Genome editing reagent delivery in plants

Transgenic Research - Genome editing holds the potential for rapid crop improvement to meet the challenge of feeding the planet in a changing climate. The delivery of gene editing reagents into the...     

New cytosine base editor for plant genome editing

正A large number of beneficial agronomic traits in crops are associated with single nucleotide polymorphisms (SNPs) or point mutations (Jiao et al., 2010; Li et al., 2017; Ma et al.,2015). In the past, site-specific point mutations in a target gene can only be achieved through the CRISPR/Cas9-mediated gene replacement via the homology-directed repair(HDR). However, the intrinsically low HDR activity in plant cells and the lack of efficient way to supply abundant HDR templates in plant nucleus have greatly limited the success     

Designing future farmed fishes using genome editing

<正>Aquaculture, the most rapidly growing food production sector, has exhibited tremendous expansion over the past several decades and it currently accounts for more than half of the global fish production for human consumption. To ensure sustainable aquaculture, it is necessary to breed farmed fish species (strains) with valuable economic traits,such as high production, high quality, disease resistance, and stress tolerance. Modern fish genetic breeding techniques     

Targeted genome editing of plants and plant cells for biomanufacturing

Plants have provided humans with useful products since antiquity, but in the last 30 years they have also been developed as production platforms for small molecules and recombinant proteins. This initially niche area has blossomed with the growth of the global bioeconomy, and now includes chemical building blocks, polymers and renewable energy. All these applications can be described as “plant molecular farming” (PMF). Despite its potential to increase the sustainability of biologics manufacturing, PMF has yet to be embraced broadly by industry. This reflects a combination of regulatory uncertainty, limited information on process cost structures, and the absence of trained staff and suitable manufacturing capacity. However, the limited adaptation of plants and plant cells to the requirements of industry-scale manufacturing is an equally important hurdle. For example, the targeted genetic manipulation of yeast has been common practice since the 1980s, whereas reliable site-directed mutagenesis in most plants has only become available with the advent of CRISPR/Cas9 and similar genome editing technologies since around 2010. Here we summarize the applications of new genetic engineering technologies to improve plants as biomanufacturing platforms. We start by identifying current bottlenecks in manufacturing, then illustrate the progress that has already been made and discuss the potential for improvement at the molecular, cellular and organism levels. We discuss the effects of metabolic optimization, adaptation of the endomembrane system, modified glycosylation profiles, programmable growth and senescence, protease inactivation, and the expression of enzymes that promote biodegradation. We outline strategies to achieve these modifications by targeted gene modification, considering case-by-case examples of individual improvements and the combined modifications needed to generate a new general-purpose “chassis” for PMF.

     

A removable virus vector suitable for plant genome editing

Plant genome editing is achieved by the expression of sequence‐specific nucleases (SSNs). RNA virus vector‐mediated expression of SSNs is a promising approach for transgene integration‐free targeted mutagenesis in plants. However, the removal of virus vectors from infected plants is challenging because no antiviral drugs are available against plant viruses. Here, we developed a removable RNA virus vector that carries the target site of tobacco microRNA398 (miR398) whose expression is induced during shoot regeneration. In the inoculated leaves in which expression of miR398 is not induced, insertion of the miR398 target site did not affect the practicability of the virus vector. When shoots were regenerated from the infected leaves, miR398 was expressed and viral RNA was eliminated. The virus vector successfully expressed SSNs in inoculated leaves, from which virus‐free genome‐edited plants were regenerated via tissue culture.     

Precision plant breeding using genome editing technologies

Transgenic Research -     

Expanding the plant genome editing toolbox with recently developed CRISPR–Cas systems

