Stable transformation of mosquito cell lines using a hsp70::neo fusion gene

Temperature-Inducible Precision-Guided Sterile Insect Technique

Releases of sterile males are the gold standard for many insect population control programs, and precise sex sorting to remove females prior to male releases is essential to the success of these operations. To advance traditional methods for scaling the generation of sterile males, we previously described a CRISPR-mediated precision-guided sterile insect technique (pgSIT), in which Cas9 and gRNA strains are genetically crossed to generate sterile males for mass release. While effective at generating F1 sterile males, pgSIT requires a genetic cross between the two parental strains, which requires maintenance and sexing of two strains in a factory. Therefore, to advance pgSIT further by removing this crossing step, here we describe a next-generation temperature-inducible pgSIT (TI-pgSIT) technology and demonstrate its proof-of-concept in Drosophila melanogaster. Importantly, we were able to develop a true breeding strain for TI-pgSIT that eliminates the requirement for sex sorting-a feature that may help further automate production at scale.

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

Aedes (Ae.) aegypti and Ae. albopictus mosquitoes transmit arthropod-borne diseases around the globe, causing ~ 700,000 deaths each year. Genetic mutants are valuable tools to interrogate both fundamental vector biology and mosquito host factors important for viral infection. However, very few genetic mutants have been described in mosquitoes in comparison to model organisms. The relative ease of applying CRISPR/Cas9-based gene editing has transformed genome engineering and has rapidly increased the number of available gene mutants in mosquitoes. Yet, in vivo studies may not be practical for screening large sets of mutants or possible for laboratories that lack insectaries. Thus, it would be useful to adapt CRISPR/Cas9 systems to common mosquito cell lines. In this study, we generated and characterized a mosquito optimized, plasmid-based CRISPR/Cas9 system for use in U4.4 (Ae. albopictus) and Aag2 (Ae. aegypti) cell lines. We demonstrated highly efficient editing of the AGO1 locus and isolated U4.4 and Aag2 cell lines with reduced AGO1 expression. Further, we used homology-directed repair to establish knock-in Aag2 cell lines with a 3xFLAG-tag at the N-terminus of endogenous AGO1. These experimentally verified plasmids are versatile, cost-effective, and efficiently edit immune competent mosquito cell lines that are widely used in arbovirus studies.

Generation of stable Drosophila cell lines using multicistronic vectors

Insect cell culture is becoming increasingly important for applications including recombinant protein production and cell-based screening with chemical or RNAi libraries. While stable mammalian cell lines expressing a protein of interest can be efficiently prepared using IRES-based vectors or viral-based approaches, options for stable insect cell lines are more limited. Here, we describe pAc5-STABLEs, new vectors for use in Drosophila cell culture to facilitate stable transformation. We show that viral-derived 2A-like (or "CHYSEL") peptides function in Drosophila cells and can mediate the multicistronic expression of two or three proteins of interest under control of the Actin5C constitutive promoter. The current vectors allow mCherry and/or GFP fusions to be generated for positive selection by G418 resistance in cells and should serve as a flexible platform for future applications.

Gene targeting in mosquito cells: a demonstration of 'knockout' technology in extrachromosomal gene arrays

BACKGROUND

Gene targeting would offer a number of advantages over current transposon-based strategies for insect transformation. These include freedom from both position effects associated with quasi-random integration and concerns over transgene instability mediated by endogenous transposases, independence from phylogenetic restrictions on transposon mobility and the ability to generate gene knockouts.

RESULTS

We describe here our initial investigations of gene targeting in the mosquito. The target site was a hygromycin resistance gene, stably maintained as part of an extrachromosomal array. Using a promoter-trap strategy to enrich for targeted events, a neomycin resistance gene was integrated into the target site. This resulted in knockout of hygromycin resistance concurrent with the expression of high levels of neomycin resistance from the resident promoter. PCR amplification of the targeted site generated a product that was specific to the targeted cell line and consistent with precise integration of the neomycin resistance gene into the 5' end of the hygromycin resistance gene. Sequencing of the PCR product and Southern analysis of cellular DNA subsequently confirmed this molecular structure.

CONCLUSIONS

These experiments provide the first demonstration of gene targeting in mosquito tissue and show that mosquito cells possess the necessary machinery to bring about precise integration of exogenous sequences through homologous recombination. Further development of these procedures and their extension to chromosomally located targets hold much promise for the exploitation of gene targeting in a wide range of medically and economically important insect species.

Mobility assays confirm the broad host-range activity of the Minos transposable element and validate new transformation tools

Fast and reliable methods for assessing the mobility of the transposable element Minos have been developed. These methods are based on the detection of excision and insertion of Minos transposons from and into plasmids which are co-introduced into cells. Excision is detected by polymerase chain reaction (PCR) with appropriate primers. Transposition is assayed by marker rescue in Escherichia coli, using a transposon plasmid that carries a tetracycline resistance gene and a target plasmid carrying a gene that can be selected against in E. coli. Using both assays, Minos was shown to transpose in Drosophila melanogaster cells and embryos, and in cultured cells of a mosquito, Aedes aegypti, and a lepidopteran, Spodoptera frugiperda. In all cases, mobility was dependent on the presence of exogenously supplied transposase, and both excision and transposition were precise. The results indicate that Minos can transpose in heterologous insect species with comparable efficiencies and therefore has the potential to be used as a transgenesis vector for diverse species.

