Scientific Resources

The endocannabinoid system has been implicated in the modulation of adult neurogenesis. Here,we describe the effect of type 1 cannabinoid receptor (CB1R) activation on self-renewal,proliferation and neuronal differentiation in mouse neonatal subventricular zone (SVZ) stem/progenitor cell cultures. Expression of CB1R was detected in SVZ-derived immature cells (Nestin-positive),neurons and astrocytes. Stimulation of the CB1R by (R)-(+)-Methanandamide (R-m-AEA) increased self-renewal of SVZ cells,as assessed by counting the number of secondary neurospheres and the number of Sox2+/+ cell pairs,an effect blocked by Notch pathway inhibition. Moreover,R-m-AEA treatment for 48 h,increased proliferation as assessed by BrdU incorporation assay,an effect mediated by activation of MAPK-ERK and AKT pathways. Surprisingly,stimulation of CB1R by R-m-AEA also promoted neuronal differentiation (without affecting glial differentiation),at 7 days,as shown by counting the number of NeuN-positive neurons in the cultures. Moreover,by monitoring intracellular calcium concentrations ([Ca(2+)]i) in single cells following KCl and histamine stimuli,a method that allows the functional evaluation of neuronal differentiation,we observed an increase in neuronal-like cells. This proneurogenic effect was blocked when SVZ cells were co-incubated with R-m-AEA and the CB1R antagonist AM 251,for 7 days,thus indicating that this effect involves CB1R activation. In accordance with an effect on neuronal differentiation and maturation,R-m-AEA also increased neurite growth,as evaluated by quantifying and measuring the number of MAP2-positive processes. Taken together,these results demonstrate that CB1R activation induces proliferation,self-renewal and neuronal differentiation from mouse neonatal SVZ cell cultures. View Publication

Stem cells are highly resistant to viral infection compared to their differentiated progeny; however,the mechanism is mysterious. Here,we analyzed gene expression in mammalian stem cells and cells at various stages of differentiation. We find that,conserved across species,stem cells express a subset of genes previously classified as interferon (IFN) stimulated genes (ISGs) but that expression is intrinsic,as stem cells are refractory to interferon. This intrinsic ISG expression varies in a cell-type-specific manner,and many ISGs decrease upon differentiation,at which time cells become IFN responsive,allowing induction of a broad spectrum of ISGs by IFN signaling. Importantly,we show that intrinsically expressed ISGs protect stem cells against viral infection. We demonstrate the in vivo importance of intrinsic ISG expression for protecting stem cells and their differentiation potential during viral infection. These findings have intriguing implications for understanding stem cell biology and the evolution of pathogen resistance. View Publication

Human rhinovirus (HRV) is the most common virus contributing to acute exacerbations of chronic obstructive pulmonary disease (COPD) nearly year-round,but the mechanisms have not been well elucidated. Recent clinical studies suggest that high levels of growth differentiation factor 15 (GDF15) protein in the blood are associated with an increased yearly rate of all-cause COPD exacerbations. Therefore,in the current study,we investigated whether GDF15 promotes HRV infection and virus-induced lung inflammation. We first examined the role of GDF15 in regulating host defense and HRV-induced inflammation using human GDF15 transgenic mice and cultured human GDF15 transgenic mouse tracheal epithelial cells. Next,we determined the effect of GDF15 on viral replication,antiviral responses,and inflammation in human airway epithelial cells with GDF15 knockdown and HRV infection. Finally,we explored the signaling pathways involved in airway epithelial responses to HRV infection in the context of GDF15. Human GDF15 protein over-expression in mice led to exaggerated inflammatory responses to HRV,increased infectious particle release,and decreased IFN-λ2/3 (IL-28A/B) mRNA expression in the lung. Moreover,GDF15 facilitated HRV replication and inflammation via inhibiting IFN-λ1/IL-29 protein production in human airway epithelial cells. Lastly,Smad1 cooperated with interferon regulatory factor 7 (IRF7) to regulate airway epithelial responses to HRV infection partly via GDF15 signaling. Our results reveal a novel function of GDF15 in promoting lung HRV infection and virus-induced inflammation,which may be a new mechanism for the increased susceptibility and severity of respiratory viral (i.e.,HRV) infection in cigarette smoke-exposed airways with GDF15 over-production. View Publication

