Project description:Throughout the various stages of tooth development, reciprocal epithelial-mesenchymal interactions are the driving force, for instance crucially involved in the differentiation of mature enamel-forming ameloblasts and dentin-producing odontoblasts. Here we established mouse tooth ‘assembloids’, comprised of tooth organoid-derived dental epithelial cells (from mouse molars and incisors) cultured together with molar dental pulp stem cells (DPSCs), to mimic these developmental interactions. Assembloids from both tooth types were grown both in basal- and differentiation-inducing conditions. Single cell transcriptomics analysis was applied to in detail characterize and validate the newly developed mouse tooth assembloid model and evaluate the induced differentiation processes.

Project description:We established a colon assembloid system comprising epithelium and diverse subtypes of stromal cells. To explore how closely assembloids resemble the native tissue, we performed the transcriptional profiling of stromal cells from assembloids and epithelial cells from assembloids, organoids, and colon tissue at the single-cell level.

Project description:Decoding glioblastoma invasion: single-cell profiling of environmental and cell cycle effects in tumour assembloids

Project description:Functional gastrointestinal disorders (FGIDs) affect ∼40% of the global population and are frequently characterized by colonic dysmotility. Symptomatic manifestations of colonic dysmotility significantly reduce quality of life in inflammatory bowel disease (IBD), diabetes, and Gulf War Illness (GWI). Current in vitro models lack the integration of functional physiology with immune and neuronal complexity required to establish causal links between neuroinflammation and dysmotility. Here, an immune-competent bioengineered colon assembloid is introduced that integrates multiple cell types of the external colonic wall, along with functional readouts of motility. Within bioengineered colon assembloids, various inflammatory insults resulted in enteric neuroinflammation, cascading to changes in colonic motility. Key mechanisms of dysmotility following inflammatory insult within the bioengineered colon assembloids included impaired neuronal regeneration, and aberrant smooth muscle remodeling. The bioengineered colon assembloid model mimicked diverse aspects of enteric neuroinflammation. Ultimately, the platform offers a physiologically relevant avenue to interrogate neuroimmune crosstalk and dissect mechanisms of colonic dysmotility, paving the way to new therapeutic strategies to improve colonic motility.

Project description:Patient-derived human organoids have the remarkable capacity to self-organise into more complex structures. However, to what extent the gastric organoids can recapitulate the human stomach functions remains unexplored. Here, we report how gastric region-specific organoids can self-assemble into complex multi-regional assembloids showing levels of differentiation unattainable with simpler models. The assembloid shows preserved fundus, body and antrum regionality and gastric-specific crosstalk pathways arise. Remarkably, the increased complexity and cross communication between the different gastric regions, allows for the arise of the elusive parietal cell type, responsible for the production of gastric acid, the essential function for food digestion. We showed functional response to drugs targeting ATPase H+/K+ and further maturation of the assembloid when transplanted in vivo. This advanced in vitro model, using patient-derived tissue-specific progenitors, successfully recapitulates the structural and functional characteristics of the human stomach, offering a promising strategy for studying developmental processes, tissue interactions, and disease mechanisms that were previously challenging to attain.

Project description:Patient-derived human organoids have the remarkable capacity to self-organise into more complex structures. However, to which extend the gastric organoids can recapitulate the human stomach functions remains unexplored. Here, we report how gastric region-specific organoids can self-assemble into complex multi-regional assembloids showing levels of differentiation unattainable with simpler models. The assembloid shows preserved fundus, body and antrum regionality and gastric-specific crosstalk pathways arise. Remarkably, the increased complexity and cross communication between the different gastric regions, allows for the arise of the elusive parietal cell type, responsible for the production of gastric acid, the essential function for food digestion. We showed functional response to drugs targeting ATPase H+/K+ and further maturation of the assembloid when transplanted in vivo. This advanced in vitro model, using patient-derived tissue-specific progenitors, successfully recapitulates the structural and functional characteristics of the human stomach, offering a promising strategy for studying developmental processes, tissue interactions, and disease mechanisms that were previously challenging to attain.

