Plant abiotic stress leads to accumulation of reactive oxygen species (ROS) and a consequent decrease in photosynthetic performance. We demonstrate that a plant nanobionics approach of localizing negatively charged, sub-11 nm, spherical cerium oxide nanoparticles (nanoceria) inside chloroplasts in vivo augments ROS scavenging and photosynthesis of Arabidopsis thaliana plants under excess light (2000 μmol m s, 1.5 h), heat (35 °C, 2.5 h), and dark chilling (4 °C, 5 days). Poly(acrylic acid) nanoceria (PNC) with a hydrodynamic diameter (10.3 nm)-lower than the maximum plant cell wall porosity-and negative ζ-potential (-16.9 mV) exhibit significantly higher colocalization (46%) with chloroplasts in leaf mesophyll cells than aminated nanoceria (ANC) (27%) of similar size (12.6 nm) but positive charge (9.7 mV). Nanoceria are transported into chloroplasts via nonendocytic pathways, influenced by the electrochemical gradient of the plasma membrane potential. PNC with a low Ce/Ce ratio (35.0%) reduce leaf ROS levels by 52%, including hydrogen peroxide, superoxide anion, and hydroxyl radicals. For the latter ROS, there is no known plant enzyme scavenger. Plants embedded with these PNC that were exposed to abiotic stress exhibit an increase up to 19% in quantum yield of photosystem II, 67% in carbon assimilation rates, and 61% in Rubisco carboxylation rates relative to plants without nanoparticles. In contrast, PNC with high Ce/Ce ratio (60.8%) increase overall leaf ROS levels and do not protect photosynthesis from oxidative damage during abiotic stress. This study demonstrates that anionic, spherical, sub-11 nm PNC with low Ce/Ce ratio can act as a tool to study the impact of oxidative stress on plant photosynthesis and to protect plants from abiotic stress.
Fundamental and quantitative understanding of the interactions between nanoparticles and plant leaves is crucial for advancing the field of nanoenabled agriculture. Herein, we systematically investigated and modeled how ζ potential (−52.3 mV to +36.6 mV) and hydrodynamic size (1.7−18 nm) of hydrophilic nanoparticles influence delivery efficiency and pathways to specific leaf cells and organelles. We studied interactions of nanoparticles of agricultural interest including carbon dots (CDs, 0.5 and 5 mg/mL), cerium oxide (CeO 2 , 0.5 mg/mL), and silica (SiO 2 , 0.5 mg/mL) nanoparticles with leaves of two major crop species having contrasting leaf anatomies: cotton (dicotyledon) and maize (monocotyledon). Biocompatible CDs allowed real-time tracking of nanoparticle translocation and distribution in planta by confocal fluorescence microscopy at high spatial (∼200 nm) and temporal (2−5 min) resolution. Nanoparticle formulations with surfactants (Silwet L-77) that reduced surface tension to 22 mN/m were found to be crucial for enabling rapid uptake (<10 min) of nanoparticles through the leaf stomata and cuticle pathways. Nanoparticle−leaf interaction (NLI) empirical models based on hydrodynamic size and ζ potential indicate that hydrophilic nanoparticles with <20 and 11 nm for cotton and maize, respectively, and positive charge (>15 mV), exhibit the highest foliar delivery efficiencies into guard cells (100%), extracellular space (90.3%), and chloroplasts (55.8%). Systematic assessments of nanoparticle−plant interactions would lead to the development of NLI models that predict the translocation and distribution of nanomaterials in plants based on their chemical and physical properties.
Sustainable
agriculture is a key component of the effort to meet
the increased food demand of a rapidly increasing global population.
Nano-biotechnology is a promising tool for sustainable agriculture.
However, rather than acting as nanocarriers, some nanoparticles (NPs)
with unique physiochemical properties inherently enhance plant growth
and stress tolerance. This biological role of nanoparticles depends
on their physiochemical properties, application method (foliar delivery,
hydroponics, soil), and the applied concentration. Here we review
the effects of the different types, properties, and concentrations
of nanoparticles on plant growth and on various abiotic (salinity,
drought, heat, high light, and heavy metals) and biotic (pathogens
and herbivores) stresses. The ability of nanoparticles to stimulate
plant growth by positive effects on seed germination, root or shoot
growth, and biomass or grain yield is also considered. The information
presented herein will allow researchers within and outside the nano-biotechnology
field to better select the appropriate nanoparticles as starting materials
in agricultural applications. Ultimately, a shift from testing/utilizing
existing nanoparticles to designing specific nanoparticles based on
agriculture needs will facilitate the use of nanotechnology in sustainable
agriculture.
Background Salinity is a global issue threatening agricultural production systems across the globe. While the major focus of plant salinity stress tolerance research has been on sodium, the transport and physiological roles of K+ in plant salt stress response has received less attention. This review attempts to bridge this knowledge gap. Scope The major emphasis is on newly proposed K+ signalling roles and plant salt tolerance cell-and tissuespecificity. In addition to summarizing the importance of K+ retention for plant salt tolerance, we focus onaspects that were not the subject of previous reviews including (1) the importance of HAK/KUP family of transporters in K+ uptake in salt stressed plants and its possible linkage with Ca2+ and ROS signalling; (2) control of xylem K+ loading in salt stressed plants, control of phloem K+ recirculation in salt stressed plants and the potential importance of plant's ability to efficiently coordinate K+ signals between root and shoot;(3) the buffering capacity of the vacuolar K+ pool; and(4) mechanisms of restoring the basal cytosolic K+ levels by coordinated activity of tonoplast K+-permeable channels. Conclusions Overall, this review emphasises the need to fully understand the newly emerging roles of K+ and regulation of its transport for improving salinity stress tolerance in plants.
Near-infrared
(nIR) fluorescent single-walled carbon nanotubes
(SWCNTs) were designed and interfaced with leaves of Arabidopsis
thaliana plants to report hydrogen peroxide (H2O2), a key signaling molecule associated with the onset
of plant stress. The sensor nIR fluorescence response (>900 nm)
is
quenched by H2O2 with selectivity against other
stress-associated signaling molecules and within the plant physiological
range (10–100 H2O2 μM). In vivo remote nIR imaging of H2O2 sensors enabled optical monitoring of plant health in response to
stresses including UV-B light (−11%), high light (−6%),
and a pathogen-related peptide (flg22) (−10%), but not mechanical
leaf wounding (<3%). The sensor’s high biocompatibility
was reflected on similar leaf cell death (<5%) and photosynthetic
rates to controls without SWCNT. These optical nanosensors report
early signs of stress and will improve our understanding of plant
stress communication, provide novel tools for precision agriculture,
and optimize the use of agrochemicals in the environment.
Nanoceria ROS scavenging is a key tool for understanding and improving plant tolerance to salinity, a stress that severely limits crop yield worldwide.
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