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24 results on '"plant invasion"'

5. Invasion of Rosa rugosa induced changes in soil nutrients and microbial communities of coastal sand dunes.

Author

Stefanowicz, Anna M., Zubek, Szymon, Stanek, Małgorzata, Grześ, Irena M., Rożej-Pabijan, Elżbieta, Błaszkowski, Janusz, and Woch, Marcin W.

Abstract

The aim of this study was to investigate the influence of R. rugosa invasion on soil physicochemical and microbial properties of coastal sand dunes. The study was performed at 25 paired invaded-native plots along the Hel Peninsula at the coast of the Baltic Sea. A number of soil physicochemical and microbial parameters were measured, namely organic matter layer thickness, pH, electrical conductivity, organic C, total Ca, N, Na, P, N-NH 4 , N-NO 3 and P-PO 4 concentrations, phospholipid and neutral fatty acid (PLFA, NLFA) markers of total microbial, bacterial, fungal biomass and microbial community structure, as well as arbuscular mycorrhizal fungi (AMF) spore and species numbers, and the degree of AMF root colonization. Since potential alterations in soil parameters induced by R. rugosa may be related to large amounts of secondary metabolites provided to the soil with litter or root exudates, total phenolic concentration in senescing tissues of R. rugosa and native species was compared. Rosa rugosa invasion was associated with increased organic C, total N and P-PO 4 concentrations in mineral soil relative to native vegetation. Organic matter layer under R. rugosa was thicker, had higher pH and Ca concentration. Rosa rugosa invasion was associated with reduced total microbial, bacterial and G+ bacterial biomass and increased AMF biomass markers (16:1ω5 NLFA and 16:1ω5 NLFA/PLFA), and changes in microbial community structure in mineral soil. The reduction in total and bacterial biomass under R. rugosa might have been related to the production of secondary metabolites as total phenolic concentration was approx. 5 times higher in senescing tissues of R. rugosa than in native vegetation. The observed increase in element concentrations and alterations in microbial community structure suggest that invasion of R. rugosa may threaten nutrient-poor habitats of coastal dunes. Changes in the soil environment may hinder restoration of these valuable habitats after invader removal. Unlabelled Image • Influence of invasive Rosa rugosa on soil properties of coastal dunes was studied. • R. rugosa increased organic C, total N and P-PO 4 in soil relative to native species. • Total microbial and bacterial biomass was decreased under R. rugosa. • A marker of arbuscular mycorrhizal fungi – NLFA 16:1ω5 – increased due to invasion. • Changes in soil might have been caused by high phenolic content in R. rugosa tissues. [ABSTRACT FROM AUTHOR]

Published
2019
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6. Do invasive alien plants differ from non-invasives in dominance and nitrogen uptake in response to variation of abiotic and biotic environments under global anthropogenic change?

Author

Liu, Yuan-Yuan, Sun, Yan, Müller-Schärer, Heinz, Yan, Rong, Zhou, Zhi-Xiang, Wang, Yong-Jian, and Yu, Fei-Hai

Abstract

Plant invasion is the outcome of complicated interactions of both biotic and abiotic environments (i.e. eutrophication and human-induced propagules) under global anthropogenic change. Here, we want to know why some alien clonal plant species become invasive and others do not in the introduced range with variations of both abiotic and biotic environments under global anthropogenic change. We selected three invasive alien and three co-occurring, non-invasive alien clonal plant species in China, and grew them under the constant or variable soil nutrient environments in a native community with low or high vegetative propagule pressure (i.e. simulating pressure of anthropogenic alien propagules). Invasive alien species produced more biomass than non-invasives. Interestingly, invasive species benefited significantly greater from high propagule pressure than non-invasives. Biomass and evenness of native communities were greater with non-invasive than with invasive target species. Invasive plants showed a greater increase of leaf N and decrease of leaf C: N ratio when subject to variable nutrients in comparison to constant nutrients than non-invasives. The negative effects of variable nutrients on evenness of native communities were significantly greater under invasive than non-invasive target species. Moreover, biomass of native communities was significantly negatively related to biomass of invasive species. Variable nutrients significantly promoted the negative biomass relationship between non-invasive species and native communities under high propagule pressure and the negative biomass-evenness relationship between invasive species and native communities. Our study suggests that soil nutrient variability and vegetative propagule pressure influence the growth and leaf C and N uptake of alien clonal plant species in native experimental communities, especially under the high propagule pressure and nutrient variability. Invasive alien clonal species have higher performance and advantages over non-invasives. Future studies should also test the mechanisms that invasive and non-invasive or native plants differ in native communities of native or introduced ranges in the field. Unlabelled Image • Plant invasion is the outcome of interactions of biotic and abiotic environmental factors under global anthropogenic change. • We tested the responses of invasive and non-invasive clonal plants to variations of soil nutrient and propagule pressure. • Invasive alien clonal species had greater increase of leaf N than non-invasives in the variable nutrient treatment. • Invasive alien clonal species have higher performance and advantages over non-invasives in variable environments. [ABSTRACT FROM AUTHOR]

