Your search keyword '"Champer J"' showing total 83 results

1. The role of the vaginal microbiome in gynaecological cancer

Author

Champer, M, Wong, AM, Champer, J, Brito, IL, Messer, PW, Hou, JY, and Wright, JD

Published

2018

2. Status of ZEPLIN II and ZEPLIN III

Author

Alner, G. J., Bewick, A., Bissit, R., Bungau, C., Camanzi, B., Carson, M. J., Cline, D. B., Champer, J., Chen, Y., Davidge, D., Davis, J., Daw, E., Dawson, J. V., Durkin, T. J., Gamble, T., Gao, J., Ghag, C., Howard, A. S., Jones, W. G., Joshi, M. K., Kudryavtsev, V. A., Lawson, T. B., Lebedenko, V., Lewin, J. D., Lightfoot, P. K., Liubarsky, I., Lüscher, R., Maxin, J., McMillan, J. E., Miller, J., Morgan, B., Murphy, A. S., Ooi, W., Paling, S. M., Preece, R. M., Quenby, J. J., Robinson, M., Salinas, G., Seifert, J., Sergiampietri, F., Smith, N. J. T., Smith, P. F., Spooner, N. J. C., Sumner, T. J., Tovey, D. R., Walker, R., Wang, H., White, J. T., Yang, X., Klapdor-Kleingrothaus, Hans Volker, editor, and Arnowitt, Richard, editor

Published

2006

3. Typing of Propionibacterium acnes: a review of methods and comparative analysis

Author

Yu, Y., Champer, J., Garbán, H., and Kim, J.

Published

2015

4. The potential of T Cell-based vaccines for broad-spectrum Antifungal Protection

Author

Champer, J., Diaz-Arevalo, D., Hong, T. B., Ito, J. I., and Kalkum, M.

Published

2012

5. 改变我们的微生物组:皮肤病学中的益生菌

Author

Yu, Y., primary, Dunaway, S., additional, Champer, J., additional, Kim, J., additional, and Alikhan, A., additional

Published

2020

6. Changing our microbiome: probiotics in dermatology

Author

Yu, Y., primary, Dunaway, S., additional, Champer, J., additional, Kim, J., additional, and Alikhan, A., additional

Published

2020

7. Monte Carlo studies of combined shielding and veto techniques for neutron background reduction in underground dark matter experiments based on liquid noble gas targets

Author

Bungau, C., Camanzi, B., Champer, J., Chen, Y., Cline, D.B., Luscher, R., Lewin, J.D., Smith, P.F., Smith, N.J.T., and Wang, H.

Published

2005

8. Changing our microbiome: probiotics in dermatology

Author

Yu, Y., primary, Dunaway, S., additional, Champer, J., additional, Kim, J., additional, and Alikhan, A., additional

Published

2019

9. The role of the vaginal microbiome in gynaecological cancer

Author

Champer, M, primary, Wong, AM, additional, Champer, J, additional, Brito, IL, additional, Messer, PW, additional, Hou, JY, additional, and Wright, JD, additional

Published

2017

10. Typing ofPropionibacterium acnes: a review of methods and comparative analysis

Author

Yu, Y., primary, Champer, J., additional, Garbán, H., additional, and Kim, J., additional

Published

2015

11. Status of ZEPLIN II and ZEPLIN III

Author

Alner, G. J., primary, Bewick, A., additional, Bissit, R., additional, Bungau, C., additional, Camanzi, B., additional, Carson, M. J., additional, Cline, D. B., additional, Champer, J., additional, Chen, Y., additional, Davidge, D., additional, Davis, J., additional, Daw, E., additional, Dawson, J. V., additional, Durkin, T. J., additional, Gamble, T., additional, Gao, J., additional, Ghag, C., additional, Howard, A. S., additional, Jones, W. G., additional, Joshi, M. K., additional, Kudryavtsev, V. A., additional, Lawson, T. B., additional, Lebedenko, V., additional, Lewin, J. D., additional, Lightfoot, P. K., additional, Liubarsky, I., additional, Lüscher, R., additional, Maxin, J., additional, McMillan, J. E., additional, Miller, J., additional, Morgan, B., additional, Murphy, A. S., additional, Ooi, W., additional, Paling, S. M., additional, Preece, R. M., additional, Quenby, J. J., additional, Robinson, M., additional, Salinas, G., additional, Seifert, J., additional, Sergiampietri, F., additional, Smith, N. J. T., additional, Smith, P. F., additional, Spooner, N. J. C., additional, Sumner, T. J., additional, Tovey, D. R., additional, Walker, R., additional, Wang, H., additional, White, J. T., additional, and Yang, X., additional

12. Improving the suppressive power of homing gene drive by co-targeting a distant-site female fertility gene.

Author

Faber NR, Xu X, Chen J, Hou S, Du J, Pannebakker BA, Zwaan BJ, van den Heuvel J, and Champer J

Subjects

Animals, Female, Anopheles genetics, Animals, Genetically Modified, Male, Drosophila melanogaster genetics, Gene Drive Technology methods, Fertility genetics

Abstract

Gene drive technology has the potential to address major biological challenges. Well-studied homing suppression drives have been shown to be highly efficient in Anopheles mosquitoes, but for other organisms, lower rates of drive conversion prevent elimination of the target population. To tackle this issue, we propose a gene drive design that has two targets: a drive homing site where drive conversion takes place, and a distant site where cleavage induces population suppression. We model this design and find that the two-target system allows suppression to occur over a much wider range of drive conversion efficiency. Specifically, the cutting efficiency now determines the suppressive power of the drive, rather than the conversion efficiency as in standard suppression drives. We construct a two-target drive in Drosophila melanogaster and show that both components of the gene drive function successfully. However, cleavage in the embryo from maternal deposition as well as fitness costs in female drive heterozygotes both remain significant challenges for both two-target and standard suppression drives. Overall, our improved gene drive design has the potential to ease problems associated with homing suppression gene drives for many species where drive conversion is less efficient., (© 2024. The Author(s).)

Published

2024

13. Gene Drive and Symbiont Technologies for Control of Mosquito-Borne Diseases.

Author

Wang GH, Hoffmann A, and Champer J

Abstract

Mosquito-borne diseases, such as dengue and malaria, pose a significant burden to global health. Current control strategies with insecticides are only moderately effective. Scalable solutions are needed to reduce the transmission risk of these diseases. Symbionts and genome engineering-based mosquito control strategies have been proposed to address these problems. Bacterial, fungal, and viral symbionts affect mosquito reproduction, reduce mosquito lifespan, and block pathogen transmission. Field tests of endosymbiont Wolbachia -based methods have yielded promising results, but there are hurdles to overcome due to the large-scale rearing and accurate sex sorting required for Wolbachia -based suppression approaches and the ecological impediments to Wolbachia invasion in replacement approaches. Genome engineering-based methods, in which mosquitoes are genetically altered for the modification or suppression of wild populations, offer an additional approach for control of mosquito-borne diseases. In particular, the use of gene drive alleles that bias inheritance in their favor is a potentially powerful approach. Several drives are frequency dependent, potentially giving them broadly similar population dynamics to Wolbachia . However, public acceptance and the behavior of released drives in natural mosquito populations remain challenges. We summarize the latest developments and discuss the knowledge gaps in both symbiont- and gene drive-based methods.

Published

2024

14. Deployment of tethered gene drive for confined suppression in continuous space requires avoiding drive wave interference.

