Effects of Different Degrees of Xanthium spinosum Invasion on the Invasibility of Plant Communities in the Yili Grassland of Northwest China

Simple Summary The effects of invasive plants on species diversity and ecosystem stability differ owing to the different stages of invasion. Xanthium spinosum is an invasive weed that is widely distributed in Europe, Asia, and North America. Its adaptability and competitive advantage over native species have led to agricultural loss and biodiversity reduction, yet its impact on local plant communities under different degrees of invasion has not been reported. Therefore, in this study, we aimed to investigate the effects of different degrees of invasion by X. spinosum on the diversity, stability, and invasibility of local plant communities in Yining County, Xinjiang, China. We believe that our study makes a significant contribution to the literature because we found that as the degree of X. spinosum invasion increased, species diversity and community stability decreased, while community invasibility increased. Notably, a light degree of invasion was found to enhance the diversity and stability of local plant communities. Based on our findings, we recommend that X. spinosum be controlled and eradicated in the early stages of invasion to prevent further invasion and harm to indigenous species. Abstract Studying the effects of different degrees of exotic plant invasion on native plants’ community structure and plant diversity is essential for evaluating the harm caused to ecosystems by plant invasion. In this study, we investigated the effects of Xanthium spinosum, a widespread invasive species, on plant community species diversity and community stability in the Ili River Valley area of Xinjiang, China, under three invasion levels (no invasion and low, moderate, and heavy invasion), and the competitive advantage index, invasion intensity, and contribution of plant community species diversity to community stability and invasibility were determined for the prickly fungus under different degrees of invasion. The results show that there were significant differences (p < 0.05) in the species diversity and community stability of plant communities caused by different degrees of invasion of X. spinosum. The species diversity and stability of plant communities were negatively correlated with the community invasibility, competitive advantage, and invasion intensity of X. spinosum (p < 0.05); therefore, the competitive advantage and invasion intensity of X. spinosum increase with the increase of its invasion degree. On the contrary, community species diversity and stability decreased with the increase of its invasion degree, ultimately leading to differences in community invasibility under different invasion degrees. The Shannon–Wiener and Simpson’s indices were the greatest contributors to community stability and invasibility, respectively. Moderate and heavy levels of invasion by X. spinosum reduced the diversity and stability of local plant communities, increased the invasibility of communities, and substantially affected the structures of plant communities. Therefore, the continued invasion by X. spinosum will have an immeasurable impact on the fragile ecosystems and diversity of indigenous species in Xinjiang. We recommend that this invasive species be controlled and eradicated at the early stages of invasion to prevent further harm.


Introduction
The invasibility of plant communities refers to the degree to which they are vulnerable to invasion by alien plants [1][2][3].The main factors that determine the invasibility of plant communities include plant diversity, characterized by genetic variability, species diversity, and functional diversity, and plant community stability, which depends on the ability of the community to maintain the combination of species and the quantitative relationships among species in a certain period and restore the original equilibrium state under disturbance [3][4][5].Studying the invasibility of plant communities has theoretical and practical relevance for understanding the mechanisms of alien plant invasion, preventing and controlling invasion by alien plants, and restoring invaded communities [6,7].Studies have investigated the invasive mechanisms of alien plants (e.g., biological characteristics and interspecific relationships) and the effects of climate or environmental changes on plant invasion, but few studies have focused on the relationship between plant invasion and community invasibility [8,9].
The effects of invasive plants on species diversity and ecosystem stability differ owing to the different stages of invasion (introduction, settlement, latency, dispersal, and outbreak) [10][11][12].For example, the invasive plants Ageratina adenophora and Eupatorium odoratum, which invade multiple habitats in Guangxi Province, China, inhibit the growth of native plants through competitive advantages and allelopathy, seriously reducing species diversity and community stability [13].Additionally, Bidens pilosa seriously damages the native plant community structure and reduces species diversity through its strong invasiveness, destroying the stability of the ecosystem [14].These studies have shown that invasive plants can severely damage species diversity and ecosystem stability in invaded areas.However, some studies have shown that the species diversity of Alternanthera philoxeroides under low invasion is higher than that under severe invasion [15].Thus, studying the impact of different degrees of invasive alien plants on the regional community structure and species diversity has important theoretical and practical significance in evaluating their harm to ecosystems.Existing studies have mainly divided the survey areas into invasive and non-invasive areas rather than clearly assessing the impact of different degrees of invasion on species diversity [16,17].
Xanthium spinosum is an annual invasive weed belonging to the Compositae family.This species is native to South America but is widely distributed in Central and Southern Europe, Asia, and North America, owing to its strong invasiveness [8].In China, it was first discovered in Dancheng County, Henan Province, in 1981.Since then, X. spinosum has spread to Anhui Province, Beijing, Liaoning, Inner Mongolia, Ningxia, Xinjiang, and six other provinces [18].This species displays strong adaptability, reproductive ability, and competitive ability in its invasiveness, which not only causes agricultural loss and biodiversity reduction but also affects the health of humans and livestock owing to pollen allergies [19].The thorns on the surface of the involucre of X. spinosum allow it to be easily spread by humans or animals when it attaches to clothing or fur, which can inadvertently spread it over a large area within a short time [9].In addition, X. spinosum has strong growth and reproductive abilities, a large seed yield, a high germination rate, diverse diffusion media, and rapid spread, and it quickly occupies a large area and inhibits the growth and reproduction of native plants and crops.Furthermore, this species is slightly toxic and has many sharp, yellow, hard spines on both sides of the petiole base [20].When the spines pierce human or animal skin, it causes severe pain for an extended time, which can interfere with cattle and sheep husbandry [18,21].Therefore, X. spinosum has been included in the updated alien invasive species list of natural ecosystems in China and the list of key management of invasive species [22].

