Our study was conducted in August of 2020 at four sites in Zhejiang Province, east China: Ningbo (29°54′ N, 121°26′ E; 4 m asl), Xiangshan (29°22′ N, 121°45′ E; 135 m asl), Taizhou (28°52′ N, 120°55′ E; 211 m asl), and Wenzhou (27°56′ N, 120°42′ E; 5 m asl). These sites were all heavily invaded by S. canadensis. There is a typical subtropical monsoon climate in these sites, with a mean annual temperature (MAT) of 16°C – 19°C, and a mean annual precipitation (MAP) of 1200 – 1900 mm. In each site, farmland, wasteland, and roadside were chosen as study habitats, where soil N contents and the proportions of different N forms may be different (Li et al., 2014; Zhou et al., 2015; Zhao et al., 2017). The farmlands in our study sites were planted with Ipomoea batatas or Brassica napus, and all were invaded by S. canadensis. At the wasteland and roadside habitats in the four sites, we selected herbaceous communities with less human interference, in which the dominant native plants mainly included A. lavandulaefolia, Setaria viridis, Paspalum thunbergii, Humulus scandens, Geranium carolinianum, and Ranunculus cantoniensis. We found numerous patches of coexisting S. canadensis and A. lavandulaefolia in the three habitats of the four study sites during a field survey. We selected A. lavandulaefolia as the native plant to compare with S. canadensis for the following reasons: (1) Both belong to the Asteraceae family, sharing similar evolutionary history; (2) more importantly, they commonly co-occur in the wild in southern China (EBFC, 1985). According to the local residents, S. canadensis began to invade in the four areas in 2005. The characteristics of rhizosphere soils of S. canadensis and A. lavandulaefolia in the three habitats of the four sites are summarized in Table S1 .

At each habitat in each study site, three 1.0 m × 1.0 m quadrats (> 5 m apart from one another) were randomly established, where the coverage of S. canadensis was greater than 90%. Nearby each S. canadensis quadrat, we established a 1.0 m × 1.0 m quadrat with more than 90% coverage of A. lavandulaefolia. The paired quadrats of S. canadensis and A. lavandulaefolia within each habitat were less than 5 m apart from each other in order to ensure similar soil physico-chemical properties.

Three individuals of S. canadensis or A. lavandulaefolia (> 15 cm apart from one another) with similar size were selected for ¹⁵N labeling in each quadrat, and one for each of the three N treatments: ¹⁵NH₄ ⁺, ¹⁵NO₃ ^-, and control. The ¹⁵N-labeled ammonium chloride (NH₄Cl, ¹⁵N 99.12 atom%) and sodium nitrate (NaNO₃, ¹⁵N 99.21 atom%) were purchased from Shanghai Engineering Research Center for Stable Isotopes (Shanghai, China). Each plant for the control treatment was treated with 48 mL deionized water with no N addition. A given mass of ¹⁵NH₄Cl and ¹⁵NaNO₃ (containing 360 μg ¹⁵N) was weighed, dissolved in 48 mL deionized water (0.5 mmol ¹⁵N L^-1), and applied for each individual plant. The nitrification inhibitor dicyandiamide (DCD) was added to each sampled plant (75 mg plant^-1; corresponding to ≈50 µg g^-1 soil) in order to prevent potential ammonium oxidation (Zhu et al., 2019). To ensure homogeneous distribution of the labeling solutions in the soil around each labeled plant, we used the Rhizon Cera soil solution sampler (Rhizosphere Research Products, Wageningen, Netherlands) instead of a traditional sterile syringe needle to inject the isotopic solution.