Since its first appearance, CRISPR–Cas9 has been developed extensively as a programmable genome-editing tool, opening a new era in plant genome engineering. However, CRISPR–Cas9 still has some drawbacks, such as limitations of the protospacer-adjacent motif (PAM) sequence, target specificity, and the large size of the cas9 gene. To combat invading bacterial phages and plasmid DNAs, bacteria and archaea have diverse and unexplored CRISPR–Cas systems, which have the potential to be developed as a useful genome editing tools. Recently, discovery and characterization of additional CRISPR–Cas systems have been reported. Among them, several CRISPR–Cas systems have been applied successfully to plant and human genome editing. For example, several groups have achieved genome editing using CRISPR–Cas type I-D and type I-E systems, which had never been applied for genome editing previously. In addition to higher specificity and recognition of different PAM sequences, recently developed CRISPR–Cas systems often provide unique characteristics that differ from well-known Cas proteins such as Cas9 and Cas12a. For example, type I CRISPR–Cas10 induces small indels and bi-directional long-range deletions ranging up to 7.2 kb in tomatoes (Solanum lycopersicum L.). Type IV CRISPR–Cas13 targets RNA, not double-strand DNA, enabling highly specific knockdown of target genes. In this article, we review the development of CRISPR–Cas systems, focusing especially on their application to plant genome engineering. Recent CRISPR–Cas tools are helping expand our plant genome engineering toolbox.

Recently discovered and characterized clustered regularly interspaced short palindromic repeats-CRISPR associated (CRISPR–Cas) systems allow additional applications to plant genome editing.     

Harnessing Type I and Type III CRISPR-Cas systems for genome editing

CRISPR-Cas (clustered regularly interspaced short palindromic repeats-CRISPR-associated) systems are widespread in archaea and bacteria, and research on their molecular mechanisms has led to the development of genome-editing techniques based on a few Type II systems. However, there has not been any report on harnessing a Type I or Type III system for genome editing. Here, a method was developed to repurpose both CRISPR-Cas systems for genetic manipulation in Sulfolobus islandicus, a thermophilic archaeon. A novel type of genome-editing plasmid (pGE) was constructed, carrying an artificial mini-CRISPR array and a donor DNA containing a non-target sequence. Transformation of a pGE plasmid would yield two alternative fates to transformed cells: wild-type cells are to be targeted for chromosomal DNA degradation, leading to cell death, whereas those carrying the mutant gene would survive the cell killing and selectively retained as transformants. Using this strategy, different types of mutation were generated, including deletion, insertion and point mutations. We envision this method is readily applicable to different bacteria and archaea that carry an active CRISPR-Cas system of DNA interference provided the protospacer adjacent motif (PAM) of an uncharacterized PAM-dependent CRISPR-Cas system can be predicted by bioinformatic analysis.     

Novel reporter systems for facile evaluation of I-SceI-mediated genome editing

Two major limitations to achieve efficient homing endonuclease-stimulated gene correction using retroviral vectors are low frequency of gene targeting and random integration of the targeting vectors. To overcome these issues, we developed a reporter system for quick and facile testing of novel strategies to promote the selection of cells that undergo targeted gene repair and to minimize the persistence of random integrations and non-homologous end-joining events. In this system, the gene target has an I-SceI site upstream of an EGFP reporter; and the repair template includes a non-functional EGFP gene, the positive selection transgene MGMTP140K tagged with mCherry, and the inducible Caspase-9 suicide gene. Using this dual fluorescent reporter system it is possible to detect properly targeted integration. Furthermore, this reporter system provides an efficient approach to enrich for gene correction events and to deplete events produced by random integration. We have also developed a second reporter system containing MGMTP140K in the integrated target locus, which allows for selection of primary cells with the integrated gene target after transplantation. This system is particularly useful for testing repair strategies in primary hematopoietic stem cells. Thus, our reporter systems should allow for more efficient gene correction with less unwanted off target effects.     

Gene delivery methods and genome editing of human pluripotent stem cells

Induced pluripotent stem cells derived from normal somatic cells could be utilized to study tumorigenesis through overexpression of specific oncogenes, downregulation of tumor suppressors and dysregulation of other factors thought to promote tumorigenesis. Therefore, effective approaches that provide direct modifications of induced pluripotent stem cell genome are extremely needed. Emerging strategies are expected to provide the ability to more effectively introduce diverse genetic alterations, from as small as single-nucleotide modifications to whole gene amplification or deletion, all with a high degree of target specificity. To date, several techniques have been applied in stem cell studies to directly edit cell genome (ZFNs, TALENs or CRISPR/Cas9). In this review, we summarize specific gene delivery strategies that were applied to stem cell studies together with genome editing techniques, which enable a direct modification of endogenous DNA sequences in the context of cancer studies.     

