Interaction of Nanomaterials with Plants: What Do We Need for Real Applications in Agriculture?

Demirer

et al. 2019

Preprint

SignificancePlant bioengineering will be necessary to sustain plant biology and agriculture, where the delivery of biomolecules such as DNA, RNA, or proteins to plant cells is at the crux of plant biotechnology. Here, we show that DNA nanostructures can passively internalize into plant cells and deliver small interfering RNA (siRNA) to mature plant tissues. Furthermore, we demonstrate that nanostructure size, shape, compactness, and stiffness, affect both nanostructure internalization into plant cells and subsequent gene silencing efficiency. Interestingly, we also find that the siRNA attachment locus affects the endogenous plant gene silencing pathway. Our work demonstrates programmable passive delivery of biomolecules to plants, and details the figures of merit for future implementation of DNA nanostructures in agriculture. AbstractPlant bioengineering may generate high yielding and stress-resistant crops amidst a changing climate and a growing global population (1-3). However, delivery of biomolecules to plants relies on Agrobacterium infection (4) or biolistic particle delivery (5), the former of which is only amenable to DNA delivery. The difficulty in delivering functional biomolecules such as RNA to plant cells is due to the plant cell wall which is absent in mammalian cells and poses the dominant physical barrier to exogenous biomolecule delivery in plants. DNA nanostructure-mediated biomolecule delivery is an effective strategy to deliver cargoes across the lipid bilayer of mammalian cells, however, nanoparticle-mediated delivery remains unexplored for passive biomolecule delivery across the cell wall in plants. Herein, we report a systematic assessment of different DNA nanostructures for their ability to internalize into cells of mature plants, deliver small interfering RNAs (siRNAs), and effectively silence a constitutivelyexpressed gene in Nicotiana benthamiana leaves. We show that nanostructure internalization into plant cells and the corresponding gene silencing efficiency depends on the DNA nanostructure size, shape, compactness, stiffness, and location of the siRNA attachment locus on the nanostructure. We further confirm that the internalization efficiency of DNA nanostructures correlates with their respective gene silencing efficiencies, but that the endogenous gene silencing pathway depends on the siRNA attachment locus. Our work establishes the feasibility of biomolecule delivery to plants with DNA nanostructures, and details both the design parameters of importance for plant cell internalization, and also assesses the impact of DNA nanostructure geometry for gene silencing mechanisms.

Section: Discussionmentioning

confidence: 99%

DNA Nanostructures Coordinate Gene Silencing in Mature Plants

Demirer

et al. 2019

Preprint

J of Chemical Tech & Biotech

“…Another reason is that the NPs can easily penetrate the cell wall to release the proteins in situ , which facilitates protein–receptor interactions. Several previous reports revealed that some NPs can enter plant tissue through foliar stoma or root absorption …”

Section: Discussionmentioning

confidence: 99%

“…Several previous reports revealed that some NPs can enter plant tissue through foliar stoma or root absorption. [32][33][34][35] The wheat seeds treated with P@NPs showed positive effects on seed vigor index [ Fig. 3(b)].…”

Section: Discussionmentioning

confidence: 99%

Enhanced plant growth promoting role of mPEG‐PLGA‐based nanoparticles as an activator protein PeaT1 carrier in wheat (Triticum aestivum L.)

Gao

Qin

Guo

et al. 2018

BACKGROUND Developing new types of bioproducts using innovative nanotechnology is one of the potentially effective options for enhancing agricultural production and reducing environmental agrochemical pollution. As a bioagent derived from fungi, activator protein can promote growth and control diseases by activating the plant immune system. Meanwhile, the nanocarrier can protect the protein within and prolong its efficiency through controlled release. RESULTS In our study, a new kind of plant nano‐activator was developed by encapsulating an activator protein PeaT1 using a polymer nanoparticle constructed with monomethoxy‐poly (ethylene glycol)‐poly (lactide‐co‐glycolide) (mPEG‐PLGA). The nanoparticles were spherical with diameter about 200 nm. Morphological and physiological parameters of wheat seedlings, including seed vigor index, root vitality, chlorophyll content and photosynthetic parameters, increased after treatment with the nano‐activator. Further observation under the confocal laser microscope showed a more effective intake of the nano‐activator protein. CONCLUSION The results showed that the nano‐activators are effective in enhancing wheat growth. This novel agent provides a promising way to improve crop production in an environmentally friendly manner. © 2018 Society of Chemical Industry

Pest Management Science

“…In general terms, an ideal nanodevice for use in agricultural should comprise the following traits: (i) it should be non‐toxic and environmentally safe, to avoid further contamination problems and a negative perception on the part of consumers; (ii) its synthesis and production must be easily up‐scaled; (iii) it should involve low‐cost materials, so that the cost of the new nanoformulated products does not exceed that of the current agrochemicals and they are affordable to farmers …”

Section: Toxicity and Environmental Impactmentioning

confidence: 99%

“…96 In general terms, an ideal nanodevice for use in agricultural should comprise the following traits: (i) it should be non-toxic and environmentally safe, to avoid further contamination problems and a negative perception on the part of consumers; (ii) its synthesis and production must be easily up-scaled; (iii) it should involve low-cost materials, so that the cost of the new nanoformulated products does not exceed that of the current agrochemicals and they are affordable to farmers. 97 In order to clarify the needs and achieve conformity among procedures, the EFSA has very recently prepared a guidance statement concerning risk assessment of nanoscience, nanoobjects and nanotechnology applications in the food and feed chain for humans and animals. The document provides insights into the physicochemical properties and into exposure assessment and hazard characterisation of nanomaterials, suggesting ways to establish whether a material is indeed a nanomaterial, and establishing the key parameters to be measured and the techniques for characterisation of nanomaterials.…”

Section: Toxicity and Environmental Impactmentioning

confidence: 99%

Safe nanotechnologies for increasing the effectiveness of environmentally friendly natural agrochemicals

Vurro

Miguel-Rojas

Pérez‐de‐Luque

2019

Self Cite

113

Natural compounds and living organisms continue to play a limited role in crop protection, and few of them have reached the market, despite their attractiveness and the efforts made in research. Very often these products have negative characteristics compared to synthetic compounds, e.g., higher costs of production, lower effectiveness, lack of persistence, and inability to reach and penetrate the target plant. Conversely, nanotechnologies are having an enormous impact on all human activities, including agriculture, even if the production of some nanomaterials is not environmentally friendly or could have adverse effects on agriculture and the environment. Thus, certain nanomaterials could facilitate the development of formulated natural pesticides, making them more effective and more environmentally friendly. Nanoformulations can improve efficacy, reduce effective doses, and increase shelf‐life and persistence. Such controlled‐release products can improve delivery to the target pest. This review considers certain available nanomaterials and nanotechnologies for use in agriculture, discussing their properties and the feasibility of their use in sustainable crop protection, in particular, in improving the effectiveness of natural bio‐based agrochemicals. © 2019 Society of Chemical Industry