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Studies on the effects of X. spinosum on local plant communities have only discussed the substantial effects on plant community diversity from the perspective of changes in the quantitative characteristics of plant communities in the invaded area, namely height, coverage, density, and importance [21]; however, the effect of X. spinosum on the invasibility of local plant communities under different degrees of invasion has not been reported.Therefore, because of the wide distribution of and damage caused by X. spinosum in Yining County, Xinjiang, China, we aimed to investigate the effects of different degrees of invasion by X. spinosum on the diversity, stability, and invasibility of local plant communities.
The main objectives of the present study were to (1) evaluate the effects of different degrees of X. spinosum invasion on species diversity, community stability, and community invasibility and identify the influencing factors, (2) determine the relationships among species diversity, community stability, and community invasibility, and (3) identify which species diversity index contributes the most to community stability and the community stability index.The results of this study provide a theoretical basis for the scientific management of X. spinosum and local biodiversity protection.

Study Site
The sampling area of this study was located in Wugong Township (81 • 35 ′ E, 44 • 17 ′ N; elevation 860 m), Yili Prefecture, Xinjiang.The habitat type was desert steppe, and the survey area was approximately 2.1 ha.The sampling area has a temperate continental semi-humid desert climate.The annual average temperature is approximately 9 • C, and the monthly average temperature is as high as 32 • C in July and as low as −11 • C in January.The annual precipitation is approximately 340 mm, the annual sunshine duration is approximately 2900 h, and the average annual evaporation is 1621 mm.The plant community in the sampling area comprised erbaceous weeds.Samples of X. spinosum and coexisting native plants in the sampling area were investigated, and the only invasive plants in the community were X. spinosum.

Experimental Design
Referring to the classification method used by previous researchers and taking into account the actual situation in the sampling area, the degree of invasion of X. spinosum was evaluated based on its population coverage in the invaded area [12].Four levels of invasion were designated: no invasion (0%, CK), low invasion (<35%, L), moderate invasion (35-75%, M), and heavy invasion (>75%, H).Based on the estimated distribution of X. spinosum, 40 quadrats (2 m × 2 m) were investigated in September 2023, and all herbaceous species in the quadrats were evaluated.The number and height of each plant species in the quadrats were measured, and coverage was estimated.Three individual plants with vigorous growth were selected from each species to determine plant functional traits, and three mature and complete leaves were randomly selected to determine leaf functional traits.

Determination of Functional Traits for X. spinosum
For the determination of functional traits, we selected 10 functional traits closely related to the growth, competitiveness, and fitness of the invasive and native plants [12,23].The plant height, leaf length, leaf width, and petiole length were measured using a ruler with an accuracy of 0.1 cm.The ground diameter, petiole diameter, and leaf thickness of the plants were measured using a Vernier caliper with an accuracy of 0.01 mm.A plant nutrition analyzer (TYS-3N; Fansheng Technology Co., Ltd., Shijiazhuang, China) was used to determine the chlorophyll and leaf nitrogen of plants, and a leaf image analyzer (FS-leaf1000; Fansheng Technology Co., Ltd., Shijiazhuang, China) was used to measure the leaf area of plant leaves.
The community stability index (ICV) and community invasibility index (CII) were calculated according to the methods of Wang et al. [28].
The competitive advantage index (CAI) was used to characterize the competitive advantage of X. spinosum under different degrees of invasion.The invasion intensity of X. spinosum under different degrees of invasion was characterized using the invasion intensity index (III).The specific calculation formulae and methodology are in Wang et al. [12,28].

