Potassium Chloroaurate-Mediated In Vitro Synthesis of Gold Nanoparticles Improved Root Growth by Crosstalk with Sucrose and Nutrient-Dependent Auxin Homeostasis in Arabidopsis thaliana

In a hydroponic system, potassium chloroaurate (KAuCl4) triggers the in vitro sucrose (Suc)-dependent formation of gold nanoparticles (AuNPs). AuNPs stimulate the growth of the root system, but their molecular mechanism has not been deciphered. The root system of Arabidopsis (Arabidopsis thaliana) exhibits developmental plasticity in response to the availability of various nutrients, Suc, and auxin. Here, we showed the roles of Suc, phosphorus (P), and nitrogen (N) in facilitating a AuNPs-mediated increase in root growth. Furthermore, the recuperating effects of KAuCl4 on the natural (IAA) auxin-mediated perturbation of the root system were demonstrated. Arabidopsis seedlings harboring the cell division marker CycB1;1::CDB-GUS provided evidence of the restoration efficacy of KAuCl4 on the IAA-mediated inhibitory effect on meristematic cell proliferation of the primary and lateral roots. Arabidopsis harboring synthetic auxin DR5rev::GFP exhibited a reinstating effect of KAuCl4 on IAA-mediated aberration in auxin subcellular localization in the root. KAuCl4 also exerted significant and differential recuperating effects on the IAA-mediated altered expression of the genes involved in auxin signaling and biosynthetic pathways in roots. Our results highlight the crosstalk between KAuCl4-mediated improved root growth and Suc and nutrient-dependent auxin homeostasis in Arabidopsis.


Introduction
Nanomaterials with novel properties provide spectacular paradigms for a wide range of applications in biological imaging, diagnostics, therapeutics, and sensors [1]. Among metal-based nanomaterials, gold nanoparticles (AuNPs) are attributed to highly stable electronic and optical properties, tunable size, and tailorable surface properties [2]. However, hazardous chemicals used for the synthesis of AuNPs contribute to environmental toxicity [3]. Therefore, the green synthesis of AuNPs is an economically viable and ecofriendly sustainable alternative [4]. Whole biomass or different parts of plants with a wide variety of bioactive compounds have been employed in the rapid synthesis of AuNPs [5]. However, plant extracts are not suitable for determining the morphophysiological and

Quantification of the Morphological Traits
Seedlings (low density) grown on the mesh were gently removed from the hydroponic system and transferred to a Petri dish containing water. Under a stereomicroscope, the shoots and roots were dissected by a sharp scalpel at the shoot-hypocotyl junction. Furthermore, leaves were dissected from the shoot, transferred to an agar (1%, w/v) Petri dish, and scanned at 600 dpi (HP scanner). Scanned images were then used for documenting the total shoot area by a Java-based ImageJ processing program [http://rsb.info.nih.gov/ij/, accessed on 15 June 2021], as previously described [31]. Individual dissected roots were immediately transferred to a 1.5 mL Eppendorf tube containing~1 mL of 70% (v/v) ethanol and stored in a refrigerator at 3-5 • C. This procedure facilitated storing the roots indefinitely till further documentation of the RSA, which is often a laborious and time-consuming process. To reveal the details of RSA, the individual root was gently removed from the Eppendorf tube and transferred to an agar (1%, w/v) Petri dish. Under a stereomicroscope, primary and first-and higher-order lateral roots were spread gently with a fine camel-hair brush to ensure that they did not overlap. Spread-out roots were scanned, and the scanned images were then used for measuring the length of the primary root and the number and length of the first-and higher-order lateral roots using the ImageJ program [31].

Transmission Electron Microscopy (TEM)
The formation of AuNPs in the solution was analyzed by TEM. To make the grid hydrophilic, a 400-mesh Formvar ® carbon-coated copper grid was glow-discharged for 30 s in a Denton DV 502 vacuum evaporator (Moorestown, NJ, USA). The solution was vortexed, sonicated and an aliquot (2 µL) was carefully pipetted onto the grid. The excess aliquot was wicked off with tissue paper after 30 s. TEM micrographs were captured at 120 kV using FEI Tecnai Spirit TEM (Hillsboro, OR, USA).

UV-Vis Spectroscopy
The absorption spectrum of AuNPs in the medium was recorded using a UV-Vis spectrophotometer.

qRT-PCR Analysis
Wild-type seeds were hydroponically grown at a high density (100 seeds/mesh), and the roots were excised, frozen in liquid nitrogen, and stored at −80 • C till further use. Total RNA was isolated from the root tissue using RNeasy Plant Mini Kit (Qiagen) and treated with RQ1 RNase-free DNase (Promega). DNase-treated RNA (~1 µg) was then reverse-transcribed using the RevertAid First Strand cDNA Synthesis kit (Thermo Scientific, Waltham, MA, USA). Real-time PCR was performed in triplicate for each sample using SYBR green, gene-specific primers, and UBQ5 (At3g62250) as an internal control on the 7500 Real-Time PCR System (Applied Biosystems). The relative expression levels of the genes were computed by the 2 −∆∆CT method of relative quantification [32]. Primers used for qRT-PCR are provided (Table S1).

Statistical Analysis
Statistical significance of the difference between mean values was determined using Student's t-test. Different letters on the histograms indicate that means were statistically different at p < 0.05.

