Development of an advanced primary human in vitro model of the small intestine

Intestinal in vitro models are valuable tools in drug discovery and infection research. Despite several advantages, the standard cell line-based Transwell® models based for example on colonic epithelial Caco-2 cells, lack the cellular complexity and transport activity associated with native small intestinal tissue. An additional experimental set-back arises from the most commonly used synthetic membranes, on which the cells are routinely cultured. These can lead to an additional barrier activity during in vitro testing. To overcome these limitations, we developed an alternative primary human small intestinal tissue model. This novel approach combines previously established gut organoid technology with a natural extracellular matrix (ECM) based on porcine small intestinal scaffold (SIS). Intestinal crypts from healthy human small intestine were expanded as gut organoids and seeded as single cells on SIS in a standardized Transwell-like setting. After only 7 days on the ECM scaffold, the primary cells formed an epithelial barrier while a subpopulation differentiated into intestinal specific cell types such as mucus-producing goblet cells or hormone-secreting enteroendocrine cells. Furthermore, we tested the influence of subepithelial fibroblasts and dynamic culture conditions on epithelial barrier function. The barrier integrity was stabilized by coculture in the presence of gut-derived fibroblasts. Compared to static or dynamic culture on an orbital shaker, dynamic culture in a defined perfusion bioreactor had an additional significant impact on epithelial cell differentiation, indicated by high prismatic cell morphology and upregulation of CYP3A4 enzyme and Mdr1 transporter activity. In summary, more physiological tissue models as presented in our study might be useful tools in preclinical research and development

Growth Retardation, Loss of Desmosomal Adhesion, and Impaired Tight Junction Function Identify a Unique Role of Plakophilin 1 In Vivo

Desmosomes mediate strong intercellular adhesion through desmosomal cadherins that interact with intracellular linker proteins including plakophilins (PKPs) 1-3 to anchor the intermediate filaments. PKPs show overlapping but distinct expression patterns in the epidermis. So far, the contribution of individual PKPs in differentially regulating desmosome function is incompletely understood. To resolve the role of PKP1 we ablated the PKP1 gene. Here, we report that PKP1(-/-) mice were born at the expected mendelian ratio with reduced birth weight, but they otherwise appeared normal immediately after birth. However, their condition rapidly declined, and the mice died within 24 hours, developing fragile skin with lesions in the absence of obvious mechanical trauma. This was accompanied by sparse and small desmosomes. Newborn PKP1(-/-) mice showed disturbed tight junctions with an impaired inside-out barrier, whereas the outside-in barrier was unaffected. Keratinocytes isolated from these mice showed strongly reduced intercellular cohesion, delayed tight junction formation, and reduced transepithelial resistance and reduced proliferation rates. Our study shows a nonredundant and essential role of PKP1 in desmosome and tight junction function and supports a role of PKP1 in growth control, a function that is crucial in wound healing and epidermal carcinogenesis