Project description:We previously established long-term 3D organoid culture systems for several murine tissues (intestine, stomach, pancreas and liver) as well as human intestine and pancreas. Here, we describe culture conditions to generate long-term 3D culture from human gastric stem cells. The technology can be applied to study the epithelial response to infection with Helicobacter pylori. Human gastric cultures can expand indefinitely in 3D Matrigel. Cultures can be generated from normal tissue, from single sorted stem cells, or from tumor tissue. Organoids maintain many characteristics of the respective tissue in terms of histology, marker expression and euploidy. Organoids from normal tissue express markers of four lineages of the stomach and self-organize in gland and pit-domains. They can be directed to specifically express either lineages of the gastric gland, or the gastric pit by addition of Nicotinamide and withdrawal of Wnt. While gastric pit lineages react marginally to bacterial infection, gastric gland lineages mount a strong inflammatory response. The gastric culture system provides a unique tool to study gastric pathologies. We generated 2 sets of experiments. The first set contains organoids in 4 conditions: (1) organoids in expansion condition ENRWFGNiTi ("gland-type organoids") from 3 donors, (2) organoids as in 1 but differentiated for 4 days in differentiation condition ENR_FGNiTi ("pit'type organoids"), (3) organoids as in 1 but infected with Helicobacter pylori strain P12 MOI 50 for 2 h, (4) organoids as in 2 but infected as in 3. All 4 conditions were tested on the same organoid line in parallel. This experiment was conducted independently with cultures from 3 different donors. The second set of experiments compares freshly isolated glands with organoids. Samples from 2 patients were analyzed. Each patient received a total gastrectomy. From each patient, glands from corpus region or pyloric antrum were isolated. From each isolation, one aliquod was stored for microarray analysis and one aliquod used to generate organoids. Organoids and glands were subsequently lysed and analyzed in parallel.

Project description:Colonization by H. pylori is associated with a wide range of gastric diseases, ranging from superficial gastritis to more severe pathologies, including intestinal metaplasia and adenocarcinoma. The interplay of the host response and the pathogen affect the outcome of disease. One major component of the mucosal response to H. pylori is the activation of a strong, but inefficient immune response that fails to control the infection and frequently causes tissue damage. We have shown that polyamines can regulate H. pylori-induced inflammation. Chemical inhibition of ornithine decarboxylase (ODC), which generates putrescine from L-ornithine, reduces gastritis in mice and adenocarcinoma incidence in gerbils infected with H. pylori. However, we have also demonstrated that Odc deletion in myeloid cells enhances M1 macrophage activation and gastritis. Here we used a genetic approach to assess the specific role of gastric epithelial ODC during H. pylori infection. Deletion of Odc in gastric epithelial cells reduces gastritis, attenuates epithelial proliferaton, alters the metabolome, and dowregulates the expression of immune mediators induced by H. pylori. Inhibition of ODC activity in gastric epithelial cells reduces H. pylori-induced NF-B activation and CXCL8 mRNA expression. Chronic inflammation is a major risk factor for the progression to more severe pathologies associated with H. pylori infection and we now show that epithelial ODC plays an important role in mediating this inflammatory response.

Project description:Although sporadic AD (sAD) accounts for the majority of AD cases, the underlying mechanisms remain largely unknown. Here we modeled sAD using human induced pluripotent stem cell (iPSC)-derived three-dimensional brain organoids. We exposed brain organoids to serum to mimic the serum exposure consequence of BBB breakdown in AD patient brains. The serum-exposed brain organoids were able to recapitulate AD-like pathologies, including increased Aβ aggregates and p-Tau level, synaptic loss, and impaired calcium signaling and neural network. Serum exposure increased Aβ and p-Tau levels through inducing BACE and GSK3α/β levels, respectively. In addition, single-cell transcriptomic analysis of brain organoids revealed that serum exposure reduced synaptic function in both neurons and astrocytes, and induced immune response in astrocytes. The human brain organoid-based sAD model established in this study could provide a powerful platform for both mechanistic study and therapeutic development.

