scholarly journals Phenotypic plasticity and adaptive evolution contribute to advancing flowering phenology in response to climate change

2012 ◽  
Vol 279 (1743) ◽  
pp. 3843-3852 ◽  
Author(s):  
Jill T. Anderson ◽  
David W. Inouye ◽  
Amy M. McKinney ◽  
Robert I. Colautti ◽  
Tom Mitchell-Olds
Keyword(s):  
Climate Change ◽  
Phenotypic Plasticity ◽  
Adaptive Evolution ◽  
Field Experiments ◽  
Flowering Phenology ◽  
Directional Selection ◽  
Major Life ◽  
Quantitative Genetic ◽  
Evolutionary Response

Anthropogenic climate change has already altered the timing of major life-history transitions, such as the initiation of reproduction. Both phenotypic plasticity and adaptive evolution can underlie rapid phenological shifts in response to climate change, but their relative contributions are poorly understood. Here, we combine a continuous 38 year field survey with quantitative genetic field experiments to assess adaptation in the context of climate change. We focused on Boechera stricta (Brassicaeae), a mustard native to the US Rocky Mountains. Flowering phenology advanced significantly from 1973 to 2011, and was strongly associated with warmer temperatures and earlier snowmelt dates. Strong directional selection favoured earlier flowering in contemporary environments (2010–2011). Climate change could drive this directional selection, and promote even earlier flowering as temperatures continue to increase. Our quantitative genetic analyses predict a response to selection of 0.2 to 0.5 days acceleration in flowering per generation, which could account for more than 20 per cent of the phenological change observed in the long-term dataset. However, the strength of directional selection and the predicted evolutionary response are likely much greater now than even 30 years ago because of rapidly changing climatic conditions. We predict that adaptation will likely be necessary for long-term in situ persistence in the context of climate change.

scholarly journals Evidence for continent-wide convergent evolution and stasis throughout 150 years of a biological invasion

2021 ◽  
Author(s):  
Yihan Wu ◽  
Robert I Colautti
Keyword(s):  
Adaptive Evolution ◽  
Fossil Record ◽  
Field Experiments ◽  
Common Garden ◽  
Lythrum Salicaria ◽  
Natural Systems ◽  
Continental Scale ◽  
Evolutionary Response ◽  
Temperature Records ◽  
Growing Conditions

The extent to which evolution can rescue a species from extinction, or facilitate range expansion, depends critically on the rate, duration, and geographical extent of the evolutionary response to natural selection. While field experiments have demonstrated that adaptive evolution can occur quickly, our understanding of the duration and geographical extent of contemporary evolution in natural systems remains limited. This is particularly true for species with large geographical ranges and for timescales that lie between 'long-term' field experiments and the fossil record. Here, we introduce the Virtual Common Garden (VCG) to estimate genetic differences among phenotypes observed in natural history collections. Reconstructing 150 years of evolution in Lythrum salicaria (purple loosestrife) as it invaded across North America, we analyze phenology measurements of 3,429 herbarium records, reconstruct growing conditions from more than 12 million local temperature records, and validate predictions across three common gardens spanning 10 degrees of latitude. We find that phenology evolves rapidly and repeatedly along parallel climatic gradients during the first century of evolution. However, the rate of microevolution stalls thereafter, recapitulating macroevolutionary stasis observed in the fossil record. Our study demonstrates why preserved specimens are a critical resource for understanding limits to evolution in natural. Our results show predictability of evolution emerging at a continental scale across 15 decades of rapid, adaptive evolution.

The Biochar challenge in Mediterranean viticulture: results from 10 years of field experiment

2020 ◽  
Author(s):  
Silvia Baronti ◽  
Anita Maienza ◽  
Fabrizio Ungaro ◽  
Antonio,Antonello Montagnoli ◽  
Lorenzo Genesio ◽  
...  
Keyword(s):  
Climate Change ◽  
Field Experiment ◽  
Water Relations ◽  
Soil Amendment ◽  
Field Experiments ◽  
Central Italy ◽  
Plant Water ◽  
Grape Quality ◽  
Mediterranean Countries

