DNA polymerase theta suppresses mitotic crossing over
Authors:
Juan Carvajal-Garcia aff001; K. Nicole Crown aff002; Dale A. Ramsden aff001; Jeff Sekelsky aff001
Authors place of work:
Curriculum in Genetics and Molecular Biology, University of North Carolina, Chapel Hill, North Carolina, United States of America
aff001; Department of Biology, Case Western Reserve University, Cleveland, Ohio, United States of America
aff002; Lineberger Comprehensive Cancer Center, University of North Carolina, Chapel Hill, North Carolina, United States of America
aff003; Department of Biochemistry and Biophysics, University of North Carolina, Chapel Hill, North Carolina, United States of America
aff004; Integrative Program in Biological and Genome Sciences, University of North Carolina, Chapel Hill, North Carolina, United States of America
aff005
Published in the journal:
DNA polymerase theta suppresses mitotic crossing over. PLoS Genet 17(3): e1009267. doi:10.1371/journal.pgen.1009267
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pgen.1009267
Summary
Polymerase theta-mediated end joining (TMEJ) is a chromosome break repair pathway that is able to rescue the lethality associated with the loss of proteins involved in early steps in homologous recombination (e.g., BRCA1/2). This is due to the ability of polymerase theta (Pol θ) to use resected, 3’ single stranded DNA tails to repair chromosome breaks. These resected DNA tails are also the starting substrate for homologous recombination. However, it remains unknown if TMEJ can compensate for the loss of proteins involved in more downstream steps during homologous recombination. Here we show that the Holliday junction resolvases SLX4 and GEN1 are required for viability in the absence of Pol θ in Drosophila melanogaster, and lack of all three proteins results in high levels of apoptosis. Flies deficient in Pol θ and SLX4 are extremely sensitive to DNA damaging agents, and mammalian cells require either Pol θ or SLX4 to survive. Our results suggest that TMEJ and Holliday junction formation/resolution share a common DNA substrate, likely a homologous recombination intermediate, that when left unrepaired leads to cell death. One major consequence of Holliday junction resolution by SLX4 and GEN1 is cancer-causing loss of heterozygosity due to mitotic crossing over. We measured mitotic crossovers in flies after a Cas9-induced chromosome break, and observed that this mutagenic form of repair is increased in the absence of Pol θ. This demonstrates that TMEJ can function upstream of the Holiday junction resolvases to protect cells from loss of heterozygosity. Our work argues that Pol θ can thus compensate for the loss of the Holliday junction resolvases by using homologous recombination intermediates, suppressing mitotic crossing over and preserving the genomic stability of cells.
Keywords:
DNA damage – DNA repair – Drosophila melanogaster – Genetic causes of cancer – Guide RNA – Heterozygosity – Homozygosity
Introduction
Double-strand breaks (DSBs) are a particularly toxic form of DNA damage. DSBs are generated during common cellular processes (e.g., replication, transcription), after exposure to ionizing radiation, or by specialized mechanisms such as meiosis or the development of the adaptive immune system [1]. DSBs are also essential intermediates during nuclease-dependent genome editing. Two pathways account for most DSB repair: non-homologous end joining (NHEJ), and homologous recombination (HR) [2]. In addition, polymerase theta-mediated end joining (TMEJ) has recently been identified as a third DSB repair pathway [3–5].
DNA polymerase theta (Pol θ, gene name POLQ) was first shown to be involved in DSB repair in Drosophila melanogaster (fruit fly), and this function was found to be conserved in other invertebrates, plants, and mammals [3–7]. Inactivation of TMEJ by knocking out POLQ orthologs has little to no effect on organismal viability in mice, zebrafish, Drosophila, or Caenorhabditis elegans. Only when exposed to exogenous DNA damaging agents does Pol θ deficiency negatively impact survival, although to a lesser extent than when other DSB repair pathways are compromised [8–11]. However, Pol θ is required in the absence of factors that promote both NHEJ (e.g., KU70 and 53BP1) [12,13] and HR (e.g., BRCA1 and BRCA2) [13–15], showing that TMEJ can compensate for their loss. This is of particular interest in the context of HR-deficient breast and ovarian cancer, where Pol θ has been proposed as a promising therapeutic target [16].
