about
Identification of hammerhead ribozymes in all domains of life reveals novel structural variationsThe biological microprocessor, or how to build a computer with biological partsMolecular Buffers Permit Sensitivity Tuning and Inversion of Riboswitch SignalsTracking, tuning, and terminating microbial physiology using synthetic riboregulators.A modern mode of activation for nucleic acid enzymes.Avoiding transcription factor competition at promoter level increases the chances of obtaining oscillation.Selecting RNA aptamers for synthetic biology: investigating magnesium dependence and predicting binding affinityNew molecular engineering approaches for crystallographic studies of large RNAsEnhanced killing of antibiotic-resistant bacteria enabled by massively parallel combinatorial geneticsFoundations for the design and implementation of synthetic genetic circuits.The ribonome: a dominant force in co-ordinating gene expressionReprogramming cellular behavior with RNA controllers responsive to endogenous proteinsPentatricopeptide repeats: modular blocks for building RNA-binding proteins.RNA-based computation in live cells.Direct selection for ribozyme cleavage activity in cellsBiocomputers: from test tubes to live cells.Synthetic biology: understanding biological design from synthetic circuits.Nanoinformatics and DNA-based computing: catalyzing nanomedicine.Use of RNA in drug design.A versatile framework for microbial engineering using synthetic non-coding RNAs.Ligand-induced folding of the guanine-sensing riboswitch is controlled by a combined predetermined induced fit mechanismMolecular dynamics simulation study of the binding of purine bases to the aptamer domain of the guanine sensing riboswitchA simple DNA gate motif for synthesizing large-scale circuits.Small hairpin RNA as a small molecule sensor.Exact calculation of loop formation probability identifies folding motifs in RNA secondary structures.Engineering protein-protein devices for multilayered regulation of mRNA translation using orthogonal proteases in mammalian cells
P2860
Q21145325-40E260A9-EF73-45D9-A04C-EEDF922C6ED6Q28660797-7947B6FC-47E6-4637-8D34-148D3EAA0FA2Q28829775-483EFAB2-37B2-4569-89BA-B53F4C9C6484Q30496523-1B0C38BD-92DC-4D30-A762-45F5C0A0B9C9Q33291764-335BDAED-551F-4CA7-BC35-A856D8DB07DEQ33579512-1F340963-669C-42A5-8062-D82B3A2CFF0AQ33812374-DCBBE98A-FB8C-4E99-BC76-38DEB5F9566BQ34021859-72B6C62C-558A-4B81-8FBB-DD135985AF28Q34119921-7D52A78C-FF7B-4D87-80AB-E41BA4ED0B0DQ34273084-CA81FAA0-0455-4D3A-9120-70AA009AC457Q35095098-0956D944-AA93-481D-8B97-0BEB69FBED23Q35209673-E09A69BC-FCE2-49F8-9BF6-68EEA7371250Q37381218-DCC76F35-F95C-4F73-9559-3B76C129FEEDQ37392994-1F2F62FA-4F05-4DA9-9561-ADADEF30C57CQ37393572-9C1F3F8A-380F-422E-AFBE-6EBF425815E2Q37534322-F372A562-8408-44F9-A886-C3189569E402Q37629608-2724E5B3-F610-402E-BF57-CC6AA3AC5F0FQ37684724-1AE979D0-3A87-49D4-A9FD-7DCCFC238DE4Q38089160-F272072D-4E2E-440C-A614-2CD36CA207F0Q38204896-19D4CDB2-2CF0-4C75-B5D0-C0B6707EA674Q38297052-A1488912-3A74-44FB-B154-CA446CB6722DQ38353288-A0329506-6F8C-4D3B-AD31-1DE50FF31DA4Q39969610-7552A0AA-F5F9-4008-AF19-84D32FF9EEB9Q43243058-C65FA9BA-6F43-45DC-8C91-BF9B5F4C289EQ46543742-99B1648D-ECBC-4223-A5B1-5429C56C4D14Q57804750-C85B7DF6-9710-4592-A550-EF8A0F71C5C0
P2860
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Synthetic RNA circuits.
@ast
Synthetic RNA circuits.
@en
type
label
Synthetic RNA circuits.
@ast
Synthetic RNA circuits.
@en
prefLabel
Synthetic RNA circuits.
@ast
Synthetic RNA circuits.
@en
P2860
P356
P1476
Synthetic RNA circuits.
@en
P2093
Andrew D Ellington
Eric A Davidson
P2860
P2888
P356
10.1038/NCHEMBIO846
P577
2007-01-01T00:00:00Z