Metabolic Heterogeneity in Human Lung Tumors. - Wikidata - wikimedia - TriplyDB

Metabolic Heterogeneity in Human Lung Tumors.

Metabolic Heterogeneity in Human Lung Tumors.

http://www.wikidata.org/entity/Q36578111

about

Fundamentals of cancer metabolism Overcoming Hypoxia-Mediated Tumor Progression: Combinatorial Approaches Targeting pH Regulation, Angiogenesis and Immune Dysfunction Intratumor Heterogeneity in Primary Kidney Cancer Revealed by Metabolic Profiling of Multiple Spatially Separated Samples within Tumors.Cancer heterogeneity is not compatible with one unique cancer cell metabolic map The distinct metabolic phenotype of lung squamous cell carcinoma defines selective vulnerability to glycolytic inhibition.From Krebs to clinic: glutamine metabolism to cancer therapy.Cancer metabolism as a central driving force of glioma pathogenesis mTORC2 activity in brain cancer: Extracellular nutrients are required to maintain oncogenic signaling.Collagen-derived proline promotes pancreatic ductal adenocarcinoma cell survival under nutrient limited conditions.The metabolic fate of acetate in cancer.Tissue-specific tumorigenesis: context matters.Metabolic network segmentation: A probabilistic graphical modeling approach to identify the sites and sequential order of metabolic regulation from non-targeted metabolomics data.Hepatic gluconeogenesis influences (13)C enrichment in lactate in human brain tumors during metabolism of [1,2-(13)C]acetate.The importance of serine metabolism in cancer Addiction to Coupling of the Warburg Effect with Glutamine Catabolism in Cancer Cells.Multimodality Imaging Identifies Distinct Metabolic Profiles In Vitro and In Vivo.Personalized Prediction of Proliferation Rates and Metabolic Liabilities in Cancer Biopsies.Multivoxel magnetic resonance spectroscopy identifies enriched foci of cancer stem-like cells in high-grade gliomas.Systems biology analysis of drivers underlying hallmarks of cancer cell metabolism.Tumour microenvironment factors shaping the cancer metabolism landscape.A platform for high-throughput bioenergy production phenotype characterization in single cells.Metabolic interactions in cancer: cellular metabolism at the interface between the microenvironment, the cancer cell phenotype and the epigenetic landscape.A Dynamic Metabolic Flux Analysis of Myeloid-Derived Suppressor Cells Confirms Immunosuppression-Related Metabolic Plasticity.Physiologic Medium Rewires Cellular Metabolism and Reveals Uric Acid as an Endogenous Inhibitor of UMP Synthase.Phenformin Enhances the Efficacy of ERK Inhibition in NF1-Mutant Melanoma.Nesting of colon and ovarian cancer cells in the endothelial niche is associated with alterations in glycan and lipid metabolism.Metformin Targets Central Carbon Metabolism and Reveals Mitochondrial Requirements in Human Cancers.A Flux Balance of Glucose Metabolism Clarifies the Requirements of the Warburg Effect.Glucose-independent Acetate Metabolism Promotes Melanoma Cell Survival and Tumor Growth.Metabolomics: A Primer.Review of metabolic pathways activated in cancer cells as determined through isotopic labeling and network analysis.Comparative metabolomics profiling of isogenic KRAS wild type and mutant NSCLC cells in vitro and in vivo.A tale of two glutaminases: homologous enzymes with distinct roles in tumorigenesis.Monitoring cancer prognosis, diagnosis and treatment efficacy using metabolomics and lipidomics.Preclinical models for interrogating drug action in human cancers using Stable Isotope Resolved Metabolomics (SIRM).Homeostasis Back and Forth: An Ecoevolutionary Perspective of Cancer.Imaging Tumor Metabolism to Assess Disease Progression and Treatment Response.Metabolic interactions with cancer epigenetics.Understanding metabolism with flux analysis: From theory to application.Adaptive Stress Responses During Tumor Metastasis and Dormancy.

