Dr. Claire Depardieu-Innovative leadership - Excellence in Research 

Université Laval-Canada

Author profile 

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Early Academic Pursuits

Dr. Claire Depardieu's academic journey has been marked by a passion for plant physiology, bioinformatics, genomics, environmental sciences, and agronomy. She holds a Master's degree in Forestry, Agronomy, and Environmental Sciences from the University of Nancy, France, and a Ph.D. in Plant Physiology from the University of Franche-Comté, France. During her Ph.D., she extensively studied the response of sessile and pedunculate oaks to waterlogging, focusing on the expression of aquaporins and their potential role in root water transport.

Professional Endeavors

Following her academic pursuits, Dr. Depardieu embarked on three postdoctoral research programs, delving into bioinformatics and genomics at the University of Toronto, agronomy at Université Laval, and forest genomics at Université Laval. Her research contributions include 18 scientific articles in peer-reviewed journals, with six more manuscripts in preparation or submission. She has actively represented her research groups at international conferences in Europe, the United States, and Canada.

Contributions and Research Focus

Dr. Depardieu's research interests revolve around plant acclimatization and adaptation to climate change, with a specific focus on understanding the physiological and molecular processes involved in abiotic stress tolerance. Specialized in plant ecophysiology and functional genomics, she has significantly contributed to unraveling the genetic and physiological basis of drought adaptation in conifers.

Accolades and Recognition

Throughout her career, Dr. Depardieu has earned accolades and recognition for her outstanding contributions. Notably, she received the second prize for the best post-doctoral presentation at the CFGA national colloquium in 2021 and secured the cover page feature for her scientific publication in Molecular Ecology. Her involvement with the International Student Network for Climate UniC highlights her commitment to climate change research and leadership in the scientific community.

Impact and Influence on innovative leadership 

As an attached researcher in forest genomics at Université Laval and Natural Resources Canada, Dr. Depardieu has played a crucial role in coordinating and contributing to research projects. Notable projects include FastTRAC II and Spruce-Up, where she led activities related to genomic relations, growth, climate sensitivity, and coordination of radio-isotope projects.

Dr. Claire Depardieu exemplifies innovative leadership in the field of plant sciences and genomics. Her ability to seamlessly integrate diverse expertise in plant physiology, bioinformatics, and agronomy showcases a holistic and forward-thinking approach to research. Driven by a passion for addressing critical challenges such as climate change, she consistently seeks novel perspectives and methodologies. As a coordinator for research projects like FastTRAC II and Spruce-Up, she has demonstrated leadership by fostering collaboration with external partners, developing cutting-edge research projects, and steering the teams towards achieving project objectives. Her innovative leadership is evident in the intersection of her scientific acumen, effective project coordination, and commitment to advancing knowledge in genomics and environmental sciences.

Legacy and Future Contributions

Dr. Depardieu's legacy lies in her multifaceted expertise encompassing plant physiology, genomics, and agronomy. Her research has contributed to advancing the understanding of tree adaptation to changing climates. As she continues to excel in her current roles and contributes to various projects, her future contributions are anticipated to further enrich the fields of forest genomics and climate adaptation.

This comprehensive overview underscores Dr. Claire Depardieu's remarkable academic and professional journey, her significant contributions to the scientific community, and the potential for continued impact in her field.

Notable publications 

• Tree rings provide a new class of phenotypes for genetic associations that foster insights into adaptation of conifers to climate change
• Hydraulic efficiency and coordination with xylem resistance to cavitation, leaf function, and growth performance among eight unrelated Populus deltoides× Populus nigra hybrids
• Adaptive genetic variation to drought in a widely distributed conifer suggests a potential for increasing forest resilience in a drying climate
• Sawdust and bark-based substrates for soilless strawberry production: Irrigation and electrical conductivity management
• Strong overestimation of water‐use efficiency responses to rising CO₂ in tree‐ring studies