The Physiological and Biochemical Effects of Phthalic Acids and the Changes of Rhizosphere Fungi Diversity under Continuous Cropping of Lanzhou Lily (Lilium davidii var. unicolor)

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Cui-ping Hua Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China; and University of Chinese Academy of Sciences, Beijing 100049, China

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Zhong-kui Xie Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Zhi-jiang Wu Horticultural Research Institute, Guangxi Academy of Agricultural Sciences, Nanning 530007, China

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Yu-bao Zhang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Zhi-hong Guo Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Yang Qiu Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Le Wang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Ya-jun Wang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Abstract

The autotoxicity of root exudates and the change of rhizosphere soil microbes are two important factors that affect the quality and yield of Lanzhou lily (Lilium davidii var. unicolor). Phthalic acid (PA) is a major autotoxin of the root exudates in Lanzhou lily. In this study, we treated plants with different concentrations of PA from the Lanzhou lily root exudates and then analyzed the effects of autotoxins on fresh weight, shoot height, root length, and Oxygen Radical Absorbance Capacity in root. The diversity of soil fungi in Lanzhou lily soil was analyzed using MiSeq. The results showed that PA induced oxidative stress and oxidative damage of Lanzhou lily roots, improved the level of the membrane lipid peroxidation, reduced the content of antioxidant defense enzyme activity and the nonenzymatic antioxidant, and eventually inhibited the growth of the Lanzhou lily. We found that continuous cropping of Lanzhou lily resulted in an increase in fungal pathogens, such as Fusarium oxysporum in the soil, and reduced the size of plant-beneficial bacteria populations. The results in this study indicate that continuous cropping would damage the regular growth of Lanzhou lily.

Continuous cropping can cause soil-borne disease and crop autotoxicity, resulting in a decline in crop quality. Succession cropping leads to the changes of physical and chemical properties in soil that crops need to grow (Dou et al., 2016). In addition, changes in microbial community composition and the residue of the toxic substances following continuous cropping are also important factors causing the continuous cropping obstacle (Kennedy and Smith, 1995; Zhang et al., 2008). One of the obvious signs of soils with continuous cropping is that the soil is transformed from “bacterial” to “fungal,” and fungi are the main pathogens of plant disease (Ibekwe et al., 2002), including Fusarium, Rhizoctonia, Pythium, Cylindrocarpon, and Phytophthora (Mazzola, 1998).

Lanzhou lily (Lilium davidii var. unicolor) is an important economic crop in northwest China's Ningxia and Gansu provinces; however, continuous cropping has seriously affected the yield and quality of Lanzhou lily bulbs. Fusarium oxysporum is the main pathogenic fungus of Lanzhou lily. Fusarium moniliforme, Fusarium tricinctum, and Fusarium solani can also result in wilt disease (Shang et al., 2014). In addition to the impact of microorganisms, the toxic effects of root exudates cannot be ignored. Many studies have shown that the autotoxicity of root exudates is an important obstacle to continuous cropping. Different concentrations of root exudates have a significant effect on the growth of seedlings of Lanzhou lily. The low-concentration root exudates promote seedlings, whereas high-concentration root exudates repress seedlings (Chen et al., 2016). Studies have shown that PA can accumulate in soil with the increase in duration of monoculture, and PA may be one of the major factors inducing continuous cropping obstacles in Lanzhou lily (Wu et al., 2015). The aim of this study was to investigate the effects of continuous cropping on soil-borne disease and the crop autotoxicity in Lanzhou lily cultivation.

Material and Methods

Experimental materials and sample plot profiles.

A total of 100 Lanzhou lily seed bulbs used in physiological experiments were purchased from lily dealers (Xiguoyuan of Lanzhou City, Gansu Province, China). The seed bulbs were dormancy broken through refrigeration for 60 d at 4 °C. PA was purchased from Tianjin Kexin Chemical Company (Tianjin, China). The test soils were obtained from the surface soil (0 to ≈15 cm) where lilies were grown. After removing the stones of soils by sieving through a 4-mm mesh screen, the soil was mixed evenly and used as the growth medium for Lanzhou lily.

Soil samples for fungal diversity analysis were collected from sites in Xiguoyuan of Lanzhou City, Gansu Province, China (lat. 35°98'N, long. 103°78'E) that had grown lily for many years. Test soils came from different sites, including sites that planted lily for a year (RS1), 2 years (RS2), 3 years (RS3), and a site that was planted with lily and idle for a year (RS0). The experimental plot size was 100 × 100 cm, and there were 36 bulbs per plot. All plots were adjacent to each other to eliminate the variation of soil properties caused by spatial differences. There were three replicate plots in every site. We collected rhizosphere soil from four plants in every plot. Meanwhile, the fertilization program and the planting management measures were consistent in all plots.

Experimental designs.

At the beginning of April, we used a pot experiment to investigate the effect of PA on growth of Lanzhou lily. Lily bulbs were immersed in Imazalil for 1 h to sterilize the surface, and then rinsed with tap water several times before planting; 3-cm lily bulbs were transplanted to the culture basin. Different concentrations of PA solution were used to water soil before planting at 0 (CK), 0.01, 0.05, 0.25, 0.5, and 1 μmol·g−1 (Wu et al., 2015). Each concentration was replicated in three basins, and each basin was planted with five bulbs. During cultivation, plants were watered every 2 days. To maintain soil moisture, culture basins were weighed to determine the amount of water, and the moisture was kept constant at ≈50% of the maximum water-holding capacity. Hoagland nutrient solution was used for half a month to maintain the mineral elements needed for the growth of lily. All the culture basins were cultured in a plastic greenhouse for ≈75 d before reaching the blooming stage. At 75 d after sowing, the root length (cm), plant height (cm), and fresh weight (g) of the lily were measured. Lanzhou lily root and leaf were put into the liquid nitrogen and brought into the refrigerator [temperature (T) = −80 °C] for physiological and biochemical analysis.

