Part:BBa_K2560041

Phytobrick version of BBa_E0030

This is the Phytobrick version of the coding sequence BBa_E0030 and was build as a part of the Marburg Collection. Instructions of how to use the Marburg Collection are provided at the bottom of the page.

Overview

Open reading frames (ORFs) are sequences that can theoretically be translated into functional proteins. They are predicted by a start codon (ATG) at their beginning and a stop codon (TAA, TAG, TGA) at the end separated by multiple codons. When an ORF is confirmed to code for a functional protein it is classified as a coding sequence (CDS). CDSs code only proteins. To translate them they need a promoter upstream the start codon.A terminator downstream of the sequence end the translation. In prokaryotes an RBS sequence is needed between the promoter and the start codon. In eukaryotes CDSs are flanked by untranslated regions (UTRs). In addition eukaryotic CDSs contain introns which are removed after transcription by splicing to form the mature mRNA which is translated into the functional protein outside the nucleus.

Sequence and Features

Marburg Toolbox

We proudly present the Marburg Collection, a novel golden-gate-based toolbox containing various parts that are compatible with the PhytoBrick system and MoClo. Compared to other bacterial toolboxes, the Marburg Collection shines with superior flexibility. We overcame the rigid paradigm of plasmid construction - thinking in fixed backbone and insert categories - by achieving complete de novo assembly of plasmids.

36 connectors facilitate flexible cloning of multigene constructs and even allow for the inversion of individual transcription units. Additionally, our connectors function as insulators to avoid undesired crosstalk.

The Marburg Collection contains 123 parts in total, including:
inducible promoters, reporters, fluorescence and epitope tags, oris, resistance cassettes and genome engineering tools. To increase the value of the Marburg Collection, we additionally provide detailed experimental characterization for V. natriegens and a supportive software. We aspire availability of our toolbox for future iGEM teams to empower accelerated progression in their ambitious projects.

Figure 3: Hierarchical cloning is facilitated by subsequent Golden Gate reactions.
Basic building blocks like promoters or terminators are stored in level 0 plasmids. Parts from each category of our collection can be chosen to built level 1 plasmids harboring a single transcription unit. Up to five transcription units can be assembled into a level 2 plasmid.

Figure 4: Additional bases and fusion sites ensure correct spacing and allow tags.
Between some parts, additional base pairs were integrated to ensure correct spacing and to maintain the triplet code. We expanded our toolbox by providing N- and C- terminal tags by creating novel fusions and splitting the CDS and terminator part, respectively.

Parts of the Marburg Toolbox

• K2560011 (5'Connector Dummy)
• K2560055
  (1-6
  Connector)
• K2560065 (5'Con1)
• K2560066 (5'Con2)
• K2560067 (5'Con3)
• K2560068 (5'Con4)
• K2560069 (5'Con5)
• K2560075 (5'Con1
  Short Res)
• K2560076 (5'Con2
  Short)
• K2560077 (5'Con3
  Short)
• K2560078 (5'Con4
  Short)
• K2560079 (5'Con5
  Short)
• K2560095 (5'Con1 inv)
• K2560096 (5'Con2 inv)
• K2560097 (5'Con3 inv)
• K2560098 (5'Con4 inv)
• K2560099 (5'Con5 inv)
• K2560105 (5'Con5 inv
  Ori)
• K2560107 (5'Con1
  Res)

• K2560007 (J23100)
• K2560009 (J23104)
• K2560014 (J23106)
• K2560015 (J23115)
• K2560017 (J23101)
• K2560018 (J23102)
• K2560019 (J23103)
• K2560020 (J23105)
• K2560021 (J23107)
• K2560022 (J23108)
• K2560023 (J23109)
• K2560024 (J23110)
• K2560025 (J23111)
• K2560026 (J23113)
• K2560027 (J23114)
• K2560028 (J23116)
• K2560029 (J23117)
• K2560030 (J23118)
• K2560031 (J23119)
• K2560123
  (pTet)
• K2560124 (pTrc)
• K2560131 (Promoter Dummy)

• K2560008 (B0034)
• K2560010 (B0032)
• K2560013 (B0031)
• K2560016 (B0030)
• K2560084
  (RBS Dummy)

• K2560033 (E1010)
• K2560041 (E0030)
• K2560042 (sfGFP)
• K2560043 (sfGFP Vn)
• K2560047 (Cas9)
• K2560051
  (Lux Operon)
• K2560054 (dCas9)
• K2560082
  (CDS Dummy)
• K2560114 (LacZ Alpha)
• K2560128 (K660004)
• K2560135
  (SXT Beta)
• K2560268
  (tfox Vc)
• K2560269
  (tfox Vn)
• K2560270
  (SXT)
• K2560272
  (flp recombinase)

• K2560034 (B0010)
• K2560035 (B0015)
• K2560081 (Terminator Dummy)
• K2560089 (B1002)
• K2560091 (B1003)
• K2560093 (B1006)

• K2560012 (3'Connector Dummy)
• K2560070 (3'Con1)
• K2560071 (3'Con2)
• K2560072 (3'Con3)
• K2560073 (3'Con4)
• K2560080 (3'Con5 Ori)
• K2560100 (3'Con1 inv
  Short)
• K2560101 (3'Con2 inv
  Short)
• K2560102 (3'Con3 inv
  Short)
• K2560103 (3'Con4 inv
  Short)
• K2560104 (3'Con5 inv
  Short)
• K2560106 (3'Con1 inv
  Short Res)
• K2560108 (3'Con1 inv)
• K2560109 (3'Con1 inv
  Res)
• K2560110 (3'Con2 inv)
• K2560111 (3'Con3 inv)
• K2560112 (3'Con4 inv)
• K2560113 (3'Con5 inv)

• K2560036 (ColE1)
• K2560037 (pMB1)
• K2560046 (p15A)

• K2560048 (Cam. Res. RFP)
• K2560056
  (Kan. Res. (pSB3K3) RFP)
• K2560057
  (Kan. Res. (pSB3K3) GFP)
• K2560058
  (Tet. Res. (pSB3T5) RFP)
• K2560059
  (Tet. Res. (pSB3T5) GFP)
• K2560125 (Carb. Res. RFP)
• K2560126 (Carb. Res. GFP)
• K2560127 (Carb. Res. into BBa_K2560002)
• K2560132 (Cam. Res. into BBa_K2560002)
• K2560133
  (Kan. Res. into BBa_K2560002)
• K2560134
  (Tet. Res. into BBa_K2560002)

Tags and Entry Vectors

• K2560060 (E1010 4x)
• K2560063 (sfGFP 4x)
• K2560085
  (His-Tag 4x)
• K2560087 (FLAG-Tag 4x)
• K2560129 (K660004 4x)
• K2560257 (Streptag 4x)

• K2560061 (E1010 5a)
• K2560062 (B0015 5b)
• K2560064 (sfGFP 5a)
• K2560086
  (His-Tag 5a)
• K2560088 (FLAG-Tag 5a)
• K2560090 (B1002 5b)
• K2560092 (B1003 5b)
• K2560094 (B1006 5b)
• K2560117 (I11012 5a)
• K2560118 (M0050 5a)
• K2560119 (M0051 5a)
• K2560130 (K660004 5a)
• K2560258 (Streptag 5a)

• K2560001 (Entry Vector with RFP dropout)
• K2560002 (Entry Vector with GFP dropout)
• K2560005 (Resistance Entry Vector with RFP Dropout)
• K2560006 (Resistance Entry Vector with GFP Dropout)
• K2560305 (gRNA Entry Vector with GFP Dropout)