Coronatine Enhances Stalk Bending Resistance of Maize, Thickens the Cell Wall and decreases the Area of the Vascular Bundles

: Coronatine (COR) is a phytotoxin produced by the pathogen Pseudomonas syringae , it has a structure similar to that of jasmonates (JAs), but it is much more active as a plant growth regulator. The goal of this study was to gain more insight into the e ﬀ ect and the mechanism of COR e ﬀ ects on stalk characteristics are related lodging resistance of maize. The agronomic traits, stalk ultrastructure, and endogenous hormones in maize stalks were studied in ﬁeld trails and greenhouses, using hybrid cultivar “Xianyu 335” (XY335), “Zhengdan 958” (ZD958) and inbred line B73 as materials in 2018 and 2019. Di ﬀ erent concentration of COR were sprayed onto maize foliar surfaces at the seven-expanded-leaves (V 7 ) stage. Foliar application with 10 µ Mol L − 1 of COR at the V 7 stage decreased plant and ear height, increased weight and diameter of the basal internodes, and increased penetration strength and stalk bending resistance. Compared to the control treatment, in COR-treated plants, salicylic acid (SA) and jasmonic acid (JA) were decreased signiﬁcantly in stalks. The treatment of 10 µ Mol L − 1 of COR enhanced lignin accumulation, the integrity, and the thickness of cell walls in maize stalks in the early stages of stem growth in the inbred line B73, as revealed by autoﬂuorescence microscopy and scanning electron micrographs. Our results indicated that COR improved stalk bending resistance of maize not only by optimizing stalk morphological characteristics, but also by altering hormone levels, which may led to greater lignin accumulation, thickens cell wall, and decreased the area of vascular bundles. acetic acid—and solvent —acetonitrile with 0.05% acetic acid. Sample measurements were performed with a gradient program that employed the starting conditions of 10% A and 90% B. Within 10 min, a linear gradient to 10% A and 90% B was programmed, and a composition of 90% A and 10% B was kept for 0 min. The ﬂow rate was held at 0.3 mL min − 1 , 5 µ L samples were injected, and then phytohormones were analyzed and quantiﬁed by a Q-Exactive high resolution mass spectrometer (Thermo Scientiﬁc, Waltham, MA, USA). The last step of LC–MS was carried out at the Biomass Bass Laboratory of China Agricultural University.


Introduction
Maize (Zea mays L.) is one of the most important and highest yielding cereal crops in the world, with its annual yield representing approximately 34% of global cereal production [1] and 39% of total grain yield in China [2]. Though the strength of stalk has been improved in maize consistently, lodging is still one of the most important factors for the limitation maize yield to further increase. Lodging causes significant economic losses associated with reduced grain quality, grain yields, and harvesting efficiency. Approximately 5%-20% yield losses in the USA due to crop lodging [3], and a survey indicated that lodging reduces the annual maize yield in Japan by 15%-28% [4]. Sun et al. [5] reported that a 1% increase in lodging decreases maize production by an average of 108 kg ha −1 in China. The poor quality and grain yield caused by lodging have become unavoidable problems in crop production. Thus, one of the challenges of breeding and crop management is to enhance lodging resistance in maize. Breeders have developed and produced new varieties that are shorter and have stronger stalks through biotechnology and conventional breeding, and these have effectively improved the stalk-bending

Morphological Trait and Bending Resistant Strength Plant Height and Ear Height
Five maize plants in central rows were randomly cut at ground level at 20 days after the silking stage in each plot. Plant height was measured with a measuring tape from the base to the top of the tassel; ear height was measured to the first node bearing the ear.