Published
2019
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7. Shifts of soil microbial community composition along a short-term invasion chronosequence of Spartina alterniflora in a Chinese estuary.

Author

Zhang, Guangliang, Bai, Junhong, Jia, Jia, Wang, Wei, Wang, Xin, Zhao, Qingqing, and Lu, Qiongqiong

Abstract

Abstract Exotic plant invasion can alter native soil microbial community composition, and further influence the biogeochemical processes. Little information is available about the impacts of the invasion chronosequence of Spartina alterniflora on the dynamics of soil microbial community. Soil microbial community in coastal salt marshes invaded by S. alterniflora and reference wetlands covered by Suaeda salsa were investigated using phospholipid fatty acids (PLFAs) profiling along a short-term chronosequence (i.e., 2-, 5- and 10-year) of S. alterniflora invasion in the Yellow River Estuary. Results exhibited an increase in soil moisture, soil organic matter (SOM), soil dissolved organic carbon (DOC), total nitrogen (TN) and the total of PLFAs with increasing invasion ages of S. alterniflora in these coastal salt marshes. Comparatively, soil pH and bulk density exhibited a weak decline along the invasion chronosequence. The elevated values of relative abundance of fungi and the ratios of fungi: bacteria (F/B) in all invaded salt marshes were mainly associated with the accumulation of soil available substrate (e.g., SOM, DOC and TN). S. alterniflora invasion also increased the ratios of gram-positive/gram-negative (G+/G-) bacterial PLFAs, with the highest value occurring in the 2-year invaded salt marshes. The bacterial stress indicated by ratios of cy17:0/16:1ω7c and cy19:0/18:1ω7c consistently decreased along the invasion chronosequence. In conclusion, the shifts of soil microbial community composition were tightly associated with soil variables, such as soil pH and soil nutrient supply. Our findings reflect the short-term chronological effects of S. alterniflora invasion on the soil physicochemical characteristics and microbial communities, which contributes to the linkage between the plant invasion and soil development of coastal salt marshes. Graphical abstract Unlabelled Image Highlights • S. alterniflora invasion triggered the shift of soil microbial community composition. • Soil physicochemical characteristics followed a linear response to invasion. • Bacteria dominated the soil microorganisms in native and invaded salt marsh soils. • The F/B ratio was increased with the accumulation of soil organic matter. • Soil pH and C/N rule the microbial development along the short-term sequence. [ABSTRACT FROM AUTHOR]

Published
2019
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10. Nutrient addition increases the capacity for division of labor and the benefits of clonal integration in an invasive plant.

