The developmentally important Hedgehog (Hh) signaling pathway has recently been implicated in several forms of solid cancer. Current drug development programs focus on targeting the protooncogene Smoothened, a key transmembrane pathway member. These drug candidates, albeit promising, do not address the scenario in which pathway activation occurs downstream of Smoothened, as observed in cases of medulloblastoma, glioma, pericytoma, breast cancer, and prostate cancer. A cellular screen for small-molecule antagonists of GLI-mediated transcription, which constitutes the final step in the Hh pathway, revealed two molecules that are able to selectively inhibit GLI-mediated gene transactivation. We provide genetic evidence of downstream pathway blockade by these compounds and demonstrate the ineffectiveness of upstream antagonists such as cyclopamine in such situations. Mechanistically, both inhibitors act in the nucleus to block GLI function, and one of them interferes with GLI1 DNA binding in living cells. Importantly, the discovered compounds efficiently inhibited in vitro tumor cell proliferation in a GLI-dependent manner and successfully blocked cell growth in an in vivo xenograft model using human prostate cancer cells harboring downstream activation of the Hh pathway.
The Hedgehog (Hh) pathway plays important roles during embryogenesis and carcinogenesis. Here, we show that ablation of the mouse Suppressor of fused (Sufu), an intracellular pathway component, leads to embryonic lethality at approximately E9.5 with cephalic and neural tube defects. Fibroblasts derived from Sufu(-/-) embryos showed high Gli-mediated Hh pathway activity that could not be modulated at the level of Smoothened and could only partially be blocked by PKA activation. Despite the robust constitutive pathway activation in the Sufu(-/-) fibroblasts, the GLI1 steady-state localization remained largely cytoplasmic, implying the presence of an effective nuclear export mechanism. Sufu(+/-) mice develop a skin phenotype with basaloid changes and jaw keratocysts, characteristic features of Gorlin syndrome, a human genetic disease linked to enhanced Hh signaling. Our data demonstrate that, in striking contrast to Drosophila, in mammals, Sufu has a central role, and its loss of function leads to potent ligand-independent activation of the Hh pathway.
Short-chain fatty acids (SCFAs) have immunomodulatory effects, but the underlying mechanisms are not well understood. Here we show that pentanoate, a physiologically abundant SCFA, is a potent regulator of immunometabolism. Pentanoate induces IL-10 production in lymphocytes by reprogramming their metabolic activity towards elevated glucose oxidation. Mechanistically, this reprogramming is mediated by supplying additional pentanoate-originated acetyl-CoA for histone acetyltransferases, and by pentanoate-triggered enhancement of mTOR activity. In experimental mouse models of colitis and multiple sclerosis, pentanoate-induced regulatory B cells mediate protection from autoimmune pathology. Additionally, pentanoate shows a potent histone deacetylase-inhibitory activity in CD4+ T cells, thereby reducing their IL-17A production. In germ-free mice mono-colonized with segmented filamentous bacteria (SFB), pentanoate inhibits the generation of small-intestinal Th17 cells and ameliorates SFB-promoted inflammation in the central nervous system. Taken together, by enhancing IL-10 production and suppressing Th17 cells, the SCFA pentanoate might be of therapeutic relevance for inflammatory and autoimmune diseases.
Pancreatic ductal adenocarcinoma (PDA) is notoriously aggressive and hard to treat. The tumour microenvironment (TME) in PDA is highly dynamic and has been found to promote tumour progression, metastasis niche formation and therapeutic resistance. Intensive research of recent years has revealed an incredible heterogeneity and complexity of the different components of the TME, including cancer-associated fibroblasts, immune cells, extracellular matrix components, tumour vessels and nerves. It has been hypothesised that paracrine interactions between neoplastic epithelial cells and TME compartments may result in either tumour-promoting or tumour-restraining consequences. A better preclinical understanding of such complex and dynamic network systems is required to develop more powerful treatment strategies for patients. Scientific activity and the number of compelling findings has virtually exploded during recent years. Here, we provide an update of the most recent findings in this area and discuss their translational and clinical implications for basic scientists and clinicians alike.