Project description:We previously established long-term 3D organoid culture systems for several murine tissues (intestine, stomach, pancreas and liver) as well as human intestine and pancreas. Here, we describe culture conditions to generate long-term 3D culture from human gastric stem cells. The technology can be applied to study the epithelial response to infection with Helicobacter pylori. Human gastric cultures can expand indefinitely in 3D Matrigel. Cultures can be generated from normal tissue, from single sorted stem cells, or from tumor tissue. Organoids maintain many characteristics of the respective tissue in terms of histology, marker expression and euploidy. Organoids from normal tissue express markers of four lineages of the stomach and self-organize in gland and pit-domains. They can be directed to specifically express either lineages of the gastric gland, or the gastric pit by addition of Nicotinamide and withdrawal of Wnt. While gastric pit lineages react marginally to bacterial infection, gastric gland lineages mount a strong inflammatory response. The gastric culture system provides a unique tool to study gastric pathologies.

Project description:The oral mucosa remains an understudied barrier tissue rich in exposure to antigens, commensals and pathogens. Moreover, it is the tissue where one of the most prevalent human microbe-triggered inflammatory diseases, periodontitis, occurs. To understand this complex environment at the cellular level, we assemble herein a human single-cell transcriptome atlas of oral mucosal tissues in health and periodontitis. Our work reveals transcriptional diversity of stromal and immune cell populations, predicts intercellular communication and uncovers an altered immune responsiveness of stromal cells participating in tissue homeostasis and disease at the gingival mucosa. In health, we define unique populations of CXCL1,2,8- expressing epithelial cells and fibroblasts mediating immune homeostasis primarily through the recruitment of neutrophils. In disease, we further observe stromal, particularly fibroblast hyper-responsiveness linked to recruitment of leukocytes and neutrophil populations. Our work suggests a stromal-neutrophil axis as a key regulator of mucosal immunity. Pursuant to these findings, most Mendelian forms of periodontitis were shown to be linked to genetic mutations in neutrophil-expressed genes. Moreover, we document previously unappreciated expression of known pattern- and damage- recognition receptors on stromal cell populations in the setting of periodontitis, suggesting avenues for triggering of stromal responsiveness. This comprehensive atlas offers an important reference for in-depth understanding of oral mucosal homeostasis and inflammation and reveals unique stromal–immune interactions implicated in tissue immunity.

Project description:Antigen uptake, processing, trafficking and presentation in nasal mucosal tissues are regulated by complex intra- and inter-cellular signalling events. Typical vaccine adjuvants lead to the transcription of pro-inflammatory cytokines and chemokines which relate to immune induction. We used microarrays to detail the global expression of genes in murine nasal mucosa underlying immune induction with a non-inflammatory nanoemulsion nasal adjuvant. 8 week old female CD-1 mice were nasally treated with 5 microliters/nare of either 20% (v/v) naomeulsion (W805EC) or PBS. Nasal epithelium was harvested immediately post-mortem at either 6 (6 hr) or 24 hours (24 hr) following treatment. The tissue was placed in OTC and frozen by immersion in liquid nitrogen. Total RNA was extracted per sample using RNA easy (Qiagen).

Project description:Most organs have tissue resident immune cells that function during tissue development, homeostasis and disease. Human organoids, derived either from adult tissues or from pluripotent stem cells (PSCs), have been lacking these immune cells, which limits their utility to model many normal and disease processes. Here we describe that human PSC-derived colonic organoids (HCOs) co-develop a diverse population of immune cells. Comparisons to the developing human hematopoietic cells, demonstrate that HCO cultures developed hemogenic endothelium and erythromyeloid progenitors that undergo stereotypical steps in differentiation, resulting in the generation of macrophages. HCO macrophages acquired a transcriptional signature most similar to human fetal small and large intestine tissue-resident macrophages. Functional analyses demonstrate that HCO-macrophages modulate cytokine secretion in response to pro- and anti-inflammatory signals. In addition, macrophages were able to phagocytose and mount a robust response to pathogenic bacteria. In HCOs that were transplanted into mice, macrophages expanded within the colonic organoid tissue, established a close association with the colonic epithelium and were not displaced by the host bone marrow-derived macrophages. These studies support the conclusion that hemogenic endothelium in HCOs gives rise to multipotent hematopoietic progenitors and functional tissue-resident macrophages.

