Healthy Organoids Research Articles

O-glycosylation contributes to mammalian glycoRNA biogenesis.

There is an increasing appreciation for the role of cell surface glycans in modulating interactions with extracellular ligands and participating in intercellular communication. We recently reported the existence of sialoglycoRNAs, where mammalian small RNAs are covalently linked to N-glycans through the modified base acp3U and trafficked to the cell surface. However, little is currently known about the role for O-glycosylation, another major class of carbohydrate polymer modifications. Here, we use parallel genetic, enzymatic, and mass spectrometry approaches to demonstrate that O-linked glycan biosynthesis is responsible for the majority of sialoglycoRNA levels. By examining the O-glycans associated with RNA from cell lines and colon organoids we find known and previously unreported O-linked glycan structures. Further, we find that O-linked glycans released from small RNA from organoids derived from ulcerative colitis patients exhibit higher levels of sialylation than glycans from healthy organoids. Together, our work provides flexible tools to interrogate O-linked glycoRNAs (O-glycoRNA) and suggests that they may be modulated in human disease.

Patient-derived tumoroids and proteomic signatures: tools for early drug discovery.

Onco-virotherapy is an emergent treatment for cancer based on viral vectors. The therapeutic activity is based on two different mechanisms including tumor-specific oncolysis and immunostimulatory properties. In this study, we evaluated onco-virotherapy in vitro responses on immunocompetent non-small cell lung cancer (NSCLC) patient-derived tumoroids (PDTs) and healthy organoids. PDTs are accurate tools to predict patient's clinical responses at the in vitro stage. We showed that onco-virotherapy could exert specific antitumoral effects by producing a higher number of viral particles in PDTs than in healthy organoids. In the present work, we used multiplex protein screening, based on proximity extension assay to highlight different response profiles. Our results pointed to the increase of proteins implied in T cell activation, such as IFN-γ following onco-virotherapy treatment. Based on our observation, oncolytic viruses-based therapy responders are dependent on several factors: a high PD-L1 expression, which is a biomarker of greater immune response under immunotherapies, and the number of viral particles present in tumor tissue, which is dependent to the metabolic state of tumoral cells. Herein, we highlight the use of PDTs as an alternative in vitro model to assess patient-specific responses to onco-virotherapy at the early stage of the preclinical phases.

Advances and Applications of Cancer Organoids in Drug Screening and Personalized Medicine.

In recent years, the rapid emergence of 3D organoid technology has garnered significant attention from researchers. These miniature models accurately replicate the structure and function of human tissues and organs, offering more physiologically relevant platforms for cancer research. These intricate 3D structures not only serve as promising models for studying human cancer, but also significantly contribute to the advancement of various potential applications in the field of cancer research. To date, organoids have been efficiently constructed from both normal and malignant tissues originating from patients. Using such bioengineering platforms, simulations of infections and cancer processes, mutations and carcinogenesis can be achieved, and organoid technology is also expected to facilitate drug testing and personalized therapies. In conclusion, regenerative medicine has the potential to enhance organoid technology and current transplantation treatments by utilizing genetically identical healthy organoids as substitutes for irreversibly deteriorating diseased organs.This review explored the evolution of cancer organoids and emphasized the significant role these models play in fundamental research and the advancement of personalized medicine in oncology.

Bridging toxicological properties of environmental chemicals between animals and humans using healthy organoid systems.

The application of organoids derived from animal tissues and human-induced pluripotent stem cells to safety assessments of environmental chemicals has been introduced over the last decade. One of the objectives of this approach is to develop an alternative method for animal toxicological studies, while another is to focus on the local reactions of chemicals in each organ/tissue. One of the most important goals is bridging the toxicological properties of chemicals between animals and humans, which may be compared on a level playing field using healthy organoids derived from both animals and humans in vitro, excluding species difference in the absorption, distribution, metabolism, and excretion properties of chemicals in vivo. An overview of the application of organoid systems to safety assessments of environmental chemicals, including general toxicology, developmental toxicology, carcinogenicity, and mutagenicity, was provided herein, and bridging strategies using both animal and human organoids are proposed as a future perspective.

