A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
about
Tunable and multifunctional eukaryotic transcription factors based on CRISPR/CasSynthetic biology in mammalian cells: next generation research tools and therapeuticsSynthetic analog and digital circuits for cellular computation and memoryRNA-guided gene activation by CRISPR-Cas9-based transcription factorsArtificial cell-cell communication as an emerging tool in synthetic biology applicationsThe biological microprocessor, or how to build a computer with biological partsEngineering Stem Cell OrganoidsRule-based design of synthetic transcription factors in eukaryotes.Modular extracellular sensor architecture for engineering mammalian cell-based devices.A unified design space of synthetic stripe-forming networks.Modular, rule-based modeling for the design of eukaryotic synthetic gene circuits.Transplantation of prokaryotic two-component signaling pathways into mammalian cells.Principles of genetic circuit design.Gateway vectors for efficient artificial gene assembly in vitro and expression in yeast Saccharomyces cerevisiae.Modular construction of mammalian gene circuits using TALE transcriptional repressors.Signal-to-Noise Ratio Measures Efficacy of Biological Computing Devices and Circuits.Engineering synthetic TAL effectors with orthogonal target sites.Engineering robust control of two-component system phosphotransfer using modular scaffolds.Locked and proteolysis-based transcription activator-like effector (TALE) regulationRapid generation of CRISPR/dCas9-regulated, orthogonally repressible hybrid T7-lac promoters for modular, tuneable control of metabolic pathway fluxes in Escherichia coliCellular heterogeneity mediates inherent sensitivity-specificity tradeoff in cancer targeting by synthetic circuits.Tuning response curves for synthetic biology.Two- and three-input TALE-based AND logic computation in embryonic stem cells.Mammalian synthetic biology for studying the cell.Synthetic biology: advancing the design of diverse genetic systemsIn pursuit of design principles of regulatory sequences.Designer cell signal processing circuits for biotechnology.Directed evolution of a synthetic RNA-protein module to create a new translational switch.Mammalian synthetic biology: emerging medical applications.Split-inteins and their bioapplications.Multiplexing Engineered Receptors for Multiparametric Evaluation of Environmental Ligands.Engineering Gene Circuits for Mammalian Cell-Based Applications.A bistable genetic switch based on designable DNA-binding domains.Protein scaffold-activated protein trans-splicing in mammalian cellsAmplifying genetic logic gates.A split intein T7 RNA polymerase for transcriptional AND-logic.DNA sense-and-respond protein modules for mammalian cells.From dead leaf, to new life: TAL effectors as tools for synthetic biology.Current Technologies Based on the Knowledge of the Stem Cells Microenvironments.Surface charge tuneable fluorescent protein-based logic gates for smart delivery of nucleic acids.
P2860
Q24606465-F1F3B2D0-F843-49C3-8EB9-ACADE8D44475Q26995293-3F17219C-9455-4879-AC53-8DBBCB9377F3Q26998440-23A23B2E-4545-4D8D-A265-4277DB21163AQ28295458-CDF3323F-B723-440F-BEFC-818DD92248A3Q28628307-E6EB6463-669F-40FC-BD5F-2CA865C60E11Q28660797-16F8CF67-3FFC-4DEF-A008-0C6DEFF60CE4Q28973598-A5050704-D194-457A-855A-C81C458EB28DQ33901124-6C611017-EC4E-4EEF-A5D0-3A188E92DDFEQ34167797-BF0615C5-3100-42DA-8DC9-117EF3A6A6E7Q34234539-3365D05A-22CA-4E7D-A2F2-6B6E777B6582Q34346565-01539A00-DEF8-440B-A0C5-F5ACC20AAD5BQ34480721-8E342C70-5907-4EA5-8CA1-A55D4871E297Q34502550-779F9D32-7911-4238-B674-F9D648BA6502Q34723380-8AB62738-376A-4323-8E4E-9BE6C2007A54Q35096976-62B8C349-A9DF-4369-B328-5A673667B862Q35692350-093A5DD2-D802-4CCB-B2C5-4BE9E9A2C60EQ36180234-402679F0-574C-44B6-83C9-B2522847956BQ36398053-973A576C-49FE-4C73-BECD-2DC9E21CA3DEQ36588954-60C0D02A-C6E5-4DBC-B7D4-AF087E50981CQ36914633-29DC30B6-EDC6-4E5D-BBDC-7CE9593F1596Q37126699-6F8F49A7-0F66-48FE-920D-57619F4B0EB4Q37247748-AF7C4C73-DA79-4090-A763-E879A8B8FA15Q37327607-8F77B29F-37E6-448E-A682-EC5D0B906029Q37576628-4D5D83CF-F2AD-4554-BFCC-4C50B0DF2551Q38081904-704489B8-CFA9-4547-98BB-3D82C121C7C0Q38218965-BAF14A6F-6889-429D-8381-2B8997D096C4Q38314510-F3790D74-C1D0-4F61-BACF-46487E5A9E1DQ38317966-00F81F11-8999-4A68-B2FB-B2F650021648Q38390803-BC86D650-ACA1-4072-9CAF-82D1F3FDA573Q38543782-822CBB60-4DBB-463F-972C-3025FC079701Q38647622-25271B10-A9AC-4557-9679-82FE12C08F2BQ38837855-7C9464F6-DA19-48C9-BAE4-2AF36396FBC1Q38952478-1D80CD67-57DF-4B24-9366-947003F7C82AQ39132822-0831B2F6-7D8F-42F0-A1F4-308DEE6A671EQ40101578-E217C912-9867-44D0-8196-E86F558BF7BBQ40225098-A0F50716-0A24-470D-A156-78133D6EE91EQ40989999-016CFF46-96E4-4295-9C18-150B298E3987Q44848243-14302A9F-2EF6-4430-8EA0-33D065A6A067Q47284554-60DB2C44-0731-4FB7-8A02-9F54D9DB8B26Q47612068-3DD0F8C5-7D98-4BC9-B3D8-212F1F0629C9
P2860
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
@en
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells.
@nl
type
label
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
@en
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells.
@nl
prefLabel
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
@en
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells.
@nl
P2860
P356
P1476
A tunable zinc finger-based framework for Boolean logic computation in mammalian cells
@en
P2093
Jason J Lohmueller
Thomas Z Armel
P2860
P304
P356
10.1093/NAR/GKS142
P407
P577
2012-02-09T00:00:00Z