Project description:Pathologic transformation represents a pivotal yet poorly defined window during which early alterations in epithelial stem cells remodel their surrounding niche to prime tumour initiation. Here, we integrate single-cell, spatial, and functional analyses to map the dynamics of this early multicellular reorganisation. We show that KrasG12D-mutant alveolar type II cells undergo an early reprogramming transition that transforms them into signalling hubs, with the Amphiregulin (Areg)-EGFR axis emerging as a central driver of cross-compartmental cooperation. Mutant epithelial cells secrete Areg to activate EGFR in adjacent fibroblasts, eliciting a regenerative-like fibrotic programme. These reprogrammed fibroblasts, in turn, reshape the immune landscape by expanding and reprogramming alveolar macrophages, amplifying inflammatory signalling, immune recruitment, and epithelial plasticity. Together, these interactions establish a self-reinforcing multicellular circuit that generates and maintains a tumour permissive niche. Disrupting that circuit through genetic and pharmacological perturbation of the Areg-EGFR axis prevents both early niche cell reprogramming and tumour formation. Findings from KRASG12D-inducible human alveolar organoids and early-stage lung adenocarcinoma tissues confirm conservation of these interactions, identifying early mutant epithelial-stromal crosstalk as a targetable step in pathologic transformation with potential to avert establishment of treatment-resistant disease.

Project description:Pathologic transformation represents a pivotal yet poorly defined window during which early alterations in epithelial stem cells remodel their surrounding niche to prime tumour initiation. Here, we integrate single-cell, spatial, and functional analyses to map the dynamics of this early multicellular reorganisation. We show that KrasG12D-mutant alveolar type II cells undergo an early reprogramming transition that transforms them into signalling hubs, with the Amphiregulin (Areg)-EGFR axis emerging as a central driver of cross-compartmental cooperation. Mutant epithelial cells secrete Areg to activate EGFR in adjacent fibroblasts, eliciting a regenerative-like fibrotic programme. These reprogrammed fibroblasts, in turn, reshape the immune landscape by expanding and reprogramming alveolar macrophages, amplifying inflammatory signalling, immune recruitment, and epithelial plasticity. Together, these interactions establish a self-reinforcing multicellular circuit that generates and maintains a tumour permissive niche. Disrupting that circuit through genetic and pharmacological perturbation of the Areg-EGFR axis prevents both early niche cell reprogramming and tumour formation. Findings from KRASG12D-inducible human alveolar organoids and early-stage lung adenocarcinoma tissues confirm conservation of these interactions, identifying early mutant epithelial-stromal crosstalk as a targetable step in pathologic transformation with potential to avert establishment of treatment-resistant disease.

Project description:Pathologic transformation represents a critical yet poorly defined window during which mutant epithelial stem cells actively construct the microenvironment that enables tumour initiation. Here, using integrated single-cell, spatial, and functional analyses, we define the earliest multicellular events that license this transition following oncogenic activation in the lung. KrasG12D-mutant alveolar type II cells rapidly adopt regenerative-like states that act as signalling hubs, orchestrating coordinated stromal and immune reprogramming while enhancing epithelial plasticity. Through secretion of Amphiregulin (Areg), mutant epithelial cells activate EGFR signalling in adjacent fibroblasts, inducing a fibrotic, injury-like programme. Reprogrammed fibroblasts, in turn, expand and reprogramme alveolar macrophages, amplifying inflammatory signalling and reinforcing epithelial plasticity. These reciprocal interactions establish a self-sustaining epithelial–stromal–immune circuit that generates a tumour-permissive niche prior to malignant outgrowth. Disruption of the Areg–EGFR axis prevents early niche formation and abrogates tumour initiation. Conservation of this programme in KRASG12D-inducible human alveolar organoids and early-stage lung adenocarcinoma tissues identifies epithelial–microenvironment communication as a therapeutically actionable vulnerability and suggests that intercepting niche formation may prevent progression to treatment-resistant disease.

