Project description:Modulation of mucus production by the human endo- and ecto-cervical epithelium by steroid hormones and associated interactions with commensal microbiome play a central role in the physiology and pathophysiology of the female reproductive tract. However, most of our knowledge about these interactions is based on results from animal studies or in vitro models that fail to faithfully mimic the mucosal environment of the human cervix. Here we describe microfluidic organ-on-a-chip (Organ Chip) models of the human cervical mucosa that recreate the cervical epithelial-stromal interface with a functional epithelial barrier and produce abundant mucus that has compositional, biophysical, and hormone-responsive properties similar to the living cervix. Application of continuous fluid flow to chips lined primary human cervical epithelial cells from a commercial source that contained a mixture of primary human ecto- and endo-cervical epithelial cells promoted preferential expression of the ecto-cervical phenotype, whereas use of periodic flow including periods of stasis induced endo-cervical specialization. When the periodic flow Cervix Chips were co-cultured with living Lactobacillus crispatus and Gardnerella vaginalis bacterial communities to respectively mimic the effects of human host interactions with optimal (healthy) or non-optimal (dysbiotic) microbiome associated with an ascending infection in the female reproductive tract, significant differences in tissue innate immune responses, barrier function, cell viability and protein profile, and mucus composition were detected reminiscent of those observed in vivo. Thus, these Organ Chip models of human cervix provide a physiologically relevant experimental in vitro model to study cervical mucus physiology and its role in human host-microbiome interactions as well as a potential preclinical testbed for development of therapeutic interventions to enhance women's health.

Project description:Modulation of mucus production by the human ecto- and endo-cervical epithelium by steroid hormones and associated interactions with commensal microbiome play a central role in the physiology and pathophysiology of the female reproductive tract. Here, we show that in a human organ-on-a-chip model of cervix (Cervix Chip), use of continuous fluid flow promotes ecto-cervical differentiation, whereas use of periodic flow including periods of stasis stimulated endo-cervical specialization. Continuous flow exhibited significant upregulation of genes associated with ectocervical epithelial phenotype whereas the same cells cultured in the same medium under periodic flow or under static conditions in Transwell inserts upregulated genes more closely associated with the endocervical epithelial phenotype. Similar results with minor differences were obtained using epithelial cells isolated from three donors each from a different ethnic background (African American, Hispanic, and Caucasian).

Project description:To collect human tissue, blood, and fecal samples from patients suffering from Inflammatory Bowel Disease and Colorectal Cancer. The samples will be used to establish biomimetic human organ-on-a-chip technology, as well as study the role of the microbiome in the pathogenesis in human gastrointestinal diseases.

Project description:Cervical mucus is a viscous fluid functioning as a uterine cervix plug. It is formed and produced by cervical glands located in the cervix. During ovulation, cervical mucus starts to become less viscous, which is a good window for non-invasive sampling. Our study focuses on the proteomic characterization of cervical mucus, which may thus act as a non-invasively acquired source of biomarkers for diseases and physiological conditions of the female genital tract. Our study aimed at two aims - the first is to optimize a proteomic workflow of cervical mucus processing. The second aim is to assess differences in the proteomic composition of cervical mucus in natural ovulatory cycles and IVF cycles with controlled ovarian hyperstimulation. The sampling was done in cooperation with women undergoing intrauterine insemination in a natural ovulatory cycle and women undergoing controlled ovarian hyperstimulation for IVF. The optimization of proteomic workflow including an analysis on an Orbitrap mass spectrometer was performed. The results revealed the protein composition and the differences of the cervical mucus between natural and stimulated uterus.

Project description:Candida albicans is the most prevalent fungal pathogen of humans, causing a variety of diseases ranging from superficial mucosal infections to deep-seated systemic infections. Mucus, the gel that coats all wet epithelial surfaces, accommodates Candida albicans as part of the regular microbiome where C. albicans resides asymptomatically in healthy humans. Through a series of in vitro experiments combined with genome-wide transcriptional profiling, we show that mucin biopolymers, the main gel-forming constituents of mucus, induce a new oval-shaped morphology in C. albicans in which a range of genes related to adhesion, filamentation, and biofilm formation are down-regulated. We also show that corresponding phenotypes are suppressed, rendering Candida incapable of forming biofilms on a range of different synthetic surfaces and human epithelial cells. Our data suggests that mucins can manipulate Candida physiology and we hypothesize that they are key regulators for retaining Candida in the host-compatible, commensal state. 3 biological replicates grown in log phase in the presence and absence of mucin for 8 hours. Experiments were performed using RPMI 1640 (Gibco 31800-089) buffered with 165mM MOPS and supplemented with 0.2% NaHCO3 and 2% glucose with and without 0.5% mucin.

Project description:Here we describe a method for fabricating a primary human Small Intestine-on-a-Chip (Intestine Chip) containing epithelial cells isolated from healthy regions of intestinal biopsies. The primary epithelial cells are expanded as 3D organoids, dissociated, and cultured on a porous membrane within a microfluidic device with human intestinal microvascular endothelium cultured in a parallel microchannel under flow and cyclic deformation. In the Intestine Chip, the epithelium forms villi-like projections lined by polarized epithelial cells that undergo multi-lineage differentiation similar to that of intestinal organoids, however, these cells expose their apical surfaces to an open lumen and interface with endothelium. Transcriptomic analysis also indicates that the Intestine Chip more closely mimics whole human duodenum in vivo when compared to the duodenal organoids used to create the chips. Because fluids flowing through the lumen of the Intestine Chip can be collected continuously, sequential analysis of fluid samples can be used to quantify nutrient digestion, mucus secretion and establishment of intestinal barrier function over a period of multiple days in vitro. The Intestine Chip therefore may be useful as a research tool for applications where normal intestinal function is crucial, including studies of metabolism, nutrition, infection, and drug pharmacokinetics, as well as personalized medicine.

Project description:H3K4me3 ChIP chips

Project description:H3K36Ac ChIP chips

Project description:In the intestine, B. cereus comes in contact with the epithelial mucus layer. To investigate the overall response to that contact, total transcriptome analyses were performed using porcine gastric mucin (PGM), which is a commonly applied model for mucus interactions. Differential regulation of genes encoding enterotoxins and further virulence factors was of special interest.

Project description:Candida albicans is the most prevalent fungal pathogen of humans, causing a variety of diseases ranging from superficial mucosal infections to deep-seated systemic infections. Mucus, the gel that coats all wet epithelial surfaces, accommodates Candida albicans as part of the regular microbiome where C. albicans resides asymptomatically in healthy humans. Through a series of in vitro experiments combined with genome-wide transcriptional profiling, we show that mucin biopolymers, the main gel-forming constituents of mucus, induce a new oval-shaped morphology in C. albicans in which a range of genes related to adhesion, filamentation, and biofilm formation are down-regulated. We also show that corresponding phenotypes are suppressed, rendering Candida incapable of forming biofilms on a range of different synthetic surfaces and human epithelial cells. Our data suggests that mucins can manipulate Candida physiology and we hypothesize that they are key regulators for retaining Candida in the host-compatible, commensal state.