P2860

Q26744062-ABE3525A-530A-40DD-999F-859FA289A235 Q26749333-431417E9-E218-4E3E-BA7B-D1F4EEE1A614 Q33715755-0C720CDB-ED7F-4CE8-AB9D-F0E4E4A236B9 Q33721222-B7710801-8CD1-41EF-ACFB-EFF98983DF79 Q33763006-3F99F912-874E-4A22-B5DE-DC3CCB948134 Q33834498-0EF3050D-159C-4B7A-B55E-38B6D2573518 Q33847616-E1405B1E-A3E9-4B1F-B7EE-67251638F7AC Q33884658-0680422E-6717-42BC-9C21-BAA099649E98 Q33891283-203D47D0-DC56-41C6-A615-F5C92A80D052 Q36113718-758B747E-900D-41B1-A73A-88ADC37D2055 Q36296335-5FE9B8FE-0ACD-466B-ADB6-41E7255923CD Q36396861-E68411BA-F84D-4B2A-A399-7BFC9FFB4531 Q37109226-B5F52106-7AA7-49D7-818E-12DBFD92FD69 Q37145927-BAD995E8-0B6F-42BF-8A1B-88353E76CE70 Q37412242-1655C286-B26F-4CB2-AB49-47F44F964E7F Q37447355-5AB41A74-5B5F-4D2F-A1F8-D6086B924EF1 Q37532946-41B51046-D53E-477E-9050-AFE2B1B9DC62 Q37573471-E0D4F55A-616B-4030-8E87-E44013E1EC8C Q37604410-A48FBB43-2585-400A-8F0F-49EEFEB67586 Q37627771-92002437-0D8D-49ED-8B1D-B8DB80EDA041 Q37724045-9070CE0F-CF05-446A-BE1E-43501430D795 Q38600506-224DD1A5-251D-4638-BA61-76EA9ACCDDC8 Q38602957-DC95166D-29EA-4D0C-961E-E7ABBE4298D9 Q38708488-BABCAC4F-FC46-4A9C-B917-0A2146CC67A1 Q38718552-C8C1FD3D-E892-4DE5-81D1-9A2ADE5C5EE9 Q38723065-40F2FCE1-1079-487B-8A04-A9E8284E3507 Q38740928-76F687A2-611E-47A6-9B2C-226E3EA68F6E Q38747766-49F514A4-8BD6-4FD8-8658-7AD9315E5B94 Q38751146-051C89DC-AE26-4D69-9875-8CDF4E8B0AF7 Q38757603-366078ED-8BF2-45B8-B634-538FF6E7A493 Q38758205-ABEB5F57-DB65-47AE-A1D5-F98916E7AD3E Q38762944-BA877F88-A0F9-4D35-8135-3BDE5E58B3A5 Q38767151-6BB878D0-0AF3-4D97-B1DB-84F1E3BB6A5D Q38822368-7FE14DB1-0613-4F40-939B-58397F456A56 Q38834695-F76324A1-2D64-43C7-98A4-4490BB2C6693 Q38910371-7D063395-1EDA-44CC-90FC-04D5235F0A91 Q38949887-E25E7416-1439-45C6-AFCA-08222E108F41 Q38952577-7FFAEC09-4626-4811-B2C4-A971D2BFD32F Q38964375-1421A3FF-335A-4FEE-8418-090DF55DF0DB Q39014967-77EDAC1C-DFB5-4040-953A-3A05DFDAEC24

P2860

Metabolic Heterogeneity in Human Lung Tumors.

http://www.wikidata.org/entity/Q36578111

description

2016 nî lūn-bûn

@nan

2016年の論文

@ja

2016年論文

@yue

2016年論文

@zh-hant

2016年論文

@zh-hk

2016年論文

@zh-mo

2016年論文

@zh-tw

2016年论文

@wuu

2016年论文

@zh

2016年论文

@zh-cn

name

Metabolic Heterogeneity in Human Lung Tumors.

@ast

Metabolic Heterogeneity in Human Lung Tumors.

@en

type

label

Metabolic Heterogeneity in Human Lung Tumors.

@ast

Metabolic Heterogeneity in Human Lung Tumors.

@en

prefLabel

Metabolic Heterogeneity in Human Lung Tumors.

@ast

Metabolic Heterogeneity in Human Lung Tumors.