Because lily disease usually occurs in the late growth period of the plant, the sampling time of the continuous cropping rhizosphere soil of Lanzhou lily for the study of fungal diversity was determined in the lily bud stage to avoid the influence of disease on fungal community structure in rhizosphere soil of Lanzhou lily. In four different types of plots, which include plots that continuously crop Lanzhou lily 0 year (RS0), 1 year (RS1), 2 years (RS2), and 3 years (RS3), respectively. Three different communities were delineated for each plot. In each plot, the continuous cropping rhizosphere soils of four plants were collected and then the soil was mixed to form a single soil sample. Therefore, a total of 12 rhizosphere soil samples were obtained. The samples were placed in sterile plastic bags, put into the ice box for transport back to the laboratory, and then saved in the refrigerator (T = −80 °C).

Analysis of physiological and biochemical effects of autotoxicity on Lanzhou lily.

SOD (superoxide dismutase), POD (peroxidase), CAT (catalase) activity, H2O2, MDA (Malondialdehyde), total phenol content, and hydroxyl radical scavenging ability were determined by kits (Suzhou coming biological technology co. LTD, Suzhou, Jiangsu Province, China). Methods were applied according to the instructions of kits. The root activity of the 5-cm root tip was determined using the 2, 3, 5-triphenyltetrazolium chloride method (Lindstrom and Nystrom, 1987). Chlorophyll (chlorophyll A and chlorophyll B) and carotenoids were extracted with 80% acetone and their contents (mg/g fresh weight) were determined according to the method of Lichtenthaler and Wellburn (Hartmut, 1983).

Fungal diversity in continuous cropping rhizosphere soil of Lanzhou lily.

The extraction of total DNA from 12 soil samples was carried out using a soil DNA extraction kit (EZNATM soil DNA Kit;

OMEGA Bio-tek, Inc., Doravilla, GA). Each sample was composed of 0.5 g fresh soil. Extracted DNA was assayed for purity and concentration by ethidium bromide staining after 1.0% agarose gel electrophoresis, and the DNA was quantified by Ultra Micro-Spectrophotometer (NanoDrop 2000; Thermo Scientific, Wilmington, DE). Samples were centrifuged and diluted with sterile water to 1 ng/μL for polymerase chain reaction (PCR) amplification. Fungal DNA was amplified by PCR (T100 gradient PCR; Bio-Rad, Hercules, CA), and the ITS1 (internal transcribed spacer 1) fragment was amplified. The primers used were specific primers ITS1F and ITS1R with Barcode, 5′-CTTGGTCATTTAGAGGAAGTAA-3′ and 5′-GCTGCGTTCTTCATCGATGC-3′. The PCR reaction system was 30 μL, containing 15 μL of Phusion Master Mix (2×), 3 μL of primer (2 μM), 10 μL of DNA (1 ng/μL), and 2 μL H2O. PCR was performed using highly efficient and high-fidelity enzymes (Phusion® High-Fidelity PCR Master Mix with GC Buffer; New England Biolabs, Ipswich, MA) to ensure amplification efficiency and accuracy. The amplification procedure was as follows: 98 °C pre-denaturation 1 min; denaturation at 98 °C for 10 s; 50 °C annealing 30 s; 72 °C extension 30 s; cycle 30 times and then 72 °C extension 5 min. The PCR products were subjected to electrophoresis using 2% agarose gel. The PCR products were mixed at the same concentration, and after mixing thoroughly, purified by agarose gel electrophoresis with 2% of 1 × TAE and recycle target bands. The purification kit was supplied by Thermo Scientific’s Gene JET Glue Recycling Kit. The library was constructed using the NEB Next® Ultra DNA Library Prep Kit for Illumina Library Kit of New England Biolabs. The constructed library was tested by Qubit quantification and examination. After passing, MiSeq was used for sequencing. There is a certain percentage of interference data in the raw data obtained by sequencing. To make the result of information analysis more accurate and reliable, the original data were spliced and filtered to obtain clean data. Based on valid data for operational taxonomic units (OTUs), data were clustered based on 97% similarity for species classification analysis. Combined OTU and species annotations were used to obtain the OTUs and classification profiling of each sample. After that, the abundance and diversity index of OTUs were analyzed. At the same time, the statistical analysis of community structure was carried out at each classification level.

Statistical analysis.

The physiological indices of Lanzhou lily under PA stress were analyzed by EXCEL (Microsoft, Redmond, WA). Statistical analysis of fungal in continuous cropping rhizosphere soil: Application of IBM SPSS Statistics 19.0 (IBM Corp., Chicago, IL) one-way analysis of variance for the difference in the relative abundance of OTUs in soils of different continuous cropping years. Principal coordinate analysis uses QIIME for visualization.

Results

Effects of PA on plant organs of Lanzhou lily.

With an increase of PA concentration, the root length, shoot height, and fresh weight of Lanzhou lily showed a decreasing trend, but the decrease was not significant. The root length of the lily was significantly decreased at 0.5 μmol·g−1 (Fig. 1A), and the fresh weight was significantly reduced at 0.25 μmol·g−1 (Fig. 1B), and the shoot height did not show significant difference between all treatments (Fig. 1C). The results show that the response of root growth to PA was more sensitive than that of the aboveground part in the plants. The effect of low concentration of PA was not significant, whereas high concentration had significant inhibitory effect on the growth of Lanzhou lily. The fresh weight of lily bulbs decreased with the increase of PA concentration and decreased significantly at 0.25 μmol·g−1 (Fig. 1D).

