Temporal Proteome and Lipidome Profiles Reveal Hepatitis C Virus-Associated Reprogramming of Hepatocellular Metabolism and Bioenergetics - Test2 - elhamkhani - TriplyDB

Temporal Proteome and Lipidome Profiles Reveal Hepatitis C Virus-Associated Reprogramming of Hepatocellular Metabolism and Bioenergetics

Temporal Proteome and Lipidome Profiles Reveal Hepatitis C Virus-Associated Reprogramming of Hepatocellular Metabolism and Bioenergetics

http://www.wikidata.org/entity/Q27490520

about

Identification and comparative analysis of hepatitis C virus-host cell protein interactions Viperin: a multifunctional, interferon-inducible protein that regulates virus replication Systems virology identifies a mitochondrial fatty acid oxidation enzyme, dodecenoyl coenzyme A delta isomerase, required for hepatitis C virus replication and likely pathogenesis Hepatitis C virus relies on lipoproteins for its life cycle Metabolic alterations and hepatitis C: From bench to bedside Architecture and biogenesis of plus-strand RNA virus replication factories Feeding uninvited guests: mTOR and AMPK set the table for intracellular pathogens Lipids at the interface of virus-host interactions Impact of lipids and lipoproteins on hepatitis C virus infection and virus neutralization Systems approaches to influenza-virus host interactions and the pathogenesis of highly virulent and pandemic viruses A metabolic network approach for the identification and prioritization of antimicrobial drug targets Reverse enGENEering of Regulatory Networks from Big Data: A Roadmap for Biologists Stealing the Keys to the Kitchen: Viral Manipulation of the Host Cell Metabolic Network Proteomic approaches to analyzing hepatitis C virus biology Persistent growth of a human plasma-derived hepatitis C virus genotype 1b isolate in cell culture Metabolomic profile of hepatitis C virus-infected hepatocytes Host defense against viral infection involves interferon mediated down-regulation of sterol biosynthesis Divergent effects of human cytomegalovirus and herpes simplex virus-1 on cellular metabolism An invertebrate Warburg effect: a shrimp virus achieves successful replication by altering the host metabolome via the PI3K-Akt-mTOR pathway A new stochastic model for subgenomic hepatitis C virus replication considers drug resistant mutants Phosphatidic acid produced by phospholipase D promotes RNA replication of a plant RNA virus Changes in the Proteome of Langat-Infected Ixodes scapularis ISE6 Cells: Metabolic Pathways Associated with Flavivirus Infection Lipidomics reveals dramatic lipid compositional changes in the maturing postnatal lung Hepatitis C virus infection promotes hepatic gluconeogenesis through an NS5A-mediated, FoxO1-dependent pathway.A network integration approach to predict conserved regulators related to pathogenicity of influenza and SARS-CoV respiratory viruses.Systems virology: host-directed approaches to viral pathogenesis and drug targeting.Biomarkers of safety and immune protection for genetically modified live attenuated leishmania vaccines against visceral leishmaniasis - discovery and implications.Lipidomics and RNA-Seq Study of Lipid Regulation in Aphis gossypii parasitized by Lysiphlebia japonica.Controlling the response: predictive modeling of a highly central, pathogen-targeted core response module in macrophage activation.Functional and mechanistic integration of infection and the metabolic syndrome.Proteomic analysis of primary duck hepatocytes infected with duck hepatitis B virus Hepatitis C virus proteins activate NRF2/ARE pathway by distinct ROS-dependent and independent mechanisms in HUH7 cells.Dengue virus-induced autophagy regulates lipid metabolism Quantitative proteomics of Spodoptera frugiperda cells during growth and baculovirus infection.Serum sphingolipids reflect the severity of chronic HBV infection and predict the mortality of HBV-acute-on-chronic liver failure Targeting Epstein-Barr virus oncoprotein LMP1-mediated glycolysis sensitizes nasopharyngeal carcinoma to radiation therapy.Dengue virus infection perturbs lipid homeostasis in infected mosquito cells.Topological analysis of protein co-abundance networks identifies novel host targets important for HCV infection and pathogenesis.Kaposi's sarcoma herpesvirus microRNAs induce metabolic transformation of infected cells Identification and validation of Ifit1 as an important innate immune bottleneck