GLI transcription factors constitute the final effectors of the Hedgehog (HH) signaling pathway. In many tumors, such as those of the pancreas, prostate, skin or lung, ectopic activation of GLI proteins has been linked to tumorigenesis. In several of these cases, HH ligand-or receptor-induced signaling (canonical HH signaling) was found to be the cause underlying GLI activation. Recent evidence points towards additional, noncanonical, mechanisms of GLI activation. Here we review findings on the crosstalk of two HH-unrelated signaling pathways (RAS and Transforming growth factor β) to the HH pathway downstream of the signaling component Smoothened. Both pathways stimulate and/or induce GLI1 and GLI2 activity independent of the presence of HH ligands. We also discuss the putative roles of these crosstalk mechanisms for tumor cell metastasis. The emerging picture of GLI transcription factors as an integrative platform of numerous signaling inputs has important implications for the understanding of tumor development and argues for inclusion of targets acting downstream of the receptor level in the design of current drug development programs. the cAnonicAl hedgehog signAling PAthwAyThe Hedgehog (HH) signaling pathway is broadly active early in life where it orchestrates the patterning of tissues in the developing vertebrate and invertebrate embryo. In vertebrates, the best studied example is the cellular specification of the neural tube, where HH molecules set up a gradient which instructs the specific type of developing neuron at a given position within the gradient. 1 Later in life, HH signaling is restricted and within the adult organism is thought to maintain stem cell populations and/or early progenitor cells. This function is very important in situations of tissue repair where stem cells have to proliferate to give rise to numerous descendants which participate in the healing of the wound. 2 The mammalian genome contains three HH genes, Sonic Hedgehog (SHH), Indian HH (IHH) and Desert HH (DHH). The three secreted proteins are cholesterol-and palmitoyl-modified and bind to the Patched1 (PTCH) transmembrane receptor on receiving cells. The in vitro binding affinities of the three HH proteins to PTCH are comparable and it is most likely the difference in expression pattern which determines which HH evokes a response. 3 Additional HH binding/sequestrating proteins which presumably modulate ligand presentation to PTCH have been identified, such as PATCHED2, HIP, CDO, BOC, and GAS1. However, their role in tumor development is presently unclear.The current view on the role of PTCH is that its main function is to restrain the activity of the seven transmembrane protein Smoothened (SMO). SMO has similarity to G-protein coupled receptors and is the central signaling entity at the membrane. In the presence of unliganded PTCH, SMO is kept inactive, while ligand binding to PTCH relieves this inhibition. The molecular mechanism of this regulation is currently not fully clear and might involve pumping of a small molec...
Emerging data demonstrate that the activity of immune cells can be modulated by microbial molecules. Here, we show that the short-chain fatty acids (SCFAs) pentanoate and butyrate enhance the anti-tumor activity of cytotoxic T lymphocytes (CTLs) and chimeric antigen receptor (CAR) T cells through metabolic and epigenetic reprograming. We show that in vitro treatment of CTLs and CAR T cells with pentanoate and butyrate increases the function of mTOR as a central cellular metabolic sensor, and inhibits class I histone deacetylase activity. This reprogramming results in elevated production of effector molecules such as CD25, IFN-γ and TNF-α, and significantly enhances the anti-tumor activity of antigen-specific CTLs and ROR1-targeting CAR T cells in syngeneic murine melanoma and pancreatic cancer models. Our data shed light onto microbial molecules that may be used for enhancing cellular anti-tumor immunity. Collectively, we identify pentanoate and butyrate as two SCFAs with therapeutic utility in the context of cellular cancer immunotherapy.
The biology of solid tumors is strongly determined by the interactions of cancer cells with their surrounding microenvironment. In this regard, pancreatic cancer (pancreatic ductal adenocarcinoma, PDAC) represents a paradigmatic example for the multitude of possible tumor–stroma interactions. PDAC has proven particularly refractory to novel immunotherapies, which is a fact that is mediated by a unique assemblage of various immune cells creating a strongly immunosuppressive environment in which this cancer type thrives. In this review, we outline currently available knowledge on the cross-talk between tumor cells and the cellular immune microenvironment, highlighting the physiological and pathological cellular interactions, as well as the resulting therapeutic approaches derived thereof. Hopefully a better understanding of the complex tumor–stroma interactions will one day lead to a significant advancement in patient care.
Notch signaling is a highly conserved signal transduction pathway that regulates stem cell maintenance and differentiation in several organ systems. Upon activation, the Notch receptor is proteolytically processed, its intracellular domain (NICD) translocates into the nucleus and activates expression of target genes. Output, strength and duration of the signal are tightly regulated by post-translational modifications. Here we review the intracellular post-translational regulation of Notch that fine-tunes the outcome of the Notch response. We also describe how crosstalk with other conserved signaling pathways like the Wnt, Hedgehog, hypoxia and TGFβ/BMP pathways can affect Notch signaling output. This regulation can happen by regulation of ligand, receptor or transcription factor expression, regulation of protein stability of intracellular key components, usage of the same cofactors or coregulation of the same key target genes. Since carcinogenesis is often dependent on at least two of these pathways, a better understanding of their molecular crosstalk is pivotal.
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