Transcriptomics_technologiesTranscriptomique%D0%A2%D1%80%D0%B0%D0%BD%D1%81%D0%BA%D1%80%D0%B8%D0%BF%D1%82%D0%BE%D0%BC%D0%BD%D1%8B%D0%B5_%D1%82%D0%B5%D1%85%D0%BD%D0%BE%D0%BB%D0%BE%D0%B3%D0%B8%D0%B8%D0%A2%D1%80%D0%B0%D0%BD%D1%81%D0%BA%D1%80%D0%B8%D0%BF%D1%82%D0%BE%D0%BC%D0%BD%D1%96_%D1%82%D0%B5%D1%85%D0%BD%D0%BE%D0%BB%D0%BE%D0%B3%D1%96%D1%97Q28946449
about
P101
Eupolybothrus cavernicolus Komerički & Stoev sp. n. (Chilopoda: Lithobiomorpha: Lithobiidae): the first eukaryotic species description combining transcriptomic, DNA barcoding and micro-CT imaging dataNew insights in Rett syndrome using pathway analysis for transcriptomics dataQuantitative analysis of ChIP-seq data uncovers dynamic and sustained H3K4me3 and H3K27me3 modulation in cancer cells under hypoxiaIntegration of expression data in genome-scale metabolic network reconstructions.A transcriptomics data-driven gene space accurately predicts liver cytopathology and drug-induced liver injuryTranscriptomics technologies.A transcriptome resource for pharaoh cuttlefish (Sepia pharaonis) after ink ejection by brief pressing.Transcriptomic Analysis of Laribacter hongkongensis Reveals Adaptive Response Coupled with Temperature.Perturbation of B Cell Gene Expression Persists in HIV-Infected Children Despite Effective Antiretroviral Therapy and Predicts H1N1 Response.Large Scale Identification of Variant Proteins in Glioma Stem Cells.Tissue and host species-specific transcriptional changes in models of experimental visceral leishmaniasisNon-invasive Biomarkers of Acute Rejection in Kidney Transplantation: Novel Targets and StrategiesPseudomonas fluorescens increases mycorrhization and modulates expression of antifungal defense response genes in roots of aspen seedlingsIdentification of genes associated with ricinoleic acid accumulation in via transcriptome analysisA bioinformatics workflow to decipher transcriptomic data from vitamin D studiesHigh-Throughput Omics and Statistical Learning Integration for the Discovery and Validation of Novel Diagnostic Signatures in Colorectal CancerProteogenomics Uncovers Critical Elements of Host Response in Bovine Soft Palate Epithelial Cells Following In Vitro Infection with Foot-And-Mouth Disease VirusCombined transcriptome and proteome profiling reveals specific molecular brain signatures for sex, maturation and circalunar clock phaseImportant Role of the GLP-1 Axis for Glucose Homeostasis after Bariatric SurgeryMetabolic Responses to Polymyxin Treatment in ATCC 19606: Integrating Transcriptomics and Metabolomics with Genome-Scale Metabolic ModelingComparative Transcriptomics Between Zebrafish and Mammals: A Roadmap for Discovery of Conserved and Unique Signaling Pathways in Physiology and DiseaseDissecting N-Glycosylation Dynamics in Chinese Hamster Ovary Cells Fed-batch Cultures using Time Course Omics AnalysesInTAD: chromosome conformation guided analysis of enhancer target genesIntegrating Genomic and Morphological Approaches in Fish Pathology Research: The Case of Turbot () EnteromyxosisA 20-Gene Set Predictive of Progression to Severe DengueAltered Gene Regulatory Networks Are Associated With the Transition From C to Crassulacean Acid Metabolism in (Oncidiinae: Orchidaceae)Peroxiredoxins in Cancer and Response to Radiation TherapiesDe Novo Sequencing and Hybrid Assembly of the Biofuel Crop L.: Identification of Quantitative Trait Loci for Geminivirus ResistanceVenomics Reveals Venom Complexity of the Piscivorous Cone Snail,Integration of