Statistical Analyses
Excel 2019 was used for data sorting, and SPSS 25.0 was used to analyze the indicators.The explore command was used to test the normality of the data, while Tukey's multiple comparison tests were used to determine the differences between the average values of each data group.A one-way ANOVA analysis of variance was used to compare the differences in plant species diversity, stability, and invasion ability under different levels of invasion, with a significance level set at p < 0.05.The Pearson product moment correlation coefficient was used for correlation analysis to determine the relationships between community diversity, community stability, and the invasibility of plant communities invaded by X. spinosum to different degrees.We also analyzed the contribution of community species diversity to community stability and invasibility through the direct path coefficient (P) and indirect path coefficient (P') of path analysis.Mapping was completed using Origin 2021.

Results
We found that different degrees of invasion by X. spinosum significantly affected the diversity index of the local plant communities (p < 0.05).As the degree of invasion increased, the diversity index of the local plant communities first increased and then decreased.The H' and D indices were significantly different at the four invasion levels (p < 0.05), and the maximum values were 1.41 and 1.29, respectively, under low invasion.Pielou's and Margalef's indices were higher under the low invasion level (0.82 and 1.04, respectively) than under the other three levels, and they were significantly higher under the no invasion and moderate invasion levels than under the heavy invasion level (p < 0.05).This shows that low invasion by X. spinosum increases the diversity of local plant communities and that heavy invasion by X. spinosum reduces the diversity of local plant communities (Figure 1).
The ICV decreased with increasing degrees of invasion.Compared with the ICV under low invasion, there was a significant decrease of 30% under heavy invasion (p < 0.05).By contrast, with an increase in the degree of invasion, the CII, CAI, and III showed an upward trend.Additionally, compared with the indices under low invasion, there were significant increases of 88%, 92%, and 89%, respectively, in the three indices under heavy invasion (p < 0.05).This shows that the dominance and invasion intensity of X. spinosum and the invasibility of the plant community increased with an increase in the invasion degree of X. spinosum but that the stability of the community decreased (Figure 2).The ICV decreased with increasing degrees of invasion.Compared with the ICV under low invasion, there was a significant decrease of 30% under heavy invasion (p < 0.05).By contrast, with an increase in the degree of invasion, the CII, CAI, and III showed an upward trend.Additionally, compared with the indices under low invasion, there were significant increases of 88%, 92%, and 89%, respectively, in the three indices under heavy invasion (p < 0.05).This shows that the dominance and invasion intensity of X. spinosum and the invasibility of the plant community increased with an increase in the invasion degree of X. spinosum but that the stability of the community decreased (Figure 2).The ICV decreased with increasing degrees of invasion.Compared with the ICV under low invasion, there was a significant decrease of 30% under heavy invasion (p < 0.05).By con trast, with an increase in the degree of invasion, the CII, CAI, and III showed an upward trend Additionally, compared with the indices under low invasion, there were significant increases of 88%, 92%, and 89%, respectively, in the three indices under heavy invasion (p < 0.05).This shows that the dominance and invasion intensity of X. spinosum and the invasibility of the plant community increased with an increase in the invasion degree of X. spinosum but that the stability of the community decreased (Figure 2).The impact index of X. spinosum on the diversity of local plant communities varied with different invasion degrees.Compared with that of low invasion by X. spinosum, the impact index of X. spinosum on the local plant community diversity under moderate and heavy invasion was positive (i.e., moderate and heavy invasion suppressed the diversity index of local plant communities).During low invasion, the impact index of X. spinosum on the diversity of local plant communities was negative (i.e., low invasion promoted the diversity index of local plant communities), with the greatest impact on Simpson's index being −0.57.Low invasion by X. spinosum increased the diversity of local plant communities, especially Simpson's index, and moderate and heavy invasion reduced the diversity of local plant communities (p < 0.05, Figure 3).