P2860

Q24338554-3663FA4D-74B9-4C5A-91C3-A59B04C9EDD2 Q24617679-9D66A772-9827-4C59-AE2E-DF2FE67614AF Q24631218-FC8AE817-A8FC-45F9-891E-A3769D07952C Q26766119-BDF5BDAC-D469-4682-B839-CA22D50D70CD Q26773261-4A4C20E8-2CF5-4278-A6E9-5D146DEA7020 Q26824445-5B03C0E8-AD27-4AD4-8663-94C1A6D2521D Q26859304-0F529B9D-2DC8-4263-AA27-1CCD0C50B4C2 Q26860983-1A697747-C6CD-4EC0-B612-314E50547BD3 Q26864485-134FB698-249C-4D4F-A59E-9D659F884C17 Q26866078-030D4438-0A4E-4049-B262-05F336E50B3D Q27014752-027D6422-0E3D-4ACA-930F-7494C0607D38 Q28083193-EFB899BF-3626-4532-8C14-216EE95F1E60 Q28084730-9D71E5A8-E9CF-479A-B3F8-9E37291C2182 Q28085146-CFE4F6CC-352C-4684-B473-A3867E0DD172 Q28473992-679288D5-93AB-44A7-B59B-87F0A68AF0F8 Q28476531-EAAC1FBF-BC13-4BF4-A972-C0962B6C7C73 Q28477369-731A06D4-3531-433E-A9CF-D205740193E6 Q28479023-F2CA321F-69C3-4D47-82CC-911DE9C0FB9B Q28539677-0A3D6B77-022B-4ADE-890E-9D9B9EEA8CB4 Q28541048-F903F004-316C-4567-A5EF-1815D06FACD9 Q28547576-A5276175-3A6C-4662-865C-3CA03B791EB0 Q28550057-47182600-8851-4A27-BD33-B960FE91949D Q28817762-4ED15E4A-4660-4B65-85FC-2F973191B65A Q30395512-A3516D70-B5F7-4C88-A51B-05F5F62CDD62 Q31126174-78F83F0A-9659-4723-B42D-5D4B6253BB81 Q33637578-850BA2B9-7830-4CFA-A2F9-6084DC4032FF Q33659753-68DFA3A0-5209-4247-8D81-C7D281A8FA2F Q33683778-0EC36F22-9181-4B28-83D7-DC1E28788D42 Q33826113-9A74DFCB-B736-422F-BAE1-9F6EE1CC1793 Q33904504-4E97A338-9FB2-419E-85E8-EAAC030E357A Q33997952-7049C10B-9D89-4A3F-A7B8-786376E7EB4F Q34024112-F6C8DBA9-B03E-4BB6-8037-0E4FE3F587D2 Q34024721-91D7F490-9CD0-4737-A230-FAFD0ABC8702 Q34062438-52646590-CC80-4132-9220-1C103B70B37F Q34066622-670F461F-9377-44F1-83E1-CA35E3A184C4 Q34171822-4AFDA167-F5F1-4F96-8F21-4860F478A826 Q34211489-4858D860-4D51-4101-BF43-9B8ED0921CBA Q34251928-ED224711-2257-4037-88A1-05E9E9E057C9 Q34257830-D1E417DD-36AF-4818-92D0-863FC5929652 Q34321053-55BE1E90-7604-4670-A124-6362FE5693CB

P2860

Temporal Proteome and Lipidome Profiles Reveal Hepatitis C Virus-Associated Reprogramming of Hepatocellular Metabolism and Bioenergetics

