Project description:Carcinoma-associated fibroblasts (CAFs) that express ?-smooth-muscle-actin (?SMA+) contribute to cancer progression, but their precise origin and role in tumorigenesis is not established. Using mouse models of inflammation-induced gastric cancer, we show that at least 20% of CAFs originate from bone marrow and derive from mesenchymal stem cells (MSCs). Surprisingly, we find that ?SMA+ myofibroblasts (MF) are niche cells normally present in bone marrow and increase markedly in the bone marrow and blood during progression to dysplasia. MSC-derived CAFs that are recruited to the dysplastic stomach express IL-6, Wnt5? and BMP4 and show DNA hypomethylation. Bone marrow (BM)-derived CAFs strongly promote tumor growth in organotypic and xenograft models. In addition, CAFs are generated from MSCs and are recruited to distant tumor sites in a TGF-?- and SDF-1?-dependent manner. Carcinogenesis therefore involves the expansion and relocation of normal bone marrow niche cells to the tumor site where they create a new niche to sustain cancer progression. Since resident (non-BM-derived) CAFs could not be cultured and directly compared to BM-derived CAFs, we additionally isolated total RFP(+) gastric CAFs from aSMA-RFP mice with Helicobacter felis-induced dysplasia, and compared them to GFP(+) BM-derived gastric CAFs from mice with H. felis-induced dysplasia mice that had been transplanted with UBC-EGFP bone marrow. The RFP+ CAFs (HF CAF) represent total CAFs (of which only 20% were BM-derived), while the latter represented only BM-derived CAFs (BM CAF). We compared their gene expression using the Illumina array (MouseWG-6v2) directly after FACS sorting. Interestingly, the GFP+ BM-derived CAFs expressed higher levels of inflammatory genes (IL-6, IL-1?, IL-33) and a number of tumor and stem cell associated factors (CCL5, SPP1, Notch3, MMP9, CD47, CXCR4, PARP10,) compared to the total (RFP+) population of gastric CAFs. Comparison of bone marrow-derived GFP-labeled gastric CAFs versus all gastric CAFs.

Project description:Background: Helicobacter pylori (H. pylori) infection is a known cause of many digestive diseases, including gastritis, peptic ulcers, and gastric cancer. However, the underlying mechanism(s)by which H. pylori infection triggers these disorders are still not clearly understood. Methods: We have developed an accelerated disease progression mouse model, which leverages mice deficient in the myeloid differentiation primary response 88 gene (Myd88-/-) infected with Helicobacter felis (H. felis) Findings: In this study, we found that H. felis-induced inflammation in Myd88-/- mice progressed to high-grade dysplasia, driven by activation of the type I interferon (IFN-I) signaling pathway and upregulation of its downstream targets, IFN-stimulated genes (ISGs). We also observed enrichment of IFN stimulated-response element (ISRE) motifs in the promoters of upregulated genes, further supporting the involvement of this pathway. In contrast, mice deficient in Toll/interleukin-1 receptor (TIR)-domain-containing adaptor inducing interferon-β (TRIF, TrifLps2) did not progress to severe gastric pathology after H. felis infection, implicating the TRIF signaling pathway in disease pathogenesis and progression. Additionally, analysis of gastric biopsy samples from human gastric cancer patients illustrated that low expression of Myd88 and high expression of Trif were both significantly correlated with poor survival. Interpretation: Our study using an accelerated animal model for gastric cancer and gastric biopsy samples from patients demonstrated that activation of the TRIF-IFN-I signaling pathway promotes Helicobacter-induced disease progression toward severe gastric pathology and gastric cancer development. This represents a potential target for therapeutic intervention, and further exploration may lead to the identification of novel treatment strategies.

Project description:Background and aims Cancer-associated fibroblasts (CAFs) play a critical role in colorectal cancer (CRC) progression. However, the precise cellular origins of the tumor stroma remain unknown, making it challenging to therapeutically target the tumor mesenchyme. Here, we aimed to identify key cellular contributors to and components of the CRC mesenchyme associated with poor prognosis. Methods We used a mouse model of inflammation-associated CRC in 5 different genetic fate-mapping transgenic mouse lines to characterize the origins of the CRC stroma. To identify a potential therapeutic target expressed by the CRC stroma, RNA-sequencing of fluorescence-activated cell sorting (FACS)-purified CRC stromal cells was performed. CRC patient RNA-sequencing data (n=621) and tissue microarray (n=101) were used to examine the prognostic significance of marker expression. Results We found that approximately half of the CRC CAFs marked by α-smooth muscle actin (αSMA) in a mouse model of CRC emerge through proliferation. Lineage tracing experiments revealed that intestinal leptin receptor (Lepr)-lineage stromal cells expanded and contributed to 75% of the αSMA+ proliferating CAFs. Notably, no αSMA+ CAFs arose from Krt19-lineage epithelial cells or bone marrow-derived cells. Moreover, RNA-sequencing of FACS-purified CRC mesenchymal cells identified MCAM as a CRC stroma-specific marker, which is expressed by Lepr-lineage cells. Analysis of human CRC samples showed that high MCAM expression driven, in part, by TGF-β was independently prognostic of poor overall survival. Conclusion Our data identify intestinal Lepr-lineage cells as a major source of the tumor stroma in CRC and suggest that targeting MCAM+ cells may serve as an attractive therapeutic approach to restrain CRC progression.