The front of the sampler is a 10-cm long porous polyester tube, with a diameter of 5 mm and many uniform pores of 0.15 μm. This sampler could release the labeling solution or deionized water evenly into different parts of the soil when pressure is carefully applied to the syringe. The effectiveness of the sampler had been confirmed in our preliminary experiments using trypan blue dye. We further determined the minimal number of the samplers needed, the volume of the solution needed to add into each sampler, and its insertion depth into soil in order to achieve a homogeneous distribution of the solution in the soil around each labeled plant. Based on these preliminary experiments, the labeling method was as follows: carefully removing plant litter from soil surface around each target plant, and putting a circular injection template on the ground with the plant as the center ( Figure S1 ). The injection template was a hardboard circle (11 cm in diameter), which matches the outside diameter of the Luoyang shovel. On the template, a circle with a radius of 2.5 cm was drawn and six holes (0.5 bore diameter) were made evenly along the circumference. Then we drilled six holes into the soil up to 10 cm depth around the target plant, inserted the sampler with 8 mL labeling solution into each hole to the depth of 10 cm, and finally injected the solution into soil. Using this method, the solution was evenly dispersed in the soil inside a cylinder with a height of 15 cm and a radius of 5 cm centered around the plant.

Forty-eight hours after ¹⁵N labeling, plant material and rhizosphere soil were collected for each labeled or control plant. We first clipped each plant at 1 cm above ground, then dug out the soil (including roots; not necessary to collect all roots of the plant, just the roots within the range of ¹⁵N labeling) around the plant with a radius of 5 cm and to a depth of 15 cm using a specialized soil auger (Luoyang shovel, 10 cm in internal diameter). The shoot and soil of each plant were immediately put into plastic self-sealing bags, respectively, which were stored in an ice box. The plant and soil samples collected every day were transported back to our laboratory on the same day. Rhizosphere soil for each soil sample was collected using a hand-shaking method in the laboratory (Zhao et al., 2020), passed through a 2-mm sieve, and separated into two portions. One portion (≈10 g) was air-dried at room temperature for determination of total N and C contents, while the other portion was stored at 4°C for determination of NH₄ ⁺ and NO₃ ^- contents. The roots in each soil sample were collected, rinsed immediately with water, soaked in 0.5 mmol L^-1 CaCl₂ solution for 5 min, and then rinsed thoroughly with deionized water to remove the ¹⁵N adsorbed on the root surface (Cui et al., 2017). The roots and the shoot from each sample plant were oven-dried at 60°C to constant weight, and then ground to a fine powder for determination of total N and δ¹⁵N contents using a ball mill (GT200, Grinder, China) with 1400 r min^-1 for 30 s.

Linear mixed-effects model was conducted to test the effects of habitats, species, and their interactions on each variable. Habitats, species, and their interactions were used as fixed factors, and quadrats nested within study sites as random factors. The models were performed in R (version 4.2.2) using the ‘lme’ and ‘anova.lme’ functions of the ‘nlme’ package (Pinheiro et al., 2016). One-way analysis of variance (ANOVA) was conducted to detect the difference in each variable for the same species (S. canadensis or A. lavandulaefolia) among different habitats. Independent samples t-test was used to detect the difference in each variable between S. canadensis and A. lavandulaefolia in the same habitat, and the difference between β _NF and 0. These analyses were carried out using SPSS (version 2018; SPSS Inc., Chicago, IL, USA). The relationships between the values of f _NH4 ⁺ or β _NH4 ⁺ versus soil DIN contents or the ratios of NO₃ ^- to NH₄ ⁺, and those between total biomass or root to shoot ratios versus the values of f _NH4 ⁺ or β _NH4 ⁺ were analyzed for each species with standardized major axis (SMA) regression, using the ‘smatr’ package in R (Warton et al., 2012). We first tested whether the slopes of SMA regressions were significantly different between S. canadensis and A. lavandulaefolia; if not, we further tested the interspecific differences in intercepts and the shift along the common slope. Before all above-mentioned analyses, the preferences for different soil N forms were quantile-transformed, and the other variables were log-transformed in order to meet the assumptions of normality (Shapiro-Wilk tests) and homoscedasticity (Levene’s test). Linear regression analysis was used to examine the significance of the correlations between root to shoot ratios versus total biomass, and those between the contents of total dissolved inorganic nitrogen, NO₃ ^- and NH₄ ⁺ versus root to shoot ratios for each species.

Total biomass, root biomass, and root to shoot ratio were significantly affected by habitats, species, and their interactions (P< 0.05; Table S2 ). Total biomass of S. canadensis was the highest in the farmland, and the lowest in the roadside (P< 0.05; Figure 1A ). In contrast, total biomass of A. lavandulaefolia was the highest in the roadside, and the lowest in the wasteland (P< 0.05). Total biomass were significantly higher for the invasive relative to the native species in all three habitats (P< 0.05).