Characteristics of the Third Basal Internode
We sprayed COR onto maize foliar surfaces at the V 7 stage, the seventh internode (the 3rd basal internode on the ground) began to elongate at this time because the internodes below the first four leaves never elongated, and the quality traits of the third to fifth basal internodes exhibited a significantly correlation with lodging resistance of maize, so the third basal internode was used to evaluate the quality of the stalks. Five maize plants in central rows were randomly collected to evaluate the characteristics of the third basal internode. We first removed the leaf blades and excised the third basal internode from the stem of each plant. The length of internode was measured with a ruler. The diameter was measured in the mid internode region by a digital caliper with an accuracy of 0.001 cm. The rind puncture strength was measured with a stalk strength tester (YYD-1, Zhejiang Top Instrument Co. Ltd., Hangzhou, China) by following the methods of Xu et al. [8]. To measure the dry Agronomy 2020, 10, 807 4 of 15 weight of the internodes, they were dried in an oven at 80 • C until they reached a constant weight. The dry weight per cm (g cm −1 ) was calculated as the division of the dry weight (g) of the internode by the length (cm) of the internode. For fresh weight density, we measured the volume of the internode using the draining method. The specific operation was: we added a certain volume of water to a graduated cylinder and recorded the volume v 1 ; after that, we put the internode into the measuring cylinder with water and pressed the internode below the water surface with a glass rod, recording the volume of water and internode v 2 ; the volume of the internode v = v 2 − v 1 . The fresh weight density was calculated by dividing the fresh weight of the internode by the volume of the internode.

Histological Analysis
Three maize plants were harvested from the CK and COR treatments at 5, 10, 15, and 20 days after spraying COR solution in the greenhouse. Sections were cut at the center of the 3rd basal internode from each stalk. Transverse and longitudinal sections were cut by hand with razor blades and then fixed for 24 h in a mixture of 2.5% glutaraldehyde and 2% paraformaldehyde in a 0.1% mol L −1 phosphoric acid buffer at 4 • C and post fixed in 1% osmium tetroxide on ice for 2 h and then washed with a fresh phosphate buffer saline(PBS)solution five times, each time for 20 min and then fixed using O s O 4 for 3 h. The samples were dehydrated in an ethanol series from 45% to 100% (30 min each time); afterwards, the samples were rinsed with isoamyl acetate twice (1 h each) and then vacuum dried. The dried samples were mounted on aluminum stubs, coated with gold using a sputter coater (SPI module, Structure Probe Inc., USA), and then viewed using a scanning electron microscope (S-3400N, SEM, Hitachi, Japan).
The middle of the 3rd basal internode was excised from the stem of each plant, fixed in Carnoy's solution (250 mL L −1 acetic acid with 750 mL L −1 ethanol), and then cross sections from the middle of the 3rd internode were cut by hand using razor blades. Lignin distribution was qualitatively evaluated by using autofluorescence microscopy. Lignin presents broad range of fluorescence emission and is excited with UV light [43]. Thus, lignified cell walls were quantified by autofluorescence microscopy [44]. To visualize lignin autofluorescence, tissue sections were visualized under UV excitation (360 to 390 nm) by a laser scanning microscope with airyscan (LSM 880, Zeiss, Germany). The fluorescence images were collected using a charge-coupled device (CCD)camera.

Phytohormone Quantification
Samples were collected at 5 days after the COR treatments. The leaves and the center of the 3rd basal internode samples were immediately frozen in liquid nitrogen and kept at −80 • C for COR, abscisic acid (ABA), auxin (IAA), jasmonic acid (JA), and salicylic acid (SA) quantification. In brief, three replicates of each frozen samples (100 mg) were ground in liquid nitrogen. We weighed 50 mg of powder into a 1.5 mL tube, an internal standard was added, samples were extracted in sequence, and extracts were centrifuged at 14,000 rpm for 5 min at 4 • C. Then, we extracted 1.2 mL of the lower organic phase that were dried in N 2 at room temperature, and then we resuspended the residue in 0.1 mL of MeOH. Then, the resuspended residue was filtered through a hydrophobic membranes using a nylon filter with a pore size of 0.22 µM.
The analytical conditions were as follows: Water Acquity ultra performance liquid chromatography-Class (Waters Corporation, 34 Maple Street Milford, MA, USA); column, Poreshell EC-120 (3.0 µM and 3.0 mm×100 mm); the mobile phase consisted of solvent A-pure water with 0.05% acetic acid-and solvent -acetonitrile with 0.05% acetic acid. Sample measurements were performed with a gradient program that employed the starting conditions of 10% A and 90% B. Within 10 min, a linear gradient to 10% A and 90% B was programmed, and a composition of 90% A and 10% B was kept for 0 min. The flow rate was held at 0.3 mL min −1 , 5 µL samples were injected, and then phytohormones were analyzed and quantified by a Q-Exactive high resolution mass spectrometer (Thermo Scientific, Waltham, MA, USA). The last step of LC-MS was carried out at the Biomass Bass Laboratory of China Agricultural University.

