BBa_I8021BBa_I8021 Version 1 (Component)Booperator test: RhlR biasing, RhlR/LuxR crosstalk
BBa_I8020BBa_I8020 Version 1 (Component)Booperator test: LuxR biasing, LuxR/RhlR crosstalk
s1+s2+s3BBa_K2027045 Version 1 (Component)Long Bacterial Collagen Fiber Monomer without Cross-linking Domains
BBa_K1091001BBa_K1091001 Version 1 (Component)green fluorescent protein with a fast translation speed
BBa_K2088006BBa_K2088006 Version 1 (Component)It encodes a kind of protein named 2Fe-2S ferredoxin, a 2Fe-2S iron-sulfur cluster binding domain. I
BBa_J04631BBa_J04631 Version 1 (Component)BBa_J04031 GFP (RBS-, LVA+) and B0015 (Intermediate Building Sequence)
BBa_J04651BBa_J04651 Version 1 (Component)BBa_J04051 RFP (RBS-, LVA+) and B0015 (Intermediate Building Sequence)
BBa_I8025BBa_I8025 Version 1 (Component)Booperator test: RhlR biasing, RhlR/LuxR/LasR crosstalk
BBa_I8026BBa_I8026 Version 1 (Component)Booperator test: LasR biasing, LasR/LuxR/RhlR crosstalk
BBa_I8024BBa_I8024 Version 1 (Component)Booperator test: LuxR biasing, LuxR/RhlR/LasR crosstalk
BBa_I8023BBa_I8023 Version 1 (Component)Booperator test: Inverter NOR biasing in polycistronic design
BBa_I8022BBa_I8022 Version 1 (Component)Booperator test: Inverter NOR biasing in monocistronic design
BBa_K1994035BBa_K1994035 Version 1 (Component)Multiple dCas9 binding site sequence with binding sequence positions shown
BBa_K801032BBa_K801032 Version 1 (Component)GAL4 DNA binding domain
BBa_I721004BBa_I721004 Version 1 (Component)Lead Binding Protein + Promoter (version a)
BBa_K2082252BBa_K2082252 Version 1 (Component)RFP under the control of an optimized lacZ promoter with lambda cI binding site combined with SH2:cI
BBa_K105101BBa_K105101 Version 1 (Component)Gal4 - DNA binding domain
BBa_K105100BBa_K105100 Version 1 (Component)LacI - DNA binding domain
BBa_J22000BBa_J22000 Version 1 (Component)DnaA binding sequence - Px
BBa_K1461309BBa_K1461309 Version 1 (Component)pCMV-RBS-GFP-4 miR 142 5p non-bindgin sites-d.term
BBa_K1777012BBa_K1777012 Version 1 (Component)sequence-specific RNA binding protein
BBa_K1777014BBa_K1777014 Version 1 (Component)sequence-specific RNA binding protein
BBa_K1777013BBa_K1777013 Version 1 (Component)sequence-specific RNA binding protein
BBa_K1777004BBa_K1777004 Version 1 (Component)sequence-specific RNA binding protein
BBa_K242300BBa_K242300 Version 1 (Component)multi-Ler binding site +promoter 1
BBa_K923005BBa_K923005 Version 1 (Component)Ribosome Binding Site in pET14b plasmid
BBa_K1412088BBa_K1412088 Version 1 (Component)A combination of theophylline aptamer and taRNA that can response theophylline to regulate circuit
BBa_J58008BBa_J58008 Version 1 (Component)Periplasmic binding protein that docks a vanillin molecule
BBa_J64863BBa_J64863 Version 1 (Component)Strong OmpR Binding Operon for Team Challenge 03-2007
BBa_K1778005BBa_K1778005 Version 1 (Component)eGFP:enhanced Green Fluorescent Protein. It???s the mutant of GFP. It is widely used as report gene
BBa_I758600BBa_I758600 Version 1 (Component)Screen for binding affinity of mutant cI lambda to promotor sites
BBa_I720010BBa_I720010 Version 1 (Component)Ara landing pad (pBBLP 8)
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.