Your search keyword '"Laura Sass"' showing total 4 results

1. 'Beyond an acronym, STEM is…': Perceptions of STEM

Author

Shannon L. Navy, Maggie Zimmerman, Christine Brewster, Fatma Kaya, Brian Boone, Kelly Calvelage, Tanzimul Ferdous, Laura Sass, and Ebony Hood

Subjects

Physics and Astronomy (miscellaneous), media_common.quotation_subject, Informal education, Teacher education, Education, Mathematics (miscellaneous), History and Philosophy of Science, Value judgment, Perception, Pedagogy, Acronym, Psychology, Engineering (miscellaneous), media_common

Published

2020

2. Species richness and taxonomic distinctness of lake macrophytes along environmental gradients in two continents

Author

Laura Sass, Jan Hjort, Maija Toivanen, Jani Heino, Janne Alahuhta, Lucinda B. Johnson, and Frauke Ecke

Subjects

0106 biological sciences, Ecology, 010604 marine biology & hydrobiology, Aquatic ecosystem, Biodiversity, Species diversity, 15. Life on land, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, Freshwater ecosystem, Macrophyte, Phylogenetic diversity, Geography, 13. Climate action, Aquatic plant, ta1181, 14. Life underwater, Species richness

Abstract

The biodiversity of aquatic ecosystems is under threat and there is an urgent need to quantify the various facets of biodiversity to assess the conservation value of freshwater ecosystems. The effects of taxonomic relatedness have so far not been taken into account in biodiversity assessments of lake macrophytes. We therefore tested the response of species richness and average taxonomic distinctness (AvTD) of aquatic macrophytes along environmental gradients using linear regression models and Bayesian Information Criterion variable selection method. We selected data from four regions, each with 50–60 lakes, situated in northern Europe (Finland and Sweden) and northern America (Minnesota and Wisconsin). We separately studied all macrophyte species, hydrophytes and helophytes. Species richness and AvTD of aquatic macrophytes were generally negatively related in all regions, although it was not statistically significant. Both biodiversity measures responded to environmental gradients to various degrees among the studied macrophyte groups and regions. Species richness was best explained by alkalinity and lake area in Finland, by elevation, annual mean temperature and total phosphorus in Minnesota, and by alkalinity in Wisconsin. AvTD was best explained by alkalinity, annual mean temperature and total phosphorus in Finland and by alkalinity in Wisconsin. Very weak relationships were found in Sweden. Our findings strongly suggest that complementary indices are needed to indicate more comprehensively the effects of environmental conditions on freshwater biodiversity. Species richness was found to be a better measure than AvTD to account for conservation value in freshwaters. However, further research is required to evaluate the usefulness of AvTD to indicate conservation value (e.g. randomisation tests), because alternative measures are clearly needed for those freshwater taxa lacking complete information on true phylogenetic diversity.

Published

2017

3. A comparative analysis reveals little evidence for niche conservatism in aquatic macrophytes among four areas on two continents

Author

Jani Heino, Janne Alahuhta, Frauke Ecke, Laura Sass, and Lucinda B. Johnson

Subjects

0106 biological sciences, Ecological niche, Ecology, 010604 marine biology & hydrobiology, Ecology (disciplines), Niche, Global change, Biology, 010603 evolutionary biology, 01 natural sciences, Environmental niche modelling, Macrophyte, Common species, Habitat, ta1181, Ecology, Evolution, Behavior and Systematics

