Title: Organoid vs In Vivo Mouse Model: Which is Better Research Tool to Understand the Biologic Mechanisms of Intestinal Epithelium?
Abstract: See rebuttal on page 193. See counterpoint on page 1. See rebuttal on page 193. See counterpoint on page 1. The mammalian intestinal epithelium consists of the glandular histologic unit, crypts. Crypts have a remarkable self-renewing capacity, and the entire unit is constantly regenerated within several days. The self-renewing capacity is instrumental for homeostasis and critical after intestinal injury, when new crypts must be formed from a landscape of denuded mucosa. Mouse models have provided an understanding of how crypts regenerate and which factors regulate the self-renewal of crypts. In the 1970s, Leblond, Cheng, and Bjerknes revealed the self-renewing dynamics of mouse intestinal crypts and proposed intestinal stem cells (ISCs) responsible for crypt self-renewal.1Cheng H. Leblond C.P. Origin, differentiation and renewal of the four main epithelial cell types in the mouse small intestine. V. Unitarian theory of the origin of the four epithelial cell types.Am J Anat. 1974; 141: 537-561Crossref PubMed Scopus (1087) Google Scholar,2Bjerknes M. Cheng H. Clonal analysis of mouse intestinal epithelial progenitors.Gastroenterology. 1999; 116: 7-14Abstract Full Text Full Text PDF PubMed Scopus (341) Google Scholar However, ISCs were not formally identified until the emergence of a lineage tracing system using mouse genetic models, when Barker and Clevers demonstrated the long-term self-renewing potential and multidifferentiation capacity of Lgr5+ ISCs.3Barker N. van Es J.H. Kuipers J. Kujala P. van den Born M. Cozijnsen M. Haegbarth A. Korving J. Begthel H. Peters P. Clevers H. Identification of stem cells in small intestine and colon by marker gene Lgr5.Nature. 2007; 449: 1003-1007Crossref PubMed Scopus (3716) Google Scholar The Lgr5 expression indicated the critical role of Wnt signaling in the maintenance of ISCs. Moreover, this finding underscored that microenvironmental factors, referred to as niche factors, could be used to support ISCs. Using a combination of niche factors including EGF (growth factor), Noggin (Bmp inhibitor), and R-spondin (Wnt signaling activator), Sato and Clevers developed an organoid culture system for mouse small intestinal epithelium.4Sato T. Vries R.G. Snippert H.J. van de Wetering M. Barker N. Stange D.E. van Es J.H. Abo A. Kujala P. Peters P.J. Clevers H. Single Lgr5 stem cells build crypt-villus structures in vitro without a mesenchymal niche.Nature. 2009; 459: 262-265Crossref PubMed Scopus (3744) Google Scholar Ever since the establishment of the organoid culture system, mouse genetic models and organoids have been 2 major tools to study ISCs and crypt development. Here, we discuss the advantages of the organoid culture system over mouse genetic models (Table 1).Table 1Characteristics of Organoid vs Mouse ModelsOrganoidsIn vivo mouse modelsSpeciesHuman, mouse, rat, pig, and so forthMouseDerivationHealthy/diseased tissue–derived or pluripotent-stem cell–derivedWild-type or genetic engineering mouse modelIn vitro+++++aMouse organoids can also be established from mouse models.In vivo- ∼ +bTransplantation enables in vivo assessment.+++Cost+ ∼ ++++Technical difficultyIn vitro: +In vivo: ++++ ∼ ++Throughput+++- ∼ +Genetic manipulation<1 mo>3–6 moHuman genetic relevance+-Relevant microenvironment- ∼ +cCoculture system or transplantation recapitulate the microenvironment.+++RegulationEthical committee approvalAnimal committee approvala Mouse organoids can also be established from mouse models.b Transplantation enables in vivo assessment.c Coculture system or transplantation recapitulate the microenvironment. Open table in a new tab The first, and most obvious, advantage of organoids is the applicability to the human intestinal epithelium. Although mouse intestinal epithelium shares major biologic and histologic traits with humans, recent studies highlighted several differences. Human and mouse organoids differ in their dependence on niche factors, suggesting fundamental differences in the molecular mechanisms of self-renewal in mouse versus human ISCs.5Sato T. Stange D.E. Ferrante M. Vries R.G.J. Van Es J.H. Van den Brink S. Van Houdt W.J. Pronk A. Van Gorp J. Siersema P.D. Clevers H. Long-term expansion of epithelial organoids from human colon, adenoma, adenocarcinoma, and Barrett's epithelium.Gastroenterology. 