BBa_K2044006BBa_K2044006 Version 1 (Component)Based on our project,<3,6> is the direct pathway from Site No.3 to Site No.6 in the map we design.
BBa_K2044004BBa_K2044004 Version 1 (Component)Based on our project, <2,4> is the direct pathway from Site No.2 to Site No.4 in the map we design.
BBa_K2044009BBa_K2044009 Version 1 (Component)Based on our project, <4,8> is the direct pathway from Site No.4 to Site No.8 in the map we design.
BBa_K2044014BBa_K2044014 Version 1 (Component)Based on our project, <1,4> is the direct pathway from Site No.1 to Site No.4 in the map we design.
BBa_K2044007BBa_K2044007 Version 1 (Component)Based on our project, <4,5> is the direct pathway from Site No.4 to Site No.5 in the map we design.
BBa_K2044013BBa_K2044013 Version 1 (Component)Based on our project,<7,8> is the direct pathway from Site No.7 to Site No.8 in the map we design.
BBa_K2044008BBa_K2044008 Version 1 (Component)Based on our project, <4,6> is the direct pathway from Site No.4 to Site No.6 in the map we design.
BBa_K2044003BBa_K2044003 Version 1 (Component)Based on our project, <2,3> is the direct pathway from Site No.2 to Site No.3 in the map we design.
BBa_K2044002BBa_K2044002 Version 1 (Component)Based on our project, <2,1> is the direct pathway from Site No.2 to Site No.1 in the map we design.
BBa_K2044005BBa_K2044005 Version 1 (Component)Based on our project, <2,6> is the direct pathway from Site No.2 to Site No.6 in the map we design.
BBa_K2044012BBa_K2044012 Version 1 (Component)Based on our project, <6,8> is the direct pathway from Site No.6 to Site No.8 in the map we design.
BBa_K2044011BBa_K2044011 Version 1 (Component)Based on our project,<6,4> is the direct pathway from Site No.6 to Site No.4 in the map we design.
BBa_J04795BBa_J04795 Version 1 (Component)Riboswitch designed to turn "ON" a protein
BBa_I763003BBa_I763003 Version 1 (Component)GFP coding device switched on by IPTG
placIQ RBSBBa_K193604 Version 1 (Component)GFP behind a constitutive promoter (placIQ) on pSB4A5
BBa_K1051356BBa_K1051356 Version 1 (Component)K1051301(clb2 promoter) + K1051053(K1051001 (non stop codon ECFP + K1051006 (Stop codon + TBY-1 term
BBa_K165100BBa_K165100 Version 1 (Component)Gli1 bs + LexA bs + mCYC + LexA repressor (mCherryx2 tagged) on pRS304*
BBa_K165101BBa_K165101 Version 1 (Component)Zif268-HIV bs + LexA bs + mCYC + Zif268-HIV repressor (mCherryx2 tagged) on pRS304*
SEGASEGA_collection Version 1 (Collection)In the Standardized Genome Architecture (SEGA), genomic integration of DNA fragments is enabled by λ-Red recombineering and so-called landing pads that are a common concept in synthetic biology and typically contain features that i) enable insertion of additional genetic elements and ii) provide well-characterized functional parts such as promoters and genes, and iii) provides insulation against genome context-dependent effects. The SEGA landing pads allow for reusable homology regions and time-efficient construction of parallel genetic designs with a minimal number of reagents and handling steps. SEGA bricks, typically synthetic DNA or PCR fragments, are integrated on the genome simply by combining the two reagents (i.e. competent cells and DNA), followed by incubation steps, and successful recombinants are identified by visual inspection on agar plates. The design of the SEGA standard was heavily influenced by the Standard European Vector Architecture (SEVA). SEGA landing pads typically hosts two major genetic “control elements” that influence gene expression on the transcriptional (C1), and translational (C2) level. Furthermore, landing pads contain gadgets such as selection and counterselection markers.
Intein_assisted_Bisection_MappingIntein_assisted_Bisection_Mapping_collection Version 1 (Collection)Split inteins are powerful tools for seamless ligation of synthetic split proteins. Yet, their use remains limited because the already intricate split site identification problem is often complicated by the requirement of extein junction sequences. To address this, we augmented a mini-Mu transposon-based screening approach and devised the intein-assisted bisection mapping (IBM) method. IBM robustly revealed clusters of split sites on five proteins, converting them into AND or NAND logic gates. We further showed that the use of inteins expands functional sequence space for splitting a protein. We also demonstrated the utility of our approach over rational inference of split sites from secondary structure alignment of homologous proteins. Furthermore, the intein inserted at an identified site could be engineered by the transposon again to become partially chemically inducible, and to some extent enabled post-translational tuning on host protein function. Our work offers a generalizable and systematic route towards creating split protein-intein fusions and conditional inteins for protein activity control.