For both species, root biomass was similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05; Figure 1B ). Root biomass was significantly higher for the invasive relative to the native species in all three habitats (P< 0.05).

For both species, root to shoot ratios were the highest in the roadside, and the lowest in the farmland (P< 0.05; Figure 1C ). Root to shoot ratios were significantly lower for the invasive relative to the native species in all three habitats (P< 0.05).

The contents of NO₃ ^-, NH₄ ⁺ and DIN in rhizosphere soil, and the ratio of NO₃ ^- to NH₄ ⁺ were all significantly influenced by habitats, species, and their interactions (P< 0.05; Table S3 ). For both the invasive and native species, soil NO₃ ^- contents were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05; Figure 2A ). The invader was significantly higher in soil NO₃ ^- content than A. lavandulaefolia in the farmland (P< 0.05), but similar in the wasteland and roadside.

For S. canadensis, NH₄ ⁺ contents in rhizosphere soils were similar in the farmland and wasteland, both significantly higher than that in the roadside (P< 0.05; Figure 2B ). For A. lavandulaefolia, soil NH₄ ⁺ content was significantly higher in the wasteland than in the farmland (P< 0.05), which were not significantly different with that in the roadside (P > 0.05). The invader was significantly higher in soil NH₄ ⁺ content than A. lavandulaefolia in the farmland, while lower in the wasteland and roadside (P< 0.05).

For S. canadensis, DIN contents in rhizosphere soils were similar in all three habitats (P > 0.05; Figure 2C ). For A. lavandulaefolia, soil DIN contents were similar in the roadside and wasteland, both significantly higher than that in the farmland (P< 0.05). Similarly as in soil NH₄ ⁺ content, the invader was significantly higher in soil DIN content than A. lavandulaefolia in the farmland, while lower in the wasteland and roadside (P< 0.05).

For S. canadensis, the ratios of NO₃ ^- to NH₄ ⁺ in rhizosphere soils were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05; Figure 2D ). For A. lavandulaefolia, the ratio of NO₃ ^- to NH₄ ⁺ was the highest in the roadside, followed by the farmland and wasteland, respectively (P< 0.05). Compared with A. lavandulaefolia, S. canadensis showed a significantly higher ratio of NO₃ ^- to NH₄ ⁺ in the wasteland and roadside (P< 0.05), but not in the farmland (P > 0.05).

The uptakes of soil NO₃ ^-, NH₄ ⁺ and DIN per quadrat, and the uptake ratio of NO₃ ^- to NH₄ ⁺ were all significantly influenced by habitats, species, and their interactions (P< 0.05; Table S4 ). For S. canadensis, the uptake of soil NO₃ ^- per quadrat was the highest in the roadside, followed by the farmland and wasteland, respectively (P< 0.05; Figure 3A ). For A. lavandulaefolia, the uptakes of soil NO₃ ^- per quadrat were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05). The uptakes of soil NO₃ ^- per quadrat were significantly higher for the invasive relative to the native species in all three habitats (P< 0.05).

In the farmland and wasteland compared with the roadside, the uptake of soil NH₄ ⁺ per quadrat were significantly higher for S. canadensis, while significantly lower for A. lavandulaefolia (P< 0.05; Figure 3B ). Compared with A. lavandulaefolia, S. canadensis showed significantly higher NH₄ ⁺ uptake per quadrat in the farmland and wasteland (P< 0.05), but not in the roadside (P > 0.05).

For S. canadensis, the uptakes of soil DIN per quadrat were similar in the farmland and roadside, both significantly higher than that in the wasteland (P< 0.05; Figure 3C ). For A. lavandulaefolia, the uptakes of soil DIN per quadrat were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05). The uptakes of soil DIN per quadrat were significantly higher for the invasive relative to the native species in all three habitats (P< 0.05).

