Optimization and construction of CRISPR/Cas9 vectors
The endogenous U6 promoter region of Fol with the Esp3 I site was synthesized and inserted into the Not I and Sph I sites of pCRISPR/Cas U6-125, resulting in pCRISPR/Cas9-FoU6. The full sequence of the sgRNA expression cassette is shown in Fig. S2. The N-terminal Cas9 region attached to the NLS of histone H2B in Fol was created using fusion PCR. For the first PCR, the N-terminal Cas9 and NLS regions were amplified from pCRISPR/Cas9-FoU6 using an NLSCas9-1/-2 primer set and from the Fol genome using an NLSCas9-3/-4 primer set, respectively. The PCR products obtained from the first PCR were mixed and fused by a second PCR performed using an NLSCas9-1/-4 primer set. The N-terminal Cas9 region with NLS generated by fusion PCR was cloned between the Asc I and Nde I sites of pCRISPR/Cas9-FoU6, resulting in pCRISPR/Cas9-FoU6-FoNLS.
For the construction of CRISPR/Cas9 expression vectors targeting endogenous genes, each oligonucleotide set of Ku80-gRNA-1/-2, Ku70-gRNA-1/-2, Lig4-gRNA-1/-2, ABHL-gRNA-1/-2, SIX1-gRNA-1/-2, or Fgm4-gRNA-1/-2 was annealed according to the procedures of a previous report 25,29. The annealed oligonucleotides were inserted into pCRISPR/Cas9-FoU6 or pCRISPR/Cas9-FoU6-FoNLS via the Golden Gate cloning method according to a previous report25,29,39. CRISPR/Cas9 expression vectors for Ku80, Ku70, and Lig4 were also used for Fos genome editing.
Construction of donor vectors and DNA fragments
For the construction of the knock-out vector for Ku80, the flanking regions were amplified using the primer sets of TKu80-1/-2 and TKu80-3/4. The PCR product generated by the TKu80-1/-2 primer set was inserted between the Sph I and Xho I sites of pMK-dGFP37, resulting in pMK-Ku80-FL. The PCR product generated by the TKu80-3/4 primer set was inserted between the Hind III and Spe I sites of pMK-Ku80-FL, which produced the donor vector for the knock-out of Ku80 (pMK-Ku80-FLFR). For the construction of the knock-out vector for Ku70, the flanking regions were amplified using each primer set of TKu70-1/-2 or TKu70-3/-4. The PCR product generated by the TKu70-1/-2 primer set was inserted between the Kpn I and Sph I sites of pMK-dGFP (pMK-Ku70-FL). The PCR product generated by the TKu70-3/-4 primer set was inserted between the Hind III and Not I sites of pMK-Ku70-FL, which produced the donor vector for the knock-out of Ku70 (pMK-Ku70-FLFR). For the construction of the knock-out vector for Lig4, the flanking regions were amplified using each primer set of TLig4-1/-2 or TLig4-3/-4. The PCR product generated by the TLig4-1/-2 primer set was inserted between the Kpn I and Sph I sites of pMK-dGFP (pMK-Lig4-FL). The PCR product generated by the TLig4-3/-4 primer set was inserted between the Sal I and Spe I sites of pMK-Lig4-FL, which produced the donor vector for the knock-out of Lig4 (pMK-Lig4-FLFR). For the construction of the knock-out vector for ABHL, the flanking regions were amplified using each primer set of TABHL1-1/-2 or TABHL-3/-4. The PCR product generated by the TABHL-1/-2 primer set was inserted between the Kpn I and Xho I sites of pMK-dGFP (pMK-ABHL-FL). The PCR product generated by the TABHL-3/-4 primer set was inserted between the Hind III and Sac I sites of pMK-ABHL-FL, which produced in the donor vector for ABHL knock-out (pMK-ABHL-FLFR). For the construction of the knock-out vector for SIX1, the PCR products generated by each primer set of SIX1_P1/P2 or SIX1_P3/P4 were mixed with the hph cassette, amplified from pCSN4342 using a SIX1_pCSN_F/R primer set, and fused by PCR using a SIX1_P1/P4 primer set. The PCR product was attached to an adenine at the ends using a 10×A-attachment mix (TOYOBO) according to the manufacturer’s protocol and cloned into pCR-XL-TOPO (Thermo Fisher Scientific), which produced in the donor vector for the knock-out of SIX1 (pCSN43-SIX1-FLFR). For the construction of the knock-out vector for W5-fgm4, the PCR products generated by each primer set of fgm4_P1/P2 or fgm4_P3/P4 were mixed with the hph cassette, amplified from pCSN43 using a fgm4_pCSN43_F/R primer set, and fused by PCR using an Fgm4_P1/P4 primer set. The PCR product was attached to adenine at the ends by the 10×A-attachment mix and cloned into pCR-XL-TOPO, which produced in the donor vector for the knock-out of W5-fgm4 (pCSN43-W5-fgm4-FLFR).