Measurement of Pushing Resistance
Lodging resistance was assessed using the measured of pushing resistance, which was carried out on the bottom part of the stalk following the method of Kashiwagi and Ishimaru [45]. At 20 days after the silking stage, the portable crop prostrate tester (AI-JGQD-01) was set perpendicularly at the basal internode of a maize stem about 50 cm above ground level, and the pushing resistance was measuring when plants were pushed to an angle from the vertical (Figure 1). The data collected by the hand-held equipment in the field when the system started to measure and the real-time curve of pressure and angle were plotted at the bottom of the interface.
performed with a gradient program that employed the starting conditions of 10% A and 90% B. Within 10 min, a linear gradient to 10% A and 90% B was programmed, and a composition of 90% A and 10% B was kept for 0 min. The flow rate was held at 0.3 mL min −1 , 5 µL samples were injected, and then phytohormones were analyzed and quantified by a Q-Exactive high resolution mass spectrometer (Thermo Scientific, Waltham, MA, USA). The last step of LC-MS was carried out at the Biomass Bass Laboratory of China Agricultural University.

Measurement of Pushing Resistance
Lodging resistance was assessed using the measured of pushing resistance, which was carried out on the bottom part of the stalk following the method of Kashiwagi and Ishimaru [45]. At 20 days after the silking stage, the portable crop prostrate tester (AI-JGQD-01) was set perpendicularly at the basal internode of a maize stem about 50 cm above ground level, and the pushing resistance was measuring when plants were pushed to an angle from the vertical (Figure 1). The data collected by the hand-held equipment in the field when the system started to measure and the real-time curve of pressure and angle were plotted at the bottom of the interface.

Statistical Analyses
Data processing in all treatments was performed by Data Processing System software 9.50 (DPS) and Microsoft Excel 2003 . Analyses of variance were judged by the least significant differences test using a 0.05 level of significance. Data plotting was performed with SigmaPlot 10.0. Pictures were quantitatively measured by ImageJ.

Plant Height and Ear Height
Maize plant and ear heights responded to COR application in a manner dependent on dose in both cultivars in each year of growth. Shorter plant and ear heights were observed under COR treatments compared to the untreated control plants in the field trial. The plant height in COR1-, COR10-, COR30-, and COR60-treated ZD958 maize plants was reduced significantly by 3.0%, 9.8%, 42.5%, and 58.0%, respectively, in 2019, while reductions of 8.5%, 11.5%, 51.2%, and 29.5%, respectively, occurred in 2018. Upon COR1, COR10, COR30, and COR60 treatments, XY335 maize plant height was significantly reduced by 1.3%, 16.9%, 38.6%, and 40.2%, respectively, in 2019, while

Statistical Analyses
Data processing in all treatments was performed by Data Processing System software 9.50 (DPS) and Microsoft Excel 2003. Analyses of variance were judged by the least significant differences test using a 0.05 level of significance. Data plotting was performed with SigmaPlot 10.0. Pictures were quantitatively measured by ImageJ.

