Variabilité saisonnière et interannuelle de la croissance du chêne vert méditerranéen et vulnérabilité au changement climatique / Seasonal and inter-annual growth variations and vulnerability to climate change in Mediterranean Quercus ilex

Lempereur, Morine

22 July 2015

La croissance secondaire est à l'origine de l'accumulation de biomasse pérenne par les arbres et détermine en partie la capacité des écosystèmes forestiers à stocker du carbone. Cependant, les contraintes environnementales sur la croissance en milieu méditerranéen sont encore mal décrites et nous ne savons pas comment les changements climatiques futurs vont les modifier. L'objectif de la thèse est de déterminer, principalement à partir de l'étude de l'allocation du carbone à la croissance secondaire, les réponses fonctionnelles saisonnières et interannuelles du chêne vert (Quercus ilex L.) aux variations climatiques en région méditerranéenne. L'utilisation de différentes approches expérimentales, à des échelles spatiales allant du cerne à l'écosystème et à des échelles temporelles allant de la journée à plusieurs dizaines d'années, a permis de mettre en évidence l'effet de différentes contraintes environnementales (disponibilité en eau, réchauffement de la température, et densité du peuplement) sur la croissance secondaire et la composition isotopique du cerne. L'étude de la phénologie de la croissance montre que celle-ci est contrôlée directement par les températures hivernales et le déficit hydrique, plus que par la disponibilité en éléments carbonés issus de la photosynthèse. De 1968 à 2013, les changements climatiques ont entrainé une contrainte hydrique de plus en plus précoce qui s'est trouvée compensée par un début de croissance initié plus tôt dans l'année, sous l'effet du réchauffement des températures hivernales, et une meilleure efficacité d'utilisation de l'eau, sous l'effet de l'augmentation de la concentration en CO2 atmosphérique. La réduction de la mortalité et l'augmentation de la croissance observée dans des parcelles éclaircies montre que cette pratique sylvicole permet de préparer les taillis de chêne vert à l'intensification de la sècheresse prévue pour la région méditerranéenne. / Tree secondary growth is responsible for woody biomass accumulation and is a major component of carbon storage in forest ecosystems. Environmental constraints on secondary growth in Mediterranean ecosystems must, however, be described in more to details to better understand how they will be modified by climate change. This dissertation aims at studying the functional responses of Mediterranean holm oak (Quercus ilex) to seasonal and inter-annual climate variations through the study of carbon allocation to secondary growth. Different experimental approaches, at spatial scales ranging from tree rings to the ecosystem and at temporal scales from the day to several decades, were used to identify the main environmental constraints (water availability, temperature warming, competition) to secondary growth and carbon isotopic composition of tree rings. The phenology of stem growth shows evidence for a direct environmental control on annual growth by winter temperature and summer drought that is more limiting than the carbon supply from photosynthesis. Climate change from 1968 to 2013 resulted in earlier water limitation on secondary growth, which was compensated by earlier growth onset, due to warmer winter temperature, and higher water use efficiency, due to increased atmospheric CO2 concentration. Thinning reduced tree mortality and increased stem growth, so thinning management in old holm oak coppices could prepare the ecosystem to better withstand the increasing drought forecasted for the Mediterranean region.

Croissance secondaire

Phénologie

Déficit hydrique

Changement climatique

Flux de carbone

Isotope du carbone

Secondary growth

Phenology

Water limitation

Climate change

Carbon flux

Carbon isotope

A simple net ecosystem productivity model for gap filling of tower-based fluxes

Zisheng, Xing

January 2007

In response to global climate change, many important earth-systems-oriented science programs have been established in the past. One such program, the Fluxnet program, studies the response of world forests and other natural ecosystems by measuring biospheric fluxes of carbon dioxide (CO2), water vapour, and energy with eddy-covariance (EC) techniques to assess the role of world ecosystems in offsetting increases in CO2 emissions and related impacts on global climate. The EC methodology has its limitations particularly when weather is inclement and during system stoppages. These limitations create non-trivial problems by creating data gaps in the monitored data stream, diminishing the integrity of the dataset and increasing uncertainty with data interpretation. This Thesis deals with the development of a parsimonious, semi-empirical approach for gap filling of net ecosystem productivity (NEP) data. The approach integrates the effects of environmental controls on diurnal NEP. The approach, because of its limited number of parameters, can be rapidly optimized when appropriate meteorological, site, and NEP target values are provided. The procedure is verified by applying it to several gap-filling case studies, including timeseries collected over balsam fir (Abies Balsamea (L.) Mill.) forests in New Brunswick (NB), Canada and several other forests along a north-south temperaturemoisture gradient from northern Europe to the Middle East. The evaluation showed that the model performed relatively well for most sites; i.e., r2 ranged from 0.68-0.83 and modelling efficiencies, from 0.89-0.97, demonstrating the possibility of applying the model to forests outside NB. Inferior model performance was associated with sites with less than complete input datasets.

Zisheng Xing

temperature and moisture effects

parsimonious

parameterization

numerical methods

environmental gradients

ecosystems

light use efficiency

gross productivity

flux Canada

tower-based flux

soil moisture control

temperature control

numerical modelling

flux

carbon flux

gap filling

Net ecosystem productivity

A design of experiments approach for engineering carbon metabolism in the yeast Saccharomyces cerevisiae

Brown, Steven Richard

January 2016

The proven ability to ferment Saccharomyces cerevisiae on a large scale presents an attractive target for producing chemicals and fuels from sustainable sources. Efficient and predominant carbon flux through to ethanol is a significant engineering issue in the development of this yeast as a multi-product cell chassis used in biorefineries. In order to evaluate diversion of carbon flux away from ethanol, combinatorial deletions were investigated in genes encoding the six isozymes of alcohol dehydrogenase (ADH), which catalyse the terminal step in ethanol production. The scarless, dominant and counter- selectable amdSYM gene deletion method was optimised for generation of a combinatorial ADH knockout library in an industrially relevant strain of S. cerevisiae. Current understanding of the individual ADH genes fails to fully evaluate genotype-by-genotype and genotype-by-environment interactions: rather, further research of such a complex biological process requires a multivariate mathematical modelling approach. Application of such an approach using the Design of Experiments (DoE) methodology is appraised here as essential for detailed empirical evaluation of complex systems. DoE provided empirical evidence that in S. cerevisiae: i) the ADH2 gene is not associated with producing ethanol under anaerobic culture conditions in combination with 25 g l-1 glucose substrate concentrations; ii) ADH4 is associated with increased ethanol production when the cell is confronted with a zinc-limited [1 μM] environment; and iii) ADH5 is linked with the production of ethanol, predominantly at pH 4.5. A successful metabolic engineering strategy is detailed which increases the product portfolio of S. cerevisiae, currently used for large-scale production of bioethanol. Heterologous expression of the cytochrome P450 fatty acid peroxygenase from Jeotgalicoccus sp., OleTJE, fused to the RhFRED reductase from Rhodococcus sp. NCIMB 978 converted free fatty acid precursors to C13, C15 and C17 alkenes (3.81 ng μl-1 total alkene concentration).

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