Fine-Scale Distribution Patterns of Phragmites australis Populations Across an Environmental Gradient in the Salt Marsh Wetland of Dunhuang, China

Jiao, Liang; Li, Fang; Liu, Xuerui; Wang, Shengjie; Zhou, Yi

doi:10.3390/su12041671

Cited by 4 publications

(4 citation statements)

References 68 publications

(68 reference statements)

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“…Appropriate salt supplementation can increase fiber content and biomass, making it healthier and more robust ( Guan et al., 2017 ). Soil salinity plays a dominant role in determining the growth of P. australis , and high salinity limits the population’s survival ( Schenck et al., 2018 ; Jiao et al., 2020 ; Zhang et al., 2021b ; Barbafieri et al., 2023 ). The results showed that the variation coefficients of plant height at low tidal flat and biomass at high tidal flat of P. australis were 37.06% and 44.6%, respectively, indicating that these two morphological traits were largely affected by environmental factors ( Table 2 ).…”

Section: Discussionmentioning

confidence: 99%

“…Soil water content, pH and salinity all affected the spatial distribution intensity of P. australis . Specifically, the spatial distribution pattern intensity was positively correlated with density, height, biomass and stem diameter ( P < 0.01) ( Jiao et al., 2020 ). Soil salinity plays a leading role in the stoichiometric characteristics of carbon, nitrogen, and phosphorus in P. australis leaves and roots ( Zhang et al., 2021b ), which indicates that soil salinity also indirectly influences the stoichiometric characteristics of soil carbon, nitrogen, and phosphorus in P. australis habitat.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Ecophysiological responses of Phragmites australis populations to a tidal flat gradient in the Yangtze River Estuary, China

Jia,

Zhao,

Jia

et al. 2024

Front. Plant Sci.

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Phragmites australis is a prevalent species in the Chongming Dongtan wetland and is capable of thriving in various tidal flat environments, including high salinity habitats. P. australis population displays inconsistent ecological performances, highlighting the need to uncover their survival strategies and mechanisms in tidal flats with diverse soil salinities. Upon comparing functional traits of P. australis at multiple tidal flats (low, middle, and high) and their responses to soil physicochemical properties, this study aimed to clarify the salt-tolerant strategy of P. australis and the corresponding mechanisms. These results showed that leaf characteristics, such as specific leaf area and leaf dry matter content, demonstrated more robust stability to soil salinity than shoot height and dry weight. Furthermore, as salt stress intensified, the activities of superoxide dismutase (SOD), catalase (CAT) and peroxisome (POD) in P. australis leaves at low tidal flat exhibited an increased upward trend compared to those at other tidal flats. The molecular mechanism of salt tolerance in Phragmites australis across various habitats was investigated using transcriptome sequencing. Weighted correlation network analysis (WGCNA) combined with differentially expressed genes (DEGs) screened out 3 modules closely related to high salt tolerance and identified 105 core genes crucial for high salt tolerance. Further research was carried out on the few degraded populations at low tidal flat, and 25 core genes were identified by combining WGCNA and DEGs. A decrease in the activity of ferroptosis marker gonyautoxin-4 and an increase in the content of Fe3+ in the degenerated group were observed, indicating that ferroptosis might participate in degradation. Furthermore, correlation analysis indicated a possible regulatory network between salt tolerance and ferroptosis. In short, this study provided new insights into the salt tolerance mechanism of P. australis population along tidal flats.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Ecophysiological responses of Phragmites australis populations to a tidal flat gradient in the Yangtze River Estuary, China

Jia,

Zhao,

Jia

et al. 2024

Front. Plant Sci.