Plant Height and Ear Height
Maize plant and ear heights responded to COR application in a manner dependent on dose in both cultivars in each year of growth. Shorter plant and ear heights were observed under COR treatments compared to the untreated control plants in the field trial. The plant height in COR1-, COR10-, COR30-, and COR60-treated ZD958 maize plants was reduced significantly by 3.0%, 9.8%, 42.5%, and 58.0%, respectively, in 2019, while reductions of 8.5%, 11.5%, 51.2%, and 29.5%, respectively, occurred in 2018. Upon COR1, COR10, COR30, and COR60 treatments, XY335 maize plant height was significantly reduced by 1.3%, 16.9%, 38.6%, and 40.2%, respectively, in 2019, while reductions of 1.7%, 9.1%, 28.2%, and 52.1%, respectively, were observed in 2018. Moreover, the ear height of ZD958 in COR1-, COR10-, COR30-, and COR60-treated plant heights was significantly reduced by 1.0%, 22 Figure 2). Taken together, with higher concentrations of COR, plant and ear heights also decreased more severely. However, when the COR concentration was greater than or equal to 30 µMol L −1 ( 30 µMol L −1 ), the growth of maize plants was poisoned, over-dwarfed the plants, weak stem, and reduced biological yield, resulting in a smaller panicle or even no panicle of maize plants ( Figure 2). The results indicated that COR had a concentration-dependent manner effect on maize plant during COR treatment with various concentrations.
27.1%, 48.2%, and 48.1% in 2018 respective to the increasing concentration series of COR treatment. The ear height of XY335 was significantly reduced by 26.7%, 29.0%, 36.3%, and 45.3% in 2019, respectively, and 4.9%, 22.5%, 39.2%, and 47.0% in 2018 over that of the control plants ( Figure 2). Taken together, with higher concentrations of COR, plant and ear heights also decreased more severely. However, when the COR concentration was greater than or equal to 30 µmol L −1 (≧30 µmol L −1 ), the growth of maize plants was poisoned, over-dwarfed the plants, weak stem, and reduced biological yield, resulting in a smaller panicle or even no panicle of maize plants ( Figure 2). The results indicated that COR had a concentration-dependent manner effect on maize plant during COR treatment with various concentrations.

Agronomic Traits of the 3rd Basal Internodes
To evaluate the alterations in the agronomic traits of maize stems in response to different concentrations of COR, the morphological characteristics and physical strength of the third basal internodes were assessed. The length of third basal internodes reduced with increasing concentrations of COR. Compared to the control treatment, COR1 had little effect on the length of the 3rd basal internode; COR10 reduced the internode length of ZD958 and XY335 by 19.5% and 10.0% in 2019 and 11.0% and 6.1% in 2018, respectively; COR30 substantially reduced the internode length of ZD958 and XY335 by 20.0% and 9.8% in 2019 and 36.4% and 5.2% in 2018, respectively; COR60 reduced the internode length of ZD958 and XY335 by 8.6% and 7.9% in 2019 and 0.1% and 6.3% in 2018, respectively. The degree of reduction of the third basal internode length with COR60 was similar to that with COR30. The average length of the third basal internodes for XY335 was higher than that of ZD958 by 53.6% and 31.4% in 2018 and 2019, respectively (Table 1).

Agronomic Traits of the 3rd Basal Internodes
To evaluate the alterations in the agronomic traits of maize stems in response to different concentrations of COR, the morphological characteristics and physical strength of the third basal internodes were assessed. The length of third basal internodes reduced with increasing concentrations of COR. Compared to the control treatment, COR1 had little effect on the length of the 3rd basal internode; COR10 reduced the internode length of ZD958 and XY335 by 19.5% and 10.0% in 2019 and 11.0% and 6.1% in 2018, respectively; COR30 substantially reduced the internode length of ZD958 and XY335 by 20.0% and 9.8% in 2019 and 36.4% and 5.2% in 2018, respectively; COR60 reduced the internode length of ZD958 and XY335 by 8.6% and 7.9% in 2019 and 0.1% and 6.3% in 2018, respectively. The degree of reduction of the third basal internode length with COR60 was similar to that with COR30. The average length of the third basal internodes for XY335 was higher than that of ZD958 by 53.6% and 31.4% in 2018 and 2019, respectively (Table 1).
The diameter of the third basal internodes was significantly increased with the COR10 treatment. Compared to the control treatment, the diameter of the third basal internode of ZD958 and XY335 with COR10 was greater by 12.3% and 10.1% in 2019 and 8.7%, and 3.7% in 2018, respectively (Table 1). However, the higher concentrations of COR (≥30 µMol −1 ) reduced the diameter of internodes, showing inhibitory effects.
Agronomy 2020, 10, 807 8 of 15 The rind puncture strength of the third basal internodes was significantly affected by COR concentrations. Increasing COR concentration resulted in a rind puncture strength of the third internodes that first increased and then decreased. Compared to the control treatment, the rind puncture strength of the COR1 and COR10 treatments was higher, but the rind puncture strength of COR30 and COR60 was lower for both cultivars in each year. Rind puncture strength was ranked as COR10 > COR1 > CK > COR30 > COR60 in XY335 in 2019 and COR1 > COR10 > CK > COR30 > COR60 in XY335 in 2018 and ZD958 in both years.