The impact index of X. spinosum on the diversity of local plant communities varied with different invasion degrees.Compared with that of low invasion by X. spinosum, the impact index of X. spinosum on the local plant community diversity under moderate and heavy invasion was positive (i.e., moderate and heavy invasion suppressed the diversity index of local plant communities).During low invasion, the impact index of X. spinosum on the diversity of local plant communities was negative (i.e., low invasion promoted the diversity index of local plant communities), with the greatest impact on Simpson's index being −0.57.Low invasion by X. spinosum increased the diversity of local plant communities, especially Simpson's index, and moderate and heavy invasion reduced the diversity of local plant communities (p < 0.05, Figure 3).As the degree of invasion by X. spinosum increased, the impact index of X. spinosum on the ICV and S showed an upward trend.Under low and moderate invasion levels, the DIIICV was <0, but under heavy invasion levels, the DIIICV was >0.The DIIs was <0 for low invasion and >0 for moderate and heavy invasion, and there was a significant difference between different invasion degrees (p < 0.05).As the degree of invasion by X. spinosum increased, it damaged the stability of the local community and reduced the number of community species (Figure 4).As the degree of invasion by X. spinosum increased, the impact index of X. spinosum on the ICV and S showed an upward trend.Under low and moderate invasion levels, the DII ICV was <0, but under heavy invasion levels, the DII ICV was >0.The DII s was <0 for low invasion and >0 for moderate and heavy invasion, and there was a significant difference between different invasion degrees (p < 0.05).As the degree of invasion by X. spinosum increased, it damaged the stability of the local community and reduced the number of community species (Figure 4).
The correlation analysis of the local plant community diversity index with community stability and invasibility showed a highly significant positive correlation between H', D, and J of community diversity and ICV (p < 0.001), and the maximum positive correlation coefficient between J and ICV was 0.831.However, the correlations between S, and F, and ICV were not significant.The S, H', D, J, and F of community diversity were significantly negatively correlated with CII, CAI, and III (p < 0.001), and the negative correlation coefficient between D and CII was the smallest at −0.99.This indicates that community diversity was positively correlated with community stability and negatively correlated with community invasibility (Figure 5).L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DIIICV represents the degree index of the impact of X. spinosum on the community stability index; DIIS represents the index of the degree of influence of X. spinosum on the number of plant species in the community.Different lowercase letters indicate significant differences in the degree of invasion of X. spinosum (mean ± SE, p < 0.05).
The correlation analysis of the local plant community diversity index with community stability and invasibility showed a highly significant positive correlation between H', D, and J of community diversity and ICV (p < 0.001), and the maximum positive correlation coefficient between J and ICV was 0.831.However, the correlations between S, and F, and ICV were not significant.The S, H', D, J, and F of community diversity were significantly negatively correlated with CII, CAI, and III (p < 0.001), and the negative correlation coefficient between D and CII was the smallest at −0.99.This indicates that community diversity was positively correlated with community stability and negatively correlated with community invasibility (Figure 5).The correlation analysis of the local plant community diversity index with community stability and invasibility showed a highly significant positive correlation between H', D, and J of community diversity and ICV (p < 0.001), and the maximum positive correlation coefficient between J and ICV was 0.831.However, the correlations between S, and F, and ICV were not significant.The S, H', D, J, and F of community diversity were significantly negatively correlated with CII, CAI, and III (p < 0.001), and the negative correlation coefficient between D and CII was the smallest at −0.99.This indicates that community diversity was positively correlated with community stability and negatively correlated with community invasibility (Figure 5).According to the path analysis results of species diversity's impact on community stability and invasibility, the magnitude of the contribution of each diversity index to community stability was in the following order: H' > F > S > D > J. Therefore, plant diversity had the greatest contribution to community stability (p = 2.264).Additionally, H had a significant indirect contribution to community stability through D (P' = 2.218).The contribution of each diversity index to community invasibility was in the order of D > H' > F > S > J. Therefore, dominance had the greatest contribution to community invasibility (p = 0.579), and dominance had a significant indirect contribution to community invasibility through its influence on plant diversity (P' = 0.565, Table 1).