Medium Composition Affects the Properties of KAuCl 4 -Mediated In Vitro Synthesis of AuNPs in a Hydroponic System
Several studies have used a hydroponic system containing a nutrient medium supplemented with KAuCl 4 for the synthesis of AuNPs in diverse plant species [6,8,[12][13][14][15]24].Therefore, the effects of different media (deionized H 2 O, one-half-strength Murashige and Skoog (MS) medium [33], nutrient-rich (NR) medium (MS medium + 1.5% Suc (w/v)) supplemented with different concentrations (0-100 ppm) of KAuCl 4 , and Arabidopsis seedlings hydroponically grown in NR medium for 14 d were investigated for color changes, the UV-Vis spectrum, and the in vitro formation of AuNPs as revealed by TEM images ( Figure 1A-C, first-fourth row). Small monodisperse AuNPs (~30 nm) reflect red light, and as the particle size increases, blue light is reflected. Therefore, changes in the color of the solution are a good indicator of the dosage-dependent KAuCl 4 -mediated synthesis of AuNPs. The concentrated stock solution (10,000 ppm) of KAuCl 4 (100 mg) prepared in deionized H 2 O (10 mL) has a distinct golden yellow color. No perceptible development of color was observed upon supplementation of deionized H 2 O with different concentrations of KAuCl 4 (1-100 ppm) ( Figure 1A, first row). However, there were perceptible changes in the color of the MS medium from pale blue to bluish-purple upon supplementation with KAuCl 4 (1 to Nanomaterials 2022, 12, 2099 5 of 23 100 ppm) ( Figure 1A, second row). A similar pattern of color changes was observed when the NR medium was supplemented with different concentrations of KAuCl 4 ( Figure 1A, third row). The results suggest that MS and NR media triggered the formation of AuNPs with different geometries in a KAuCl 4 concentration-dependent manner. Arabidopsis seedlings were hydroponically grown in NR medium supplemented with different concentrations of KAuCl 4, also inducing variable changes in the color of the medium ( Figure 1A, fourth row). The optical properties of AuNPs are sensitive to their sizes, shapes, concentrations, agglomeration states, and refractive indices near their surfaces [34]. Therefore, the surface plasmon resonance of AuNPs could be easily detected in a UV-Vis spectrum as a peak at ~530 nm [35]. Therefore, UV-Vis spectroscopy was used to determine the status of AuNPs in different media supplemented with KAuCl4 (0-100 ppm) ( Figure 1B). As anticipated, no visible peaks could be detected in deionized H2O at any of the KAuCl4 concentrations The optical properties of AuNPs are sensitive to their sizes, shapes, concentrations, agglomeration states, and refractive indices near their surfaces [34]. Therefore, the surface plasmon resonance of AuNPs could be easily detected in a UV-Vis spectrum as a peak at 530 nm [35]. Therefore, UV-Vis spectroscopy was used to determine the status of AuNPs in different media supplemented with KAuCl 4 (0-100 ppm) ( Figure 1B). As anticipated, no visible peaks could be detected in deionized H 2 O at any of the KAuCl 4 concentrations tested ( Figure 1B, first row). The result was consistent with no apparent change in the color of deionized H 2 O upon adding different concentrations of KAuCl 4 ( Figure 1A, first row). Interestingly, there were no detectable peaks in the MS medium supplemented with 1 and 10 ppm KAuCl 4 ( Figure 1B, second row), despite changes in the color of these solutions ( Figure 1A, second row). The non-detection of peaks could be due to the low amounts of AuNPs formed at these concentrations of KAuCl 4 . A peak was detected at 530 nm when MS medium was supplemented with 25 ppm KAuCl 4, and the absorbance value commensurately increased with an increase in the concentration of KAuCl 4 to 100 ppm ( Figure 1B, second row). The addition of 1.5% Suc (w/v) to the MS medium supplemented with 10 ppm KAuCl 4 resulted in the detection of a small peak at 530 nm ( Figure 1B, third row). Whereas the UV-Vis spectra of MS medium with ( Figure 1B, third row) and without Suc ( Figure 1B, second row) and supplemented with 25-100 ppm KAuCl 4 were comparable, albeit with some minor variations in their absorbance values. However, there were significant increases in the absorbance values when wild-type Arabidopsis seedlings were grown in NR medium supplemented with different concentrations (0-100 ppm) of KAuCl 4 for 14 d ( Figure 1B, fourth row) compared with KAuCl 4 (0-100 ppm)-supplemented NR medium ( Figure 1B, third row). UV-Vis spectrum analysis further corroborated the likely effects of exudates from the roots of Arabidopsis on the synthesis of AuNPs in the medium.
Transmission electron microscopy (TEM) is a commonly used technique for the accurate documentation of the geometry and size distribution of AuNPs [36]. Therefore, TEM images were captured to determine the formation of AuNPs in different media supplemented with KAuCl 4 (100 ppm) ( Figure 1C). AuNPs could not be detected in deionized H 2 O ( Figure 1C, first row). The results are consistent with no changes in the color of the solutions and the non-detection of peaks at 530 nm in deionized H 2 O supplemented with KAuCl 4 (100 ppm) ( Figure 1A,B; first row). The distinct formation of AuNPs could be detected in both MS ( Figure 1C, second row) and NR ( Figure 1C, third row) media, and their sizes were 50 ± 2.6 nm and 10 ± 4.2 nm, respectively. The results suggest that the addition of Suc to MS medium triggered the formation of AuNPs smaller in size. The study revealed the presence of AuNPs in KAuCl 4 (100 ppm)-supplemented MS and NR media without any plants growing in them. However, when Arabidopsis seedlings were grown for 14 d in KAuCl 4 (100 ppm)-supplemented NR medium, the sizes of the majority of AuNPs were 12 ± 3.8 nm, of which~20% were >5 nm ( Figure 1C, fourth row). Plant roots continuously secrete an array of chemically diverse compounds into the medium in which they are grown, including sugar alcohols, amino acids, and phenolics [37]. The exudates from the roots of hybrid poplar (Populus deltoides × nigra, DN34) comprising amino acids, enzymes, mucilage, phenolics, and sugars were presumed to be responsible for a reduction of >90% Au(III) ions into AuNPs (ranging in size from 20 to 40 nm) during growth in a hydroponic solution within 2 d [38]. Therefore, it could be speculated that exudates from the roots of the Arabidopsis seedlings potentially contributed to the formation of AuNPs in the KAuCl 4 (100 ppm)-supplemented NR medium. AuNPs formed in hydroponics can bind to the carrier proteins and/or organic chemicals and are taken up by the roots through aquaporins or ion channels, transported apoplastically (through intercellular spaces) or symplastically (through plasmodesmata) between cells, and translocated to the shoot along with nutrients and water [38,39].
The temporal effects of Suc in the NR medium on the solution color and UV-Vis spectrum (12 h, 24 h, and 48 h) and the TEM images (48 h) during KAuCl 4 (100 ppm)mediated synthesis of AuNPs were also investigated ( Figure S1) (see the Supplementary Materials). The changes in the color of the medium from pale blue to bluish-purple ( Figure S1A) and increase in absorbance at~530 nm ( Figure S1B) revealed the temporal effect of Suc in NR medium on KAuCl 4 -mediated synthesis of AuNPs ( Figure S1C). Suc is a non-reducing sugar, and its progressive hydrolysis into reducing glucose, and fructose ( Figure S1D) possibly contributed to the in vitro synthesis of AuNPs.