Abstract

One of the most intriguing questions in current ecology is the extent to which the ecological niches of species are conserved in space and time. Niche conservatism has mostly been studied using coarse-scale data of species' distributions, although it is at the local habitat scales where species' responses to ecological variables primarily take place. We investigated the extent to which niches of aquatic macrophytes are conserved among four study regions (i.e. Finland, Sweden and the US states of Minnesota and Wisconsin) on two continents (i.e. Europe and North America) using data for 11 species common to all the four study areas. We studied how ecological variables (i.e. local, climate and spatial variables) explain variation in the distributions of these common species in the four areas using species distribution modelling. In addition, we examined whether species' niche parameters vary among the study regions. Our results revealed large variation in both species' responses to the studied ecological variables and in species' niche parameters among the areas. We found little evidence for niche conservatism in aquatic macrophytes, though local environmental conditions among the studied areas were largely similar. This suggests that niche shifts, rather than different environmental conditions, were responsible for variable responses of aquatic macrophytes to local ecological variables. Local habitat niches of aquatic macrophytes are mainly driven by variations in local environmental conditions, whereas their climate niches are more or less conserved among regions. This highlights the need to study niche conservatism using local-scale data to better understand whether species' niches are conserved, because different niches (e.g. local versus climate) operating at various scales may show different degrees of conservatism. The extent to which species' niches are truly conserved has wide practical implications, including for instance, predicting changes in species' distributions in response to global change.

Published

2016

4. Climate-related differences in the dominance of submerged macrophytes in shallow lakes

Author

Erik Jeppesen, Edwin T. H. M. Peeters, Laura Sass, Nicole Hansel-Welch, Marten Scheffer, Egbert H. van Nes, Torben L. Lauridsen, Jennifer Hauxwell, Amy M. Kamarainen, Néstor Mazzeo, Roger W. Bachmann, Gissell Lacerot, Martin Søndergaard, and Sarian Kosten

Subjects

Aquatic Ecology and Water Quality Management, eutrophic lakes, aquatic macrophytes, aquatic plants, depth, water quality, waterplanten, nitrogen, noord-amerika, klimaat, lakes, diepte, fytoplankton, phosphorus, Periphyton, General Environmental Science, Global and Planetary Change, Ecology, zuid-amerika, Plankton, Macrophyte, communities, europa, stikstof, europe, fosfor, restoration, growth, meren, troebelheid, Subtropics, vegetatie, nutrients, vegetation, Aquatic plant, temperatuur, Phytoplankton, Environmental Chemistry, Dominance (ecology), climate, fish, Hydrology, WIMEK, nutrient, temperature, waterkwaliteit, Aquatische Ecologie en Waterkwaliteitsbeheer, north america, turbidity, voedingsstoffen, south america, phytoplankton, Environmental science, Fish kill, phosphorus concentrations

Abstract

It has been suggested that shallow lakes in warm climates have a higher probability of being turbid, rather than macrophyte dominated, compared with lakes in cooler climates, but little field evidence exists to evaluate this hypothesis. We analyzed data from 782 lake years in different climate zones in North America, South America, and Europe. We tested if systematic differences exist in the relationship between the abundance of submerged macrophytes and environmental factors such as lake depth and nutrient levels. In the pooled dataset the proportion of lakes with substantial submerged macrophyte coverage (430% of the lake area) decreased in a sigmoidal way with increasing total phosphorus (TP) concentration, falling most steeply between 0.05 and 0.2mgL � 1 . Substantial submerged macrophyte coverage was also rare in lakes with total nitrogen (TN) concentrations above 1‐2mgL � 1 , except for lakes with very low TP concentrations where macrophytes remain abundant until higher TN concentrations. The deviance reduction of logistic regression models predicting macrophyte coverage from nutrients and water depth was generally low, and notably lowest in tropical and subtropical regions (Brazil, Uruguay, and Florida), suggesting that macrophyte coverage was strongly influenced by other factors. The maximum TP concentration allowing substantial submerged macrophyte coverage was clearly higher in cold regions with more frost days. This is in agreement with other studies which found a large influence of ice cover duration on shallow lakes’ ecology through partial fish kills that may improve light conditions for submerged macrophytes by cascading effects on periphyton and phytoplankton. Our findings suggest that, in regions where climatic warming is projected to lead to fewer frost days, macrophyte cover will decrease unless the nutrient levels are lowered.

Published

2009