Author

Feng R and Champer J

Abstract

Gene drives have great potential for suppression of pest populations and removal of exotic invasive species. CRISPR homing suppression drive is a powerful but unconfined drive, posing risks of uncontrolled spread. Thus, developing methods for confining a gene drive is of great significance. Tethered drive combines a confined system such as Toxin-Antidote Recessive Embryo drive with a strong drive such as a homing suppression drive. It can prevent the homing drive from spreading beyond the confined drive and can be constructed readily, giving it good prospects for future development. However, we have found that care must be taken when deploying tethered drive systems in some scenarios. Simulations of tethered drive in a panmictic population model reveal that successful deployment requires a proper release ratio between the two components, tailored to prevent the suppression drive from eliminating the confined system before it has the chance to spread. Spatial models where the population moves over a one-dimensional landscape display a more serious phenomenon of drive wave interference between the two tethered drive components. If the faster suppression drive wave catches up to the confined drive wave, success is still possible, but it is dependent on drive performance and ecological parameters. Two-dimensional simulations further restrict the parameter range for drive success. Thus, careful consideration must be given to drive performance and ecological conditions, as well as specific release proposals for potential application of tethered drive systems., (© 2024 John Wiley & Sons Ltd.)

Published

2024

15. Population suppression by release of insects carrying a dominant sterile homing gene drive targeting doublesex in Drosophila.

Author

Chen W, Guo J, Liu Y, and Champer J

Subjects

Animals, Female, Male, Alleles, CRISPR-Cas Systems, Genes, Dominant, Pest Control, Biological methods, Infertility genetics, Infertility therapy, RNA, Guide, CRISPR-Cas Systems genetics, DNA-Binding Proteins, Drosophila melanogaster genetics, Gene Drive Technology methods, Animals, Genetically Modified, Drosophila Proteins genetics, Drosophila Proteins metabolism

Abstract

CRISPR homing gene drives can suppress pest populations by targeting female fertility genes, converting wild-type alleles into drive alleles in the germline of drive heterozygotes. fsRIDL (female-specific Release of Insects carrying a Dominant Lethal) is a self-limiting population suppression strategy involving continual release of transgenic males carrying female lethal alleles. Here, we propose an improved pest suppression system called "Release of Insects carrying a Dominant-sterile Drive" (RIDD), combining performance characteristics of homing drive and fsRIDL. We construct a split RIDD system in Drosophila melanogaster by creating a 3-gRNA drive disrupting the doublesex female exon. Drive alleles bias their inheritance in males, while drive alleles and resistance alleles formed by end-joining cause dominant female sterility. Weekly releases of RIDD males progressively suppressed and eventually eliminated cage populations. Modeling shows that RIDD is substantially stronger than SIT and fsRIDL. RIDD is also self-limiting, potentially allowing targeted population suppression., (© 2024. The Author(s).)

Published

2024

16. Population suppression with dominant female-lethal alleles is boosted by homing gene drive.

Author

Zhu J, Chen J, Liu Y, Xu X, and Champer J

Subjects

Animals, Female, Male, Genes, Lethal, Pest Control, Biological methods, Mosquito Control methods, Animals, Genetically Modified genetics, Genes, Dominant, Gene Drive Technology methods, Drosophila melanogaster genetics, Alleles

Abstract

Background: Methods to suppress pest insect populations using genetic constructs and repeated releases of male homozygotes have recently been shown to be an attractive alternative to older sterile insect techniques based on radiation. Female-specific lethal alleles have substantially increased power, but still require large, sustained transgenic insect releases. Gene drive alleles bias their own inheritance to spread throughout populations, potentially allowing population suppression with a single, small-size release. However, suppression drives often suffer from efficiency issues, and the most well-studied type, homing drives, tend to spread without limit., Results: In this study, we show that coupling female-specific lethal alleles with homing gene drive allowed substantial improvement in efficiency while still retaining the self-limiting nature (and thus confinement) of a lethal allele strategy. Using a mosquito model, we show the required release sizes for population elimination in a variety of scenarios, including different density growth curves, with comparisons to other systems. Resistance alleles reduced the power of this method, but these could be overcome by targeting an essential gene with the drive while also providing rescue. A proof-of-principle demonstration of this system in Drosophila melanogaster was effective in both biasing its inheritance and achieving high lethality among females that inherit the construct in the absence of antibiotic., Conclusions: Overall, our study shows that substantial improvements can be achieved in female-specific lethal systems for population suppression by combining them with various types of gene drive., (© 2024. The Author(s).)

Published

2024

17. Population dynamics in spatial suppression gene drive models and the effect of resistance, density dependence, and life history.

Author

Zhang X, Sun W, Kim IK, Messer PW, and Champer J

Abstract

Due to their super-Mendelian inheritance, gene drive systems have the potential to provide revolutionary solutions to critical public health and environmental problems. For suppression drives, however, spatial structure can cause "chasing" population dynamics that may postpone target population elimination or even cause the drive to fail. In chasing, wild-type individuals elude the drive and recolonize previously suppressed areas. The drive can re-enter these recolonized areas, but often is not able to catch up to wild-type and finally eliminate it. Previous methods for chasing detection are only suitable to limited parameter ranges. In this study with expanded parameter ranges, we found that the shift from chasing dynamics to static equilibrium outcomes is continuous as drive performance is reduced. To quantify this, we defined a Weighted Average Nearest Neighbor statistic to assess the clustering degree during chasing, while also characterizing chasing by the per-generation chance of population elimination and drive loss. To detect chasing dynamics in local areas and to detect the start of chasing, we implemented Density-Based Spatial Clustering of Applications with Noise. Using these techniques, we determined the effect of arena size, resistance allele formation rate in both the germline and in the early embryo from maternally deposited Cas9, life history and reproduction strategies, and density-dependent growth curve shape on chasing outcomes. We found that larger real-world areas will be much more vulnerable to chasing and that species with overlapping generations, fecundity-based density dependence, and concave density-dependent growth curves have smaller and more clustered local chasing with a greater chance of eventual population elimination. We also found that embryo resistance and germline resistance hinder drive performance in different ways. These considerations will be important for determining the necessary drive performance parameters needed for success in different species, and whether future drives could potentially be considered as release candidates.

Published

2024

18. A homing rescue gene drive with multiplexed gRNAs reaches high frequency in cage populations but generates functional resistance.

Author

Hou S, Chen J, Feng R, Xu X, Liang N, and Champer J

Subjects

Animals, Alleles, Drosophila Proteins genetics, Gene Editing, Gene Drive Technology methods, Drosophila melanogaster genetics, RNA, Guide, CRISPR-Cas Systems genetics, CRISPR-Cas Systems genetics

Abstract

CRISPR homing gene drives have considerable potential for managing populations of medically and agriculturally significant insects. They operate by Cas9 cleavage followed by homology-directed repair, copying the drive allele to the wild-type chromosome and thus increasing in frequency and spreading throughout a population. However, resistance alleles formed by end-joining repair pose a significant obstacle. To address this, we create a homing drive targeting the essential hairy gene in Drosophila melanogaster. Nonfunctional resistance alleles are recessive lethal, while drive carriers have a recoded "rescue" version of hairy. The drive inheritance rate is moderate, and multigenerational cage studies show drive spread to 96%-97% of the population. However, the drive does not reach 100% due to the formation of functional resistance alleles despite using four gRNAs. These alleles have a large deletion but likely utilize an alternate start codon. Thus, revised designs targeting more essential regions of a gene may be necessary to avoid such functional resistance. Replacement of the rescue element's native 3' UTR with a homolog from another species increases drive inheritance by 13%-24%. This was possibly because of reduced homology between the rescue element and surrounding genomic DNA, which could also be an important design consideration for rescue gene drives., Competing Interests: Conflict of interest The authors declare that they have no conflict of interest., (Copyright © 2024 Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, and Genetics Society of China. Published by Elsevier Ltd. All rights reserved.)

Published

2024

19. Overriding Mendelian inheritance in Arabidopsis with a CRISPR toxin-antidote gene drive that impairs pollen germination.