KAuCl 4 Triggers a Dosage-Dependent Augmented Growth Response
Root system architecture (RSA) comprises the ontogenetically distinct embryonic and post-embryonic development of primary and lateral roots, respectively [17]. RSA exhibits extensive developmental plasticity in response to various environmental cues, including crosstalk effects of various macro-and micro-nutrients, and phytohormone auxin [18,19,21,22]. Therefore, we investigated the dosage-dependent effect of KAuCl 4 on the growth response of Arabidopsis by growing a wild-type in an element contaminationfree and sterile hydroponic system [29] containing a nutrient-rich (NR) medium for 7 d and then transferred to an NR medium supplemented with 0, 1, 10, 25, 50, and 100 ppm KAuCl 4 and grown for a further 7 d. The dosage-dependent effects of KAuCl 4 on the growth responses of Arabidopsis seedlings were documented, which varied from no perceptible effect (1 ppm KAuCl 4 ), augmented (10 ppm KAuCl 4 ), inhibited (25 ppm and 50 ppm KAuCl 4 ) and no growth (100 ppm KAuCl 4 ) compared with the control (0 ppm KAuCl 4 ) ( Figure 2). This study revealed a significant effect of KAuCl 4 on the growth and development of Arabidopsis seedlings in a dosage-dependent manner. Since there was a perceptible augmented growth of Arabidopsis seedlings in the NR medium supplemented with 10 ppm KAuCl 4 (NR.KAuCl 4 ) compared with NR medium (Figure 2), the shoot and root were carefully removed from the hydroponic system, dissected, and separated at the shoot-hypocotyl junction to document their phenotype and quantification of different traits by the ImageJ program ( Figure 3A-G). There was an increase in the number and size of the leaflets of NR.KAuCl 4 compared with NR ( Figure 3A), which led to a significant (p < 0.05) increase in the total shoot area ( Figure 3C). NR.KAuCl 4 also exhibited robust root growth compared with NR ( Figure 3B) due to significant (p < 0.05) increases in the primary root length ( Figure 3D), number and total length of first-and higher-order lateral roots ( Figure 3E,F), which together contributed to a~3-fold increase in the total root length ( Figure 3G). The stimulatory effects of NR.KAuCl 4 on the growth and development of Arabidopsis seedlings were consistent with earlier studies [12,14]. It was evident from the study that KAuCl 4 exerted a biphasic dose-response (10 ppm KAuCl 4 : low-dosagemediated stimulation; 25-100 ppm KAuCl 4 : high-dosage-mediated inhibitory or toxic effect) on the growth and development of the Arabidopsis seedlings. This type of biphasic response to toxic heavy metals is called hormesis, which could be caused by an increase in the production of antioxidants and/or the generation of reactive oxygen species in plants [12,40,41]. Metal nanoparticles at extremely low concentrations (~pg/mL) have also been shown to induce hormetic activation in high-potency homeopathic medicines [42].

KAuCl 4 -Mediated Augmented Growth Response Is Dependent on Suc and Nutrients
Suc and macro-and micro-nutrients play pivotal roles during growth and development of Arabidopsis [18,19,21,22]. Therefore, we investigated the effects of deficiencies of Suc and macronutrients (phosphate [Pi] and nitrogen [N]) and micronutrients (iron [Fe] and zinc [Zn]) on low-dosage KAuCl 4 -mediated augmented growth responses of the shoots and various root traits. Wild-type seedlings were hydroponically grown in an NR medium deprived of Suc (Suc-), Pi (P-), N (N-), Fe (Fe-), and Zn (Zn-), and these media were supplemented with 10 ppm KAuCl 4 (Suc-.KAuCl 4 , P-.KAuCl 4 , N-.KAuCl 4 , Fe-.KAuCl 4 , and Zn-.KAuCl 4 ) for 7 d. The shoot and roots were removed from the hydroponic system, dissected, and separated at the root-hypocotyl junction for documentation of their phenotype and quantification of traits by the ImageJ program ( Figure 4A-F). The growth of the shoots and primary roots was highly attenuated under a Suc-condition ( Figure 4A-C), and there was no development of first-and higher-order lateral roots ( Figure 4D,E), which resulted in a significant (p < 0.05) reduction in the total root length ( Figure 4F) compared with NR, which contained 1.5% (w/v) Suc ( Figure 3A-G). The results are consistent with an earlier study reporting the key role of Suc in the growth and development of Arabidopsis during growth under controlled growth conditions where white fluorescent tubes provide PAR of 80-90 µmol m −2 s −1 , which is not sufficient for making the plants photosynthetically active, and hence supplementation of the medium is mandatory [19]. A Suc-deprived medium supplemented with KAuCl 4 (Suc-.KAuCl 4 ) could not alleviate the inhibitory effects of Suc-on the developmental responses of the shoot and root, and there were no significant (p < 0.05) differences in their values between Suc-and Suc-.KAuCl 4 ( Figure 4A-F). The study revealed that Suc-dependent low-dosage KAuCl 4 -mediated augmented the growth and development of the shoots and roots. rated at the shoot-hypocotyl junction to document their phenotype and quantification of different traits by the ImageJ program ( Figure 3A-G). There was an increase in the number and size of the leaflets of NR.KAuCl4 compared with NR ( Figure 3A), which led to a significant (p < 0.05) increase in the total shoot area ( Figure 3C). NR.KAuCl4 also exhibited robust root growth compared with NR ( Figure 3B) due to significant (p < 0.05) increases in the primary root length ( Figure 3D), number and total length of first-and higher-order lateral roots ( Figure 3E,F), which together contributed to a ~3-fold increase in the total root length ( Figure 3G). The stimulatory effects of NR.KAuCl4 on the growth and development of Arabidopsis seedlings were consistent with earlier studies [12,14]. It was evident from the study that KAuCl4 exerted a biphasic dose-response (10 ppm KAuCl4: low-dosagemediated stimulation; 25-100 ppm KAuCl4: high-dosage-mediated inhibitory or toxic effect) on the growth and development of the Arabidopsis seedlings. This type of biphasic response to toxic heavy metals is called hormesis, which could be caused by an increase in the production of antioxidants and/or the generation of reactive oxygen species in plants [12,40,41]. Metal nanoparticles at extremely low concentrations (~pg/mL) have also been shown to induce hormetic activation in high-potency homeopathic medicines [42].   Wild-type Arabidopsis seedlings were initially grown hydroponically in the NR medium for 7 d and then transferred to the NR medium (control) and NR medium supplemented with 10 ppm KAuCl4 (NR.KAuCl4) and grown for a further 7 d. The seedlings were removed from the hydroponic system, and then (A) shoots and (B) roots were separated under the stereomicroscope and spread on an agar plate (1.0%; w/v) to document their phenotype and quantification of different traits. (C-G) Data are presented for (C) total shoot area, (D) primary root length, (E) the number of first-and higher-order lateral roots, (F) total length of first-and higher-order lateral roots, and (G) total root length. Values (C-G) are means ± SE (n = 12) and different letters on the histograms indicate significant differences (p < 0.05).