Detection of Endogenous Hormone Contents
We detected the contents of the endogenous hormones in the stems and leaves of maize treated with COR. Our results (Figure 3) showed that compared to the control plants, COR was still present in leaves but was not detected in stems five days after 10 µMol L −1 of COR solution was sprayed on maize foliar surfaces. These results indicated that there was a remnant of COR in the leaf, but there was no residual of COR in the stem at five days after COR application to the foliage surfaces. After COR treatment, the SA content increased and reached a significant level in the leaves, while the ABA and IAA contents decreased slightly at statistically insignificant levels. In the stem, SA and JA levels decreased significantly, while the IAA content decreased and ABA content increased to an insignificant level in the COR treatment group.
Agronomy 2020, 10, x; doi: FOR PEER REVIEW www.mdpi.com/journal/agronomy third internode was higher by 4.4%, 20.6%, 28.0%, and 30.9% in 2019 and 7.1%, 1.4%, 2.8%, and 25.7% in 2018 than that of control plants, respectively (Table 1). The highest tested concentration of COR (COR60) resulted in the greatest effect on the dry weight per cm of the third basal internodes among all the treatments except for ZD958 in 2018 (Table 1). Additionally, the trend of fresh weight density increased with increasing concentrations of COR (Table 1), with the fresh weight density of ZD958 being significantly higher than that of XY335 in cultivars.
The rind puncture strength of the third basal internodes was significantly affected by COR concentrations. Increasing COR concentration resulted in a rind puncture strength of the third internodes that first increased and then decreased. Compared to the control treatment, the rind puncture strength of the COR1 and COR10 treatments was higher, but the rind puncture strength of COR30 and COR60 was lower for both cultivars in each year. Rind puncture strength was ranked as COR10 > COR1 > CK > COR30 > COR60 in XY335 in 2019 and COR1 > COR10 > CK > COR30 > COR60 in XY335 in 2018 and ZD958 in both years.

Detection of Endogenous Hormone Contents
We detected the contents of the endogenous hormones in the stems and leaves of maize treated with COR. Our results (Figure 3) showed that compared to the control plants, COR was still present in leaves but was not detected in stems five days after 10 µmol L −1 of COR solution was sprayed on maize foliar surfaces. These results indicated that there was a remnant of COR in the leaf, but there was no residual of COR in the stem at five days after COR application to the foliage surfaces. After COR treatment, the SA content increased and reached a significant level in the leaves, while the ABA and IAA contents decreased slightly at statistically insignificant levels. In the stem, SA and JA levels decreased significantly, while the IAA content decreased and ABA content increased to an insignificant level in the COR treatment group.

