How can genomic information help improve technologies for reducing the environmental impacts of human activities?
Adrian Tsang
- Professor
- Department of Biology
- Director
- Centre for Structural and Functional Genomics
- genomics31
- enzymes for industrial processes7
- fungal genomics5
- bioproduct development6
- biofuels and biochemicals7
- transcriptomics7
- thermophilic fungi
- biomass-degrading enzymes6
- synthetic biology19
- renewable energy31
- proteomics16
- gene annotation
- recombinant enzymes7
- enzymology12
- biotechnology31
- genetics16
- bioinformatics18
- molecular and cellular biology27
- phylogenomics2
-
David Secko
science/technology communication, role of journalism, new models of journalism
-
Gregory Butler
bioinformatics, big data, genomics
-
Justin Powlowski
environmental chemistry, biomass-degrading enzymes, bioremediation strategies
-
Reginald Storms
renewable energy, biofuels and biochemicals, bioremediation strategies
-
David Kwan
synthetic biology, molecular and cellular biology, directed evolution
-
Vincent Martin
synthetic biology, bioproduct development, microbial genomics
-
Isabelle Benoit
fungal physiology, fungal genomics, lignocellulosic biomass
-
Malcolm Whiteway
candida albicans, biomedical engineering, cell cycle control
-
Patrick Gulick
plant abiotic stress tolerance, gene regulation, stress response signaling pathways
-
Laurent Potvin-Trottier
synthetic biology, systems biology, microfluidics
-
Michael T. Hallett
computational biology, bioinformatics, systems biology
-
Paul Joyce
tRNA nucleotidyltransferase, biochemistry of cell membranes, protein targeting
-
Steve Shih
microfluidics, synthetic biology, biofuels and biochemicals
-
Luc Varin
plant molecular genetics, plant growth and development, stress response signaling pathways
-
Madoka Gray-Mitsumune
pedagogy, educational technologies, academic integrity
-
Aashiq H. Kachroo
yeast systems genetics, synthetic biology, systems biology
-
Andrew Delong
deep learning, genomics, machine learning
-
Peter D. Pawelek
siderophore-mediated iron uptake, bacterial iron uptake, bacterial pathogenesis
-
Michael Sacher
vesicle recognition, biochemistry of cell membranes, protein complexes
-
Nawwaf Kharma
soft computing, synthetic biology, image processing
-
William Zerges
photosynthesis, chlamydomonas reinhardtii, chloroplast biogenesis
-
Alisa Piekny
cytoskeleton regulation, cytokinesis, mitosis
-
Selvadurai Daya Dayanandan
evolutionary genomics, molecular systematics, population genetics
-
Vladimir Titorenko
aging (ageing), mechanics of apoptosis, anti-aging molecules
-
Joanne L. Turnbull
enzymology, protein engineering, catalysis
-
Ann M. English
cell signaling, molecular and cellular biology, peroxidases
-
Jin Suk Lee
cell signaling, peptide signals, plant biology
-
Muthukumaran Packirisamy
micro/nano devices, microfabrication, MEMS/NEMS
-
Guillaume Lamoureux
molecular modeling, computational biophysical chemistry, computational enzymology
-
David Walsh
aquatic ecology, molecular and cellular biology, evolutionary biology
-
Sana Jahanshahi-Anbuhi
biosensors, biomarkers and diagnostics, bioactive paper devices (µPADs)
-
Brandon Findlay
drug discovery, directed evolution, metabolic engineering
-
Amir Asif
signal processing, array processing, distributed particle filter
-
Dajana Vuckovic
metabolomics, mass spectrometry, solid-phase microextraction
-
Christopher Brett
endocytic system, biochemistry of cell membranes, mechanisms of autophagy
-
Cameron D. Skinner
gestational diabetes, amniotic fluid bioanalysis, bioanalytical chemistry
-
Chiara Gamberi
RNA biology, messenger RNA translation, Drosophila
-
Andreas Bergdahl
atherosclerosis, cardiovascular health, human physiology
-
Chris Wilds
nucleic acid chemistry, X-ray crystallography, organic synthesis
-
Lea Popovic
probability theory, randomness in the living world, mathematical biology
-
Mojtaba Kahrizi
nanosystems, quantum devices, MEMS/NEMS
-
Tagny Duff
viral media, biomedia, vitalities