Author Correction: A selectable, plasmid-based system to generate CRISPR/Cas9 gene edited and knock-in mosquito cell lines

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

We first replaced the dme phsp70 with the strong constitutive Ae. aegypti polyubiquitin promoter (aae PUb 15,32,54 ; Fig. 1b). Expression of hSpCas9 in this intermediate plasmid (pKRG2) was then assessed in comparison to the parental pDCC6 plasmid (Fig. 1c,d). We observed increased expression of hSpCas9 in both Aag2 and U4.4 cells using the mosquito PUb promoter. The dme phsp70 promoter has long been applied to mosquito cells and, notably, the first stable transformations of mosquito cell lines was performed using this promoter 55 . However, the reported frequency of transformants was quite low, an observation possibly explained by the lower levels of expression we observed from dme phsp70 in mosquito cells.
We next updated the U6 promoter to drive sgRNA expression (Fig. 1e). The Drosophila U6-2 promoter in the pDCC6 plasmid 29 , which was also used to generate prior CRISPR/Cas9-edited mosquito cells 33,39 , is quite ineffective in mosquito cell lines 56 . We selected the previously described Ae. aegypti-derived U6 promoter, AAEL017774 57 , which is effective in mosquito cells 56 . These two promoter replacements generate the backbone of the mosquito optimized pKRG3 plasmid (pKRG3-mU6-PUb-3xFLAG-hSpCas9). Because the N-terminal 3xFLAG tag on the hSpCas9 may be undesirable for some applications, we also generated a pKRG3 plasmid with this tag removed (pKRG3-mU6-PUb-hSpCas9).
Finally, we added a selectable marker to pKRG3. Although we optimized transfections (representative transfections of U4.4 and Aag2 shown in Supplementary Fig. 1), no estimates of CRISPR/Cas9-mediated editing efficiency have been reported in mosquito cells. Thus, it may be essential to select transfected cells to increase the likelihood of editing. We generated a plasmid expressing hSpCas9 fused to a selectable marker, a puromycin resistance cassette (pAc). The pAc was inserted after the well-characterized insect virus Thosea asigna T2A 58 '2A-like' ribosome skipping site. This T2A has been applied in Drosophila S2 and mosquito (C6/36 and Aag2) cells 30,33,39,59,60 , and was the most efficient skipping site in a comparison of five 2A variations in Drosophila 61 . This design ensures co-expression of the hSpCas9 and the pAc selectable marker under one strong, constitutive mosquito promoter (pKRG3-mU6-PUb-hSpCas9-pAc).
To assess the suitability of puromycin selection in Aag2 and U4.4 cells, we performed puromycin kill curves to titrate the optimal concentration (data not shown). Puromycin treatment killed both cell lines efficiently in the absence of pAc expression, and PUb-driven expression of hSpCas9-pAc significantly increased cell viability in the presence of puromycin (Fig. 2a,b). We additionally confirmed efficient T2A skipping in both mosquito cell lines by examining the size of hSpCas9 by immunoblot (Fig. 2c,d). In both cases, the hSpCas9 was processed correctly and we observed a strong band at the expected size (~ 160 kDa) in both constructs. The slight shift in hSpCas9-pAc is due to additional amino acids in the T2A upstream of the skipped residue, and is consistent with T2A processing in Drosophila 59 . A higher nonspecific band is present in all lanes and does not reflect unprocessed hSpCas9-pAc, which would run at ~ 185 kDa. Therefore, PUb-hSpCas9-pAc constructs correctly express and process hSpCas9 and enable rapid selection in U4. 