@en

P1433

Q36578111-2EEAF286-F40C-4716-A5C9-240B417C52C4

P1476

Q36578111-D7EFC893-9D7A-488A-ABDC-036CDB917CFA

P2093

Q36578111-027F4934-F2CE-4B37-800A-12B36A1B9F6E

Q36578111-04CCE500-5DA2-49F0-9103-94AAA5C3CD00

Q36578111-062CA7F3-3F38-4ECB-88CD-B715C8B2DF19

Q36578111-17251109-C70C-4E00-B297-6C943B9BED43

Q36578111-253A28BB-A308-4898-A029-2F2C15360B87

Q36578111-3A723F5F-4B21-4DFA-B4B3-95DD4E277F2D

Q36578111-4E34C908-685D-4125-AEA5-03784AD76063

Q36578111-54EB1B30-ACBB-46A5-8727-7D1E7F83D7AE

Q36578111-5D4A0DE1-2264-4EB8-B4CB-58D268048A14

Q36578111-69C2C352-043E-429C-8F46-A86010BFAA28

P2860

Q36578111-06F9207C-E650-4EFC-9F50-BA863BC801AD

Q36578111-07FECEF4-1AC5-4468-A26A-5BD639BF5115

Q36578111-0A4EC38E-67FE-45A7-9482-4F26DD95EB37

Q36578111-0C915C9D-8D3E-4BD1-BF2B-7F545F570EC2

Q36578111-193265E6-8FB6-49BB-BF97-3BA398FCFDD3

Q36578111-1B4EC0E7-385D-4CA6-9E6E-D76FC7DD718F

Q36578111-2454127C-D706-4B05-809B-EF207C750941

Q36578111-24B38E48-123D-43ED-A483-B659A823CC1C

Q36578111-2F7DFEBF-6F2D-4468-82B2-202A48BCEC64

Q36578111-300D9C42-B3D4-4EE3-AA59-8100BA57A193

P304

Q36578111-D4E1EC3D-2DDF-4643-98A0-4FB3EE712142

P31

Q36578111-6B226F45-F5D2-4D50-9D35-DEC9D58918EA

P356

Q36578111-D33B21AF-3AC4-4A1E-ABC3-DDB5DF4CB7A4

P407

Q36578111-3BFC27B7-E552-4935-955E-B3FD8BB521AF

P433

Q36578111-1A252712-E859-4200-BB51-1CBBFB910B99

P478

Q36578111-1BB79500-AE98-4576-861E-B889A0C66908

P50

Q36578111-7E6BBCAC-E0B3-4F74-97B7-6790FEF069CC

Q36578111-FA664B7F-DB3B-4CAD-9DF2-B2EC4D47B7E5

P577

Q36578111-5E5A6310-B448-43FB-879D-8836BFDB5E35

P698

Q36578111-2A8459D6-A045-429B-A5EE-32EA050E64B2

P932

Q36578111-7DC81534-0285-4099-A74A-3E2DE0FE8811

P356

J.CELL.2015.12.034

P1433

P1476

Metabolic Heterogeneity in Human Lung Tumors

@en

P2093

Bookyung Ko

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

Christopher T Hensley

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

Claire Klimko

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

Craig R Malloy

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

Dwight Oliver

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

Elizabeth McMillan

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

Eunsook Jin

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

Jiyeon Kim

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

Jose Torrealba

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

Kemp Kernstine

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

P2860

Hallmarks of Cancer: The Next Generation

A roadmap for interpreting (13)C metabolite labeling patterns from cells

Metabolic pathways promoting cancer cell survival and growth

Why do cancers have high aerobic glycolysis?

The biology of cancer: metabolic reprogramming fuels cell growth and proliferation

c-Myc suppression of miR-23a/b enhances mitochondrial glutaminase expression and glutamine metabolism

On respiratory impairment in cancer cells

Targeting lactate-fueled respiration selectively kills hypoxic tumor cells in mice

LKB1 modulates lung cancer differentiation and metastasis

Pyruvate carboxylase is critical for non-small-cell lung cancer proliferation.

P304

681-694

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

P31

scholarly article

P356

10.1016/J.CELL.2015.12.034

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

P407

P433

4

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

P478

164

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

P50

Robert E. Lenkinski

Brandon Faubert

P577

2016-02-04T00:00:00Z

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

P698

26853473

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

P932

4752889

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