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Precise single base substitution in the shibire gene by CRISPR/Cas9-mediated homology directed repair in Bactrocera tryoni

Abstract

Background

Pest eradication using the Sterile Insect Technique (SIT) involves high-density releases of sterilized males that mate with wild females and ultimately suppress the population. Sterilized females are not required for SIT and their removal or separation from males prior to release remains challenging. In order to develop genetic sexing strains (GSS), conditional traits such as temperature sensitive lethality are required.

Results

Here we introduce a known Drosophila melanogaster temperature sensitive embryonic lethal mutation into Bactrocera tryoni, a serious horticultural pest in Australia. A non-synonymous point mutation in the D. melanogaster gene shibire causes embryonic lethality at 29 °C and we successfully used CRISPR/Cas9 technology to recreate the orthologous shibire temperature sensitive-1 (shits1) mutation in B. tryoni. Genotypic analyses over three generations revealed that a high fitness cost was associated with the shits1 mutant allele and shits1 homozygotes were not viable at 21 °C, which is a more severe phenotype than that documented in D. melanogaster.

Conclusions

We have demonstrated the first successful use of CRISPR/Cas9 to introduce precise single base substitutions in an endogenous gene via homology-directed repair in an agricultural pest insect and this technology can be used to trial other conditional mutations for the ultimate aim of generating genetic sexing strains for SIT.

Background

Queensland fruit fly, Bactrocera tryoni (Froggatt), can infest more than one hundred different host plants and is the most serious pest of horticulture in Australia [1]. Area wide integrated pest management programmes to control B. tryoni include the use of Sterile Insect Technique (SIT), which was first proposed by E. F. Kipling as a method of controlling insect populations [2]. SIT has been widely used to suppress or eradicate numerous pest species [3] through intensive releases of steriles into targeted locations. Sterilised males mate with wild females to produce non-viable embryos and reduce the population. Current practices for B. tryoni involve sterile releases of both males and females, yet the release of only sterilized males have proven to be more efficient for SIT of other tephritids [4]. The development of a B. tryoni genetic sexing strain (GSS) for conditional removal of females in SIT rearing facilities is highly desirable.

The generation of a functional GSS is a two-step process. First, an effective visual or inducible trait, such as embryonic temperature sensitive lethality, has to be identified or generated in the desired species. Second, male fitness must then be restored through translocation or insertion of a wild type allele onto the male Y-chromosome. Previous efforts to produce a B. tryoni GSS for SIT took advantage of a temperature sensitive lethal (tsl) mutation obtained through inbreeding laboratory cultures [5]. The bent wings (bw) strain carried a recessive curved wing mutation on chromosome 2, causing poor flight ability in addition to lethality at high temperatures. Heat treating 1 day old wild type or bw eggs at 40 °C for 4 h caused 4.6 and 80% lethality respectively, while rearing puparium at 31 °C caused 15% lethality in wild type and 100% lethality in bw. This bw tsl mutation was therefore proposed as a conditional lethal trait that could be used to form the basis of a B. tryoni GSS, although a tsl causing complete embryonic lethality at a temperature that does not result in a fitness cost for wild types would be more ideal. As the autosomal bw mutation affects both males and females, a functional bw allele (bw+) is required on the male Y chromosome to protect males from temperature sensitivity. Meats et al. [5] used gamma radiation on a strain without bent wings to induce translocations between chromosome 2 and the Y chromosome (2-Y translocations). Extensive screening through crossing viable irradiated lines with bent wings produced a strain where females expressed bent wing phenotype and males had normal wings due to the 2-Y translocation. Unfortunately, the 2-Y translocation males were also temperature sensitive and unsuitable for use as a GSS.

Random mutagenesis methods, including ionizing radiation, have been shown to induce genome wide germline mutations that often result in reduced fitness of the mutants [6,7,8]. Generating desirable mutants using these methods can therefore be challenging. Targeted approaches for precise gene editing and modification, including the Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/CRISPR-associated 9 (Cas9) technology [9], provided new opportunities for creating GSS. The CRISPR/Cas9 technology can be used to induce frame-shift mutations in the form of indels (insertions or deletions) through the non-homologous end-joining (NHEJ) repair mechanism to knock out genes or introduce specific genetic modifications (“knock-in”) via the homology-directed repair (HDR) mechanism using a donor template. We have previously created a B. tryoni strain with a white eye phenotype, through a white gene knock out using the NHEJ pathway [10], demonstrating that the CRISPR/Cas9 technology is applicable to B. tryoni and could hence be used to produce a B. tryoni GSS. The generation of a functional GSS using CRISPR/Cas9 gene editing will require creating an efficient embryonic conditional lethal mutation such as a tsl mutation (usually through the HDR mechanism), followed by translocation or insertion of a functional copy of the gene into identified Y chromosome regions [11]. The aim of this study is to introduce a tsl mutation into the germline of B. tryoni using the CRISPR/Cas9 technology.

