Atomic Clock and Plant DNA Research Launching Aboard NASA’s SpaceX CRS-32 Mission

NASA’s SpaceX CRS-32 mission is launching experiments that could revolutionize our understanding of time, aging, and disease.
The ACES (Atomic Clock Ensemble in Space) investigation aims to measure the precise effects of gravity on time, which could improve global time synchronization and clock comparison experiments.
The APEX-12 (Advanced Plant EXperiment-12) investigation will test whether plant DNA molecules can be protected from damage by inducing telomerase activity in space, with potential implications for developing therapies for age-related diseases.
These experiments could lead to significant advancements in precision timekeeping, which is necessary for improved space navigation and communication, as well as insights into how plants adapt to protect their DNA molecules from cellular stress.
The results of these investigations could also benefit humanity by improving GPS technology, developing new therapies for age-related diseases, and enhancing our understanding of the effects of spaceflight on living organisms.

NASA’s SpaceX 32nd commercial resupply services mission, scheduled to lift off from the agency’s Kennedy Space Center in April, is heading to the International Space Station with experiments that include research on whether plant DNA responses in space correlate to human aging and disease, and measuring the precise effects of gravity on time.

Discover more details about the two experiments’ potential impacts on space exploration and how they can enhance life on Earth:

“Second Guessing” Time in Space

As outlined in Einstein’s general theory of relativity, how we experience the passage of time is influenced by gravity. However, there is strong evidence to believe this theory may not be complete and that there are unknown forces at play. These new physics effects may manifest themselves in small deviations from Einstein’s prediction.

The ACES (Atomic Clock Ensemble in Space) investigation is an ESA (European Space Agency) mission that aims to help answer fundamental physics questions. By comparing a highly precise atomic clock in space with numerous ground atomic clocks around the world, ACES could take global time synchronization and clock comparison experiments to new heights.

Sponsored by NASA, United States scientists are participating in the mission in various ways, including contributing ground station reference clocks. Scheduled to collect data for 30 months, this vast network of precise clocks is expected to provide fresh insights into the exact relationship between gravity and time, set new limits for unknown forces, and improve global time synchronization.

In addition to investigating the laws of physics, ACES will enable new terrestrial applications such as relativistic geodesy, which involves measuring Earth’s shape and gravitational field with extreme precision. These advancements are critical to space navigation, satellite operations, and GPS systems. For example, without understanding the time fluctuations between Earth and medium Earth orbit, GPS would be progressively less accurate.

A depiction of a robotic arm extends to attach a transparent gray metal box containing scientific equipment to a large white cylinder representing the space station.

A robotic arm will attach ACES to the Columbus Laboratory module aboard the International Space Station.

Image courtesy of ESA

Probing Plants for Properties to Protect DNA

The APEX-12 (Advanced Plant EXperiment-12) investigation will test the hypothesis that induction of telomerase activity in space protects plant DNA molecules from damage elicited by cellular stress evoked by the combined spaceflight stressors experienced by seedlings grown aboard the space station. It is expected that results will lead to a better understanding of differences between human and plant telomere behavior in space.

Data on telomerase activity in plants could be leveraged not only to develop therapies for age-related diseases in space and on Earth, but also for ensuring food crops are more resilient to spaceflight stress.

Telomeres and telomerase influence cell division and cell death, two processes crucial to understanding aging in humans. Telomeres are the protective end caps of chromosomes. Each time a cell divides, the telomeres shorten slightly, essentially acting as a biological clock for cell aging. Conversely, telomerase is an enzyme that adds nucleotide sequences to the ends of telomeres, lengthening them and counteracting their shortening.

In humans, telomere shortening is linked to various age-related conditions, such as cardiovascular diseases and certain cancers. In astronauts, studies have shown that spaceflight leads to changes in telomere length, with a notable lengthening observed. This phenomenon carries potential implications for astronaut health outcomes. By contrast, plant telomere length did not change during spaceflight, despite a dramatic increase in telomerase activity.

In front of a black background there are two glowing X-shaped chromosomes in light blue with the end cap telomeres highlighted in yellow.