Analysis of off-tumour toxicities of T-cell-engaging bispecific antibodies via donor-matched intestinal organoids and tumouroids

Predicting the toxicity of cancer immunotherapies preclinically is challenging because models of tumours and healthy organs do not typically fully recapitulate the expression of relevant human antigens. Here we show that patient-derived intestinal organoids and tumouroids supplemented with immune cells can be used to study the on-target off-tumour toxicities of T-cell-engaging bispecific antibodies (TCBs), and to capture clinical toxicities not predicted by conventional tissue-based models as well as inter-patient variabilities in TCB responses. We analysed the mechanisms of T-cell-mediated damage of neoplastic and donor-matched healthy epithelia at a single-cell resolution using multiplexed immunofluorescence. We found that TCBs that target the epithelial cell-adhesion molecule led to apoptosis in healthy organoids in accordance with clinical observations, and that apoptosis is associated with T-cell activation, cytokine release and intra-epithelial T-cell infiltration. Conversely, tumour organoids were more resistant to damage, probably owing to a reduced efficiency of T-cell infiltration within the epithelium. Patient-derived intestinal organoids can aid the study of immune–epithelial interactions as well as the preclinical and clinical development of cancer immunotherapies.

γδ T cell-mediated cytotoxicity against patient-derived healthy and cancer cervical organoids.

Cervical cancer is a leading cause of death among women globally, primarily driven by high-risk papillomaviruses. However, the effectiveness of chemotherapy is limited, underscoring the potential of personalized immunotherapies. Patient-derived organoids, which possess cellular heterogeneity, proper epithelial architecture and functionality, and long-term propagation capabilities offer a promising platform for developing viable strategies. In addition to αβ T cells and natural killer (NK) cells, γδ T cells represent an immune cell population with significant therapeutic potential against both hematologic and solid tumours. To evaluate the efficacy of γδ T cells in cervical cancer treatment, we generated patient-derived healthy and cancer ectocervical organoids. Furthermore, we examined transformed healthy organoids, expressing HPV16 oncogenes E6 and E7. We analysed the effector function of in vitro expanded γδ T cells upon co-culture with organoids. Our findings demonstrated that healthy cervical organoids were less susceptible to γδ T cell-mediated cytotoxicity compared to HPV-transformed organoids and cancerous organoids. To identify the underlying pathways involved in this observed cytotoxicity, we performed bulk-RNA sequencing on the organoid lines, revealing differences in DNA-damage and cell cycle checkpoint pathways, as well as transcription of potential γδ T cell ligands. We validated these results using immunoblotting and flow cytometry. We also demonstrated the involvement of BTN3A1 and BTN2A1, crucial molecules for γδ T cell activation, as well as differential expression of PDL1/CD274 in cancer, E6/E7+ and healthy organoids. Interestingly, we observed a significant reduction in cytotoxicity upon blocking MSH2, a protein involved in DNA mismatch-repair. In summary, we established a co-culture system of γδ T cells with cervical cancer organoids, providing a novel in vitro model to optimize innovative patient-specific immunotherapies for cervical cancer.

Progress of 3D Organoid Technology for Preclinical Investigations: Towards Human In Vitro Models

