Researcher Makenzie Mabry

Makenzie Mabry

A feral past may help chart the future for Brassica vegetables

June 22, 2021 By Roger Meissen in Research

Illustration of wild relative brassica cretica next to modern broccoli, cabbage and kohlrabi — Although Brassica cretica doesn’t look much like cabbage, broccoli or kohlrabi, the wild relative is the closest relation to our modern vegetables and its endurance might show us how to make our vegetable crops more resilient in the future. | Illustration courtesy of Andi Kur

By Roger Meissen | Bond LSC

You might not envision plant scientists as the modern-day Indiana Jones of biology, but University of Missouri researchers have been hot on the hunt for an evolutionary history, looking for clues to the ancestors of our gardens and grocery shelves.

To find the closest wild relative of the wide-ranging plant species Brassica oleracea, Makenzie Mabry and the Chris Pires lab figuratively combed the hills and seashores of Europe, Africa and the Mediterranean to find a long-lost cousin to many of our vegetable staples.

What they found brings together a puzzling past of a species that could provide insight for conservation and breeding efforts for the future of our vegetables.

“These wild relatives — because they are not under cultivation like our crops — have adapted differently and might be better at herbivory defenses or might be more drought tolerant, and knowing where things were domesticated may help identify genes for those traits,” said Mabry, a principal author and recent Mizzou doctoral graduate. “With techniques like CRISPR, we can look at these differences among wild relatives once they’ve been identified using family trees, and then in the future, hopefully, breeders can then move those traits into the plants, which could help our crops dealing with future climate change.”

The Family Bush

The family structure for mustards to cabbages and everything in between is a messy one.

“Charles Darwin really plugged for evolution to be thought of as a tree with branching patterns, but he did say, well, you know, in some cases, maybe it’s really more like a coral or a shrub,” said Pires, principal investigator and co-investigator on this project. “It’s like the branches are all mixed together, and this paper is revealing Brassica as a classic case of this, a very shrubby ancestry. It’s a mess.”

Whether it’s a bush or a coral, the tangle of Brassica oleracea species show a full gambit of diversification.

You have versions of the species that evolved their leaves into staples like cabbage or kale, others where flowers or inflorescences were domesticated into what we eat now as broccoli or cauliflower and even more that put their efforts into underground parts like kohlrabi.

Pires likens this to how modern dogs have diversified into starkly different breeds from Great Dane to chihuahua.

“You got dogs with big heads and ones wagging fluffy tails and others with little-bitty feet, but they are all still the same in that they are all clearly dogs, right?” Pires said. “Just like dogs, Brassica has shown so much plasticity during its domestication, but many still think of each vegetable as distinct branches and that’s obviously not at all what has happened.”

Pinpointing the origin

This path to finding ancestors and relatives of Brassica oleracea requires covering a lot of territory from comparing thousands of genes to scrutinizing ancient texts on cabbage to analyzing trade routes in the Mediterranean Sea.

Recent theories on the origin of Brassica oleracea have ranged from believing there is a single common ancestor to multiple domestication attempts from several ancestors. Despite these hypotheses, it had yet to have been fully confirmed. From England to France to Spain, each region has a certain pride in its favorite varieties of the species. One Greek legend refers to where cabbage sprung from where Zeus’ sweat hit the ground.

The team looked through the literature and archaeological evidence across centuries for these cultural references to gain insight into the origin of the species.

“For some reason, cabbage specifically means a lot to the English, but one of the parts that I think is really cool is that these vegetables have such cultural identities,” Mabry said. “Whether it’s a backyard garden in Portugal or England, there’s a lot of humanity in Brassica oleracea and while understanding that history is complicated, it has such a human component to it that deserves attention.”

The genetics beneath

From a genetic standpoint, Mabry compared 224 different specimens representing 14 crops and nine wild species. After grinding up the leaves in liquid nitrogen and using the Mizzou Genomics Technology Core to sequence transcriptomes (the expressed part of genomes), she then analyzed the DNA from samples that were originally collected all over the world, and then looked for overlapping similarities to understand their shared evolutionary history.

“Just like my mom and I share a set of genes, I can look at the genes in common here. Each sample will have little bits of differences due to mutations, but the more closely related they are the more they share those differences,” Mabry said. “We found Brassica cretica is the closest living wild relative, which grows in the landscape of the eastern Mediterranean region east of Italy. But my favorite part might be we also found that B. cretica has a long history of at least being partially domesticated and then returning to the wild.”

These so-called feral species of former vegetables hold a lot of promise.

“For me, I really love the feral plants. These plants had a different evolutionary history through being cultivated then returning to the wild, now on their own their own path doing their own thing,” Mabry said. “I think it’s really exciting because this subset of plants have even more in common with our crops than wild relatives because they have been domesticated at one time with the same subset of genes. This is under-appreciated gene pool that could really be an exciting avenue for future crop improvement.”

