Project description:The immune system in the gastrointestinal tract plays a crucial role in the control of infection, as it constitutes the first line of defense against mucosal pathogens. The attractive features of oral immunization have led to the exploration of a variety of oral delivery systems. However, none of these oral delivery systems have been applied to existing commercial vaccines. To overcome this, a new generation of oral vaccine delivery systems that target antigens to gut-associated lymphoid tissue is required. One promising approach is to exploit the potential of microfold (M) cells by mimicking the entry of pathogens into these cells. Targeting specific receptors on the apical surface of M cells might enhance the entry of antigens, initiating the immune response and consequently leading to protection against mucosal pathogens. In this article, we briefly review the challenges associated with current oral vaccine delivery systems and discuss strategies that might potentially target mouse and human intestinal M cells.

Project description:Leiomyosarcoma (LMS) is aggressive cancer with few therapeutic options. LMS cells are more sensitive to proteotoxic stress compared to normal smooth muscle cells. We used small compound 2c to induce proteotoxic stress and compare the transcriptomic adaptations of immortalized human uterine smooth muscle cells (HUtSMC) and LMS cells SK-UT-1. We found that the expression of the heat shock proteins (HSPs) gene family is upregulated with higher efficiency in normal cells. In contrast, the upregulation of BH3-only proteins is higher in LMS cells. HSF1, the master regulator of HSP transcription, is sequestered into transcriptionally incompetent nuclear foci only in LMS cells, which explains the lower HSP upregulation. We also found that several compounds can enhance the cell death response to proteotoxic stress. Specifically, when low doses were used, an inhibitor of salt-inducible kinases (SIKs) and the inhibitor of IRE1α, a key element of the unfolded protein response (UPR), support proteotoxic-induced cell death with strength in LMS cells and without effects on the survival of normal cells. Overall, our data provide an explanation for the higher susceptibility of LMS cells to proteotoxic stress and suggest a potential option for co-treatment strategies.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:T-cell immunotherapy is a promising approach to treat disseminated cancer. However, it has been limited by the ability to isolate and expand T cells restricted to tumour-associated antigens. Using ex vivo gene transfer, T cells from patients can be genetically engineered to express a novel T cell receptor or chimeric antigen receptor to specifically recognize a tumour-associated antigen and thereby selectively kill tumour cells. Indeed, genetically engineered T cells have recently been successfully used for cancer treatment in a small number of patients. Here we review the recent progress in the field, and summarize the challenges that lie ahead and the strategies being used to overcome them.

Project description:Leiomyosarcoma (LMS) is an aggressive cancer with few therapeutic options. LMS cells are more sensitive to proteotoxic stress compared to normal smooth muscle cells. We used small compound 2c to induce proteotoxic stress and compare the transcriptomic adaptations of immortalized human uterine smooth muscle cells (HUtSMC) and LMS cells SK-UT-1. We found that the expression of the heat shock proteins (HSP) gene family is upregulated with higher efficiency in normal cells. In contrast, upregulation of BH3-only proteins is higher in LMS cells. HSF1, the master regulator of HSP transcription, is sequestered into transcriptionally incompetent nuclear foci only in LMS cells, which explains the lower HSP upregulation. We also found that several compounds can enhance the cell death response to proteotoxic stress. Specifically, when low doses were used, an inhibitor of salt-inducible kinases (SIKs) and the inhibitor of IRE1, a key element of the unfolded protein response (UPR), support proteotoxic-induced cell death with strength in LMS cells and without effects on the survival of normal cells. Overall, our data provide an explanation for the higher susceptibility of LMS cells to proteotoxic stress and suggest a potential option for co-treatment strategies.

Project description:Mouse naïve pluripotent stem cells (ESC) can contribute to all embryonic tissues and the germline, but rarely to the extra-embryonic tissues in chimeric embryos. Here we describe a novel advanced pluripotent stem cell (ASC) with higher potency, since a single ASC contributes very efficiently to the fetus, germline, yolk sac and the placental labyrinth in chimeras. ASCs were derived from blastocysts in two steps in a chemically defined medium with Activin A (ActA) and basic fibroblast growth factor (bFGF), followed by Wnt and BMP. Notably, ASCs exhibit a distinct transcriptome with the expression of both naïve pluripotent genes, as well as mesodermal somatic genes; Eomes, Eras, Tdgf1, Evx1, hand1, Wnt5a, and distinct repetitive elements. Established ESCs can also be readily and directly to ASCs. Importantly, ASCs exhibit a stable hypermethylated epigenome unlike the hypomethylated epiblast in blastocysts and naïve ESCs, indicating that ASCs might represent a state in between the naïve and primed states of pluripotency.

