A Resource for Inactivation of MicroRNAs Using Short Tandem Target Mimic Technology in Model and Crop Plants

Peng, Ting; Qiao, Mengmeng; Li, Haiping; Teotia, Sachin; Zhang, Zhan‐Hui; Zhao, Yongju; Wang, Bobo; Zhao, Dongjie; Shi, Li; Zhang, Cui; Le, Brandon H.; Rogers, Kestrel; Gunasekara, T.D.C.P.; Duan, Haitang; Gu, Ying; Tian, Lei; Nie, Jinfu; Qi, Jian; Meng, Fanrong; Huang, Lan; Chen, Qinghui; Wang, Zhenlin; Tang, Jian; Tang, Xiaoqing; Lan, Ting; Chen, Xuemei; Wei, Hairong; Zhao, Quanzhi; Tang, Guiliang

doi:10.1016/j.molp.2018.09.003

Cited by 53 publications

(57 citation statements)

References 93 publications

(109 reference statements)

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“…Then, these 21-nt amiRNAs are methylated by HEN1, which subsequently undergoes nucleus-cytoplasm transport by HST to P-bodies and becomes integrated into the RISC, where it will act in a manner similar to canonical miRNAs on PTGS. (b) Target mimicry strategy to deplete specific miRNAs (Peng et al, 2018;Zhang et al, 2017). The constitutive or transient expression of the target mimic gene driven by a specific promoter is transcribed by RNA polymerase II in the nucleus.…”

Section: Artificial Mir Genesmentioning

confidence: 99%

“…Thus, STTM sequester miRNAs from the endogenous target mRNA resulting in its up-regulation (Franco-Zorrilla et al, 2007). Several STTMs targeting the MIR genes in model and crop plants have been recently engineered and constitutively expressed as transgenes for the comprehensive functional analysis of miRNAs (Peng et al, 2018;Zhang et al, 2017). In addition, STTMs have been optimized to enhance lossof-function phenotypes caused by artificial single target mimics.…”

Section: Endogenous and Artificial Target Mimicrymentioning

confidence: 99%

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MicroRNAs and new biotechnological tools for its modulation and improving stress tolerance in plants

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Ferreira

Kobayashi

et al. 2019

Plant Biotechnology Journal

108

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Summary Micro RNA s (mi RNA s) modulate the abundance and spatial–temporal accumulation of target mRNA s and indirectly regulate several plant processes. Transcriptional regulation of the genes encoding mi RNA s ( MIR genes) can be activated by numerous transcription factors, which themselves are regulated by other mi RNA s. Fine‐tuning of MIR genes or mi RNA s is a powerful biotechnological strategy to improve tolerance to abiotic or biotic stresses in crops of economic importance. Current approaches for mi RNA fine‐tuning are based on the down‐ or up‐regulation of MIR gene transcription and the use of genetic engineering tools to manipulate the final concentration of these mi RNA s in the cytoplasm. Transgenesis, cisgenesis, intragenesis, artificial MIR genes, endogenous and artificial target mimicry, MIR genes editing using Meganucleases, ZNF proteins, TALEN s and CRISPR /Cas9 or CRISPR /Cpf1, CRISPR / dC as9 or dC pf1, CRISPR 13a, topical delivery of mi RNA s and epigenetic memory have been successfully explored to MIR gene or mi RNA modulation and improve agronomic traits in several model or crop plants. However, advantages and drawbacks of each of these new biotechnological tools ( NBT s) are still not well understood. In this review, we provide a brief overview of the biogenesis and role of mi RNA s in response to abiotic or biotic stresses, we present critically the main NBT s used for the manipulation of MIR genes and mi RNA s, we show current efforts and findings with the MIR genes and mi RNA s modulation in plants, and we summarize the advantages and drawbacks of these NBT s and provide some alternatives to overcome. Finally, challenges and future perspectives to mi RNA modulating in important crops are also discussed.

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Section: Artificial Mir Genesmentioning

confidence: 99%

Section: Endogenous and Artificial Target Mimicrymentioning

confidence: 99%

MicroRNAs and new biotechnological tools for its modulation and improving stress tolerance in plants

Basso

Ferreira

Kobayashi

et al. 2019

Plant Biotechnology Journal

108

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“…Several genetic engineering technologies have been deployed to study the functions of miRNAs, such as target mimic (MIM) (Franco‐Zorrilla et al, ) and short tandem target mimic (STTM) (Yan et al, ). In addition, large scale studies involving MIMs and STTMs for functional interrogation of miRNAs have been done in Arabidopsis, rice and other species (Peng et al, ; Todesco et al, ; Zhang, Zhang, et al, ), and offers a useful platform and resource for such studies. In recent years, targeted genome modification technologies, such as ZFNs (Zhang et al, ), TALENs (Li, Liu, Spalding, Weeks, & Yang, ), CRISPR/Cas9 (Li, Teng, Li, & Zhou, ), and CRISPR/Cas13 (Ali, Mahas, & Mahfouz, ; Aman et al, ), were successfully used for plant genome editing.…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