A GSS of the Mediterranean fruit fly (Medfly, Ceratitis capitata (Wiedemann)) that carries a tsl mutation causing complete embryonic lethality was previously generated using random mutagenesis [12]. Recreating the Medfly homologous mutation in B. tryoni using CRISPR/Cas9-mediated mutagenesis is currently not possible as its genetic basis is still unknown. An alternative approach is to take known temperature mutations characterised in other systems and introduce homologous mutations into the genome of B. tryoni. Studies have previously been conducted to identify tsl mutations in Drosophila melanogaster [13,14,15,16] and among them are those detected in the shibire gene. Shibire is a dynamin GTPase involved in formation of endocytic vesicles required for synaptic vesicle recycling and transmission at nerve terminals [17]. The shibire temperature sensitive-1 (shits1) mutation is a G-to-A point mutation that results in a single amino acid substitution at the boundary of the shibire GTPase domain [18]. The shits1 mutation results in embryonic lethality and adult paralysis when treated at the higher temperature of 29 °C [13]. The homologous mutation has also been shown to have a temperature sensitive effect in human cells [19], providing further support that this specific mutation results in a temperature sensitive phenotype.

Here we use the CRISPR/Cas9-mediated HDR pathway to successfully introduce a specific mutation with a donor template and the crRNA-tracRNA guide system, creating the orthologous D. melanogaster shits1 mutation in the B. tryoni shibire gene. We found the desired shits1 mutation to be homozygous lethal in B. tryoni even at ambient temperatures with a fitness cost to the heterozygotes, making it unsuitable as a genetic sexing trait. Nevertheless, our established CRISPR/Cas9 technique of generating precise single base substitution allows the possibility of introducing other candidate tsl mutations to obtain a functional B. tryoni GSS in the future.

Results

Identification of the D. melanogaster shibire ortholog in B. tryoni

A BLAST comparison search against the B. tryoni draft genome (JHQJ00000000) [20] was performed using the D. melanogaster shibire gene sequence (Flybase FBgn0003392), which identified an orthologous gene on scaffold Btry154 (GenBank accession JHQJ01000182.1 position 173,234….213,616). This scaffold has been mapped to one end of the B. tryoni chromosome 5 [21], which is homologous to the D. melanogaster X where the D. melanogaster shibire gene is located. A NCBI Conserved Domain search (CD-search) identified conserved domains in the B. tryoni shibire protein, including the domain where the D. melanogaster shits1 mutation is located (Fig. 1). The amino acid residue (Glycine-268) that causes temperature sensitivity in D. melanogaster when mutated to aspartic acid (the shits1 mutation) is conserved in the B. tryoni shibire ortholog (Fig. 1).

Fig. 1
figure 1

Protein alignment comparing the D. melanogaster and B. tryoni shibire. There is a high level of conservation between the two proteins (90% identity). Amino acid 268 is mutated in the shits1 mutant, which changes the glycine (G) residue to an aspartic acid (D) residue. Middle = Middle domain, PH = pleckstrin homology domain, GED = GTPase effector domain

Designing CRISPR/Cas9 components to target the shi ts1 locus in B. tryoni

A 635 bp region in exon 3 of the shibire gene was sequenced in eight B. tryoni individuals of the Ourimbah laboratory strain to determine if there were any single nucleotide polymorphisms (SNPs) within that region. A guide RNA sequence was designed with a protospacer adjacent motif (PAM) cut site seven bases upstream of the shits1 locus (Fig. 2). A blastn search of the guide RNA sequence against the B. tryoni reference genome revealed no likely off-target matches. The shits1 guide sequence had no additional exact hits and five other sequences contained at least 5 mismatches, but all lacked a PAM site.

