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A lack of mechanistic understanding of nanomaterial interactions with plants and algae cell walls limits the advancement of nanotechnology-based tools for sustainable agriculture. We systematically investigated the influence of nanoparticle charge on the interactions with model cell wall surfaces built with cellulose or pectin and performed a comparative analysis with native cell walls of Arabidopsis plants and green algae (Choleochaete). The high affinity of positively charged carbon dots (CDs) (46.0 ± 3.3 mV, 4.3 ± 1.5 nm) to both model and native cell walls was dominated by the strong ionic bonding between the surface amine groups of CDs and the carboxyl groups of pectin. In contrast, these CDs formed weaker hydrogen bonding with the hydroxyl groups of cellulose model surfaces. The CDs of similar size with negative (−46.2 ± 1.1 mV, 6.6 ± 3.8 nm) or neutral (−8.6 ± 1.3 mV, 4.3 ± 1.9 nm) ζ-potentials exhibited negligible interactions with cell walls. Real-time monitoring of CD interactions with model pectin cell walls indicated higher absorption efficiency (3.4 ± 1.3 10−9) and acoustic mass density (313.3 ± 63.3 ng cm–2) for the positively charged CDs than negative and neutral counterparts (p < 0.001 and p < 0.01, respectively). The surface charge density of the positively charged CDs significantly enhanced these electrostatic interactions with cell walls, pointing to approaches to control nanoparticle binding to plant biosurfaces. Ca2+-induced cross-linking of pectin affected the initial absorption efficiency of the positively charged CD on cell wall surfaces (∼3.75 times lower) but not the accumulation of the nanoparticles on cell wall surfaces. This study developed model biosurfaces for elucidating fundamental interactions of nanomaterials with cell walls, a main barrier for nanomaterial translocation in plants and algae in the environment, and for the advancement of nanoenabled agriculture with a reduced environmental impact. 

Chloroplast are sites of photosynthesis that have been bioengineered to produce food, biopharmaceuticals, and biomaterials. Current approaches for altering the chloroplast genome rely on inefficient DNA delivery methods, leading to low chloroplast transformation efficiency rates. For algal chloroplasts, there is no modifiable, customizable, and efficient in situ DNA delivery chassis. Herein, we investigated polyethylenimine-coated single-walled carbon nanotubes (PEI-SWCNT) as delivery vehicles for DNA to algal chloroplasts. We examined the impact of PEI-SWCNT charge and PEI polymer size (25k vs 10k) on the uptake into chloroplasts of wildtype and cell wall knockout mutant strains of the green algae Chlamydomonas reinhardtii. To assess the delivery of DNA bound to PEI-SWCNT, we used confocal microscopy and colocalization analysis of chloroplast autofluorescence with fluorophore-labeled single-stranded GT15 DNA. We found that highly charged DNA-PEI25k-SWNCT have a statistically significant higher percentage of DNA colocalization events with algal chloroplasts (22.28% ± 6.42, 1 hr) over 1-3 hours than DNA-PEI10k-SWNCT (7.23% ± 0.68, 1 hr) (P<0.01). We determined the biocompatibility of DNA-PEI-SWCNT through assays for living algae cells, reactive oxygen species (ROS) generation, and in vivo chlorophyll assays. Through these assays, it was shown that algae exposed to DNA-PEI25k-SWCNT (30 fg/cell) and DNA-PEI10k-SWCNT (300 fg/cell) were viable over 4 days and had little impact on oxidative stress levels. DNA coated PEI-SWCNT transiently increased ROS levels within one hour of exposure to nanomaterials (30- 300 fg/cell) both in the wildtype strain and cell-wall knockout strain, followed by ROS decline to normal levels due to reaction with antioxidant glutathione and lipid membranes. PEI-SWCNT can act as biological carriers for delivering biomolecules such as DNA and have the potential to become novel tools for chloroplast biotechnology and synthetic biology. 

Abstract Current practices for delivering agrochemicals are inefficient, with only a fraction reaching the intended targets in plants. The surfaces of nanocarriers are functionalized with sucrose, enabling rapid and efficient foliar delivery into the plant phloem, a vascular tissue that transports sugars, signaling molecules, and agrochemicals through the whole plant. The chemical affinity of sucrose molecules to sugar membrane transporters on the phloem cells enhances the uptake of sucrose‐coated quantum dots (sucQD) and biocompatible carbon dots with β‐cyclodextrin molecular baskets (suc‐β‐CD) that can carry a wide range of agrochemicals. The QD and CD fluorescence emission properties allowed detection and monitoring of rapid translocation (<40 min) in the vasculature of wheat leaves by confocal and epifluorescence microscopy. The suc‐β‐CDs more than doubled the delivery of chemical cargoes into the leaf vascular tissue. Inductively coupled plasma mass spectrometry (ICP‐MS) analysis showed that the fraction of sucQDs loaded into the phloem and transported to roots is over 6.8 times higher than unmodified QDs. The sucrose coating of nanoparticles approach enables unprecedented targeted delivery to roots with ≈70% of phloem‐loaded nanoparticles delivered to roots. The use of plant biorecognition molecules mediated delivery provides an efficient approach for guiding nanocarriers containing agrochemicals to the plant vasculature and whole plants.