Browsing by Subject "signaling pathways"
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Item Open Access Molecular characterization of numr-1 and numr-2: genes that increase both resistance to metal-induced stress and lifespan in Caenorhabditis elegans(2010) Tvermoes, Brooke E; Boyd, Windy A; Freedman, Jonathan HTo define the mechanisms involved in the molecular response to the carcinogenic metal cadmium, two novel metal-inducible genes from C. elegans were characterized: numr-1 and numr-2 (nuclear localized metal responsive). numr-1 and numr-2 sequences and cellular patterns of expression are identical, indicating that these are functionally equivalent genes. Constitutive transcription of numr-1 and numr-2 is developmentally regulated and occurs in the intestine, in head and tail neurons, and vulva muscles. Exposure to metals induces numr-1 and numr-2 transcription in pharyngeal and intestinal cells. Other environmental stressors do not affect transcription, indicating that these are metal-specific, stress-responsive genes. NUMR-1 and NUMR-2 target to nuclei and colocalize with HSF-1, suggesting that they may be components of nuclear stress granules. Nematodes overexpressing NUMR-1 and NUMR-2 are resistant to stress and live longer than control animals; likewise reducing expression increases sensitivity to metals and decreases neuromuscular functions. Upstream regulatory regions of both genes contain potential binding sites for DAF-16 and SKN-1, which are components of the insulin-IGF-like signaling pathway. This pathway regulates longevity and stress responses in C. elegans. NUMR-1 and NUMR-2 may function to promote resistance to environmental stressors and longevity, which is mediated by the insulin-IGF-like signaling pathway.Item Open Access Narrowing the focus: a toolkit to systematically connect oncogenic signaling pathways with cancer phenotypes.(Genes Cancer, 2016-07) Singleton, Katherine R; Wood, Kris CFunctional genomics approaches such as gain- and loss-of-function screening can efficiently reveal genes that control cancer cell growth, survival, signal transduction, and drug resistance, but distilling the results of large-scale screens into actionable therapeutic strategies is challenging given our incomplete understanding of the functions of many genes. Research over several decades, including the results of large-scale cancer sequencing projects, has made it clear that many oncogenic properties are controlled by a common set of core oncogenic signaling pathways. By directly screening this core set of pathways, rather than much larger numbers of individual genes, it may be possible to more directly and efficiently connect functional genomic screening results with therapeutic targets. Here, we describe the recent development of methods to directly screen oncogenic pathways in high-throughput. We summarize the results of studies that have used pathway-centric screening to map the pathways of resistance to targeted therapies in diverse cancer types, then conclude by expanding on potential future applications of this approach.Item Open Access Spatiotemporal Kinetics of AMPAR Trafficking in Single Spines(2010) Patterson, Michael AndrewLearning and memory is one of the critical components of the human experience. In one model of memory, hippocampal LTP, it is believed that the trafficking of AMPA receptors to the synapse is a fundamental process, yet the spatiotemporal kinetics of the process remain under dispute. In this work, we imaged the trafficking of AMPA receptors by combining two-photon glutamate uncaging on single spines with a fluorescent reporter for surface AMPA receptors. We found that AMPA receptors are trafficked to the spine at the same time as the spine size is increasing. Using a bleaching protocol, we found that the receptors that reach the spine come from a combination of the surface and endosomal pools. Imaging exocytosis in real time, we found that the exocytosis rate increases briefly (~1 min.), both in the spine and neighbouring dendrite. Finally, we performed pharmacological and genetic manipulations of signaling pathways, and found that the Ras-ERK signaling pathway is necessary for AMPAR exocytosis.
In a set of related experiments, we also investigated the capacity of single spines to undergo potentiation multiple times. By stimulating spines twice using glutamate uncaging, we found that there is a refractory period for synaptic plasticity in spines during which they cannot further be potentiated. We furthermore found that inducing plasticity in a given spine inhibits plasticity at nearby spines.