New Evidence Suggests Life May Not Have Begun on Earth: Discover What Changed Experts’ Minds

If you’ve been closely following developments in space science, you may have heard about the groundbreaking discovery of DNA’s building blocks on an asteroid. This is a crucial finding for understanding the origins of life.

The latest findings stem from the carbon-rich near-Earth asteroid Ryugu, which was explored by JAXA’s Hayabusa2 spacecraft, returning samples to Earth in 2020.

A recent study published in Nature Astronomy confirms that all five standard nucleobases—the molecular “letters” that encode genetic information in DNA and RNA—are present in these samples.

This finding, combined with similar discoveries from asteroid Bennu and the Murchison meteorite, suggests a broader pattern rather than isolated incidents.

Genetic Letters Etched in Space

Nucleobases are nitrogen-rich molecules that hold genetic information. The five primary nucleobases—adenine, guanine, cytosine, thymine, and uracil—pair together along the backbone of DNA and RNA, encoding the instructions necessary for life. Without these nucleobases, life as we know it could not exist.

While the presence of these molecules on an asteroid doesn’t imply life existed there, it does indicate that the chemistry needed to create essential biological ingredients occurs naturally in the universe, a process called abiotic synthesis.

“The important point is that nucleobases formed naturally on primitive asteroids and may be widely distributed across the solar system,” explains Dr. Toshiki Koga, a postdoctoral fellow at the Japan Agency for Marine-Earth Science and Technology (JAMSTEC) and the lead author of this study.

The discovery of life’s building blocks in meteorites usually raises concerns about contamination from Earth’s biology. For instance, the presence of organic molecules near a meteorite can complicate interpretations of its origin.

The solution lies in studying the asteroids directly. The Hayabusa2 mission collected samples in space and, before returning to Earth, sealed them in a clean room under an inert gas atmosphere.

“The samples were collected in space and sealed to avoid exposure to Earth’s environment,” Koga states, emphasizing that all analytical processes were conducted under strict contamination controls.

Similarly, NASA’s OSIRIS-REx mission returned samples from asteroid Bennu in 2023, which also contained all five nucleobases.

The Hayabusa2 spacecraft visited asteroid Ryugu on June 27, 2018, and collected 5.4g of samples before returning to Earth in December 2020 – Photo credit: JAXA

Analyzing Chemical Ratios

The Ryugu study offers more than just confirmation of previously expected results; it provides insights into the varying chemical compositions of different asteroids.

Different space rocks exhibit varying proportions of two classes of nucleobases: purines (adenine and guanine, which have a two-ring structure) and pyrimidines (cytosine, thymine, and uracil, which have a simpler single-ring structure).

The Murchison meteorite is rich in purines, Bennu predominantly contains pyrimidines, while Ryugu falls somewhere in between.

Researchers found a strong correlation between the ratio of purines to pyrimidines and the levels of ammonia in each sample. Higher ammonia levels correspond to an increase in pyrimidines, implying a shared yet environmentally sensitive formation pathway.

“By comparing the nucleobase compositions of Ryugu, Bennu, and the meteorite, we have uncovered evidence for a potentially new formation mechanism,” Koga notes, with laboratory experiments underway for further investigation.

Rethinking the Origins of Life

According to Critie Grice, a Professor of Geochemistry at Curtin University who was not involved in the study, the accumulating evidence suggests a shift in our understanding of life’s origins.

“Life did not originate from scratch on Earth; the molecules necessary for life, such as nucleobases, may have formed in space and been delivered to Earth very early on,” she explains.

This reframing of the origin of life narrative suggests that rather than questioning how life produced its essential chemistry on a young Earth, we should consider how Earth organized existing molecular tools into replicating, evolving systems.

In this model, Earth acts more as an assembly line than a chemical laboratory.

The essential ingredients for nucleobase production—carbon, nitrogen, water, and radiation—are abundant throughout the universe.

The chemical processes in molecular clouds and primitive asteroids are common to planetary formation, reinforcing that the chemistry we observe is not unique to our solar system.

“The essential ingredients are widespread in the universe; the processes we’re discussing are foundational to planetary formation,” Grice states.

Large particles collected from asteroid Ryugu during Hayabusa2’s second touchdown, ranging from 3mm to over 10mm – Photo credit: JAXA

If the molecular precursors of life tend to form where planets develop, then the question of life spreading throughout the universe shifts from whether these ingredients exist to whether the conditions for their utilization will ever arise.

However, it’s essential to clarify that nucleobases themselves are not DNA or life forms. Transitioning from nucleobases to self-replicating molecules that can undergo Darwinian evolution requires the presence of sugars, phosphates, water, and potentially a bit of luck.

Moreover, some molecules carried by asteroids can disintegrate upon atmospheric entry, potentially preventing them from reaching concentrations that foster life.

Nonetheless, the patterns emerging from studies of Ryugu, Bennu, and various meteorite analyses are astonishing.

Approximately 4.6 billion years ago, as the solar system took shape, the basic materials for genetics were likely already being synthesized in cosmic rocks floating between planets.

Understanding how these components were assembled and whether similar processes could occur elsewhere in the universe remains one of science’s most critical open questions.

What we can confidently assert is that there has never been a shortage of essential materials for life.

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Source: www.sciencefocus.com

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