Discussion
Invasion by non-native plants has a substantial impact on local species diversity, community stability, and community invasibility [12,19].In this study, the impact index of low invasion by X. spinosum on local species diversity, community stability, and community invasibility was negative, indicating a significant increase in local species diversity compared to that in uninvaded areas.Other studies have reached similar conclusions [29][30][31].The reasons for these results may be that the competitive ability or allelopathy of invasive plants in the early stages of invasion is insufficient to cause a large impact and that crowding out of local species is not yet apparent.Instead, communities under low invasion exhibit species diversity similar to that of uninvaded communities, demonstrating a positive impact on community species diversity [28].By contrast, in this study, a heavy level of invasion significantly reduced local species diversity and community stability while increasing community invasibility.This is likely due to the fact that as the degree of invasion by X. spinosum increased, its invasion intensity and competitive advantage continued to increase, resulting in a positive impact index of heavy invasion by X. spinosum on local species diversity, community stability, and community invasibility.This led to the loss of local plant diversity and serious damage to community stability, resulting in negative impacts and ultimately increasing community invasibility.
A few studies have demonstrated that prickly ash fungus had a stronger survival ability than the local plants, creating favorable conditions for its invasion [32,33].Thus, invasion by alien plants does not necessarily lead to a decrease in the species diversity and community stability of local communities, leading to an increase in invasibility.There were significant differences in the impact of X. spinosum on community species diversity at different invasion levels [34,35].Low invasion by alien plants can increase species diversity in plant communities, improve community stability, fill empty niches, utilize available resources, and reduce community invasibility [36].
There is a close relationship between the invasion and stability of the community and the species diversity of the local plant community [1,37,38].The present study showed that community invasibility was negatively correlated with species diversity and community stability, indicating that species diversity and community stability decreased with an increase in the invasion degree of X. spinosum.However, community invasibility increased, and the competitive advantage of X. spinosum increased its coverage and was negatively correlated with species diversity and community stability.The level of invasion by X.
Biology 2024, 13, 14 9 of 11 spinosum increased, and its strong competitive advantage disrupted the balance of the local ecosystem, leading to a decrease in local plant diversity and community stability, and under heavy levels of invasion, the extinction of other plants may occur [38,39].However, there are inconsistencies in the literature.For example, invasive plants have been shown to have higher community invasiveness in ecosystems with higher species diversity, showing a positive correlation [40,41].Additionally, the invasibility of the community has been shown to be not significantly related to the species diversity of local plant communities [31,42].Therefore, the relationship between community invasibility, species diversity, and plant community stability is relatively complex [12].
The differences between local plant communities (for example with regard to aspects such as structure, size, and stability) can lead to changes in the species diversity and invasive relationships of different communities.Species diversity, as the core component of plant communities, affects the stability and invasibility of communities [36,40,43].This study showed that the contribution of H' to community stability was higher than that of other diversity indices, indicating that communities with higher diversity are likely to have higher levels of community stability and develop greater resistance to plant invasion.A previous study reached similar conclusions [12].However, another previous study suggested that plant dominance is crucial for maintaining community stability [43].In addition, the contribution of D to community invasibility was higher than that of the other diversity indices, which is inconsistent with results in the literature [12].As the CAI and III of X. spinosum increased, it became the dominant species in the invaded community, significantly affecting the invasibility of the community.Thus, diversity plays a crucial role in the stability of communities, and dominance has a notable impact on the invasibility of communities.

Figure 2 .
Figure 2. The changes in the stability, invasiveness, competitive advantage index, and invasion intensity index of the local plant community under different degrees of Xanthium spinosum invasion.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; ICV represents the community stability index; CII represents the community invasiveness index; CAI represents the competitive advantage index of X. spinosum; III represents the invasion intensity index of X. spinosum.Different lowercase letters indicate signif-

Figure 2 .
Figure 2. The changes in the stability, invasiveness, competitive advantage index, and invasion in tensity index of the local plant community under different degrees of Xanthium spinosum invasion L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H repre sents heavy invasion of X. spinosum; ICV represents the community stability index; CII represents the community invasiveness index; CAI represents the competitive advantage index of X. spinosum III represents the invasion intensity index of X. spinosum.Different lowercase letters indicate signif icant differences under different degrees of invasion by X. spinosum (mean ± SE, p < 0.05).

Figure 2 .
Figure 2. The changes in the stability, invasiveness, competitive advantage index, and invasion intensity index of the local plant community under different degrees of Xanthium spinosum invasion.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; ICV represents the community stability index; CII represents the community invasiveness index; CAI represents the competitive advantage index of X. spinosum; III represents the invasion intensity index of X. spinosum.Different lowercase letters indicate significant differences under different degrees of invasion by X. spinosum (mean ± SE, p < 0.05).