Project description:Most organs have tissue resident immune cells that function during tissue development, homeostasis and disease. Human organoids, derived either from adult tissues or from pluripotent stem cells (PSCs), have been lacking these immune cells, which limits their utility to model many normal and disease processes. Here we describe that human PSC-derived colonic organoids (HCOs) co-develop a diverse population of immune cells. Comparisons to the developing human hematopoietic cells, demonstrate that HCO cultures developed hemogenic endothelium and erythromyeloid progenitors that undergo stereotypical steps in differentiation, resulting in the generation of macrophages. HCO macrophages acquired a transcriptional signature most similar to human fetal small and large intestine tissue-resident macrophages. Functional analyses demonstrate that HCO-macrophages modulate cytokine secretion in response to pro- and anti-inflammatory signals. In addition, macrophages were able to phagocytose and mount a robust response to pathogenic bacteria. In HCOs that were transplanted into mice, macrophages expanded within the colonic organoid tissue, established a close association with the colonic epithelium and were not displaced by the host bone marrow-derived macrophages. These studies support the conclusion that hemogenic endothelium in HCOs gives rise to multipotent hematopoietic progenitors and functional tissue-resident macrophages.

Project description:Background & Aims Patient-derived gastrointestinal organoids are powerful tools for studying human physiology and disease. However, generating organoids requires prompt isolation and culture of fresh tissue, which is labor and time intensive, placing restraints on basic and clinical research. For example organoid biobanking efforts, or the ability to obtain specimens from distant locations that lack the expertise to culture organoids, is limited by current approaches. We sought to develop a method by which tissue biopsies from patients could be cryo-preserved, stored, or shipped, and later thawed in order to establish live organoid cultures. Methods A method for freezing and recovery, along with straightforward isolation methods using readily available materials were developed. Epithelial isolation and culture conditions were optimized to promote cell survival and the establishment of long-term culture post-thawing. Results Patient biopsies from stomach, duodenum, ileum, colon and from adenomateous colonic polyps were frozen, subsequently thawed and used to successfully establish patient-specific epithelium-only organoid cultures with 100% efficiency (n=31 independent patient biopsies from different regions of the GI tract). Frozen tissue could be shipped internationally and across the United States and used to establish successful organoid cultures. Organoid cultures could be expanded, passaged and frozen down for long-term storage. RNA-sequencing demonstrates that organoids derived from fresh tissue or from frozen biopsies are >99% transcriptionally identical. Conclusions Cryo-preservation of human tissue biopsies followed by the establishment of long-term, expandable cultures has negligible effect on transcription when compared to freshly prepared organoids, and will be of immense benefit to research and for clinical applications. This technique will allow for the establishment of biobanks of human tissues that can be revived and cultured in the future as well as transported across the globe for research, therapeutic or diagnostic use in remote labs and/or clinics.

Project description:Organoid technology has provided unique insights into human organ development, function, and diseases. Patient derived organoids are increasingly used for drug screening, modeling rare disorders, designing regenerative therapies, and understanding pathological changes associated with disease progression. However, the use of Matrigel to grow organoids represents a major challenge in the clinical translation of organoid technology. Matrigel is a poorly defined cocktail of extracellular matrix proteins and growth factors extracted from the Engelbreth Holm Swarm mouse tumor. The extracellular matrix is a major driver of multiple cellular processes and differs significantly between tissues as well as in healthy and diseases states of the same tissue. Therefore, we envisioned that extracellular matrix derived from a native healthy tissue would be sufficient to support organoid growth akin to organogenesis in vivo. Here, we have developed hydrogels from decellularized human and bovine endometrium. These hydrogels supported the growth of mouse and human endometrial organoids, which was comparable to Matrigel. Organoids grown in endometrial hydrogels were proteomically more similar to the native tissue than the organoids cultured in Matrigel. Proteomic and Raman spectroscopy analyses showed that the method of decellularization affects the biochemical composition of hydrogels and subsequently, their ability to support organoid growth. The amount of laminin in hydrogels correlated with the number and the shape of organoids. We also demonstrated the utility of endometrial hydrogels in developing solid scaffolds for supporting high throughput cell culture-based applications. In summary, endometrial hydrogels overcome a major limitation of organoid technology and greatly expand the applicability of organoids to understand endometrial biology and associated pathologies.