Fig. 2
figure 2

CRISPR guide sequence used to introduce the shits1 point mutation into B. tryoni. The single base change that is being induced in the shits1 locus is a ‘G’ to ‘A’, resulting in change of the amino acid residue glycine (G, highlighted by the red box) to aspartic acid and removing the BaeGI restriction site (GKGCM^C). The red arrow indicates the PAM cut site

CRISPR/Cas9 mutagenesis efficiency using the shibire guide RNA sequence was assessed through a T7 Endonuclease I (T7EI) assay in vivo (Fig. 3, Additional File 2). The CRISPR/Cas9 ribonucleoprotein (RNP) complex was microinjected into 150–200 embryos less than one hour old, then after 24 h they were pooled into groups of 20–30 for DNA isolation and PCR amplification. Amplicon cleavage was observed for all injected samples in the T7EI assay, forming banding patterns consistent with indels introduced at the target site through CRISPR/Cas9 NHEJ. Amplicons from uninjected control embryos were not cleaved.

Fig. 3
figure 3

Assessing the efficiency of CRISPR/Cas9-mediated DNA cleavage at the shits1 locus. T7 Endonuclease I (T7EI) assay was performed to assess mutagenesis efficiency using the CRISPR/Cas9 RNP complexes. T7EI-induced cleavage at the shits1 target site (resulting in 539 bp and 318 bp fragments) was observed in all injected samples and not in the uninjected control embryos. This indicated successful targeting of the shi locus using that particular guide sequence. UC = uncleaved, injected sample was not treated with the T7E1

Introduction of the shi ts1 mutation into B. tryoni shibire

In order to introduce the shits1 mutation into the B. tryoni genome, a 151 nt single-stranded oligo donor template (ssODN) containing the shits1 G➔A base substitution was designed (see Supplementary Table S1, Additional File 1). The CRISPR/Cas9 RNP complex consisting of the crRNA-tracrRNA complex and Cas9 enzyme was injected into embryos together with the ssODN HDR template. Three different concentrations of the ssODN (200 ng/μL, 250 ng/μL and 300 ng/μL) were tested to determine the optimal concentration for inducing mutagenesis. The ssODN concentration was found to inversely correlate with the percentage of injected embryo survival to adulthood (Table 1), suggesting that there is increased toxicity with higher ssODN concentrations. The 200 ng/μL ssODN concentration was found to be the optimal of these three concentrations, as it produced two germline mutants out of 14 G0 adults, including a female that carried the desired shits1 single base substitution (7.1% mutagenesis efficiency, Table 1, Fig. 4). Detection of the germline mutation was confirmed by genotyping G1 progeny from the individual mating of the G0 female with wild type laboratory males.

Table 1 Summary of the microinjections performed using the crRNA-tracrRNA RNP complex system to introduce the shits1 point mutation into B. tryoni
Fig. 4
figure 4

Mutant alleles identified from the G1 population at the shits1 locus. Shits1 CRISPR/Cas9 mutagenesis experiments produced two mutant genotypes (the shits1 single base substitution and a 4 bp deletion) in G1 progeny. The shits1 G to A mutant allele (highlighted in red) causes a glycine (G) to aspartic acid (D) amino acid change (highlighted in blue). A 4 bp deletion (indicated by the red dotted lines) causes a frameshift and consequently a change in the downstream amino acid sequence (highlighted in blue). WT = wild type (reference genome) sequence, KI = knock-in, Del = deletion. The 3 bp PAM sequence is underlined with a bold line and the 20 bp guide sequence with dotted lines, with the red arrow indicating the PAM cut site. The base where the shits1 point mutation is made is highlighted in bold and with an asterisk

The shi ts1mutation carries a fitness cost in B. tryoni

Eighteen shits1/+ heterozygous mutants (11 males and 7 females) were identified from 120 G1 flies screened (Table 1). Seven of the surviving shits1/+ G1 flies (five males and two females) were mated to each other and the G2 progeny were reared at 25 °C (±2 °C). 100 G2 adult progeny were then genotyped with the expectation of Mendelian segregation ratios of 1:2:1 (shits1/shits1: shits1/+: +/+). However, no shits1/shits1 homozygotes were identified suggesting that this genotype is homozygous lethal at 25 °C (Fig. 5). Only 19 of the G2 flies were detected to be shits1/+ heterozygous mutants (7 males and 12 females) with the remaining 81 G2 flies wild type. This result deviates significantly (X2(2) =169.66, p < 2.2 × 10− 16) from the expected 1:2:1 ratio and highlights a fitness cost to B. tryoni individuals with at least one shits1 allele.