KAuCl4-Mediated Augmented Growth Response is Dependent on Suc and Nutrients
Suc and macro-and micro-nutrients play pivotal roles during growth and development of Arabidopsis [18,19,21,22]. Therefore, we investigated the effects of deficiencies of Suc and macronutrients (phosphate  Wild-type Arabidopsis seedlings were initially grown hydroponically in the NR medium for 7 d and then transferred to the NR medium (control) and NR medium supplemented with 10 ppm KAuCl 4 (NR.KAuCl 4 ) and grown for a further 7 d. The seedlings were removed from the hydroponic system, and then (A) shoots and (B) roots were separated under the stereomicroscope and spread on an agar plate (1.0%; w/v) to document their phenotype and quantification of different traits. (C-G) Data are presented for (C) total shoot area, (D) primary root length, (E) the number of firstand higher-order lateral roots, (F) total length of first-and higher-order lateral roots, and (G) total root length. Values (C-G) are means ± SE (n = 12) and different letters on the histograms indicate significant differences (p < 0.05). opment of Arabidopsis during growth under controlled growth conditions where white fluorescent tubes provide PAR of 80-90 µ mol m −2 s −1 , which is not sufficient for making the plants photosynthetically active, and hence supplementation of the medium is mandatory [19]. A Suc-deprived medium supplemented with KAuCl4 (Suc-.KAuCl4) could not alleviate the inhibitory effects of Suc-on the developmental responses of the shoot and root, and there were no significant (p < 0.05) differences in their values between Suc-and Suc-.KAuCl4 ( Figure 4A-F). The study revealed that Suc-dependent low-dosage KAuCl4mediated augmented the growth and development of the shoots and roots.  Among macronutrients, phosphorus (P) is a component of several molecules (ATP, nucleic acids, and phospholipids), playing a key role in signal transduction and various metabolic pathways. Therefore, it is indispensable for the growth and development of plants [43]. Phosphate (Pi) is a bioavailable form of P in soil, and its acquisition by the roots and mobilization to different parts of the plant is mediated by membrane-localized Pi transporters [44]. Pi deficiency (P-) triggered the accumulation of anthocyanin in shoots and significant (p < 0.05) reductions in the total shoot area, primary root length, number and length of first-and higher-order lateral roots, and total root length ( Figure 4A-F) compared with NR containing P+ (1.25 mM KH 2 PO 4 ) ( Figure 3A-G). These findings are coherent with earlier studies [19,22]. A P-medium supplemented with KAuCl 4 (P-.KAuCl 4 ) could not recuperate the inhibitory effects of P-on the developmental responses of the shoot and root, and their values were comparable between P-and P-.KAuCl 4 ( Figure 4A-F). Suc plays a key role in various spatiotemporal morphophysiological and molecular adaptive responses of Arabidopsis during growth under different Pi regimes [19]. Thus, this study highlighted the critical role of Pi in KAuCl 4 -mediated augmented growth responses.
We then investigated whether N availability also influenced the elevated growth responses of Arabidopsis triggered by treatment with low-dosage KAuCl 4 . N is a vital component of chlorophyll, nucleotides, and proteins and is critical for the growth and development of plants [45]. N deficiency (N-) caused leaf chlorosis (insufficient production of chlorophyll), which caused the shoots to become bluish-white ( Figure 4A), and there was a significant (p < 0.05) reduction in the total shoot area ( Figure 4B) compared with NR containing N+ (2.0 mM NH 4 NO 3 and 1.9 mM KNO 3 ) ( Figure 3C). Contrary to P-, the primary root length under N-condition was significantly (p < 0.05) longer ( Figure 4C) than NR ( Figure 3D). The results reveal an antagonistic effect of P-and N-on primary root growth. N-also caused a perceptible and significant (p < 0.05) increase in the number of first-and higher-order lateral roots ( Figure 4D) compared with NR ( Figure 3E). The results suggest the stimulatory effect of N-on the growth of primary and lateral roots, which indicates a systemic foraging strategy that augments the soil volume explored by the root system ( Figure 4C,D). However, N-triggered significant (p < 0.05) reductions in the length of first-and higher-order lateral roots and total root length ( Figure 4E,F) compared to NR ( Figure 3F,G). The differential effects (inhibitory and stimulatory) of N-observed on different shoot and root traits ( Figure 4A-F) were consistent with earlier studies [20,46]. Nmedium supplemented with KAuCl 4 (N-.KAuCl 4 ) could not salvage the inhibitory effects of N-on the developmental responses of the shoots, length of first-and higher-order lateral roots, and total root length ( Figure 4A,B,E,F). The number of first-and higher-order lateral roots was also comparable between N-and N-.KAuCl 4 ( Figure 4D). Interestingly, primary root length was significantly (p < 0.05) longer in N-.KAuCl 4 compared with N-, which suggested a stimulatory effect of KAuCl 4 on primary root growth ( Figure 4C).
Furthermore, the effects of micro-nutrient Fe and Zn availability on the low-dosage KAuCl 4 -mediated elevated growth responses of the shoot and root traits of Arabidopsis were investigated ( Figure 4A-F). Fe is a key component of various metabolic processes, including chlorophyll biosynthesis, photosynthesis, respiration. It is also a component of Fe-binding sites and heme, involved in a multitude of redox reactions, and is a vital mineral nutrient for almost all organisms [47]. Fe also plays a critical role in Pi-deficiencymediated adaptive morphophysiological and molecular responses [22,48]. Although Fe deficiency (Fe-) did not exert any significant influence on shoot color, which remained green ( Figure 4A), there was a significant reduction (p < 0.05) in the total shoot area ( Figure 4B) compared with NR containing Fe+ (0.1 mM FeSO 4 ·7H 2 O and 0.1 mM EDTA) ( Figure 3C). On the contrary, Fe-caused significant (p < 0.05) increases in the primary root length, number, and length of first-and higher-order lateral roots, and total root length ( Figure 4C-F) compared with NR ( Figure 3D-G). The results agree with an earlier study reporting Fe-deficiency-mediated increased primary root length [49]. Compared with Fe-, Fe-.KAuCl 4 did not cause any significant (p < 0.05) increases in total shoot area, primary root length, number, and length of first-and higher-order lateral roots, and total root length ( Figure 4A-F). The results further highlight the role of Fe in regulating the augmented growth responses of the seedlings treated with KAuCl 4 .
After Fe, Zn is the second-most abundant essential transition metal in organisms and acts as a cofactor of many enzymes involved in protein binding, signal transduction, and transcriptional and translational regulation, but it could be toxic when present in excess [50,51]. Zn also exhibits crosstalk with Fe, which is key to adaptive and defense responses during stress mediated by heavy metals in Arabidopsis [51,52]. Zn-caused chlorosis (yellowing of normally green shoots due to a lack of chlorophyll) ( Figure 4A) and significant reductions (p < 0.05) in the total shoot area and primary root length ( Figure 4B,C) compared with NR-containing Zn+ (3 µM ZnSO 4 ·7H 2 O) ( Figure 3C,D). On the contrary, Zn-triggered significant increases (p < 0.05) in the number and length of first-and higherorder lateral roots and total root length ( Figure 4D-F) compared with NR ( Figure 3E-G). The differential responses of primary and lateral roots to Zn-could be attributed to their distinct ontogeny and were consistent with an earlier study [51]. Although total shoot area and the number of first-and higher-order lateral roots were comparable between Zn-and Zn-.KAuCl 4 ( Figure 4A,B,D), there were significant increases (p < 0.05) in the primary root length, length of first-and higher-order lateral roots, and total root length in the latter compared with the former (Figure 4C,E,F). Overall, these results reveal the important and differential roles of Suc and nutrients (P, N, Fe, and Zn) in low-dosage KAuCl 4 (10 ppm)-mediated augmented growth responses of shoots and roots.

