BBa_K2066508 1 BBa_K2066508 Modified pLacO-1 Promoter (Lou et. al 2012) 2016-08-30T11:00:00Z 2016-08-31T09:01:04Z Part sequence inspired by Lou et al. 2012 (???Ribozyme-based insulator parts buffer synthetic circuits from genetic context???) This promoter sequence is modified from section V of Supplementary Material of Lou et al. The Supplementary sequence contains 98bp of the end of BioBrick backbone pSB1C3, followed by an EcoRI site and an XbaI site, then 20bp of the beginning of pTac (as described in fig. S1), before beginning the sequence of plLacO-1 (as described in fig. S1). Here we use only the 20bp of pTac followed by the plLacO-1 sequence as described in fig. S1. WM iGEM 2016 used this part for our Ribozyme Characterization project. false false _2534_ 31541 31541 9 false Design inspired by Lou et al. 2012 (???Ribozyme-based insulator parts buffer synthetic circuits from genetic context???) so that constitutive LacI repressor can bind to it. false Likhitha Kolla BBa_K2066018 1 BBa_K2066018 UNS 2 Sequence, from Torella et al., 2013 2016-07-11T11:00:00Z 2016-10-19T05:41:43Z Torella, J. P., Boehm, C. R., Lienert, F., Chen, J. H., Way, J. C., & Silver, P. A. (2013). Rapid construction of insulated genetic circuits via synthetic sequence-guided isothermal assembly. Nucleic acids research, gkt860. This is Unique Nucleotide Sequence 2, (UNS 2), from Torella et al., 2013. The William and Mary iGEM team has adopted this as our standard prefix; as such, all of our parts will have this sequence immediately following the BioBrick prefix. We took this measure in order to allow easier Gibson Assembly cloning of our parts. Primer sequences which can be used to clone with the UNS 2/3 standard can be found on our wiki. false false _2534_ 31544 27446 9 false UNS 2 was chosen because it works well with UNS 3 and it is in accordance with the BioBrick standard. false Kalen Clifton, Christine Gao, Andrew Halleran, Ethan Jones, Likhitha Kolla, Joseph Maniaci, John Marken, John Mitchell, Callan Monette, Adam Reiss BBa_K2066530 1 BBa_K2066530 TACTAG spacer 2016-10-11T11:00:00Z 2016-10-12T01:25:53Z n/a TACTAG spacer, exists so that we can manually insert correct scar sequences false false _2534_ 27446 27446 9 false n/a false Joseph L Maniaci BBa_K2066509 1 BBa_K2066509 sfGFP 2016-08-30T11:00:00Z 2016-10-19T02:54:25Z The sequence for this sfGFP reporter gene is modified from Lou et al. Supplement section V. This is the sequence of superfolder GFP BBa_I746916, but with four codon modifications to match WM16_015: at position 441, G->T. At 446, C->T. At 495, T->C. At 562, C->A. The part is a reporter used for K2066014. false false _2534_ 31541 31541 9 false Design inspired by Lou et. al. 2012 false Likhitha Kolla BBa_B0034 1 BBa_B0034 RBS (Elowitz 1999) -- defines RBS efficiency 2003-01-31T12:00:00Z 2015-08-31T04:07:20Z Released HQ 2013 RBS based on Elowitz repressilator. false true _1_ 0 24 7 In stock false Varies from -6 to +1 region from original sequence to accomodate BioBricks suffix. <p>No secondary structures are formed in the given RBS region. Users should check for secondary structures induced in the RBS by upstream and downstream elements in the +50 to -50 region, as such structures will greatly affect the strength of the RBS. Contact info for this part: <a href="mailto:(bchow@media.mit.edu)">Brian Chow</a> true Vinay S Mahajan, Voichita D. Marinescu, Brian Chow, Alexander D Wissner-Gross and Peter Carr IAP, 2003. annotation23325 1 conserved range23325 1 5 8 BBa_K2066019 1 BBa_K2066019 UNS 3 Sequence, from Torella et al., 2013 2016-07-11T11:00:00Z 2016-10-19T05:43:00Z Torella, J. P., Boehm, C. R., Lienert, F., Chen, J. H., Way, J. C., & Silver, P. A. (2013). Rapid construction of insulated genetic circuits via synthetic sequence-guided isothermal assembly. Nucleic acids research, gkt860. This is Unique Nucleotide Sequence 3, (UNS 3), from Torella et al., 2013. The William and Mary iGEM team has adopted this as our standard prefix; as such, all of our parts will have