Biotic and abiotic drivers of species loss rate in isolated lakes

Today, anthropogenic impacts are causing a serious crisis for global biodiversity, with rates of extinction increasing at an unprecedented rate. Extinctions typically occur after a certain delay, and understanding the mechanisms causing delays is a key challenge for both fundamental and applied pers...

Full description

Saved in:
Bibliographic Details
Published in:The Journal of animal ecology 2019-06, Vol.88 (6), p.881-891
Main Authors: Bellard, Céline, Englund, Göran, Hugueny, Bernard, Noelia Barrios‐Garcia, M.
Format: Article
Language:English
Subjects:
age
Animals
Anthropogenic factors
aquatic ecosystems
Biodiversity
Biodiversity and Ecology
Biotic factors
Climate Change
Climate effects
Climate models
Ecology, environment
Ecosystems
Endangered & extinct species
Environmental changes
Environmental factors
Environmental Sciences
Extinction
Extinction, Biological
fragmentation
Human influences
isolation
Lakes
Life Sciences
pH effects
piscivores
Scandinavian and Nordic Countries
Species
Uplift
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Today, anthropogenic impacts are causing a serious crisis for global biodiversity, with rates of extinction increasing at an unprecedented rate. Extinctions typically occur after a certain delay, and understanding the mechanisms causing delays is a key challenge for both fundamental and applied perspectives. Here, we make use of natural experiments, the isolation of lakes by land uplift in Northern Scandinavia, to examine how yearly extinction rates are affected by time since isolation and a range of abiotic and biotic factors. In this aim, we adapted a model of delayed species loss within isolated communities to test the effects of time since isolation, area, pH, depth and the presence/absence of piscivores on extinction rates. As expected, we found that small and/or young lakes experience a higher annual rate of extinctions per species than larger and/or older ones. Compared to previous studies that were conducted for either young (few thousand years ago) or very old (>10,000 years ago) isolates, we demonstrated over a large and continuous temporal scales (50–5,000 years), similar relationship between extinction rates and age. We also show that extinction rates are modified by local environmental factors such as a strong negative effect of increasing pH. Our results urge for the need to consider the time since critical environmental changes occurred when studying extinction rates. In a wider perspective, our study demonstrates the need to consider extinction debts when modelling future effects of climate change, land‐use changes or biological invasions on biodiversity. Today, anthropogenic impacts are causing a serious crisis for global biodiversity, with rates of extinction increasing at an unprecedented rate. Extinctions typically occur after a certain delay, and understanding the mechanisms causing delays is a key challenge for both fundamental and applied perspectives. Here, the authors make use of natural experiments, the isolation of lakes by land uplift in Northern Scandinavia, to examine how yearly extinction rates are affected by time since isolation and a range of abiotic and biotic factors.
ISSN:0021-8790
1365-2656
1365-2656
DOI:10.1111/1365-2656.12980