Fig. 5
figure 5

Genetic crosses performed to determine ratio of progeny carrying shits1 mutant allele(s). Crosses were carried out over three generations (G1-G3 matings) and the G2-G4 adult progeny were genotyped to determine if they carried any shits1 mutant allele(s). The observed ratio of progeny from each mating was compared to the expected ratio

Homozygous shits1/shits1 D. melanogaster have been shown to have a 77% egg hatch rate at 22 °C and high pupal eclosion rate of 98% [22]. In order to determine whether B. tryoni shits1/ shits1 homozygotes are viable at a lower temperature similar to the D. melanogaster mutants, the 19 shits1/+ heterozygous G2 mutants were mated inter se and their eggs (G3 progeny) were collected and reared at 21 °C (±2 °C) until pupation, after which they were moved to 25 °C to increase development. Genotyping performed on 105 G3 adults revealed that there were again no shits1 homozygotes amongst the progeny (Fig. 5). 52 shits1/+ heterozygotes and 53 wildtype (+/+) flies were identified at 1:1 progeny ratio instead of the expected 2:1 ratio (X2(2) = 53.514, p < 2.4 × 10− 12). From the 52 shits1/+ heterozygotes identified in the G3 screening, 33 of the flies (18 males and 15 females) were then mated inter se. Eggs (G4 progeny) were collected from the mating and reared at 21 °C (±2 °C) this time until adult eclosion to determine the effects of rearing the eggs through to adulthood at the low temperature. Of the 70 G4 progeny genotyped, 29 were wild type flies, 38 were shits1/+ heterozygotes and 3 flies were identified as homozygous shits1/shits1flies. Although a small number of shits1/shits1 homozygotes was obtained when reared at 21 °C, they all died soon after genotyping. The deviation between observed (1:13:10) and expected (1:2:1) ratios was significant (X2(2) = 19.829, p < 4.9 × 10− 5). The continual failure to obtain viable shits1/shits1 homozygotes and shits1/+ heterozygotes at the expected proportions (25 and 50% of the total progeny respectively from each mating cross) demonstrated that there is lethality associated with the shits1 mutation in B. tryoni even at lower temperatures.

Discussion

Targeted mutagenesis using the CRISPR/Cas9 genome editing technology has now been successfully achieved in a number of agricultural pest species, where non-specific indel mutations were generated through the NHEJ pathway [10, 23,24,25,26,27,28]. Whilst NHEJ-induced indel mutations have been useful for enabling the study of gene function, a greater focus has now been placed on using the HDR repair pathway particularly to introduce precise mutations to generate specific mutants without producing transgenic strains that contain DNA from other species. Conditional lethal mutants, such as temperature sensitive mutants, are crucial for development of effective SIT genetic sexing strains. Temperature sensitive mutations identified in the model organism D. melanogaster have primarily been found to be single base substitutions [13,14,15,16, 29], and precise CRISPR/Cas9-mediated HDR mutagenesis of homologous sites in B. tryoni may help generate these useful traits for producing a B. tryoni GSS. Successful HDR have been demonstrated in various dipteran species [30,31,32,33,34], involving the introduction or editing of transgenes, however there have been no reports of precise single base substitutions in endogenous genes.

The CRISPR/Cas9 system is a ribonucleoprotein (RNP) complex consisting of the bacterial endonuclease Cas9 and a guide RNA complex containing a unique sequence complementary to its target sequence in the genome [9]. The RNA complex can either be made up of two RNA structures – the CRISPR RNA (crRNA) and the trans-activating CRISPR RNA (tracrRNA) or a long single synthetic guide RNA (sgRNA) structure. Whilst a RNP complex consisting of the crRNA and tracrRNA mimics the bacterial system from which this CRISPR/Cas technology originates from, many research labs opt for the use of the sgRNA that combines the crRNA and tracrRNA into the single RNA structure and which can be easily synthesised in the laboratory [35].