Fig. 1.
Fig. 1.

Effect of phthalic acid (PA) on root length (A), fresh weight (B), shoot height (C), and bulb fresh weight (D) of Lanzhou lily plant. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Effects of PA on activities of antioxygen protective enzymes in Lanzhou lily.

With the increase of PA concentration, the activities of SOD, POD, and CAT in the roots of lily showed a tendency to increase first and then decrease. SOD and CAT activities reached the highest value at 0.01 μmol·g−1, and then decreased gradually at 1 μmol·g−1 and reached the lowest value, respectively, at 1.40 and 23.89 U/g (Fig. 2A and C). POD activity reached the highest value at 0.25 μmol·g−1, although the activity was decreased at 1.0 μmol·g−1, and the activity was still higher than that of the control (Fig. 2B).

Fig. 2.
Fig. 2.

Effects of phthalic acid (PA) on enzyme activities of superoxide dismutase (SOD) (A), peroxidase (POD) (B), and catalase (CAT) (C) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Effects of PA on reactive oxygen and free radical scavenging ability of Lanzhou lily roots.

The contents of H2O2 and MDA increased with the increase of PA concentration, and increased significantly at the concentration of 1 μmol·g−1, which was 37.8 μmol·g−1 and 0.6 nmol·g−1, respectively (Fig. 3A and B). With the increase of the concentration of PA, the total phenolic content increased and later decreased, and it was significantly lower than that of the control at the concentration of 0.5 and 1 μmol·g−1 (Fig. 3C). The scavenging rate of hydroxyl radicals was not significantly changed at low concentrations and significantly decreased at high concentrations (no less than 0.5 μmol·g−1) (Fig. 3D).

Fig. 3.
Fig. 3.

Effects of different concentration of phthalic acid (PA) on H2O2 (A), Malondialdehyde (MDA) (B), total phenolics (C), and scavenging rate of hydroxyl radical (D) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Effects of PA on the root’s vigor of lily.

PA can decrease the root vigor of lily, and the decreased range increased with the increase of treatment concentration, while the concentration was 0.5 µmol·g−1, which was a significant decrease (Fig. 4). This indicated that the inhibitory intensity of lily root activity was not significant while the PA concentration was below 0.5 μmol·g−1, and the inhibitory effect was enhanced with the increase in concentration.

Fig. 4.
Fig. 4.

Effects of phthalic acid (PA) on root vigor of Lanzhou lily. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Effects of PA on cytochrome of lily leaves.

Chlorophyll A, chlorophyll B, and carotenoid content decreased with the increase of PA concentration, whereas the decrease was not significant at low concentration, and significant at high concentration. Chlorophyll A, chlorophyll B, and carotenoid contents were significantly lower at 0.5 and 1 μmol·g−1 (Fig. 5). This indicated that the low concentration of PA had little effect on the chlorophyll and carotenoid content of lily leaves, whereas the content of chlorophyll and carotenoid was significantly decreased at high concentration.

Fig. 5.
Fig. 5.

Effects of phthalic acid (PA) on the content of chlorophyll A (A), chlorophyll B (B), and carotenoid (C) of Lanzhou lily leaves. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Sequencing data and fungi profile.

The original tags were split, stitched, intercepted, and filtered, resulting in a total of 621083 valid tags, whereas the number of tags used to build OTUs and obtaining the classified information was 615030. The clustering of the tags obtained 855 OTUs based on 97% similarity (Fig. 6). The number of fungi sequences obtained from RS0, RS1, RS2, and RS3 rhizosphere soil samples were 46,779 ± 16,184, 44,314 ± 14,782, 55,120 ± 5222, and 58,796 ± 1327 (mean ± sd), respectively. The sequence length ranged from 213 to 368 base pairs. The results of sparse curves show that the abundance of OTU (abundance of species) increases with the number of extracted sequences, and the curve tends to increase and reaches an equilibrium state when reaching 25,000 (Fig. 7). Fungi OTUs consisted of five phyla, with Ascomycota (65.1% of the total abundance), followed by Zygomycota (12.3%), Basidiomycota (3.5%), Chytridiomycota (0.09%), and Glomeromycota (0.01%) (Fig. 8).

Fig. 6.
Fig. 6.

Number of Tags and operational taxonomic units (OTUs) recovered from various soil samples. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Fig. 7.
Fig. 7.

Rarefaction curves show the relationship between sampling intensity and the number of recovered operational taxonomic units from soil of lily fields. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Fig. 8.
Fig. 8.

Relative abundances of the main fungal phylum in various soil sample. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Effects of continuous cropping of Lanzhou lily on the diversity and structure of the fungal community.

To determine the change of fungal community diversity, the OTU abundance, Chao1 index, and Shannon index were selected as the diversity index. At the species level, continuous cropping of Lanzhou lily had a significant effect on OTU abundance and Shannon index. At the genus level, continuous lily had no significant effect on OTUs and Chao1, but had a significant effect on the Shannon index (Table 1). Continuous cropping for 2 years (RS2) significantly reduced the Shannon index, whereas for 3 consecutive years (RS3) slightly reduced the Shannon index (Table 1).

Table 1.

Diversity indexes of fungal communities.

Table 1.

