Facilitation of a tropical seagrass by a chemosymbiotic bivalve increases with environmental stress

Chin, Daeje; Fouw, Jimmy de; Heide, Tjisse van der; Cahill, Brianna V.; Katcher, Kevin; Paul, Valerie J.; Campbell, Justin E.; Peterson, Bradley J.

doi:10.1111/1365-2745.13462

Cited by 16 publications

(18 citation statements)

References 89 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For instance, recent work revealed that the endosymbiotic gill-bacteria are also capable of nitrogen fixation (diazotrophy), which suggests that, apart from sulfide detoxification, the lucinid− bacteria consortium might also benefit seagrasses under nutrient-poor conditions by providing nitrogen (König et al 2017, Petersen et al 2017, Cardini et al 2019). In contrast, other studies have shown that sediment porewater nutrients are de creased in the presence of lucinids, suggesting that lucinids could cause or amplify nutrient limitation for seagrasses (van der Heide et al 2012, König et al 2017, Chin et al 2021. Clearly, the nutritional role of the facultative mutualistic interaction under different environmental conditions in seagrass systems is unclear.…”

Section: Increased Temperature Reduces the Positive Effect Of Sulfide...mentioning

confidence: 97%

“…The bacteria and the lucinid bivalves form a symbiotic relationship in which the clams transport sulfide and oxygen to their gills where the bacteria oxidize sulfide for synthesizing sugars that fuel the growth of both organisms (Cavanaugh 1983, van der Heide et al 2012. In this way, the seagrass and the lucinid−bacteria consortium engage in a facultative mutualism in which the seagrass provides the clams and their bacteria with sulfide and oxygen, while the seagrass profits from the removal of toxic sulfides (van der Heide et al 2012, van der Geest et al 2020, Chin et al 2021.…”

Section: Increased Temperature Reduces the Positive Effect Of Sulfide...mentioning

confidence: 99%

See 1 more Smart Citation

Increased temperature reduces the positive effect of sulfide-detoxification mutualism on Zostera noltii nutrient uptake and growth

Fouw

Rehlmeyer

Geest

et al. 2022

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

Seagrass meadows form essential ecological components in coastal zones but are rapidly declining worldwide due to anthropogenic impacts, including eutrophication and climate change-related heat waves. An important consequence of increased eutrophication is organic matter input in the sediment, which, together with raised temperatures, stimulates the production of toxic sulfide. Although multiple recent studies have highlighted that seagrass can engage in a mutualistic relationship with lucinid bivalves alleviating sulfide toxicity in the rhizosphere, it remains unclear how this mutualism is affected by temperature and eutrophication. To unravel this relation, we investigated the response of the seagrass Zostera noltii to contrasting sediment organic matter conditions, temperatures and presence/absence of the lucinid clam Loripes orbiculatus in a full-factorial mesocosm experiment. Results demonstrate that temperature increased porewater sulfide and nutrient levels, particularly in treatments with high sediment organic matter content. Interestingly, L. orbiculatus reduced not only sulfide levels, but also porewater nutrients. The removal of sulfide in turn stimulated Z. noltii growth, despite lower nutrient availability. Finally, increased temperature suppressed the mutualistic benefit for Z. noltii as sulfide detoxification became hampered. We conclude that, as eutrophication remains an issue in the coastal zone and temperature extremes will likely become more common in the future, seagrass meadows where lucinids occur may need to increasingly rely on this mutualism. At the same time, however, this interaction will become more strained, with an inherent increasing risk of mutualism breakdown.

show abstract

Section: Increased Temperature Reduces the Positive Effect Of Sulfide...mentioning

confidence: 97%

Section: Increased Temperature Reduces the Positive Effect Of Sulfide...mentioning

confidence: 99%

Increased temperature reduces the positive effect of sulfide-detoxification mutualism on Zostera noltii nutrient uptake and growth

Fouw

Rehlmeyer

Geest

et al. 2022

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

show abstract

“…Considering differences in seagrass ontogeny as well as site characteristics and bivalve type will be key to determining the role of positive interactions and expanding the theoretical framework for restoration. In addition to nitrogen deposition, bivalves may facilitate seagrasses by reducing sulfide concentrations in the sediment (van der Heide et al, 2012;de Fouw et al, 2016;Chin, 2020;Van Der Geest et al, 2020) or by consuming and reducing epiphyte loads that could otherwise hinder seagrass photosynthesis (Peterson and Heck, 2001a,b). Although we did not test for the effect of bivalves on epiphytes in our experiments, we suspect that this mechanism would have had a stronger effect on the adult transplant experiment where clams were significantly larger than seed clams (<1 cm umbo width).…”