Author

Liu Y, Jiao B, Champer J, and Qian W

Subjects

Germination genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Plants, Genetically Modified genetics, Gene Editing methods, Arabidopsis genetics, Pollen genetics, CRISPR-Cas Systems

Abstract

Synthetic gene drives, inspired by natural selfish genetic elements and transmitted to progeny at super-Mendelian (>50%) frequencies, present transformative potential for disseminating traits that benefit humans throughout wild populations, even facing potential fitness costs. Here we constructed a gene drive system in plants called CRISPR-Assisted Inheritance utilizing NPG1 (CAIN), which uses a toxin-antidote mechanism in the male germline to override Mendelian inheritance. Specifically, a guide RNA-Cas9 cassette targets the essential No Pollen Germination 1 (NPG1) gene, serving as the toxin to block pollen germination. A recoded, CRISPR-resistant copy of NPG1 serves as the antidote, providing rescue only in pollen cells that carry the drive. To limit potential consequences of inadvertent release, we used self-pollinating Arabidopsis thaliana as a model. The drive demonstrated a robust 88-99% transmission rate over two successive generations, producing minimal resistance alleles that are unlikely to inhibit drive spread. Our study provides a strong basis for rapid genetic modification or suppression of outcrossing plant populations., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

20. Performance characteristics allow for confinement of a CRISPR toxin-antidote gene drive for population suppression in a reaction-diffusion model.

Author

Zhang S and Champer J

Subjects

Animals, Models, Genetic, Clustered Regularly Interspaced Short Palindromic Repeats, Gene Drive Technology, CRISPR-Cas Systems

Abstract

Gene drive alleles that can bias their own inheritance could engineer populations for control of disease vectors, invasive species and agricultural pests. There are successful examples of suppression drives and confined modification drives, but developing confined suppression drives has proven more difficult. However, CRISPR-based toxin-antidote dominant embryo (TADE) suppression drive may fill this niche. It works by targeting and disrupting a haplolethal target gene in the germline with its gRNAs while rescuing this target. It also disrupts a female fertility gene by driving insertion or additional gRNAs. Here, we used a reaction-diffusion model to assess drive performance in continuous space, where outcomes can be substantially different from those in panmictic populations. We measured drive wave speed and found that moderate fitness costs or target gene disruption in the early embryo from maternally deposited nuclease can eliminate the drive's ability to form a wave of advance. We assessed the required release size, and finally we investigated migration corridor scenarios. It is often possible for the drive to suppress one population and then persist in the corridor without invading the second population, a potentially desirable outcome. Thus, even imperfect variants of TADE suppression drive may be excellent candidates for confined population suppression.

Published

2024

21. Germline Cas9 promoters with improved performance for homing gene drive.

Author

Du J, Chen W, Jia X, Xu X, Yang E, Zhou R, Zhang Y, Metzloff M, Messer PW, and Champer J

Subjects

Animals, Animals, Genetically Modified, CRISPR-Associated Protein 9 metabolism, CRISPR-Associated Protein 9 genetics, Alleles, Female, Male, RNA-Binding Proteins, Promoter Regions, Genetic genetics, Drosophila melanogaster genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Gene Drive Technology methods, CRISPR-Cas Systems, Germ Cells metabolism, RNA, Guide, CRISPR-Cas Systems genetics

Abstract

Gene drive systems could be a viable strategy to prevent pathogen transmission or suppress vector populations by propagating drive alleles with super-Mendelian inheritance. CRISPR-based homing gene drives convert wild type alleles into drive alleles in heterozygotes with Cas9 and gRNA. It is thus desirable to identify Cas9 promoters that yield high drive conversion rates, minimize the formation rate of resistance alleles in both the germline and the early embryo, and limit somatic Cas9 expression. In Drosophila, the nanos promoter avoids leaky somatic expression, but at the cost of high embryo resistance from maternally deposited Cas9. To improve drive efficiency, we test eleven Drosophila melanogaster germline promoters. Some achieve higher drive conversion efficiency with minimal embryo resistance, but none completely avoid somatic expression. However, such somatic expression often does not carry detectable fitness costs for a rescue homing drive targeting a haplolethal gene, suggesting somatic drive conversion. Supporting a 4-gRNA suppression drive, one promoter leads to a low drive equilibrium frequency due to fitness costs from somatic expression, but the other outperforms nanos, resulting in successful suppression of the cage population. Overall, these Cas9 promoters hold advantages for homing drives in Drosophila species and may possess valuable homologs in other organisms., (© 2024. The Author(s).)

Published

2024

22. Battles between ants (Hymenoptera: Formicidae): a review.

Author

Champer J and Schlenoff D

Subjects

Animals, Competitive Behavior, Social Behavior, Behavior, Animal, Ants physiology

Abstract

With their unique colony structure, competition between ants (Hymenoptera: Formicidae) can be particularly intense, with colonies potentially willing to sacrifice large number of individuals to obtain resources or territory under the right circumstances. In this review, we cover circumstances in which ant competition escalates into combat, battle strategies and tactics, and analysis methods for these battles. The trends for when colonies choose to fight can vary greatly dependent on the species and situation, which we review in detail. Because of their large group sizes, ant conflicts can follow different patterns than many other species, with a variety of specialist adaptations and battle strategies, such as specialized worker classes and the need to rapidly recruit large number of compatriots. These same large group sizes also can make ant fighting amenable to mathematical analysis, particularly in the context of Lanchester's laws that consider how total numbers influence the outcome of a confrontation. Yet, dynamic behavior can often disrupt idealized mathematical predictions in real-world scenarios, even though these can still shed light on the explanations for such behavior. We also systematically cover the literature on battles between groups of ants, presenting several other interesting studies on species with unique colony organization, such as army ants and leafcutter ants., (© The Author(s) 2024. Published by Oxford University Press on behalf of Entomological Society of America.)

Published

2024

23. A small-molecule approach to restore female sterility phenotype targeted by a homing suppression gene drive in the fruit pest Drosophila suzukii.

Author

Ma S, Ni X, Chen S, Qiao X, Xu X, Chen W, Champer J, and Huang J

Subjects

Female, Animals, Humans, Drosophila genetics, Drosophila melanogaster genetics, CRISPR-Cas Systems, Fruit, RNA, Guide, CRISPR-Cas Systems, Phenotype, Gene Drive Technology, Infertility, Female genetics

Abstract

CRISPR-based gene drives offer promising prospects for controlling disease-transmitting vectors and agricultural pests. A significant challenge for successful suppression-type drive is the rapid evolution of resistance alleles. One approach to mitigate the development of resistance involves targeting functionally constrained regions using multiple gRNAs. In this study, we constructed a 3-gRNA homing gene drive system targeting the recessive female fertility gene Tyrosine decarboxylase 2 (Tdc2) in Drosophila suzukii, a notorious fruit pest. Our investigation revealed only a low level of homing in the germline, but feeding octopamine restored the egg-laying defects in Tdc2 mutant females, allowing easier line maintenance than for other suppression drive targets. We tested the effectiveness of a similar system in Drosophila melanogaster and constructed additional split drive systems by introducing promoter-Cas9 transgenes to improve homing efficiency. Our findings show that genetic polymorphisms in wild populations may limit the spread of gene drive alleles, and the position effect profoundly influences Cas9 activity. Furthermore, this study highlights the potential of conditionally rescuing the female infertility caused by the gene drive, offering a valuable tool for the industrial-scale production of gene drive transgenic insects., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Ma et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

24. Involvement of miR-8510a-3p in response to Cry1Ac protoxin by regulating PxABCG3 in Plutella xylostella.

Author

Yang J, Xu X, Wu J, Champer J, and Xie M

Subjects

Animals, Larva genetics, Endotoxins genetics, Endotoxins metabolism, Bacillus thuringiensis Toxins metabolism, ATP-Binding Cassette Transporters genetics, ATP-Binding Cassette Transporters metabolism, Hemolysin Proteins genetics, Hemolysin Proteins pharmacology, Hemolysin Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Moths metabolism, Bacillus thuringiensis chemistry, Insecticides pharmacology, Insecticides metabolism, MicroRNAs genetics, MicroRNAs metabolism