HR is a multi-stage process that can lead to different repair outcomes, some of which can be detrimental [17]. An important example of detrimental HR is mitotic crossing over, as it can result in loss of heterozygosity, which can lead to cancer development [18,19]. The first step in HR is DNA end resection, which generates 3’-ended ssDNA tails. One tail is used to invade another duplex DNA molecule, forming a displacement loop (D-loop) and priming DNA synthesis. Unwinding of the D-loop and reannealing to the other end of the broken molecule completes synthesis-dependent strand annealing (SDSA). Alternatively, the D-loop may progress to form a joint molecule, the double-Holliday junction, that needs to be dissolved or resolved through cleavage for the chromosomes to be segregated; the latter process can lead to a mitotic crossover [2].
Mechanistically, how Pol θ compensates for the loss of HR proteins is largely unknown. Mutations in genes involved in early stages of HR have been shown to be synthetic lethal with POLQ mutations. This suggests that when these steps are inactivated, the resulting 3’ ssDNA can be used by Pol θ to repair the DSB. It remains unclear whether mutations in genes involved in later steps in HR (e.g., downstream of BRCA1/2) can similarly generate recombination intermediates that are toxic for cells in the absence of Pol θ activity.
Here we describe a strong genetic interaction between POLQ and the Holliday junction resolvase genes SLX4 and GEN1, which encode some of the latest acting HR proteins, both in Drosophila melanogaster and in mammalian cells. We also show that Pol θ suppresses mitotic crossing-over in flies, thus protecting cells from this potentially pathogenic form of repair. Moreover our results, together with the observation that POLQ mutations have no effect in SDSA in Drosophila [3], argue that Pol θ is surprisingly important in processing HR intermediates even after D-loop formation.
Results
Brca2 and POLQ mutations are synthetic lethal in Drosophila melanogaster
During repair of double-strand breaks (DSBs) in mammals, TMEJ is able to compensate for some HR deficiencies (Fig 1A). This is best illustrated by the requirement of POLQ for the survival of BRCA1/2 mutant cancer cell lines [14,15], and the upregulation of POLQ in BRCA1/2 deficient breast and ovarian tumors [14,20,21]. We therefore initially assessed whether a comparable phenomenon is evident at a whole animal level in Drosophila, by crossing flies heterozygous for mutations in PolQ and Brca2 (the Drosophila melanogaster orthologs of POLQ and BRCA2; hereafter, the human gene/protein names will be used for simplicity) (Fig 1B). Homozygous mutant flies are easily identified due to the presence of a homologous balancer chromosome (CyO, Cy1 dplvl pr1 cn2 on the second chromosome and TM6B, AntpHu Tb1 e1 ca1 on the third chromosome) that carries a dominant phenotypic marker (Curly (Cy) for BRCA2, Humeral (AntpHu) for POLQ) (Fig 1B). When we looked at the progeny of these flies, we observed that single mutant flies in either gene alone displayed approximately 100% viability (Fig 1C). Conversely, only 12% of the expected double homozygous mutant flies eclosed as adults, indicating semi-lethality when these two proteins are absent (Fig 1C).
Previous investigations have emphasized the strong genetic interaction between POLQ and genes involved in early steps of HR (i.e., steps preceding D-loop formation) (Fig 1A) [13–15]. However, DNA intermediates formed downstream of end resection and strand invasion may also be amenable to repair by TMEJ. This has recently been suggested to be the case when long-range resection is impaired due to mutations in BRCA1, which may inhibit re-annealing of the unwound D-loop [22]. If so, mutations in genes involved in later steps of HR might also be synthetic lethal with POLQ mutations. Therefore, we assessed whether a genetic interaction exists between POLQ and genes encoding proteins involved in late steps of HR.
Pol θ is required for viability in the absence of the Holliday junction resolvases
We decided to use Drosophila melanogaster to investigate the genetic relationship between Pol θ and some of the latest acting HR proteins, the Holliday junction resolvases Mus312 (SLX4 in humans), and Gen (GEN1 in humans). Human SLX4 is a scaffolding protein that coordinates at least three endonucleases: SLX1, XPF-ERCC1, and MUS81-EME1 (the interaction with MUS81-EME1 has only been reported in mammals), forming the SMX tri-nuclease [23–27]. GEN1 acts independently of SLX4 [28]. These structure-specific endonucleases have both unique and overlapping DNA substrate specificities [29–31].