The fungal community structure of four different lily fields was compared at the class level (Table 2). Continuous planting lily for 3 years (RS3) significantly increased the relative abundance of Sordariomycetes, Eurotiomycetes, Dothideomycetes, and Pezizomycetes, and 1 and 2 years (RS1 and RS2) did not significantly affect the relative abundance of Sordariomycetes, Eurotiomycetes, and Dothideomycetes (Table 2). RS3 significantly reduced the relative abundance of Agaricomycetes and RS1 significantly increased the relative abundance of Agaricomycetes. Compared with the control fields of no lily cropping (RS0), RS1, RS2, and RS3 had no significant effect on Chytridiomycetes, Tremellomycetes, Leotiomycetes, and others (Table 2).

Table 2.

Relative abundances of the main fungal classes in various soil samples.

Table 2.

Effects of continuous cropping of Lanzhou lily on relative abundance of specific fungi.

The 35 OTUs with the longest sequence number in all soil samples was 78.5% of the total number of sequences, and the first 5 OTUs were Plectosphaerella cucumerina, F. oxysporum, Mortierella alpina, uncultured zygomycete, and Stilbella aciculosa. The relative abundance of F. oxysporum, Penicillium sp., Alternaria longissim, Botrytis cinereaa, and Colletotrichum circinans showed an increasing trend with the lengthening of the years of lily continuous cropping, and all of them increased significantly when the lily was continuous cropping for 3 years. F. oxysporum had a relatively high abundance, reaching 12.3% ± 0.2% (mean ± se) at 3 years, whereas C. circinans had a relatively low abundance, 0.007% ± 0.001%. The relative abundance of Fusarium solani, Fusarium equiseti, and Ilyonectria macrodidyma showed a decreasing trend with the extension of the continuous cropping period. Lily continuous cropping for 2 years (RS2) significantly reduced the relative abundance of F. solani and F. equiseti, whereas the decrease in I. macrodidyma was not significant (Fig. 9).

Fig. 9.
Fig. 9.

Relative abundances of eight groups of fungi: Fusarium oxysporum, Fusarium solani, Fusarium equiseti, Alternaria longissima, Ilyonectria macrodidyma, Botrytis cinerea, Colletotrichum circinans, and Penicillium sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Lily continuous cropping variously reduced the relative abundance of M. alpina, Glomeromycota, Trichoderma sp., and M. alpine and Glomeromycota showed a significant decrease in lily continuous cropping for 2 years (RS2) and 3 years (RS3). The relative abundance of M. alpina reduced from 9.9% ± 1.8% to 4.7% ± 0.9%. Glomeromycota and Trichoderma sp. have a lower relative abundance, and Glomeromycota was only 0.003% at 2 years, Trichoderma sp. was not found in soil samples for lily continuous cropping 1 year (Fig. 10).

Fig. 10.
Fig. 10.

Relative abundances of eight groups of fungi, Mortierella alpina, uncultured Basidiomycota, Glomeromycota, and Trichoderma sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

Citation: HortScience horts 54, 2; 10.21273/HORTSCI13527-18

Discussion

PA significantly inhibited the growth of lily plants by reducing root length, root activity, and leaf photosynthesis, leading to a decrease in lily bulb production (Fig. 1D). The stem root system significantly effects the growth and development of lily shoots (Song, 2017). Meanwhile PA induced oxidative stress and lipid peroxidation of lily roots, increased the content of H2O2 and MDA, and induced the changes of activities of antioxygen protective enzymes and the content of total phenol. Other research demonstrates the phytotoxicity of PA, which inhibited the growth of apple plants by inducing oxidative stress and oxidative damage (Bai et al., 2009).

Reactive oxygen species (O2, H2O2, •OH) and their associated oxidative stress are considered to be an action mechanism for allelochemicals to inhibit plants (Weir et al., 2004). The allelochemicals are mainly formed by the formation of semiquinone free radicals, transferring electrons to molecular oxygen to form superoxide radicals (O2), and then through a series of reactions to become more active hydroxyl radicals (•OH) or oxidation of hydroxyl radicals (HO2•) (Hammond-Kosack and Jones, 1996). Hydroxy radicals are the most active free radicals (Beckman et al., 1990), which act on biological macromolecules, such as proteins, nucleic acids, and lipids, resulting in damage to cell structure and function, leading to metabolic disorders that cause disease. Therefore, the hydroxyl radical scavenging ability is one of the important indicators of antioxidant capacity in plants (Fox, 1984; Husain et al., 1987; Smirnoff and Cumbes, 1989). H2O2 is the most common reactive oxygen molecule (Apel and Hirt, 2004), and as a signal molecule mediates a series of biochemical reactions during plant growth (Deng et al., 2012). MDA is one of the membrane peroxidation products after free radical initiated, often as an indicator of the degree of membrane lipid (Vilaplana et al., 2006). Our results showed that PA increased the contents of H2O2 and MDA in Lanzhou lily roots, indicating that PA induced root oxidative stress, and then damaged the cell membrane structure. With the increase of PA concentration, the contents of H2O2 and MDA increased (Fig. 3A and B), which indicated that the remaining active oxygen in the lily roots increased, and the membrane lipids were damaged by excessive free radicals, thereby elevating levels of membrane lipid peroxide. The scavenging ability of hydroxyl radicals decreased with the increase of PA concentration, which exacerbated injury of free radicals to cells with the increased concentration.

