BBa_K861070BBa_K861070 Version 1 (Component)AdrA gene from E.coli K12
BBa_K861090BBa_K861090 Version 1 (Component)YhjH Gene From <i>E.coli str. K12</i>
BBa_K863030BBa_K863030 Version 1 (Component)tvel5 laccase cDNA sequence from Trametes versicolor
BBa_K863012BBa_K863012 Version 1 (Component)tthl laccase from T. thermophilus with constitutive promoter J23100, RBS and His-tag
BBa_K863034BBa_K863034 Version 1 (Component)pcil35 laccase cDNA sequence from Pycnoporus cinnabarinus
LipABBa_K836000 Version 1 (Component)lipA from B. cepacia (codon usage optimized for E. coli)
DGATBBa_K836001 Version 1 (Component)O-acyltransferase WSD from Acinetobacter sp. (codon usage optimized for R. opacus)
DGATBBa_K836002 Version 1 (Component)O-acyltransferase WSD from Acinetobacter sp. (codon usage optimized for R. opacus) as used
lipABBa_K836003 Version 1 (Component)lipA from B. cepacia (codon usage optimized for E. coli)
BBa_K750005BBa_K750005 Version 1 (Component)LuxI expression device activated by arabinose(Regulated by RBS of 0.01 strength)
BBa_K759003BBa_K759003 Version 1 (Component)phaA (beta-ketothiolase orgin from Ralstonia eutropha)
BBa_K759004BBa_K759004 Version 1 (Component)phaA (beta-ketothiolase orgin from Ralstonia eutropha)
BBa_K863020BBa_K863020 Version 1 (Component)bhal laccase from Bacillus halodurans with T7 promoter, RBS and His-tag
BBa_K759005BBa_K759005 Version 1 (Component)phaB (acetoacetyl-CoA reductase orgin from Ralstonia eutropha)
BBa_K759006BBa_K759006 Version 1 (Component)B0034 and phaA (beta-ketothiolase orgin from Ralstonia eutropha)
gpSBBa_K836004 Version 1 (Component)Lysis inhibitor from Enterobacteria phage lambda (codon usage optimized for R. opacus)
BBa_K750008BBa_K750008 Version 1 (Component)Quorum sensing system based on LuxI and LuxR to control the expression of parts behind
TD1.0BBa_K750009 Version 1 (Component)TIME DELAY1.0:LuxI(RBS1.0)->LuxR->LuxPR->GFP
TD0.6BBa_K750010 Version 1 (Component)TIME DELAY 0.6:LuxI(RBS0.6)->LuxR->LuxPR->GFP
TD0.3BBa_K750011 Version 1 (Component)TIME DELAY0.3:LuxI(RBS0.3)->LuxR->LuxPR->GFP
TD0.01BBa_K750012 Version 1 (Component)TIME DELAY0.01:LuxI(RBS0.01)->LuxR->LuxPR->GFP
BBa_K836005BBa_K836005 Version 1 (Component)Lysozyme from Rhodococcus phage RER2 (codon usage optimized for R, opacus)
BBa_K759007BBa_K759007 Version 1 (Component)RBS(B0034)and phaB (acetoacetyl-CoA reductase orgin from Ralstonia eutropha)
gpSBBa_K836006 Version 1 (Component)Lysis protein S from Enterobacteria phage lambda (codon usage optimized for R. opacus)
nitRBBa_K836007 Version 1 (Component)Nitrilase regulator from R. rhodochrous (codon usage optimized for R. opacus)
BBa_K102906BBa_K102906 Version 1 (Component)TA8 gate from synthetic algorithm v1.1
BBa_K102907BBa_K102907 Version 1 (Component)TA9 gate from synthetic algorithm v1.1
BBa_K102908BBa_K102908 Version 1 (Component)TA10 gate from synthetic algorithm v1.1
BBa_K102909BBa_K102909 Version 1 (Component)TA11 gate from synthetic algorithm v1.1
BBa_K102910BBa_K102910 Version 1 (Component)TA12 gate from synthetic algorithm v1.1
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.
BBa_K131021BBa_K131021 Version 1 (Component)R0040+K131016
BBa_K102911BBa_K102911 Version 1 (Component)TA13 gate from synthetic algorithm v1.2
p_qrr4BBa_K131017 Version 1 (Component)p_qrr4 from <I>Vibrio harveyi</I>
BBa_K131026BBa_K131026 Version 1 (Component)AHL inducible GFP
BBa_K102101BBa_K102101 Version 1 (Component)TA10 gate in output test harness
BBa_K102111BBa_K102111 Version 1 (Component)TA11 gate in output test harness
BBa_K102121BBa_K102121 Version 1 (Component)TA12 gate in output test harness
BBa_K102131BBa_K102131 Version 1 (Component)TA13 gate in output test harness
BBa_K102141BBa_K102141 Version 1 (Component)TA14 gate in output test harness
BBa_K102102BBa_K102102 Version 1 (Component)TA10In anti-sense input in test harness
BBa_K102112BBa_K102112 Version 1 (Component)TA11In anti-sense input in test harness
BBa_K102122BBa_K102122 Version 1 (Component)TA12In anti-sense input in test harness
BBa_K102132BBa_K102132 Version 1 (Component)TA13In anti-sense input in test harness
BBa_K102142BBa_K102142 Version 1 (Component)TA14In anti-sense input in test harness
BBa_K102905BBa_K102905 Version 1 (Component)TA7 gate from synthetic algorithm v1.1
BBa_K082030BBa_K082030 Version 1 (Component)luxI generator on PSB3C5
BBa_K082029BBa_K082029 Version 1 (Component)LuxI generator