RESUMEN
Habitat fragmentaion into small patches is regarded as a vital cause of biodiversity loss. Fragmentationof habitat-forming species is especially harmful, as patchiness of such species often controls ecosystem stability and resilience by density and patch size-dependent self-reinforcing feedbacks. Although fragmentation are expected to weaken or even break such feedbacks, it remains unclear how the resulting patchiness of habitat-forming species affect ecosystem resilience to environmental stresses. Here, using Spartian alterniflora, the habitat-forming species in saltmarshes as a model, we investigate how patch size, plant density, and shell aggregation interactively control the persistence of a degrading salt marsh that suffered from erosion induced by hydrodynamics. Our results demonstrate that large patches can trap more shells along the patch edge than the smaller ones, therefore significantly facilitating plant re-growth within the patch. Shell removal experiments further reveal that large patches trapping more shells along patch edges reinforce their own persistence by decreasing erosion and thus facilitating plant recovery. By contrast, small patches with lesser plants cannot persist as they trap less shells along patch edges but are able to accumulate more shells at interior locations where they hinder plant re-growth, indicating a critical threshold of patch size ~20 m2 below which ecosystem collapses. The current study highlights the importance to identify critical threshold of stress-resistant patch sizes in transition-prone ecosystems as early-warning to alert undesired ecosystem collapse and restoration practice.
Asunto(s)
Ecosistema , Humedales , Biodiversidad , PoaceaeRESUMEN
Invasion of habitat-modifying nonnative species and alteration of ecosystem engineer by exploitation are two of the dominant human impacts on natural ecosystem functioning. The effects of these co-occurring ecosystem engineers may act simultaneously and vary independently depending on ambient environmental conditions they modify. Using a saltmarsh ecosystem with continuing invasion of nonnative cordgrass and aggregation of native bivalve shells, we tested whether the ecosystem engineering effects of shell aggregation on macroinvertebrates depended on the plants due to their ability to trap shell debris. We found habitats covered with shell aggregation and vegetated cordgrass significantly increase the biodiversity but decrease the biomass of macroinvertebrates comparing to the tidal bare flats, whereas no differences were detected among shell covered, cordgrass vegetated and their coexistent habitats. Our study highlights the importance of considering multiple, potentially conflicting management goals, which may require flexibility and trade-offs to integrate nonnative and native resources into ecosystem management.
Asunto(s)
Bivalvos , Ecosistema , Animales , Biodiversidad , Biomasa , Humanos , PlantasRESUMEN
The competition-to-stress hypothesis suggests that some competitively disadvantaged species are excluded from higher inundation estuaries due to abiotic stress (high flooding level) and from lower inundation estuaries by competition. How abiotic and biotic stress interactions affect plant growth and whether competition intensity and importance are stable along environmental gradients is a controversial subject. We explored the influence of two factors, and we clarified that inundation stress and invasion competition are the main reasons leading to the traits exhibited by target plant Suaeda salsa and population presence changes. Our results indicated that when the flooding height exceeded 13.4 cm, the S. salsa mortality rate was 90%-100%. At the lower flooding heights (<13.4 cm), the S. salsa mortality rate when neighboring plants were present was 77.7%-100%, whereas, without neighbors it was 30.9%-83.7%. The invader Spartina alterniflora inhibited S. salsa plant height by 48%-77%, whereas the S. alterniflora inhibited S. salsa density by 11%-98% and reduced its biomass by 50.5%-90.1%. The changes in competition intensity and importance showed that the S. alterniflora had a distinct impact from the early germinant period to growing period (from May to July), finally stable no differences along the flooding height in the maturity period. At the same flooding level, the analysis of above and belowground competition by S. alterniflora showed that aboveground and belowground competition are the main causes of individual S. salsa inhibition. Our results confirm the competitive stress hypothesis, which is that competition shapes individual traits and population presence in the context of abiotic stress. This conclusion can guide the management and protection of native plants under biological invasion in a stressful environment.
Asunto(s)
Chenopodiaceae , Estuarios , China , Inundaciones , Poaceae , HumedalesRESUMEN
Understanding plant traits in response to physical stress has been an important issue in the study of coastal saltmarshes. For plants that reproduce both sexually and asexually, whether and how seedlings (sexual reproduction) and clonal ramets (asexual reproduction) may differentially respond to tidal inundation is still unclear. We investigated the growth and morphology of sexual and asexual propagules of an exotic saltmarsh plant (Spartina alterniflora) along a gradient of tidal submergence in the Yellow River Delta. Our results showed that the density, height and basal diameter of clonal ramets or sexual seedlings increased with tidal inundation. The patch amplification edge clonal ramets are superior than patch center plants. The differences response of plants to tidal inundation highlight the sensitivity of S. alterniflora to future tidal regime shifts and can help predict and evaluate the impacts of changes in inundation conditions due to sea level rise, coastal erosion and human activities.