Continuous accumulation of reactive oxygen species under stress can activate plant cell defense genes (Dayan and Watson, 2011), thus the activity of antioxygen protective enzymes to remove reactive oxygen species, for example, SOD, POD, and CAT, ascorbate peroxidase, glutathione reductase, and glutathione peroxidase (Blokhina et al., 2003; Nakano and Asada, 1981). SOD as the main superoxide (•O2) scavenger, which converts the superoxide (•O2) into H2O2 and O2, plays an important role in defense of cell damage (Hasan et al., 2009; Meloni et al., 2003). With the increase of PA concentration, the activities of SOD, POD, and CAT in the roots of lily tended to increase first and then decrease (Fig. 2). The results show that low concentrations of PA could promote the protective effect of root on its own. With an increase in the concentration of PA, the oxidative stress on the lily plant was deepened and the activity of SOD, POD, and CAT decreased. Zhang et al. (2014) studied effects of di-n-butyl phthalate on cucumber and had similar findings (Zhang et al., 2014). Jiang and Yang (2009) also found similar trends in the effects of different concentrations of herbicide on the antioxidant enzyme activity of wheat. Phenolics, as nonenzymatic antioxidants, can scavenge free radicals and resist oxidation (Chimi et al., 1991; Dinis et al., 1994; Sakihama et al., 2002). In our research, as the concentration of PA increased, the total phenolic content also showed a tendency to increase first and then decrease (Fig. 3C). This indicates that the increase of oxygen free radicals leads to an increase of the total phenolic content to remove oxygen free radicals in the low-concentration treatment, whereas excess oxygen free radicals at high concentrations may affect the metabolism of the cells, resulting in a decrease in the total phenolic content.

Root vigor can be used as an indicator of root absorbency and metabolism, and can reflect plant growth ability to a certain extent (Li et al., 2011; Liu et al., 2014). In this study, PA decreased the activity of lily roots. This indicated that PA could inhibit the absorption of water and mineral elements in the soil by affecting the root activity, which in turn affected the normal growth of the Lanzhou lily.

Chloroplast photosynthetic pigments are an important basis for photosynthesis of plants, and their levels reflect the potential of plant photosynthesis to a certain extent (Ahammed et al., 2012). Carotene is an oxygen free radical scavenger on the chloroplast membrane that is associated with photosynthetic centers PSI and PSII to protect chlorophyll from oxidation and reduce free radicals (Demmig-Adams and Adams, 1996; Farquhar and Sharkey, 1982; Reddy et al., 2004). Chlorophyll A, chlorophyll B, and carotenoids decreased with the increase of PA concentration, whereas the decrease was not significant at low concentration (Fig. 5). This indicates that the low concentration of PA is less damaging and does not cause a decrease in the total chlorophyll content. When the content of carotenoids decreased at high-concentration PA, it was difficult to remove excess oxygen free radicals in time. The chlorophyll was oxidized and content decreased significantly, which resulted in the decrease of photosynthetic rate and the decrease of photosynthetic products. This result is consistent with the inhibitory effect of other allelochemicals on plant photosynthesis (Han et al., 2009; Jaleel et al., 2008; Pan et al., 2011; Pinto et al., 2003; Prasad and Zeeshan, 2005).

Continuous cropping is often influenced by autotoxicity. Our study showed that accumulation of PA in rhizosphere soil as under continuous cropping of Lanzhou lily could cause oxidative damage of Lanzhou lily roots and inhibit the growth of the lily. Phthalate esters are the major autotoxic agents of tobacco root exudates that affect seed germination and seedling growth and cause tobacco autotoxicity (Deng et al., 2017).

The change of the fungal community in rhizosphere soil samples from plots with different lily cropping duration was determined by pyrosequencing. The results showed that the diversity of fungal communities decreased trend with an increase in continuous cropping duration. The composition and structure of fungal communities had significant differences among different soil samples.

The diversity of fungal communities in continuous cropping potato plots was significantly lower than that of rotation plots (Manici and Caputo, 2009). In our research, the fungal OTUs contained five phyla, the main is Ascomycota, followed by Zygomycota and Basidiomycota (Fig. 8). This result is consistent with the results of Xingang Zhou and Fengzhi Wu (Zhou and Wu, 2012). They added coumaric acid to the cucumber continuous cropping soil to simulate the change of microbial community. The results showed that the main fungi were Ascomycota and Zygomycota at the phylum level. In our study, the relative abundance of Chytridiomycota (0.09%) and Glomeromycota (0.01%) was the lowest, consistent with the results of Xu et al. (2012), who found that the relative abundance of Chytridiomycota and Glomeromycota was the lowest in all strains, 0.1% and 0.03%, respectively (Xu et al., 2012). At the level of class, Sordariomycetes was the dominant species, and the relative abundance of fungi in the intercropping soil was significantly higher than that in the control. The Dothideomycetes significantly increased in the intercropping for 2 and 3 years, whereas the Agaricomycetes were significantly reduced in the intercropping for 3 years, indicating that the long-term continuous cropping increased Sordariomycetes and Dothideomycetes, and reduced the relative abundance of Agaricomycetes. These results are consistent with those reported by Li et al. (2014). Earlier studies have found that Lanzhou lily root rot is mainly caused by Fusarium spp., including F. oxysporum, F. moniliforme, and F. salani; F. oxysporum has the highest separation frequency and pathogenicity as the main pathogen (Shang et al., 2014). In this study, except for P. cucumerina, the highest absolute abundance of OTU was F. oxysporum, and its relative abundance showed an increasing trend with the extension of the continuous cropping period, and the RS3 significantly higher than that of the RS0, which is 12.3%. In summary, F. oxysporum may be the main pathogen in the Lanzhou lily of this study, and the increase in relative abundance exacerbates the disease. In this study, we found Penicillium sp., A. longissim, B. cinereaa, and C. circinans, and their relative abundance increased with the extension of the continuous cropping period, and increased significantly in plots of continuous cropping for 3 years. Meanwhile, these fungi were reported to cause plant disease (Kiehr et al., 2012; Lou et al., 2013; Thomma, 2003). Therefore, Penicillium sp., A. longissima, B. cinerea, and C. circinans are likely to be the pathogenic fungi of Lanzhou lily. This study also found I. macrodidyma, which has been reported to be an olive tree root rot pathogen (Urbez-Torres et al., 2012). In addition, the study found that the relative abundance of M. alpina, Glomeromycotan fungus, and Trichoderma sp. within the lily continuous cropping showed a downward trend. Glomeromycota (AMF) and Trichoderma sp. are plant-beneficial bacteria that can improve plant resistance (Kubicek et al., 2001; Whipps, 2004). The reduction of these beneficial bacteria may be due to the accumulation of carbon deposited in the rhizosphere soil of Lanzhou lily. The increase of the fungal pathogen population also exacerbates the competition with beneficial bacteria. The reduction of these beneficial bacteria reduces the inhibition in soil-borne pathogens and competition for resources, potentially exacerbating the occurrence of disease in Lanzhou lily.