We have previously demonstrated success using the in vitro-transcribed sgRNA method to generate indel mutations in the B. tryoni white gene via the NHEJ pathway [10] but have had no success using the same method to introduce a precise single base substitution through the HDR pathway (see Supplementary Methods, Table S2, Additional File 1). A recent study has shown that in vitro-transcribed sgRNAs, due to a triphosphate group introduced at the 5′ terminus by the T7 polymerase, can trigger the innate immune response in cells resulting in cell death [36]. This could potentially lead to poorer survival rates post microinjections in addition to the lethality induced by the microinjection process itself and consequently a larger number of injected embryos are required to obtain a desired mutant. That, coupled with the HDR pathway being the less efficient cellular repair pathway [37], could have contributed to difficulties in obtaining our desired mutant using the in vitro-transcribed sgRNA method in our B. tryoni organism. Some studies have shown that the use of crRNA-tracrRNA complexes can result in higher HDR efficiencies compared to sgRNAs [38,39,40]. There are also the benefits of the crRNAs and tracRNAs being easily chemically synthesised and modified, making the RNP complex more stable and less likely to induce an immune response, thus being an overall more efficient protocol [41]. In this study, we successfully utilised the crRNA-tracrRNA RNP complex system to introduce into the B. tryoni genome the specific shits1 single base substitution with a detected mutagenesis efficiency of 7.1%. This is, to our knowledge, not only the first report of CRISPR/Cas9-mediated precise single base substitution in an endogenous gene of an agricultural pest insect, but also the first report of gene editing using the crRNA-tracrRNA guide system in tephritids, which we have shown to be more effective than the commonly used sgRNA system in regards to making this precise shits1 base change.

In D. melanogaster, the shibire temperature lethal mutation shits1 was found to result in embryonic lethality and cause larval and adult paralysis if treated at 29 °C during the specific life stages [13]. We successfully engineered the homologous shits1 mutation into B. tryoni but were unable to obtain and/or maintain viable homozygotes even at 21 °C. A decrease in viability has been reported for shits1 homozygotes at 22 °C in D. melanogaster, with an overall 41% survival rate from the embryonic stage to eclosion [22], suggesting that the mutation does have a slight fitness cost; however in B. tryoni, the effects of the shits1 mutation on viability is far more severe. We found the shits1 mutation to be homozygous lethal even at low temperatures and resulted in significantly lower viability in the heterozygotes.

The shits1 mutation is thought to induce a conformational change in the protein, affecting the GTP binding site and protein aggregation, thus blocking endocytosis [42]. Despite Drosophilidae and Tephritidae diverging an estimated 70–100 million years ago [11, 43, 44], the shibire protein remains highly conserved. It is unclear why B. tryoni shits1 mutants appear to have a higher fitness cost than in D. melanogaster, however one possibility could be the contribution of modifier genes affecting shibire and/or its functional pathways, with different genetic modifiers present or with differential expression in D. melanogaster and B. tryoni. Indeed it has been observed that identical mutations in the same gene can lead to varying phenotypes in organisms with different genetic backgrounds [45]. This study highlights that replication of a phenotype may not always be successful despite high conservation of the protein sequence.

Conclusions

We successfully introduced the D. melanogaster temperature sensitive lethal shibire ts1 (shits1) point mutation into the B. tryoni genome. The shits1 mutation was shown be homozygous lethal in B. tryoni and has a fitness cost in heterozygotes even at lower temperatures, making it unsuitable as a GSS. We have nonetheless demonstrated an efficient method for engineering precise single base mutations via the CRISPR/Cas9-mediated HDR pathway in B. tryoni, which can be applied to other tephritid flies and non-model organisms and be used in further efforts to generate a functional GSS for SIT.

Methods

Fly rearing

Bactrocera tryoni flies were from New South Wales Department of Primary Industries (NSW DPI), Ourimbah, Australia. Flies were reared under a controlled environment (25 ± 2 °C, 65 ± 10% relative humidity (RH) and under a 14:10 light/dark cycle), as described in Choo et al. [10]. Eggs from B. tryoni carrying the shits1 allele were maintained at 21 °C (±2 °C) unless described otherwise.