Project description:The paired kidneys are the central organs of homeostasis for our body systems, the sophisticated structure and complex cells composition underpins kidneys’ functions. Here we report the generation of mouse kidney progenitor assembloid (KPA) with expandable nephron progenitor cells (NPC) and ureteric bud (UB). Unexpectedly, versatile renal interstitial cells can be induced in kidney progenitor assembloids. Mechanistically, some NPC can be transdifferentiated into interstitial progenitor cells (IPCs) in KPA context, then induced IPCs differentiate into various renal interstitial cells. These kidney progenitors-based KPA highly resembled postnatal mouse kidneys with well pattern and showed essential renal physiological functions.

Project description:The nucleus basalis, also known as the nucleus basalis of Meynert (nbM), which is considered to be one of the major cholinergic output of basal forebrain, have been found to dynamically modulate activity in the cortex. Dysfunction of nucleus basalis-cortical cholinergic circuit led to cognitive impairment, such as Alzheimer's disease (AD) and Down syndrome (DS). Human nucleus basalis cholinergic neurons derived from human pluripotent stem cells provide powerful tools to study cholinergic neurons-associated diseases and cell therapy. Previous studies reported the generation of 2D human basal forebrain cholinergic neurons which failed to recapitulate the spatial organization, cellular diversity, and crosstalk between different regions. Therefore, a better model to recapitulate human nucleus basalis and cholinergic projections in nbM-cortical is desired. Here we developed a approach for differentiating human pluripotent stem cells into nucleus basalis of Meynert organoids (hnbMOs). We reconstructed hnbM-cortex cholinergic projection by transplanting hnbMOs into immunodeficiency mice to construct chimeric brains and coculturing with human fetal brain. Then we fused hnbMOs with cerebral cortex organoids (hCOs) to form hnbMO-hCO assembloids. We validate the structural and functional connectivity of basal forebrain cholinergic neurons to the cortex in assembloids. An assembloid-chimeric brain was constructed innovatively by transplanting corresponding organoids in the cortex and nbM region to establish a complete human cholinergic projection system. Futhermore, we identified the defects in projection of cholinergic neurons at the morphological and transcriptomic level in Down syndrome patient iPSC-derived assembloids as well as Down syndrome fetal brain tissue. Our work establishes new approach for the study of neurological disorders associated with nbM and nbM-cortical cholinergic neuron circuit.

Project description:To investigate whether the bladder assembloids recapitulate cell compositions, in addition to the gene expression patterns of each cell type in the adult bladder, we performed single-cell RNA-seq of bladder assembloids and mouse adult bladders, and compared the transcriptional profiles between them at the single-cell level.

Project description:In this study, we aimed to differentiate atrioventricular (AV) canal-like cardiomyocytes (AVCM) from hiPSCs to facilitate the study of disorders that affect the AV conduction axis. hiPSC-derived AVCM preferentially expressed AV canal-associated genes MSX2, TBX2 and TBX3. Single cell RNA sequencing and comparative analysis with mouse heart further validated their AV canal-like identity. In addition, hiPSC-AVCM demonstrated sensitivity to ivabradine and carbachol, indicating the presence of key nodal currents If and IKACh. To model the AV conduction axis, we created an organoid-based tissue model. These so-called “assembloids” consisted of atrial, AVC, and ventricular organoids, which exhibited spontaneous contractions and unidirectional conduction with impulses initiated predominantly at the atrial end. Remarkably, we observed slower conduction in the AVC region of the assembloid, effectively recapitulating the “fast-slow-fast” conduction pattern found in the early heart tube. Our results demonstrate that hiPSC-derived AVCM recapitulate molecular and electrophysiological properties of in vivo AV canal cardiomyocytes and tissue models incorporating this cell type enhance our ability to evaluate complex cardiac conduction disorders.