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WOMEN
IN PLANT BIOLOGY
Reflections
on Relevance
by
Mary E. Musgrave
Professor and Head, Department of Plant Science, University of Connecticut;
mary.musgrave@uconn.edu
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Mary
Musgrave
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The first time I thought
seriously about what makes science relevant came during my days as a graduate
student studying the physiological significance of cyanide-resistant respiration
in plants. My major adviser in the Botany Department at Duke University,
then assistant professor Jim Siedow, had given me a grant proposal to
read. I thought that the paragraphs at the beginning of his proposal to
NIH, giving background on the linkage between cyanide-resistant respiration
and disease, “didn’t fit in,” because it was the first
time I had considered that studying plant mitochondria could have medical
applications. Over the intervening years, I saw the relevance of this
basic research on plants to combating human disease; Jim used his extramural
funding from NIH to make many fundamental research discoveries and move
through the ranks as a powerful and effective advocate for science.
In my own first faculty
position, at Louisiana State University, I had the title of plant stress
physiologist. In Louisiana, it was easy to discover the most relevant
environmental problem—soil waterlogging—and the most severely
affected crop—winter wheat. The Louisiana Small Grains Research and
Promotion Board funded work that promised to identify wheat varieties
that best stood up to waterlogging, and this gave me an opportunity to
study physiological traits that confer waterlogging tolerance. Since waterlogging
affects 12% of agricultural soils in the United States as a whole and
a much higher percentage in Louisiana, the relevance of my work was becoming
increasingly clear to me.
Nevertheless, this
relevance was suddenly challenged by an unfortunate national discourse
that arose surrounding “plant stress” at that time (which other
stress physiologists in ASPB no doubt recall). Former President Clinton
chose to ridicule investigators studying plant stress, charging that scientists
should have better things to do with their time and the nation’s
money than fretting over the emotions of vegetables. The fallout was immediate.
Almost overnight, I became an “environmental plant physiologist,”
and my popular graduate course, Plant Stress Physiology, followed suit
with the new name of Environmental Plant Physiology.
In the 1990s, I realized
that what I had learned about waterlogging could be put to use in solving
a persistent problem facing NASA. Plants had been grown in “microgravity”
(<10-3 g) in freely falling orbital spacecraft since the 1960s. However,
by the late 1980s, the problems with getting plants to reproduce in space
had led researchers to conclude that there might be some step in flowering
and seed production that was absolutely dependent on gravity. Waterlogging
research had given me the perspective that the problems faced by plants
growing in microgravity were likely caused by zero-g-related environmental
conditions rather than by any direct biological requirement for gravity.
Microgravity, famous for scenes of astronauts playing with floating globs
of water, also gives us the ultimate in undrained rootzones.
At the time, NASA
had two research programs that sponsored plant research: the Space Biology
Program and the CELSS (Controlled Ecological Life Support System) Program.
The former was dominated by scientists who wanted to use the microgravity
environment to perform basic research on gravitropism, while the latter
was a group of scientists pushing the limits of yield in hydroponic culture
by manipulating light, carbon dioxide, and nutrients, with the long-term
goal of being able to sustain human food and atmosphere regeneration needs
away from Earth.
Program managers in
both groups were convinced that a project investigating the reasons behind
reproductive failure by plants in microgravity fell solidly in the other
program’s camp. However, when I proposed to team up with plant anatomist
Shirley Tucker to tackle this problem, the work qualified as “Space
Biology.” My lab soon had the opportunity to study early reproductive
development in Arabidopsis during a series of experiments on the U.S.
Space Shuttle. Our findings that the microgravity environment was functionally
waterlogging the rootzone due to lack of drainage and starving the plants
for carbon dioxide due to ineffective gas exchange lay the basis for redesigns
of plant growth hardware and cultural practices, so that during the late
1990s and early 2000s, reproduction became a routine success for plants
growing in space. The relevance of terrestrial research to extraterrestrial
systems was immediate and obvious.
Because of the success
of this initial work with Arabidopsis on the space shuttle, NASA soon
gave my group a new opportunity. In 1995, for purposes of foreign policy,
it was decided that a Ukrainian was going to fly on the U.S. Space Shuttle.
This edict was given to NASA, along with the task of selecting a project
that would make best use of the astronaut/cosmonaut’s time in space.
NASA managers had to decide whether a space welding demonstration or experiments
in plant space biology would have greater relevance.
The decision tipped
in the favor of plant space biology when we showed that the experiments
could intercalate with education and outreach by engaging the public in
the scientific process. Discarding Arabidopsis in favor of the more charismatic
Wisconsin Fast Plant (Brassica rapa L., cv. “Astroplants”),
we partnered with Paul Williams, who developed “Teachers and Students
Investigating Plants in Space,” a middle and high school hands-on
curriculum that adapted our flight experiment to the classroom. More than
200,000 students in the United States joined 20,000 students working with
the Ukrainian version of the curriculum. The scope of the project and
intensity of the media coverage during the real-time participation by
students gave us scientists celebrity status. It was a public relations
coup for NASA.
Years passed, and
new opportunities came for experiments in space. My experience with a
national-scale outreach project earned me the position of associate dean
in the College of Natural Sciences and Mathematics at the University of
Massachusetts–Amherst. After four years in this role, I found myself
missing the relevance of my background as a plant scientist to my daily
work.
It was while I was
interviewing for the Plant Science Department head position at the University
of Connecticut that I had a mishap at the Dairy Bar. During one of the
dental visits that followed, I happened to notice that the Highlights
for Children I was reading had run an article about my research, “Farming
in Space.” Knowing that Highlights has a readership of about
4 million, I strangely felt that I had arrived.
Surely of all scientists,
plant scientists have the greatest opportunity to devote their lives to
relevant pursuits. From our antecedents in agronomy, horticulture, and
forestry, we inherit the scientific stewardship of the world’s food
supply, its atmosphere regeneration, and its nutrient and water cycling.
The green revolution, biofuels, phytoremediation, nutriceuticals, sustainability,
seeds . . . our list of key words goes on and on.
For my group, hooked
on space biology, thoughts now turn away from weightless plants to those
that will grow in habitats on the moon or Mars. The relevance test continues:
I am in Washington, D.C., taking a cab to the National Academies building,
and the driver’s eyes narrow back at me in the rearview mirror. “Are
you some kind of scientist?” As I explain my work, he nods in slow
understanding and grudging respect. I realize anew that it is a privilege
to be a scientist. Much of a scientist’s satisfaction comes from
the simple joy of discovery, but it is just as important that what we
do matters to the rest of the world—that we are, in a word, relevant.
View past columns
of Women in Plant Biology at http://www.aspb.org/newsletter/wipb.cfm.
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