“…Therefore, traditional over‐expression of miRNAs or downregulating them through methods such as MIM, STTM, CRISPR/Cas9 and/or CRISPR/Cas13 technology can be further used to study the roles of these miRNAs in regulating rice grain development. Using STTM technology, we already identified the roles of miR159, miR167, and miR1432 in controlling rice seed development (Peng et al, ; Zhao et al, ). Furthermore, majority of the miRNAs mentioned in this review, negatively regulate rice yield‐associated agronomic traits, therefore lowering their expression in rice may enhance the yield.…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

MicroRNAs meet with quantitative trait loci: Small powerful players in regulating quantitative yield traits in rice

et al. 2019

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MicroRNAs (miRNAs) are small noncoding RNAs which regulate various functions related to growth, development, and stress responses in plants and animals. Rice, Oryza sativa, is one of the most important food crops of the world. In rice, a number of quantitative trait loci (QTL) controlling yield‐related traits have been identified. Some of them are actually controlled by miRNAs, which control various yield‐related quantitative traits in rice. On one hand, many of these miRNAs are found to regulate more than one yield‐related traits, such as tillering, grain size, and branch number of a panicle. On the other hand, a rice yield‐related trait is usually controlled by multiple miRNAs, for example, grain size being controlled by miR156, miR167, miR396, miR397, and miR1432. In rare case, a single miRNA may specifically regulate only one yield‐related trait, such as, miR444 regulating rice tillering. In this review, we focus on the functions of miRNAs in controlling yield‐related quantitative traits in rice, including panicle grain number, grain weight/size, panicle length and branching, tiller number per plant, spikelet number, seed setting rate, and leaf inclination, and discuss how to modulate the expression of these miRNAs using modern molecular biology tools to promote grain yield. This article is categorized under: RNA in Disease and Development > RNA in Development

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“…sRNA levels can be increased either by directly overexpressing the endogenous precursor [3] or by the use of molecular tools such as artificial miRNAs (amiRs), which substitutes the 21 nt sequence of an endogenous pri-miRNA for our miRNA of interest [4,5]. Conversely, molecular tools such as Target Mimics (MIMs or TMs) [6,7], Short Tandem Target Mimic (STTMs) [8,9], or molecular SPONGES (SPs) [10] are used to reduce plant miRNA levels with varying degrees of efficacy, which depend mainly on the miRNA family targeted [10]. Such techniques are extensively employed in both model (Arabidopsis) and crop plants (e.g.…”

Section: Introductionmentioning

confidence: 99%

Protocol: low cost fast and efficient generation of molecular tools for small RNA analysis

et al. 2020

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Background: Small RNAs are sequence-dependent negative regulators of gene expression involved in many relevant plant processes such as development, genome stability, or stress response. Functional characterization of sRNAs in plants typically relies on the modification of the steady state levels of these molecules. State-of-the-art strategies to reduce plant sRNA levels include molecular tools such as Target Mimics (MIMs or TMs), Short Tandem Target Mimic (STTMs), or molecular SPONGES (SPs). Construction of these tools routinely involve many different molecular biology techniques, steps, and reagents rendering such processes expensive, time consuming, and difficult to implement, particularly high-throughput approaches. Results: We have developed a vector and a cloning strategy that significantly reduces the number of steps required for the generation of MIMs against any given small RNA (sRNA). Our pGREEN-based binary expression vector (pGREEN-DLM100) contains the IPS1 gene from A. thaliana bisected by a ccdB cassette that is itself flanked by restriction sites for a type IIS endonuclease. Using a single digestion plus a sticky-end ligation step, the ccdB cassette that functions as a negative (counter) selection system is replaced by a pair of 28 nt self-annealing primers that provide specificity against the selected target miRNA/siRNA. The method considerably reduces the number of steps and the time required to generate the construct, minimizes the errors derived from long-range PCRs, bypasses bottlenecks derived from subcloning steps, and eliminates the need for any additional cloning technics and reagents, overall saving time and reagents. Conclusions: Our streamlined system guarantees a low cost, fast and efficient cloning process that it can be easily implemented into high-throughput strategies, since the same digested plasmid can be used for any given sRNA. We believe this method represents a significant technical improvement on state-of-the-art methods to facilitate the characterization of functional aspects of sRNA biology.

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A Resource for Inactivation of MicroRNAs Using Short Tandem Target Mimic Technology in Model and Crop Plants

Cited by 53 publications

References 93 publications

MicroRNAs and new biotechnological tools for its modulation and improving stress tolerance in plants

MicroRNAs and new biotechnological tools for its modulation and improving stress tolerance in plants

MicroRNAs meet with quantitative trait loci: Small powerful players in regulating quantitative yield traits in rice

Protocol: low cost fast and efficient generation of molecular tools for small RNA analysis

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