Review Progress of 3D Organoid Technology for Preclinical Investigations: Towards Human In Vitro Models Yingjuan Liu *, Honglin Xu, Sabu Abraham, Xin Wang, and Bernard D. Keavney* Division of Cardiovascular Sciences, Faculty of Biology, Medicine and Health, University of Manchester, M13 9PT, UK. * Correspondence: yingjuan.liu@manchester.ac.uk (Yingjuan Liu); bernard.keavney@manchester.ac.uk (Bernard D. Keavney) Received: 1 November 2022 Accepted: 24 November 2022 Published: 21 December 2022 Abstract: Currently, with an increased requirement for new therapeutic strategies, preclinical drug testing or screening platforms have rapidly evolved in recent years. In comparison to traditional 2D cell cultures, 3D organoids or spheroids with or without scaffolds improve the microenvironment of in vitro cultures, advancing the in vitro biological observation and enabling mechanistic studies of drug reactions in the human tissue-like environment. 3D organoids and spheroids are straightforward to produce, and relatively uniform in size and shape. This helps to facilitate high throughput screening requirements. Spheroids and organoids have been applied in anti-cancer drug testing, toxicity evaluations, as well as mechanism studies for variable organ systems, including the intestine, liver, pancreas, brain, and heart. Among 3D cultures of spheroids and organoids, ‘tumour spheroids’ formed by dissociated tumour tissues or cancer cell lines are relatively simple in composition and commonly applied to anticancer drug screening. The ‘healthy organoids’ differentiated from hiPSCs/hESCs are more complex in cell composition, distribution, structure and function with higher similarity to in vivo organs, and have found applications in toxicity tests, personalised medicine, and therapeutic and mechanistic studies. In most cases, the multicellular 3D organoids are more resistant and stable in reaction to stimulations or chemicals in vitro , suggesting more accurate modelling of in vivo responses. Here, we review recent progress in human-origin organoid/spheroid systems and their applications in preclinical studies.

The establishment of COPD organoids to study host-pathogen interaction reveals enhanced viral fitness of SARS-CoV-2 in bronchi.

Chronic obstructive pulmonary disease (COPD) is characterised by airflow limitation and infective exacerbations, however, in-vitro model systems for the study of host-pathogen interaction at the individual level are lacking. Here, we describe the establishment of nasopharyngeal and bronchial organoids from healthy individuals and COPD that recapitulate disease at the individual level. In contrast to healthy organoids, goblet cell hyperplasia and reduced ciliary beat frequency were observed in COPD organoids, hallmark features of the disease. Single-cell transcriptomics uncovered evidence for altered cellular differentiation trajectories in COPD organoids. SARS-CoV-2 infection of COPD organoids revealed more productive replication in bronchi, the key site of infection in severe COVID-19. Viral and bacterial exposure of organoids induced greater pro-inflammatory responses in COPD organoids. In summary, we present an organoid model that recapitulates the in vivo physiological lung microenvironment at the individual level and is amenable to the study of host-pathogen interaction and emerging infectious disease.

Abstract A50: IFNλ1 is a marker of DNA damage-triggered STING-signaling in lung cancer that induces immune activation through macrophage stimulation