For S. canadensis, the uptake ratios of soil NO₃ ^- to NH₄ ⁺ was highest in the roadside, followed by the farmland and wasteland, respectively (P< 0.05; Figure 3D ). For A. lavandulaefolia, the uptake ratios of NO₃ ^- to NH₄ ⁺ were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05). Compared with A. lavandulaefolia, S. canadensis showed significantly lower uptake ratios of NO₃ ^- to NH₄ ⁺ in the farmland and wasteland (P< 0.05), but not in the roadside (P > 0.05).

The values of f _NO3 ^- and f _NH4 ⁺ were significantly influenced by habitats, species, and their interactions (P< 0.05; Table S6 ). For S. canadensis, the value of f _NO3 ^- was the highest in the roadside, followed by the farmland and wasteland, respectively (P< 0.05; Figure 4A ). For A. lavandulaefolia, the values of f _NO3 ^- were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05). Compared with A. lavandulaefolia, S. canadensis showed significantly lower f _NO3 ^- values in the farmland and wasteland (P< 0.05), but not in the roadside (P > 0.05).

For S. canadensis, the value of f _NH4 ⁺ was the highest in the wasteland, followed by the farmland and roadside, respectively (P< 0.05; Figure 4B ). For A. lavandulaefolia, the values of f _NH4 ⁺ were similar in the farmland and wasteland, both significantly higher than that in the roadside (P< 0.05). Compared with A. lavandulaefolia, S. canadensis showed significantly higher f _NH4 ⁺ values in the farmland and wasteland (P< 0.05), but not in the roadside (P< 0.05).

For S. canadensis, there was no significant difference between β _NO3 ^- or β _NH4 ⁺ versus zero in the farmland (P > 0.05), indicating no significant preference for N forms; in the wasteland the value of β _NO3 ^- was significantly lower than zero and the value of β _NH4 ⁺ was significantly higher than zero, indicating a preference for NH₄ ⁺; and in the roadside the value of β _NO3 ^- was significantly higher than zero and the value of β _NH4 ⁺ was significantly lower than zero, showing a preference for NO₃ ^-. For A. lavandulaefolia, the values of β _NO3 ^- were significantly higher than zero in all three habitats, while the values of β _NH4 ⁺ were significantly lower than zero, indicating a consistent preference for NO₃ ^-.

The values of β _NO3 ^- and β _NH4 ⁺ were significantly influenced by habitats, species, and their interactions (P< 0.05; Table S7 ). For both species, the values of β _NO3 ^- were similar in the farmland and wasteland, both significantly lower than that in the roadside (P< 0.05; Figure 5A ). For the values of β _NH4 ⁺, however, both species were significantly lower in the roadside than in the farmland and wasteland (P< 0.05; Figure 5B ).

Compared with A. lavandulaefolia, S. canadensis showed significantly lower values of β _NO3 ^- and significantly higher values of β _NH4 ⁺ in the farmland and wasteland (P< 0.05). There was no significant difference in the values of β _NO3 ^- and β _NH4 ⁺ between the two species in the roadside (P > 0.05).

The percentage similarity between plant uptake patterns of different N forms and their pattern of availability in rhizosphere soil was significantly influenced by habitats and species (P< 0.05; Table S8 ), while the effect of the interaction of these factors was not significant (P = 0.798).

For both species, the vales of percentage similarity were similar in the farmland and wasteland, both significantly higher than that in the roadside (P< 0.05; Figure 6 ). Compared with A. lavandulaefolia, S. canadensis showed significantly higher value of percentage similarity in the farmland (P< 0.05), but not in the wasteland and roadside(P > 0.05).

For both the invasive and native species, the values of f _NH4 ⁺ or β _NH4 ⁺ decreased significantly with increasing soil DIN contents or the ratios of NO₃ ^- to NH₄ ⁺ except the values of f _NH4 ⁺ with soil DIN contents for A. lavandulaefolia (marginally significant) (P< 0.05; Figure 7 ). The SMA slope of the relationship between the values of β _NH4 ⁺ and soil DIN contents was significantly lower for S. canadensis than for A. lavandulaefolia (P< 0.05), indicating that the values of β _NH4 ⁺ was more strongly influenced by change in soil DIN contents for the invasive relative to the native species. The SMA slopes of the relationship between the values of f _NH4 ⁺ or β _NH4 ⁺ and the ratios of NO₃ ^- to NH₄ ⁺ were also significantly lower for S. canadensis than for A. lavandulaefolia (P< 0.05), indicating that the values of f _NH4 ⁺ and β _NH4 ⁺ were more strongly influenced by change in the ratios of NO₃ ^- to NH₄ ⁺ for the invasive relative to the native species.