Mabry’s next step is to go in person to these regions in Greece, Crete, Italy, and Morocco to search the hills herself for the ancestors of mustard as part of a National Geographic grant project postponed because of Covid-19.

“I was supposed to go to create and collect these plants in March 2020 and then the pandemic happened, so now that is the next step to figure out,” Mabry said. “My goal is to go next summer once vaccination rollouts around the world play out. We’ll get there soon, and I know the plants will be there waiting.”

This research published June 22, 2021, in the journal Molecular Biology and Evolution, titled “The Evolutionary History of Wild, Domesticated, and Feral Brassica Oleracea.”

Another Piece of the Pi: Tech gives research automation edge

February 12, 2020 By Mariah Cox in Research Tags: bioinformatics, computer science

This Raspberry Pi device developed by former MU undergrad Brandin Grindstaff allowed members of the Chris Pires lab to remotely monitor their plants. | photo by Roger Meissen, Bond LSC

By Mariah Cox | Bond LSC

What does an iconic American dessert have in common with a credit-card-sized single-board computer? Well, only its name.

Small but mighty, the Raspberry Pi can be programmed for use in multiple settings and has been increasingly used for tasks in research labs.

But it took a scientific conference in Europe for one Bond LSC lab to tap into its usefulness. Makenzie Mabry, a doctoral candidate in the Chris Pires lab, found herself with the dilemma that she couldn’t monitor her research plants back home in the lab across an ocean. This predicament sparked an idea in biology undergraduate Brandin Grindstaff, who found the solution and the hands-on research opportunities he was searching for.

“Ever since I can remember I’ve been fascinated by biology and technology. Computer science is an important component of biological research,” Grindstaff said. “Programming, specifically, is a really powerful tool for a researcher and it can be indispensable for collecting data or solving problems that might be impossible without it.”

While computer programming was a foreign skill for Grindstaff, the unfamiliarity was a motivator. Grindstaff proposed an idea for a small plant growth chamber monitor to Pires and Mabry his final semester of undergrad and began development the following summer. The Growth Monitor pi (GMpi) tracks the functionality of designated room parameters, meaning if a light goes out or someone left the door open, it sends a Slack message to all members of the lab.

Brandin Grindstaff poses with some plants in a growing room. | Photo courtesy of Grindstaff

Without any prior experience working on Raspberry Pi’s, electronics, or with the Python program language, he spent a large chunk of time teaching himself.

“Every day was a new and interesting challenge interfacing the sensors and camera with the Raspberry Pi. I spent hours sifting through tutorials and Python and Linux documentation,” Grindstaff said. “After a few weeks, we got the first iteration set up for testing the growth chamber, but it would crash after only a few hours of automation because something was causing the code to break.”

This hands-on participation in a lab was hugely important to Grindstaff’s college experience. As a first-generation college student, he often found himself struggling to navigate higher education. Before his work on GMpi, Grindstaff spent time on other projects but had a hard time finding his fit. At that point, Grindstaff was about to leave the lab, but he saw the opportunity for the device and made his case.

“Chris and Makenzie took a chance on me because I was passionate about research, not because I had the best grades. The GMpi project would have been a tough sell to most mentors, but they gave me a chance,” Grindstaff said. “Education and internship opportunities need to be more accessible to everyone, especially first-generation college students.”

For Mabry, his mentor, the project was important because it was entirely led by one of her undergrads who eventually was first author on a journal publication.

“It’s really rewarding when I get my own stuff published, but to have someone that you’ve mentored be so successful, it’s even more meaningful,” Mabry said. “The value of undergraduate research is making sure people have those opportunities.”

Devices using the Raspberry Pi are becoming more prevalent in research settings to streamline lab processes. The core computer costs roughly $40 and GMpi’s attachments added up to $200. Other systems that are used to monitor growing environments typically cost thousands of dollars.

Grindstaff’s work in the Pires lab earned him attention from businesses who’ve asked him to develop similar devices. One year out of college, Grindstaff is still on the hunt for a job but in the meantime, he’s working on an expanded monitoring system for use in a commercial cultivation facility to track more environmental parameters and automate a large part of the cultivation process.

“Devices like the Raspberry Pi, open-source communities, and tutorial creators make this sort of technology accessible to everyone. You don’t really have to know anything about computer science to get started,” Grindstaff. “More than anything, I hope this project makes researcher’s lives a little easier, or even inspires somebody else to create something awesome.”

Grindstaff graduated from MU with a degree in biological sciences in 2018. His research was published in the Journal “Botanical Society of America” in Aug. 2019.