4 29 . The dme U6-2 promoter drives sgRNA transcription and the dme phsp70 promoter drives expression of a 3xFLAG-tagged hSpCas9. Guide RNAs are cloned by BbsI digest. (b) pKRG2 plasmid, generated by replacing the dme phsp70 promoter with the aae PUb promoter. Cloning of guide RNAs as in (a). (c) Immunoblot of Aag2 cells treated with transfection reagent (ctrl) or transfected with pDCC6 (3xFLAG-hSpCas9; expressed from the dme pshp70 promoter) or with pKRG2 (3xFLAG-hSpCas9; expressed from the PUb promoter). kDa = kilodaltons. Full-length blots in Supplementary Fig. 4. (d) As in (c) for U4.4 cells. (e) To generate pKRG3 mosquito adapted plasmids, the pKRG2 guide RNA cloning site was redesigned to use BsmBI (allowing insertion of the aae U6 promoter, which is incompatible with the BbsI sgRNA cloning site). The RNA Pol II aae U6 promoter was then inserted to express sgRNAs. This plasmid was further modified by removing the N-terminal 3xFLAG from hSpCas9 and adding a T2A-pAc to allow puromycin selection to yield several options for mosquito optimized CRISPR/Cas9 editing. www.nature.com/scientificreports/ genomic sequence near the AGO1 translational start site by searching for PAM NGG sequences. Because no U4.4 genome has been published, we first verified the starting methionine to target by 5′RACE (this differed from the annotated start site; unpublished results). Three guides were designed in the first exon near the beginning of the coding sequence in order to disrupt AGO1 (Fig. 3a). Guides were cloned into pKRG3 and these plasmids were transfected singly or in combination into U4.4 cells (Fig. 3b). Post-puromycin selection, we assessed editing efficiency by surveyor assay (Fig. 3c). In this assay, mismatches between annealed wild-type (WT) and edited amplicons lead to cleavage by the surveyor nuclease. Un-transfected WT cells exhibited the expected amplicon at ~ 350 bp (black arrow; and a smaller, nonspecific band). In contrast, U4.4 cells transfected with pKRG3 plasmids revealed a slightly lower band (red arrow) in addition to the WT band. This indicates amplification of both WT and CRISPR/Cas9-edited AGO1 loci from pKRG3-transfected cells. We observed that editing was not equally efficient for all single guides, although they were all designed in close proximity. Further, combinatorial transfections with two or three guides performed by far the best 47,50,51 . For a head-to-head comparison, we additionally examined editing using the same hSpCas9 expression and puromycin selection conditions with the dme U6-2 promoter (pKRG2) instead of the aae U6 promoter (pKRG3). When guides were expressed from the dme U6-2 promoter we did not observe any editing, even using all three guides in combination. Therefore, in U4.4 cells the pKRG3 plasmid substantially increases editing efficiency compared to plasmids that rely on dme U6-2 for sgRNA expression. We next isolated single U4.4 cell clones from this edited population to establish clonal cell lines and assess their potential edits and AGO1 protein levels (Fig. 3d). Sequencing of clonal lines showed disruptive edits corresponding to sgRNA cleavage sites (~ 65% of clones were edited; example alignment shown in Supplementary  Fig. 2a). Immunoblot showed decreased protein levels in several of the isolated clones compared to WT levels ( Fig. 3d, top). Consistently, we observed that most clones with lower AGO1 levels were isolated from cell populations transfected with combinations of guides. Detection of an ectopically expressed 3xFLAG-tagged U4.4 AGO1 confirmed detection of mosquito AGO1 using the immunoblot antibody (Fig. 3d, bottom). Interestingly, we were unable to isolate a knock-out clone completely lacking AGO1 protein, despite isolating a variety of different edited lines with reduced AGO1 levels.  www.nature.com/scientificreports/ To confirm that reduced AGO1 protein levels corresponded with reduced AGO1 function, we performed a microRNA (miRNA) reporter assay. In mosquitoes, small, genome encoded miRNAs direct AGO1 to repress imperfectly complementary transcripts 45 . We assessed whether U4.4 clones with WT or reduced AGO1 expression could use endogenous miR-34 to repress a Renilla luciferase reporter gene containing miR-34 target sequences (Fig. 3e). While neither WT clone was functionally impaired, several of the clones deficient in AGO1 exhibited consistently reduced repression. However, we note that AGO1 protein level was not strictly correlated with functional repression. These data indicate that mosquito optimized CRISPR/Cas9 plasmids can be used to edit AGO1 and to impair AGO1 expression and function in U4.4 cells.

