Awan Muhammad Jawad Akbar, Pervaiz Komal, Rasheed Awais, Amin Imran, Saeed Nasir A, Dhugga Kanwarpal S, Mansoor Shahid
Agricultural Biotechnology Division, National Institute for Biotechnology and Genetic Engineering (NIBGE), Constituent College of Pakistan Institute of Engineering and Applied Sciences, Jhang Road, Faisalabad, Pakistan.
Department of Plant Sciences, Quaid-i-Azam University, Islamabad 45320, Pakistan; Institute of Crop Science, Chinese Academy of Agricultural Sciences (CAAS) & CIMMYT-China office, 12 Zhongguanccun South Street, Beijing 100081, China.
Biotechnol Adv. 2022 Nov;60:108006. doi: 10.1016/j.biotechadv.2022.108006. Epub 2022 Jun 19.
Common wheat is a major source of nutrition around the globe, but unlike maize and rice hybrids, no breakthrough has been made to enhance wheat yield since Green Revolution. With the availability of reference genome sequence of wheat and advancement of allied genomics technologies, understanding of genes involved in grain yield components and disease resistance/susceptibility has opened new avenues for crop improvement. Wheat has a huge hexaploidy genome of approximately 17 GB with 85% repetition, and it is a daunting task to induce any mutation across three homeologues that can be helpful for the enhancement of agronomic traits. The CRISPR-Cas9 system provides a promising platform for genome editing in a site-specific manner. In wheat, CRISPR-Cas9 is being used in the improvement of yield, grain quality, biofortification, resistance against diseases, and tolerance against abiotic factors. The promising outcomes of the CRISPR-based multiplexing approach circumvent the constraint of targeting merely one gene at a time. Deployment of clustered regularly interspaced short palindromic repeats (CRISPR)-associated (Cas) 9 endonuclease (CRISPR-Cas9) and Cas9 variant systems such as cytidine base editing, adenosine base editing, and prime editing in wheat has been used to induce point mutations more precisely. Scientists have acquired major events such as induction of male sterility, fertility restoration, and alteration of seed dormancy through Cas9 in wheat that can facilitate breeding programs for elite variety development. Furthermore, a recent discovery in tissue culturing enables scientists to significantly enhance regeneration efficiency in wheat by transforming the GRF4-GIF1 cassette. Rapid generation advancement by speed breeding technology provides the opportunity for the generation advancement of the desired plants to segregate out unwanted transgenes and allows rapid integration of gene-edited wheat into the breeding pipeline. The combination of these novel technologies addresses some of the most important limiting factors for sustainable and climate-smart wheat that should lead to the second "Green Revolution" for global food security.
普通小麦是全球主要的营养来源,但与玉米和水稻杂交品种不同,自绿色革命以来,在提高小麦产量方面尚未取得突破。随着小麦参考基因组序列的可得以及相关基因组技术的进步,对参与籽粒产量构成和抗病性/易感性的基因的了解为作物改良开辟了新途径。小麦拥有一个庞大的六倍体基因组,约17GB,重复率达85%,要在三个同源染色体上诱导任何有助于提高农艺性状的突变是一项艰巨的任务。CRISPR-Cas9系统为以位点特异性方式进行基因组编辑提供了一个有前景的平台。在小麦中,CRISPR-Cas9正被用于提高产量、改善籽粒品质、生物强化、抗病性以及对非生物因素的耐受性。基于CRISPR的多重编辑方法取得的有前景的成果克服了一次只能靶向一个基因的限制。在小麦中部署成簇规律间隔短回文重复序列(CRISPR)相关(Cas)9核酸内切酶(CRISPR-Cas9)以及Cas9变体系统,如胞嘧啶碱基编辑、腺嘌呤碱基编辑和引导编辑,已被用于更精确地诱导点突变。科学家们通过在小麦中使用Cas9获得了诸如诱导雄性不育、育性恢复和改变种子休眠等重大成果,这有助于开展培育优良品种的育种计划。此外,组织培养方面的一项最新发现使科学家们能够通过转化GRF4-GIF1盒式结构显著提高小麦的再生效率。快速育种技术实现的快速世代推进为培育所需植株以分离出不需要的转基因提供了机会,并使基因编辑小麦能够迅速融入育种流程。这些新技术的结合解决了可持续和气候智能型小麦的一些最重要的限制因素,有望带来全球粮食安全领域的第二次“绿色革命”。
