At the current warming rate, many organisms should go extinct if they are not able to disperse or adapt locally, which often involves plastic responses. In ectotherms, warming influences plastic life history traits with an acceleration of early life production at the expense of longevity and senescence. This may be due to trade-offs involving warming-induced oxidative stress and telomere shortening. Although pace-of-life acceleration may provide short-term benefits, it also increases sensitivity to limited resources, extreme climate events and unusual nighttime thermal conditions. Thus, in an increasingly warmer climate, ectotherms could reach critical physiological thresholds that would precipitate their decline. To date, physiological mechanisms and ecological consequences of this pace-of-life acceleration are poorly characterized. Here, we will combine experimental, observational and analytical approaches to unlock critical gaps in our understanding of thermal plasticity of life history. We will focus on a bimodal reproductive lizard (Zootoca vivipara), which offers a unique context to analyze how evolutionary transition between oviparity and viviparity influenced pace-of-life acceleration. Using long-term data sets and surveys across climatic gradients, we will document patterns of pace-of-life acceleration in response to climate warming in the two reproductive modes, focusing on vulnerable populations of the warm margin. In addition, we will perform outdoor and laboratory experiments to identify physiological tipping points in the context of day-night asymmetry of warming and extreme climate events. Given their major potential role in this thermal plasticity, non-energetic trade-offs will be quantified using longitudinal and cross-sectional assays of oxidative stress and telomere length dynamics. Altogether, this project will highlight patterns, mechanisms, and consequences on population viability of pace-of-life acceleration in response to climate warming.

Nitrogen protoxide (N2O) is a powerful greenhouse gas (GHG), with an impact 300 times higher than carbon dioxide, contributing significantly to global warming. Microbial processes (nitrification or denitrification) in soils or water contribute significantly to the production of N2O. To date, the contribution of wastewater management is still controversial as N2O emissions were poorly measured in wastewater treatment plants. Recent campaigns demonstrated however that the values assumed by the IPPC are much lower than reality. Moreover intensification of nitrogen removal in wastewater treatment and innovation for minimizing energy consumption can potentially increase the N2O emissions if nitrification and denitrification are insufficiently controlled with appropriate tools. This project aims to quantify, model and reduce N2O emissions from wastewater treatment facilities. The ambition of the project is to evaluate solutions in intensive processes receiving domestic wastewater which are used for nutrient removal. The project is divided in different tasks: (1) monitoring of full scale systems during long term campaigns, (2) tracking the main microbial pathways by innovative techniques (isotopes signature and NO:N2O ratio), (3) validation of a multiple pathway model for simulation and evaluation of mitigation strategies, (4) demonstration of innovative sensors and control tools for energy reduction and N2O mitigation. N2OTRACK will provide representative and objective information on direct greenhouse gas emissions from depollution systems. The contribution of these systems to the national anthropogenic N2O emissions will be estimated. Special effort will be deployed on biofilters at full scale, systems poorly characterized so far. The aim is also to provide an N2O modelling framework validated by lab-scale data with isotopic signature measurements and calibrated by full scale campaigns. Finally innovative control tools based on well-known and new sensors will be developed for both activated sludge processes and biofilters. The project involves six partners: three academic laboratories (LISBP-INSA, IEES-UPMC, RBPE-ECOBIO), one applied research institute (IRSTEA), a large WWTP facility (SIAAP-Paris) and a private company SME (BIOTRADE).

The project NatInControl aims to develop a collaborative structure of research and development between the Institute of Ecology and Environmental Sciences of Paris (iEES-Paris) and the SBM group. This association aims to bring together two entities working for many years in their respective sectors on insect pest problems. The iEES-Paris team involved in the project develop fundamental and applied research on biology / physiology of insect pests and the impacts of pesticides on their biology. The SBM group is meanwhile specialized in the development, manufacture and distribution ranges of crop protection products for professionals and individuals. Carried on mutual purpose, the NatInControl project will aim to identify and develop new effective biocontrol solutions on insect pests. The issue is to propose new effective products, environmentally friendly and safe for human to meet various regulatory and societal changes.

