Abstract
Since the discovery of RNA interference (RNAi), scientists have made significant progress towards the development of this unique technology for crop protection. The RNAi mechanism works at the mRNA level by exploiting a sequence-dependent mode of action with high target specificity due to the design of complementary dsRNA molecules, allowing growers to target pests more precisely compared to conventional agrochemicals. The delivery of RNAi through transgenic plants is now a reality with some products currently in the market. Conversely, it is also expected that more RNA-based products reach the market as non-transformative alternatives. For instance, topically applied dsRNA/siRNA (SIGS – Spray Induced Gene Silencing) has attracted attention due to its feasibility and low cost compared to transgenic plants. Once on the leaf surface, dsRNAs can move directly to target pest cells (e.g., insects or pathogens) or can be taken up indirectly by plant cells to then be transferred into the pest cells. Water-soluble formulations containing pesticidal dsRNA provide alternatives, especially in some cases where plant transformation is not possible or takes years and cost millions to be developed (e.g., perennial crops). The ever-growing understanding of the RNAi mechanism and its limitations has allowed scientists to develop non-transgenic approaches such as trunk injection, soaking, and irrigation. While the technology has been considered promising for pest management, some issues such as RNAi efficiency, dsRNA degradation, environmental risk assessments, and resistance evolution still need to be addressed. Here, our main goal is to review some possible strategies for non-transgenic delivery systems, addressing important issues related to the use of this technology.
Highlights
From the earliest days of agriculture, mankind cultivated the land to feed their descendants, allowing for an increase in population growth over the years
Once RNA molecules are delivered in the field, they need to enter the cell of a target organism to trigger gene silencing
What is known about this process so far is that the double-stranded RNA (dsRNA)/smallinterfering RNAs (siRNAs) spread from one cell to another cell or tissue is highly dependent on the cell’s ability to take up the dsRNA or siRNA molecules (Vélez and Fishilevich, 2018), or on mediation through nanotube-like structures (Karlikow et al, 2016)
Summary
Insects and Plant Diseases by NonTransformative RNAi. Since the discovery of RNA interference (RNAi), scientists have made significant progress towards the development of this unique technology for crop protection. The delivery of RNAi through transgenic plants is a reality with some products currently in the market. It is expected that more RNA-based products reach the market as non-transformative alternatives. Water-soluble formulations containing pesticidal dsRNA provide alternatives, especially in some cases where plant transformation is not possible or takes years and cost millions to be developed (e.g., perennial crops). The evergrowing understanding of the RNAi mechanism and its limitations has allowed scientists to develop non-transgenic approaches such as trunk injection, soaking, and irrigation. Our main goal is to review some possible strategies for non-transgenic delivery systems, addressing important issues related to the use of this technology
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