Conclusion

In conclusion, high concentrations of PA resulted in inhibited the growth of Lanzhou lily, which may be one of the mechanisms that trigger continuous cropping obstacles of Lanzhou lily. With the increase of continuous cropping time, the diversity of fungal communities showed a decreasing trend. The composition and structure of fungal communities had significant differences among different soil samples. F. oxysporum may be the major pathogen in the Lanzhou lily of this study, and the increase in relative abundance exacerbates the decrease in yield and occurrence of disease. Lanzhou lily continuous cropping resulted in an increase in fungal pathogens, and reduced the size of the beneficial bacteria, which may be the main cause of increase in disease of Lanzhou lily.

Literature Cited

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  • Effect of phthalic acid (PA) on root length (A), fresh weight (B), shoot height (C), and bulb fresh weight (D) of Lanzhou lily plant. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

  • Effects of phthalic acid (PA) on enzyme activities of superoxide dismutase (SOD) (A), peroxidase (POD) (B), and catalase (CAT) (C) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Effects of different concentration of phthalic acid (PA) on H2O2 (A), Malondialdehyde (MDA) (B), total phenolics (C), and scavenging rate of hydroxyl radical (D) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Effects of phthalic acid (PA) on root vigor of Lanzhou lily. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

  • Effects of phthalic acid (PA) on the content of chlorophyll A (A), chlorophyll B (B), and carotenoid (C) of Lanzhou lily leaves. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Number of Tags and operational taxonomic units (OTUs) recovered from various soil samples. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Rarefaction curves show the relationship between sampling intensity and the number of recovered operational taxonomic units from soil of lily fields. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of the main fungal phylum in various soil sample. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of eight groups of fungi: Fusarium oxysporum, Fusarium solani, Fusarium equiseti, Alternaria longissima, Ilyonectria macrodidyma, Botrytis cinerea, Colletotrichum circinans, and Penicillium sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of eight groups of fungi, Mortierella alpina, uncultured Basidiomycota, Glomeromycota, and Trichoderma sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Ahammed, G.J., Wang, M.-M., Zhou, Y.-H., Xia, X.-J., Mao, W.-H., Shi, K. & Yu, J.-Q. 2012 The growth, photosynthesis and antioxidant defense responses of five vegetable crops to phenanthrene stress Ecotoxicol. Environ. Saf. 80 132 139

    • Search Google Scholar
    • Export Citation
  • Apel, K. & Hirt, H. 2004 Reactive oxygen species: Metabolism, oxidative stress, and signal transduction Annu. Rev. Plant Biol. 55 373 399

  • Bai, R., Ma, F., Liang, D. & Zhao, X. 2009 Phthalic acid induces oxidative stress and alters the activity of some antioxidant enzymes in roots of Malus prunifolia J. Chem. Ecol. 35 488 494

    • Search Google Scholar
    • Export Citation
  • Beckman, J.S., Beckman, T.W., Chen, J., Marshall, P.A. & Freeman, B.A. 1990 Apparent hydroxyl radical production by peroxynitrite: Implications for endothelial injury from nitric oxide and superoxide Proc. Natl. Acad. Sci. USA 87 1620 1624

    • Search Google Scholar
    • Export Citation
  • Blokhina, O., Virolainen, E. & Fagerstedt, K.V. 2003 Antioxidants, oxidative damage and oxygen deprivation stress: A review Ann. Bot. (Lond.) 91 179 194

    • Search Google Scholar
    • Export Citation
  • Chen, J., Sun, H., Fan, S., Li, L., Shi, G., Qu, X. & Yang, H. 2016 Effect of root exudates from Lanzhou lily on allelopathy of lily seedlings Gansu Nongye Daxue Xuebao 51 64 69

    • Search Google Scholar
    • Export Citation
  • Chimi, H., Cillard, J., Cillard, P. & Rahmani, M. 1991 Peroxyl and hydroxyl radical scavenging activity of some natural phenolic antioxidants J. Amer. Oil Chem. Soc. 68 307 312

    • Search Google Scholar
    • Export Citation
  • Dayan, F.E. & Watson, S.B. 2011 Plant cell membrane as a marker for light-dependent and light-independent herbicide mechanisms of action Pestic. Biochem. Physiol. 101 182 190