Abstract Immunotherapy is a fundamental pillar in the treatment of lung cancer but remains inefficient in half of the treated patients. Recent clinical trials showed synergistic effects of combining chemotherapy and immunotherapy for lung cancer, suggesting that increased DNA damage imposed by chemotherapy modulates the tumor microenvironment to aid the efficacy of immunotherapy. But the immunological mechanisms related to this remains to be fully elucidated. The cGAS-STING pathway senses cytosolic DNA introduced by DNA-damaging agents such as chemotherapy. Activation of this pathway and induction of inflammatory cytokines may contribute to better immunotherapy efficacy. In particular, the release of type I IFN is a hallmark for STING pathway activation. However, we also know that IFNλ – a type III IFN – can be induced by STING-signaling. Despite the relevance of IFNλ in controlling inflammatory responses, its contribution in cancer remains unclear. Here, we investigated cGAS-STING expression and signaling in a panel of lung cancer cells. We identified IFNλ1 as an alternative hallmark for cGAS-STING DNA-sensing with higher expression after DNA-stimulation than IFNb in 6 out of 8 cell lines with one cell line having no IFNb expression at all. We then tested IFN induction after chemotherapeutic treatment in three different NSCLC cell lines and saw significant increase in both IFNb and IFNλ1 expression across four different chemotherapeutics, but with a higher fold change for IFNλ1. The induction of both IFNb and IFNλ1 was abolished when STING KO cell lines were treated with doxorubicin pointing to a STING-dependent response. To access the effect of IFNλ1 on macrophages, a prevalent cell type in the tumor microenvironment expressing IFNLR1, we performed RNA-sequencing on four primary human macrophage donors stimulated with IFNλ1. This stimulation led to a significant increase in well-known interferon-stimulated genes including the chemokines CXCL10 and CXCL11. We also explored whether IFNλ1 stimulation led to increased macrophage-dependent activation of autologous CD8+ T-cells. Interestingly, we found increased expression of both IFNg (p = 0.0215, n = 6) and Granzyme B (p = 0.0033, n = 6) measured by flow cytometry and ELISA (p > 0.0001, n = 6 for both). The addition of IFNλ1 during direct co-culture of macrophages and lung tumor organoids furthermore dampened the induction of the signal regulatory protein-a (SIRPa), a phagocytosis-inhibiting receptor, (p = 0.0041, n = 4) otherwise induced by the tumor organoids, but not matched healthy organoids. In support of this, there was an increased activation of CD8+ T-cells measured by IFNg production in an organoid-macrophage-CD8+ T-cell co-culture model. To summarize, we demonstrate that IFNλ1 may be a strong and broad marker of STING activation induced by chemotherapy in NSCLC and that IFNλ1 has the ability to prime a wider immune response by targeting macrophages. Hence, we propose that an IFNλ1 induced immune response has the potential to support and boost the response induced by existing immunotherapies. Citation Format: Kristine R Gammelgaard, Stine H Godsk, Albert G Olivier, Maria Riedel, Silke D Nielsen, Allard van Renterghem, Trine V Larsen, Anders Etzerodt, Emile Voest, Martin R Jakobsen. IFNλ1 is a marker of DNA damage-triggered STING-signaling in lung cancer that induces immune activation through macrophage stimulation [abstract]. In: Proceedings of the AACR Special Conference: Tumor Immunology and Immunotherapy; 2022 Oct 21-24; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2022;10(12 Suppl):Abstract nr A50.

Acoustic Bioprinting of Patient-Derived Organoids for Predicting Cancer Therapy Responses.

Cancer models, which are biologically representative of patient tumors, can predict the treatment responses and help determine the most appropriate cancer treatment for individual patients. Here, a point-of-care testing system called acoustically bioprinted patient-derived microtissues (PDMs) that can model cancer invasion and predict treatment response in individual patients with colorectal cancer (CRC), is reported. The PDMs are composed of patient-derived colorectal tumors and healthy organoids which can be precisely arranged by acoustic bioprinting approach for recapulating primary tissue's architecture. Particularly, these tumor organoids can be efficiently generated and can apprehend histological, genomic, and phenotypical characteristics of primary tumors. Consequently, these PDMs allow physiologically relevant in vitro drug (5-fluorouracil) screens, thus predicting the paired patient's responses to chemotherapy. A correlation between organoid invasion speed and normalized spreading speed of the paired patients is further established. It provides a quantitative indicator to help doctors make better decisions on ultimate anus-preserving operation for extremely low CRC patients. Thus, by combing acoustic bioprinting and organoid cultures, this method may open an avenue to establish complex 3D tissue models for precision and personalized medicine.

Proteomic analysis distinguishes extracellular vesicles produced by cancerous versus healthy pancreatic organoids

Extracellular vesicles (EVs) are produced and released by both healthy and malignant cells and bear markers indicative of ongoing biological processes. In the present study we utilized high resolution flow cytometry to detect EVs in the plasma of patients with pancreatic ductal adenocarcinoma (PDAC) and in the supernatants of PDAC and healthy control (HC) pancreatic organoid cultures. Using ultrafiltration and size exclusion chromatography, PDAC and HC pancreatic organoid EVs were isolated for mass spectrometry analysis. Proteomic and functional protein network analysis showed a striking distinction in that EV proteins profiled in pancreatic cancer organoids were involved in vesicular transport and tumorigenesis while EV proteins in healthy organoids were involved in cellular homeostasis. Thus, the most abundant proteins identified in either case represented non-overlapping cellular programs. Tumor-promoting candidates LAMA5, SDCBP and TENA were consistently upregulated in PDAC EVs. Validation of specific markers for PDAC EVs versus healthy pancreatic EVs will provide the biomarkers and enhanced sensitivity necessary to monitor early disease or disease progression, with or without treatment. Moreover, disease-associated changes in EV protein profiles provide an opportunity to investigate alterations in cellular programming with disease progression.

