about
CRISPR-mediated modular RNA-guided regulation of transcription in eukaryotesThe interaction of TIGIT with PVR and PVRL2 inhibits human NK cell cytotoxicityDecoding human cytomegalovirusStem cells. m6A mRNA methylation facilitates resolution of naïve pluripotency toward differentiationA Regression-Based Analysis of Ribosome-Profiling Data Reveals a Conserved Complexity to Mammalian TranslationRibosome profiling reveals pervasive translation outside of annotated protein-coding genes.Host immune system gene targeting by a viral miRNAIntercellular transfer of carcinoembryonic antigen from tumor cells to NK cells.Decoding viral infection by ribosome profiling.The Transcription and Translation Landscapes during Human Cytomegalovirus Infection Reveal Novel Host-Pathogen Interactions.Regulation of mRNA translation during mitosis.Term-seq reveals abundant ribo-regulation of antibiotics resistance in bacteria.A conserved abundant cytoplasmic long noncoding RNA modulates repression by Pumilio proteins in human cellsKSHV 2.0: a comprehensive annotation of the Kaposi's sarcoma-associated herpesvirus genome using next-generation sequencing reveals novel genomic and functional features.An integrated view of the regulation of NKG2D ligands.Expansion of CD16 positive and negative human NK cells in response to tumor stimulation.Manipulation of host pathways by human cytomegalovirus: insights from genome-wide studies.Ribosome Profiling as a Tool to Decipher Viral Complexity.MiR-10b downregulates the stress-induced cell surface molecule MICB, a critical ligand for cancer cell recognition by natural killer cells.An identical miRNA of the human JC and BK polyoma viruses targets the stress-induced ligand ULBP3 to escape immune elimination.Analysis of human cytomegalovirus-encoded microRNA activity during infection.Human microRNAs regulate stress-induced immune responses mediated by the receptor NKG2D.Intracellular cysteine residues in the tail of MHC class I proteins are crucial for extracellular recognition by leukocyte Ig-like receptor 1.CEACAM1-Mediated Inhibition of Virus Production.Comparative genetics. Systematic discovery of cap-independent translation sequences in human and viral genomes.The activating receptor NKp46 is essential for the development of type 1 diabetes.Cap-binding protein 4EHP effects translation silencing by microRNAs.RNA editing by ADAR1 leads to context-dependent transcriptome-wide changes in RNA secondary structure.Diverse herpesvirus microRNAs target the stress-induced immune ligand MICB to escape recognition by natural killer cells.Decay of the Stress-Induced Ligand MICA Is Controlled by the Expression of an Alternative 3' Untranslated Region.Defining the Transcriptional Landscape during Cytomegalovirus Latency with Single-Cell RNA Sequencing.Notch activation enhances IFNγ secretion by human peripheral blood and decidual NK cellsTranslational Control in Virus-Infected CellsUrea Cycle Dysregulation Generates Clinically Relevant Genomic and Biochemical SignaturesEndometrial NK cells are special immature cells that await pregnancy
P50
Q24625361-91B0053A-8876-4A8F-A306-E5457EA7458DQ24651041-81C35AFB-BB93-431A-8CE2-E1650A39192DQ28279933-59ADCA4A-FBAE-4D36-A03D-7E21BFB74463Q28511267-1EF6AAAA-585C-4A3B-94F9-DEF22E1BB7CAQ31030361-314DFDF8-7A8D-4910-907A-90FDA842254FQ34435177-DD54F0E8-2C7D-4E57-8220-7A49B71723BFQ34581221-8B368783-4D89-4B2E-BF84-7BCDED4E16E0Q34689944-FD59AA65-7F02-4DDE-8CA1-2C1ED8466BC1Q35760510-09B00DB1-56B4-4F13-A048-E9F3F771F5F0Q35850190-673E7F18-4E35-4562-993A-08141BDB8C40Q35992687-42EF479E-B6E6-43E0-854C-668712FFB952Q36000911-AD9E8D40-6420-427E-BC7C-FE78A4B608B8Q37099460-E48436DB-1E1D-416B-ACB4-01F6E2268D51Q37488130-76AE8730-285B-4370-90C6-03A75083A616Q37582005-7E4A6FA8-01F7-40A2-BC01-2929884370E5Q37732133-0D138BA2-4181-4D15-8721-7B9035884621Q38254758-02128939-E045-4541-9908-F431F1BBD68AQ38766711-D25952DB-D522-49C0-A68D-FB2E2C065E25Q39292548-95E5B3C4-3CDB-4894-8067-FFB3E19F526FQ39592344-439FCBF3-4851-4BCF-AB86-494FA96C294BQ39816458-33600673-E28F-4708-BF9C-623892F39B46Q39954301-B1C3FD08-B9F1-4B37-8FAA-6D90421DC8FFQ40085364-219D3D0A-161E-4239-A040-46BB57E00E3FQ40644885-ECCB51E5-FA18-416D-9F14-C4F9CB8E65E2Q40948268-CAF763D1-8CC1-4834-ABE9-C0A214C1BCABQ43214288-CF42A651-2633-4FBE-A38A-08E6CFBD83F3Q45141966-BBCA1137-4776-4B98-95AD-907A7617C013Q47158316-AC4D913E-A8ED-4ACD-96F3-EB33B5545F15Q47978435-0702EA87-CE17-43C4-A178-37750B583C8AQ52655448-BD6EEF37-666D-438C-9BA9-C61E7AFE58E0Q55032738-A214A6D2-CBEA-4ED8-B25F-8EC4EA6A69EFQ56956120-781A6CF1-E8E2-4C7C-B5BA-6198A109FA0FQ59359160-E77F5030-8958-4494-AFD0-3807C148570AQ64122915-D0AF9D01-5DAE-4945-9F0A-68C172DE9812Q81670825-094A0339-BB7C-4E75-B514-C4E01716E8D7
P50
name
Noam Stern-Ginossar
@en
type
label
Noam Stern-Ginossar
@en
prefLabel
Noam Stern-Ginossar
@en