Differential Efficacy of KAuCl 4 in Recuperating Natural and Synthetic Auxin-Mediated Modulation in RSA
The metabolism, signaling, and transport of phytohormone auxin orchestrates diverse processes of plant growth and development, including apical dominance, root elongation, and responses to phototropic, gravitropic, and various stresses [53]. In Arabidopsis, there is extensive crosstalk between auxin, Suc, and Pi in regulating the developmental responses of the ontogenetically distinct primary and first-and higher-order lateral roots [19]. Although indole-3-acetic acid (IAA) was identified as the key active auxin in most plant species, many other synthetic compounds, including herbicide 2,4-dichlorophenoxyacetic acid (2,4-D) and 1-naphthaleneacetic acid (NAA) revealed auxin-like activities in bioassays [53]. KAuCl 4 (10 ppm) in NR medium triggered augmented growth in the shoot and root system of Arabidopsis during growth in a hydroponic system (Figure 3).Therefore, to investigate the effects of KAuCl 4 on the developmental responses of the shoot and root system modulated by the treatment with natural (IAA) and synthetic (NAA and 2,4-D) auxins, wild-type Arabidopsis seedlings were hydroponically grown in the NR medium for 7 d.  Figure 5A,B). The results are coherent with earlier studies reporting the inhibitory effects of IAA, NAA, and 2,4-D on the growth and development of Arabidopsis leaves [54][55][56]. When the seedlings were grown in NR.IAA.KAuCl 4 and NR.NAA.KAuCl 4 , shoot area increased significantly (~17-32%) compared with NR.IAA, NR.NAA, respectively ( Figure 5A,B). The study revealed the efficacy of KAuCl 4 in partially recuperating the inhibitory effect of IAA and NAA on shoot growth. However, the shoot area of the seedlings grown in NR.2,4-D and NR.2,4-D.KAuCl 4 was comparable, which suggested the inability of KAuCl 4 in mitigating the 2,4-D-mediated inhibitory effect on shoot growth and development. Furthermore, we investigated the effects of NR.IAA, NR.NAA and NR.2,4-D on the developmental responses of different root traits (primary root length, the number of first-and higher-order lateral roots, total length of first-and higher-order lateral roots, and total root length) ( Figure 5A,C-F). There were significant reductions (~57-60%) in the primary root length of the seedlings grown in NR.IAA, NR.NAA and NR.2,4-D compared with NR ( Figure 5A,C). NR.NAA triggered a significant increase (~2.4-fold) in the number of first-and higher-order lateral roots compared with NR, while NR.IAA and NR.2,4-D did not exert any significant influence on this root trait and were comparable with NR ( Figure 5A,D). The total length of first-and higher-order lateral roots in NR.IAA and NR.2,4-D significantly reduced bỹ 60.0% and~79.0%, respectively, compared with NR, while NR.NAA did not exert any significant influence on this root trait ( Figure 5A,E). The total root length was significantly reduced by~10%,~60.0%, and~73.0%, in NR.NAA, NR.IAA, and NR.2,4-D, respectively, compared with NR ( Figure 5 A, F). We further investigated the efficacy of NR.IAA.KAuCl 4 , NR.NAA.KAuCl 4 , and NR.2,4-D.KAuCl 4 in recuperating the inhibitory effects of NR.IAA, NR.NAA and NR.2,4-D on different root traits. Interestingly, the primary root length of the seedlings grown under NR.IAA.KAuCl 4 was~39% and~3.48-fold higher compared with NR and NR.IAA, respectively ( Figure 5C). NR.NAA.KAuCl 4 could recuperate only~18% primary root length compared with NR.NAA, while NR.2,4-D.KAuCl 4 did not exhibit any recuperation efficacy and was comparable with NR.2,4-D ( Figure 5C). A significant recuperation in the number of first-and higher-order lateral roots was induced by NR.IAA.KAuCl 4 (~29.0%), NR.NAA.KAuCl 4 (~24.0%), and NR.2,4-D.KAuCl 4 (~41.0%) compared with NR.IAA, NR.NAA and NR.2,4-D, respectively ( Figure 5D). Interestingly, the total length of first-and higher-order lateral roots and total root length of NR.IAA.KAuCl 4 exhibited a complete recuperation of NR.IAA-induced inhibitory effects on these traits as evidenced by their values, which were comparable to NR ( Figure 5E,F). Overall, this study provides empirical evidence of the efficacy of KAuCl 4 in mitigating the adverse effects of IAA on different root traits compared with NAA and 2,4-D. Earlier studies also reported the differential diffusion and carrier-mediated influx and efflux rates of IAA, NAA, and 2,4-D and their variable effects on cell division and cell elongation in the cell lines of Nicotiana tabacum [57,58]. Since the efficacy of KAuCl 4 in recuperating the IAA-mediated inhibitory effects on different root traits was relatively more explicit than by NAA and 2,4-D, for the subsequent studies, the role of KAuCl 4 (10 ppm) in mitigating IAA-mediated perturbation of auxin signal transduction pathway was investigated.

