sameAs
P185
Guidelines for the use and interpretation of assays for monitoring autophagyGuidelines for the use and interpretation of assays for monitoring autophagy (3rd edition)Type III Interferons Produced by Human Placental Trophoblasts Confer Protection against Zika Virus InfectionArs2 links the nuclear cap-binding complex to RNA interference and cell proliferationInstrument-Free Point-of-Care Molecular Detection of Zika VirusA CRISPR screen defines a signal peptide processing pathway required by flavivirusesIn memoriam--Richard M. Elliott (1954-2015)Viruses and antiviral immunity in DrosophilaRelease of intracellular calcium stores facilitates coxsackievirus entry into polarized endothelial cellsA kinome RNAi screen identified AMPK as promoting poxvirus entry through the control of actin dynamicsInnate antiviral immunity in DrosophilaScreening Bioactives Reveals Nanchangmycin as a Broad Spectrum Antiviral Active against Zika VirusCOPI activity coupled with fatty acid biosynthesis is required for viral replication.Ars2 regulates both miRNA- and siRNA- dependent silencing and suppresses RNA virus infection in Drosophila.Rift valley fever virus infection of human cells and insect hosts is promoted by protein kinase C epsilon.Genome-wide RNAi screen reveals a specific sensitivity of IRES-containing RNA viruses to host translation inhibition.RNAi screening in mammalian cells to identify novel host cell molecules involved in the regulation of viral infections.Stem-loop recognition by DDX17 facilitates miRNA processing and antiviral defense.Nup98 promotes antiviral gene expression to restrict RNA viral infection in DrosophilaAMP-activated kinase restricts Rift Valley fever virus infection by inhibiting fatty acid synthesis.Dicer-2 processes diverse viral RNA species.The major cellular sterol regulatory pathway is required for Andes virus infectionGenome-wide RNAi screen identifies broadly-acting host factors that inhibit arbovirus infection.Natural resistance-associated macrophage protein is a cellular receptor for sindbis virus in both insect and mammalian hosts.The transcription factor FoxK participates with Nup98 to regulate antiviral gene expression.Virus-induced translational arrest through 4EBP1/2-dependent decay of 5'-TOP mRNAs restricts viral infection.The Orphan Nuclear Receptor TLX Is an Enhancer of STAT1-Mediated Transcription and Immunity to Toxoplasma gondii.RNASEK is required for internalization of diverse acid-dependent viruses.Microbiota-Dependent Priming of Antiviral Intestinal Immunity in Drosophila.RIP3 Regulates Autophagy and Promotes Coxsackievirus B3 Infection of Intestinal Epithelial Cells.Combinatorial control of Drosophila circular RNA expression by intronic repeats, hnRNPs, and SR proteins.The cytokines interleukin 27 and interferon-γ promote distinct Treg cell populations required to limit infection-induced pathology.Transcriptional pausing controls a rapid antiviral innate immune response in DrosophilaA genome-wide RNAi screening method to discover novel genes involved in virus infectionCell-based genomic screening: elucidating virus-host interactionsAMP-activated protein kinase is required for the macropinocytic internalization of ebolavirus.Host-pathogen interactions in drosophila: new tricks from an old friend.A genome-wide RNAi screen reveals that mRNA decapping restricts bunyaviral replication by limiting the pools of Dcp2-accessible targets for cap-snatchingERK signaling couples nutrient status to antiviral defense in the insect gut.Genomic RNAi screening in Drosophila S2 cells: what have we learned about host-pathogen interactions?