Project description:Cellular senescence is an irreversible growth arrest with a highly dynamic secretome, termed the senescence-associated secretory phenotype (SASP). Senescence has been implicated in somatic reprogramming to pluripotency. The cell-intrinsic proliferation arrest is a barrier for reprogramming, whereas the SASP facilitates the cell fate conversion in nonsenescent cells. However, the mechanisms by which reprogramming-induced senescence regulates cell plasticity are not well understood. Here, we have further investigated how the heterogeneity of paracrine senescence impacts reprogramming. We show that senescence promotes in vitro reprogramming in a stress-dependent manner. We identified a catalog of SASP factors and pathways potentially involved in the cell fate conversion using an unbiased proteomic analysis. Amphiregulin (AREG), a growth factor frequently secreted by the senescent cells, promotes in vitro reprogramming by accelerating proliferation and MET via the EGFR signaling pathway. Of note, AREG treatment diminished the negative effect of donor age on reprogramming. Finally, AREG enhances in vivo reprogramming in the skeletal muscle. Hence, senescence could facilitate cellular plasticity via various SASP factors to promote reprogramming and tissue repair.

Project description:Lung adenocarcinoma is responsible for significant global mortality with limited effective treatments. Although some studies suggest that these tumors arise from alveolar epithelial type 2 cells (AEC2s), there is scant information regarding the early events that might occur in human AEC2s at the inception of oncogenesis. This limitation, is partially due to a lack of human model systems that recapitulate the initiation of oncogenesis in AEC2s. Unfortunately, primary AEC2s from patients are difficult to access in vivo or stably maintain in cell cultures. Hence, we sought to develop an in vitro system to model the early stages of oncogenesis utilizing human induced AEC2s (iAEC2s) generated through the directed differentiation of induced pluripotent stem cells (iPSCs). To this end, we selected a normal human iPSC line we have previously engineered to carry fluorochrome reporters targeted to lung epithelial-specific loci, NKX2-1GFP and SFTPCtdTomato that enable monitoring and purification of alveolar lung epithelial cells. To test the effects of adenocarcinoma oncogene induction in these cells, we targeted a third locus, AAVS1 using gene editing to engineer a doxycycline-inducible cassette encoding mutant KRASG12D, the most commonly found oncogene in lung adenocarcinomas. Successful induction of KRASG12D with doxycycline was demonstrated in both the targeted undifferentiated iPSCs as well as in the iAEC2s derived from these cells. We profiled the downstream effects of KRASG12D induction in iAEC2s, comparing dox vs vehicle exposed cells by cell counting, FACS for NKX2-1GFP/SFTPCtdTomato, RT-qPCR, deep proteomic and phosphoproteomic analyses, and scRNA-sequencing. Through this characterization, we found that induction of KRASG12D robustly activates MAPK signaling resulting in a shift of iAEC2s away from their mature alveolar program towards a distal lung epithelial progenitor phenotype. Successful modeling of lung adenocarcinoma with this model system has a variety of future applications, including testing unknown mechanisms for oncogenesis, discovery of novel biomarkers of disease, or development of new effective treatment methods through drug screening.

Project description:Background & Aims: Isthmic progenitors, tissue-specific stem cells in the stomach corpus, maintain mucosal homeostasis by balancing between proliferation and differentiation to gastric epithelial lineages. The progenitor cells rapidly adopt an active state in response to mucosal injury. However, it remains unclear how the isthmic progenitor cell niche is controlled during the regeneration of damaged epithelium. Methods: We recapitulated tissue recovery process after acute mucosal injury in the mouse stomach. BrdU incorporation was utilized to trace newly generated cells during the injury and recovery phases. To define epithelial lineage commitment process during recovery, we performed single cell RNA-sequencing on epithelial cells from the mouse stomachs. We validated the effects of amphiregulin (AREG) on the mucosal recovery, utilizing recombinant AREG treatment or AREG deficient mice. Results: We determined that an EGFR ligand, AREG, can control progenitor cell lineage commitment. Based on the identification of lineage-committed subpopulations in the corpus epithelium through single cell RNA-sequencing and BrdU incorporation, we showed that isthmic progenitors give rise to epithelial cell lineages through an ordered paradigm during mucosal regeneration. During recovery, AREG treatment promotes repopulation with parietal cells, while suppressing surface cell commitment of progenitors. In contrast, TGF-alpha did not alter parietal cell regeneration but did induce expansion of surface cell populations. AREG deficiency impairs parietal cell regeneration, but increases surface cell commitment. Conclusions: These data demonstrate that different EGF receptor ligands can distinctly regulate isthmic progenitor-driven mucosal regeneration and lineage commitment.