    • Search Google Scholar
    • Export Citation
  • Demmig-Adams, B. & Adams, W.W. 1996 The role of xanthophyll cycle carotenoids in the protection of photosynthesis Trends Plant Sci. 1 21 26

  • Deng, J., Zhang, Y., Hu, J., Jiao, J., Hu, F., Li, H. & Zhang, S. 2017 Autotoxicity of phthalate esters in tobacco root exudates: Effects on seed germination and seedling growth Pedosphere 27 1073 1082

    • Search Google Scholar
    • Export Citation
  • Deng, X.P., Cheng, Y.J., Wu, X.B., Kwak, S.S., Chen, W. & Eneji, A.E. 2012 Exogenous hydrogen peroxide positively influences root growth and exogenous hydrogen peroxide positively influences root growth and metabolism in leaves of sweet potato seedlings Austral. J. Crop Sci. 6 1572 1578

    • Search Google Scholar
    • Export Citation
  • Dinis, T.C.P., Madeira, V.M.C. & Almeida, L.M. 1994 Action of phenolic derivatives (acetaminophen, salicylate, and 5-aminosalicylate) as inhibitors of membrane lipid peroxidation and as peroxyl radical scavengers Arch. Biochem. Biophys. 315 161 169

    • Search Google Scholar
    • Export Citation
  • Dou, F., Wright, A.L., Mylavarapu, R.S., Jiang, X. & Matocha, J.E. 2016 Soil enzyme activities and organic matter composition affected by 26 years of continuous cropping Pedosphere 26 618 625

    • Search Google Scholar
    • Export Citation
  • Farquhar, G.D. & Sharkey, T.D. 1982 Stomatal conductance and photosynthesis Annu. Rev. Plant Physiol. Plant Mol. Biol. 33 317 345

  • Fox, R.B. 1984 Prevention of granulocyte-mediated oxidant lung injury in rats by a hydroxyl radical scavenger, dimethyl thiourea J. Clin. Invest. 74 1456 1464

    • Search Google Scholar
    • Export Citation
  • Hammond-Kosack, K.E. & Jones, J.D. 1996 Resistance gene-dependent plant defense responses Plant Cell 8 1773 1791

  • Han, C., Liu, Q. & Yang, Y. 2009 Short-term effects of experimental warming and enhanced ultraviolet-B radiation on photosynthesis and antioxidant defense of Picea asperata seedlings Plant Growth Regulat. 58 153 162

    • Search Google Scholar
    • Export Citation
  • Hasan, S.A., Fariduddin, Q., Ali, B., Hayat, S. & Ahmad, A. 2009 Cadmium: Toxicity and tolerance in plants J. Environ. Biol. 30 165 174

  • Husain, S.R., Cillard, J. & Cillard, P. 1987 Hydroxyl radical scavenging activity of flavonoids Phytochemistry 26 2489 2491

  • Ibekwe, A.M., Kennedy, A.C., Frohne, P.S., Papiernik, S.K., Yang, C.H. & Crowley, D.E. 2002 Microbial diversity along a transect of agronomic zones FEMS Microbiol. Ecol. 39 183 191

    • Search Google Scholar
    • Export Citation
  • Jaleel, C.A., Gopi, R., Manivannan, P. & Panneerselvam, R. 2008 Exogenous application of triadimefon affects the antioxidant defense system of Withania somnifera Dunal Pestic. Biochem. Physiol. 91 170 174

    • Search Google Scholar
    • Export Citation
  • Jiang, L. & Yang, H. 2009 Prometryne-induced oxidative stress and impact on antioxidant enzymes in wheat Ecotoxicol. Environ. Saf. 72 1687 1693

  • Kennedy, A.C. & Smith, K.L. 1995 Soil microbial diversity and the sustainability of agricultural soils Plant Soil 170 75 86

  • Kiehr, M., Delhey, R. & Azpilicueta, A. 2012 Smudge and other diseases of onion caused by Colletotrichum circinans, in southern Argentina Phyton 47 1043 1049

    • Search Google Scholar
    • Export Citation
  • Kubicek, C., Mach, R., Peterbauer, C. & Lorito, M. 2001 Trichoderma: From genes to biocontrol J. Plant Pathol. 83 11 23

  • Li, P., Zhao, Z., Li, Z. & Xue, S. 2011 Root distributions and drought resistance of plantation tree species on the Weibei Loess Plateau in China Afr. J. Agr. Res. 6 4989 4997

    • Search Google Scholar
    • Export Citation
  • Li, X.G., Ding, C.F., Zhang, T.L. & Wang, X.X. 2014 Fungal pathogen accumulation at the expense of plant-beneficial fungi as a consequence of consecutive peanut monoculturing Soil Biol. Biochem. 72 11 18

    • Search Google Scholar
    • Export Citation
  • Lichtenthaler, H.K. & Wellburn, A.R. 1983 Determinations of total carotenoids and chlorophylls a and b of leaf extracts in different solvents[J] Analysis 11 5 591 592

    • Search Google Scholar
    • Export Citation
  • Lindstrom, A. & Nystrom, C. 1987 Seasonal-variation in root hardiness of container-grown Scots pine, Norway spruce, and lodgepole pine-seedlings Can. J. Forest Res. 17 787 793

    • Search Google Scholar
    • Export Citation
  • Liu, J.J., Wei, Z. & Li, J.H. 2014 Effects of copper on leaf membrane structure and root activity of maize seedling Bot. Stud. 55 47