Lignin Distribution in Stalks Identified by Autofluorescence Microscopy
In our experimental study, lignin distribution and content in stem transverse sections were qualitatively measured by autofluorescence microscopy during stem development to investigate the lignin accumulation patterns in maize stems. The UV-excited fluorescence in the transverse sections of a maize inbred line B73 stem is shown in Figure 4. Lignin accumulation gradually increased in the stem tissues after 10 µMol L −1 of COR treatment, with minimal lignification observed at five days and strong lignification observed at 20 days after COR treatment. Compared to the control treatment, a strong intensity of autofluorescence was detected in vascular bundles at an early stage (5-10 days) after treatments in the COR treatment group. Lignin was mainly deposited in the cell walls of vascular bundle sheaths, xylem, and sclerenchyma. The lignin fluorescence in CK plants increased as stem development progressed and was higher than that of the COR-treated plants at 15 days after treatment. Lignin fluorescence was found to be stronger in the CK stems at 20 days compared to Agronomy 2020, 10, 807 9 of 15 the COR treatment. Our results demonstrated that COR enhanced lignin accumulation at the early stages of stem development, but COR treatment was not conducive to the deposition of lignin in the later stage.
strong lignification observed at 20 days after COR treatment. Compared to the control treatment, a strong intensity of autofluorescence was detected in vascular bundles at an early stage (5-10 days) after treatments in the COR treatment group. Lignin was mainly deposited in the cell walls of vascular bundle sheaths, xylem, and sclerenchyma. The lignin fluorescence in CK plants increased as stem development progressed and was higher than that of the COR-treated plants at 15 days after treatment. Lignin fluorescence was found to be stronger in the CK stems at 20 days compared to the COR treatment. Our results demonstrated that COR enhanced lignin accumulation at the early stages of stem development, but COR treatment was not conducive to the deposition of lignin in the later stage.  Figure 5 shows scanning electron micrographs of the cross-section of vascular bundles. The vascular bundle consists of protoxylem vessels (PX), metaxylem vessels (MX), phloem tissue (Ph), and the vascular bundle sheath (VBS). Compared to the control treatment, the area of the vascular bundle cross-sectional gradually decreased in COR treatment, mainly due to VBS thickening and a gradual decrease in PX area (Table 2). In addition, compared to the COR treatment plants, in the CK group, the cell wells were thinner and there were many holes (a natural part of anatomy) in the cell well at five days after the treatment ( Figure 5). This suggests that COR treatment bolstered the integrity and the thickness of the cell wall at the early stages of stem development.

Scanning Electron Micrographs of Vascular Bundles and Cell Walls
By using scanning electron microscopy, we also observed the cell wells of the maize stem in longitudinal sections and transverse sections at 15 days after COR treatment. Figure 6 shows the  Figure 5 shows scanning electron micrographs of the cross-section of vascular bundles. The vascular bundle consists of protoxylem vessels (PX), metaxylem vessels (MX), phloem tissue (Ph), and the vascular bundle sheath (VBS). Compared to the control treatment, the area of the vascular bundle cross-sectional gradually decreased in COR treatment, mainly due to VBS thickening and a gradual decrease in PX area (Table 2). In addition, compared to the COR treatment plants, in the CK group, the cell wells were thinner and there were many holes (a natural part of anatomy) in the cell well at five days after the treatment ( Figure 5). This suggests that COR treatment bolstered the integrity and the thickness of the cell wall at the early stages of stem development.

Scanning Electron Micrographs of Vascular Bundles and Cell Walls
By using scanning electron microscopy, we also observed the cell wells of the maize stem in longitudinal sections and transverse sections at 15 days after COR treatment. Figure 6 shows the longitudinal section and the transverse section. Under ×350X magnification, we observed that the tension of the cell walls was relatively looser in COR treatment than that in CK treatment. Meanwhile, the cell walls in the CK treatment were tightly arranged.

Pushing Resistance of Maize Stalks
The real-time curve of pressure and angle is shown in Figure 7. The pressure stress increased when the tilt angle was pushed from the vertical. In both cultivars, COR10 treatment increased the pressure stress. The pressure stress was higher in ZD958 than that of in XY335 when plants were pushed to an angle from the vertical. Our results clearly indicated that the resistance to the bending of the stalk in ZD958 was higher than that of XY335, and COR10 could enhance the stalk bending resistance.
Agronomy 2020, 10, x FOR PEER REVIEW 10 of 16 longitudinal section and the transverse section. Under ×350X magnification, we observed that the tension of the cell walls was relatively looser in COR treatment than that in CK treatment. Meanwhile, the cell walls in the CK treatment were tightly arranged.

Pushing Resistance of Maize Stalks
The real-time curve of pressure and angle is shown in Figure 7. the pressure stress increased when the tilt angle was pushed from the vertical. In both cultivars, COR10 treatment increased the pressure stress. The pressure stress was higher in ZD958 than that of in XY335 when plants were  Table 2. The effects of COR on the areas of the vascular bundles and protoxylem vessel in Figure 5.

Areas (µm 2 )
Treatments 5d 10d 15d 20 longitudinal section and the transverse section. Under ×350X magnification, we observed that the tension of the cell walls was relatively looser in COR treatment than that in CK treatment. Meanwhile, the cell walls in the CK treatment were tightly arranged.