Figure 3 .
Figure 3.The influence of different degrees of Xanthium spinosum invasion on the diversity index of local plant communities.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DIIH' represents the index of the degree of influence of X. spinosum on the Shannon−Wiener index; DIID' represents the index of the degree of influence of X. spinosum on Simpson's index; DIIJ' represents the index of the degree of influence of X. spinosum on Pielou's index; DIIF' represents the index of the degree of influence of X. spinosum on the Margalef's index.Different lowercase letters indicate significant differences under different degrees of invasion by X. spinosum (mean ± SE, p < 0.05).

Figure 3 .
Figure 3.The influence of different degrees of Xanthium spinosum invasion on the diversity index of local plant communities.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DII H' represents the index of the degree of influence of X. spinosum on the Shannon−Wiener index; DII D' represents the index of the degree of influence of X. spinosum on Simpson's index; DII J' represents the index of the degree of influence of X. spinosum on Pielou's index; DII F' represents the index of the degree of influence of X. spinosum on the Margalef's index.Different lowercase letters indicate significant differences under different degrees of invasion by X. spinosum (mean ± SE, p < 0.05).

Figure 4 .
Figure 4.The influence of different degrees of Xanthium spinosum invasion on the species number and stability index of local plant communities.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DIIICV represents the degree index of the impact of X. spinosum on the community stability index; DIIS represents the index of the degree of influence of X. spinosum on the number of plant species in the community.Different lowercase letters indicate significant differences in the degree of invasion of X. spinosum (mean ± SE, p < 0.05).

Figure 5 .
Figure5.The correlation between the local plant community diversity index and community stability and invasibility.ICV is the community stability index; CII is the invasiveness index; CAI is the competitive advantage index of X. spinosum; III is the invasion intensity index of X. spinosum; S is

Figure 4 .
Figure 4.The influence of different degrees of Xanthium spinosum invasion on the species number and stability index of local plant communities.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DIIICV represents the degree index of the impact of X. spinosum on the community stability index; DIIS represents the index of the degree of influence of X. spinosum on the number of plant species in the community.Different lowercase letters indicate significant differences in the degree of invasion of X. spinosum (mean ± SE, p < 0.05).

Figure 5 .
Figure5.The correlation between the local plant community diversity index and community stability and invasibility.ICV is the community stability index; CII is the invasiveness index; CAI is the competitive advantage index of X. spinosum; III is the invasion intensity index of X. spinosum; S is The variation trend of the local plant community diversity index under different degrees o Xanthium spinosum invasion.CK represents no invasion of X. spinosum; L represents low invasion of X spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; H represents the Shannon-Wiener index; D represents Simpson's index; J represents Pielou's index; F rep resents Margalef's index.Different lowercase letters indicate significant differences in species diversity indices under different levels of invasion by X. spinosum (mean ± SE, p < 0.05).
Figure 1.The variation trend of the local plant community diversity index under different degrees of Xanthium spinosum invasion.CK represents no invasion of X. spinosum; L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; H' represents the Shannon-Wiener index; D represents Simpson's index; J represents Pielou's index; F represents Margalef's index.Different lowercase letters indicate significant differences in species diversity indices under different levels of invasion by X. spinosum (mean ± SE, p < 0.05).Figure 1.
The influence of different degrees of Xanthium spinosum invasion on the species number and stability index of local plant communities.L represents low invasion of X. spinosum; M represents moderate invasion of X. spinosum; H represents heavy invasion of X. spinosum; DII ICV represents the degree index of the impact of X. spinosum on the community stability index; DII S represents the index of the degree of influence of X. spinosum on the number of plant species in the community.Different lowercase letters indicate significant differences in the degree of invasion of X. spinosum (mean ± SE, p < 0.05).
The correlation between the local plant community diversity index and community stability and invasibility.ICV is the community stability index; CII is the invasiveness index; CAI is the competitive advantage index of X. spinosum; III is the invasion intensity index of X. spinosum; S is the number of plant species in the community; H' is the Shannon−Wiener index; D is Simpson's index; J is Pielou's index; F is Margalef's index; **, p < 0.01; ***, p < 0.001.

Table 1 .
The contribution of plant community diversity to community stability and invasibility.
P is the direct path coefficient; P' is the indirect path coefficient; S is the number of plant species in the community; H' is the Shannon-Wiener index; D is Simpson's index; J is Pielou's index; F is Margalef's index.