Modelling Chlamydia and HPV co-infection in patient-derived ectocervix organoids reveals distinct cellular reprogramming

Coinfections with pathogenic microbes continually confront cervical mucosa, yet their implications in pathogenesis remain unclear. Lack of in-vitro models recapitulating cervical epithelium has been a bottleneck to study coinfections. Using patient-derived ectocervical organoids, we systematically modeled individual and coinfection dynamics of Human papillomavirus (HPV)16 E6E7 and Chlamydia, associated with carcinogenesis. The ectocervical stem cells were genetically manipulated to introduce E6E7 oncogenes to mimic HPV16 integration. Organoids from these stem cells develop the characteristics of precancerous lesions while retaining the self-renewal capacity and organize into mature stratified epithelium similar to healthy organoids. HPV16 E6E7 interferes with Chlamydia development and induces persistence. Unique transcriptional and post-translational responses induced by Chlamydia and HPV lead to distinct reprogramming of host cell processes. Strikingly, Chlamydia impedes HPV-induced mechanisms that maintain cellular and genome integrity, including mismatch repair in the stem cells. Together, our study employing organoids demonstrates the hazard of multiple infections and the unique cellular microenvironment they create, potentially contributing to neoplastic progression.

P463 Serum and mucosal Serpin E1 concentration correlates with endoscopic activity in inflammatory bowel disease - potential new activity marker

Abstract Background Inflammatory bowel disease (IBD) is characterized by an unregulated immune response generating unbalance cytokine homeostasis. Analysis of patient-specific cytokine profiles may open new therapeutic targets or identify biomarkers that distinguish responders from non-responders before initiating therapy. Therefore, the aim of the present study was to determine cytokine profile of IBD patients and identify cytokines with predictive potential. Methods Blood and biopsy samples were obtained from 79 clinically active IBD patients and 28 controls without IBD. Inclusion criteria included change of therapy or initiation of new treatment for IBD patients. Organoid culture (OC) was generated from 5 clinically active IBD patients and 5 controls. Cytokine Array was used to analyse cytokine expression patterns. Total protein and mRNA were isolated from biopsies and from OCs. Protein levels were measured by ELISA and gene expression by qRT-PCR in serum, mucosa and in OCs. Results Pro-inflammatory cytokines were not detected in control samples, whereas in IBD biopsies the cytokine profiles enabled the discrimination between inflamed or non-inflamed areas. The mucosal expression of Serpin E1 was detected in all inflamed biopsy samples, whereas it was below the detection limit in healthy subjects. In responders Serpin E1 gene expressions were significantly (p<0.001) lower than in non-responders. On the other hand, we were not able to detect significant changes between responders and non-responders in gene expression of TNF-α, IL-1β, IL-6 and TGF-β. In responders, mucosal Serpin E1 concentration significantly decreased (p<0,05) after the initiation of therapy compared to non-responders. Serum and mucosal Serpin E1 concentrations were significantly higher in patients with endoscopically and clinically active disease compared to inactive (endoscopic: p<0.0001, clinical: p<0.05). Correlation analysis revealed that serum Serpin E1 level correlates with disease activity (p<0.01). In OCs the level and expression of Serpin E1 was lower in healthy organoids compared to OCs generated from inflamed samples. Conclusion Our results suggest that serum and mucosal Serpin E1 expression reflects endoscopic activity in IBD, which could be used to follow-up disease activity and possibly therapeutic response. Organoids mimicked the expression of Serpin E1 in the original biopsies suggesting that OCs can be used to study the effect of Serpin E1 inhibition.

Protease-activated receptor 1 drives and maintains ductal cell fates in the premalignant pancreas and ductal adenocarcinoma.