Project description:Mouse naïve pluripotent stem cells (ESC) can contribute to all embryonic tissues and the germline, but rarely to the extra-embryonic tissues in chimeric embryos. Here we describe a novel advanced pluripotent stem cell (ASC) with higher potency, since a single ASC contributes very efficiently to the fetus, germline, yolk sac and the placental labyrinth in chimeras. ASCs were derived from blastocysts in two steps in a chemically defined medium with Activin A (ActA) and basic fibroblast growth factor (bFGF), followed by Wnt and BMP. Notably, ASCs exhibit a distinct transcriptome with the expression of both naïve pluripotent genes, as well as mesodermal somatic genes; Eomes, Eras, Tdgf1, Evx1, hand1, Wnt5a, and distinct repetitive elements. Established ESCs can also be readily and directly to ASCs. Importantly, ASCs exhibit a stable hypermethylated epigenome unlike the hypomethylated epiblast in blastocysts and naïve ESCs, indicating that ASCs might represent a state in between the naïve and primed states of pluripotency.

Project description:Enhancing the Potency of Mouse Embryonic Stem Cells

Project description:Dysfunction or loss of blood vessel causes several ischemic diseases. Although endothelial progenitor cells (EPCs) are a promising source for cell-based therapy, ischemia-induced pathophysiological condition limits the recovery rate by causing drastic cell death. To overcome this issue, we attempted to develop a cell-targeted peptide delivery and priming system to enhance EPC-based neovascularization using an engineered M13 bacteriophage harboring nanofibrous tubes displaying ~2700 multiple functional motifs. The M13 nanofiber was modified by displaying RGD, which is an integrin-docking peptide, on the minor coat protein, and by mutilayering SDKP motifs, which are the key active sites for thymosin ?4, on the major coat protein. The engineered M13 nanofiber dramatically enhanced ischemic neovascularization by activating intracellular and extracellular processes such as proliferation, migration, and tube formation in the EPCs. Furthermore, transplantation of the primed EPCs with the M13 nanofiber harboring RGD and SDKP facilitated functional recovery and neovascularization in a murine hindlimb ischemia model. Overall, this study demonstrates the effectiveness of the M13 nanofiber-based novel peptide delivery and priming strategy in promoting EPC bioactivity and neovessel regeneration. To our knowledge, this is first report on M13 nanofibers harboring dual functional motifs, the use of which might be a novel strategy for stem and progenitor cell therapy against cardiovascular ischemic diseases.

Project description:By exploiting their biological functions, the use of biological nanoparticles such as extracellular vesicles can provide an efficient and effective approach for hepatic delivery of RNA-based therapeutics for the treatment of liver cancers such as hepatocellular cancer (HCC). Targeting liver cancer stem cells (LCSC) within HCC provide an untapped opportunity to improve outcomes by enhancing therapeutic responses. Cells with tumor-initiating capabilities such as LCSC can be identified by expression of markers such as epithelial cell adhesion molecule (EpCAM) on their cell surface. EpCAM is a target of Wnt/β-catenin signaling, a fundamental pathway in stem-cell growth. Moreover, mutations in the β-catenin gene are frequently observed in HCC and can be associated with constitutive activation of the Wnt/β-catenin pathway. However, targeting these pathways for the treatment of HCC has been challenging. Using RNA nanotechnology, we developed engineered biological nanoparticles capable of specific and effective delivery of RNA therapeutics targeting β-catenin to LCSC. Extracellular vesicles isolated from milk were loaded with small interfering RNA to β-catenin and decorated with RNA scaffolds to incorporate RNA aptamers capable of binding to EpCAM. Cellular uptake of these EpCAM-targeting therapeutic milk-derived nanovesicles in vitro resulted in loss of β-catenin expression and decreased proliferation. The uptake and therapeutic efficacy of these engineered biological nanotherapeutics was demonstrated in vivo using tumor xenograft mouse models. Conclusion: β-catenin can be targeted directly to control the proliferation of hepatic cancer stem cells using small interfering RNA delivered using target-specific biological nanoparticles. Application of this RNA nanotechnology-based approach to engineer biological nanotherapeutics provides a platform for developing cell-surface molecule-directed targeted therapeutics.