Author

Huang, Qiaoqiao, Li, Xiaoxia, Huang, Fangfang, Wang, Ruilong, Lu, Baoqian, Shen, Yide, Fan, Zhiwei, and Lin, Peiqun

Subjects
*INVASIVE plants, *PLANT cloning, *SOIL moisture, *PLANT nutrients, *MIKANIA
Abstract

Abstract Many of the most invasive plants are clonal, and clonal integration has been proposed as an important mechanism promoting invasiveness. When the availabilities of two essential resources are negatively correlated in space, clonal integration may benefit clonal plants through division of labor. We hypothesized that environments with reciprocal patchiness of light and soil water may induce division of labor, and nutrient addition may increase both the division of labor and the benefits of clonal integration. To test this, we grew pairs of connected and disconnected ramets of the clonal invader Mikania micrantha under negative spatial covariance of light and soil water such that the proximal ramets were grown under high light and low soil water conditions and the distal ramets were grown under low light and high soil water conditions. In half of the ramet pairs, both ramets of a pair received a nutrient addition treatment. The results showed that connection decreased the root to shoot ratio in proximal ramets and increased it in distal ramets, indicating that division of labor was induced. In addition, connection increased the root to shoot ratio of distal ramets more under high soil nutrient conditions than under low soil nutrient conditions, indicating that nutrient addition increased the division of labor. Connection increased plant biomass at the whole clonal fragment level, and this increase was larger under high soil nutrient conditions than under low soil nutrient conditions. This study showed, for the first time, that in environments with reciprocal patchiness of two essential resources, the capacity for division of labor and its influence on plant performance may depend on the availability of a third essential resource. Because invasive plants often can acquire a larger amount of soil resources than native plants, our study may also contribute to the understanding why clonality is related to invasiveness. Graphical abstract Unlabelled Image Highlights • Environments with reciprocal patchiness of light and soil water may induce division of labor. • No study has examined how this division of labor may depend on the availability of a third environmental resource. • Nutrient addition increased the division of labor in the clonal invader Mikania micrantha. • Integration increased the biomass of the whole clone more under high soil nutrient conditions. • The capacity for division of labor depends on the availability of a third essential resource. [ABSTRACT FROM AUTHOR]

Published
2018
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11. Can nutrient enrichment influence the invasion of Phragmites australis?

Author

Uddin, Md Nazim and Robinson, Randall William

Subjects
*PLANT invasions, *PLANT nutrients, *WETLAND ecology, *GREENHOUSE management, *NITROGEN
Abstract

Plant invasion and nutrient enrichment because of anthropogenic landscape modifications seriously threaten native plant community diversity in aquatic and wetland ecosystems. It is poorly understood, however, whether these two disturbances interact with the functional identity of recipient native plants to drive community change. We performed combined studies in the fields and greenhouse to examine whether nutrient enrichment may trigger the invasion of Phragmites australis in wetlands through competitive advantage over native Melaleuca ericifolia . Chemical characterizations of rhizosphere water were distinguished in two different nutrient enriched wetlands associated with and without Phragmites over the seasons. Significant changes in rhizosphere water were observed in invaded area compared to uninvaded area at both sites. High nitrogen (NO 3 − ), phosphorous (PO 4 3 − ), dissolved organic carbon, phenolics contents, with low pH were found in invaded areas compared to uninvaded areas. Total biomass of Phragmites was positively regressed with rhizosphere water nitrogen (NO 3 − ) and phosphorous (PO 4 3 − ) content. Nutrient addition significantly enhanced the growth and competitive ability of Phragmites over Melaleuca . In contrast, Melaleuca was significantly less competitive than Phragmites . There was a significantly positive correlation between the growth of Phragmites grown alone and its competitive ability. The findings in greenhouse studies coupled with characteristics of Phragmites and its' rhizosphere chemistry in the nutrient enriched fields suggest that nutrient enrichment may enhance Phragmites invasion through correspondingly increasing growth and maintaining inherent competitive advantages of Phragmites . Nutrient management could limit the vigorous growth of Phragmites in wetlands and thereby reduce invasion through competitive advantages over natives, which might have important management implications for wetland managers. [ABSTRACT FROM AUTHOR]

Published
2018
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12. Black locust—Successful invader of a wide range of soil conditions.