We assessed the viability of every double mutant combination (POLQ SLX4, POLQ GEN1, and SLX4 GEN1) as well as the triple mutant (POLQ SLX4 GEN1) by crossing heterozygous flies and comparing the fraction of adult homozygous mutant flies observed to what would be expected by Mendelian genetics. While POLQ SLX4, POLQ GEN1, and SLX4 GEN1 double mutant combinations are fully viable, flies that lack Pol θ, SLX4, and GEN1 rarely progress to adulthood (<1% survival) (Fig 2A and S1 Table). When using the PolQnull allele over PolQZ2003 (PolQZ2003 is a nonsense mutation reported to be a strong hypomorph; see Materials and methods), we observed a 3% survival for POLQ SLX4 GEN1 mutant flies (n = 1059). This is, to our knowledge, the first evidence for synthetic lethality for POLQ and genes required for steps in HR after strand invasion.
These results indicate a genetic redundancy between Pol θ and the resolvases. The functions of the resolvases suggested that the synthetic lethality could be due to a role for Pol θ in rescuing unresolved HR intermediates that arise from spontaneous DSBs, or stalled or broken replication forks. If this is the case, we reasoned such roles would be apparent as sensitivity to exogenous DNA damaging agents in double mutants that are viable in the absence of such agents.
We used ionizing radiation (IR) to induce DSBs, and camptothecin, a type I topoisomerase poison, to generate stalled and broken replication forks. We compared the sensitivity of POLQ, SLX4, and GEN1 single mutants, as well as POLQ SLX4, and POLQ GEN1 double mutant flies, to moderate doses of IR (1000 rads) and camptothecin (10 μM). All three single mutants showed an average survival of ≥80% for both DNA damaging agents (Fig 2B and 2C and S2 Table). POLQ SLX4 double mutant flies showed the strongest reduction of viability, 31% and 9% survival when treated with IR or camptothecin, respectively (Fig 2B and 2C and S2 Table). POLQ GEN1 double mutants showed only a modest reduction in viability. Pol θ is thus more important for cell viability in the absence of SLX4 than in the absence of GEN1. These results show that DSBs and collapsed or broken replication forks generate DNA substrates, likely HR intermediates, that require the use of Pol θ or SLX4 for repair.
We also tested whether SLX1 or MUS81, two of the nucleases that associate with SLX4, played a more significant role than the other in the repair of these intermediates. We observed mild sensitivity to IR of both POLQ MUS81 and POLQ SLX1 double mutants (Fig 2D and S2 Table), reflecting an apparent redundancy between these two nucleases in the presence of SLX4 and GEN1. Interestingly, POLQ MUS81 GEN1 triple mutant files are much more sensitive to IR (1% survival) than POLQ SLX1 GEN1 triple mutant flies (50% survival) (Fig 2D and S2 Table), which suggests that MUS81 is required for the repair of certain DNA substrates in the absence of GEN1.
Next, we addressed whether this genetic interaction observed in flies is conserved in mammals. For this, we used T-antigen transformed mouse embryonic fibroblasts (MEFs) derived from isogenic wild type (wt) and Polq-/- mice [8]. In addition, we used Polq-/- MEFs that have been complemented with the human POLQ cDNA [5]. We electroporated ribo-nucleoprotein complexes of purified Staphylococcus pyogenes Cas9 protein with gRNAs targeting either the non-protein-coding Rosa26 locus (control locus, R26) or exon 4 in SLX4 (Fig 3A). 72 hours later, we assayed cell viability by a colony formation assay. In addition, we harvested DNA from the cells, amplified the genomic regions across the Cas9 site and used tracking of indels by decomposition (TIDE) [32] to calculate the fraction of chromatids that had an indel at the target sites (% editing) (Fig 3A). Targeting SLX4 did not decrease viability in wt or in complemented Polq-/- MEFs compared to targeting the non-coding locus (Figs 3B and S1 and S3 Table). However, we observed a 54% reduction in viability in the Polq-/- MEFs when targeting SLX4, relative to the control locus, which matches the editing efficiency of 58% in that cell line (Figs 3B and S1 and S3 Table). Unlike flies, this decrease in viability in POLQ SLX4 double mutants MEFs is observed in the absence of exogenous DNA damage (except for the DSB made by Cas9), arguing the genetic interaction between POLQ and SLX4 is stronger in mammalian cells than it is in flies.