BACKGROUND Single-cell RNA-Seq can be a valuable and unbiased tool to dissect cellular heterogeneity,despite the transcriptome's limitations in describing higher functional phenotypes and protein events. Perhaps the most important shortfall with transcriptomic 'snapshots' of cell populations is that they risk being descriptive,only cataloging heterogeneity at one point in time,and without microenvironmental context. Studying the genetic ('nature') and environmental ('nurture') modifiers of heterogeneity,and how cell population dynamics unfold over time in response to these modifiers is key when studying highly plastic cells such as macrophages. RESULTS We introduce the programmable Polaris microfluidic lab-on-chip for single-cell sequencing,which performs live-cell imaging while controlling for the culture microenvironment of each cell. Using gene-edited macrophages we demonstrate how previously unappreciated knockout effects of SAMHD1,such as an altered oxidative stress response,have a large paracrine signaling component. Furthermore,we demonstrate single-cell pathway enrichments for cell cycle arrest and APOBEC3G degradation,both associated with the oxidative stress response and altered proteostasis. Interestingly,SAMHD1 and APOBEC3G are both HIV-1 inhibitors ('restriction factors'),with no known co-regulation. CONCLUSION As single-cell methods continue to mature,so will the ability to move beyond simple 'snapshots' of cell populations towards studying the determinants of population dynamics. By combining single-cell culture,live-cell imaging,and single-cell sequencing,we have demonstrated the ability to study cell phenotypes and microenvironmental influences. It's these microenvironmental components - ignored by standard single-cell workflows - that likely determine how macrophages,for example,react to inflammation and form treatment resistant HIV reservoirs. View Publication

Metazoan development depends on the accurate execution of differentiation programs that allow pluripotent stem cells to adopt specific fates. Differentiation requires changes to chromatin architecture and transcriptional networks,yet whether other regulatory events support cell-fate determination is less well understood. Here we identify the ubiquitin ligase CUL3 in complex with its vertebrate-specific substrate adaptor KBTBD8 (CUL3(KBTBD8)) as an essential regulator of human and Xenopus tropicalis neural crest specification. CUL3(KBTBD8) monoubiquitylates NOLC1 and its paralogue TCOF1,the mutation of which underlies the neurocristopathy Treacher Collins syndrome. Ubiquitylation drives formation of a TCOF1-NOLC1 platform that connects RNA polymerase I with ribosome modification enzymes and remodels the translational program of differentiating cells in favour of neural crest specification. We conclude that ubiquitin-dependent regulation of translation is an important feature of cell-fate determination. View Publication

Despite the high incidence of trophoblast-related diseases,the molecular mechanism of inadequate early trophoblast development is still unclear due to the lack of an appropriate cellular model in vitro. In the present study,we reprogrammed the amniotic cells to be induced pluripotent stem cells (iPSCs) via a non-virus and non-integrated method and subsequently differentiated them into trophoblast-like cells by a modified BMP4 strategy in E6 medium. Compared with the previously studied trophoblast-like cells from ESCs,the iPSCs derived trophoblast-like cells behave similarly in terms of gene expression profiles and biofunctions. Also we confirmed the differentiating tendency from iPSCs to be syncytiotrophoblasts-like cells might be caused by inappropriate differentiating oxygen condition. Additionally,we preliminarily indicated in vitro artificial" differentiation of iPSCs also undergoing a possible trophoblastic stem cell stage as witnessed in vivo. In conclusion we provided an in vitro cellular model to study early trophoblast development for specific individual by using the feasible amnion. View Publication

Hypoxia is a near-universal feature of cancer,promoting glycolysis,cellular proliferation,and angiogenesis. The molecular mechanisms of hypoxic signaling have been intensively studied,but the impact of changes in oxygen partial pressure (pO2) on the state of signaling networks is less clear. In a glioblastoma multiforme (GBM) cancer cell model,we examined the response of signaling networks to targeted pathway inhibition between 21% and 1% pO2. We used a microchip technology that facilitates quantification of a panel of functional proteins from statistical numbers of single cells. We find that near 1.5% pO2,the signaling network associated with mammalian target of rapamycin (mTOR) complex 1 (mTORC1)--a critical component of hypoxic signaling and a compelling cancer drug target--is deregulated in a manner such that it will be unresponsive to mTOR kinase inhibitors near 1.5% pO2,but will respond at higher or lower pO2 values. These predictions were validated through experiments on bulk GBM cell line cultures and on neurosphere cultures of a human-origin GBM xenograft tumor. We attempt to understand this behavior through the use of a quantitative version of Le Chatelier's principle,as well as through a steady-state kinetic model of protein interactions,both of which indicate that hypoxia can influence mTORC1 signaling as a switch. The Le Chatelier approach also indicates that this switch may be thought of as a type of phase transition. Our analysis indicates that certain biologically complex cell behaviors may be understood using fundamental,thermodynamics-motivated principles. View Publication

The multifunctional signaling protein p75 neurotrophin receptor (p75(NTR)) is a central regulator and major contributor to the highly invasive nature of malignant gliomas. Here,we show that neurotrophin-dependent regulated intramembrane proteolysis (RIP) of p75(NTR) is required for p75(NTR)-mediated glioma invasion,and identify a previously unnamed process for targeted glioma therapy. Expression of cleavage-resistant chimeras of p75(NTR) or treatment of animals bearing p75(NTR)-positive intracranial tumors with clinically applicable gamma-secretase inhibitors resulted in dramatically decreased glioma invasion and prolonged survival. Importantly,proteolytic processing of p75(NTR) was observed in p75(NTR)-positive patient tumor specimens and brain tumor initiating cells. This work highlights the importance of p75(NTR) as a therapeutic target,suggesting that gamma-secretase inhibitors may have direct clinical application for the treatment of malignant glioma. View Publication