Author

Vítková, Michaela, Tonika, Jaroslav, and Müllerová, Jana

Subjects
*BLACK locust, *SOIL conditioners, *HABITATS, *SOIL classification, *VEGETATION & climate
Abstract

Black locust ( Robinia pseudoacacia , BL), a species native to North America, has successfully invaded many types of habitats over the world. This study provides an overall assessment of BL soil conditions to determine the range of physical–chemical soil properties it can tolerate. 511 BL stands (for the soil types) and 33 permanent plots (for the soil chemistry) were studied in the Czech Republic. Relationships among different environmental variables (physical–chemical soil properties, vegetation characteristics and habitat conditions) were investigated and variables with the highest effect on species composition were detected. The results were compared with data in the literature for other parts of the secondary and native distributions of this species. This assessment showed that BL is able to tolerate extremely diverse soil physical–chemical conditions, from extremely acid to strongly alkaline, and from medium to highly base saturated soils with a gradient of different subsurface stoniness. Soil nitrate, N mineralization and nitrification rates also varied considerably and the concentrations of exchangeable phosphorus and ammonium were consistently low. N mineralization rate, incubated inorganic nitrogen and nitrates were positively correlated with base saturation and cation exchange capacity. The most common soil types were young soils (Cambisols, Leptosols, Arenosols, and coarsely textured Fluvisols). BL seems to be limited by water supply and soil aeration and prefers well aerated and drained soils, and tolerates desiccation but avoids compact soils and areas where the soils are frequently waterlogged. On steep slopes, BL was less vigorous, stunted and less competitive. By contrast, the tallest BL trees were found on sandy soils in a flat landscape. Number and share of nitrophytes in the herb layer were positively related to basic bedrock, soil reaction and N–NO 3 /N ratio. Soil reaction was determined as the most important environmental characteristic explaining the variability in BL species composition in the Czech Republic. [ABSTRACT FROM AUTHOR]

Published
2015
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14. The introduced tree Prosopis juliflora is a serious threat to native species of the Brazilian Caatinga vegetation.

Author

de Souza Nascimento, Clóvis Eduardo, Tabarelli, Marcelo, da Silva, Carlos Alberto Domingues, Leal, Inara Roberta, de Souza Tavares, Wagner, Serrão, José Eduardo, and Zanuncio, José Cola

Subjects
*PROSOPIS juliflora, *PLANT species, *CAATINGA plants, *PLANT stems, *PLANT competition, *PLANT mortality
Abstract

Abstract: Despite its economic importance in the rural context, the Prosopis juliflora tree species has already invaded millions of hectares globally (particularly rangelands), threatening native biodiversity and rural sustainability. Here we examine seedling growth (leaf area, stem diameter, plant height) and seedling mortality across five native plant species of the Caatinga vegetation in response to competition with P. juliflora. Two sowing treatments with 10 replications were adopted within a factorial 2×5 randomized block design. Treatments consisted of P. juliflora seeds sowed with seeds of Caesalpinia ferrea, Caesalpinia microphylla, Erythrina velutina, Mimosa bimucronata and Mimosa tenuiflora (one single native species per treatment), while seeds of native species sowed without P. juliflora were adopted as controls. Overall, our results suggest that P. juliflora can reduce seedling growth by half and cause increased seedling mortality among woody plant species. Moreover, native species exhibit different levels of susceptibility to competition with P. juliflora, particularly in terms of plant growth. Such a superior competitive ability apparently permits P. juliflora to establish monospecific stands of adult trees, locally displacing native species or limiting their recruitment. The use of less sensitive species, such as C. ferrea and M. tenuiflora, to restore native vegetation before intensive colonization by P. juliflora should be investigated as an effective approach for avoiding its continuous spread across the Caatinga region. [Copyright &y& Elsevier]

Published
2014
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19. Artificial modification on lateral hydrological connectivity promotes range expansion of invasive Spartina alterniflora in salt marshes of the Yellow River delta, China.