Abstract

Overuse of insecticides has accelerated the evolution of insecticide resistance and created serious environmental concerns worldwide, thus incentivizing development of alternative methods. Bacillus thuringiensis (Bt) is an insecticidal bacterium that has been developed as a biopesticide to successfully control multiple species of pests. It operates by secreting several insect toxins such as Cry1Ac. However, metabolic resistance based on ATP-binding cassette (ABC) transporters may play a crucial role in the development of metabolic resistance to Bt. Here, we characterized an ABCG gene from the agricultural pest Plutella xylostella (PxABCG3) and found that it was highly expressed in a Cry1Ac-resistant strain, up-regulated after Cry1Ac protoxin treatment. Binding miR-8510a-3p to the coding sequence (CDS) of PxABCG3 was then confirmed by a luciferase reporter assay and RNA immunoprecipitation. miR-8510a-3p agomir delivery markedly reduced PxABCG3 expression in vivo and consequently decreased the tolerance of P. xylostella to Cry1Ac, while reduction of miR-8510a-3p significantly increased PxABCG3 expression, accompanied by an increased tolerance to Cry1Ac. Our results suggest that miR-8510a-3p could potentially be used as a novel molecular target against P. xylostella or other lepidopterans, providing novel insights into developing effective and environmentally friendly pesticides., Competing Interests: Declaration of competing interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

25. A framework for identifying fertility gene targets for mammalian pest control.

Author

Clark AC, Edison R, Esvelt K, Kamau S, Dutoit L, Champer J, Champer SE, Messer PW, Alexander A, and Gemmell NJ

Subjects

Animals, Mice, Female, Male, Animals, Wild, Mammals, Vertebrates, Pest Control methods, Fertility genetics

Abstract

Fertility-targeted gene drives have been proposed as an ethical genetic approach for managing wild populations of vertebrate pests for public health and conservation benefit. This manuscript introduces a framework to identify and evaluate target gene suitability based on biological gene function, gene expression and results from mouse knockout models. This framework identified 16 genes essential for male fertility and 12 genes important for female fertility that may be feasible targets for mammalian gene drives and other non-drive genetic pest control technology. Further, a comparative genomics analysis demonstrates the conservation of the identified genes across several globally significant invasive mammals. In addition to providing important considerations for identifying candidate genes, our framework and the genes identified in this study may have utility in developing additional pest control tools such as wildlife contraceptives., (© 2023 The Authors. Molecular Ecology Resources published by John Wiley & Sons Ltd.)

Published

2024

26. Resource-explicit interactions in spatial population models.

Author

Champer SE, Chae B, Haller BC, Champer J, and Messer PW

Abstract

Continuous-space population models can yield significantly different results from their panmictic counterparts when assessing evolutionary, ecological, or population-genetic processes. However, the computational burden of spatial models is typically much greater than that of panmictic models due to the overhead of determining which individuals interact with one another and how strongly they interact. Though these calculations are necessary to model local competition that regulates the population density, they can lead to prohibitively long runtimes. Here, we present a novel modeling method in which the resources available to a population are abstractly represented as an additional layer of the simulation. Instead of interacting directly with one another, individuals interact indirectly via this resource layer. We find that this method closely matches other spatial models, yet can dramatically increase the speed of the model, allowing the simulation of much larger populations. Additionally, models structured in this manner exhibit other desirable characteristics, including more realistic spatial dynamics near the edge of the simulated area, and an efficient route for modeling more complex heterogeneous landscapes.

Published

2024

27. Making waves: Comparative analysis of gene drive spread characteristics in a continuous space model.

Author

Pan M and Champer J

Subjects

Humans, CRISPR-Cas Systems, Gene Drive Technology methods

Abstract

With their ability to rapidly increase in frequency, gene drives can be used to modify or suppress target populations after an initial release of drive individuals. Recent advances have revealed many possibilities for different types of drives, and several of these have been realized in experiments. These drives have advantages and disadvantages related to their ease of construction, confinement and capacity to be used for modification or suppression. Though characteristics of these drives have been explored in modelling studies, assessment in continuous space environments has been limited, often focusing on outcomes rather than fundamental properties. Here, we conduct a comparative analysis of many different gene drive types that have the capacity to form a wave of advance in continuous space using individual-based simulations in continuous space. We evaluate the drive wave speed as a function of drive performance and ecological parameters, which reveals substantial differences between drive performance in panmictic versus spatial environments. In particular, we find that suppression drive waves are uniquely vulnerable to fitness costs and undesired CRISPR cleavage activity in embryos by maternal deposition. Some drives, however, retain robust performance even with widely varying efficiency parameters. To gain a better understanding of drive waves, we compare their panmictic performance and find that the rate of wild-type allele removal is correlated with drive wave speed, though this is also affected by other factors. Overall, our results provide a useful resource for understanding the performance of drives in spatially continuous environments, which may be most representative of potential drive deployment in many relevant scenarios., (© 2023 John Wiley & Sons Ltd.)

Published

2023

28. Adversarial interspecies relationships facilitate population suppression by gene drive in spatially explicit models.

Author

Liu Y, Teo W, Yang H, and Champer J

Subjects

Animals, Population Dynamics, Ecosystem, Gene Drive Technology methods

Abstract

Suppression gene drives bias their inheritance to spread through a population, potentially eliminating it when they reach high frequency. CRISPR homing suppression drives have already seen success in the laboratory, but several models predict that success may be elusive in population with realistic spatial structure due to extinction-recolonization cycles. Here, we extend our continuous space framework to include two competing species or predator-prey pairs. We find that in both general and mosquito-specific models, competing species or predators can facilitate drive-based suppression, albeit at the cost of an increased rate of drive loss outcomes. These results are robust in mosquito models with seasonal fluctuations. Our study illustrates the difficulty of predicting outcomes in complex ecosystems. However, our results are promising for the prospects of less powerful suppression gene drives to successfully eliminate target mosquito and other pest populations., (© 2023 John Wiley & Sons Ltd.)

Published

2023

29. A framework for identifying fertility gene targets for mammalian pest control.

Author

Clark AC, Alexander A, Edison R, Esvelt K, Kamau S, Dutoit L, Champer J, Champer SE, Messer PW, and Gemmell NJ

Abstract

Fertility-targeted gene drives have been proposed as an ethical genetic approach for managing wild populations of vertebrate pests for public health and conservation benefit.This manuscript introduces a framework to identify and evaluate target gene suitability based on biological gene function, gene expression, and results from mouse knockout models.This framework identified 16 genes essential for male fertility and 12 genes important for female fertility that may be feasible targets for mammalian gene drives and other non-drive genetic pest control technology. Further, a comparative genomics analysis demonstrates the conservation of the identified genes across several globally significant invasive mammals.In addition to providing important considerations for identifying candidate genes, our framework and the genes identified in this study may have utility in developing additional pest control tools such as wildlife contraceptives., Competing Interests: CONFLICT OF INTEREST The authors have no conflicts of interest to declare.

Published

2023

30. Simulations Reveal High Efficiency and Confinement of a Population Suppression CRISPR Toxin-Antidote Gene Drive.

Author

Zhu Y and Champer J

Subjects

Humans, CRISPR-Cas Systems genetics, Antidotes, Gene Drive Technology

Abstract

Though engineered gene drives hold great promise for spreading through and suppressing populations of disease vectors or invasive species, complications such as resistance alleles and spatial population structure can prevent their success. Additionally, most forms of suppression drives, such as homing drives or driving Y chromosomes, will generally spread uncontrollably between populations with even small levels of migration. The previously proposed CRISPR-based toxin-antidote system called toxin-antidote dominant embryo (TADE) suppression drive could potentially address the issues of confinement and resistance. However, it is a relatively weak form of drive compared to homing drives, which might make it particularly vulnerable to spatial population structure. In this study, we investigate TADE suppression drive using individual-based simulations in a continuous spatial landscape. We find that the drive is actually more confined than in simple models without space, even in its most efficient form with low cleavage rate in embryos from maternally deposited Cas9. Furthermore, the drive performed well in continuous space scenarios if the initial release requirements were met, suppressing the population in a timely manner without being severely affected by chasing, a phenomenon in which wild-type individuals avoid the drive by recolonizing empty areas. At higher embryo cut rates, the drive loses its ability to spread, but a single, widespread release can often still induce rapid population collapse. Thus, if TADE suppression gene drives can be successfully constructed, they may play an important role in control of disease vectors and invasive species when stringent confinement to target populations is desired.