  • Lou, J., Fu, L., Peng, Y. & Zhou, L. 2013 Metabolites from Alternaria fungi and their bioactivities Molecules 18 5891 5935

  • Manici, L.M. & Caputo, F. 2009 Fungal community diversity and soil health in intensive potato cropping systems of the east Po Valley, northern Italy Ann. Appl. Biol. 155 245 258

    • Search Google Scholar
    • Export Citation
  • Mazzola, M. 1998 Elucidation of the microbial complex having a causal role in the development of apple replant disease in Washington Phytopathology 88 930 938

    • Search Google Scholar
    • Export Citation
  • Meloni, D.A., Oliva, M.A., Martinez, C.A. & Cambraia, J. 2003 Photosynthesis and activity of superoxide dismutase, peroxidase and glutathione reductase in cotton under salt stress Environ. Expt. Bot. 49 69 76

    • Search Google Scholar
    • Export Citation
  • Nakano, Y. & Asada, K. 1981 Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts Plant Cell Physiol. 22 867 880

  • Pan, X., Zhang, D., Chen, X., Bao, A. & Li, L. 2011 Antimony accumulation, growth performance, antioxidant defense system and photosynthesis of Zea mays in response to antimony pollution in soil Water Air Soil Pollut. 215 517 523

    • Search Google Scholar
    • Export Citation
  • Pinto, E., Sigaud-Kutner, T.C.S., Leitao, M.A.S., Okamoto, O.K., Morse, D. & Colepicolo, P. 2003 Heavy metal-induced oxidative stress in algae J. Phycol. 39 1008 1018

    • Search Google Scholar
    • Export Citation
  • Prasad, S.M. & Zeeshan, M. 2005 UV-B radiation and cadmium induced changes in growth, photosynthesis, and antioxidant enzymes of cyanobacterium Plectonema boryanum Biol. Plant. 49 229 236

    • Search Google Scholar
    • Export Citation
  • Reddy, A.R., Chaitanya, K.V. & Vivekanandan, M. 2004 Drought-induced responses of photosynthesis and antioxidant metabolism in higher plants J. Plant Physiol. 161 1189 1202

    • Search Google Scholar
    • Export Citation
  • Sakihama, Y., Cohen, M.F., Grace, S.C. & Yamasaki, H. 2002 Plant phenolic antioxidant and prooxidant activities: Phenolics-induced oxidative damage mediated by metals in plants Toxicology 177 67 80

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Cui-ping Hua Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China; and University of Chinese Academy of Sciences, Beijing 100049, China

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Zhong-kui Xie Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Zhi-jiang Wu Horticultural Research Institute, Guangxi Academy of Agricultural Sciences, Nanning 530007, China

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Yu-bao Zhang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Zhi-hong Guo Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Yang Qiu Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Le Wang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Ya-jun Wang Northwest Institute of Eco-environment and Resource, Chinese Academy of Sciences, No. 320 West Donggang Road, Lanzhou, Gansu 730000, China

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Contributor Notes

This study was funded by Ningxia Agricultural Comprehensive Development Office (NTKJ2016-02-02), Major science and technology project of Gansu province (18ZD2NA010), Lanzhou Branch of Chinese Academy of Sciences institutional cooperation program (2BY52BI61), the Key program of Chinese Academy of Sciences (22Y622AM1), and Science and Technology Service Network Initiative of Chinese Academy of Sciences (Grant No. KFJ-STS-QYZD-120). We thank Technician Qiuming He for helping us collect samples and we express our sincere gratitude to Richard T. Conant for his help in the manuscript draft.

These authors contributed equally to this study.

Corresponding author. E-mail: wangyajun@lzb.ac.cn.

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  • Effect of phthalic acid (PA) on root length (A), fresh weight (B), shoot height (C), and bulb fresh weight (D) of Lanzhou lily plant. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

  • Effects of phthalic acid (PA) on enzyme activities of superoxide dismutase (SOD) (A), peroxidase (POD) (B), and catalase (CAT) (C) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Effects of different concentration of phthalic acid (PA) on H2O2 (A), Malondialdehyde (MDA) (B), total phenolics (C), and scavenging rate of hydroxyl radical (D) of Lanzhou lily roots. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Effects of phthalic acid (PA) on root vigor of Lanzhou lily. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test.

  • Effects of phthalic acid (PA) on the content of chlorophyll A (A), chlorophyll B (B), and carotenoid (C) of Lanzhou lily leaves. Data are the means of three replicates. Different letters above error bars indicate significant differences at the 5% level by the Duncan test. FW = fresh weight.

  • Number of Tags and operational taxonomic units (OTUs) recovered from various soil samples. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Rarefaction curves show the relationship between sampling intensity and the number of recovered operational taxonomic units from soil of lily fields. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of the main fungal phylum in various soil sample. RS0.1, RS0.2, and RS0.3 indicate three replicates in RS0; other treatments include the similar replicates. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of eight groups of fungi: Fusarium oxysporum, Fusarium solani, Fusarium equiseti, Alternaria longissima, Ilyonectria macrodidyma, Botrytis cinerea, Colletotrichum circinans, and Penicillium sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

  • Relative abundances of eight groups of fungi, Mortierella alpina, uncultured Basidiomycota, Glomeromycota, and Trichoderma sp. in all of the soil samples. Data are means of three replicates. Letters above error bars indicate significant differences at the 5% level by the Duncan multiple range test. RS0 = control field of no lily cropping; RS1 = field of 1-year, RS2 = field of 2-year, RS3 = field of 3-year consecutive lily cropping.

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