Author

Xie, Tian, Wang, Qing, Ning, Zhonghua, Chen, Cong, Cui, Baoshan, Bai, Junhong, Shi, Wei, and Pang, Bo

Abstract

'Invasibility', or the extent to which a habitat is prone to being invaded by plants, is a measure of the resistance of that ecosystem to biological invasion: a limited extent represents abiotic conditions unsuitable for invasion by invasive species; however, human activity can change that and make a habitat prone to rapid invasion. Field surveys and greenhouse experiments were carried out to explore, using spatial analysis, how a strong invader, namely Spartina alterniflora , is assisted by such activities as constructing levees and digging trenches, ditches, and pits in a tidal salt marsh. These activities changed the lateral hydrological connectivity of a salt marsh. The invasibility was then estimated based on the probability of seed dispersal and retention using the classical probabilistic method, and the rate of seedling emergence using threshold analysis. Changes in lateral hydrological connectivity led to more seeds of the invading species being retained, especially in high marshes, and promoted the emergence of its seedlings by making the soil more moist and less saline. The results suggest that changes in the lateral hydrological connectivity in a salt marsh can make it more prone to being invaded. The results have important implications for the control of invasive plants by limiting human activity and thereby regulating lateral hydrological connectivity in coastal ecosystems. Unlabelled Image • Lateral hydrological connectivity was estimated from inundation time in saltmarsh. • Soil factors and seed retention were related to lateral hydrological connectivity. • Modifying lateral hydrological connectivity made saltmarsh more prone to invasion. • Artificial modification facilitated invasion of salt marsh by cordgrass. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Invasive plant Reynoutria japonica produces large amounts of phenolic compounds and reduces the biomass but not activity of soil microbial communities.

Author

Stefanowicz, Anna M., Kapusta, Paweł, Stanek, Małgorzata, Frąc, Magdalena, Oszust, Karolina, Woch, Marcin W., and Zubek, Szymon

Abstract

Reynoutria japonica is one of the most invasive plant species. Its success in new habitats may be associated with the release of secondary metabolites. The aim of this study was to compare phenolic concentrations in plant biomass and soils between plots with R. japonica and resident plants (control), and determine the effects of these compounds on soil microbial communities. Samples of plant shoots and rhizomes/roots, and soil were collected from 25 paired plots in fallow and riparian habitats in Poland. We measured concentrations of total phenolics, condensed tannins, catechin, chlorogenic acid, emodin, epicatechin, hyperoside, physcion, piceatannol, polydatin, procyanidin B3, quercetin, resveratrol, and resveratroloside. Soil microbial parameters were represented by acid and alkaline phosphomonoesterases, β-glucosidase, phenoloxidase, and peroxidase activity, culturable bacteria activity and functional diversity measured with Biolog Ecoplates, and microbial biomass and community structure measured with phospholipid fatty acid (PLFA) analysis. We found that concentrations of total phenolics and condensed tannins were very high in R. japonica leaves and rhizomes/roots, and concentrations of most phenolic compounds were very high in R. japonica rhizomes/roots when compared to resident plant species. Concentrations of most phenolics in mineral soil did not differ between R. japonica and control plots; the only exceptions were catechin and resveratrol which were higher and lower, respectively, under the invader. Total microbial and bacterial (G+, G–) biomass was decreased by approx. 30% and fungal biomass by approx. 25% in invaded soils in comparison to control. Among soil functional microbial parameters, only peroxidase activity and functional diversity differed between R. japonica and resident plant plots; peroxidase activity was higher, while functional diversity was lower in soil under R. japonica. The negative effects of R. japonica on microbial biomass may be related to catechin or its polymers (proanthocyanidins) or to other phenolics contained in high concentrations in R. japonica rhizomes. Unlabelled Image • Biomass of invasive Reynoutria japonica contained large amounts of phenolics. • Soil phenolic contents hardly differed between R. japonica and control. • Catechin was higher and resveratrol was lower in R. japonica relative to control soil. • Soil bacterial and fungal biomass were clearly reduced by invasion. • Invasion hardly affected the activity of soil microbial communities. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Phenotypic plasticity in resource allocation to sexual trait of alligatorweed in wetland and terrestrial habitats.