Project description:Purpose: This study interrogated the role of αSMA+ CAFs in a genetic moue model of metastatic colorectal cancer. Methods: αSMA+ CAFs were selectively depleted in mouse CRC model. RNA was isolated from tumors from control and depleted mice, as well as from the colon of WT mice and sequenced. Results: Mice with αSMA+ CAF-depletion exhibited increased inflammation and immunosuppressive phenotype in tumors. Depleted mice also had an increased incidence of Lgr5+ CSCs. BMP4 and TGFβ1 was increased in depleted tumors compared to control. Conclusion: αSMA+ CAFs have a tumor restraining function in CRC, via BMP4/TGFβ1 signaling.

Project description:Bone metastasis occurs frequently in cancer patients. Conventional therapies have limited therapeutic outcomes, and thus, exploring the mechanisms of cancer progression in the bone metastasis is important to develop new effective therapies. In the bone microenvironment, adipocytes are the major stromal cells that interact with cancer cells during the bone metastasis. However, the comprehensive functions of bone marrow adipocytes in cancer progression are not yet fully understood. To address this, we investigated the role of bone marrow adipocytes on cancer cells, by focusing on an invasive front which reflects the direct effects of stromal cells on caner. In comprehensive histopathological and genetic analysis using bone metastasis specimens, we examined invasive fronts in bone metastasis and compared invasive fronts with adipocyte-rich bone marrow (adipo-BM) to those with hematopoietic cell-rich bone marrow (hemato-BM) as a normal counterpart of adipocytes. We found morphological complexity of invasive front with adipo-BM was significantly higher than that with hemato-BM. Based on immunohistochemistry, the invasive front with adipo-BM comparatively had significantly increased cancer-associated fibroblasts (CAFs) marker-positive area and lower density of CD8 positive lymphocytes compared to that with hemato-BM. RNA-seq analysis of primary and bone metastasis cancer reveals that bone metastasized cancer cells acquired drug resistance related gene expression phenotypes. Clearly, these findings indicate that bone marrow adipocytes provide favorable tumor microenvironment for cancer invasion and therapeutic resistance of bone metastasized cancers via CAF induction and immune evasion, providing a potential target for the treatment of bone metastasis.

Project description:In this study, we have analyzed DNA methylation characteristics of human mesenchymal stem and progenitor cells (MSPCs) form different tissue sources including bone marrow (BM), white adipose tissue (WAT ), umbilical cord (UC) as well as dermal fibroblasts by using the HumanMethylation450K array. Cells able to form bone through endochondral ossification and attract bone marrow in an innovative in vivo model were compared to cells lacking these capacities. Interestingly only BM-derived MSPCs were capable of bone formation and marrow attraction. These features correlated with unique epigenetic characteristics potentially enabling BM-derived cells to undergo endochondral ossification.