Pushing Resistance of Maize Stalks
The real-time curve of pressure and angle is shown in Figure 7. the pressure stress increased when the tilt angle was pushed from the vertical. In both cultivars, COR10 treatment increased the pressure stress. The pressure stress was higher in ZD958 than that of in XY335 when plants were pushed to an angle from the vertical. Our results clearly indicated that the resistance to the bending of the stalk in ZD958 was higher than that of XY335, and COR10 could enhance the stalk bending resistance.

Discussion
There are many factors that contribute to the lodging of maize, including plant morphology, plant density, stalk quality, root characteristics, genomic characteristics, damage caused by pests and diseases, water and fertilizers management, and environmental factors [46]. Enhancing the mechanical strength of stalks and controlling the morphological characteristics of plants are the major targets for increasing the lodging resistance of maize [6,38]. Previous research has shown that dry weight per cm and stem diameter are key indicators for evaluating lodging resistance in crops, as greater stem diameter and density and shorter basal internodes can enhance stalk bending resistance [47][48][49]. Reducing stem diameter, dry weight and lignin content in basal internodes in wheat and rice decrease lodging resistance [38,50]. In our study, our data indicated that spraying appropriate concentrations of COR onto maize foliar surfaces had significant effects on basal internodes and could enhance stalk lodging resistance. However, the higher concentration COR (30 µmol L −1 ) showed inhibitory effects on internode diameter, over-dwarfed the plants, and decreased the rind puncture strength, indicating that COR had a dosage-dependent effect on maize plant; this is in agreement with previous research [20,21]. Therefore, an appropriate COR concentration should be determined before using in the field. Based on our results, we suggest that COR should be applied at a concentration of 10 µmol L −1 as a foliar application at the V7 stage of maize to enhance stalk bending resistance.
The elastic modulus of the basal internodes is also strongly influenced by lodging resistance. It is a useful way to enhance the stalk bending of plants through increased the elastic modulus of fiber bundles in the basal internode by increasing the thickness of the cell wall and decreasing the area ratio of transverse sectional area occupied by phloem and vessels tissue [41]. Khanna [51] found that increasing the number of vascular bundles could enhance lodging resistance in wheat. However, other studies have reported that the vascular bundle number was not significantly related to the stalk strength in wheat [52] or barley [53]. Decreasing the diameter of vascular bundles could increase the stiffness of vascular bundles [54]. These conflicting results showed that the relationship between the anatomy characteristics of vascular bundles and stalk lodging resistance are still unclear. Considering the anatomy characteristics of vascular bundles, the two primary xylem vessels-MX and PX-are distinct in development and function. PX is differentiated first, and the spiral patterning of the