Total biomass increased significantly with the increase of the values of f _NH4 ⁺ or β _NH4 ⁺ for S. canadensis (P< 0.001; Figure 8A, B ), while decreased significantly for A. lavandulaefolia. The absolute values of the SMA slope of the relationship were significantly lower for S. canadensis than for A. lavandulaefolia.

For both species, the root to shoot ratios significantly decreased with the increase of the values of f _NH4 ⁺ or β _NH4 ⁺ (P< 0.01; Figure 8C, D ). The SMA slopes of the relationships between root to shoot ratios and the values of f _NH4 ⁺ were not significantly different between the two species (P > 0.05). The value of the y-intercept of the relationship was significantly higher for A. lavandulaefolia than for S. canadensis (P< 0.05), indicating that root to shoot ratio was significantly lower in S. canadensis than in A. lavandulaefolia under the same value of f _NH4 ⁺. The shift along the common slope of the relationship was also significantly different between the two plants (P< 0.05), with S. canadensis showing higher values of f _NH4 ⁺ but lower root to shoot ratios, and A. lavandulaefolia showing lower values of f _NH4 ⁺ but higher root to shoot ratios. The SMA slope of the relationship between root to shoot ratios and the values of β _NH4 ⁺ was significantly higher for S. canadensis than for A. lavandulaefolia (P< 0.05), indicating that root to shoot ratios were less influenced by the change in the values of β _NH4 ⁺ for the invasive relative to the native species.

In the farmland and wasteland, the invader had both higher DIN uptake rates ( Figure S2C ) and total root biomass per quadrat ( Figure 1B ), both contributing to its higher N uptake. James et al. (2009) also found that N uptake rates were significantly higher in three invasive perennial forbs than in six native perennial grasses and forbs in both heterogeneous and homogeneous nutrient soils. In the roadside, however, the higher total root biomass per quadrat was the main reason for the higher N uptake of the invader, where its DIN uptake rate was lower than that of A. lavandulaefolia ( Figure S2C ). Of course, we do not know whether the invader could absorb more organic N than A. lavandulaefolia in the roadside, which warrants further study. A recent study showed that S. canadensis could absorb organic N, particularly in habitats rich in free amino acids (Yu et al., 2016). Similarly, for S. canadensis, total biomass was the lowest in the roadside among the habitats ( Figure 1A ), while the uptake of soil DIN in the roadside was similar with that in the farmland, and higher than that in the wasteland. These results indicate that the invader may also absorb organic N in the wasteland and farmland. In general, the organic N content in the farmland is higher than that in the wasteland and roadside (Lv et al., 2011; Quan et al., 2022). Specific root morphology, high carbon allocation to roots, and a flexible N uptake strategy may all contribute to the high N uptake rates of invasive plants (James et al., 2009; Hewins and Hyatt, 2010; Mozdzer et al., 2010; Hu et al., 2019). In our study, the higher plasticity in soil N form uptake and the preference for the dominant soil N form contributed to the higher N uptake rate of S. canadensis (see below). In addition, the invasive relative to the native species also showed more stable N uptake rates across all three habitats ( Figure S2C ). The stability of DIN uptake may contribute to adaptation of the invader to temporal and spatial fluctuations in soil N availability, and thus to invasion success of the invader in the different habitats.

The higher total root biomass of the invasive relative to the native species was due to its faster growth (i.e., higher total biomass), rather than to the interspecific difference in root to shoot ratio. The invader had significantly lower root to shoot ratios in all three habitats. Lower root to shoot ratios were also found in other invasive species relative to their co-occurring natives (Zou et al., 2007; te Beest et al., 2009; Liao et al., 2013; Liao et al., 2019). The low root to shoot ratios may contribute to invasiveness of exotic species in fertile habitats, by leaving more biomass for allocation to shoot and thus increasing utilization of aboveground resources. Negative relationship between total biomass and root to shoot ratios was indeed found for the invader ( Figure S3A ). This result also indicates that the invader had allometric growth relationship between root and shoot.