A microscopic image of plant telomeres taken under a fluorescent microscope. The chromosomes are highlighted in blue. The telomeres are highlighted in yellow.

Image courtesy of Texas A&M University

How this benefits space exploration: Experiments aboard NASA’s SpaceX CRS-32 mission is twofold. One, they have the potential to significantly enhance precision timekeeping, which is necessary to improve space navigation and communication. Two, they can provide insights into how plants adapt to protect DNA molecules from cellular stress caused by environmental factors experienced in spaceflight, in an effort to sustain plant life in space.

How this benefits humanity: The experiments conducted on NASA’s SpaceX CRS-32 mission offer a range of potential benefits to humanity. First, improving precision timekeeping for more accurate GPS technology. Second, capturing data about how telomerase activity correlates to cellular stress in plants, which could lead to assays which better correlate telomerase activity and cellular stress and provide fundamental research to contribute to potential therapies for humans.

Learn more about the investigations:

Borja Barbero is wearing a blue baseball cap, blue gloves, and a white face mask. He is carefully placing a plant sample into a small clear, plastic tube. There is a red bin filled with clear, plastic-looking pieces of rocks underneath his hands.

ACES (Atomic Clock Ensemble in Space)

Atomic Clock Ensemble in Space (ACES) is a European Space Agency (ESA) mission that aims to help answer fundamental physics questions.

Blue blobs are illuminated under a microscope on a black background. Small yellow, fluorescent dots are scattered throughout the blue blobs.

APEX-12 (Advanced Plant EXperiment-12)

Advanced Plant EXperiment-12 (APEX-12) will test the hypothesis that induction of telomerase, a protein complex, activity in space protects plant DNA molecules from damage elicited by cellular stress evoked by the combined spaceflight stressors experienced by seedlings grown aboard the space station.

About BPS

NASA’s Biological and Physical Sciences Division pioneers scientific discovery and enables exploration by using space environments to conduct investigations not possible on Earth. Studying biological and physical phenomenon under extreme conditions allows researchers to advance the fundamental scientific knowledge required to go farther and stay longer in space, while also benefitting life on Earth.

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Q. What is the main objective of NASA’s SpaceX CRS-32 mission?

A. The mission aims to launch experiments that include research on plant DNA responses in space and measuring the precise effects of gravity on time.

Q. What is the name of the experiment that investigates how we experience the passage of time in space?

A. ACES (Atomic Clock Ensemble in Space) investigation

Q. How long will the ACES experiment collect data for?

A. The experiment is scheduled to collect data for 30 months.

Q. What is the main goal of the APEX-12 experiment?

A. To test the hypothesis that induction of telomerase activity in space protects plant DNA molecules from damage elicited by cellular stress.

Q. Why is understanding the relationship between gravity and time important?

A. It’s crucial for improving global time synchronization, which is necessary for accurate GPS technology and space navigation.

Q. What are some potential benefits of the experiments conducted on NASA’s SpaceX CRS-32 mission?

A. The experiments have the potential to enhance precision timekeeping, improve space navigation, and provide insights into how plants adapt to protect DNA molecules from cellular stress in space.

Q. How does telomerase activity relate to plant DNA protection in space?

A. Telomerase activity is expected to protect plant DNA molecules from damage elicited by cellular stress evoked by the combined spaceflight stressors experienced by seedlings grown aboard the space station.

Q. What are some potential applications of the research conducted on NASA’s SpaceX CRS-32 mission?

A. The research could lead to better understanding of differences between human and plant telomere behavior in space, which could be leveraged for developing therapies for age-related diseases in space and on Earth.

Q. Why is it important to study biological and physical phenomena under extreme conditions?

A. Studying these phenomena allows researchers to advance fundamental scientific knowledge required to go farther and stay longer in space, while also benefiting life on Earth.

Q. What is the Biological and Physical Sciences Division of NASA’s mission?

A. The division pioneers scientific discovery and enables exploration by using space environments to conduct investigations not possible on Earth.