Scientific Reports
CRISPR/Cas9 mediates efficient editing and allows knock-in of AGO1 in Aag2 cells. We next asked whether mosquito adapted plasmids would also allow editing of Ae. aegypti Aag2 cells. In addition to isolating AGO1-deficient cell lines, as in U4.4, we also aimed to generate a knock-in AGO1 Aag2 cell line by applying CRISPR/Cas9 editing and providing a homology-directed repair (HDR) donor template. Not only are Aag2 cells are widely used in arbovirus studies, thus far, knock-in Ae. aegypti cell lines have not been reported. Further, gene annotation is more reliable in Ae. aegypti than in Ae. albopictus, facilitating the design of HDR donor templates. We thus used the AGO1 locus to provide proof-of-principle that the CRISPR/Cas9 system can be used to generate Ae. aegypti knock-in cell lines. We designed three guide RNAs near the AGO1 starting methionine, as in U4.4 cells (Fig. 4a). Additionally, we designed an HDR donor template to insert an N-terminal 3xFLAG tag at the endogenous AGO1 locus (Fig. 4b). Because HDR can be very inefficient, upstream of the 3xFLAG we inserted a red fluorescent protein (RFP) driven by the PUb promoter, flanked by two loxP sites. This allows sorting of RFP-positive cells to isolate potentially rare clones with the PUb-RFP-3xFLAG integrated. The PUb-RFP marker can then be excised via expression of Cre recombinase, leaving only a small scar upstream of the 3xFLAG-tagged AGO1. This entire cassette was flanked by ~ 1 kb of homology on either terminus 30 .
Aag2 cells were transfected with pKRG3 plasmids singly or in combination, with the linearized HDR donor template (Fig. 4b). As in U4.4 cells, editing efficiency of bulk Aag2 cells was assessed post-puromycin selection. In contrast to in U4.4 cells, in Aag2 cells we consistently observed high editing efficiency whether guides were expressed singly or in combination (Fig. 4c). Isolation of single cell clones followed by sequencing showed ~ 28% of isolated clones contained edits (example alignment shown in Supplementary Fig. 2b). Immunoblot showed several clones with decreased and one clone with ablated AGO1 expression (clone sg1 + 2 B; Fig. 4d, top). We were able to detect 3xFLAG-tagged short and long Aag2 AGO1 isoforms by ectopic expression or constitutive expression in stably transformed cell lines, confirming reliable detection of mosquito AGO1 (Fig. 4d, bottom). Unfortunately, the single AGO1 knock-out clone grew poorly and could not be expanded to sufficient cell numbers to establish a knock-out cell line. We were able to establish several Aag2 clonal cell lines with lower AGO1 expression, as with U4.4. However, expansion and subsequent culturing of AGO1-deficient Aag2 cell lines was much more difficult than in U4.4. Unlike in U4.4 cells, in Aag2 cells, despite isolating clones with decreased AGO1 protein, none of the three clones were significantly and consistently impaired in AGO1 function (Supplementary Fig. 3). Two of the three clones examined had slightly reduced AGO1 function, but the effect was subtle and generally not significant. It remains unclear why, in particular for Aag2 cells, even clones with large reductions in AGO1 protein levels (e.g. sg1 + 2 D) were only subtly impaired in AGO-mediated target repression.
Although we observed high editing efficiencies and isolated clones with decreased AGO1 expression, no AGO1 knock-in cell lines were isolated by serial limiting dilution (Fig. 4d). Therefore, after transfection and selection, cells were cultured until the input HDR donor template RFP signal diminished. Cells were then sorted to identify clones that were RFP-positive due to knock-in of the donor template (Fig. 4b). Consistent with the lack of knock-in clones obtained by serial limiting dilution, the efficiency of HDR was very low and only ~ 0.1% of cells were RFP-positives. We screened RFP-positive single cell clones by PCR and identified two homozygous clones (B2 and C10) with the correct integration, indicated by a ~ 3700 bp product (compared to the WT amplicon of ~ 1500 bp; Fig. 4e). Our primer design outside of the homology arms ensured that this screening PCR only detects the integrated HDR donor template. (WT + HDR control lane). To excise the loxP-PUb-RFP-loxP cassette, we transfected cells with a plasmid expressing a puromycin-selectable Cre recombinase using the PUb promoter (pKRG4-mPUb-Cre-pAc; Fig. 4f). Upon Cre expression, ~ 50% of the selectable cassette was excised; this percentage could be increased by selecting for Cre-transfected cells with puromycin. To generate the final 3xFLAG-tagged AGO1 knock-in cell lines, RFP-negatives, which were abundant, were again sorted following Cre transfection and selection (Fig. 4g). PCR of established B2 and C10 subclones indicated homozygous excision. Therefore, CRISPR/Cas9 editing and HDR were applied to commonly used Aag2 cells to knock-in a 3xFLAG tag at the N-terminus of the endogenous AGO1 locus.
