Understanding variation in salamander ionomes: A nutrient balance approach

Prater, Clay; Scott, David E.; Lance, Stacey L.; Nunziata, Schyler O.; Sherman, Ryan E.; Tomczyk, Nathan J.; Capps, Krista A.; Jeyasingh, Punidan D.

doi:10.1111/fwb.13216

Cited by 12 publications

(17 citation statements)

References 52 publications

(131 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although similar data are becoming available for a few other taxa (e.g. arthropods, Goos et al 2017; fish, Rudman et al 2019; amphibians, Prater et al, 2019), the majority of such work do not characterise ionomic responses to changes in elemental supply. Unlike autotrophs, the responses of metazoan consumer ionomes to changes in inorganic nutrient supply include associated ionomic changes in diet (Jeyasingh & Pulkkinen 2019).…”

Section: Introductionmentioning

confidence: 99%

Phosphorus supply shifts the quotas of multiple elements in algae and Daphnia: ionomic basis of stoichiometric constraints

et al. 2020

Self Cite

View full text Add to dashboard Cite

The growth rate hypothesis posits that the rate of protein synthesis is constrained by phosphorus (P) supply. P scarcity invokes differential expression of genes involved in processing of most if not all elements encompassing an individual (the ionome). Whether such ionome‐wide adjustments to P supply impact growth and trophic interactions remains unclear. We quantified the ionomes of a resource‐consumer pair in contrasting P supply conditions. Consumer growth penalty was driven by not only P imbalance between trophic levels but also imbalances in other elements, reflecting complex physiological adjustments made by both the resource and the consumer. Mitigating such imbalances requires energy and should impact the efficiency at which assimilated nutrients are converted to biomass. Correlated shifts in the handling of multiple elements, and variation in the supplies of such elements could underlie vast heterogeneity in the rates at which organisms and ecosystems accrue biomass as a function of P supply.

show abstract

Section: Introductionmentioning

confidence: 99%

Phosphorus supply shifts the quotas of multiple elements in algae and Daphnia: ionomic basis of stoichiometric constraints

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…Rather, such changes in one element invariably interacts with other elements in the extracellular or intracellular environment, with important correlated impacts on functional traits of organisms (e.g., Baxter 2015;Jeyasingh et al 2017). Data on such interactions are important to characterize the biogeochemical niches of taxa (Peñuelas et al 2019), and illuminate a wider set of physiological mechanisms that taxa employ to acclimate or adapt to ecosystems with contrasting biogeochemistry (e.g., Goos et al 2017;Prater et al 2019;Rudman et al 2019), including Fe supply. Indeed, Spijkerman et al (2007) found that at high concentrations, Fe binds to the cell membrane of Chlamydomonas and inhibits transport of bulk elements such as P.…”

Section: Introductionmentioning

confidence: 99%

“…A t-test was used to test the effect of iron treatment on the iron content of Daphnia soma and eggs.To explore correlated changes in the ionomes of algae and Daphnia due to iron treatment (and associated shifts in algal and daphniid iron contents), we utilized a nutrient balance approach(Parent et al 2013). As elaborated inPrater et al (2019), this approach enables unbiased estimates of multivariate relationships among elements, which avoid violating common statistical assumptions and can be used to describe and interpret elemental interactions in organismal tissues. Nutrient balances represent orthogonal log contrasts of elements derived from binary partitions of multivariate elemental data projected into Euclidean space.…”

mentioning

confidence: 99%

Does differential iron supply to algae affect Daphnia life history? An ionome-wide study

Jeyasingh

Pulkkinen

2019

Oecologia

Self Cite

View full text Add to dashboard Cite

The availability of iron (Fe) varies considerably among diet items, as well as ecosystems. Availability of Fe has also changed due to anthropogenic environmental changes in oceanic as well as inland ecosystems. We know little about its role in the nutrition of ecologically important consumers, particularly in inland ecosystems. Physiological studies in several taxa indicate marked effects of dietary Fe on oogenesis. We predicted that differential Fe supply to algae will impact algal Fe concentration with consequences on the life history of the freshwater grazer, Daphnia magna. We found that algal Fe concentration increased with Fe supply, but did not affect algal growth, indicating that the majority of experimental Fe additions were likely adsorbed to, or stored in algal cells. Regardless, data indicate that algal Fe impacted Manuscript Click here to access/download;Manuscript;Oecologia ms.docx Click here to view linked References the reproductive traits (age and size at maturity) but not juvenile growth rate of Daphnia. A subsequent experiment revealed that Fe concentration in eggs was significantly higher than the rest of Daphnia. These results indicate that the concentration of Fe in or on algal cells may vary considerably among ecosystems overlying distinct geological formations differing in Fe, possibly with important implications for zooplankton life histories. Understanding the mechanisms underlying this response is unlikely to be accomplished by a strict focus on Fe because we found correlated shifts in the algal ionome, with concomitant ionome-wide adjustments in Daphnia. Information on ionome-wide responses may be useful in better understanding the responses of biota to changes in the supply of any one element.

show abstract

“…Salamanders represent a large standing stock of nutrients in aquatic systems [108], but the nutrient composition of salamander species may change across ontogenetic stages [109]. Although salamanders usually have a lower capacity of nutrient recycling compared to other aquatic vertebrates such as fish species because excretion rates are higher in fish species [110,111], it is expected that salamanders can be important recyclers of biologically essential nutrients in fishless systems [21,111].…”

Section: Salamanders As Energy Subsides For Higher Trophic Levelsmentioning

confidence: 99%

Reciprocal Role of Salamanders in Aquatic Energy Flow Pathways

Sánchez‐Hernández

2020

Diversity

View full text Add to dashboard Cite

Many species of salamanders (newts and salamanders per se) have a pivotal role in energy flow pathways as they include individuals functioning as prey, competitors, and predators. Here, I synthesize historic and contemporary research on the reciprocal ecological role of salamanders as predators and prey in aquatic systems. Salamanders are a keystone in ecosystem functioning through a combination of top–down control, energy transfer, nutrient cycling processes, and carbon retention. The aquatic developmental stages of salamanders are able to feed on a wide variety of invertebrate prey captured close to the bottom as well as on small conspecifics (cannibalism) or other sympatric species, but can also consume terrestrial invertebrates on the water surface. This capacity to consume allochthonous resources (terrestrial invertebrates) highlights the key role of salamanders as couplers of terrestrial and aquatic ecosystems (i.e., aquatic–terrestrial linkages). Salamanders are also an important food resource for other vertebrates such as fish, snakes, and mammals, covering the energy demands of these species at higher trophic levels. This study emphasizes the ecological significance of salamanders in aquatic systems as central players in energy flow pathways, enabling energy mobility among trophic levels (i.e., vertical energy flow) and between freshwater and terrestrial habitats (i.e., lateral energy flow).

show abstract

Understanding variation in salamander ionomes: A nutrient balance approach

Cited by 12 publications

References 52 publications

Phosphorus supply shifts the quotas of multiple elements in algae and Daphnia: ionomic basis of stoichiometric constraints

Phosphorus supply shifts the quotas of multiple elements in algae and Daphnia: ionomic basis of stoichiometric constraints

Does differential iron supply to algae affect Daphnia life history? An ionome-wide study

Reciprocal Role of Salamanders in Aquatic Energy Flow Pathways

Contact Info

Product

Resources

About