Author

Zhang, Jialiang, Huang, Wei, and Ding, Jianqing

Abstract

Environmental heterogeneity in resource availability affects invasive plant reproductive strategies and resource allocation to reproduction. Here, we conducted two field surveys to examine the effect of wetland and terrestrial habitats on inflorescence production and resource allocation to inflorescence of the amphibious invasive plant Alternanthera philoxeroides in its invasive range (China). We also specifically examined the effects of water availability, fertilizer application, and plant density (space) in a greenhouse experiment. In field surveys, inflorescence biomass, normal monoclinous flowers and ratio of inflorescences to shoots of plants from wetlands were about 2.4-, 0.8- and 1.3-fold higher than those from terrestrial habitats, respectively. In greenhouse experiment, plants with higher fertilizer application and lower competition conditions produced more inflorescences, and had a lower ratio of roots to shoots and a comparable ratio of inflorescences to shoot and root. Furthermore, water availability had a significant interactive effect when combined with fertilizer level or plant density on inflorescence production and resource allocation. Together, our results indicate that high resources, such as those found in wetland habitats, favor both vegetative growth and sexual trait in A. philoxeroides. However, in terrestrial habitats where resources are relatively poor, the invader can adapt to the environment by allocating more resources to vegetative growth for clonal reproduction and less resources for sexual trait. This phenotypic plasticity in resource allocation likely facilitates the plant to invade heterogeneous wetlands and terrestrial environments. Unlabelled Image • Environmental heterogeneity affected resource allocation of invasive alligatorweed. • High resource availability increased resource allocation to sexual trait. • Low resource availability increased resource allocation to clonal growth. • Phenotypic plasticity in resource allocation may facilitate alligatorweed invasion. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Drifting away. Seawater survival and stochastic transport of the invasive Carpobrotus edulis.

Author

Souza-Alonso, Pablo, Lechuga-Lago, Yaiza, Guisande-Collazo, Alejandra, Pereiro Rodríguez, Diego, Rosón Porto, Gabriel, and González Rodríguez, Luís

Abstract

Coastal areas are vulnerable and fluctuating habitats that include highly valuable spaces for habitat and species conservation and, at the same time, they are among the most invaded ecosystems worldwide. Occupying large areas within Mediterranean-climate coastlines, the "ecosystem engineer" Carpobrotus edulis appears as a menace for coastal biodiversity and ecosystem services. By combining the observation, current distribution, glasshouse experiment, and dispersion modeling, we aim to achieve a better understanding of the successful invasion process and potential dispersion patterns of C. edulis. We analyzed the response of plant propagules (seeds and plant fragments) to seawater immersion during increasing periods of time (up to 144 h). After 2 months of growth, plant fragments showed a total survival rate (100%) indicating high tolerance to salinity. During this time, fragment length was increased (up to 60%) and root length was higher than control in all cases. Also, immersed fragments consistently accumulated more biomass than control fragments. After two months of growth, photosynthetic parameters (F v '/F m ', Φ NO , and Φ II) remained stable compared to control fragments. Physiologically, osmolyte and pigment content did not evidence significant changes regardless of immersion time. Based on the capacity of propagules to survive seawater immersion, we modeled the potential transport of C. edulis by combining an oceanic model (ROMS-AGRIF) with a particle-tracking model. Results indicated that propagules may travel variable distances maintaining physiological viability. Our model suggested that short-scale circulation would be the dominant process, however, long-scale circulation of propagules may be successfully accomplished in <6 days. Furthermore, under optimal conditions (southerly winds dominance), propagules may even travel large distances (250 km alongshore). Modeling transport processes, in combination with the dynamics of introduction and expansion, will contribute to a better understanding of the invasive mechanisms of C. edulis and, consequently, to design preventive strategies to reduce the impact of plant invasion. Unlabelled Image • Carpobrotus edulis represents a threat for coastal habitat conservation. • There is no previous evidence that C. edulis can be transported by seawater currents. • Fragments maintained viability after immersion accumulating more biomass than controls. • Our model suggests that transportation of C. edulis fragments occurs mainly in the short-scale. • Particle-tracking model also forecasts potential long-distance dispersal events (up to 250 km). [ABSTRACT FROM AUTHOR]

Published
2020
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23. Mikania micrantha invasion enhances the carbon (C) transfer from plant to soil and mediates the soil C utilization through altering microbial community.