KAuCl 4 Recuperates the IAA-Mediated Inhibitory Effect on Primary Root Growth
The activities of a few stem cells residing at the tips of primary and lateral roots control the overall root system architecture [59]. Auxin governs the root apical meristem (RAM) size by regulating cell division [58]. Since KAuCl 4 exhibited a significant recuperation of IAA-mediated inhibitory effects on different root traits ( Figure 5A-F), its role in mitigating IAA-mediated perturbation in the cell division of primary and lateral root tips was investigated ( Figure 6). Eukaryotic cell division is directed by the successive action of cyclin/cyclin-dependent kinase (CYC/CDK) complexes [60]. Mitotic cyclins are under stringent cell-cycle control and accumulate during mitosis, and thus are potent markers for cells undergoing mitosis [61]. In Arabidopsis, mitotic cyclin CycB1;1 is expressed only around the G2/M transition of the cell cycle and is transcriptionally regulated [62]. Arabidopsis CycB1;1, expressed in the G2/M phase of the cell cycle, was translationally fused to Escherichia coli uidA to generate a labile CycB1;1::uidA reporter for the precise spatio-temporal histochemical analysis of the mitotic activity [63]. Transgenic Arabidopsis expressing CycB1;1::uidA has been extensively used to demonstrate the Pi-deficiency-mediated progressive loss of meristematic activity in the roots triggering a determinate developmental program that plays a pivotal role in modulating the RSA [19,22]. The cell-cycle-specific ubiquitin-proteasome-mediated rapid degradation of the green fluorescent protein (GFP) was achieved by fusing the cyclin B destruction box (CDB) motif [64]. These studies revealed the enhanced sensitivity of the CDB-fused reporter genes in accurately deciphering the spatio-temporal regulation of gene expression. Transgenic Arabidopsis harboring a translational fusion of chimeric CycB1;1::CDB-uidA exhibited a tissue-specific post-mitotic expression of CycB1 [26]. Therefore, transgenic Arabidopsis harboring CycB1;1::CDB-uidA was used to examine the efficacy of KAuCl 4 in recuperating IAA-mediated perturbation in the cell division of primary and lateral root tips ( Figure 6). Transgenic Arabidopsis seedlings (7-d-old) were hydroponically grown in NR, NR.KAuCl 4 , NR.IAA, and NR.IAA.KAuCl 4 media for 7 d, and roots were harvested for the histochemical assay of CycB1;1::CDB-uidA expression in primary and lateral root tips. Histochemical analysis revealed robust expression of CycB1;1::CDB-uidA in the tips of the primary root of the seedlings grown in NR, NR.KAuCl 4 . The results demonstrate the non-inhibitory effect of KAuCl 4 on meristematic activity in the primary root tip. On the contrary, there was no expression of CycB1;1::CDB-uidA in the primary root tip of the seedlings grown in NR.IAA. The red arrow indicates the NR.IAA mediated perturbation of meristematic cell proliferation in the primary root tip. Interestingly, the expression of CycB1;1::CDB-uidA in the primary root tip of the seedlings grown in NR.IAA.KAuCl 4 was comparable with NR and NR.KAuCl 4 , highlighting the efficacy of KAuCl 4 in recuperating the inhibitory effect of IAA on meristematic activity in the primary root tip. The results are coherent with the inhibitory and recuperation effects of IAA and KAuCl 4 , respectively, on the primary root growth (Figure 5A,C). In a study on pea (Pisum sativum L.), cobalt (Co) and silver (Ag) ions negated the inhibitory effect induced by ethylene precursor 1-aminocyclopropane-1carboxylic acid (ACC) but did not mitigate the IAA-mediated inhibition or swelling of the roots [65]. The study suggested that the growth inhibition or swelling of the roots triggered by IAA was not mediated by ethylene and provided evidence of the inhibitory effect of IAA on root growth due to altered auxin homeostasis [65]. Therefore, it is presumed that KAuCl 4 exerts a significant influence on the auxin-mediated developmental response of the primary root. Unlike the primary root, the expression of CycB1;1::CDB-uidA in the lateral roots of NR.IAA was not affected and was comparatively more intense compared with NR, NR.KAuCl 4 , and NR.IAA.KAuCl 4 . Primary and lateral roots are embryonic and post-embryonic, respectively, in origin [17], and this could be a plausible explanation for their differential responses to the treatments with IAA and KAuCl 4 . A temporal delay in the loss of meristematic activity in the lateral root tip compared with the primary root tip was also observed in Arabidopsis seedlings deprived of Pi and was attributed to the difference in their ontogeny [22].

KAuCl 4 Affects Root Growth by Modulating the Components of the Auxin Response Pathways
Auxin plays a pivotal role in the growth and development of the root system [66]. The primary root length was significantly reduced during growth in NR.IAA compared with NR, and, interestingly the inhibitory effect of IAA could be circumvented by growing the seedlings in NR.IAA.KAuCl 4 ( Figure 5A,C). This led to an assumption of plausible crosstalk between KAuCl 4 and auxin sensing and signaling pathways. The distribution patterns and levels of IAA are tightly regulated by synthesis, inactivation by conjugating with sugars or amino acids, and transport [67]. High-NH 4 + stress-mediated inhibition of root growth promoted the conjugation of auxin rather than its inhibition [68]. Several genes from Group II of the GRETCHEN HAGEN3 (GH3) family encode IAA-amido synthetases, which conjugate excess IAA to amino acids to maintain auxin homeostasis, and GH3.3 is one of the GH3 enzymes, which could convert chlorinated IAAs to amino acid conjugates in vitro [69]. The electrophoresis mobility shift assay (EMSA) revealed that the WRINKLED1 (WRI1) transcription factor binds to the promoter of GH3.3 and plays a pivotal role in maintaining the homeostasis of the root auxin [70]. In addition, Auxin/IAA (Aux/IAA) proteins are the auxin-sensitive transcriptional repressors of the auxin response genes and mediate various developmental and physiological processes [71]. Among the Aux/IAA genes, IAA6 was shown to play diverse roles, such as controlling the initiation of adventitious roots and mediating drought tolerance by regulating glucosinolate levels [72]. Both GH3.3 and IAA6 are the early auxin response genes [73], and thus potent candidates for determining the effects of KAuCl 4 on their expression. Therefore, qRT-PCR was employed to determine the relative expression levels of GH3.3 and IAA6 in the roots of the seedlings grown in NR, NR.KAuCl 4 , NR.IAA, and NR.IAA.KAuCl 4 media for 7 d ( Figure 7A). Although the relative expression levels of GH3.3 and IAA6 were comparable under NR and NR.KAuCl 4 , NR.IAA triggered significant increases, which were attenuated and became comparable with NR and NR.KAuCl 4 upon treatment with NR.IAA.KAuCl 4 . The results suggest that the attenuation of IAA-mediated early auxin response genes by KAuCl 4 . The likely influence of KAuCl 4 on the IAA-mediated local modulations in auxin subcellular concentrations and localization in the root was assumed. The activity of the synthetic auxin-responsive promoter DR5 comprising tandem direct repeats of 11 bp, including the auxin-responsive TGTCTC element, has been used for the microscopic visualization of the spatial distribution pattern of auxin [74]. A fluorescent variant DR5rev::GFP was constructed as a reliable reporter to monitor auxin response, its dynamics, and cellular levels [27]. Therefore, to investigate the effect of KAuCl 4 on auxin distribution in the primary root tip, transgenic DR5rev::GFP was hydroponically grown in NR, NR.KAuCl 4

KAuCl4 Recuperates the IAA-Mediated Inhibitory Effect on Primary Root Growth
The activities of a few stem cells residing at the tips of primary and lateral roots control the overall root system architecture [59]. Auxin governs the root apical meristem (RAM) size by regulating cell division [58]. Since KAuCl4 exhibited a significant recuperation of IAA-mediated inhibitory effects on different root traits ( Figure 5A-F), its role in mitigating IAA-mediated perturbation in the cell division of primary and lateral root tips