P50
Q21996341-A92CE48A-8924-4345-9D5B-DCAC1FA96E8DQ22676705-C4BAF806-6E8B-4C05-A6E5-87714DBD87B7Q23748220-C6C1F550-591A-4362-830B-E70ACFF843F3Q24317359-3428481B-1AEC-4F87-A9CF-6D2FF7D23BADQ24705227-246D9779-C1D9-4A2C-ABB6-948470C32E74Q24705237-84AD9C32-5EB8-421B-8BE2-CE4FE343EFF5Q26700157-5AF1116B-898E-47F2-AAC4-166C70AE14B8Q26998819-A9E5993A-9BDE-4F1F-8EF0-4CBB99811E25Q27313258-4608E291-F1FE-4FC7-8206-5C4F5BDC27D1Q27314508-7CE0A5A2-39DF-44DF-AF95-546603A55885Q27491008-170F72B4-5060-401C-AC4D-983D0D506C4CQ28595153-F6F42FCF-6F03-4DAC-B224-D6CB7BA78370Q33260346-E47846D1-684F-4513-A10D-771234B88FC5Q33486941-5EAD6DC6-F7CA-44F7-8CF0-52BE7B2573BAQ33760778-96F4768C-79D0-4901-BDE2-F575D75D9CB1Q33848936-1481730F-F981-43A0-98AF-5E7399BC9CE8Q33854009-855FBF7B-A0F2-4692-9107-64CF157F0165Q34052027-66CB135A-2BEB-4CEE-9DE6-ACA50364138EQ34218467-DADB3205-0874-4E6F-9DCA-9810CDB211F5Q34244912-EB92B08B-10A3-4154-A708-EC721706073AQ34592647-C556E795-B87B-44E0-8167-1577F8F70533Q35091225-780E764C-BFEF-4AA1-8F49-6429B7D57C2BQ35097100-2FB9D05A-582B-4E24-9D2B-2E7233FAE25CQ35188739-75295761-9094-4904-B538-6991FE840463Q35677583-39468559-266C-4CE8-8DA8-E20188ECEC30Q35699045-179C8515-7B24-4E54-8205-DEE9548937FAQ35702559-7D25A4A8-33C3-41C6-A406-E38E1E6918DDQ35795990-D35C24AA-9FEC-46DC-8D4D-2A836CD1CEB2Q35841268-478B5964-0683-47B4-9A83-AAA55F773F5DQ36035406-ACBEB2E0-69FB-4805-BDDA-8567576E814FQ36199645-B6DD71CB-D30E-43AC-94E9-7D2457EF3C5FQ36336588-58E2C114-1664-40A2-B998-A5CA72245490Q36343296-4105DDDB-3CDF-4B64-BAB3-675ABF0C6809Q36386235-FBD727F1-AAE3-4072-B082-0BE8BD5C975FQ36439726-87BF62C4-8112-48F2-952B-92D7872260F6Q36559650-C2B86329-3B8C-4971-B918-E5909FEC1069Q36573327-C3ACA003-9E9E-44EA-A73B-3B5844773300Q37019225-AD3CB7DC-9D2F-4F14-B47A-28E2B4120CF4Q37173282-EE3F8EE1-DF95-43D1-B564-FBCC42E1ED69Q37186263-327435FF-8778-40CC-8C32-EF6D19A621E5
P50
description
American microbiologist
@en
microbiologa statunitense
@it
microbiologista norte-americana
@pt
microbiologiste américaine
@fr
microbiòloga estatunidenca
@ca
microbióloga estadounidense
@es
microbióloga estadounidense
@gl
microbióloga estauxunidense
@ast
mikrobiologo estatubatuarra
@eu
name
Sara Cherry
@ast
Sara Cherry
@en
Sara Cherry
@es
Sara Cherry
@nl
Sara Cherry
@ro
type
label
Sara Cherry
@ast
Sara Cherry
@en
Sara Cherry
@es
Sara Cherry
@nl
Sara Cherry
@ro
altLabel
Sara R. Cherry
@en
prefLabel
Sara Cherry
@ast
Sara Cherry
@en
Sara Cherry
@es
Sara Cherry
@nl
Sara Cherry
@ro
P106
P184
P21
P31
P496
0000-0003-3956-6610