Root to shoot ratio was not influenced by soil nutrient levels (DIN contents) for S. canadensis ( Figure S4 ), which is different with the results of many other studies (Liao et al., 2013; Guo et al., 2019; Yan et al., 2019; Li et al., 2020). Liao et al. (2013) found that root to shoot ratio of the invasive plant Chromolaena odarata decreased significantly with increasing soil nutrient in both mono- and mixed cultures. Addition of N also decreases root to shoot ratio of Arabidopsis thaliana (Yan et al., 2019). However, root to shoot ratio of the invader decreased significantly with increasing soil NH₄ ⁺ content, while increased with increasing soil NO₃ ^- content ( Figure S4 ). The invader can better absorb NH₄ ⁺ compared with NO₃ ^- (see below), and thus increasing soil NH₄ ⁺ can better improve its N status. These results indicate that root to shoot ratio of the invader may be influenced by its nutrient status, rather than by soil nutrient levels per se. Root to shoot ratios were negatively correlated with f _NH4 ⁺ or β _NH4 ⁺ for both the invasive and native species ( Figure 8C, D ). Along the common SMA slope of the two species, S. canadensis was located at the end with low root to shoot ratios and high f _NH4 ⁺ values. This result indicates that the higher f _NH4 ⁺ was at least one of the reasons for the lower root to shoot ratio for the invasive species. Consistently, the values of f _NH4 ⁺ were significantly higher ( Figure 4 ), while root to shoot ratios lower for the invader in the farmland and wasteland than in the roadside ( Figure 1 ).

Consistent with our hypothesis, the invasive relative to the native species had higher plasticity in uptake of different soil N forms, contributing to its more DIN uptake. In the farmland and wasteland, where NH₄ ⁺ was the dominant DIN in rhizosphere soils for both species, the invasive and native species absorbed NH₄ ⁺ relative to NO₃ ^- more quickly, and thus NH₄ ⁺ contributed more greatly to plant N. In the roadside, where NO₃ ^- was the dominant DIN in rhizosphere soils for the two species, both species absorbed NO₃ ^- relative to NH₄ ⁺ more quickly, and thus NO₃ ^- contributed more greatly to plant N. These results indicate that the invasive and native species had plasticity in N form uptake. This plasticity could ensure that the two species always utilized the dominant soil N form, and thus contributed to their adaptation to the changes in soil N forms. The higher plasticity in N form uptake for the invasive relative to the native species (especially in the farmland) could help the invader to adapt to the changes in soil N forms. Plasticity in N form uptake have also been found in other plants (Andersen and Turner, 2013; Russo et al., 2013). For example, some plants switch their N source from NO₃ ^- to NH₄ ⁺ when their habitats change from dry to wet (Houlton et al., 2007; Wang and Macko, 2011). Plasticity in N form uptake may be a basic strategy for plants to adapt to the changes in soil N forms (Ashton et al., 2010), and an important factor determining plant dominances and diversity patterns (Craine and Dybzinski, 2013). Until now, however, very few references have studied the roles of plasticity in N form uptake in exotic plant invasions, especially using a quantitative estimator.

Preferential uptake of N forms also contributed to the more N uptake of the invasive relative to the native species. In the farmland and wasteland, the invader preferred NH₄ ⁺, especially in the wasteland, and the N (DIN) uptake rates of the invader were significantly higher than those of the native species ( Figure S2C ). The higher DIN uptake rates were mainly associated with its higher NH₄ ⁺ uptake rates, while its NO₃ ^- uptake rate was not significantly higher than that of A. lavandulaefolia in the wasteland. In the roadside, where NO₃ ^- was the dominant soil N, the invader preferred NO₃ ^-. however, A. lavandulaefolia always preferred NO₃ ^- in three habitats. These results indicate that the invader could adjust its preference for N form according to the dominant soil N form, while A. lavandulaefolia could not. The invader always preferred to absorb the dominant soil N form, contributing to its higher N uptake, and therefore to its invasiveness.