2011; 141: 1762-1772Abstract Full Text Full Text PDF PubMed Scopus (1869) Google Scholar There are unique epithelial cell types found in humans but not in mouse, such as motilin+ enteroendocrine cells and BEST4+/OTOP2+ cells,6Fujii M. Matano M. Toshimitsu K. Takano A. Mikami Y. Nishikoti Sugimoto S. Sato T. Human intestinal organoids maintain self-renewal capacity and cellular diversity in niche-inspired culture condition.Cell Stem Cell. 2018; 23: 787-793Abstract Full Text Full Text PDF PubMed Scopus (162) Google Scholar,7Parikh K. Antanaviciute A. Fawkner-Corbett D. Marta J. Aulicino A. Lagerholm C. Davis S. Kinchen J. Chen H.H. Alham N.K. Ashley N. Johnson E. Hublitz P. Bao L. Lukomska J. Andev R.S. Björklund E. Kessler B.M. Fischer R. Goldin R. Koohy H. Simmons A. Colonic epithelial cell diversity in health and inflammatory bowel disease.Nature. 2019; 567: 49-55Crossref PubMed Scopus (199) Google Scholar which may suggest different constraints during crypt development and regeneration. Organoids regenerated these cell types and might be able to reveal their as-yet-unknown function. Moreover, the effects of environmental signals, such as certain human microbes or the human diet, can be species-specific; to understand their roles in crypt development it is essential to use species-matched host cells, something that is readily achieved with organoids. The second advantage is the throughput of the experimental platform. Both mouse genetic models and organoids provide causal evidence of pharmaceutical and genetic targeting. However, the throughput of organoid-based assays outweighs that of mouse models. Organoids can be plated in large multiplex arrays for drug screening or CRISPR-Cas9 editing. Such an increase of throughput in mouse models would raise miscellaneous issues, such as animal ethics, labor-intensive procedures, and mouse housing costs. Imaging-based screening of organoids has led to the discovery of key molecules regulating crypt development.8Lukonin I. Serra D. Challet Meylan L. Volkmann K. Baaten J. Zhao R. Meeusen S. Colman K. Maurer F. Stadler M.B. Jenkins J. Liberali P. Phenotypic landscape of intestinal organoid regeneration.Nature. 2020; 586: 275-280Crossref PubMed Scopus (65) Google Scholar The advance of organoid-based imaging analysis by overcoming phototoxicity will drive further understanding of the crypt self-renewing mechanism. In addition, the potential differences between homeostatic state and regeneration phase should be taken into consideration because it is generally believed that early organoid growth primarily models regeneration. Third, organoids provide a tractable technical platform to understand spatiotemporal regulation of crypt morphogenesis. Neonatal intestines start to form a crypt-villus axis along with the initiation of Paneth cell differentiation. After the initial maturation, adult mouse intestines undergo homeostatic regeneration, in which not only are individual cells constantly replaced, but also the total number of crypt units are maintained through a fluid combination of whole-crypt fission or fusion events. Although the dynamics of crypt development could, in principle, be captured by a high-end intravital imaging system, the detailed mechanisms remain elusive because of a lack of a manipulatable experimental platform. Organoid studies will help to bridge this gap. Budding events in organoids are broadly similar to crypt fission, an important mechanism through which crypts regenerate in vivo. Because budding occurs frequently and rapidly in organoids, this process can be interrogated using traditional microscopy. In addition to specific changes in the local density of stem and Paneth cells,9Langlands A.J. Almet A.A. Appleton P.L. Newton I.P. Osborne J.M. Näthke I.S. Paneth cell-rich regions separated by a cluster of Lgr5+ cells initiate crypt fission in the intestinal stem cell niche.PLoS Biol. 2016; 14e1002491Crossref PubMed Scopus (46) Google Scholar factors that drive budding include mechanical force.10Tallapragada N.P. Cambra H.M. Wald T. Jalbert S.K. Abraham D.M. Klein O.D. Klein A.M. Inflation-collapse dynamics drive patterning and morphogenesis in intestinal organoids.Cell Stem Cell. 2021; Abstract Full Text Full Text PDF PubMed Scopus (13) Google Scholar Thus, organoid-based studies enable high spatiotemporal resolution and perturbation of crypt-villus development. Although intestinal organoids derived from adult human tissues emulate the diversity of in vivo intestinal epithelial cell types, it is true that they lack vascularization, neural innervation, fluid flow, interactions with other cells (eg, endothelial, mesenchymal, and immune cells), and intestinal luminal contents. To understand these complicated interactions between epithelium and nonepithelial cells, mouse models are currently the best experimental platform. However, in this specific regard, the gap between mouse models and organoids may be quickly closing. There has been some success in the coculture of organoids with other cell types (eg, endothelial cells11Palikuqi B. Nguyen D.