Toward Anopheles transformation: Minos element activity in anopheline cells and embryos

The ability of the Minos transposable element to function as a transformation vector in anopheline mosquitoes was assessed. Two recently established Anopheles gambiae cell lines were stably transformed by using marked Minos transposons in the presence of a helper plasmid expressing transposase. The markers were either the green fluorescent protein or the hygromycin B phosphotransferase gene driven by the Drosophila Hsp70 promoter. Cloning and sequencing of the integration sites demonstrated that insertions in the cell genome occurred through the action of Minos transposase. Furthermore, an interplasmid transposition assay established that Minos transposase is active in the cytoplasmic environment of Anopheles stephensi embryos: interplasmid transposition events isolated from injected preblastoderm embryos were identified as Minos transposase-mediated integrations, and no events were recorded in the absence of an active transposase. These results demonstrate that Minos vectors are suitable candidates for germ-line transformation of anopheline mosquitoes.

Construction of modular and versatile plasmid vectors for the high-level expression of single or multiple genes in insects and insect cell lines

We have constructed a series of plasmid vectors for the expression of foreign genes in insects or insect cell lines. We incorporated the Drosophila hsp70 and actin 5C promoters, as well as the hr5 enhancer-driven baculovirus ie1 promoter, into plasmids that allow convenient cloning of heterologous genes into multiple cloning sites. We combined these promoters with either a short, double poly-adenylation site derived from the Heliothis virescens p63 chaperonin gene, or with a fusion of the small t intron with the early 3' untranslated region and poly-adenylation sites of SV40. Unique eight base cutter restriction sites flanking the promoters and poly-adenylation sequences make it possible to transfer the entire transcription units into other sequence contexts, for example, into transposable elements or into other plasmids bearing selectable marker genes. It is also convenient to combine two of our transcription units on the same plasmid in order to express multiple genes simultaneously. To test the ability of our vectors to drive expression of reporter genes, luciferase derivatives were made of the expression plasmids and introduced into Aedes albopictus C6/36 cells by electroporation or into Anopheles gambiae embryos by biolistic particle bombardment. All three promoters directed high levels of luciferase expression. However, there were differences in their relative activities in the two experimental systems. In C6/36 cells, the actin 5C and hr5-ie1 promoters were significantly more active than the hsp70 promoter. In Anopheles embryos, hsp70 and actin 5C had maximal activities, while hr5-ie1 was weaker. We also found that the constructs containing the SV40 small t intron and early 3' untranslated region sequences had higher expression levels than their counterparts containing the Heliothis poly-adenylation sequence. Our most active construct combines the actin 5C promoter with the SV40 intron and 3' untranslated region sequences. This vector was also used to drive expression of a visible marker, the enhanced green fluorescent protein gene, resulting in readily visible green fluorescent protein expression in C6/36 cells.

Comparative analysis of promoters for transient gene expression in cultured mosquito cells

Three heterologous promoters (hsp70 and actin 5C from Drosophila melanogaster and IE1 from the immediate early gene of the Bombyx mori baculovirus) were assessed for their ability to drive transient luciferase expression in mosquito cells. Overall, the actin 5C promoter was considerably more effective at driving luciferase expression than either hsp70 or IE1 in cell lines derived from Anopheles, Aedes and Culex species. hsp70 functioned well when induced by heat shock and was also induced to a lesser extent by chemicals such as sodium arsenite. IE1 was also an effective initiator of transcription, particularly in two Anopheles cell lines, but generally it performed less well than the actin 5C promoter and was also outperformed by hsp70 in Anopheles gambiae cells.

A series of broad host range shuttle vectors for constitutive and inducible expression of heterologous proteins in insect cell lines

A series of shuttle vectors have been constructed that allow expression of heterologous proteins in either dipteran or lepidopteran insect cell lines. Constitutive expression in a broad range of host cells is mediated by the Orgyia pseudotsugata multicapsid nucleopolyhedrosis virus (OpMNPV) immediate-early 2 (ie2) promoter. Alternatively, if inducible expression is required, for example to express cytotoxic proteins, a vector has been constructed that uses the Drosophila metallothionein (Mtn) promoter for metal-inducible protein expression in dipteran cell lines. A chimeric synthetic bacterial-OpMNPV ie promoter-Zeocin resistance gene cassette has been included to facilitate cloning in E. coli as well as the generation of stably transformed insect cell lines. The utility of the system is demonstrated by the constitutive and inducible expression of the highly processed glycosylphosphatidylinositol-anchored glycoprotein, human melanotransferrin, in transformed insect cell lines.