Bactrocera tryoni shibire gene analyses

The D. melanogaster shibire gene sequence (FBgn0003392) and protein sequence (FBpp0290811) were obtained from Flybase and the gene sequence used in a blastn search against the B. tryoni genome (JHQJ00000000) with Geneious 7.17 and 10.1.3. Conserved domains within the B. tryoni shibire were identified through a NCBI Conserved Domain search (CD-search). Amplification of B. tryoni genomic DNA spanning the shits1 locus was performed as described in Choo et al. [10] using MyTaq polymerase, forward primer 5′-CGAGGATGAAACGGATCGTG-3′ and reverse primer 5′-GATCGTCAGGTCTGAAGTGC-3′ with the following cycling conditions: 95 °C for 2 min, 35 cycles of 95 °C for 15 s, 55 °C for 15 s and 72 °C for 3 min, followed by a final extension at 72 °C for 7 mins. Amplicon sequencing was carried out by the Australian Genome Research Facility (AGRF Adelaide).

CRISPR/Cas9 reagents

All CRISPR/Cas9 reagents used to generate the shits1 mutant were obtained from Integrated DNA Technologies (IDT) as follows: purified Cas9 protein (Alt-R® S.p. Cas9 nuclease 3NLS, #1078729, 10 μg/μL), guide RNAs (customised Alt-R® CRISPR/Cas9 crRNA, 2 nmol and Alt-R® CRISPR/Cas9 tracrRNA, #1072532, 5 nmol) and customised ultramer® DNA oligo (4 nmol) which was used as the 151 nt single-stranded donor (ssODN) template for HDR. The guide RNAs were resuspended to a 100 μM stock solution with nuclease-free duplex buffer and the ultramer® DNA oligo to 1 μg/μL with ddH2O before use. The customised 20 bp crRNA sequence (shits1 – GTATGGTGTGCCCAAACGAT) was compared against the B. tryoni genome (JHQJ00000000) through a blastn search using Geneious 7.17 and 10.1.3 to verify that there are no likely off-targets.

Embryo microinjections

Embryo microinjections were performed as described in Choo et al. [10] except for the steps stated otherwise. The injection mixes comprised of 0.3 μg/μL Cas9 protein, 0.12 μg/μL crRNA + 0.22 μg/μL rRNA, 0.2 μg/μL ssODN and 1x injection buffer (0.1 mM sodium phosphate buffer pH 6.8, 5 mM KCl) [46]. The crRNA and tracrRNA were first heated together at 95 °C for 5 min and cooled to room temperature to allow annealing to form a crRNA-tracrRNA complex. The crRNA-tracrRNA complex was then mixed with the Cas9 enzyme, ssODN and injection buffer to make the injection mix. Embryos 0–1 h old were adhered to a glass coverslip with Maruni rubber cement (No. 37022C) and injected under paraffin oil. Microscope slides with injected embryos were placed on 1% agar in a Petri dish, which was then placed in a “humid box” (a vented container with wet paper towels) and left for 48–72 h to allow larval hatching. Hatched first-instar larvae and developing embryos were then transferred to the gel diet for larval development and reared to adulthood, with all surviving adults designated as G0 flies.

T7 endonuclease I cleavage assay

CRISPR/Cas9 mixes were microinjected into embryos less than 1 h old. Embryos that had not been injected were used as controls. After 24 h, embryos were pooled in groups of 20–30 and genomic DNA was isolated using the Phire Animal Tissue Direct PCR kit (#F140WH, ThermoFisher Scientific). PCR was performed to amplify 857 bp of the DNA region containing the shibire mutation loci using the Phire polymerase with the forward primer 5′-CACCAGTTTCGATGAGATCC-3′ and reverse primer 5′ CAAAGCTGAACCGGAACCTT-3′. The PCR cycling conditions used were 98 °C for 5 min, 35 cycles of 98 °C for 5 s, 60 °C for 5 s and 72 °C for 40 s, followed by a final extension at 72 °C for 1 min. 200 ng of PCR amplicon were then denatured and reannealed using the following conditions: 95 °C for 5 min, ramp down to 85 °C at − 2 °C/s and ramp down to 25 °C at − 0.1 °C/s. The annealed PCR products were then incubated with 1 μL of T7 endonuclease I (New England BioLabs, M0302S) at 37 °C for 15 mins. Products were visualised using 2% agarose (Scientifix Pty. Ltd., #9010E) gel electrophoresis.

Molecular detection of CRISPR/Cas9-induced shibire tsl mutations

For the genotyping assays, genomic DNA was extracted from a single adult leg using the Phire Animal Tissue Direct PCR kit. PCR was performed as described above for the T7 Endonuclease I cleavage Assay. The PCR amplicons were then digested with the BaeG1 restriction enzyme (New England BioLabs, R0708S) at 37 °C for 1.5 h to distinguish potential heterozygous mutants (partially digested products) from wild type (digested products). PCR amplicons of heterozygotes were Sanger sequenced for genotype validation (AGRF Adelaide).