Pancreatic acinar cells have high plasticity and can transdifferentiate into ductal‐like cells. This acinar‐to‐ductal metaplasia (ADM) contributes to tissue maintenance but may also contribute to the premalignant transformation that can eventually progress to pancreatic ductal adenocarcinoma (PDAC). Macrophages are key players in ADM, and macrophage‐secreted matrix metalloproteinase (MMP)‐9 induces ADM through yet unknown mechanisms. As we previously identified MMP9 as a novel agonist of protease‐activated receptor 1 (PAR1), a receptor that is known to orchestrate the cross‐talk between macrophages and tumor cells in PDAC, we here assessed the contribution of PAR1 to pancreatic cell fates. We found that genetic deficiency for PAR1 increases acinar gene expression programs in the healthy pancreas and that PAR1 deficiency limits ductal transdifferentiation in experimental systems for ADM. Moreover, PAR1 silencing in PDAC cells increases acinar marker expression. Changes in PDAC cell lines were associated with a downregulation of known Myc‐target genes, and Myc inhibition mimics PAR1 deficiency in enhancing acinar programs in healthy organoids and PDAC cells. Overall, we identify the PAR1‐Myc axis as a driver of ductal cell fates in premalignant pancreas and PDAC. Moreover, we show that cellular plasticity is not unique to acinar cells and that ductal regeneration into acinar‐like cells is possible even in the context of oncogenic KRAS activation.

Organoids of Human Endometrium: A Powerful In Vitro Model for the Endometrium-Embryo Cross-Talk at the Implantation Site.

Embryo implantation has been defined as the “black box” of human reproduction. Most of the knowledge on mechanisms underlining this process derives from animal models, but they cannot always be translated to humans. Therefore, the development of an in vitro/ex vivo model recapitulating as closely and precisely as possible the fundamental functional features of the human endometrial tissue is very much desirable. Here, we have validated endometrial organoids as a suitable 3D-model to studying epithelial endometrial interface for embryo implantation. Transmission and scanning electron microscopy analyses showed that organoids preserve the glandular organization and cell ultrastructural characteristics. They also retain the responsiveness to hormonal treatment specific to the corresponding phase of the menstrual cycle, mimicking the in vivo glandular-like aspect and functions. Noteworthy, organoids mirroring the early secretive phase show the development of pinopodes, large cytoplasmic apical protrusions of the epithelial cells, traditionally considered as reliable key features of the implantation window. Moreover, organoids express glycodelin A (GdA), a cycle-dependent marker of the endometrial receptivity, with its quantitative and qualitative features accounting well for the profile detected in the endometrium in vivo. Accordingly, organoids deriving from the eutopic endometrium of women with endometriosis show a GdA glycosylation pattern significantly different from healthy organoids, confirming our prior data on endometrial tissues. The present results strongly support the idea that organoids may closely recapitulate the molecular and functional characteristics of their cells/tissue of origin.

Harnessing The Biology of Intestinal Organoids To Accelerate Drug Discovery in Inflammatory Bowel Disease: A One Health Approach