Expression of the membrane protein glycophorin A as a fusion with the antibiotic resistance protein neomycin phosphotransferase II

The gene for the integral membrane protein glycophorin A (GPA) was cloned in frame to the 5' end of the antibiotic resistance gene, neomycin phosphotransferase II (NPT). Protein expression was achieved in Escherichia coli as well as in mammalian cells. In case of Chinese hamster ovary cells (CHO) the resistant populations were analyzed 2 weeks after transfection; the amount of GPA-NPT fusion protein produced was constant from experiment to experiment. Neomycin resistance was directly correlated with GPA expression, thus allowing the direct selection for a stable GPA-expressing cell population without the need of a cloning step. The amount of GPA-NPT produced was further increased by weakening the specific NPT enzymatic activity via site-directed mutagenesis. Detection was simplified by the fact that all different fusion proteins could be detected by the same anti-NPT antibody. This approach may be also applicable to other membrane proteins.

Stable insect cell cultures for recombinant protein production

Insect cells are relatively cheap to maintain and are capable of producing accurately translated and correctly processed heterologous proteins. Recent research has focused on the development of improved expression vectors for continuous, high-level production of foreign proteins, including a number of membrane-targeted receptors, in Drosophila and lepidopteran insect cells. Mosquito cells have also been employed for studies on the control of vector-borne diseases, such as malaria.

DNA transfection in the ecdysteroid-responsive GV1 cell line from the tobacco hornworm, Manduca sexta

The embryonic cell line, GV1, from Manduca sexta was transiently transfected with DNA constructs of the Drosophila hsp70 promoter fused to either a beta-galactosidase (pXH70ZT) or a chloramphenicol acetyl transferase (HSP-CAT-1) reporter gene using lipofectin. Optimal cell density, DNA:lipofectin ratio, and time of incubation were varied to determine the optimal conditions: 2 x 10(5) cells/ml, 1:3, and 5 h. Under these conditions, the transfection efficiency was about 40%. Heat inducibility of two hsp70 constructs was compared. The HSP-CAT-1, containing 1127 bp of upstream sequence, was more sensitive to heat shock than that of pXH70ZT, containing only 194 bp of upstream sequence. Thus, the 1127 bp hsp70 promoter appears to be a better inducible promoter in these cells. A 2 kb fragment of the proximal promoter region of the MHR3 gene containing a putative ecdysone response element was shown to be responsive to 20-hydroxyecdysone after its transfection into these cells.

Baculovirus immediate-early promoter-mediated expression of the Zeocin resistance gene for use as a dominant selectable marker in dipteran and lepidopteran insect cell lines

The antibiotic Zeocin, a derivative of phleomycin, was evaluated for use as a selection system in both dipteran and lepidopteran insect cell lines. Growth of Drosophila cell lines, Kc1 and SL2, was inhibited at Zeocin concentrations of 50 and 75 microg/ml, respectively, while the Spodoptera cell line, Sf9, was inhibited at a concentration of 250 microg/ml Zeocin. The mammalian cytomegalovirus (CMV) and Simian virus 40 (SV40) early promoters did not function in these insect cell lines. Several baculovirus-derived immediate-early (IE) promoters from the Orgyia pseudotsugata multicapsid nucleopolyhedrovirus (OpMNPV) and Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) were used to drive expression of the Zeocin resistance gene (ble) in these cell lines. The resulting plasmid vectors enabled selection of Zeocin-resistant cell lines within 3-4 weeks. Gene amplification events in the presence of increasing Zeocin concentrations were not detected using Southern blot analysis. Furthermore, the function of the baculovirus IE promoters, as demonstrated by beta-galactosidase expression, was not detectable in a variety of mammalian cell lines tested. A cloning/shuttle vector, containing ten unique restriction sites, was constructed which allows for selection of Zeocin resistance in insect cell lines and in Escherichia coli.

Approaches to vector control: new and trusted. 3. Prospects for genetic manipulation of insect vectors

Insect vector control has proved an effective method of reducing the transmission of disease-causing organisms to human populations in many tropical countries. A variety of methods has been employed for suppressing vector populations, including the application of biological control agents and the elimination of breeding sites, with a continuing and heavy reliance on the use of chemical insecticides. However, the development of insecticide resistance by vector insects, the cost of developing and registering new insecticidal compounds, and the increase in legislation to combat the detrimental effects of insecticidal residues on the environment, have emphasized the need to assess a variety of alternatives to vector control. What is required is a completely novel approach either to suppress vector populations, or to alter their ability to transmit disease-causing organisms in such a way as to have a profound and long-lasting effect on disease transmission. Genetic manipulation of insect vectors may provide just such an approach. The major requirements for being able to manipulate the genomes of insects are reviewed together with the progress which has been made to create transgenic vector insects. The potential applications of this technology are then explored, emphasizing that its most immediate use will be as an analytical tool. Finally, the feasibility of creating refractory vector strains by genetic manipulation and releasing them into the environment is assessed in relation to its future use as a disease control strategy.