In the context of climate change, the impact of earthworms on soil porosity and thus soil water characteristics becomes of increasing significance. The project PRECIOUS aims to define new functional groups for predicting soil water fluxes and water storage and test the complementarity of these groups to mitigate the impact of extreme events on soil water dynamics. Functional groups will be defined in the laboratory from earthworm morphological traits and the 3D characteristics of their galleries (30 Megascolecidae in Vietnam and 30 Lumbricidaein France), as well as their effects on soil hydraulic conductivity and water retention. The relevance of the functional groups will be tested in 28 lysimeters in Vietnam using different assemblages of functional groups. Water flows will be monitored, covering seasonal rainfall variations, and modelled to test different scenarios of extreme climatic events. This project will have a strong impact on future research in the field of functional ecology and agricultural management.

Summary Tropical tree plantations provide indispensable renewable goods to the global market and family farms represent the majority of their surface area and production. To ensure the sustainability of plantation systems, environmental and socio-economic conditions should remain favorable during several decades. How can such conditions be ensured when the environment is changing? Even if the local consequences of global increase in temperature are difficult to assess, the farmers will probably face a more variable climate, with probable changes in rain patterns. Moreover, all natural resources have recently faced hugely variable prices related to variations in global demand. High prices attract new investors and drive the extension of plantations into new areas, inducing land-use changes and changes in farming structures. The final aim of the project is to analyze how smallholder’s tree plantations can adapt and keep sustainable whereas they face variable climatic conditions and deep changes in their socio-economic context. Do farmers perceive these risks and do they initiate adaptive strategies? Rubber tree-based systems in Thailand will be used as a model of tropical family plantations integrated in a major global commodity channel. The project will assess both the specificities of rubber cropping and the more general features of tree plantations. The originality of the project relies on the multi-disciplinary approach of both the characterization of changes and their consequences on rubber plantations and the related risks for farmers. Plant and soil sciences will be associated to social sciences and economics. We will analyze the way socio-economic factors interact with biophysical factors to determine farmers’ vulnerability or adaptability to changes. This will require the identification of relevant indicators to measure farmers’ adaptation, and the impacts of changes on sustainability and resilience of the systems. We will refer to the Sustainable Livelihood Framework (Ellis, 2000) to represent the household/holding , combined with the OECD risk matrix (2009) to assess households’ viability. We will focus on two major factors, (i) the type of holdings, particularly the emergence of new investors and (ii) the share-cropping contracts that frame the management of plantations. The main biophysical risk relate to climate changes and to the extension of plantations in new and more adverse areas. We will evaluate the risks at plot or farm levels, as well as potential externalities, in terms of soil sustainability (soil fertility preservation related to soil physical quality and soil functional diversity) and tree adaptation to water stress. Specific ecological constraints linked to the different cultivation area will be considered. In the North-eastern rubber extension area, the climate is drier and the soil fertility is low, whereas in the traditional area (South) continuous rubber cropping occurs for more than 50 years (third cycle). In the North, the specific issue of rubber installation in mountainous area will particularly focus on the effects of terracing, considering the impact on water flow and water balance. A typology of rubber farming systems and of practices will be proposed from socio-economic survey, particularly regarding land management and latex harvesting systems. The impact of practices on economic performances, soil physical and bio-functioning will be evaluated through specific indicators that will be developed or adapted in the perspective of multi-criteria evaluation of plantation systems. The information will be integrated at different scales from plot to farm and watershed and shared with stakeholder through a co-innovation platform. Beside the specific case of rubber plantations, a more generic output of the project is to determine, through modelling and risk framework analysis, the most significant indicators to be observed to assess the long-term adaptation and sustainability of tree-based family farms.