Rationale and SignificanceCanine inflammatory bowel disease (IBD) refers to a group of chronic gastrointestinal (GI) disorders of unknown cause and pathogenesis which mimic the spectrum of chronic enteropathies in human patients with IBD. There is currently no cure for IBD and many therapeutic interventions developed over the past 3 decades have consistently failed to demonstrate evidence of efficacy in clinical trials. There is, therefore, a critical need to develop robust drug screening tools to accelerate the availability of effective and safe therapeutic strategies for management of IBD. With the aim of modeling spontaneous GI disease in dogs and humans, intestinal stem cell (ISC)‐derived organoids are emerging as a promising ex vivo tool in the study of IBD pathogenesis. Our working testable hypothesis is that canine organoids will faithfully reproduce structural and functional changes of the intestinal epithelium in dogs with IBD, which will enable more accurate prediction of therapeutic drug efficacy and safety. Long‐term, this model will provide critical information for the design of canine clinical trials, and ultimately generate preclinical data for similar studies in humans with IBD. Altogether, we therefore expect to contribute to decreased morbidity/mortality, and improved quality of life in dogs and patients with IBD.MethodsISCs isolated from endoscopic biopsies of two healthy dogs and two dogs with active IBD were differentiated into intestinal organoids. Ileal organoids and matching tissues were probed by RNA in situ hybridization and immunohistochemistry for phenotypic changes in IBD. A panel of six phenotypic markers identified different epithelial cell lineages (LGR5+: intestinal stem cell, ALP: enterocyte, PAS: goblet cell, NeuroG3: enteroendocrine cell), epithelial barrier integrity (ZO‐1) and cell proliferation (Ki‐67). Functional features of IBD organoids were investigated by cystic fibrosis transmembrane conductance regulator (CFTR) organoid swelling assay to measure Cl− channel‐water conductance.ResultsOur preliminary findings suggest that IBD organoids exhibit increased cell proliferation, intestinal stem cells, enteroendocrine cells, and expression of tight junction protein as compared to healthy organoids. Similar trends were observed when comparing phenotypic marker expression in original intestinal tissues. Forskolin significantly (P < 0.05) increased swelling of IBD organoids after 1 and 4 hr vs. controls indicating functional CFTR in organoids.ConclusionOverall, our data show that ileal organoids derived from dogs with IBD recapitulate both the phenotypic and physiological features of diseased tissue compared to healthy tissue, demonstrating its utility as an ex vivo model for investigating mechanism and therapeutic strategies in IBD. These preliminary results will be further validated by additional intestinal biopsies from 14 dogs with IBD in an ongoing clinical trials.Support or Funding Information Research Support: IG BiosciencesPreliminary phenotypic characterization of IBD organoids.(Left) Representative RNA ISH of ALP and NeuroG3 staining in ileal organoids at x40 magnification (ratio of total area). Scale bar: 50 μm. (Right) Summary box plots of ALP and PAS expression in IBD vs. Control (CTR) organoids. Data from 10 distinct microscopic fields were aggregated per dog.Figure 1

Nascent Lung Organoids Reveal Epithelium- and Bone Morphogenetic Protein-mediated Suppression of Fibroblast Activation.

Reciprocal epithelial-mesenchymal interactions are pivotal in lung development, homeostasis, injury, and repair. Organoids have been used to investigate such interactions, but with a major focus on epithelial responses to mesenchyme and less attention to epithelial effects on mesenchyme. In the present study, we used nascent organoids composed of human and mouse lung epithelial and mesenchymal cells to demonstrate that healthy lung epithelium dramatically represses transcriptional, contractile, and matrix synthetic functions of lung fibroblasts. Repression of fibroblast activation requires signaling via the bone morphogenetic protein (BMP) pathway. BMP signaling is diminished after epithelial injury in vitro and in vivo, and exogenous BMP4 restores fibroblast repression in injured organoids. In contrast, inhibition of BMP signaling in healthy organoids is sufficient to derepress fibroblast matrix synthetic function. Our results reveal potent repression of fibroblast activation by healthy lung epithelium and a novel mechanism by which epithelial loss or injury is intrinsically coupled to mesenchymal activation via loss of repressive BMP signaling.

Molecular signature of interleukin-22 in colon carcinoma cells and organoid models

