectories identified temporally-enriched “ECM-secreting” (Csmd1+) and “pro-resolving” (Cd248+) fibroblasts, for which Visium inferred divergent histological signatures and spatial-transcriptional “neighborhoods”. Critically, pro-resolving fibroblast instillation helped ameliorate fibrosis in vivo. Further, fibroblast neighborhood-associated moieties, Serpine2 and Pi16, functionally modulated human lung fibrosis ex vivo. Spatial phenotyping of idiopathic pulmonary fibrosis further uncovered analogous fibroblast subtypes and neighborhoods in human disease. Collectively, these findings establish an atlas of pro-/anti-fibrotic factors underlying lung matrix architecture and implicate fibroblast-centered moieties in modulating fibrotic progression vs. resolution.

Project description:Fibrosis, the replacement of healthy tissue with collagen-rich matrix, can occur following injury in almost every organ. Mouse lungs follow stereotyped sequences of fibrogenesis-to-resolution after bleomycin injury, and we reasoned that profiling post-injury histological progression could uncover pro- vs. anti-fibrotic features with functional value for human fibrosis. We mapped spatiotemporally-resolved transformations in lung extracellular matrix (ECM) architecture to spatially-resolved, multi-omic data. First, we charted stepwise trajectories of matrix aberration vs. resolution using unsupervised machine learning, denoting a reversible transition in uniform-to-disordered histological architecture. Single-cell sequencing along these trajectories identified temporally-enriched “ECM-secreting” (Csmd1+) and “pro-resolving” (Cd248+) fibroblasts, for which Visium inferred divergent histological signatures and spatial-transcriptional “neighborhoods”. Critically, pro-resolving fibroblast instillation helped ameliorate fibrosis in vivo. Further, fibroblast neighborhood-associated moieties, Serpine2 and Pi16, functionally modulated human lung fibrosis ex vivo. Spatial phenotyping of idiopathic pulmonary fibrosis further uncovered analogous fibroblast subtypes and neighborhoods in human disease. Collectively, these findings establish an atlas of pro-/anti-fibrotic factors underlying lung matrix architecture and implicate fibroblast-centered moieties in modulating fibrotic progression vs. resolution.

Project description:Image-based spatial transcriptomics identifies molecular niche dysregulation associated with distal lung remodeling in pulmonary fibrosis [Xenium]

Project description:Malaria-associated lung pathology, a severe and life-threatening manifestation of Plasmodium infection, involves complex immune remodeling within the pulmonary microenvironment. To resolve the spatial architecture of this immune response, we performed spatial transcriptomic analysis on lung tissues from a Plasmodium berghei NK65-induced rodent model. Our study identifies IFN-γ signaling in T cells as a pivotal regulator of the lung's spatial immune landscape. By utilizing conditional knockout (cKO) mice lacking Ifngr1 specifically in T cells, we observed that the blockade of T cell-intrinsic IFN-γ signaling attenuates lung pathology. Spatially, this protection is characterized by an enriched colocalization and enhanced interaction between T cells and monocytes. This robust interaction drives the expansion of a unique proinflammatory monocyte subset defined by CD8 and Ly6C expression within specific pulmonary niches. These CD8+ Ly6C+ monocytes exhibit significantly enhanced phagocytic capacity and elevated MHCII expression in situ. Our spatially resolved findings illustrate that the T cell-IFN-γ signaling axis dictates the spatial organization of T cell-monocyte communication, highlighting this interaction as a potential therapeutic target for mitigating malaria-induced lung injury.

Project description:We developed a method that utilizes floating mounting of thin sections of fixed frozen mouse lung tissue onto Xenium slides for the fluorescent in situ hybridization (FISH) and imaging–based spatial transcriptomics analysis of gene expression using the Xenium platform provided by 10X Genomics. Spatial transcriptomics techniques provide a comprehensive view by merging gene expression data with spatial context within their native tissue architecture. However, the Xenium pipeline has been validated only for formalin-fixed paraffin-embedded (FFPE) and fresh frozen sections by 10X Genomics. Notably, many researchers prefer paraformaldehyde-fixed cryosections for immunohistochemistry and in situ hybridization. In our study, we assessed the compatibility of standard fixed frozen mouse lung sections with the Xenium protocol. Our findings reveal that these sections not only align well with the Xenium platform but also offer superb imaging and gene expression quantification, even with limited number of genes in the Xenium panel. This protocol can serve as a valuable resource for preparing various tissues where FFPE and fresh frozen samples present challenges.

Project description:We profiled human lung and breast tumor fragments using imaging-based single-cell spatial transcriptomics (10x Xenium) and compared the results to sequencing-based spatial transcriptomics (10x Visium) and single-nucleus RNA-seq