Lack of Pol θ and resolvases leads to high levels of apoptosis
Interestingly, etched tergites (disrupted tissue patterning in the abdomen) could be readily observed in most POLQ SLX4 double mutant flies (88.1%, n = 42) (Fig 4A). These are indicative of defects in cell survival or proliferation during development. We never observed them in wt (n = 71) and POLQ mutants (n = 40) and rarely in the SLX4 ones (18.2%, n = 44). This phenomenon has been described in POLQ RAD51 double mutants [3].
To accurately quantify the level of apoptosis in flies with different genotypes, we used an antibody that detects cleaved Dcp-1, a marker of apoptosis in Drosophila [33]. We immunostained larval wing imaginal discs, a highly proliferative tissue that becomes the adult wings after metamorphosis. The use of a larval tissue also allows us to assess the levels of apoptosis in POLQ SLX4 GEN1 flies, at least in the fraction of animals that reach the larval stage. We observed very little apoptosis in POLQ mutant flies, while levels of apoptosis were significantly higher in POLQ SLX4, and even higher in the POLQ SLX4 GEN1 triple mutant (Fig 4B and 4C and S4 Table). This is consistent with the reduction in viability observed in the POLQ SLX4 GEN1 triple mutant, as well as sensitivity to exogenous DNA damage by IR or camptothecin in the POLQ SLX4 double mutant.
Pol θ suppresses mitotic crossovers
The strong genetic interaction between Pol θ and the resolvases suggests the existence of a DNA intermediate that will either be joined by TMEJ or progress to a double Holliday junction and be resolved by SLX4 or GEN1. This DNA intermediate, when left unrepaired, causes cell death. We hypothesize that this substrate is an HR intermediate. In Drosophila somatic cells, both TMEJ and Holliday junction formation are downstream of the preferred HR pathway, SDSA. Support for this hypothesis comes from the finding that Pol θ-dependent end joining products and mitotic crossovers are both increased when SDSA is inactive due to the absence of the BLM helicase [34,35]. This leads to a model in which DNA intermediates formed after aborted SDSA can then be processed by either TMEJ or the structure-specific endonucleases. In the absence of both pathways, these DNA intermediates accumulate and become toxic to cells, which ultimately undergo apoptosis; high levels of apoptosis lead to organismal death.
We set out to identify potential consequences of the epistatic relationship between TMEJ and Holliday junction resolution described above by designing a DSB repair assay in Drosophila that allows for assessment of an expected product of Holliday junction resolution, mitotic crossovers (Fig 5A). DSBs are generated in the germline cells of male flies by expressing Cas9 under a germline promoter (nos), and a gRNA, expressed with the U6 promoter, targeting the coding region of the rosy (ry) gene, located in the right arm of chromosome 3. Homozygous ry mutant flies are viable and have an easily identifiable mutant eye color. Only the maternal chromosome gets cut, as the paternal allele harbors a SNP that alters the protospacer adjacent motif (PAM) sequence (TGG becomes TGA) required for recognition and cleavage by Cas9 (Fig 5A).
This assay allows us to detect mutagenic end joining, homologous recombination events that used the homologous chromosome as a template, and unedited (never cut or precisely repaired) chromosomes. Moreover, we can characterize HR events as crossovers or non-crossovers due to the presence of the phenotypic markers scarlet (st) and ebony (e), as well as the fact that Drosophila males don’t generate crossovers during meiosis [35].
We performed this assay using 60 single males, six of which were sterile. We randomly selected one progeny fly from each of the 54 remaining males, and detected editing in 40 (74%), showing that the assay is highly efficient (Fig 5B). In wild-type flies we observed that repair of a DSB by end joining (EJ) and HR are roughly equally common (EJ: 21/54, 39%; HR: 19/54, 35%) (Fig 5B).
Mitotic crossovers are present in only 0.2% of wild type flies (Fig 5C and 5D and S5 Table); strikingly, they are present at 18-fold higher levels in POLQ deficient flies (Fig 5D and S5 Table). Interestingly, ablation of all resolvase activity (i.e., both SLX4 and GEN1) was required to completely eliminate mitotic crossing over. This is in contrast to mitotic crossovers generated in the absence of the anti-crossover helicase FANCM, which depend solely on SLX4 [36], and are likely not originated by a blunt DSB like the ones in this assay.
