Motivation

With a Type IIS assembly method, multiple parts can be assembled easily and reliably in a single reaction, and this can be scaled further to create more complex genetic circuits quickly, efficiently, and affordably.

A Type IIS assembly method uses Type IIS restriction enzymes, which are offsite cutters; they cut DNA at a specific distance from their recognition site. This allows for specified overhangs left by the Type IIS enzymes.

Currently, there are several Type IIS assembly standards in use, many of these were designed for specific purposes. iGEM believes strongly in standards, and as we approach Type IIS assembly methods we want to support one that we believe will be useful, reliable, long-lasting and widespread for the synthetic biology community.

We want to ensure that the assembly standard and method we support is widely used, tested, and has flexibility for different applications and groups.

Technical Specifications

Assembly Compatibility / Illegal Sites

iGEM Type IIS compatible parts must not contain the Bsa1 and Sap1 Type IIS recognition sequences, as these restriction enzymes are required for assembly. Parts that have these “illegal” recognition sites are not compatible with the standard.

In order to check for Type IIS compatibility, when you've added a part's sequence to the Registry, the sequence and features box will show if a part is compatible or not.

Why were these restriction enzymes selected?

One benefit of Type IIS assembly standards is that the assembly method requires only two restriction enzymes for creation of basic parts (Level 0s), assembly of composite parts or transcriptional units (Level 1s), and multiple transcriptional units (Level 2+). Fewer illegal restriction sites means it will be easier to make compatible parts when compared to BioBrick RFC 10. Other Type IIS assembly standards may require different Type IIS restriction enzymes (AarI, Bsmb1, Bbs1, etc.), but in order to ensure ease of making parts compatible, the iGEM Type IIS standard only designates Bsa1 and Sap1 as “illegal” restriction sites. Users may choose to avoid these other Type IIS restriction enzymes in their part design at their discretion.

Why Bsa1?

Most, if not all, Type IIS assembly standards use Bsa1 for basic parts (Level 0) parts, so this ensures maximum compatibility.

Why Sap1?

In addition to Bsa1, Loop Assembly requires Sap1. While this restriction enzyme site only leaves a 3bp overhang, it has a 7bp recognition site, which theoretically will make it rarer, and make standardization of parts easier. For iGEM Type IIS, we have also modified the PhytoBricks Universal Acceptor plasmid, so that users can PCR their Level 0 parts into the iGEM Type IIS Universal Acceptor using Sap1. Cost analysis [link] has shown that Sap1, while initially more expensive than BioBrick enzymes, is within the price range of other Type IIS enzymes, and due to.

What about the BioBrick restriction enzymes?

Your iGEM Type IIS parts do not need to be BioBrick compatible. Your BioBrick parts do not need to be Type IIS compatible.

Fusion Sites

iGEM's Type IIS assembly standard specifies fusion sites that flank four basic parts types (Level 0) when cut with Bsa1.

Why were these fusion sites selected?

These fusion sites were outlined in the original MoClo paper (Weber, et al. 2011). They have since been adopted in other Type IIS assembly standards. As an example, these MoClo fusion sites completely overlap with the PhytoBricks standard. These fusion sites have also been tested against NEB’s 4bp ligation fidelity tool [link], finding them to be completely reliable when used as a set in a reaction.

To ensure maximum compatibility, and because of a long history of use, iGEM has adopted these fusion sites for the following basic parts. As a note, iGEM has elected to not define the fusion sites within a CDS region (AGGT, for MoClo).

Prefix and Suffix