Project description:This study investigates the role of regulatory T cell–derived Areg in driving epithelial repair following influenza infection. We use RNA sequencing to probe the gene expression changes within epithelial cells in wildtype mice and in mice that conditionally lack Areg from T cell sources (CD4-cre Areg-flox). Further, we identify a population of damage-associated transitional alveolar epithelial cells that are induced in reponse to acute injury and exhibit gene expression changes reflective of AT2 transdifferentiation to AT1.

Project description:This study investigates the role of regulatory T cell–derived Areg in driving epithelial repair following influenza infection. We use RNA sequencing to probe the gene expression changes within epithelial cells in wildtype mice and in mice that conditionally lack Areg from T cell sources (CD4-cre Areg-flox). Further, we identify a population of damage-associated intermediate alveolar epithelial cells (AECint) that are induced in reponse to acute injury and exhibit gene expression changes reflective of AT2 transdifferentiation to AT1.

Project description:Our lab has identified a completely unexpected requirement for ERBB signalling in KRAS‐driven Lung Adenocarcinoma (LuAd). We have shown that this requirement is present from the very outset of lung tumour initiation, and, crucially, we have found a pronounced increase in ERBB signalling during progression from low grade adenocarcinoma to locally invasive disease. We hypothesize that this increased activity, which manifests as strongly elevated expression of multiple EGF/ERBB-family ligands, such as Amphiregulin (AREG), and paracrine activation of ERBB2 on infiltrating macrophages, may be exploited for early detection of KRAS‐ driven malignancy. Alongside a more general increase in AREG expression as tumours progress to higher grade disease, we find individual cells that express extremely high levels of AREG mRNA. We refer to these cells as AREG super-expressers and their lineage identity is unknown. Cell morphology suggests they maybe epithelial, however, unlike the bulk of tumours, these cells fail to express the lung epithelial marker SPC and staining for cytokeratins is inconclusive. Their detection at and adjacent to the tumour:normal interface suggests that they maybe disseminating tumour cells undergoing EMT. Alternatively, they may belong to another lung-resident or infiltrating population, induced to express AREG through direct contact with tumour cells. Immediately adjacent to progressing tumours we find large numbers of F4/80-positive macrophages that stain strongly for tyrosine phosphorylated ERBB2 (p-Tyr-ERBB2), suggesting paracrine activation in response to local production of ERBB ligands. The aim of this part of the work is to identify the cell lineage of the AREG superexpressers and to investigate the effect of ERBB-inhibition using the multi-ERBB inhibitor Neratinib.

Project description:Disseminated cancer cells reside in the lung alveolar niche where they are exposed to interactions with alveolar macrophages. Here we report bulk RNA-sequencing data from co-cultured MMTV-HER2 mammary early lesion cells or mammary primary tumor cells cultured with lung alveolar macrophages. We discovered reciprocal regulation between mammary cells and alveolar macrophages, where early lesion cells instruct alveolar macrophages to maintain an anti-tumor phenotype and alveolar macrophages activate an epithelial to mesenchymal program in early lesion cells. Coveresely, primary tumor cells activate inflammatory prorgams in alveolar macrophages, while alveolar macrophages are not able to activate growth restriction programs in primary tumor cells. Receptor-ligand analysis highlighted two known pathways invovled in quiencesce, namely the TGF-beta pathway and the OSM pathway.