Molecular crowding shapes gene expression in synthetic cellular nanosystems.
about
Investigating transcription reinitiation through in vitro approachesEngineering protocells: prospects for self-assembly and nanoscale production-linesThe biology of boundary conditions: cellular reconstitution in one, two, and three dimensionsEnhancement of biological reactions on cell surfaces via macromolecular crowding.Synthetic biology outside the cell: linking computational tools to cell-free systemsMechanotransduction in intervertebral discsStochastic Simulation of Biomolecular Networks in Dynamic EnvironmentsThe Global Relationship between Chromatin Physical Topology, Fractal Structure, and Gene ExpressionMacromolecular crowding as a regulator of gene transcription.Parallel solutions for voxel-based simulations of reaction-diffusion systems.Connecting the dots: the effects of macromolecular crowding on cell physiology.Synthetic Biology: A Bridge between Artificial and Natural CellsCarbon catabolite repression correlates with the maintenance of near invariant molecular crowding in proliferating E. coli cells.Efficient search, mapping, and optimization of multi-protein genetic systems in diverse bacteria.Crowding induces complex ergodic diffusion and dynamic elongation of large DNA molecules.Sealable femtoliter chamber arrays for cell-free biology.Towards self-assembled hybrid artificial cells: novel bottom-up approaches to functional synthetic membranes.Macromolecular Crowding Regulates the Gene Expression Profile by Limiting Diffusion.How can macromolecular crowding inhibit biological reactions? The enhanced formation of DNA nanoparticles.Cajal bodies are linked to genome conformationX-ray characterization of mesophases of human telomeric G-quadruplexes and other DNA analogues.The engineering of artificial cellular nanosystems using synthetic biology approaches.Designer cell signal processing circuits for biotechnology.The role of mechanics in biological and bio-inspired systems.Artificial cell mimics as simplified models for the study of cell biology.Cajal body function in genome organization and transcriptome diversity.Cell-Free Systems Based on CHO Cell Lysates: Optimization Strategies, Synthesis of "Difficult-to-Express" Proteins and Future Perspectives.Role of Proteome Physical Chemistry in Cell Behavior.Minimal synthetic cells to study integrin-mediated adhesion.Macromolecular crowding directs the motion of small molecules inside cells.Filling polymersomes with polymers by peroxidase-catalyzed atom transfer radical polymerization.The Greater Genomic Landscape: The Heterogeneous Evolution of Cancer.A moldable putty containing silk fibroin yolk shell particles for improved hemostasis and bone repair.Nanoscale Structural Plasticity of the Active Zone Matrix Modulates Presynaptic Function.Engineering genetic circuit interactions within and between synthetic minimal cellsNetwork motifs modulate druggability of cellular targets.The Role of Chromatin Density in Cell Population Heterogeneity during Stem Cell Differentiation.Complexity of molecular crowding in cell-free enzymatic reaction networks.Rapid access to phospholipid analogs using thiol-yne chemistry.Molecular finite-size effects in stochastic models of equilibrium chemical systems.
P2860
Q26824513-ADB01374-BF54-4E74-9CFC-EFC3C1592F42Q27010455-1F874FE9-178A-431C-B942-DDCB530C3435Q27012970-375F734D-28AC-44B2-AA91-9751B3050F41Q27324653-BC74D9A1-B0E8-4BBA-AC07-184BFFA4C390Q28085024-0D953803-B1A3-4281-80D0-F72C51F22798Q28543051-7B9E6ADD-3D0F-475B-971F-61643AC0DB62Q28552548-45366E2B-25E9-42A3-91C4-E81882FF5952Q28818455-677B90F9-34B8-41C3-BC99-7D0263E2BEC9Q33561494-A3755998-7E57-4D0C-AD1D-E7FB0A6F62B4Q33850042-5633767B-3C43-4F13-ACD1-09D18D7A6DA6Q34454279-47CEE5A3-8271-4A98-8DFE-7A0F01522FDFQ34829709-31E87F54-1DEE-49A2-9640-05DA6F9CF1B3Q35065247-1AE5330C-A6E3-4328-A30C-837C55B3CB41Q35192734-AD48D8B3-3E46-445A-BCDA-2C7B9A4B16B0Q35221715-A8289CBF-BE8E-4185-86DC-896030840707Q35459400-35137AEC-A057-42E2-BEBE-A39F700B890DQ36199094-49766F33-7156-4196-9D28-EAD9A66E876EQ36205485-B75F16FD-DB73-4C13-8065-42E515457A06Q36605957-D261AB38-A1AE-4A9F-9EB3-93D8B70353A4Q36713390-471A4984-20DC-4FBF-B9EE-91FAF648269BQ36959471-D691E413-DE99-44D8-87F5-FE261CCE6DF1Q38199457-20EA3060-EC24-4625-BBA3-DCC9489804FBQ38314510-60318873-55E1-414F-98F4-8E60E4C08792Q38543007-5D14B435-2987-4424-8520-E0D83AC7008AQ38674809-4E9CB2E2-75BE-40BF-91C3-F3372602406FQ38808242-FBF3A5C7-FB78-4F6B-9E70-4622BDF80EB3Q38816515-FEFCBB91-9F33-443D-86E4-8A1F62F4DA44Q38924689-39366A7D-4AAD-4AE5-A1D2-C83C1A50B0DAQ40643019-9A77F743-B63E-481D-98C4-DC2E003D4BC4Q40984695-0E0C160E-2FDC-46AC-AB97-3A18183694ECQ41606425-CCFFCB6B-834D-4659-A7A6-0C5B2430B08EQ41608657-100F6330-A579-4FF8-A248-2B2071780E1DQ42001245-17AD1922-6DF8-42C2-8226-5F02EEF851CBQ42142389-45986548-EF12-4A44-B463-16316F2F2126Q42290368-7D2CD8CE-0697-4EE6-816C-F9439216FA6CQ42372160-98796AE0-EA04-4DB6-AF9C-B6DA10BA9504Q42656948-64D74C79-98A6-45D5-8451-B894B39F6B14Q44114011-40D8DD2F-D5DA-4135-9E95-411F2EE08F8BQ46073448-485A31FA-2189-40F3-87D8-45213C74E3B6Q46587099-1C3BF64A-4070-4CD0-B066-9A1A01DC86AD
P2860
Molecular crowding shapes gene expression in synthetic cellular nanosystems.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
2013年學術文章
@zh
2013年學術文章
@zh-hant
name
Molecular crowding shapes gene expression in synthetic cellular nanosystems.
@en
type
label
Molecular crowding shapes gene expression in synthetic cellular nanosystems.
@en
prefLabel
Molecular crowding shapes gene expression in synthetic cellular nanosystems.
@en
P2860
P50
P356
P1476
Molecular crowding shapes gene expression in synthetic cellular nanosystems.
@en
P2093
Saumya Saurabh
P2860
P2888
P304
P356
10.1038/NNANO.2013.132
P407
P577
2013-07-14T00:00:00Z
P5875
P6179
1014359662