this sequence immediately following the BioBrick prefix. We took this measure in order to allow easier Gibson Assembly cloning of our parts. Primer sequences which can be used to clone with the UNS 2/3 standard can be found on our wiki. The sequence for this part came from the following paper: Torella, J. P., Boehm, C. R., Lienert, F., Chen, J. H., Way, J. C., & Silver, P. A. (2013). Rapid construction of insulated genetic circuits via synthetic sequence-guided isothermal assembly. Nucleic acids research, gkt860. A huge thanks to all the researchers involved in its original creation! false false _2534_ 31544 27446 9 false This UNS sequence was chosen to serve as the 3' primer in our standard because it works well with UNS 2 and it adheres to the BioBrick standards. false Kalen Clifton, Christine Gao, Andrew Halleran, Ethan Jones, Likhitha Kolla, Joseph Maniaci, John Marken, John Mitchell, Callan Monette, Adam Reiss BBa_B0015 1 BBa_B0015 double terminator (B0010-B0012) 2003-07-16T11:00:00Z 2015-08-31T04:07:20Z Released HQ 2013 Double terminator consisting of BBa_B0010 and BBa_B0012 false true _1_ 0 24 7 In stock false true Reshma Shetty component1916612 1 BBa_B0012 component1916610 1 BBa_B0010 annotation1916612 1 BBa_B0012 range1916612 1 89 129 annotation1916610 1 BBa_B0010 range1916610 1 1 80 BBa_K2066506 1 BBa_K2066506 RiboJ (Ribozyme Insulator) Lou et. al. 2012 2016-08-30T11:00:00Z 2016-10-12T12:27:33Z Part sequence is from Lou et al. 2012, Supplemental Section V (???Ribozyme-based insulator parts buffer synthetic circuits from genetic context???). RiboJ is the sequence for a ribozyme studied in Lou et. al 2012 ("Ribozyme-based insulator parts buffer synthetic circuits from genetic context"). WM iGEM 2016 used this sequence between the promoter and ribosome sequence. One of our goals for using this part is moving it onto a Biobrick backbone. Furthermore, In Lou et. al, this ribozyme sequence was said to act as an insulator which generalizes protein expression levels for a given promoter. We used RiboJ to collect data for our Ribozyme characterization project as well as our ribosome and promoter characterization projects. false false _2534_ 27446 31541 9 false We designed this part to use as an insulator and also move this riboJ sequence onto a Biobrick backbone. false Likhitha Kolla BBa_B0012 1 BBa_B0012 TE from coliphageT7 2003-01-31T12:00:00Z 2015-08-31T04:07:20Z Derived from the TE terminator of T7 bacteriophage between Genes 1.3 and 1.4 <genbank>V01146</genbank>. Released HQ 2013 Transcription terminator for the <i>E.coli</i> RNA polymerase. false false _1_ 0 24 7 In stock false <P> <P>Suggested by Sri Kosuri and Drew Endy as a high efficiency terminator. The 5' end cutoff was placed immediately after the TAA stop codon and the 3' end cutoff was placed just prior to the RBS of Gene 1.4 (before AAGGAG).<P> Use anywhere transcription should be stopped when the gene of interest is upstream of this terminator. false Reshma Shetty annotation1690 1 polya range1690 1 28 41 annotation7020 1 BBa_B0012 range7020 1 1 41 annotation1687 1 stop range1687 1 34 34 annotation1686 1 T7 TE range1686 1 8 27 BBa_B0010 1 BBa_B0010 T1 from E. coli rrnB 2003-11-19T12:00:00Z 2015-08-31T04:07:20Z Transcriptional terminator consisting of a 64 bp stem-loop. false false _1_ 0 24 7 In stock false true Randy Rettberg annotation7018 1 BBa_B0010 range7018 1 1 80 annotation4184 1 stem_loop range4184 1 12 55 BBa_K2066035 1 BBa_K2066035 B0034 IPTG-inducible RBS Measurement Part 2016-10-13T11:00:00Z 2016-10-14T12:04:09Z This part was assembled from existing BioBrick parts This part is part of William and Mary iGEM 2016's library of IPTG-inducible RBS characterization parts. It contains the RBS BBa_B0034. The part codes for the expression of a superfolder GFP and is regulated by a lacI-repressible plLacO-1 Promoter. By adding IPTG one should be able to induce the expression of sfGFP and compare the induction curve to other IPTG-inducible RBS characterization parts from our library