We indeed found that total biomass was positively associated with f _NH4 ⁺ or β _NH4 ⁺ for the invader, while the relationships were negative for A. lavandulaefolia ( Figure 8 ). This result indicates that increasing preference for NH₄ ⁺ and its proportional contribution to plant N increased invasiveness of the invader. A previous study also found that S. canadensis grows better in soils with a higher ratio of NH₄ ⁺ to NO₃ ^- soils, indicating its preference for NH₄ ⁺ (Lu et al., 2005). Preferential uptake of N forms was also found in other plants (Huangfu et al., 2016; Chen and Chen, 2018; Tang et al., 2020; Luo et al., 2022; Zhang et al., 2022a). Luo et al. (2022) found that preference for NO₃ ^- relative to NH₄ ⁺ may help the invasive plant X. strumarium to invade NO₃ ^–enriched disturbed habitats. However, the reasons for the difference in the preference for soil N forms between invasive and native species are still poorly understood.

Our results showed that plant N form acquisition strategy was influenced by both soil N levels and the proportions of different N forms ( Figure 7 ). Numerous studies have shown that the habitats invaded by exotic plants are diverse, and the levels and the proportions of NO₃ ^- and NH₄ ⁺ in these habitats are different greatly (Peng et al., 2011; Andersen and Turner, 2013; Li et al., 2014; Li et al., 2016a; Wang et al., 2020). However, few studies have investigated the effects of these factors on plant N form uptake strategy for invasive plants. We found that S. canadensis and A. lavandulaefolia increased their preferences for NH₄ ⁺ and the proportional contributions of NH₄ ⁺ to plant N with decreasing soil DIN contents and the ratios of NO₃ ^- to NH₄ ⁺. These results indicate that plants are more likely to prefer NH₄ ⁺ and NH₄ ⁺ is the main N source for plants in barren relative to fertile habitats or in habitats with low relative to high ratios of NO₃ ^- to NH₄ ⁺. However, the values of f _NH4 ⁺ and β _NH4 ⁺ were more susceptible to the changes in soil DIN contents and the ratios of NO₃ ^- to NH₄ ⁺ for the invasive relative to the native species, indicating that the invader responded more sensitively to the changes in soil contents of NO₃ ^- to NH₄ ⁺ and their ratios ( Figure 7 ). In addition, the values of f _NH4 ⁺ and β _NH4 ⁺ were significantly higher for the invasive relative to the native species in habitats with low DIN contents or low ratios of NO₃ ^- to NH₄ ⁺.

Plants absorb NH₄ ⁺ and NO₃ ^- using different N transporters, and the differences in the expressions of the genes of these transporters may explain interspecific difference in N form preference (genetic basis). For example, many NO₃ ^- and NH₄ ⁺ transporter genes are significantly different in sequences, or differentially expressed between the invasive plant X. strumarium (preference for NO₃ ^-) and its native congener X. sibiricum (preference for NH₄ ⁺) (Luo et al., 2022; Zhang et al., 2022a).

The differences in sensitivities to NH₄ ⁺ toxicity may also contribute to the interspecific differences in N form preference (Britto and Kronzucker, 2002; Niinemets, 2010). Zhang et al. (2022b) found that X. strumarium is more sensitive to NH₄ ⁺, and always preferred NO₃ ^-, contributing to alleviating NH₄ ⁺ toxicity at high levels (Lambers et al., 1998). We do not know whether A. lavandulaefolia is more sensitive to NH₄ ⁺ than the invader, and whether this is the reason for that pattern A. lavandulaefolia preferred NO₃ ^- in the farmland and wasteland, where NH₄ ⁺ was the dominant soil N form. Further studies are needed.

Other factors such as mycorrhizal type, mycorrhizal taxa and the extent of their infection may also affect interspecific differences in N form preference between invasive and native plants. A better understanding of the degree to which mycorrhizal fungi affect plant N form preferences could significantly improve our understanding of how invasive plant N acquisition strategies will respond to environmental changes.