Agrobacterium-mediated delivery of CRISPR/Cas reagents for genome editing in plants enters an era of ternary vector systems

Lack of appropriate methods for delivery of genome-editing reagents is a major barrier to CRISPR/Cas-mediated genome editing in plants. Agrobacterium-mediated genetic transformation(AMGT) is the preferred method of CRISPR/Cas reagent delivery,and researchers have recently made great improvements to this process. In this article, we review the development of AMGT and AMGT-based delivery of CRISPR/Cas reagents. We give an overview of the development of AMGT vectors including binary vector, superbinary vector, dual binary vector, and ternary vector systems. We also review the progress in Agrobacterium genomics and Agrobacterium genetic engineering for optimal strains. We focus in particular on the ternary vector system and the resources we developed. In summary, it is our opinion that Agrobacterium-mediated CRISPR/Cas genome editing in plants is entering an era of ternary vector systems, which are often integrated with morphogenic regulators. The new vectors described in this article are available from Addgene and/or MolecularCloud for sharing with academic investigators for noncommercial research.     

Harnessing the type I CRISPR-Cas systems for genome editing in prokaryotes

Genetic analysis is crucial to the understanding, exploitation, and control of microorganisms. The advent of CRISPR-Cas-based genome-editing techniques, particularly those mediated by the single-effector (Cas9 and Cas12a) class 2 CRISPR-Cas systems, has revolutionized the genetics in model eukaryotic organisms. However, their applications in prokaryotes are rather limited, largely owing to the exceptional diversity of DNA homeostasis in microorganisms and severe cytotoxicity of overexpressing these nuclease proteins in certain genotypes. Remarkably, CRISPR-Cas systems belonging to different classes and types are continuously identified in prokaryotic genomes and serve as a deep reservoir for expansion of the CRISPR-based genetic toolkits. ~90% of the CRISPR-Cas systems identified so far belong to the class 1 system which hinges on multi-protein effector complexes for DNA interference. Harnessing these widespread native CRISPR-Cas systems for ‘built-in’ genome editing represents an emerging and powerful genetic tool in prokaryotes, especially in the genetically recalcitrant non-model species and strains. In this progress review, we introduce the general workflow of this emerging editing platform and summarize its establishment in a growing number of prokaryotes by harnessing the most widespread, diverse type I CRISPR-Cas systems present in their genomes. We also discuss the various factors affecting the success and efficiency of this editing platform and the corresponding solutions.     

NgAgo-gDNA基因组编辑系统的成功及启示

韩春雨等发明的DNA指导的基因组编辑系统NgAgo-gDNA,比原有的RNA指导的基因组编辑系统CRISPR-Cas9在靶向特异性(防脱靶),反应可控性和基因组编辑范围等方面都有显著的改进。NgAgo-gDNA不是一项简单的改进,是一项具有开拓性的工作,沿着这条研究路线,可以继续开发出更先进的基因组编辑系统。该研究充分体现了生物信息学,特别是大数据挖掘在未来生命科学研究中的重要地位。本文仅从生物信息学角度,谈谈这项研究的价值、意义以及可能引发的相关研究方向。     

CRISPR/Cas9 for plant genome editing: accomplishments,problems and prospects

The increasing burden of the world population on agriculture requires the development of more robust crops. Dissecting the basic biology that underlies plant development and stress responses will inform the design of better crops. One powerful tool for studying plants at the molecular level is the RNA-programmed genome editing system composed of a clustered regularly interspaced short palindromic repeats (CRISPR)-encoded guide RNA and the nuclease Cas9. Here, some of the recent advances in CRISPR/Cas9 technology that have profound implications for improving the study of plant biology are described. These tools are also paving the way towards new horizons for biotechnologies and crop development.     

A showcase of future plant biology: moving towards next-generation plant genetics assisted by genome sequencing and systems biology

A report on the Cold Spring Harbor Asia conference on Genome Assisted Biology of Crops and Model Plant Systems Meeting, held in Suzhou, China, April 21–25, 2014.