Recently, our own Berkley Walker was recorded skiing across campus on the eve of a polar vortex. That recording went viral. Read why he thinks plants are even hardier than he was that day.
New research reveals a protein, TGNap1, that supports the poorly-understood Trans-Golgi Network in structure, function, and motion. The study also provides evidence for microtubule-driven organelle movement, a new line of thought in plant science.
A Lansing State Journal story features Dr. Brandizzi, Evan Angelos, a fourth-year doctoral student, Starla Zemelis-Durfee, Brandizzi lab manager, and their research on how plants grow in and respond to stressful environments.
For the fifth year in a row, the faculty members have been recognized in the Highly Cited Researchers List, an annual compilation of the global leaders in scientific influence by Clarivate Analytics.
MSU scientists report how cyanobacteria line up their CO2-fixing factories within them in a system that works like Velcro. The research is part of an effort to control and repurpose these factories to make products for human consumption.
The new methods let scientists assemble the factories on demand and insert custom molecules inside them for further processing. The aim is to eventually design sustainable medical, industrial, or energy applications.
Castroverde, a post-doc in the He lab who researches how climate conditions influence plant defense responses, has won a Natural Sciences and Engineering Research Council of Canada Postdoctoral Fellowship.
Can plants defend and grow simultaneously? The answer could help us understand natural ecosystems or help farmers increase yields without increasing dependence on pesticides.
A new study identifies 111 peroxisomal proteins, including six newly identified ones, in dark-treated plants. It is part of an effort to fully map the functions of plant peroxisomes.
When facing drought or heat stress, roots are advance scouts that warn the rest of the plant to prepare for the big 'hit.'
A multi-university study reveals how plant communication systems respond to threats from herbivores. Once wounded, plants use calcium signals to warn distant tissues of future attacks.
The recent PRL alumnus from the Howe lab will train students, maintain facilities, and teach classes on analytical chemistry and lab equipment usage.
Atmospheric scientists factor lesser known photosynthesis research into their models. The result: carbon levels in the air could be much higher by 2100 than previously predicted.
The freshly minted PRL alumnus, a former member of the Hu and He labs, will explore how pathogenic microbes manipulate plant communication systems to their advantage.
The system lowers cultivation and harvesting costs and increases productivity, factors that currently hold back biofuels from being widely adopted.