For the construction of the donor DNA fragments with truncated short homology arms, fragments with 1000, 750, 500, 250, 100, and 50 bp homology arms for Ku80 were amplified from pMK-Ku80-FLFR using Ku80-1000-1/-2, Ku80-750-1/-2, Ku80-500-1/-2, Ku80-250-1/-2, Ku80-100-1/-2, and Ku80-50-1/-2, respectively. Similarly, donor fragments with 1000, 750, 500, 250, 100, and 50 bp homology arms for Lig4 were amplified from pMK-Lig4-FLFR using the primer sets Lig4-1000-1/-2, Lig4-750-1/-2, Lig4-500-1/-2, Lig4-250-1/-2, Lig4-100-1/-2, or Lig4-50-1/-2, respectively. Donor fragments with 1000, 750, 500, 250, 100, and 50 bp homology arms for ABHL were amplified from pMK-ABHL-FLFR using the primer sets of ABHL-1000-1/-2, ABHL-750-1/-2, ABHL − 500-1/-2, ABHL-250-1/-2, ABHL-100-1/-2, and ABHL-50-1/-2, respectively.
For the construction of the donor vector of the single crossover-mediated Ku80 base editing, the Ku80 gene region comprising point mutations was generated by fusion PCR. For the first PCR, the Ku80 gene regions were amplified from the genome of Fol using each primer set of SKu80-1/-2 or SKu80-3/-4. The PCR products obtained from the first PCR were mixed and fused by the second PCR using the SKu80-1/-4 primer set. The Ku80 gene region with point mutations obtained by fusion PCR was inserted between the HindIII and SpeI sites of pMK-dGFP, which produced in pMK-SKu80.
For the construction of the donor vector of the single crossover-mediated Ku80 gene tagging, GFP-fused Ku80 gene was generated by fusion PCR. For the first PCR, the Ku80 gene regions with silent mutations, with deleted start and stop codons, were amplified from pMK-SKu80 using SKu80-1/KKu80-2. The amplified Ku80 gene region was inserted between the Hind III and Spe I sites of pMK-dGFP (pMK-KKu80). The GFP gene amplified from pMK41237 using a KK80-3/KK80-4 primer set was cloned between the Spe I and Sac I sites of pMK-KKu80, resulting in pMK-KKu80-GFP.
Protoplasts preparation and transformation of Fusarium species
Protoplasts of F. commune were prepared as previously described40. In the case of Fol and Fos, protoplasts were isolated similar to previous reports37,41 with some modifications. Fol or Fos was cultured in 30 mL of YG liquid medium at 28°C for 1 d at 180 rpm. One milliliter of the culture was transferred into 100 mL fresh YG medium and incubated at 28ºC and 180 rpm overnight. The mycelia were collected by centrifugation at 12,000 rpm for 10 min and washed twice with 1.2 M MgSO4. In the case of Fol, the mycelia were treated with a mixture of 20 mg/mL Yatalase (Takara bio, Japan), 20 mg/mL lysing enzyme (Sigma, USA), and 20 mg/mL cellulase (Yakult Pharmaceutical Industry, Japan) in 1.2 M MgSO4 for 3–4 h. In the case of Fos, the mycelia were treated with a mixture of 40 mg/mL Yatalase, 40 mg/mL Driserase (ASKA Animal Health, Japan), 40 mg/mL lysing enzyme (Sigma), and 40 mg/mL cellulase in 1.2 M MgSO4 for 16 h. The fungal protoplasts were collected and washed twice with STC (1.2 M sorbitol, 50 mM CaCl2, and 10 mM Tris–HCl pH 7.5). Then, the protoplasts were diluted to a concentration of 5×106/mL with STC buffer.
About 2.5 µg each of CRISPR/Cas9 and donor vectors were mixed and added to 50 µL of the protoplast suspension. In the case of the donor DNA fragments, approximately 1 µg of CRISPR/Cas9 vector and 500 ng of the donor DNA fragments were mixed and added to 50 µL protoplast suspension. For the disruption of SIX1 and W5-fgm4, 15 µg of each donor vector and CRISPR/Cas9 vector were mixed and added to 150 µL of the protoplast suspensions. The transformants were selected and maintained on YG solid medium containing hygromycin B (100 µg/mL). The primers used for the PCR analysis to check the disrupted mutants are listed in Table S1. To check the SIX1 and W5-fgm4 disruptions, the primer sets of SIX1_P1/P4 and fgm4_P1/P4 were used, respectively. To check the sequences obtained by single crossover-mediated genome editing, a Ku80-check-1/Ku80-seq-2 primer set was used for the PCR, and Ku80-seq-2 was also used for the sequencing analysis.