Because nos is expressed early in the male germline, it should be noted that repair events might be amplified unevenly during cell proliferation prior to spermatogenesis. Even though we don’t expect this to disproportionately affect different genotypes, we analyzed these results in a different way by assessing only whether each male had some crossover progeny or no crossover progeny. The results of this analysis mirrored those in the previous one, though the magnitude of the change was lower (3.5X more mitotic crossovers in POLQ mutant flies than in wt flies) (Table 1). This latter analysis is definitively unaffected by unequal expansion, but presumably underestimates the amount of crossing over due to our inability to distinguish between one and multiple crossover events in the same male germline.
These results show that the absence of Pol θ increases the amount of mitotic crossing over during HR. Moreover, our results imply that Pol θ can act upstream of the Holliday junction resolvases, and thus presumably upstream of Holliday junction formation as well.
Discussion
Pol θ has the ability to compensate for the loss of BRCA1 and BRCA2, key mediators of HR, as well as for loss of proteins involved in NHEJ [12,14,15]. Moreover, a recent synthetic lethality screen uncovered 140 genes that have a synthetic growth defect with POLQ, most of which operate outside of DSB repair, and showed that as much as 30% of breast tumors may be relying on Pol θ for survival [13]. This ability has motivated the search for a Pol θ inhibitor for treatment of cancer [37].
However, no HR gene outside of the resection/strand invasion step has been shown to be synthetic lethal with POLQ. Here we show that flies deficient in Pol θ, SLX4, and GEN1 –the latter of two acting late during HR–are inviable, due to high levels of apoptosis likely caused by endogenous DNA damage, and that flies with mutations in POLQ and SLX4 are hypertensive to the DNA damaging agents IR and camptothecin. Moreover, we demonstrate that the genetic interaction between Pol θ and SLX4 is conserved in mice. This striking genetic redundancy strongly suggests that TMEJ and Holliday junction formation/resolution are involved in processing similar DNA substrates.
The ability of Pol θ to rescue deficiencies in HR genes is not completely understood. A well-defined starting substrate for TMEJ is generated after 5’ resection of both ends of a DSB [5,12], yet it is not known whether that is the only substrate used by Pol θ. Two 3’ ssDNA tails are also the starting substrate in HR, implying a possible competition between TMEJ and HR. The difficulty in accurately measuring the different outcomes of HR in mammalian cells has led to conflicting evidence on whether Pol θ has the ability to suppress HR, and therefore compete for a starting substrate [12,14,15].
Well characterized assays in Drosophila allow for the unambiguous assessment of SDSA, the major pathway for completion of repair by HR in somatic cells [34], and they show that lack of Pol θ doesn’t affect the frequency of DSB-induced SDSA [3]. Pol θ deficiency similarly doesn’t affect the frequency of single strand annealing, another pathway immediately downstream of end resection, in flies or in human cells [38,39]. This argues that Pol θ does not compete for the 3’ ends generated by 5’ end-resection.
In contrast, Pol θ suppresses mitotic crossovers and is synthetic lethal with resolvase deficiency, arguing it does compete for repair by the alternate means for completion of HR that involves a double Holliday junction. SDSA is upstream of TMEJ and Holliday junction formation/resolution, yet both Pol θ-associated indels and mitotic crossovers are observed in wild-type flies. This indicates that sometimes SDSA either fails or cannot be completed. We propose that the remaining DNA intermediate(s) can either be joined by Pol θ, generating a small indel, or can progress to a double Holliday junction, that may be resolved to create a mitotic crossover.
Thus, though the generation of small indels is implicit to repair by TMEJ, this pathway protects against potentially more deleterious forms of repair, such as larger deletions [21], or interhomolog recombination after a DSB is made in both homologs [40]. Holliday junction resolution also generates genotypes, in the form of loss of heterozygosity, that can affect whole chromosome arms. The high potential pathogenicity of these events may make them more detrimental to cells than small indels, supporting Pol θ’s role in maintaining genomic stability.