Project description:Background & Aims: Previous studies have suggested that dietary folic acid (FA) can protect against certain types of cancers. However, the findings have varied and the mechanisms by which this vitamin exerts chemopreventive effects remain to be clarified. We examined the effects of FA supplementation on DNA methylation, gene expression and gastric dysplasia in a transgenic mouse model that is etiologically and histologically well matched with human gastric cancers. Methods: Hypergastrinemic mice (INS-GAS) infected with Helicobacter felis were studied at multiple stages of gastric dysplasia and early cancer, with FA supplementation initiated both at weaning and later in life. Global DNA methylation was assessed by a methylation-sensitive cytosine incorporation assay, bisulfite pyrosequencing of B1 repetitive elements and immunohistochemistry (IHC) with anti-5-methylcytosine. We also profiled gene expression in the same tissues. Results: We found a decrease in global DNA methylation and tissue folate and an increase in serum homocysteine with progression of gastric dysplasia. FA supplementation prevented this loss of global DNA methylation and markedly reduced gastric dysplasia and mucosal inflammation. FA protected against the loss of global DNA methylation both in the dysplastic gastric epithelial cells and in gastric stromal myofibroblasts. In addition, FA supplementation had an anti-inflammatory effect, as indicated by expression profiling and IHC for lymphocyte markers. Conclusions: We conclude that FA supplementation is chemopreventive in this model of Helicobacter-associated gastric cancer. The beneficial effect of FA is likely due to its ability to reverse global loss of methylation and suppress inflammation. Study the difference in gene expression between transgenic hypergastrinemic (INS-GAS) mice fed a folate-supplemented diet and a diet with normal folate content. Because folate had a substantial protective effect, we matched the animals not only by folate status but also by dysplasia score (DYS). The degree of dysplasia was scored on a 1-4 scale. True replicates are not included. The first five samples are from folate supplemented animals, and the latter five are from controls on regular chow.

Project description:Macrophages are central in regulating iron homeostasis. Transcription repressor Bach2 regulates by heme. Here we investigated the relationship between heme-regulated Bach2 and macrophage in bone marrow. We identified RFP-positive and negative macrophage were in bone marrow. We found that RFP-positive macrophage related with iron-heme homeostasis maintenance and RPF-negative population related with immune response. In RFP positive macrophage, we also found the lysosomal heme transporter hrg-1 was Bach2 direct target gene. Our results suggest that the function of the bone marrow macrophage alters according to expression of Bach2.

Project description:Background and methods: Myeloid-derived suppressor cells (MDSCs) are immature myeloid cells which originate in the bone marrow (BM) and have immunoregulatory functions. MDSCs have been implicated in the pathogenesis of several autoimmune diseases but not in immune aplastic anemia (AA). We examined the roles of granulocytic-MDSCs (G-MDSCs) in murine models of human AA and bone marrow failure (BMF). To perform Totalseq, bone marrow mononuclear cells were FACS sorted to obtain alive cells based on FSC and SSC from five bone marrow failure control mice and five G-MDSC-treated mice, mRNA profiles of single cells were generated and sequenced on an Illumina Novaseq System. Results: As both prophylaxis and therapy, BM-derived G-MDSCs improved pancytopenia and BM cellularity and decreased BM T cell infiltration in major histocompatibility (MHC)-matched CB10 BMF mice. Single cell RNA sequencing demonstrated that G-MDSCs downregulated cell cycle related pathways in BM infiltrated T cells, consistent with suppression of T cell proliferation by G-MDSCs. Conclusion: Our results demonstrate that BM-derived G-MDSCs improved pancytopenia and BM cellularity and decreased BM T cell infiltration in major histocompatibility (MHC)-matched CB10 BMF mice, but not in MHC-mismatched CByB6F1 BMF model. Therapeutic efficacy of G-MDSCs are immune context-dependent. Bone marrow mononuclear cells were FACS sorted to obtain alive cells based on FSC and SSC from five bone marrow failure control mice and five G-MDSC-treated mice.

Project description:Background & Aims: Previous studies have suggested that dietary folic acid (FA) can protect against certain types of cancers. However, the findings have varied and the mechanisms by which this vitamin exerts chemopreventive effects remain to be clarified. We examined the effects of FA supplementation on DNA methylation, gene expression and gastric dysplasia in a transgenic mouse model that is etiologically and histologically well matched with human gastric cancers. Methods: Hypergastrinemic mice (INS-GAS) infected with Helicobacter felis were studied at multiple stages of gastric dysplasia and early cancer, with FA supplementation initiated both at weaning and later in life. Global DNA methylation was assessed by a methylation-sensitive cytosine incorporation assay, bisulfite pyrosequencing of B1 repetitive elements and immunohistochemistry (IHC) with anti-5-methylcytosine. We also profiled gene expression in the same tissues. Results: We found a decrease in global DNA methylation and tissue folate and an increase in serum homocysteine with progression of gastric dysplasia. FA supplementation prevented this loss of global DNA methylation and markedly reduced gastric dysplasia and mucosal inflammation. FA protected against the loss of global DNA methylation both in the dysplastic gastric epithelial cells and in gastric stromal myofibroblasts. In addition, FA supplementation had an anti-inflammatory effect, as indicated by expression profiling and IHC for lymphocyte markers. Conclusions: We conclude that FA supplementation is chemopreventive in this model of Helicobacter-associated gastric cancer. The beneficial effect of FA is likely due to its ability to reverse global loss of methylation and suppress inflammation.