Published

2023

31. Assessment of distant-site rescue elements for CRISPR toxin-antidote gene drives.

Author

Chen J, Xu X, and Champer J

Abstract

Gene drive is a genetic engineering technology that can enable super-mendelian inheritance of specific alleles, allowing them to spread through a population. New gene drive types have increased flexibility, offering options for confined modification or suppression of target populations. Among the most promising are CRISPR toxin-antidote gene drives, which disrupt essential wild-type genes by targeting them with Cas9/gRNA. This results in their removal, increasing the frequency of the drive. All these drives rely on having an effective rescue element, which consists of a recoded version of the target gene. This rescue element can be at the same site as the target gene, maximizing the chance of efficient rescue, or at a distant site, which allows useful options such as easily disrupting another essential gene or increasing confinement. Previously, we developed a homing rescue drive targeting a haplolethal gene and a toxin-antidote drive targeting a haplosufficient gene. These successful drives had functional rescue elements but suboptimal drive efficiency. Here, we attempted to construct toxin-antidote drives targeting these genes with a distant-site configuration from three loci in Drosophila melanogaster . We found that additional gRNAs increased cut rates to nearly 100%. However, all distant-site rescue elements failed for both target genes. Furthermore, one rescue element with a minimally recoded sequence was used as a template for homology-directed repair for the target gene on a different chromosomal arm, resulting in the formation of functional resistance alleles. Together, these results can inform the design of future CRISPR-based toxin-antidote gene drives., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Chen, Xu and Champer.)

Published

2023

32. Harnessing Wolbachia cytoplasmic incompatibility alleles for confined gene drive: A modeling study.

Author

Li J and Champer J

Subjects

Female, Male, Alleles, Cytoplasm genetics, Cytoplasm microbiology, Cytosol, Reproduction genetics, Symbiosis, Animals, Genome, Insect, Insecta genetics, Insecta microbiology, Transgenes, Gene Drive Technology, Wolbachia genetics, Symbiont Induced Cytoplasmic Incompatibility

Abstract

Wolbachia are maternally-inherited bacteria, which can spread rapidly in populations by manipulating reproduction. cifA and cifB are genes found in Wolbachia phage that are responsible for cytoplasmic incompatibility, the most common type of Wolbachia reproductive interference. In this phenomenon, no viable offspring are produced when a male with both cifA and cifB (or just cifB in some systems) mates with a female lacking cifA. Utilizing this feature, we propose new types of toxin-antidote gene drives that can be constructed with only these two genes in an insect genome, instead of the whole Wolbachia bacteria. By using both mathematical and simulation models, we found that a drive containing cifA and cifB together creates a confined drive with a moderate to high introduction threshold. When introduced separately, they act as a self-limiting drive. We observed that the performance of these drives is substantially influenced by various ecological parameters and drive characteristics. Extending our models to continuous space, we found that the drive individual release distribution has a critical impact on drive persistence. Our results suggest that these new types of drives based on Wolbachia transgenes are safe and flexible candidates for genetic modification of populations., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Li, Champer. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

33. Anopheles homing suppression drive candidates exhibit unexpected performance differences in simulations with spatial structure.

Author

Champer SE, Kim IK, Clark AG, Messer PW, and Champer J

Subjects

Animals, Male, Female, Alleles, Inheritance Patterns, Mosquito Vectors genetics, Anopheles genetics, Malaria

Abstract

Recent experiments have produced several Anopheles gambiae homing gene drives that disrupt female fertility genes, thereby eventually inducing population collapse. Such drives may be highly effective tools to combat malaria. One such homing drive, based on the zpg promoter driving CRISPR/Cas9, was able to eliminate a cage population of mosquitoes. A second version, purportedly improved upon the first by incorporating an X-shredder element (which biases inheritance towards male offspring), was similarly successful. Here, we analyze experimental data from each of these gene drives to extract their characteristics and performance parameters and compare these to previous interpretations of their experimental performance. We assess each suppression drive within an individual-based simulation framework that models mosquito population dynamics in continuous space. We find that the combined homing/X-shredder drive is actually less effective at population suppression within the context of our mosquito population model. In particular, the combined drive often fails to completely suppress the population, instead resulting in an unstable equilibrium between drive and wild-type alleles. By contrast, otherwise similar drives based on the nos promoter may prove to be more promising candidates for future development than originally thought., Competing Interests: SC, IK, AC, JC No competing interests declared, PM Reviewing editor, eLife, (© 2022, Champer, Kim et al.)

Published

2022

34. Fitness effects of CRISPR endonucleases in Drosophila melanogaster populations.

Author

Langmüller AM, Champer J, Lapinska S, Xie L, Metzloff M, Champer SE, Liu J, Xu Y, Du J, Clark AG, and Messer PW

Subjects

Animals, Animals, Genetically Modified, CRISPR-Associated Protein 9 metabolism, CRISPR-Cas Systems, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Gene Editing methods, RNA, Guide, CRISPR-Cas Systems genetics, Endonucleases genetics, Endonucleases metabolism, Gene Drive Technology

Abstract

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/Cas9 provides a highly efficient and flexible genome editing technology with numerous potential applications ranging from gene therapy to population control. Some proposed applications involve the integration of CRISPR/Cas9 endonucleases into an organism's genome, which raises questions about potentially harmful effects to the transgenic individuals. One example for which this is particularly relevant are CRISPR-based gene drives conceived for the genetic alteration of entire populations. The performance of such drives can strongly depend on fitness costs experienced by drive carriers, yet relatively little is known about the magnitude and causes of these costs. Here, we assess the fitness effects of genomic CRISPR/Cas9 expression in Drosophila melanogaster cage populations by tracking allele frequencies of four different transgenic constructs that allow us to disentangle 'direct' fitness costs due to the integration, expression, and target-site activity of Cas9, from fitness costs due to potential off-target cleavage. Using a maximum likelihood framework, we find that a model with no direct fitness costs but moderate costs due to off-target effects fits our cage data best. Consistent with this, we do not observe fitness costs for a construct with Cas9HF1, a high-fidelity version of Cas9. We further demonstrate that using Cas9HF1 instead of standard Cas9 in a homing drive achieves similar drive conversion efficiency. These results suggest that gene drives should be designed with high-fidelity endonucleases and may have implications for other applications that involve genomic integration of CRISPR endonucleases., Competing Interests: AL, JC, SL, LX, MM, SC, JL, YX, JD, AC No competing interests declared, PM Reviewing editor, eLife, (© 2022, Langmüller, Champer et al.)

Published

2022

35. Symbionts and gene drive: two strategies to combat vector-borne disease.

Author

Wang GH, Du J, Chu CY, Madhav M, Hughes GL, and Champer J

Subjects

Animals, Mosquito Vectors genetics, Culicidae genetics, Gene Drive Technology, Malaria genetics, Malaria prevention & control, Wolbachia genetics

Abstract

Mosquitoes bring global health problems by transmitting parasites and viruses such as malaria and dengue. Unfortunately, current insecticide-based control strategies are only moderately effective because of high cost and resistance. Thus, scalable, sustainable, and cost-effective strategies are needed for mosquito-borne disease control. Symbiont-based and genome engineering-based approaches provide new tools that show promise for meeting these criteria, enabling modification or suppression approaches. Symbiotic bacteria like Wolbachia are maternally inherited and manipulate mosquito host reproduction to enhance their vertical transmission. Genome engineering-based gene drive methods, in which mosquitoes are genetically altered to spread drive alleles throughout wild populations, are also proving to be a potentially powerful approach in the laboratory. Here, we review the latest developments in both symbionts and gene drive-based methods. We describe some notable similarities, as well as distinctions and obstacles, relating to these promising technologies., Competing Interests: Declaration of interests The authors have no competing interests to declare., (Crown Copyright © 2022. Published by Elsevier Ltd. All rights reserved.)