KAuCl4 Affects Root Growth by Modulating the Components of the Auxin Response Pathways
Auxin plays a pivotal role in the growth and development of the root system [66]. The primary root length was significantly reduced during growth in NR.IAA compared with NR, and, interestingly the inhibitory effect of IAA could be circumvented by growing the seedlings in NR.IAA.KAuCl4 ( Figure 5A,C). This led to an assumption of plausible crosstalk between KAuCl4 and auxin sensing and signaling pathways. The distribution patterns and levels of IAA are tightly regulated by synthesis, inactivation by conjugating with sugars or amino acids, and transport [67]. High-NH4 + stress-mediated inhibition of root growth promoted the conjugation of auxin rather than its inhibition [68]. Several genes from Group II of the GRETCHEN HAGEN3 (GH3) family encode IAA-amido synthetases, which conjugate excess IAA to amino acids to maintain auxin homeostasis, and GH3.3 is one of the GH3 enzymes, which could convert chlorinated IAAs to amino acid conjugates in vitro [69]. The electrophoresis mobility shift assay (EMSA) revealed that the WRINKLED1 (WRI1) transcription factor binds to the promoter of GH3.3 and plays a pivotal role in maintaining the homeostasis of the root auxin [70]. In addition, Auxin/IAA (Aux/IAA) proteins are the auxin-sensitive transcriptional repressors of the auxin response genes and mediate various developmental and physiological processes [71]. Among the Aux/IAA genes, IAA6 was shown to play diverse roles, such as controlling the initiation of adventitious roots and mediating drought tolerance by regulating glucosinolate levels [72]. Both GH3.3 and IAA6 are the early auxin response genes [73], and thus potent candidates for determining the effects of KAuCl4 on their expression. Therefore, qRT-PCR was employed to determine the relative expression levels of GH3.3 and IAA6 in the roots of the seedlings grown in NR, NR.KAuCl4, NR.IAA, and NR.IAA.KAuCl4 media for 7 d ( Figure 7A). Although the relative expression levels of GH3.3 and IAA6 were comparable under NR and NR.KAuCl4, NR.IAA triggered significant increases, which were attenuated and became comparable with NR and NR.KAuCl4 upon treatment with NR.IAA.KAuCl4. The results suggest that the attenuation of IAA-mediated early auxin  The activity of the synthetic auxin-responsive promoter DR5 comprising tandem direct repeats of 11 bp, including the auxin-responsive TGTCTC element, has been used for the microscopic visualization of the spatial distribution pattern of auxin [74]. A fluorescent variant DR5rev::GFP was constructed as a reliable reporter to monitor auxin response, its dynamics, and cellular levels. [27]. Therefore, to investigate the effect of KAuCl4 on auxin distribution in the primary root tip, transgenic  We further investigated whether KAuCl4 exerts any influence on the auxin export carriers that could provide a more in-depth understanding of its observed effects on the auxin fluxes in the root tip ( Figure 7B). In Arabidopsis, PIN-FORMED (PIN) are secondary transporter proteins asymmetrically localized within cells; their polarity governs the directionality of intercellular auxin flow and exerts a regulatory influence on an array of diverse developmental responses, including embryogenesis, organogenesis, root and shoot architecture, stem cell maintenance, tissue differentiation, and tropic responses [75]. We further investigated whether KAuCl 4 exerts any influence on the auxin export carriers that could provide a more in-depth understanding of its observed effects on the auxin fluxes in the root tip ( Figure 7B). In Arabidopsis, PIN-FORMED (PIN) are secondary transporter proteins asymmetrically localized within cells; their polarity governs the directionality of intercellular auxin flow and exerts a regulatory influence on an array of diverse developmental responses, including embryogenesis, organogenesis, root and shoot architecture, stem cell maintenance, tissue differentiation, and tropic responses [75]. Among the PIN family members, PIN1-PIN4, PIN6, and PIN7 are PIN auxin export carrier proteins mainly localized at the plasma membrane and facilitate intercellular auxin fluxes [76]. In Arabidopsis root tips, PINs exhibited tissue-specific differential expression in vascular tissue (PIN1), epidermal and outer cortical cells (PIN2), vascular cells and particularly at the basal end of the provascular cells), vascular cells, and largely in the QC and auxin peak region (PIN4), and vascular and columella cells (PIN7) [28]. PIN genes mediate the directional transport of auxin toward the root tip region and their expressions are modulated by both the external and internal cues fluxes [76]. The functional redundancy of PIN proteins and auxin-dependent cross-regulation of PINs expression facilitates auxin gradient stabilization, which potentially contributes to the vigor of the adaptive development responses of plants [77]. Therefore, the recuperating effects of KAuCl 4 on IAA-mediated changes in the spatial expression pattern of PIN1-4 and PIN7 reporter lines in the primary root were investigated. Arabidopsis transgenic seedlings were hydroponically grown in NR, NR.KAuCl 4 , NR.IAA, and NR.IAA.KAuCl 4 media for 7 d, and root tips were excised for histochemical analysis of their GUS activity (Figure 8). Although the expression patterns of PIN1-4 and PIN7 were comparable in NR and NR.KAuCl 4 , in NR.IAA, there were variable reductions in their expression patterns with a relatively more profound effect on pPIN2:GUS, where it was largely confined to the columella cells of the root tip (indicated by black arrows). However, the modulated and differential GUS activities of PIN1-4 and PIN7 in NR.IAA was reinstated in the meristem region of the primary root tip of NR.IAA.KAuCl 4 (indicated by red arrows). The study thus revealed the recuperating influence of KAuCl 4 on IAA-mediated differential perturbation of the spatial expression pattern of PIN1-4 and PIN7 in the primary root tip.
Next, we addressed whether KAuCl 4 exerts any recuperating influence on IAAmediated modulation in the relative expression of the genes involved in the maintenance of auxin homeostasis. An array of functionally diverse genes is involved in the biosynthesis of auxin (Anthranilate synthase alpha1 (ASA1), Anthranilate synthase beta1 (ASB1), Nitrilase1 (NITI), Tryptophan aminotransferases of Arabidopsis1 (TAA1), and YUCCA9 (YUC9)), its influx (Auxin1 (AUX1) and Like-Aux2 (LAX2)) and intracellular transport (PIN-Likes (PILS2, PILS5, and PILS7)), and its signaling (Auxin Response Factor (ARF6 and ARF8)), which coordinately play pivotal roles in regulating tissue-specific auxin homeostasis [53,67,75]. Therefore, Arabidopsis wild-type seedlings were hydroponically grown in NR, NR.KAuCl 4 , NR.IAA, and NR.IAA.KAuCl 4 media for 7 d, roots were harvested, and the relative expression levels of the genes involved in auxin biosynthesis, its influx, intracellular transport, and signaling were assayed by qRT-PCR (Figure 9). The relative expression of all the genes (indicated by blue dots), except TAAI (indicated by red dot), significantly reduced in NR.IAA compared with NR. Interestingly, the relative expression of TAAI was~8-fold higher in NR.IAA than NR. However, the relative expressions of many of these genes were reinstated in NR.IAA.KAuCl 4 and comparable with NR, either completely (TAAI, YUC9, AUX1, LAX2, PILS2, and ARF8) or partially (ASAI, ASB1, PILS7, and ARF6). Notably, the relative expression levels of NIT1 and PILS5 in NR.IAA.KAuCl 4 were significantly higher compared with both NR and NR.IAA. This study revealed that KAuCl 4 recuperated the effects of IAA partially, completely, or with augmentative effects on the relative expression of the functionally diverse genes, which play a pivotal role in the maintenance of auxin homeostasis, which is required for the proper growth and development of plants, including different traits of the root system. A schematic model is presented, highlighting the differential recuperation efficacy of KAuCl 4 on the cascade of functionally distinct genes, which play significant roles in intricate auxin biosynthetic pathway-mediated root development ( Figure 10). found effect on pPIN2:GUS, where it was largely confined to the colume tip (indicated by black arrows). However, the modulated and differen of PIN1-4 and PIN7 in NR.IAA was reinstated in the meristem region o tip of NR.IAA.KAuCl4 (indicated by red arrows). The study thus revea ing influence of KAuCl4 on IAA-mediated differential perturbation of sion pattern of PIN1-4 and PIN7 in the primary root tip. . Differential recuperating effects of KAuCl4 on IAA-mediated effects on the genes involved in the auxin pathway in the root. Wild-type Arabidopsis seedlings were hydroponically grown in the NR medium for 7 d and then transferred to NR, NR.IAA, and NR.IAA.KAuCl4 for a further 7 d, as described in the legend of Figure 5. Roots were harvested, and the relative expression levels of the genes involved in auxin biosynthesis, its influx, intracellular transporters, and signaling were assayed by qRT-PCR. ACT2 was used as an internal control. Values are means ± SE (n = 6) and different letters on the histograms indicate significant differences (p < 0.05). Blue and red dots on the histogram indicate the suppression and induction of the genes, respectively, in response to NR.IAA treatment and their subsequent recuperation upon treatment with NR.IAA.KAuCl4. Figure 9. Differential recuperating effects of KAuCl 4 on IAA-mediated effects on the genes involved in the auxin pathway in the root. Wild-type Arabidopsis seedlings were hydroponically grown in the NR medium for 7 d and then transferred to NR, NR.IAA, and NR.IAA.KAuCl 4 for a further 7 d, as described in the legend of Figure 5. Roots were harvested, and the relative expression levels of the genes involved in auxin biosynthesis, its influx, intracellular transporters, and signaling were assayed by qRT-PCR. ACT2 was used as an internal control. Values are means ± SE (n = 6) and different letters on the histograms indicate significant differences (p < 0.05). Blue and red dots on the histogram indicate the suppression and induction of the genes, respectively, in response to NR.IAA treatment and their subsequent recuperation upon treatment with NR.IAA.KAuCl 4 .

