One-step efficient generation of dual-function conditional knockout and geno-tagging alleles in zebrafish

Li, Wenyuan; Zhang, Yage; Han, Bingzhou; Li, Lianyan; Li, Muhang; Lu, Xiaochan; Chen, Cheng; Lu, Mengjia; Zhang, Yujie; Jia, Xuefeng; Zhu, Zuoyan; Tong, Xiangjun; Zhang, Bo

doi:10.7554/elife.48081

Cited by 41 publications

(64 citation statements)

References 55 publications

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“…The other is that we pre-selected fluorescence-positive founder (F 0 ) embryos after injection of the targeting system and before rearing for germline transmission screening. The importance of pre-selection for the enrichment of F 0 embryos bearing correct insertions has been demonstrated in our previous publication (Li et al, 2019) One of the major improvements of our Bi-FoRe strategy is the successful utilization of insertions occurring in both directions, due to the special design of our donor vector. Bidirectional KI enables concurrent generation of positive and negative alleles, allowing for in vivo monitoring of gene expression and conditional manipulation of gene function.…”

Section: Discussionmentioning

confidence: 94%

“…Based on these allele pairs, we successfully achieved conditional knockout and conditional rescue in parallel, both coupled with switch of fluorescent reporter genes, from positive and negative conditional alleles at the sox10 locus, respectively. Similar to other organisms, KI in zebrafish could be achieved by either homology-dependent or -independent approaches (Zu et al, 2013;Auer et al, 2014;Shin et al, 2014;Li et al, 2015;Hoshijima et al, 2016;Sugimoto et al, 2017;Burg et al, 2018;Luo et al, 2018;Li et al, 2019;Li et al, 2020). Inclusion of homology arms in the donor allows for precise integration of the donor through HR, while dramatically compromising the KI efficiency.…”

Section: Discussionmentioning

confidence: 99%

“…Complex genome modification techniques utilizing site-specific knockin (KI) to achieve gene expression labeling by protein tags or gene inactivation or reactivation via Cre/ loxP system have advanced remarkably since the emergence of engineered endonucleases such as TALENs and the CRISPR/Cas system (Zu et al, 2013 ; Auer et al, 2014 ; Shin et al, 2014 ; Li et al, 2015 ; Hoshijima et al, 2016 ; Sugimoto et al, 2017 ; Burg et al, 2018 ; Luo et al, 2018 ; Li et al, 2019 , 2020 ). These technical developments are particularly important in organisms lacking embryonic stem cell-based approaches, including zebrafish ( Danio rerio ).…”

Section: Introductionmentioning

confidence: 99%

“…Li et al reported a fluorescent gene-tagging method which introduced a fluorescent reporter into the last intron via nonhomologous end joining (NHEJ)-mediated targeted insertion in zebrafish using the CRISPR/Cas system (Li et al, 2015 ), taking advantage of its higher KI efficiency than homologous recombination (HR) (Auer et al, 2014 ). Recently, we and others further improved the technique and established “two-in-one” dual-function KI strategies to achieve conditional knockout (CKO) coupled with in-frame fusion of double fluorescent reporters to label two different alleles (positive/normal vs. negative/defective), facilitated by specially designs of dual-cassette donors (Li et al, 2019 , 2020 ). However, generation of conditional rescue alleles through these new approaches has not been reported, and a method for simultaneously generating CKO and conditional rescue allele pairs is also not available.…”

Section: Introductionmentioning

confidence: 99%

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Bi-FoRe: an efficient bidirectional knockin strategy to generate pairwise conditional alleles with fluorescent indicators

Han

Zhang

et al. 2020

Protein Cell

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Gene expression labeling and conditional manipulation of gene function are important for elaborate dissection of gene function. However, contemporary generation of pairwise dual-function knockin alleles to achieve both conditional and geno-tagging effects with a single donor has not been reported. Here we first developed a strategy based on a flipping donor named FoRe to generate conditional knockout alleles coupled with fluorescent allele-labeling through NHEJ-mediated unidirectional targeted insertion in zebrafish facilitated by the CRISPR/ Cas system. We demonstrated the feasibility of this strategy at sox10 and isl1 loci, and successfully achieved Cre-induced conditional knockout of target gene function and simultaneous switch of the fluorescent reporter, allowing generation of genetic mosaics for lineage tracing. We then improved the donor design enabling efficient one-step bidirectional knockin to generate paired positive and negative conditional alleles, both tagged with two different fluorescent reporters. By introducing Cre recombinase, these alleles could be used to achieve both conditional knockout and conditional gene restoration in parallel; furthermore, differential fluorescent labeling of the positive and negative alleles enables simple, early and efficient realtime discrimination of individual live embryos bearing different genotypes prior to the emergence of morphologically visible phenotypes. We named our improved donor as Bi-FoRe and demonstrated its feasibility at the sox10 locus. Furthermore, we eliminated the undesirable bacterial backbone in the donor using minicircle DNA technology. Our system could easily be expanded for other applications or to other organisms, and coupling fluorescent labeling of gene expression and conditional manipulation of gene function will provide unique opportunities to fully reveal the power of emerging single-cell sequencing technologies.

