Enhancing HR efficiency by expressing a fusion of Exonuclease and Cas9 Exonuclease can cleave DSBs to form single-stranded DNA, we thus tried to fuse exonuclease with Cas9 to initiate the HR based repair immediately upon Cas9 cutting. To select the suitable exonuclease, we fused five exonuclease-encoded genes, phage T7 exonuclease (T7Exo), phage λ Red recombination system exonuclease (λRedExo), Escherichia coli exonuclease III (EcExoIII), and endogenous MRE11 and EXO1 to the N-terminal or C-terminal of CAS9 on the plasmids, respectively (Figure S1). We compared the HR efficiency by quantifying the positive rate of seamless deletion of FAA1 (encoding fatty acyl-CoA synthase 1), since FAA1 deletion efficiency was low in wild-type of P. pastoris GS115 [16].
The endogenous MRE11 and EXOI significantly improved the positive rate by 25% and 23.4%, respectively, while the control with only expressing CAS9 had a positive rate of 13.3%. In particular, fusing expression of MRE11 to the C-terminal of CAS9 (MRE11-C) resulted in the highest positive rate of 38.3% (Figure 2A). It is worthy to mention the position of exonuclease resulted in the big variance of positive rates, which might be attributed to difference in enzyme activity or the structure interface between Cas9 and exonuclease. There was a negative correlation between of positive rates and colony forming units (CFU, Figure 2B), which agreed with that HR based repair was rigorous and resulted low survival during DNA repair [16]. Considering the highest positive rate and relative sufficient CFU number, the C-terminal fusion of Mre11 (MRE11-C) to Cas9 was used for further genetic manipulation (Figure 2B).
Synergistic effect of MRE11 and RAD52 for enhancing HR
We previously showed that overexpressing endogenous RAD52 significantly improved HR [16]. We here tried to combine the MRE11 and RAD52 for further enhancing HR. Overexpression of RAD52 had a high positive rate of 88.3% and further fusing the expression of MRE11 to C terminal of CAS9 (CAS9-MRE11) had a higher positive rate of 91.7% when seamlessly deleting FAA1. Consistently, the CFU number of CAS9-MRE11 decreased slightly (Figure 3). We previously showed that RAD52 overexpression significantly improved the manipulation of single genes [16], but precise engineering of multiple genes is still challenging. We thus investigated the synergistic influence of RAD52 overexpression coupled with the MRE11 fusion to Cas9 for simultaneously manipulation of multiple genes.
Simultaneous deletion of multiple genes
We firstly applied our system for simultaneous deletion of multiple genes, which should be helpful for extensive metabolic engineering. Fusion expression of CAS9-MRE11 resulted a high positive rate of 86.7% when simultaneously deleting FAA2 and HFD1, which was higher than that of the control (CAS9, 76.7%) in the RAD52 overexpression strain. Interestingly, CAS9-MRE11 significantly increased the CFU number (Figure 4A). In simultaneous deletion of three genes (FAA2, HFD1 and POX1), CAS9-MRE11 improved the positive rate more significantly (from 10.8% of the control CAS9 to 16.7%) with the similar CFU numbers (Figure 4B). These results suggested that fusing Mre11 with Cas9 helped to initiate the HR based repair of multiple DSBs and thus improved the seamless deletion of multiple genes.
CAS9-MRE11 enhances genomic integration of multi-fragments
Multi-fragments assembly is useful for integrating long biosynthetic pathways. We previously observed that overexpressing RAD52 and deleting MPH1 contributed to the integration of three DNA fragments into specific genomic locus of P. pastoris [16]. We here decided to further investigate if CAS9-MRE11 expression enhance the integration of multi-fragments (total 11 kb) of a fatty alcohol biosynthetic pathway (Figure 5A). In the RAD52 overexpression strain, CAS9-MRE11 improved the positive rate to 91.7%, in comparison to the control strain of 66.7% (Figure 5B). In the RAD52-mph1Δ background, CAS9-MRE11 also resulted a significant higher positive rate of 93.3% compared with the control strain (71.7%). Remarkably, MRE11 overexpression increased CFU number by 103.7% and 76% in these two genetic backgrounds.
The Yeast Srs2 protein is a 3′–5′ DNA helicase and negative regulator of Rad51 function. It removes Rad51 filament and thereby inhibit HR (Figure 5C) [20, 21]. We thus tried to delete SRS2 for enhancing HR, which however resulted in lower positive rates during the integration of multi-fragments. But expressing CAS9-MRE11 still improved the positive rates and CFU numbers in the background RAD52-srs2Δ and RAD52-mph1Δ-srs2Δ (Figure 5B).