Conclusions
In the present study, the model plant Arabidopsis was used to investigate the effects of the low-dosage (10 ppm) KAuCl4-mediated synthesis of AuNPs on the morphological and molecular responses during growth in a hydroponic system. KAuCl4 stimulated the growth of the shoots and root, which was dependent on the availability of Suc and different nutrients, in particular Pi. Since phytohormone auxin plays a vital role in the growth and development of the root system, we then investigated whether there was any perturbation in auxin sensing and signaling cascades during KAuCl4-mediated stimulation of the root growth. IAA is a natural and active auxin and caused a significant reduction in the growth of the primary root, which was recuperated upon treatment with KAuCl4. The results provide morphological evidence for the effect of KAuCl4 on auxin-mediated developmental responses of the root. Furthermore, the use of Arabidopsis transgenics (CycB1;1::CDB-uidA, DR5rev::GFP, pPIN1:GUS, pPIN2:GUS, pPIN3:GUS, pPIN4:GUS, and pPIN7:GUS) revealed the intricate molecular mechanisms involved in the KAuCl4-mediated mitigation of the IAA-induced inhibitory effects on the root growth. Finally, a qRT- Figure 10. A model depicting the differential effects of KAuCl 4 on the genes involved in the biosynthesis, transport, and signaling of auxin in the root. (A) A schematic diagram of the primary root tip with 11 specific cell types indicated with color codes. ASA1, ASB1, NIT1, AUX1, PILS2, PILS7, ARF6, and ARF8 are expressed in all the cell types. However, TAA1 (vascular initials, quiescent center, cortex/endodermal initials, lateral root cap/epidermal initials, and columella stem cells), YUC9 (vascular initials, quiescent center, cortex/endodermal initials, lateral root cap/epidermal initials, columella stem cells, columella, and lateral root cap), LAX1 (stele cells), and PILS5 (stele cells, endodermis, cortex, quiescent center, and epidermis) show expressions in only some of the specific cell types. (B) Blue and red dots on the genes indicate their suppression and induction, respectively, in response to NR.IAA treatment and their subsequent recuperation upon treatment with NR.IAA.KAuCl 4 . Solid arrows indicate pathways in which the genes, enzymes, or intermediates are known, and dashed arrows indicate pathways that are not well-defined.

Conclusions
In the present study, the model plant Arabidopsis was used to investigate the effects of the low-dosage (10 ppm) KAuCl 4 -mediated synthesis of AuNPs on the morphological and molecular responses during growth in a hydroponic system. KAuCl 4 stimulated the growth of the shoots and root, which was dependent on the availability of Suc and different nutrients, in particular Pi. Since phytohormone auxin plays a vital role in the growth and development of the root system, we then investigated whether there was any perturbation in auxin sensing and signaling cascades during KAuCl 4 -mediated stimulation of the root growth. IAA is a natural and active auxin and caused a significant reduction in the growth of the primary root, which was recuperated upon treatment with KAuCl 4 . The results provide morphological evidence for the effect of KAuCl 4 on auxin-mediated developmental responses of the root. Furthermore, the use of Arabidopsis transgenics (CycB1;1::CDB-uidA, DR5rev::GFP, pPIN1:GUS, pPIN2:GUS, pPIN3:GUS, pPIN4:GUS, and pPIN7:GUS) revealed the intricate molecular mechanisms involved in the KAuCl 4 -mediated mitigation of the IAA-induced inhibitory effects on the root growth. Finally, a qRT-PCR analysis highlighted the efficacy of KAuCl 4 in salvaging the attenuating effects of IAA on cascades of functionally diverse genes involved in the auxin biosynthesis, transport, and signaling. Future studies, employing synchrotron micro-focus X-ray fluorescence (µ-XRF) and micro-X-ray absorption near-edge structure (µ-XANES) [78] could shed more light on the in situ tissue-specific rates of speciation and bioreduction of KAuCl 4 (Au 3+ ) into AuNPs (Au 0 ) in hydroponically grown Arabidopsis under different nutrient regimes.

Supplementary Materials:
The following supporting information can be downloaded at: https:// www.mdpi.com/article/10.3390/nano12122099/s1, Figure S1. Effects of Suc in NR medium on the solution color, UV-vis spectrum, and TEM images during KAuCl 4 -mediated synthesis of AuNPs. NR medium containing Suc was supplemented with KAuCl 4 (100 ppm) and after 12 h, 24 h, and 48 h (A) Color and (B) UV-vis spectrum was documented. (C) TEM images of AuNPs formed in the medium after 48 h. (D) Hydrolysis of non-reducing sucrose into reducing glucose and fructose by the process known as 'inversion of sugar'. Table S1. List of primers used for qRT-PCR.