http://www.wikidata.org/entity/Q27490520

description

2010 nî lūn-bûn

@nan

2010 թուականի Յունուարին հրատարակուած գիտական յօդուած

@hyw

2010 թվականի հունվարին հրատարակված գիտական հոդված

@hy

2010年の論文

@ja

2010年論文

@yue

2010年論文

@zh-hant

2010年論文

@zh-hk

2010年論文

@zh-mo

2010年論文

@zh-tw

2010年论文

@wuu

name

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@ast

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@en

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@nl

type

label

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@ast

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@en

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@nl

altLabel

Temporal proteome and lipidome ...... r metabolism and bioenergetics

@en

prefLabel

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@ast

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@en

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@nl

P1433

Q27490520-B3D5D408-F30B-4DF1-8648-CA6E552758BF

P1476

Q27490520-E6DE5C5D-0AC4-428B-B627-920AE1F81F7F

P2093

Q27490520-2E9CA781-3568-4862-ACFE-B4BB6D99B128

Q27490520-471348BA-D390-428E-8EEB-EAB14E274406

Q27490520-75D5F82B-A988-4BCA-99BB-42CF18FCCDA9

Q27490520-872570C2-940C-4CD7-BD10-3C428B440895

Q27490520-8DC4CDB3-471F-471D-A185-36F71891C4A4

Q27490520-9DB37B53-762F-41F3-B68B-DA6AC0B8C9FD

Q27490520-CB63B617-0856-4CFA-A2E1-A339155F5942

Q27490520-E2D5F1D7-9920-4E0E-9CB8-C9872E68F58C

Q27490520-EA91C72F-1FD3-41F8-84B1-38941750BC18

P2860

Q27490520-0B47F3B1-7908-4E75-81AC-429257C263DD

Q27490520-0B6A7BAA-18EB-4EFE-B69C-53CE47EA1417

Q27490520-0C5A5B6A-F744-44F1-BF16-B9322A66C3DC

Q27490520-0EDF8638-07BD-476D-B4CC-840E7F546D76

Q27490520-0EF0C746-B944-4B12-A932-E6FAB5259460

Q27490520-0F34CC6C-5972-4354-BB13-7F8B7119C04B

Q27490520-16AE11F9-A295-4A2E-BAA7-FF3195BF296F

Q27490520-17CB40A1-47A1-4A18-ADED-A33A91D2CFBE

Q27490520-181F1814-FDA6-47F5-BFBA-0591FD8B07BA

Q27490520-1CF8C2E3-B342-4BA3-B98B-938E7246FFDF

P304

Q27490520-07BF03F0-6EE5-4877-B899-A5C7CEDF2042

P31

Q27490520-1FB362E8-58F8-4DB6-8FD2-E8F2453BF02C

P3181

Q27490520-F87221B1-97C0-40D6-A1C4-534EF2CBCFC0

P356

Q27490520-0BDCB2BC-D6B3-436A-85FB-4920C191F6CF

P407

Q27490520-12F6BFB0-A2D9-4BB4-B70C-60EBF0305CD7

P433

Q27490520-0658ADC7-9AA3-4FA3-9067-459C6F08705E

P478

Q27490520-C74E366B-E9F3-4B74-A809-CD105A9DBFE9

P50

Q27490520-0C22C633-93C4-4872-AA4A-34E1BC0435F1

Q27490520-3A39CC95-9506-420B-AAA2-F8B75512D5A7

Q27490520-3B068AA9-6B13-41AF-9E10-240B8AC6684F

Q27490520-4CBC54E4-1BAB-4126-BDF5-95F2133D47DB

Q27490520-717A2E03-FC4E-4BEE-8408-F61318EFD7F2

Q27490520-7D952728-FD88-4C26-8ABD-7D1998855F90

Q27490520-B140982F-9061-4210-9E98-25008DAC9216

P577

Q27490520-EC732DB1-4EC2-44CA-B1CC-A52C944B97FB

P5875

Q27490520-3FB3A5F2-53C1-4167-B3A7-08FE58671F93

P698

Q27490520-6AAFB6A7-64DB-47E1-AE0C-3E12BFB0EC8B

P921

Q27490520-d1dbf5ad-4ed5-83eb-f7f4-959f041e9049

P932

Q27490520-D697D28C-4E0F-4E24-9BCC-BC84F2C7BA98

P3181

P356

JOURNAL.PPAT.1000719

P1433

P1476

Temporal Proteome and Lipidome ...... r Metabolism and Bioenergetics

@en

P2093

Andrew J Syder

http://www.w3.org/2001/XMLSchema#string

Charles M Rice

http://www.w3.org/2001/XMLSchema#string

Christina M Sorensen

http://www.w3.org/2001/XMLSchema#string

David G Camp

http://www.w3.org/2001/XMLSchema#string

Deborah L Diamond

http://www.w3.org/2001/XMLSchema#string

Jon M Jacobs

http://www.w3.org/2001/XMLSchema#string

Marina A Gritsenko

http://www.w3.org/2001/XMLSchema#string

Rui Zhao

http://www.w3.org/2001/XMLSchema#string

Sean C Proll

http://www.w3.org/2001/XMLSchema#string

P2860

Reliance of host cholesterol metabolic pathways for the life cycle of hepatitis C virus

Protein synthesis and endoplasmic reticulum stress can be modulated by the hepatitis C virus envelope protein E2 through the eukaryotic initiation factor 2alpha kinase PERK

Long chain acyl-CoA synthetase 3-mediated phosphatidylcholine synthesis is required for assembly of very low density lipoproteins in human hepatoma Huh7 cells

Identification of FBL2 as a geranylgeranylated cellular protein required for hepatitis C virus RNA replication

Hepatitis C virus infection protein network

Hepatitis C virus subgenomic replicons induce endoplasmic reticulum stress activating an intracellular signaling pathway

Proteome analysis of liver cells expressing a full-length hepatitis C virus (HCV) replicon and biopsy specimens of posttransplantation liver from HCV-infected patients.

Hepatitis C Virus RNA Replication Occurs on a Detergent-Resistant Membrane That Cofractionates with Caveolin-2

Hepatitis C virus production by human hepatocytes dependent on assembly and secretion of very low-density lipoproteins

Cellular Determinants of Hepatitis C Virus Assembly, Maturation, Degradation, and Secretion

P304

e1000719

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P3181

127414

http://www.w3.org/2001/XMLSchema#string

P356

10.1371/JOURNAL.PPAT.1000719

http://www.w3.org/2001/XMLSchema#string

P407

P433

1

http://www.w3.org/2001/XMLSchema#string

P478

6

http://www.w3.org/2001/XMLSchema#string

P50

Jason McDermott

Katrina M. Waters

Richard D. Smith

Kathie-Anne Walters

P577

2010-01-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

40900223

http://www.w3.org/2001/XMLSchema#string

P698

20062526

http://www.w3.org/2001/XMLSchema#string

P921

Hepatitis C virus

P932

2796172

http://www.w3.org/2001/XMLSchema#string