Discussion
There are many factors that contribute to the lodging of maize, including plant morphology, plant density, stalk quality, root characteristics, genomic characteristics, damage caused by pests and diseases, water and fertilizers management, and environmental factors [46]. Enhancing the mechanical strength of stalks and controlling the morphological characteristics of plants are the major targets for increasing the lodging resistance of maize [6,38]. Previous research has shown that dry weight per cm and stem diameter are key indicators for evaluating lodging resistance in crops, as greater stem diameter and density and shorter basal internodes can enhance stalk bending resistance [47][48][49]. Reducing stem diameter, dry weight and lignin content in basal internodes in wheat and rice decrease lodging resistance [38,50]. In our study, our data indicated that spraying appropriate concentrations of COR onto maize foliar surfaces had significant effects on basal internodes and could enhance stalk lodging resistance. However, the higher concentration COR (30 µMol L −1 ) showed inhibitory effects on internode diameter, over-dwarfed the plants, and decreased the rind puncture strength, indicating that COR had a dosage-dependent effect on maize plant; this is in agreement with previous research [20,21]. Therefore, an appropriate COR concentration should be determined before using in the field. Based on our results, we suggest that COR should be applied at a concentration of 10 µMol L −1 as a foliar application at the V 7 stage of maize to enhance stalk bending resistance.
The elastic modulus of the basal internodes is also strongly influenced by lodging resistance. It is a useful way to enhance the stalk bending of plants through increased the elastic modulus of fiber bundles in the basal internode by increasing the thickness of the cell wall and decreasing the area ratio of transverse sectional area occupied by phloem and vessels tissue [41]. Khanna [51] found that increasing the number of vascular bundles could enhance lodging resistance in wheat. However, other studies have reported that the vascular bundle number was not significantly related to the stalk strength in wheat [52] or barley [53]. Decreasing the diameter of vascular bundles could increase the stiffness of vascular bundles [54]. These conflicting results showed that the relationship between the anatomy characteristics of vascular bundles and stalk lodging resistance are still unclear. Considering the anatomy characteristics of vascular bundles, the two primary xylem vessels-MX and PX-are distinct in development and function. PX is differentiated first, and the spiral patterning of the secondary cell walls of PX allows for cell elongation; these cells are the dominant conductive elements for water in plants. In contrast, the secondary cell walls of MX are differentiated later in development and can be characterized by a rigid pitted pattern after the cessation of elongation growth [55]. In the present research, COR reduced the area of PX and the area of the vascular bundle ( Figure 6). It can be inferred that such variations of the anatomy characteristics of vascular bundles influence the spiral patterning and the secondary cell walls of PX, which could inhibit cell elongation, shorten the internode length of maize stalk, and be a vital factor of evaluating the lodging resistance in crop plants. The elastic modulus of vascular bundles may also be changed by fertilization strategies [37] or by using phytohormones [56]. Phytohormones have a vital role in plant cell elongation and cell wall biosynthesis and modification [57]. IAA leads to the inhibition of cell elongation [58] and has a negative effect on lignification [59]. SA mediates cell growth by controlling cell enlargement, endoreduplication, and cell division [60]. Application JA could freeze the cell mitosis, but the effect was sensitive to the phase of cell cycle [61]. Our results suggested that COR significantly decreased SA and JA in the stem, which may directly or indirectly regulate cell wall biosynthesis and manipulate the regulation of cell division, cell differentiation, and cell elongation. Together, these hormone-controlled processes contribute to changing the thicknesses of the cell wall and the area of vascular bundles, and they might be involved in affecting the diameter of internodes. Previous studies also have indicated that COR can thicken the cell wall of mesocotyl parenchyma [62]. It has been reported that phytohormones play important roles in the organization of the plant microtubule network [63], which is important for cell wall biosynthesis. However, the molecular mechanism of COR mediated the accumulation of lignin, and the synthesis of cell walls remains largely unclear and requires further investigation.
Plant growth depends on cell division and cell expansion/elongation. Maize internode elongation mainly depends on cell elongation and cell division. Our results suggest that COR could influence lignin accumulation and thicken cell walls in the early stage of internode elongation. A previous study indicated that cell walls play a crucial role in controlling the shape and size of a cell [64]. Cell wall synthesis, organization, and modification modulate cell volume and vacuolar turgor pressure, which have effects on plant cell growth [65]. The key requirement for cellular elongation is cell wall remodeling enzymes to loosen the cell wall by rearranging cell wall matrix polymers [65]. In our study, a higher level of lignin accumulation induced by COR-treated may have contributed to the lignification of cell walls (Figure 4). Increasing lignin deposition was found to thicken the cell walls, and plant tissues became stiffer. Similar results were demonstrated by Liu [63], who reported that COR could thicken cell walls. Lignin is mainly deposited in secondary cell walls, and it not only provides structural rigidity to the plant but also plays a vital role in mechanical support, nutrient and water transport, and plant pathogen defense [66]. Lignification thickens cell walls and could lead to the cessation of cell elongation or cell division in COR-treated internodes, thereby altering the chemical composition and anatomical features of the stem during the early stages of internode elongation and therefore changing agronomic traits and enhancing stalk bending resistance.

Conclusions
COR has a dose-dependent effect on the strength of maize stalks. Spraying an appropriate concentration of COR at the V 7 stage could increase the diameter, density, and rind penetration strength of basal internodes, thus improving stalk bending resistance. COR was found to alter hormone levels, manipulate cell wall biosynthesis and modification, decrease the area of protoxylem and vascular bundles, and increase the cell wall thickness, all of which may lead to the early cessation of cell division and cell elongation to reduce stem internode length and plant height.