Materials and methods
Drosophila stocks
Drosophila stocks were kept at 25°C on standard cornmeal media (Archon Scientific). Mutant alleles were obtained from the Bloomington Drosophila Stock Center (BDSC) or were a gift from Dr. Mitch McVey and have been described in [41] (Brca2KO), [42] (Brca247), [43] (PolQnull) and [3] (PolQZ2003), [44] (mus312D1 and mus312Z1973), [45] (GenZ5997, slx1F93I and slx1e01051), and [46] (mus81Nhe). PolQnull (a deletion) was used either homozygous (Figs 1, 2 and 4), or in trans to PolQZ2003, a nonsense mutation reported to be severely hypomorphic [3] (Fig 5). Brca2 and mus312 alleles were used compound heterozygous. GenZ5997 was used hemizygous over the deficiency Df(3L)6103. Since mus81 is in the X chromosome, mus81Nhe was used homozygous in females and hemizygous in males. Allele-specific PCR was used to detect the presence of the mutant alleles in recombinant chromosomes (primers in S6 Table).
Pictures of fly abdomens shown in Fig 4A were taken with a Swiftcam 16 Megapixel Camera, and the Swift Imaging 3.0 software.
Flies expressing Streptococcus pyogenes Cas9 controlled by the nanos promoter, inserted on the X chromosome (attPA2) were obtained from BDSC (stock number 54591 [47]).
Flies expressing a gRNA targeting the rosy (ry) locus (5’-CATTGTGGCGGAGATCTCGA-3’) were generated by cloning the gRNA sequence into the pCFD3 plasmid (Addgene #49410) as in [47]. The gRNA construct was stably integrated into an attP landing site at 58A using phi-C31 targeting (stock number 24484) (Best Gene).
For the generation of flies with a deletion of the ry locus, two gRNA sequences were cloned into the pU6-BbsI-chiRNA plasmid (Addgene #45946) [48]. One gRNA targeted 5’ of the ry start site (5’-GGCCATGTCTAGGGGTTACG-3’) and the other targeted 3’ of the ry stop codon (5’-GATATGCACAGAATGCGCCT-3’). These were injected along with the pHsp70-Cas9 plasmid (Addgene #45945) [48] into a w1118 stock (Best Gene). The resulting ry deletion starts 373 bp upstream of the ry start codon and ends 1048 bp downstream of the ry stop codon.
DNA damage survival assays
Survival in the presence of DNA damaging agents was determined as in [49]. Five females and three males carrying heterozygous mutations for the indicated genes were allowed to mate and to lay eggs for 72 hours (untreated progeny), when they were moved to a new vial where they laid for 48 hours (treated progeny). The latter brood was exposed to 1000 rads of ionizing radiation (source: 137Cs) or 10 μM camptocethin, diluted from a concentrated stock in a 10% ethanol, 2% Polysorbate 20 aqueous solution. The fraction of heteroallelic mutant flies in the treated progeny was divided by the fraction of heteroallelic mutant flies in the untreated progeny to calculate the survival.
Statistical analysis
Experiments that employ statistical tests as indicated in the figure legends were done using GraphPad Prism 6 (ANOVA) or Excel (Χ2 test).
Cell lines
Mouse Embryonic Fibroblasts (MEFs) were made from isogenic wt or Polq-null mice generated by conventional knock-out [8] that were obtained from Jackson Laboratories and maintained on a C57BL/6J background and immortalized with T antigen as described in [5]. Cells were incubated at 37°C, 5% CO2 and cultured in DMEM (Gibco) with 10% Fetal Bovine Serum (VWR Life Science Seradigm) and Penicillin (5 U/ml, Sigma). All lines used in this study were certified to be free of mycoplasma by a qPCR [50] with a detection limit below 10 genomes/ml. In addition, cell lines were randomly selected for third party validation using Hoechst staining [51].