-H.T. Li G. Schreiner R. Pellegata A.F. Liu Y. Redmond D. Geng F. Lin Y. Gómez-Salinero J.M. Yokoyama M. Zumbo P. Zhang T. Kunar B. Witherspoon M. Han T. Tedeshi A.M. Scottoni F. Lipkin S.M. Dow L. Elemento O. Xiang J.Z. Shido K. Spence J.R. Zhou Q.J. Schwartz R.E. De Coppi P. Rabbany S.Y. Rafii S. Adaptable haemodynamic endothelial cells for organogenesis and tumorigenesis.Nature. 2020; 585: 426-432Crossref PubMed Scopus (56) Google Scholar). However, it remains undetermined to what extent these coculture systems recapitulate the heterocellular interactions in vivo, and further optimization is required to tackle this challenge through the development of advanced culture platforms. As an alternative to the coculture system, organoid transplantation could provide an opportunity for the assessment of heterocellular interactions. We and others have established an organoid transplantation system to investigate epithelium-stromal interaction in vivo.12Sugimoto S. Ohta Y. Fujii M. Mantano M. Shimokawa M. Nanki K. Date S. Nishikori S. Nakazato Y. Nakamura T. Kanai T. Sato T. Reconstruction of the human colon epithelium in vivo.Cell Stem Cell. 2018; 22: 171-176Abstract Full Text Full Text PDF PubMed Scopus (94) Google Scholar On the heterotopic interaction between small intestinal epithelium and colonic stroma, the engineered colon formed crypt-villi structures and lacteals, unique histologic features found in the small intestine, and rescued short bowel syndrome model in rats.13Sugimoto S. Kobayashi E. Fujii M. Ohta Y. Arai K. Matano M. Ishikawa K. Miyamoto K. Toshimitsu K. Takahashi S. Nanki K. Hakamata Y. Kanai T. Sato T. An organoid-based organ-repurposing approach to treat short bowel syndrome.Nature. 2021; 592: 99-104PubMed Google Scholar This result suggested that the heterocellular interaction instructs intricate tissue morphogenesis, findings that could be translated to regenerative medicine. The transplantation system can also be used to investigate the human intestinal epithelium in a tissue context. Interestingly, orthotopically transplanted human colonic organoids formed crypts that more closely resembled human colonic crypts than the surrounding mouse crypts.12Sugimoto S. Ohta Y. Fujii M. Mantano M. Shimokawa M. Nanki K. Date S. Nishikori S. Nakazato Y. Nakamura T. Kanai T. Sato T. Reconstruction of the human colon epithelium in vivo.Cell Stem Cell. 2018; 22: 171-176Abstract Full Text Full Text PDF PubMed Scopus (94) Google Scholar Furthermore, CRISPR-Cas9-mediated genome editing enabled genetic studies of human intestinal epithelium in vivo, such as genetic lineage tracing of human LGR5+ ISCs and precise disease modeling of human colon tumorigenesis.12Sugimoto S. Ohta Y. Fujii M. Mantano M. Shimokawa M. Nanki K. Date S. Nishikori S. Nakazato Y. Nakamura T. Kanai T. Sato T. Reconstruction of the human colon epithelium in vivo.Cell Stem Cell. 2018; 22: 171-176Abstract Full Text Full Text PDF PubMed Scopus (94) Google Scholar,14Kawasaki K. Fujii M. Sugimoto S. Ishikawa K. Matano M. Ohta Toshimitsu K. Takahashi S. Hosoe N. Sekine S. Kanai T. Sato T. Chromosome engineering of human colon-derived organoids to develop a model of traditional serrated adenoma.Gastroenterology. 2020; 158: 638-651Abstract Full Text Full Text PDF PubMed Scopus (32) Google Scholar Therefore, the transplantation system offers a complementary approach to understand stem cell function and crypt morphogenesis of organoids in a tissue context. In conclusion, organoids are the best research tool to study the biology of human intestinal epithelium and provide a complementary and alternative approach to the understanding of mouse intestinal physiology. Rebuttal to: Organoid vs Mouse Model: Which is a Better Research Tool to Understand the Biologic Mechanisms of Intestinal Epithelium?Cellular and Molecular Gastroenterology and HepatologyVol. 13Issue 1PreviewThere are obvious pros and cons when choosing an in vitro and in vivo model for addressing biologic questions. This has been clearly outlined in both ours and the commentary by Drs Sugimoto and Sato. Evidently, one should always strive to take advantage of a combination of different models to address research questions in a comprehensive manner and ascertain that observations are physiologically relevant. Full-Text PDF Open Access