Published

2022

36. A homing suppression gene drive with multiplexed gRNAs maintains high drive conversion efficiency and avoids functional resistance alleles.

Author

Yang E, Metzloff M, Langmüller AM, Xu X, Clark AG, Messer PW, and Champer J

Subjects

Alleles, Animals, CRISPR-Cas Systems, Drosophila melanogaster genetics, Female, Translocation, Genetic, Gene Drive Technology methods, RNA, Guide, CRISPR-Cas Systems genetics

Abstract

Gene drives are engineered alleles that can bias inheritance in their favor, allowing them to spread throughout a population. They could potentially be used to modify or suppress pest populations, such as mosquitoes that spread diseases. CRISPR/Cas9 homing drives, which copy themselves by homology-directed repair in drive/wild-type heterozygotes, are a powerful form of gene drive, but they are vulnerable to resistance alleles that preserve the function of their target gene. Such resistance alleles can prevent successful population suppression. Here, we constructed a homing suppression drive in Drosophila melanogaster that utilized multiplexed gRNAs to inhibit the formation of functional resistance alleles in its female fertility target gene. The selected gRNA target sites were close together, preventing reduction in drive conversion efficiency. The construct reached a moderate equilibrium frequency in cage populations without apparent formation of resistance alleles. However, a moderate fitness cost prevented elimination of the cage population, showing the importance of using highly efficient drives in a suppression strategy, even if resistance can be addressed. Nevertheless, our results experimentally demonstrate the viability of the multiplexed gRNAs strategy in homing suppression gene drives., (© The Author(s) 2022. Published by Oxford University Press on behalf of Genetics Society of America.)

Published

2022

37. Experimental demonstration of tethered gene drive systems for confined population modification or suppression.

Author

Metzloff M, Yang E, Dhole S, Clark AG, Messer PW, and Champer J

Subjects

Animals, CRISPR-Cas Systems, Clustered Regularly Interspaced Short Palindromic Repeats, Drosophila genetics, Gene Drive Technology methods

Abstract

Background: Homing gene drives hold great promise for the genetic control of natural populations. However, current homing systems are capable of spreading uncontrollably between populations connected by even marginal levels of migration. This could represent a substantial sociopolitical barrier to the testing or deployment of such drives and may generally be undesirable when the objective is only local population control, such as suppression of an invasive species outside of its native range. Tethered drive systems, in which a locally confined gene drive provides the CRISPR nuclease needed for a homing drive, could provide a solution to this problem, offering the power of a homing drive and confinement of the supporting drive., Results: Here, we demonstrate the engineering of a tethered drive system in Drosophila, using a regionally confined CRISPR Toxin-Antidote Recessive Embryo (TARE) drive to support modification and suppression homing drives. Each drive was able to bias inheritance in its favor, and the TARE drive was shown to spread only when released above a threshold frequency in experimental cage populations. After the TARE drive had established in the population, it facilitated the spread of a subsequently released split homing modification drive (to all individuals in the cage) and of a homing suppression drive (to its equilibrium frequency)., Conclusions: Our results show that the tethered drive strategy is a viable and easily engineered option for providing confinement of homing drives to target populations., (© 2022. The Author(s).)

Published

2022

38. Modelling homing suppression gene drive in haplodiploid organisms.

Author

Liu Y and Champer J

Subjects

Alleles, CRISPR-Cas Systems, Female, Germ Cells, Humans, Male, RNA, Guide, CRISPR-Cas Systems genetics, Gene Drive Technology methods

Abstract

Gene drives have shown great promise for suppression of pest populations. These engineered alleles can function by a variety of mechanisms, but the most common is the CRISPR homing drive, which converts wild-type alleles to drive alleles in the germline of heterozygotes. Some potential target species are haplodiploid, in which males develop from unfertilized eggs and thus have only one copy of each chromosome. This prevents drive conversion, a substantial disadvantage compared to diploids where drive conversion can take place in both sexes. Here, we study homing suppression gene drives in haplodiploids and find that a drive targeting a female fertility gene could still be successful. However, such drives are less powerful than in diploids and suffer more from functional resistance alleles. They are substantially more vulnerable to high resistance allele formation in the embryo owing to maternally deposited Cas9 and guide RNA and also to somatic cleavage activity. Examining spatial models where organisms move over a continuous landscape, we find that haplodiploid suppression drives surprisingly perform nearly as well as in diploids, possibly owing to their ability to spread further before inducing strong suppression. Together, these results indicate that gene drive can potentially be used to effectively suppress haplodiploid populations.

Published

2022

39. Modeling CRISPR gene drives for suppression of invasive rodents using a supervised machine learning framework.

Author

Champer SE, Oakes N, Sharma R, García-Díaz P, Champer J, and Messer PW

Subjects

Animals, Biodiversity, Female, Introduced Species, Male, Population Control, Population Dynamics, Rats, Clustered Regularly Interspaced Short Palindromic Repeats genetics, Gene Drive Technology methods, Models, Genetic, Pest Control, Biological methods, Supervised Machine Learning

Abstract

Invasive rodent populations pose a threat to biodiversity across the globe. When confronted with these invaders, native species that evolved independently are often defenseless. CRISPR gene drive systems could provide a solution to this problem by spreading transgenes among invaders that induce population collapse, and could be deployed even where traditional control methods are impractical or prohibitively expensive. Here, we develop a high-fidelity model of an island population of invasive rodents that includes three types of suppression gene drive systems. The individual-based model is spatially explicit, allows for overlapping generations and a fluctuating population size, and includes variables for drive fitness, efficiency, resistance allele formation rate, as well as a variety of ecological parameters. The computational burden of evaluating a model with such a high number of parameters presents a substantial barrier to a comprehensive understanding of its outcome space. We therefore accompany our population model with a meta-model that utilizes supervised machine learning to approximate the outcome space of the underlying model with a high degree of accuracy. This enables us to conduct an exhaustive inquiry of the population model, including variance-based sensitivity analyses using tens of millions of evaluations. Our results suggest that sufficiently capable gene drive systems have the potential to eliminate island populations of rodents under a wide range of demographic assumptions, though only if resistance can be kept to a minimal level. This study highlights the power of supervised machine learning to identify the key parameters and processes that determine the population dynamics of a complex evolutionary system., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

40. Suppression gene drive in continuous space can result in unstable persistence of both drive and wild-type alleles.

Author

Champer J, Kim IK, Champer SE, Clark AG, and Messer PW

Subjects

Alleles, Disease Vectors, Humans, Models, Genetic, Population Dynamics, Gene Drive Technology

Abstract

Rapid evolutionary processes can produce drastically different outcomes when studied in panmictic population models vs. spatial models. One such process is gene drive, which describes the spread of "selfish" genetic elements through a population. Engineered gene drives are being considered for the suppression of disease vectors or invasive species. While laboratory experiments and modelling in panmictic populations have shown that such drives can rapidly eliminate a population, it remains unclear if these results translate to natural environments where individuals inhabit a continuous landscape. Using spatially explicit simulations, we show that the release of a suppression drive can result in what we term "chasing" dynamics, in which wild-type individuals recolonize areas where the drive has locally eliminated the population. Despite the drive subsequently reconquering these areas, complete population suppression often fails to occur or is substantially delayed. This increases the likelihood that the drive is lost or that resistance evolves. We analyse how chasing dynamics are influenced by the type of drive, its efficiency, fitness costs, and ecological factors such as the maximal growth rate of the population and levels of dispersal and inbreeding. We find that chasing is more common for lower efficiency drives when dispersal is low and that some drive mechanisms are substantially more prone to chasing behaviour than others. Our results demonstrate that the population dynamics of suppression gene drives are determined by a complex interplay of genetic and ecological factors, highlighting the need for realistic spatial modelling to predict the outcome of drive releases in natural populations., (© 2021 John Wiley & Sons Ltd.)

