Single nucleotide editing without DNA cleavage using CRISPR/Cas9‐deaminase in the sea urchin embryo

Shevidi, Saba; Uchida, Alicia; Schudrowitz, Natalie; Wessel, Gary M.; Yajima, Mamiko

doi:10.1002/dvdy.24586

Cited by 25 publications

(20 citation statements)

References 42 publications

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“…These results further suggest the specificity of Rb1‐MO as well as the functionality of Rb1‐GFP mRNA in the embryo. The genome editing technology (e.g., CRISPR/Cas9 system) was not used in this study as a knockdown approach because of the maternal load of Rb1 mRNA during early embryogenesis of the sea urchin . This alternative approach will be, however, important to test these Rb1‐knockdown phenotypes in the larval stage in the future.…”

Section: Resultsmentioning

confidence: 99%

A tumor suppressor Retinoblastoma1 is essential for embryonic development in the sea urchin

Fernández-Nicolas

Yajima

2019

Developmental Dynamics

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Background Embryonic cells and cancer cells share various cellular characteristics important for their functions. It has been thus proposed that similar mechanisms of regulation may be present in these otherwise disparate cell types. Results To explore how regulative embryonic cells are fundamentally different from cancerous cells, we report here that a fine balance of a tumor suppressor protein Retinoblastoma1 (Rb1) and a germline factor Vasa are important for proper cell proliferation and differentiation of the somatic cells during embryogenesis of the sea urchin. Rb1 knockdown blocked embryonic development and induced Vasa accumulation in the entire embryo, while its overexpression resulted in a smaller‐sized embryo with differentiated body structures. These results suggest that a titrated level of Rb1 protein may be essential for a proper balance of cell proliferation and differentiation during development. Vasa knockdown or overexpression, on the other hand, reduced or increased Rb1 protein expression, respectively. Conclusions Taken together, it appears that Vasa protein positively regulates Rb1 protein while Rb1 protein negatively regulates Vasa protein, balancing the act of these two antagonistic molecules in somatic cells. This mechanism may provide a fine control of cell proliferation and differentiation, which is essential for regulative embryonic development.

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Section: Resultsmentioning

confidence: 99%

A tumor suppressor Retinoblastoma1 is essential for embryonic development in the sea urchin

Fernández-Nicolas

Yajima

2019

Developmental Dynamics

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“…The preceding study using S. purpuratus introduced a combination of three sgRNAs targeting the Pks1 gene and resulted in efficient mutagenesis and larval albino phenotype, but only a slight portion of embryos showed pigmentation (Oulhen & Wessel, 2016). A similar albino phenotype was reported using CRISPR-Cas9 and CRISPR-Cas9-deaminase by introduction of mixture of 16 sgRNAs targeting the Pks1 gene, but the efficiency was not so high (Shevidi, Uchida, Schudrowitz, Wessel, & Yajima, 2017). Whereas, in our study, we introduced single sgRNA, and the introduction of sgRNA#2 achieved 100% of mutagenesis efficiency and all injected embryos showed the complete loss of pigmentation.…”

Section: Discussionmentioning

confidence: 68%

Establishment of knockout adult sea urchins by using a CRISPR‐Cas9 system

et al. 2019

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Sea urchins are used as a model organism for research on developmental biology and gene regulatory networks during early development. Gene knockdown by microinjection of morpholino antisense oligonucleotide (MASO) has been used to analyze gene function in early sea urchin embryos. However, as the effect of MASO is not long lasting, it is impossible to perturb genes expressed during late development by MASO. Recent advances in genome editing technologies have enabled gene modification in various organisms. We previously reported genome editing in the sea urchin Hemicentrotus pulcherrimus using zinc‐finger nuclease (ZFN) and transcription activator‐like effector nuclease (TALEN); however, the efficiencies of these technologies were not satisfactory. Here, we applied clustered regularly interspaced short palindromic repeat (CRISPR)‐CRISPR‐associated nuclease 9 (Cas9) technology to knock out the Pks1 gene in H. pulcherrimus. When sgRNAs targeting Pks1, which is required for the biosynthesis of larval pigment, were microinjected into fertilized eggs with SpCas9 mRNA, high‐efficiency mutagenesis was achieved within 24 hr post fertilization and SpCas9/sgRNA‐injected pluteus larvae had an albino phenotype. One of the sgRNAs yielded 100% mutagenesis efficiency, and no off‐target effect was detected. In addition, the albino phenotype was maintained in juvenile sea urchins after metamorphosis, and the knockout sea urchins survived for at least one year and grew to albino adult sea urchins. These findings suggest that knockout adult sea urchins were successfully established and the CRISPR‐Cas9 system is a feasible method for analyzing gene functions from late developmental to adult stage.

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“…Note that deaminase catalyzes single‐strand DNA; therefore, deaminase fused with ZF or TALE was likely to show less activity compared to that fused with dCas9 or Cas9n . The applicability of base editing systems has been initially proven in yeasts and mammalian cells, followed by various organisms including plants, mice, sea urchins, and bacteria . The high specificity of the system was confirmed by genome‐wide assessment .…”

Section: A Closer Look At Front‐line Technologiesmentioning

confidence: 99%

Acceleration of cancer science with genome editing and related technologies

Sakuma

Yamamoto

2018

Cancer Science

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Genome editing includes various edits of the genome, such as short insertions and deletions, substitutions, and chromosomal rearrangements including inversions, duplications, and translocations. These variations are based on single or multiple DNA double‐strand break (DSB)‐triggered in cellulo repair machineries. In addition to these “conventional” genome editing strategies, tools enabling customized, site‐specific recognition of particular nucleic acid sequences have been coming into wider use; for example, single base editing without DSB introduction, epigenome editing with recruitment of epigenetic modifiers, transcriptome engineering using RNA editing systems, and in vitro detection of specific DNA and RNA sequences. In this review, we provide a quick overview of the current state of genome editing and related technologies that multilaterally contribute to cancer science.

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Single nucleotide editing without DNA cleavage using CRISPR/Cas9‐deaminase in the sea urchin embryo

Cited by 25 publications

References 42 publications

A tumor suppressor Retinoblastoma1 is essential for embryonic development in the sea urchin

A tumor suppressor Retinoblastoma1 is essential for embryonic development in the sea urchin

Establishment of knockout adult sea urchins by using a CRISPR‐Cas9 system

Acceleration of cancer science with genome editing and related technologies

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