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“…recent studies have demonstrated that some clonal plants may be suitable for repairing and restoring vulnerable habitats. These include (a) clonal plants in karst landform habitats, such as Ficus tikoua [20], Alchornea trewioides [21], and Drepanostachyum luodianense [22]; (b) clonal plants in deserts, such as Calamagrostis epigejos [23], Hedysarum leave [24], Hippophae rhamnoides L., Psammochloa villosa [25], and Stenocereus eruca (Cactaceae) [26]; (c) clonal plants in grasslands, such as Leymus chinensis [27,28], Zoysia japonica Steud [29,30], and Buchloe dactyloides [31]; (d) clonal plants in wetlands, such as Phragmites australis [32,33], Paspalum paspaloides [34], Acorus calamus L., and Spartina alterniflora Loisel [34]. Researchers have also been keen to study the invasion mechanism in invasive clonal plants such as Alternanthera philoxeroides [35], Solidago canadensis L. [36], Carpobrotus edulis [37], and Mikania micrantha H.B.K.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Strategies Employed by Clonal Plants in Heterogeneous Patches

Yang

Huang

et al. 2023

Forests

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Heterogeneity is widespread in natural environments; as a result, connected clonal ramets often live in areas characterized by patches of different resources. Specifically, clonal plants are frequently affected by conditions of heterogeneous water stress. This raises the question of how clonal plants grow and reproduce in areas with patches of different resources. In this study, we investigated the adaptation mechanisms of clonal plants under heterogeneous environmental conditions. On the one hand, we bore in mind that phenotypic plasticity is abundantly exhibited in clonal plants. Clonal plants respond to water stress mainly through regulation of the size of individuals, the allocation of population biomass, and the number of daughter plants, as well as the extension ability and branching intensity of clonal organs, which directly affect reproduction and population stability in clonal plants. On the other hand, we also considered the physiological integration in clonal plants which has been shown in many studies. Ramets of clonal plants normally stay connected to each other through horizontal connectors (stolons or rhizomes). Communicated substances and resources such as water, mineral nutrition, photosynthetic products, and secondary metabolites are translocated between ramets; by such means, the plant relieves stress caused by heterogeneous patches. In this study, we sought to obtain scientific references to improve our understanding of how clonal plants in natural environments acclimate to stresses caused by soil heterogeneity.

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“…As a result, some potential limitations are gradually emerging in the sustainable restoration efficiency [6]. Plant populations present different spatial patterns at different spatial scales under the influence of these biological interactions and ecological processes [7]. Therefore, the potential biological interactions and ecological process within saltcedar populations can be explored through spatial pattern analysis, which will provide theoretical guidance for saltcedar restoration [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Spatial Analysis as a Tool for Plant Population Conservation: A Case Study of Tamarix chinensis in the Yellow River Delta, China

et al. 2021

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Saltcedar (Tamarix chinensis) is undergoing population declination and fragmentation due to climate change and human disturbance. The existing restoration strategies usually focus on improving the environmental conditions based on the environment–saltcedar relationship, while they ignore the role of spatial autocorrelation resulting from biological interaction and ecological processes. This oversight limits the efficiency and sustainability of the restoration. Here, we explored the spatial pattern of the saltcedar population in the Yellow River Delta, China, and its relationship with environmental factors, incorporating spatial autocorrelation. The plant and soil parameters were extracted by an airborne LiDAR system integrated with fixed soil environment measurements. The environment–saltcedar relationship incorporating spatial autocorrelation was evaluated with different regression models. Results showed that saltcedars aggregated at small scales (2–6 m), resulting from intraspecific facilitation and wind dispersal of seeds, while intraspecific competition was responsible for the random distribution at large scales (>10 m). The long-distance dispersal of seeds through water explained the significant positive spatial autocorrelation of saltcedars at distances up to 125 m. Consequently, resulting from intraspecific facilitation and seed dispersal, aggregation distribution and positive spatial autocorrelation within the saltcedar population improved the adaptability of saltcedar to environmental stress and thereby reduced the impact of environmental factors on the abundance of saltcedar.

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Fine-Scale Distribution Patterns of Phragmites australis Populations Across an Environmental Gradient in the Salt Marsh Wetland of Dunhuang, China

Cited by 4 publications

References 68 publications

Ecophysiological responses of Phragmites australis populations to a tidal flat gradient in the Yangtze River Estuary, China

Ecophysiological responses of Phragmites australis populations to a tidal flat gradient in the Yangtze River Estuary, China

Adaptive Strategies Employed by Clonal Plants in Heterogeneous Patches

Spatial Analysis as a Tool for Plant Population Conservation: A Case Study of Tamarix chinensis in the Yellow River Delta, China

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