Genome Projects include the study of many kinds of organisms that are important in our daily lives, for example bacteria. One of the most important groups of bacteria in the world is also one of the least known by many people—microbes that cause the formation of nodules on the roots of many plants. Inside these nodules specialized bacteria convert atmospheric nitrogen into a chemically useful form, which is essential for plant growth and thus ultimately for life on Earth. One of the beststudied nitrogenfixing bacteria is called S. meliloti, which fixes nitrogen in the roots alfalfa and other plants.
We aim to understand more about S. meliloti by using genomic methods to study its genes—how they direct nitrogen fixation and many other important biochemical reactions.
Using complex genetic methods, we constructed lightemitting versions of almost 50% of S. meliloti proteins. This gave us an easy way to measure the amount of these proteins present in S. meliloti cells, a reflection of genetic activity, under over 100 conditions of growth. We used similar genetic methods to remove many individual genes from the S. meliloti genome. This enabled us to learn how the absence of these genes affected bacterial growth under many conditions. We used a method called DNA microarraying to measure geneexpression from all S. meliloti genes (6,200). The deeper understanding of S. meliloti growth that stems from our research will lead to better and more environmentally friendly methods of nitrogen fixation for the food and agricultural industries in Canada and the world.
- Creation of a body of knowledge about S. meliloti, a bacterium that fixes nitrogen, which is an essential process for plant growth.
- Number of research personnel employed by the project: 28 undergraduates, 9 graduate students, 3 fellows, 15 technicians
- Number of peer-reviewed publications: 17 research papers
- Co-funders: McMaster University, Ontario Research Development Challenge
- Fund, Premier’s Research Excellence Fund, Canada Foundation for Innovation, University of Waterloo