We next verified 3xFLAG-tagged AGO1 expression for knocked-in Cre excised Aag2 cell lines (Fig. 5a). We generally observed four AGO1 isoforms expressed in Aag2 cells, although the expression of each isoform often varied between clones (Figs. 4d, 5a). The two largest isoforms were experimentally verified using 5′RACE (unpublished results) and are expressed with 3xFLAG tags as immunoblot controls; both the short (S) and long (L) isoform arise from the same transcriptional start site. The smaller two isoforms (termed 3, 4 in Fig. 5) have not been verified by sequencing but are often decreased with the other two isoforms (Fig. 4d), and therefore likely also represent bona fide AGO1 isoforms. Expression levels of the short and long AGO1 isoforms were fairly consistent between clonal lines and WT cells, while expression of the smaller isoforms (3,4) were more variable (Fig. 5a, top). Interestingly, we found that although the short and long AGO1 isoforms were still expressed in B2 and C10 clones containing the integrated PUb-RFP cassette, they were not 3xFLAG-tagged (Fig. 5a, middle). The lack of 3xFLAG on the AGO1 isoforms expressed in B2 and C10 clones may indicate that the PUb-RFP cassette alters the AGO1 transcriptional start site. Upon excision, as expected, both AGO1 short and long isoforms were confirmed to contain 3xFLAG tags (+ Cre lines). RFP was only detected in B2 and C10 clones and was www.nature.com/scientificreports/ successfully excised in the Cre-transfected subclones (Fig. 5a, bottom). These results confirmed that Cre excised, knock-in Aag2 cells express 3xFLAG-tagged AGO1 short and long isoforms from the endogenous AGO1 locus. After determining that 3xFLAG-tagged AGO1 isoforms were detected in Cre excised knock-in cell lines, we evaluated the functionality of 3xFLAG-tagged AGO1 in the miRNA reporter assay (Fig. 5b). We only observed defects in AGO1-mediated repression using the 6 × miR-34 reporter, where we saw a moderate decrease in silencing efficiency in particular for the B2 and C10 clones containing the integrated HDR donor template (HDR clones). This defect was largely alleviated upon Cre excision, with the exception of one excised clone (B2 + Cre B). Thus, most of the 3xFLAG-tagged knock-in lines maintain WT functional repression of miR-34 targets. These Aag2 knock-in lines will facilitate a wide variety of studies of endogenous, functional mosquito AGO1.

Discussion
This study provides the first detailed overview and optimization of CRISPR/Cas9 editing in mosquito cells. We generated a set of versatile, selectable CRISPR/Cas9 plasmids, updated for use in mosquito cells. First, by replacing the Drosophila hsp70 promoter with the Ae. aegypti PUb promoter, we demonstrated increased hSpCas9 expression in both mosquito cell lines examined. We also verified correct processing of the T2A ribosomal skipping site, enabling constitutive hSpCas9 and pAc expression from the same promoter (Fig. 2). This strategy was previously employed to generate CRISPR edited Aag2 and C6/36 cells using the same hSpCas9-T2A-pAc under the Drosophila Actin-5c promoter 30,33,39 . We showed that expression of hSpCas9 or Cre fused to T2A-pAc conferred resistance to puromycin and that puromycin treatment increased the desired cell population (Figs. 2,  4). Second, we replaced the dme U6-2 promoter with an aae promoter for sgRNA expression. Although we saw high levels of editing of the AGO1 locus using the aae U6 promoter, we could not detect any editing using the dme U6-2 promoter used in the prior mosquito cell studies 33,39 . This observation is consistent with previous results that the dme U6-2 promoter is not very active in mosquito cells 56 . Thus, the mosquito optimized CRISPR plasmids reported here are a significant improvement upon the Drosophila-based plasmids previously used in mosquito cells 33,39 .