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Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Bi-FoRe: an efficient bidirectional knockin strategy to generate pairwise conditional alleles with fluorescent indicators

Han

Zhang

et al. 2020

Protein Cell

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“…[17] Since zebra sh has regeneration capability in its organs such as ns, central nervous system (CNS), heart, pancreas, liver, and kidney, it has been used for different models of injury for example in cardiovascular, neurological, and metabolic diseases. [18][19][20] The technology of transgenic and genome editing is mature and e cient in zebra sh, which made zebra sh as a common model for genetic screen and disease models. [21][22][23] Moreover, the zebra sh embryos are transparent and develop externally, a variety of imaging modalities were applicable to live image of embryogenesis and disease occurrence.…”

Section: Introductionmentioning

confidence: 99%

Scanning Various Nanomaterials and Variable Camouflages to Evaluate the Biocompatibility in Multi-organs of Embryos

Zheng¹,

Guo²,

Pang³

et al. 2020

Preprint

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Background:Nanomaterials are under a wide range of application prospects in human health and disease, such as medical imaging and drug delivery and treatment. With the gradual advent of the nano era, the safety of nanomaterials in biology must be evaluated more widely and deeply. Therefore, superficial safety assessment based on specific cell lines in vitro is difficult to meet the current needs. Multi-organs assessment in vivo will be beneficial in establishing a more comprehensive pathway for the understanding of nanomaterials-induced biotoxicity. Results:In this work, we employed a series of genetically modified zebrafish models for nanomaterials toxicity assessment. The results demonstrated that cadmium selenide (CdSe) quantum dot (QDs) was the most toxic after scanning some popular nanomaterials. Among modified methods of silica coating, core-shell structure development and organic molecular camouflage, the polyethylene glycol camouflage method exhibits a better performance of improving the biocompatibility of CdSe QDs in multiple-organs including hearts, nerves, blood vessels, and immune system. Conclusion:Our work provides an alternative paradigm for more in-depth and sensitive preclinical validation of biocompatibility, especially in neurotoxicity and cardiotoxicity of embryos, and a guidance for reducing the toxicity of biomedical materials.

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Genome editing pig models with elements for controllable gene expression

Jin,

Shi,

Liu

et al. 2023

Animal Research and One Health

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Conditional gene regulation systems can control gene expression in predefined tissues or organs at a desired time. Site‐specific recombinase systems and chemically induced gene expression systems are the two most widely used approaches for creating genetically modified (GM) animals with conditional regulation of gene expression. Generation of GM pigs with controllable elements, usually involving multiple gene editing, used to be a major challenge due to a lack of germ line‐competent pluripotent stem cells. With the emergence of artificial endonuclease‐mediated gene editors, a variety of GM pigs with recombinase‐specific recognition elements or chemically induced elements for conditional regulation of gene expression have been generated by the combination of site‐directed knock‐in of somatic cells and somatic cell nuclear transfer technology, allowing conditional deletion of endogenous genes or overexpression of exogenous genes in pigs. These inducible tool pig models will greatly facilitate the production of GM pigs and broaden the applications of transgenic pigs in biomedicine and agriculture fields. In this paper, we review the progress in the construction and application of pigs with controllable elements using gene editing techniques.

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One-step efficient generation of dual-function conditional knockout and geno-tagging alleles in zebrafish

Cited by 41 publications

References 55 publications

Bi-FoRe: an efficient bidirectional knockin strategy to generate pairwise conditional alleles with fluorescent indicators

Bi-FoRe: an efficient bidirectional knockin strategy to generate pairwise conditional alleles with fluorescent indicators

Scanning Various Nanomaterials and Variable Camouflages to Evaluate the Biocompatibility in Multi-organs of Embryos

Genome editing pig models with elements for controllable gene expression

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