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U of T plant biologists use high-tech growth chambers to develop stronger crops

"The ultimate goal is to translate our research into improved crop varieties that can support local agriculture"
Jenan Noureddine examines plants being grown indoors under a growth lamp

Jenan Noureddine, a PhD candidate in U of T Scarborough's department of biological sciences, examines plants being grown indoors under a growth lamp (all photos by Don Campbell)

In the basement of the Ƶ Scarborough’s Science Research Building are four chambers that look like industrial walk-in fridges in a restaurant – but they’re high-tech labs where biologists are conducting plant experiments that could one day lead to more resilient food crops.

Located in the building’s Plant Growth Facility, these newly installed chambers are equipped to mimic different types of growing conditions, with researchers able to control heat, humidity and light intensity as well as speed and direction of wind inside the chambers – enabling them to test the effects of stressors such as drought, heat and infections on plant growth.

There’s even an astronomical clock that can recreate the average amount of sunlight during different times of year in any part of the world.

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Each chamber has a growing space of 18 cubic metres and the top shelf can move up or down to make space for tall plants to grow

Here, Jenan Noureddine, a PhD candidate in the department of biological sciences, checks on the state of her Arabidopsis plants. These small, flowering plants are related to cabbage and mustard and are among the most widely studied by plant biologists due to their status as a model organism.

“The ultimate goal is to translate our research into improved crop varieties that can support local agriculture,” says Adam Mott, an assistant professor in the department of biological sciences who manages the facility.

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PhD candidate Jenan Noureddine ties the Arabidopsis stems to wooden sticks to provide structural support for the plants, allowing them to grow upright and protecting them from damage.

In all, the facility contains 21 growth chambers used for a range of plant experiments, including identifying genes that are important for disease resistance and proteins that help regulate growth and development. 

Mott says an important feature of the four new chambers is the ability to control carbon dioxide levels, which will allow scientists in the facility to develop experiments to study climate change. 

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This instrument precisely measures carbon dioxide concentrations – a novel feature of the new growth chambers.

The chambers can be set to 75 per cent humidity (90 per cent with the lights off) and reach a maximum temperature of 40 degrees Celsius – conditions akin to the Amazon rainforest during summer. Each chamber has a growing space of 18 cubic metres and the top shelf can move up or down to make space for tall plants to grow.

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Researchers wear sunglasses with UV protection to shield from the light.

Their brightest setting can output nearly as much light as a sunny day in Toronto during the summer. The LED lights in the newer chambers can get so intense that UV protective eyewear is recommended as a safety precaution. 

 

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PhD candidate Aparna Bhasin injects bacteria containing a gene receptor from Arabidopsis into her Nicotiana plant. This particular gene was chosen because it’s been shown to improve immunity to pathogens in other plants.

The new growth chambers received funding courtesy of a grant from the Office of the Vice-Principal Research and Innovation at U of T Scarborough.

 

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