Our results with AGO1 demonstrate that a plasmid-based CRISPR/Cas9 system works well in mosquito cells. Using the updated mosquito CRISPR/Cas9 plasmids, we obtained ~ 28 to 65% edited AGO1 clones (Figs. 3, 4). Co-delivery and expression of both hSpCas9 and sgRNAs from the same, selectable plasmid may increase editing efficiency. Ultimately, high editing efficiencies reduce the labor involved expanding and screening clones, enabling functional interrogation of larger gene sets. Further, selecting bulk edited cells rather than starting with a clonal cell line for editing 39 allows isolation of multiple WT and edited clonal cell lines. Surveying multiple WT and edited clones gives an accurate impression of the phenotypic variation obtained for a given gene mutant from cell to cell. For example, we observed reduced ability to repress miR-34 reporters for the majority of U4.4 AGO1-deficient clones but observed variability in the degree of AGO1 impairment.
Interestingly, despite high editing efficiency of the AGO1 locus in both cell types examined, we were only able to isolate clones with reduced AGO1 protein, not complete knock-outs. The observed reduction in AGO1 protein levels could be due to heterozygous clones or to gene mutations that disrupt, but do not fully ablate, AGO1 expression. Where clonal cell lines were isolated by serial limiting dilution, it also remains possible that some of the AGO1-deficient lines obtained are, in fact, mixed, not clonal populations. Whatever the mechanistic explanation for reduced AGO1 protein levels as opposed to complete ablation of AGO1 expression, this result was extremely consistent in both mosquito cell types examined. We hypothesize that there is selective pressure against complete AGO1 knock-outs, which would be consistent with the impaired growth observed for miRNA-deficient Drosophila and mammalian cells 30,62 . Indeed, the only Aag2 cell clone that we identified completely lacking AGO1 could not be expanded. Further, even Aag2 clones with reduced AGO1 levels were difficult to culture, and the clones we were able to expand to sufficient numbers to perform miRNA reporter assays did not generally exhibit significant impairment of AGO1 function. Although we were able to isolate several U4.4 clones that were consistently impaired in AGO1 function, we also noted there was not a strict correlation between AGO1 protein levels and functional impairment in U4.4 cells. Thus, AGO1-deficient clones that grow 2) and is based on sequencing of U4.4 cells. A PCR was designed for surveyor assay (primers = green arrows). (b) U4.4 AGO1 sgRNAs were cloned into pKRG3, and U4.4 cells were transfected with these plasmids singly or in combination. Workflow to obtain edited cells is shown. (c) Editing efficiency was assessed by surveyor assay. Expected size of wild-type (WT) amplicon = ~ 350 base pairs (bp; black arrow); expected size of digested fragments based on sgRNA cleavage sites = ~ 330 bp (red arrow) + ~ 23 bp (not visible), In comparison to the aae U6 promoter, no editing is observed with the same guides using the dme U6-2 promoter (both plasmids express hSpCas9 using PUb promoter). m = marker. (d) Single cells clones were sequenced to assess the percentage of edited clones. Immunoblot of AGO1 (top) showed clones with WT and reduced (salmon arrows) AGO1 protein levels; A, B, C denote clones. The ectopically expressed, 3xFLAG-tagged U4.4 AGO1 was detected by both the anti-AGO1 antibody and the anti-FLAG antibody (bottom). (e) Luciferase reporter assay measuring repression of 4 or 6 repeated miR-34 sites (4 ×, 6 × miR-34 reporter). Repression for each clone was measured by normalizing to internal transfection controls (reporter luciferase/control luciferase), then to unrepressed reporters in the same clone. The percent (%) of repression compared to WT clones sg1 A and sg1 B is shown. p < 0.0001 (overall ANOVA comparing different clones); individual groups