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SYGL-1 and LST-1 link niche signaling to PUF RNA repression for stem cell maintenance in Caenorhabditis elegans
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نویسنده
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shin h. ,haupt k.a. ,kershner a.m. ,kroll-conner p. ,wickens m. ,kimble j.
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منبع
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plos genetics - 2017 - دوره : 13 - شماره : 12
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چکیده
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Central questions in regenerative biology include how stem cells are maintained and how they transition from self-renewal to differentiation. germline stem cells (gscs) in caeno-rhabditis elegans provide a tractable in vivo model to address these questions. in this system,notch signaling and puf rna binding proteins,fbf-1 and fbf-2 (collectively fbf),maintain a pool of gscs in a naïve state. an open question has been how notch signaling modulates fbf activity to promote stem cell self-renewal. here we report that two notch targets,sygl-1 and lst-1,link niche signaling to fbf. we find that sygl-1 and lst-1 proteins are cytoplasmic and normally restricted to the gsc pool region. increasing the distribution of sygl-1 expands the pool correspondingly,and vast overexpression of either sygl-1 or lst-1 generates a germline tumor. thus,sygl-1 and lst-1 are each sufficient to drive “stemness” and their spatial restriction prevents tumor formation. importantly,sygl-1 and lst-1 can only drive tumor formation when fbf is present. moreover,both proteins interact physically with fbf,and both are required to repress a signature fbf mrna target. together,our results support a model in which sygl-1 and lst-1 form a repressive complex with fbf that is crucial for stem cell maintenance. we further propose that progression from a naïve stem cell state to a state primed for differentiation relies on loss of sygl-1 and lst-1,which in turn relieves fbf target rnas from repression. broadly,our results provide new insights into the link between niche signaling and a downstream rna regulatory network and how this circuitry governs the balance between self-renewal and differentiation. © 2017 shin et al.
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آدرس
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department of biochemistry,university of wisconsin-madison,madison,wi, United States, department of biochemistry,university of wisconsin-madison,madison,wi, United States, howard hughes medical institute,university of wisconsin-madison,madison,wi,united states,department of biochemistry,stanford university school of medicine,stanford,ca, United States, howard hughes medical institute,university of wisconsin-madison,madison,wi, United States, department of biochemistry,university of wisconsin-madison,madison,wi, United States, department of biochemistry,university of wisconsin-madison,madison,wi,united states,howard hughes medical institute,university of wisconsin-madison,madison,wi, United States
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Authors
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