Section: Intra-but Not Interspecific Facilitation Enhances Adult Seagrass Planting Successmentioning

confidence: 99%

Inclusion of Intra- and Interspecific Facilitation Expands the Theoretical Framework for Seagrass Restoration

et al. 2021

View full text Add to dashboard Cite

Restoration is increasingly utilized as a strategy to stymie the loss of coastal habitats. Coastal habitat restoration has predominantly emphasized designs that minimize physical stress and competition. As evidence of the pervasiveness of this approach, we conducted a global survey of seagrass restorationers and found a strong affinity for stress-avoidant designs with adult shoots in dispersed rather than aggregated configurations. To test the alternative hypothesis that including positive interactions can enhance restoration success, we experimentally incorporated: (i) interspecific facilitation (clam additions) into seed sowing, and (ii) both intra- and interspecific facilitation (planting a single-large versus multiple-small patches and adding clams) into shoot planting. Clam additions to seeds significantly enhanced plant biomass and patch size; and nutrient analysis suggested the causative mechanism was clam enhancement of available nitrogen. In contrast, adult outplant growth was enhanced by intra- but not inter-specific facilitation. Dispersed configurations consistently declined, whereas large-intact patches, which had the same initial biomass as dispersed plots, increased in patch area and doubled in shoot density. These results demonstrate that expanding restoration strategies to include positive interactions with respect to seagrass ontogeny has the capability to switch the trajectory of restoration from failure to success.

show abstract

“…This holobiont was suggested to form a positive nested interaction with seagrasses (van der Heide et al, 2012). In this example of a nested ecosystem, the clam and its microbial symbionts are suggested to contribute to the removal of sulfide (toxic to the plant) from the sediments and thus to enhance seagrass growth (Chin et al, 2021). Additionally, a role of the lucinid clam Loripes orbiculatus in N provisioning to the seagrass ecosystem was recently proposed, given the ability of the symbionts to also fix atmospheric N 2 (Petersen et al, 2017;Cardini et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Nested interactions between chemosynthetic lucinid bivalves and seagrass promote ecosystem functioning in contaminated sediments

et al. 2022

View full text Add to dashboard Cite

In seagrass sediments, lucinid bivalves and their chemoautotrophic bacterial symbionts consume H2S, relying indirectly on the plant productivity for the presence of the reduced chemical. Additionally, the role of lucinid bivalves in N provisioning to the plant (through N2 fixation by the symbionts) was hypothesized. Thus, lucinids may contribute to sediment detoxification and plant fitness. Seagrasses are subject to ever-increasing human pressure in coastal environments. Here, disentangling nested interactions between chemosynthetic lucinid bivalves and seagrass exposed to pollution may help to understand seagrass ecosystem dynamics and to develop successful seagrass restoration programs that consider the roles of animal-microbe symbioses. We evaluated the capacity of lucinid bivalves (Loripes orbiculatus) to promote nutrient cycling and seagrass (Cymodocea nodosa) growth during a 6-week mesocosm experiment. A fully crossed design was used to test for the effect of sediment contamination (metals, nutrients, and hydrocarbons) on plant and bivalve (alone or interacting) fitness, assessed by mortality, growth, and photosynthetic efficiency, and for the effect of their nested interaction on sediment biogeochemistry. Plants performed better in the contaminated sediment, where a larger pool of dissolved nitrogen combined with the presence of other trace elements allowed for an improved photosynthetic efficiency. In fact, pore water nitrogen accumulated during the experiment in the controls, while it was consumed in the contaminated sediment. This trend was accentuated when lucinids were present. Concurrently, the interaction between clams and plants benefitted both organisms and promoted plant growth irrespective of the sediment type. In particular, the interaction with lucinid clams resulted in higher aboveground biomass of C. nodosa in terms of leaf growth, leaf surface, and leaf biomass. Our results consolidate the notion that nested interactions involving animal-microbe associations promote ecosystem functioning, and potentially help designing unconventional seagrass restoration strategies that exploit chemosynthetic symbioses.

show abstract

Facilitation of a tropical seagrass by a chemosymbiotic bivalve increases with environmental stress

Cited by 16 publications

References 89 publications

Increased temperature reduces the positive effect of sulfide-detoxification mutualism on Zostera noltii nutrient uptake and growth

Increased temperature reduces the positive effect of sulfide-detoxification mutualism on Zostera noltii nutrient uptake and growth

Inclusion of Intra- and Interspecific Facilitation Expands the Theoretical Framework for Seagrass Restoration

Nested interactions between chemosynthetic lucinid bivalves and seagrass promote ecosystem functioning in contaminated sediments

Contact Info

Product

Resources

About