It is now widely accepted that hippocampal neurogenesis underpins critical cognitive functions,such as learning and memory. To assess the behavioral importance of adult-born neurons,we developed a novel knock-in mouse model that allowed us to specifically and reversibly ablate hippocampal neurons at an immature stage. In these mice,the diphtheria toxin receptor (DTR) is expressed under control of the doublecortin (DCX) promoter,which allows for specific ablation of immature DCX-expressing neurons after administration of diphtheria toxin while leaving the neural precursor pool intact. Using a spatially challenging behavioral test (a modified version of the active place avoidance test),we present direct evidence that immature DCX-expressing neurons are required for successful acquisition of spatial learning,as well as reversal learning,but are not necessary for the retrieval of stored long-term memories. Importantly,the observed learning deficits were rescued as newly generated immature neurons repopulated the granule cell layer upon termination of the toxin treatment. Repeat (or cyclic) depletion of immature neurons reinstated behavioral deficits if the mice were challenged with a novel task. Together,these findings highlight the potential of stimulating neurogenesis as a means to enhance learning. View Publication

Neurogenesis occurs continuously in two brain regions of adult mammals,underpinned by a pool of resident neural stem cells (NSCs) that can differentiate into all neural cell types. To advance our understanding of NSC function and to develop therapeutic and diagnostic approaches,it is important to accurately identify and enrich for NSCs. There are no definitive markers for the identification and enrichment of NSCs present in the mouse brain. Recently,a fluorescent rosamine dye,CDy1,has been identified as a label for pluripotency in cultured human embryonic and induced pluripotent stem cells. As similar cellular characteristics may enable the uptake and retention of CDy1 by other stem cell populations,we hypothesized that this dye may also enrich for primary NSCs from the mouse brain. Because the subventricular zone (SVZ) and the hippocampus represent brain regions that are highly enriched for NSCs in adult mammals,we sampled cells from these areas to test this hypothesis. These experiments revealed that CDy1 staining indeed allows for enrichment and selection of all neurosphere-forming cells from both the SVZ and the hippocampus. We next examined the effectiveness of CDy1 to select for NSCs derived from the SVZ of aged animals,where the total pool of NSCs present is significantly lower than in young animals. We found that CDy1 effectively labels the NSCs in adult and aged animals as assessed by the neurosphere assay and reflects the numbers of NSCs present in aged animals. CDy1,therefore,appears to be a novel marker for enrichment of NSCs in primary brain tissue preparations. View Publication

Small-molecule inhibitors targeting growth factor receptors have failed to show efficacy for brain cancers,potentially due to their inability to achieve sufficient drug levels in the CNS. Targeting non-oncogene tumor co-dependencies provides an alternative approach,particularly if drugs with high brain penetration can be identified. Here we demonstrate that the highly lethal brain cancer glioblastoma (GBM) is remarkably dependent on cholesterol for survival,rendering these tumors sensitive to Liver X receptor (LXR) agonist-dependent cell death. We show that LXR-623,a clinically viable,highly brain-penetrant LXRα-partial/LXRβ-full agonist selectively kills GBM cells in an LXRβ- and cholesterol-dependent fashion,causing tumor regression and prolonged survival in mouse models. Thus,a metabolic co-dependency provides a pharmacological means to kill growth factor-activated cancers in the CNS. View Publication

Global cerebral ischemia induces selective acute neuronal injury of the CA1 region of the hippocampus. The type of cell death that ensues may include different programmed cell death mechanisms namely apoptosis and necroptosis,a recently described type of programmed necrosis. We investigated whether necroptosis contributes to hippocampal neuronal death following oxygen-glucose deprivation (OGD),an in vitro model of global ischemia. We observed that OGD induced a death receptor (DR)-dependent component of necroptotic cell death in primary cultures of hippocampal neurons. Additionally,we found that this ischemic challenge upregulated the receptor-interacting protein kinase 3 (RIP3) mRNA and protein levels,with a concomitant increase of the RIP1 protein. Together,these two related proteins form the necrosome,the complex responsible for induction of necroptotic cell death. Interestingly,we found that caspase-8 mRNA,a known negative regulator of necroptosis,was transiently decreased following OGD. Importantly,we observed that the OGD-induced increase in the RIP3 protein was paralleled in an in vivo model of transient global cerebral ischemia,specifically in the CA1 area of the hippocampus. Moreover,we show that the induction of endogenous RIP3 protein levels influenced neuronal toxicity since we found that RIP3 knock-down (KD) abrogated the component of OGD-induced necrotic neuronal death while RIP3 overexpression exacerbated neuronal death following OGD. Overexpression of RIP1 also had deleterious effects following the OGD challenge. Taken together,our results highlight that cerebral ischemia activates transcriptional changes that lead to an increase in the endogenous RIP3 protein level which might contribute to the formation of the necrosome complex and to the subsequent component of necroptotic neuronal death that follows ischemic injury. View Publication