Clonogenic survival assay
Transfections were performed as in [21]. Genome targeting ribonucleotide-protein complexes (RNP) were made by annealing the indicated crRNA (R26: 5’-ACTCCAGTCTTTCTAGAAGA-3’, SLX4: 5’-ACAGCAGGAGTTTAGAAGGG-3’) to a tracrRNA (Alt-R, IDT) to form 8.4 pmol of gRNA, followed by incubation of annealed gRNA with 7 pmol of purified Cas9 (made after expression of Addgene #69090) [52]. The assembled RNPs were electroporated into 200,000 MEFs along with 32ng of pMAX-GFP using the Neon system (Invitrogen) in a 10 ul tip with one 1,350 V, 30 ms pulse and plated (three electroporations formed one biological replicate). After 72 h, 500 cells were plated into 3 different plates and let grow for 7 days to allow for colonies to form. Cells were fixed and stained as in [53], using a 6% glutaraldehyde, 0.5% crystal violet aqueous solution. Colonies were counted and survival was calculated for each cell line individually. Genomic DNA for the remaining cells was harvested and used as a template for the generation of a PCR product surrounding the R26 or the SLX4 break site (primers in S6 Table). This PCR product was sequenced (Eton) and the editing efficiency was calculated using TIDE [32]. The editing efficiencies for the SLX4 break site are noted in the figure; editing efficiencies for the R26 break site were 84.7%, 95.7% and 95.3% for wt, Polq-/- and Polq-/- + POLQ respectively.
Wing imaginal disc immunofluorescence
The anterior halves of third instar larvae of third instar, 5-7-day old, homozygous mutant for the indicated genes, larvae were dissected in phosphate-buffered saline (PBS), everted, and fixed in 4% formaldehyde at room temperature for 45 min. They were washed three times in PBS+0.1% Triton-X (PBSTx), blocked in 5% normal goat serum for one hour at room temperature, and incubated overnight at 4°C in a 1:100 dilution of cleaved Dcp-1 antibody (Cell signaling #9578S) in PBSTx. Larva heads were then washed six times with PBSTx and incubated in a 1:500 dilution of secondary antibody (goat anti-Rabbit IgG, Alexa Fluor 488, Life Technologies) for two hours at room temperature. After washing six times in PBSTx, DAPI was added at a 1:1000 dilution. Discs were dissected and mounted in 50 ul of Fluoromount G mounting media (Thermo).
Pictures were taken with a Zeiss LSM880 confocal laser scanning microscope using a 40X oil immersion objective with a constant gain and a 0.6X zoom using ZEN software. Images were saved as.czi files and were processed and the signal was quantified using ImageJ as in [54].
Mitotic crossover assay
For Fig 4B, single males expressing Cas9 and the gRNA targeting the ry gene were generated (see cross below).
In addition, these males were heterozygous for st1 and e1 as well as for a SNP that changes the PAM sequence recognized by Cas9 immediately downstream of the gRNA sequence in ry (the chromosome with the mutation in st has the functional PAM and will be cut by Cas9). These males were crossed to females that were e1 over TM6B, AntpHu Tb1 e1 ca1. To characterize the repair event that occurred after the DSB, a single male progeny, heterozygous for e and AntpHu, was crossed to females homozygous for a deletion in ry. If the non- AntpHu progeny has rosy eye color, the repair event was characterized as mutagenic end joining (EJ). If the non- AntpHu progeny had wild-type eye color, genomic DNA from a single male was extracted and the DNA surrounding the break was amplified by PCR (primers in S6 Table). The presence of the silent mutation that changes the PAM sequence, revealed by resistance to cutting by BccI of the PCR product surrounding the Cas9 target site, was interpreted as HR. The presence of the intact PAM was characterized as unedited.
For Fig 4D and Table 1, single males as the ones described above and with maternal and zygotic mutations in the indicated genes (see crosses used to generate them below), where crossed to flies homozygous mutant for st and e.
Flies that were wild type for both markers or mutant for both markers were characterized as having a crossover event.
Supporting information
S1 Fig [tif]
Representative images of one plate per condition (genotype and gRNA) scored for .
S1 Table [csv]
Number of heterozygous and homozygous mutant flies scored for , and % of mutant flies expected and observed.
S2 Table [csv]
Number of flies heterozygous (balanced) and homozygous mutant (unbalanced), treated or untreated with the indicated mutagen, scored for , and calculated % survival for each vial pair.
S3 Table [csv]
Number of colonies counted, for each biological replicate of cells of the indicated genotype transfected with Cas9 and the indicated gRNA, and calculated viability relative to the gRNA represented in .
S4 Table [csv]
Area of each wing disc in pixels and area of Dcp-1 positive signal within that disc in pixels for discs of the indicated genotype, as well as the calculated % area positive for Dcp-1 represented in .
S5 Table [csv]
Number progeny from each male that didn’t have crossover (NCO) or that did (MCO), as well as the percentage of the progeny that had a crossover, represented in .
S6 Table [docx]
Primers used in this study.
Zdroje
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