were compared using the Dunnett's post hoc test compared to the WT clone sg1 A; *p < 0.05, **p < 0.001, ***p ≤ 0.0001. All fulllength immunoblots in Supplementary Fig. 4; all full-length DNA gels in Supplementary Fig. 5 www.nature.com/scientificreports/ well may contain specific mutations that decrease protein levels but largely do not impact AGO1 function. It is also possible that some clones upregulate compensatory transcripts related to AGO1, as has been observed for other genetic mutants 63,64 . Our results are perhaps unsurprising, given the important regulatory roles played by the miRNA pathway. In the future, CRISPR/Cas9 editing of AGO1 in the presence of inducible AGO1 expression may circumvent negative effects on cell growth and allow isolation of true knock-outs. However, the present results clearly indicate that CRISPR/Cas9 editing is efficient in both the mosquito cell lines examined and can be used to disrupt AGO1 expression. Notably, we were also able to use CRISPR/Cas9 plasmids in combination with an HDR donor template to generate Aag2 AGO1 knock-in cells. In contrast to in Ae. albopictus cells, knock-in Ae. aegypti cell lines generated using CRISPR/Cas9 genome engineering have not been reported to-date. Therefore, to our knowledge, these Aag2 lines expressing 3xFLAG-tagged AGO1 are the first examples of CRISPR/Cas9-mediated knock-ins in an Ae. aegypti cell line. Consistent with previous studies 65 , we show that the N-terminal 3xFLAG tag does not interfere with AGO1's function repressing miRNA targets. Thus, these cell lines represent valuable tools to better characterize endogenous mosquito AGO1. Although the efficiency of HDR-mediated integration was low, 0.1% was still sufficiently high to isolate AGO1 knock-in Aag2 cells. Further, the robust CRISPR/Cas9 system we report will permit future optimization of HDR efficiency in mosquito cells. The ability to knock-in large cassettes and excise them allows further flexibility in tagging endogenous proteins for mechanistic studies or generating conditional knock-outs in mosquito cells.
In all, we generated a versatile, effective, single plasmid system for the generation of CRISPR/Cas9 edited mosquito cell lines. The mosquito adapted plasmids we report are a cost-effective tool to screen and investigate functional phenotypes for a large number of gene mutants. This easily customizable set of plasmids can also be updated to encode different Cas9 variants for other applications, such as blocking gene transcription (CRISPR interference) or increasing gene expression (CRISPR activation). It is our hope that this system will facilitate functional genetic studies using widely accessible, immune-competent cell models for major vectors of arboviruses. Plasmid generation. All CRISPR/Cas9 plasmids were generated from the pDCC6 plasmid, which encodes the human codon-optimized Streptococcus pyogenes Cas9 (hSpCas9 29,53 ; a gift from Peter Duchek (Addgene plasmid #59985; http:// n2t. net/ addge ne: 59985; RRID:Addgene_59985). All oligos and gBlocks Gene Fragments were purchased from IDT (see Supplementary Table 1 for all oligo and gBlock sequences). All restriction enzymes, calf intestinal phosphatase (CIP), T4 DNA ligase and Gibson Assembly Master Mix were purchased from NEB, and digests and ligations were performed according to the manufacturer's protocol. Polymerase chain reactions (PCRs) were performed using Phusion DNA polymerase (NEB) according to manufacturer's protocols. All transformations were performed using in-house DH5alpha chemically competent cells according to standard protocols. Plasmids were isolated from bacteria using the QIAprep Spin Miniprep Kit (Qiagen) and DNA purifications were performed using QIAquick Gel Extraction and QIAquick PCR Purification Kits (Qiagen), all according to the manufacturer's protocols. All plasmids were sequence-verified and pKRG3 and HDR donor template sequences are available in the