Part:BBa_K3425002

pSB3C12: Improved pEven2 Loop Vector based on pSB3C02

The illegal BsaI site was removed from pSB3C02 by PCR mutagenesis to obtain the new pEven2 plasmid pSB3C12.

iGEM Type IIS Vectors

pEven Loop Vectors (for Level 2)

When four Level 1 parts (TUs) are assembled into a Multi-Transcriptional Unit (MTU) into the following plasmid backbones (with BBa_J04455), the MTU will be flanked by BsaI restriction sites and these 4 bp Fusion Sites.

The iGEM Type IIS assembly standard is based on MoClo and Loop

• A Modular Cloning System for Standardized Assembly of Multigene Constructs
• Loop assembly: a simple and open system for recursive fabrication of DNA circuits

Note: This section was adapted from pSB3C01 in order to collect all the information in one page. More information, as well as all our experience in this cloning method, can be found in Team Uppsala 2020's iGEM Type IIS standard guidebook.

This part is part of iGEM Uppsala 2020's iGEM Type IIS standard collection.

Sequence and Features

Mutagenesis of pSB3C0# pEven Loop vectors

The sequence of pEven Loop vectors for Level 2 assemblies (pSB1C0#) contains an additional, illegal BsaI site. BsaI is the enzyme which is used to cleave the assembly out of a pEven vector to be cloned back to a pOdd vector. Therefore, the presence of this illegal site would impact the construction of Level 3 assemblies. Site-directed mutagenesis by PCR was conducted in order to remove the illegal sites. The new plasmids were named pSB3C1#. This page corresponds to pSB3C12 which was obtained from pSB3C02.

After PCR mutagenesis, screening was done by digestion of the plasmid DNA with BsaI (Figure 1). All backbones (pSB3C0# and pSB3C1#) contain a band that corresponds to the mRFP1 cassette (BBa_J04455) with a size of 1093bp. Then, pSB3C1# consist of one more band of 2725pb. Since pSB3C0# have one more BsaI site, they should present two more bands of 2434bp and 291bp. While the 291bp band is not visible, probably due to too low DNA amount, the shift in size before and after mutagenesis is clearly visible.

This difference cannot be seen, however, for pSB3C01 and pSB3C11. In addition, a longer band can be seen for pSB3C01, but a comparison to the linearised pSB3C03 shows that it corresponds to linearised plasmid. To investigate the lack of difference between pSB3C01 and pSB3C11, as well as to confirm the mutagenesis by another method, pSB3C01 and pSB3C1# were sequenced.

Sequencing results showed a successful PCR mutagenesis for all of the pSB3C1# backbones, with the expected point mutation (Figure 2, B). Furthermore, they also showed a point mutation in the original backbone, pSB3C01, (at a different point than the planned one) which eliminated the extra BsaI site (Figure 2, A).

Afterwards, some assemblies into pSB3C1# were conducted, which show their functionality. One such example is part BBa_K3425072. This confirmed that these backbones would work as the new pEven set of vectors.

This information can also be found in Team Uppsala 2020's Wet lab page. Sequencing results of this part with J04455 can be found in the Sequence Analysis section and the trace files are in the collection page as well as our Parts page.