Published

2021

41. Design and analysis of CRISPR-based underdominance toxin-antidote gene drives.

Author

Champer J, Champer SE, Kim IK, Clark AG, and Messer PW

Abstract

CRISPR gene drive systems offer a mechanism for transmitting a desirable transgene throughout a population for purposes ranging from vector-borne disease control to invasive species suppression. In this simulation study, we assess the performance of several CRISPR-based underdominance gene drive constructs employing toxin-antidote (TA) principles. These drives disrupt the wild-type version of an essential gene using a CRISPR nuclease (the toxin) while simultaneously carrying a recoded version of the gene (the antidote). Drives of this nature allow for releases that could be potentially confined to a desired geographic location. This is because such drives have a nonzero-invasion threshold frequency required for the drive to spread through the population. We model drives which target essential genes that are either haplosufficient or haplolethal, using nuclease promoters with expression restricted to the germline, promoters that additionally result in cleavage activity in the early embryo from maternal deposition, and promoters that have ubiquitous somatic expression. We also study several possible drive architectures, considering both "same-site" and "distant-site" systems, as well as several reciprocally targeting drives. Together, these drive variants provide a wide range of invasion threshold frequencies and options for both population modification and suppression. Our results suggest that CRISPR TA underdominance drive systems could allow for the design of flexible and potentially confinable gene drive strategies., Competing Interests: The authors declare that they have no conflict of interest., (© 2020 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published

2020

42. Core commitments for field trials of gene drive organisms.

Author

Long KC, Alphey L, Annas GJ, Bloss CS, Campbell KJ, Champer J, Chen CH, Choudhary A, Church GM, Collins JP, Cooper KL, Delborne JA, Edwards OR, Emerson CI, Esvelt K, Evans SW, Friedman RM, Gantz VM, Gould F, Hartley S, Heitman E, Hemingway J, Kanuka H, Kuzma J, Lavery JV, Lee Y, Lorenzen M, Lunshof JE, Marshall JM, Messer PW, Montell C, Oye KA, Palmer MJ, Papathanos PA, Paradkar PN, Piaggio AJ, Rasgon JL, Rašić G, Rudenko L, Saah JR, Scott MJ, Sutton JT, Vorsino AE, and Akbari OS

Subjects

Animals, Guidelines as Topic, Gene Drive Technology standards, Organisms, Genetically Modified, Safety

Published

2020

43. A CRISPR homing gene drive targeting a haplolethal gene removes resistance alleles and successfully spreads through a cage population.

Author

Champer J, Yang E, Lee E, Liu J, Clark AG, and Messer PW

Subjects

Alleles, Animals, CRISPR-Cas Systems, Drosophila melanogaster physiology, Female, Gene Editing, Germ Cells cytology, Male, Models, Genetic, Pedigree, RNA, Guide, CRISPR-Cas Systems genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics

Abstract

Engineered gene drives are being explored as a new strategy in the fight against vector-borne diseases due to their potential for rapidly spreading genetic modifications through a population. However, CRISPR-based homing gene drives proposed for this purpose have faced a major obstacle in the formation of resistance alleles that prevent Cas9 cleavage. Here, we present a homing drive in Drosophila melanogaster that reduces the prevalence of resistance alleles below detectable levels by targeting a haplolethal gene with two guide RNAs (gRNAs) while also providing a rescue allele. Resistance alleles that form by end-joining repair typically disrupt the haplolethal target gene and are thus removed from the population because individuals that carry them are nonviable. We demonstrate that our drive is highly efficient, with 91% of the progeny of drive heterozygotes inheriting the drive allele and with no functional resistance alleles observed in the remainder. In a large cage experiment, the drive allele successfully spread to all individuals within a few generations. These results show that a haplolethal homing drive can provide an effective tool for targeted genetic modification of entire populations., Competing Interests: The authors declare no competing interest.

Published

2020

44. Population Dynamics of Underdominance Gene Drive Systems in Continuous Space.

Author

Champer J, Zhao J, Champer SE, Liu J, and Messer PW

Subjects

Genetics, Population, Models, Genetic, Population Dynamics, Gene Drive Technology

Abstract

Underdominance systems can quickly spread through a population, but only when introduced in considerable numbers. This promises a gene drive mechanism that is less invasive than homing drives, potentially enabling new approaches in the fight against vector-borne diseases. If regional confinement can indeed be achieved, the decision-making process for a release would likely be much simpler compared to other, more invasive types of drives. The capacity of underdominance gene drive systems to spread in a target population without invading other populations is typically assessed via network models of panmictic demes linked by migration. However, it remains less clear how such systems would behave in more realistic population models where organisms move over a continuous landscape. Here, we use individual-based simulations to study the dynamics of several proposed underdominance systems in continuous-space. We find that all these systems can fail to persist in such environments, even after an initially successful establishment in the release area, confirming previous theoretical results from diffusion theory. At the same time, we find that a two-locus two-toxin-antidote system can invade connected demes through a narrow migration corridor. This suggests that the parameter space where underdominance systems can establish and persist in a release area while at the same time remaining confined to that area could be quite limited, depending on how a population is spatially structured. Overall, these results indicate that realistic spatial context must be considered when assessing strategies for the deployment of underdominance drives.

Published

2020

45. Performance analysis of novel toxin-antidote CRISPR gene drive systems.

Author

Champer J, Kim IK, Champer SE, Clark AG, and Messer PW

Subjects

Genes, Essential, Haploinsufficiency, Models, Genetic, Antidotes pharmacology, Antitoxins pharmacology, CRISPR-Cas Systems, Gene Drive Technology methods

Abstract

Background: CRISPR gene drive systems allow the rapid spread of a genetic construct throughout a population. Such systems promise novel strategies for the management of vector-borne diseases and invasive species by suppressing a target population or modifying it with a desired trait. However, current homing-type drives have two potential shortcomings. First, they can be thwarted by the rapid evolution of resistance. Second, they lack any mechanism for confinement to a specific target population. In this study, we conduct a comprehensive performance assessment of several new types of CRISPR-based gene drive systems employing toxin-antidote (TA) principles, which should be less prone to resistance and allow for the confinement of drives to a target population due to invasion frequency thresholds., Results: The underlying principle of the proposed CRISPR toxin-antidote gene drives is to disrupt an essential target gene while also providing rescue by a recoded version of the target as part of the drive allele. Thus, drive alleles tend to remain viable, while wild-type targets are disrupted and often rendered nonviable, thereby increasing the relative frequency of the drive allele. Using individual-based simulations, we show that Toxin-Antidote Recessive Embryo (TARE) drives targeting an haplosufficient but essential gene (lethal when both copies are disrupted) can enable the design of robust, regionally confined population modification strategies with high flexibility in choosing promoters and targets. Toxin-Antidote Dominant Embryo (TADE) drives require a haplolethal target gene and a germline-restricted promoter, but they could permit faster regional population modification and even regionally confined population suppression. Toxin-Antidote Dominant Sperm (TADS) drives can be used for population modification or suppression. These drives are expected to spread rapidly and could employ a variety of promoters, but unlike TARE and TADE, they would not be regionally confined and also require highly specific target genes., Conclusions: Overall, our results suggest that CRISPR-based TA gene drives provide promising candidates for flexible ecological engineering strategies in a variety of organisms.