Interleukin (IL)-22 activates STAT (signal transducer and activator of transcription) 3 and antiapoptotic and proproliferative pathways; but beyond this, the molecular mechanisms by which IL-22 promotes carcinogenesis are poorly understood. Characterizing the molecular signature of IL-22 in human DLD-1 colon carcinoma cells, we observed increased expression of 26 genes, including NNMT (nicotinamide N-methyltransferase, ≤10-fold) and CEA (carcinoembryonic antigen, ≤7-fold), both known to promote intestinal carcinogenesis. ERP27 (endoplasmic reticulum protein-27, function unknown, ≤5-fold) and the proinflammatory ICAM1 (intercellular adhesion molecule-1, ≤4-fold) were also increased. The effect on CEA was partly STAT3-mediated, as STAT3-silencing reduced IL-22-induced CEA by ≤56%. Silencing of CEA or NNMT inhibited IL-22-induced proliferation/migration of DLD-1, Caco-2, and SW480 colon carcinoma cells. To validate these results in primary tissues, we assessed IL-22-induced gene expression in organoids from human healthy colon and colon cancer patients, and from normal mouse small intestine and colon. Gene regulation by IL-22 was similar in DLD-1 cells and human and mouse healthy organoids. CEA was an exception with no induction by IL-22 in organoids, indicating the 3-dimensional organization of the tissue may produce signals absent in 2D cell culture. Importantly, augmentation of NNMT was 5-14-fold greater in human cancerous compared to normal organoids, supporting a role for NNMT in IL-22-mediated colon carcinogenesis. Thus, NNMT and CEA emerge as mediators of the tumor-promoting effects of IL-22 in the intestine. These data advance our understanding of the multifaceted role of IL-22 in the gut and suggest the IL-22 pathway may represent a therapeutic target in colon cancer.

Microfluidic-Based Cell-Embedded Microgels Using Nonfluorinated Oil as a Model for the Gastrointestinal Niche.

Microfluidic-based cell encapsulation has promising potential in therapeutic applications. It also provides a unique approach for studying cellular dynamics and interactions, though this concept has not yet been fully explored. No in vitro model currently exists that allows us to study the interaction between crypt cells and Peyer's patch immune cells because of the difficulty in recreating, with sufficient control, the two different microenvironments in the intestine in which these cell types belong. However, we demonstrate that a microfluidic technique is able to provide such precise control and that these cells can proliferate inside microgels. Current microfluidic-based cell microencapsulation techniques primarily use fluorinated oils. Herein, we study the feasibility and biocompatibility of different nonfluorinated oils for application in gastrointestinal cell encapsulation and further introduce a model for studying intercellular chemical interactions with this approach. Our results demonstrate that cell viability is more affected by the solidification and purification processes that occur after droplet formation rather than the oil type used for the carrier phase. Specifically, a shorter polymer cross-linking time and consequently lower cell exposure to the harsh environment (e.g., acidic pH) results in a high cell viability of over 90% within the protected microgels. Using nonfluorinated oils, we propose a model system demonstrating the interplay between crypt and Peyer's patch cells using this microfluidic approach to separately encapsulate the cells inside distinct alginate/gelatin microgels, which allow for intercellular chemical communication. We observed that the coculture of crypt cells alongside Peyer's patch immune cells improves the growth of healthy organoids inside these microgels, which contain both differentiated and undifferentiated cells over 21 days of coculture. These results indicate the possibility of using droplet-based microfluidics for culturing organoids to expand their applicability in clinical research.

Morphological alterations of cultured human colorectal matched tumour and healthy organoids.

Organoids have extensive applications in many fields ranging from modelling human development and disease, personalised medicine, drug screening, etc. Moreover, in the last few years, several studies have evaluated the capacity of organoids as transplantation sources for therapeutic approaches and regenerative medicine. Nevertheless, depending on the origin of the cells and anatomical complications, an organoid transplant may make tissue regeneration difficult. However, some essential aspects of organoids including the morphological alterations and the growth pattern of the matched tumour and their healthy derived organoids have received less attention. Therefore, the current work focused on culturing matched healthy and tumour organoids from the same patient with colorectal cancer (CRC) and assessed their timed growth and structural differences on a daily basis. The healthy organoids underwent proliferation and branching morphogenesis, while the tumour organoids did not follow the same pattern, and the majority of them developed cystic structures instead. However, the number and size of tumour organoids were different from one patient to another. The differential morphological changes of the healthy versus human colonic tumour organoids likely linked to distinct molecular and cellular events during each day. Thus, while their specific structural features provide valuable in vitro models to study various aspects of human intestinal/colon tissue homeostasis and CRC which avoid or replace the use of animals in research, this model may also hold a great promise for the transplantation and regenerative medicine applications.