RoundupReads Researchers Put Space Garden Microbes Under the Microscope

Researchers Put Space Garden Microbes Under the Microscope

by Deepthi Srinidhi & Jennifer Turner | 2021-11-29

A NASA astronaut aboard the International Space Station checks on plants in the Vegetable Production System, called Veggie. An ongoing NASA study seeks to examine the types of microbes present on Veggie’s hardware. Credits: NASA
A NASA astronaut aboard the International Space Station checks on plants in the Vegetable Production System, called Veggie. An ongoing NASA study seeks to examine the types of microbes present on Veggie’s hardware. Credits: NASA

When people and equipment travel to the International Space Station, microbes like bacteria and fungi also come along for the ride. While some are harmless or even beneficial, some hitchhiking microbes could cause problems on the station. Even sparse populations of microbes that are normally benign on Earth could impact crew heath if given a chance to multiply. Other bacteria, if grown unchecked on station surfaces, can potentially degrade critical life support, research, and electronic systems.

To ensure crew safety, NASA scientists carefully monitor the microbiome of the space station. They have two main goals: to map and keep track of microbes present through time and discover any patterns of microbial growth that could potentially affect the crew’s health and safety. They’re seeking to puzzle out whether the station itself creates conditions that spur microbial growth.

A group of NASA scientists are paying particular attention to monitoring the Vegetable Production System, or Veggie, the hardware used for growing plants aboard the space station. Led by Dr. Cherie Oubre, a senior scientist at NASA’s Johnson Space Center Microbiology Laboratory in Houston, this group is on a multiyear effort to characterize and monitor the microbes present on Veggie.

“NASA is going to the Moon and will someday head to Mars. These long missions will need systems like Veggie,” explained Oubre. “But if the crew consumes food contaminated with pathogenic organisms, they could become ill. Or, if plant-growth systems become contaminated with plant pathogens, the crops could be compromised or fail. To prepare, we must assess Veggie’s vulnerabilities and carefully monitor it for microbial growth.”

With its root-mat to provide water to the plants and plant “pillows” that contain fertilizer and seed, Veggie creates added pockets for possible microbes to thrive. Oubre’s team wants to know: What kind of microbes are actually growing there, and are they different from those on Earth?   

To help find out, astronauts on the station swab exterior components of the Veggie system, such as the vent screen and control panel. They also take water samples from the station’s drinking water supply. Swabbing and sample collection occurs about every four months.

These swabs and samples are then transferred to growth media slides (microbe “food”) and incubated at ambient temperature to allow the microbes to grow for several days — until colonies of organisms are visible. After five days of incubation, crew members analyze the slides and record the density of the colonies. Finally, samples are stowed and returned to Earth when a mission ends.

At that point, the work of Oubre’s team begins. They identify each distinct microbial species on the slides, which involves carefully scrutinizing microbes under a microscope. They whittle down possible species classifications based on how different microbes react in the presence of nutrients and other biochemicals and sequence the microbes’ DNA.

Once different samples have been analyzed over four to five years, the team will try to assess patterns in microbial growth through time. With this information, scientists can also see how growth patterns on Veggie fit with data on the full microbial map of the station through time.

Samples have been collected, returned to Earth, and analyzed from four space station expeditions: 58, 59, 61, and 62. Sampling began in 2019. Oubre anticipates that samples need to be collected for at least two more years to obtain the necessary information.

Victoria Castro, a microbiologist on Oubre’s team, notes that thus far, microbes found on Veggie align with what the team expects to find. The team found, for instance, species of Penicillium fungi, commonly found on bread, and Staphylococcus epidermidis bacteria, often found on human skin.

“Such microbial growth alone is not always enough to cause concern or even warrant any immediate action,” said Castro. “Continued surveillance is important to capture patterns or trends that indicate issues. And, if known pathogens are ever isolated, we’re on hand to step the crew through how to remove them, and the crew will assist us in resampling to make sure the pathogens stay gone.”

Results from this study will help researchers design a better plant production system, and ensure the crew’s safety and fresh food security during Artemis missions, on Gateway and, eventually, Mars. On Earth, the same principles can be applied to improve food production in remote environments. 

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NASA’s Human Research Program, or HRP, is dedicated to discovering the best methods and technologies to support safe, productive human space travel. HRP enables space exploration by reducing the risks to astronaut health and performance using ground research facilities, the International Space Station, and analog environments. This leads to the development and delivery of an exploration biomedical program focused on several goals: informing human health, performance, and habitability standards; developing countermeasures and risk-mitigation solutions; and advancing habitability and medical-support technologies. HRP supports innovative, scientific human research by funding more than 300 research grants to respected universities, hospitals, and NASA centers to over 200 researchers in more than 30 states.

 

Deepthi Srinidhi
Jennifer Turner
NASA Human Research Program Strategic Communications

A close-up of fungi growth after a sample collected from the Veggie system aboard the space station was incubated in conditions that promoted its growth. Incubating samples in this way helps to provide researchers with enough material to run tests on the microbes found. Credits: NASA
NASA astronaut Victor Glover, seen here on the space station, observes and records the density of a microbial colony after its incubation period. Credits: NASA