Metabolomics and Transcriptomics Reveals the Therapeutic Mechanism Underlying Paeoniflorin for the Treatment of Allergic AsthmawebCEMiTool: Co-expression Modular Analysis Made EasySymbiotic organs shaped by distinct modes of genome evolution in cephalopodsUsing 'collective omics data' for biomedical research trainingThe Stringent Response Determines the Ability of a Commensal Bacterium to Survive Starvation and to Persist in the GutQuantification and discovery of sequence determinants of protein-per-mRNA amount in 29 human tissuesGene expression shifts in yellow-bellied marmots prior to natal dispersalRelative Abundance of Transcripts ( ): Identifying differential isoform abundance from RNA-seqHuman cytomegalovirus genomics and transcriptomics through the lens of next-generation sequencing: revision and future challengesCorrection of gene model annotations improves isoform abundance estimates: the example of ketohexokinase ( )Gene expression analysis delineates the potential roles of multiple interferons in systemic lupus erythematosus
P921
Q21090457-01bb6541-44bf-58ec-aba7-beb8d0f13b25Q28530264-0eb256ea-4898-a956-ecf4-db648a9b5f5eQ28950947-459433B8-46A7-4A27-AFEF-212A6B054FE7Q30425389-261A16A6-3903-439B-BF1D-B876834FEFD3Q31724476-3ecd3396-478f-1f37-1720-cb828322c69bQ33703532-70fe8635-4494-01ed-cb97-c31d78577c74Q36043092-F12397B4-6427-422F-A261-40B26B3DB1EEQ36248921-a6d93353-4ba2-3e3f-0e92-0cb28ed11f5fQ41684162-803C85D4-785A-427C-9E4C-DC8C039336FDQ47237240-96E26736-A2C3-42B3-99F7-E91F2FCBFB86Q58867683-D2BF0E4E-C876-49D8-BC37-BC676880F001Q60916304-F7A7C99D-BAD0-46AF-83F2-564F32261B13Q60921353-978BC327-8EDF-49EF-9E3B-0E5BCE3EEF97Q61445771-07B00100-9D24-4E40-BC43-8F0C58D74FBBQ61485024-55bdfbb3-4126-54f8-497e-d20037c0b6f7Q61795646-541C5B13-C7A6-4C71-83FA-87D9F06F6B52Q61795741-BE824D3A-8979-41F4-961D-A2D5F2449F9AQ61795858-F2530734-1F31-4790-8E6A-F65D0338FD36Q61799220-6F14C4CA-5962-4C98-B50D-A759AC814561Q61799375-7B9A547A-2348-4C5F-93C9-69448FA32E69Q61803729-7C3DC7FD-6F52-4513-9D97-79D07CBB2B23Q61804586-B28FB29E-A443-47C3-8DFA-5248D9CF5F2DQ61804725-38DB4892-1F05-432B-9DDC-83256B85D07BQ61805050-B95F0A7A-3D6D-4505-979E-87B6D2266C35Q61806871-0A16D987-F77F-45AF-A23F-99FBE0679E39Q61808063-693251C7-DA35-4DF7-84A5-2D4406419CF3Q61808369-9B61D405-1FD8-4F9F-8463-7FAF809BD258Q61812384-FBD24AC9-9E9E-468C-A2D8-473D66C066EEQ61812517-DD62991B-198D-462C-A1FC-C3A66E895BE0Q61813302-71DFB787-7D64-4719-BE50-3085EED82601Q62485122-E02F7A47-5FAE-4C88-851C-1AD8A05CFBD2Q62580393-C90DDBB1-875D-40FE-8969-0C855580345EQ62658190-19482C00-697A-4FD2-8D51-CFB983AC13CAQ63214066-4301D361-24EE-4CB7-93D9-91B604A68B01Q63359380-C99D29A0-BC3F-43BA-A5A8-407C947345BAQ63379872-395E9305-A2DA-41FA-A500-B5DEBFE8527AQ63648097-D38A745C-2A68-48AF-A8F3-2273BC195643Q63740162-28670454-1843-403C-94E6-C54D79D34F53Q63884189-9E4A58BB-099F-409D-9703-4B5B3B262C5CQ63976610-773AE1FC-CE6A-450D-8932-89EFA85DFEE2
P921
description
study of the transcriptome
@en
name
Transcriptomique
@fr
transcriptomics
@en
Транскриптомные технологии
@ru
Транскриптомні технології
@uk
тыранскриптумикы
@tt
トランスクリプトミクステクノロジー
@ja
type
label
Transcriptomique
@fr
transcriptomics
@en
Транскриптомные технологии
@ru
Транскриптомні технології
@uk
тыранскриптумикы
@tt
トランスクリプトミクステクノロジー
@ja
altLabel
Transcriptomics technologies
@en
トランスクリプトームの技術
@ja
prefLabel
Transcriptomique
@fr
transcriptomics
@en
Транскриптомные технологии
@ru
Транскриптомні технології
@uk
тыранскриптумикы
@tt
トランスクリプトミクステクノロジー
@ja
P1417
topic/transcriptomics