<p>There are extensive reports and scientific articles in literature on the applicability of biochar as soil amendment in agriculture and on the benefits that this practice can bring in terms of soil improvement and optimization of water resources. The use of biochar as a soil amendment in agriculture is a suitable option that helps to mitigate the effects of climate change. Biochar has an approximate mean residence time in the soil over 1,000 years and this long-term stability is a fundamental prerequisite for considering biochar as a suitable method for carbon sequestration. Unfortunately, most literature provides results based on one-year trials. Not enough for a soil amendment to be able to claim effectiveness for many decades and not enough for a soil treatment to be considered irreversible. An effective option to fill this knowledge gap is represented by long-term field experiments. In this study, we investigated the effect of biochar application on plant water relations and soil properties during 10 years in a field experiment in Central Italy on Vitis vinifera. Biochar was applied at a rate of 22 t ha-1 in two consecutive growing seasons: 2009 and 2010. The results obtained during these years on biochar treatment compared to the control treatment are exciting: we demonstrated an increase in grape production, up to 66%, without a decrease of the grape quality, an increase in plant-soil water relations, no effects on the concentrations of soil PAHs, no eco-toxicity soil effect and a positive effect on soil chemical and biological parameters. Surprisingly, after 10 years the biochar effect continued to demonstrate significant differences among treatments, in particular: a significant increase of soil biological quality, decrease in soil bulk density coupled with a corresponding increase in saturated hydraulic conductivity, an enhance in soil available water content and a significant improvement of plant water status. The modification of plant water availability induced by biochar application increase the resilience of vineyards to droughts, as demonstrated by the lower leaf potential and higher stomatal conductance. This effect has a significant impact on quantity and quality of grape production after 10 years. Moreover, in the long-term perspective the biochar demonstrates to have an effect on soil biological communities that resulted sensitive to biochar with positive increase of abundance of species related to soil moisture content and enhance of biodiversity index. According to these results, the viticulture is now in the position to provide an effective contribution to mitigate climate change and we expect that this will be an example for other Mediterranean countries.</p>

Behavioral, plastic, and evolutionary responses to a changing world

2018 ◽  
Author(s):  
Wolf U. Blanckenhorn
Keyword(s):  
Climate Change ◽  
Life History ◽  
Environmental Change ◽  
Physiological Responses ◽  
Short Term ◽  
Temporal Scales ◽  
Evolutionary Response ◽  
Physiological Adjustments ◽  
Changing World

Organisms can respond to environmental change by modifying their behavior to obtain an instant response, through short-term phenotypically plastic, often physiological, adjustments, and/or by adapting their life history through a more long-term evolutionary response. Behavioural and physiological responses, in fact, can occur at all these three temporal scales. Examples of behaviors so affected include congregation, dispersal, foraging, migration, or mating. Such responses have consequences at the population and community levels, and ultimately for the evolution of species. This chapter discusses insect examples of these kinds, with an emphasis on human-induced factors, such as (primarily) climate change, pollution, fragmentation, and urbanization.

Monitoring agroecological transformation processes induced by climate and agricultural innovations over time and space

2021 ◽  
Author(s):  
Heide Spiegel ◽  
Julia Miloczki ◽  
Bernhard Freyer ◽  
Andreas Surböck ◽  
Jürgen K. Friedel ◽  
...  
Keyword(s):  
Climate Change ◽  
Field Experiments ◽  
Agricultural Land ◽  
Arable Land ◽  
Agricultural Management ◽  
Soil Tillage ◽  
Agroecological Zones ◽  
Long Term Ecological Research ◽  
Agricultural Innovations

<p>Sustainable agricultural production of food, feed, fibre and fuel with limited agricultural land to cover human demands and at the same time to secure natural resources is currently one of the biggest global challenges. Changes in agricultural management to ensure fertile soils, stable yields and product qualities and to avoid adverse environmental impacts, affect various soil and plant characteristics, agrobiodiversity and the micro-climate of agroecosystems.</p><p>Long-term field experiments (LTEs) are indispensable to detect and understand impacts of climate (drought, heat, floods, frost) and agricultural innovations on soils and plants. Amongst agricultural innovations are adaptions of crop rotations to climate change, efficient fertilisation systems with and without livestock, reduced soil tillage intensity, the conversion of a whole landscape section from conventional to organic farming and introducing landscape elements like flowering strips or hegdes that serve, e.g., as habitats for pollinators and beneficials.</p><p>For the evaluation of impacts of climate change and agricultural innovations, researchers of agricultural long-term ecological research (LTER) sites in Austria have developed indicators to enable the systematic comparison of long-term trials impact on soil-plant systems in different agroecological zones of Austria and Europe, respectively, including different agro-ecosystems, e.g., arable land and grassland. Examples for soil indicators include soil characteristics like organic carbon, nutrients and contaminants, biological and physical (e.g., porosity, structure) indicators that have already been measured since many years in various field experiments. Embedded in long-term socio-ecological regions (LTSER), which allow analyzing long-term socio-economic and biophysical drivers of change in agricultural management, these agricultural LTER sites contribute crucial insights into the interaction between nature and society.</p>

Importance and necessity of long-term field experiments

2010 ◽  
Vol 58 (Supplement 1) ◽  
pp. 7-11
Author(s):  
T. Kismányoki
Keyword(s):  
Climate Change ◽  
Sustainable Development ◽  
Field Experiments ◽  
Long Term Effects ◽  
Nutrient Balances ◽  
The Sustainable Development ◽  
Term Data ◽  
Made In ◽  
Term Field

The importance and necessity of long-term field experiments lie in the fact that long-term effects can only be studied reliably over several decades. The agronomic advances made in recent decades, based on chemicals and genetic gains, can be measured using long-term data, which will also be important in the future. Nutrient balances can be estimated reliably from the results of these experiments. The effect of climate change can be estimated by comparing long-term data from different locations. Long-term databases also form the background for computer models, designed to promote the sustainable development of agriculture and the environment.

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