Supplemental Information and at Addgene (plasmids 162161-162164). Please see the Supplemental Methods in the Supplemental Information file for detailed cloning procedures. . CRISPR/Cas9-mediated editing and knock-in of AGO1 in Aag2 cells. (a) Three sgRNAs (sg) were designed near the AGO1 translation start site in Aag2 cells. PCRs were designed for surveyor assay (green arrows 1 and 2) and to assess integration (green arrows 1 + and 3). (b) Homology-directed repair (HDR) donor template design. The PUb promoter drives expression of red fluorescent protein (RFP); the PUb-RFP cassette is flanked by two loxP sites, followed by a 3xFLAG-tag. Aag2 AGO1 sgRNAs transfections were performed as in Fig. 3b with the HDR donor template added. Workflows to obtain edited or integrated clones are shown. (c) Editing efficiency was assessed by surveyor assay. Expected size of wild-type (WT) amplicon = ~ 410 base pairs (bp; black arrow); expected size of digested fragments based on sgRNA cleavage sites = ~ 180 bp + ~ 230 bp (red arrow); m = marker. (d) Single cell clones were sequenced to determine the percentage of edited clones. Immunoblot of AGO1 (top) showed clones with WT and reduced AGO1 protein levels (salmon arrows); A, B, C denote clones. 3xFLAG-tagged Aag2 AGO1 short and long isoforms were detected by both the anti-AGO1 antibody and the anti-FLAG antibody (bottom). (e) RFP-positive Aag2 clones from (b) were screened for HDRmediated integration of the donor template. Expected size of amplicons from WT clones = ~ 1500 bp (black arrow); expected size of amplicons from clones containing the integrated HDR donor template = ~ 3700 bp (dark red arrow). B2 and C10 clones were knock-in at the AGO1 locus. (f) The PUb-RFP cassette was excised from Aag2 AGO1 knock-in clones (B2 and C10) by transfection of PUb-driven Cre-T2A-pAc and puro selection. WT and un-transfected B2 cells are shown; expected WT and integrated HDR donor template amplicon sizes as in (e); expected size of Cre excised amplicon = ~ 1500 bp (black arrow). Puro treatment increases the proportion of Cre excision (B2 + Cre + puro). (g) B2 and C10 Cre excised cell lines were sorted for RFP negative clones to obtain homozygous knock-in 3xFLAG-AGO1 Aag2 cell lines. Expected amplicon sizes as in (e-f). All full-length immunoblots in Supplementary Fig. 4; all full-length DNA gels in Supplementary Fig. 5.  Generation of stable cell lines. To generate Aag2 cells stably expressing the long AGO1 isoform with an N-terminal 3xFLAG tag, Aag2 cells were transfected with pKRG4-mPUb-3xFLAG-Aag2-AGO1-long-pAc. Day 2 post-transfection, Aag2 cells were treated with a low concentration of puromycin (1 µg/mL) and maintained until cultures recovered (~ 2 weeks). 3xFLAG-tagged AGO1 expression was confirmed by immunoblot in polyclonal transformants.
To isolate knock-in 3xFLAG tagged AGO1 Aag2 cell lines, cells were resuspended at 2E6/mL in FACS cell sorting buffer (complete L-15 supplemented with 10 mM HEPES, 5 mM EDTA and 40 ng/mL DAPI). Live, RFP-positive cells were sorted for integration of the donor template. Live, RFP negative cells were sorted post Cre transfection and excision. All sorting was performed using a BD FACSAria II sorter (BD Biosciences) with a 100 µm nozzle and a sheath pressure of ~ 20 lbf/in 2 into 96-well plates containing 50% fresh media, and 50% conditioned media. Cells were expanded and genomic DNA was isolated and screened for integration or excision by PCR (primers RU-O-26075 and RU-O-26076); amplicons were visualized on ~ 1% agarose gels with 1 kb plus DNA ladder (NEB) and SYBR Gold (Thermo Fisher Scientific). WT DNA generates a band of ~ 1460 bp, DNA with HDR-mediated integration of the donor template generates a band of ~ 3700 bp, and Cre excised DNA generates a band of ~ 1500 bp). The same PCR was used to Sanger-sequence (Genewiz) B2 and C10 knock-in cell lines to confirm the correct sequence post-integration and post-excision.