Published

2020

46. Computational and experimental performance of CRISPR homing gene drive strategies with multiplexed gRNAs.

Author

Champer SE, Oh SY, Liu C, Wen Z, Clark AG, Messer PW, and Champer J

Subjects

Alleles, Animals, Anopheles metabolism, CRISPR-Associated Protein 9 metabolism, Clustered Regularly Interspaced Short Palindromic Repeats, Drosophila melanogaster metabolism, Female, Gene Editing methods, Male, Models, Genetic, RNA, Guide, CRISPR-Cas Systems metabolism, Anopheles genetics, CRISPR-Associated Protein 9 genetics, CRISPR-Cas Systems, Drosophila melanogaster genetics, Gene Drive Technology methods, RNA, Guide, CRISPR-Cas Systems genetics

Abstract

The rapid evolution of resistance alleles poses a major obstacle for genetic manipulation of populations with CRISPR homing gene drives. One proposed solution is using multiple guide RNAs (gRNAs), allowing a drive to function even if some resistant target sites are present. Here, we develop a model of homing mechanisms parameterized by experimental studies. Our model incorporates several factors affecting drives with multiple gRNAs, including timing of cleavage, reduction in homology-directed repair efficiency due to imperfect homology, Cas9 activity saturation, gRNA activity level variance, and incomplete homology-directed repair. We find that homing drives have an optimal number of gRNAs, usually between two and eight, depending on the specific drive type and performance parameters. These results contradict the notion that resistance rates can be reduced to arbitrarily low levels by gRNA multiplexing and highlight the need for combined approaches to counter resistance evolution in CRISPR homing drives., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2020

47. A toxin-antidote CRISPR gene drive system for regional population modification.

Author

Champer J, Lee E, Yang E, Liu C, Clark AG, and Messer PW

Subjects

Animals, Animals, Genetically Modified, CRISPR-Cas Systems genetics, Drosophila genetics, Female, Genetics, Population, Heterozygote, Mutation, Antidotes, Drosophila Proteins genetics, Gene Drive Technology methods, Models, Genetic, Protein Engineering methods

Abstract

Engineered gene drives based on a homing mechanism could rapidly spread genetic alterations through a population. However, such drives face a major obstacle in the form of resistance against the drive. In addition, they are expected to be highly invasive. Here, we introduce the Toxin-Antidote Recessive Embryo (TARE) drive. It functions by disrupting a target gene, forming recessive lethal alleles, while rescuing drive-carrying individuals with a recoded version of the target. Modeling shows that such drives will have threshold-dependent invasion dynamics, spreading only when introduced above a fitness-dependent frequency. We demonstrate a TARE drive in Drosophila with 88-95% transmission by female heterozygotes. This drive was able to spread through a large cage population in just six generations following introduction at 24% frequency without any apparent evolution of resistance. Our results suggest that TARE drives constitute promising candidates for the development of effective, flexible, and regionally confinable drives for population modification.

Published

2020

48. CRISPR Gene Drive Efficiency and Resistance Rate Is Highly Heritable with No Common Genetic Loci of Large Effect.

Author

Champer J, Wen Z, Luthra A, Reeves R, Chung J, Liu C, Lee YL, Liu J, Yang E, Messer PW, and Clark AG

Subjects

Animals, CRISPR-Cas Systems, Clustered Regularly Interspaced Short Palindromic Repeats, Crosses, Genetic, Female, Genome-Wide Association Study, Male, Drosophila melanogaster genetics, Gene Drive Technology methods, Genetic Loci, Genetic Predisposition to Disease, Genetic Variation

Abstract

Gene drives could allow for control of vector-borne diseases by directly suppressing vector populations or spreading genetic payloads designed to reduce pathogen transmission. Clustered regularly interspaced short palindromic repeat (CRISPR) homing gene drives work by cleaving wild-type alleles, which are then converted to drive alleles by homology-directed repair, increasing the frequency of the drive in a population over time. However, resistance alleles can form when end-joining repair takes place in lieu of homology-directed repair. Such alleles cannot be converted to drive alleles, which would eventually halt the spread of a drive through a population. To investigate the effects of natural genetic variation on resistance formation, we developed a CRISPR homing gene drive in Drosophila melanogaster and crossed it into the genetically diverse Drosophila Genetic Reference Panel (DGRP) lines, measuring several performance parameters. Most strikingly, resistance allele formation postfertilization in the early embryo ranged from 7 to 79% among lines and averaged 42 ± 18%. We performed a genome-wide association study using our results in the DGRP lines, and found that the resistance and conversion rates were not explained by common alleles of large effect, but instead there were several genetic polymorphisms showing weak association. RNA interference knockdown of several genes containing these polymorphisms confirmed their effect, but the small effect sizes imply that their manipulation would likely yield only modest improvements to the efficacy of gene drives., (Copyright © 2019 by the Genetics Society of America.)

Published

2019

49. Maximum Likelihood Estimation of Fitness Components in Experimental Evolution.

Author

Liu J, Champer J, Langmüller AM, Liu C, Chung J, Reeves R, Luthra A, Lee YL, Vaughn AH, Clark AG, and Messer PW

Subjects

Animals, Drosophila Proteins genetics, Drosophila melanogaster, Female, Gene Frequency, Likelihood Functions, Loss of Function Mutation, Male, Selection, Genetic, Evolution, Molecular, Genetic Fitness, Models, Genetic

Abstract

Estimating fitness differences between allelic variants is a central goal of experimental evolution. Current methods for inferring such differences from allele frequency time series typically assume that the effects of selection can be described by a fixed selection coefficient. However, fitness is an aggregate of several components including mating success, fecundity, and viability. Distinguishing between these components could be critical in many scenarios. Here, we develop a flexible maximum likelihood framework that can disentangle different components of fitness from genotype frequency data, and estimate them individually in males and females. As a proof-of-principle, we apply our method to experimentally evolved cage populations of Drosophila melanogaster , in which we tracked the relative frequencies of a loss-of-function and wild-type allele of yellow This X-linked gene produces a recessive yellow phenotype when disrupted and is involved in male courtship ability. We find that the fitness costs of the yellow phenotype take the form of substantially reduced mating preference of wild-type females for yellow males, together with a modest reduction in the viability of yellow males and females. Our framework should be generally applicable to situations where it is important to quantify fitness components of specific genetic variants, including quantitative characterization of the population dynamics of CRISPR gene drives., (Copyright © 2019 by the Genetics Society of America.)

Published

2019

50. Molecular safeguarding of CRISPR gene drive experiments.

Author

Champer J, Chung J, Lee YL, Liu C, Yang E, Wen Z, Clark AG, and Messer PW

Subjects

Animals, Animals, Genetically Modified, Clustered Regularly Interspaced Short Palindromic Repeats genetics, Gene Editing methods, Genetics, Population, Genotype, Germ Cells, Phenotype, RNA, Guide, CRISPR-Cas Systems metabolism, CRISPR-Cas Systems genetics, Drosophila melanogaster genetics, Gene Drive Technology methods, RNA, Guide, CRISPR-Cas Systems genetics

Abstract

CRISPR-based homing gene drives have sparked both enthusiasm and deep concerns due to their potential for genetically altering entire species. This raises the question about our ability to prevent the unintended spread of such drives from the laboratory into a natural population. Here, we experimentally demonstrate the suitability of synthetic target site drives as well as split drives as flexible safeguarding strategies for gene drive experiments by showing that their performance closely resembles that of standard homing drives in Drosophila melanogaster . Using our split drive system, we further find that maternal deposition of both Cas9 and gRNA is required to form resistance alleles in the early embryo and that maternally-deposited Cas9 alone can power germline drive conversion in individuals that lack a genomic source of Cas9., Competing Interests: JC, JC, YL, CL, EY, ZW, AC, PM No competing interests declared, (© 2019, Champer et al.)

Published

2019