Genetic crosses

Individual G0 flies were mated to 6–8 virgin flies from the Ourimbah laboratory strain. A minimum of 50 G1 adult progeny were collected from each successful G0 mating for genotyping, with the exception of when less than 50 G1 progeny were obtained. Mutagenesis efficiencies were calculated as the percentage of G0 adults with an identified germline mutation out of the total number of G0 flies obtained. Upon detection of a shits1 germline mutation, further crosses were carried out between identified shits1/+ heterozygous siblings of the G1, G2 and G3 generations. Eggs were collected from each mating and reared under the conditions as described: G2 eggs reared to adulthood at normal rearing temperature (25 °C) while G3 and G4 eggs were reared at 21 °C up to pupation (and then moved to 25 °C) and adulthood respectively. Genotyping was performed on all obtained adult progeny. The ratios of G2 – G4 progeny carrying the shits1 mutant allele(s) were determined for the G1 – G3 matings and Pearson’s Chi-square goodness of fit tests were performed using R ‘chisq.test’ [47] to determine significance between the observed and expected genotypes.

Availability of data and materials

Data generated in this study is provided in the manuscript and supplementary information. Sequence data for the shibire gene was obtained from Genbank accession JHQJ01000182.1, position 173,234….213,616 and is available from https://0-www-ncbi-nlm-nih-gov.brum.beds.ac.uk/nuccore/JHQJ01000182.1 [20].

Abbreviations

SIT:

Sterile Insect Technique

GSS:

Genetic Sexing Strain

tsl:

Temperature sensitive lethal

CRISPR/Cas9:

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/CRISPR-associated 9 (Cas9) technology

NHEJ:

Non-homologous end-joining

HDR:

Homology-directed repair

SNP:

Single nucleotide polymorphism

PAM:

Protospacer adjacent motif

T7E1:

T7 Endonuclease 1

RNP:

Ribonucleoprotein

ssODN:

Single-stranded oligo donor

sgRNA:

Synthetic guide RNA

crRNA:

CRISPR RNA

tracrRNA:

Trans-activating CRISPR RNA

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Acknowledgements

We thank Kostas Bourtzis (IAEA) and Phil Taylor (Macquarie University) for providing technical and intellectual advice. The study has benefitted from discussions at International Atomic Energy Agency funded meetings for the Coordinated Research Project “Comparing Rearing Efficiency and Competitiveness of Sterile Male Strains Produced by Genetic, Transgenic or Symbiont-based Technologies”.

About this supplement

This article has been published as part of BMC Genetics Volume 21 Supplement 2, 2020: Comparing rearing efficiency and competitiveness of sterile male strains produced by genetic, transgenic or symbiont-based technologies. The full contents of the supplement are available online at https://0-bmcgenet-biomedcentral-com.brum.beds.ac.uk/articles/supplements/volume-21-supplement-2.

Funding

This project is part of the National SITplus program and has been funded by Horticulture Innovation Australia, using the research and development levy funds from the vegetable, apple and pear, citrus, strawberry, table grape, cherry and summerfruit industries, with co-investment from South Australian Research and Development Institute (SARDI) and Primary Industries and Regions South Australia (PIRSA), and funds from the Australian Government. SWB is supported by the Australian Research Council (FT140101303). The funding bodies played no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript. Publication costs are funded by the Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture, IAEA (CRP No.: D4.20.16) Vienna, Austria.

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AC, RS, PC and SWB conceived and designed the study. AC, EF and IYC performed the experiments and analysed and interpreted the data. AC and SWB wrote the manuscript; EF revised the manuscript. All authors read and approved the manuscript.

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Correspondence to Amanda Choo.

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Supplementary Information

Additional file 1.

Supplementary Methods. Supplementary Reference. Supplementary Table S1. Supplementary Table S2.

Additional file 2.

Raw gel image of T7 Endonuclease I (T7EI) assay result.

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Choo, A., Fung, E., Chen, I.Y. et al. Precise single base substitution in the shibire gene by CRISPR/Cas9-mediated homology directed repair in Bactrocera tryoni. BMC Genet 21 (Suppl 2), 127 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s12863-020-00934-3

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