to determine the relative strengths of different RBS sequences across an induction curve. We have included the self-cleaving ribozyme RiboJ immediately upstream of the RBS sequence in order to buffer against translational influence from the 5' untranslated region conferred to the transcript by the promoter sequence. false false _2534_ 27446 27446 9 false See Design Details for individual parts plLacO-1 (K2066508) and sfGFP (K2066509) false Kalen Clifton, Christine Gao, Andrew Halleran, Ethan Jones, Likhitha Kolla, Joseph Maniaci, John Marken, John Mitchell, Callan Monette, Adam Reiss component2500906 1 BBa_K2066019 component2500892 1 BBa_K2066018 component2500898 1 BBa_K2066509 component2500893 1 BBa_K2066508 component2500897 1 BBa_K2066530 component2500905 1 BBa_B0015 component2500894 1 BBa_K2066506 component2500896 1 BBa_B0034 annotation2500893 1 BBa_K2066508 range2500893 1 41 118 annotation2500905 1 BBa_B0015 range2500905 1 938 1066 annotation2500894 1 BBa_K2066506 range2500894 1 119 199 annotation2500897 1 BBa_K2066530 range2500897 1 212 217 annotation2500898 1 BBa_K2066509 range2500898 1 218 937 annotation2500906 1 BBa_K2066019 range2500906 1 1067 1106 annotation2500896 1 BBa_B0034 range2500896 1 200 211 annotation2500892 1 BBa_K2066018 range2500892 1 1 40 BBa_B0010_sequence 1 ccaggcatcaaataaaacgaaaggctcagtcgaaagactgggcctttcgttttatctgttgtttgtcggtgaacgctctc BBa_K2066530_sequence 1 tactag BBa_K2066509_sequence 1 atgcgtaaaggcgaagagctgttcactggtgtcgtccctattctggtggaactggatggtgatgtcaacggtcataagttttccgtgcgtggcgagggtgaaggtgacgcaactaatggtaaactgacgctgaagttcatctgtactactggtaaactgccggtaccttggccgactctggtaacgacgctgacttatggtgttcagtgctttgctcgttatccggaccatatgaagcagcatgacttcttcaagtccgccatgccggaaggctatgtgcaggaacgcacgatttcctttaaggatgacggcacgtacaaaacgcgtgcggaagtgaaatttgaaggcgataccctggtaaaccgcattgagctgaaaggcattgactttaaagaagacggcaatatcctgggccataagctggaatacaattttaacagccacaatgtgtacattaccgcagataaacaaaaaaatggcattaaagcgaatttcaaaattcgccacaacgtggaggatggcagcgtgcagctggctgatcactaccagcaaaacactccaatcggtgatggtcctgttctgctgccagacaatcactatctgagcacgcaaagcgttctgtctaaagatccgaacgagaaacgcgatcatatggttctgctggagttcgtaaccgcagcgggcatcacgcatggtatggatgaactgtacaaatgatga BBa_K2066019_sequence 1 gcactgaaggtcctcaatcgcactggaaacatcaaggtcg BBa_B0034_sequence 1 aaagaggagaaa BBa_K2066508_sequence 1 ggcaaatattctgaaatgagctgataaatgtgagcggataacattgacattgtgagcggataacaagatactgagcac BBa_K2066506_sequence 1 agctgtcaccggatgtgctttccggtctgatgagtccgtgaggacgaaacagcctctacaaataattttgtttaaactaga BBa_K2066018_sequence 1 gctgggagttcgtagacggaaacaaacgcagaatccaagc BBa_K2066035_sequence 1 gctgggagttcgtagacggaaacaaacgcagaatccaagcggcaaatattctgaaatgagctgataaatgtgagcggataacattgacattgtgagcggataacaagatactgagcacagctgtcaccggatgtgctttccggtctgatgagtccgtgaggacgaaacagcctctacaaataattttgtttaaactagaaaagaggagaaatactagatgcgtaaaggcgaagagctgttcactggtgtcgtccctattctggtggaactggatggtgatgtcaacggtcataagttttccgtgcgtggcgagggtgaaggtgacgcaactaatggtaaactgacgctgaagttcatctgtactactggtaaactgccggtaccttggccgactctggtaacgacgctgacttatggtgttcagtgctttgctcgttatccggaccatatgaagcagcatgacttcttcaagtccgccatgccggaaggctatgtgcaggaacgcacgatttcctttaaggatgacggcacgtacaaaacgcgtgcggaagtgaaatttgaaggcgataccctggtaaaccgcattgagctgaaaggcattgactttaaagaagacggcaatatcctgggccataagctggaatacaattttaacagccacaatgtgtacattaccgcagataaacaaaaaaatggcattaaagcgaatttcaaaattcgccacaacgtggaggatggcagcgtgcagctggctgatcactaccagcaaaacactccaatcggtgatggtcctgttctgctgccagacaatcactatctgagcacgcaaagcgttctgtctaaagatccgaacgagaaacgcgatcatatggttctgctggagttcgtaaccgcagcgggcatcacgcatggtatggatgaactgtacaaatgatgaccaggcatcaaataaaacgaaaggctcagtcgaaagactgggcctttcgttttatctgttgtttgtcggtgaacgctctctactagagtcacactggctcaccttcgggtgggcctttctgcgtttatagcactgaaggtcctcaatcgcactggaaacatcaaggtcg BBa_B0012_sequence 1 tcacactggctcaccttcgggtgggcctttctgcgtttata BBa_B0015_sequence 1 ccaggcatcaaataaaacgaaaggctcagtcgaaagactgggcctttcgttttatctgttgtttgtcggtgaacgctctctactagagtcacactggctcaccttcgggtgggcctttctgcgtttata igem2sbol 1 iGEM to SBOL conversion Conversion of the iGEM parts registry to SBOL2.1 James Alastair McLaughlin Chris J. Myers 2017-03-06T15:00:00.000Z