Author

Ni, Guangyan, Zhao, Ping, Huang, Qiaoqiao, Zhu, Liwei, Hou, Yuping, Yu, Yina, Ye, Youhua, and Ouyang, Lei

Abstract

• Invasive plants effect on soil C accumulation and soil microbes' role are unclear. • Photoassimilated-13C' distribution and utilization by microbes were determined. • Invasive plants photoassimilated more C and transferred the C faster to soils. • Soil C accumulate rate was modulated by soil microbes. Exotic plant invasion alters the structure and coverage of terrestrial vegetation and affects the carbon (C) stocks in ecosystems. Previous studies have shown the increases in the C stocks with increasing invasive plants, but these results remain contentious. Soil microbial communities are usually altered by plant invasion, which potentially influences the C cycling underground. We hypothesized that the plant invasion-caused dynamic changes in soil microbes would lead to the corresponding change in soil C accumulation. Using greenhouse experiments we simulated different invader intensities through varying the relative abundance of invasive species Mikania micrantha and its co-occurring native species Paederia scandens. By analyzing 13C-phospholipid fatty acid we found the invasive M. micrantha assimilated more 13C and transferred faster the fixed 13C through different tissues to soils, as compared to native P. scandens. Soil microbial components, i.e., i15:0, 16:0, 10Me16:0, 18:1w9c and 18:2w6,9 were mainly using the photo-assimilated 13C. In addition, we found a hump-shaped relationship between soil net 13C accumulate rate and rhizosphere microbial biomass, indicating that the soil C accumulation may be either enhanced or reduced in invaded ecosystems, depending on microbe abundance. [ABSTRACT FROM AUTHOR]

Published
2020
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24. Invasive Quercus rubra negatively affected soil microbial communities relative to native Quercus robur in a semi-natural forest.

Author

Stanek, Małgorzata and Stefanowicz, Anna M.

Abstract

Invasive tree species can exert a profound effect on soil properties and ecosystem processes. Quercus rubra is a Northern American species that has an invader status in many European countries. However, the direction and magnitude of its effect on soil physicochemical and microbial properties relative to native tree species in forests are largely unknown. The aim of this study was to investigate the influence of invasive Q. rubra on physicochemical and microbial properties of soil organic and mineral horizons in comparison to native Quercus robur in a semi-natural forest. The study was performed on 23 Q. rubra and 10 Q. robur stands in the Niepołomice Forest (southern Poland). A number of soil parameters were assessed, namely moisture, water holding capacity, electrical conductivity, pH, organic C, total N, respiration, bacterial and fungal biomass and community structure (phospholipid fatty acid and ergosterol analyses). As soil properties are influenced by the quality of leaf litter deposited by trees, senesced Q. rubra and Q. robur leaves were characterized in terms of C, Ca, Mg, K, N, P, total phenolics and condensed tannins concentrations. It was found that total microbial and bacterial biomass was significantly lower under Q. rubra than Q. robur in both soil horizons. Microbial community structure of organic horizon also differed between the two Quercus species. In contrast, no differences were found in fungal biomass and soil physicochemical variables. The reduction in microbial and bacterial biomass beneath Q. rubra may be associated with the quantity and quality of its litter. Senesced Q. rubra leaves were characterized by significantly higher C/N and C/P ratios relative to those of Q. robur. Preliminary data indicate that although they had lower concentrations of phenolics and condensed tannins, the pools of these compounds supplied to the soil were higher due to higher litter production by Q. rubra. Unlabelled Image • Soil properties under invasive Quercus rubra and native Quercus robur were compared. • Q. rubra reduced soil total microbial and bacterial biomass relative to Q. robur. • Soil physicochemical properties did not differ between Q. rubra and Q. robur. • Leaf litter of Q. rubra had higher C/N and C/P ratios than that of Q. robur. • Q. rubra provided the soil with higher amounts of phenolics with its litter. [ABSTRACT FROM AUTHOR]

Published
2019
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