origins of life news, articles and features | New Scientist /topic/origins-of-life/ Science news and science articles from New Scientist Mon, 13 Jul 2026 11:45:32 +0000 en-US hourly 1 https://wordpress.org/?v=7.0.1 242057827 Sugar molecules found in interstellar space for the first time /article/2533910-sugar-molecules-found-in-interstellar-space-for-the-first-time/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Mon, 13 Jul 2026 15:00:54 +0000 /?post_type=article&p=2533910 2533910 Has the answer to life’s origins been hiding in our cells all along? /article/2529162-has-the-answer-to-lifes-origins-been-hiding-in-our-cells-all-along/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Mon, 15 Jun 2026 15:00:51 +0000 /?post_type=article&p=2529162 2529162 How a radical new view of life could reveal its origin – and aliens /article/2526959-how-a-radical-new-view-of-life-could-reveal-its-origin-and-aliens/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Tue, 26 May 2026 15:00:56 +0000 /?post_type=article&p=2526959 2526959 RNA strand that can almost self-replicate may be key to life’s origins /article/2515482-rna-strand-that-can-almost-self-replicate-may-be-key-to-lifes-origins/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Thu, 12 Feb 2026 19:00:31 +0000 /?post_type=article&p=2515482
Artist’s depiction of QT45 (based on AlphaFold3 prediction) overlayed on a microscopy image of the frozen environment that aids RNA replication
Elfy Chiang, microscopy image by James Attwater

According to the RNA world hypothesis, life began when RNA molecules evolved the ability to make more copies of themselves. Now we have discovered an RNA molecule that is almost capable of this – it can carry out the key steps involved, just not all at once.

“It’s been a long quest to get to the point where you can convince yourself that RNA has the capacity to make itself under the right conditions. I think this shows that it is possible,” says at the MRC Laboratory of Molecular Biology in Cambridge, UK.

In living cells, proteins carry out key tasks such as catalysing chemical reactions, and the recipes for making them are stored in double-stranded DNA molecules. RNA is a chemical cousin of DNA that usually exists in the form of single strands.

It isn’t as good for storing information as DNA because it is less stable, but it can do something DNA can’t: fold up to form protein-like enzymes that can catalyse chemical reactions. Because RNA can both store information and act as a catalyst, it was suggested as early as the 1960s that life might have begun with RNA molecules capable of catalysing their own formation.

But finding such molecules has proved really difficult. Researchers had long assumed that self-replicating RNAs must be relatively large and complex, but it turns out to be very hard to unfold large RNAs to replicate them.

What’s more, while it has been shown that relatively short RNA molecules can form spontaneously in the right conditions, large molecules are very unlikely to have done so.

“This led us to think, well, maybe we’re wrong. Maybe something simple, something small, could carry out this process,” says Holliger. “And so we went looking, and we found one.”

RNAs are made of building blocks called nucleotides. The team started by generating a trillion random sequences that were 20, 30 or 40 nucleotides long. From these, they picked out three that could carry out reactions such as joining nucleotides together. The three were joined together and put through several rounds of evolution – randomly changing, or mutating, parts of the sequence and selecting the better-performing variants.

The resulting molecule, called QT45, is just 45 nucleotides long. In alkaline water that is just above freezing, it can use single-stranded RNA as a template for making complementary strands by joining together short strands of two or three nucleotides, including making a sequence complementary to its own. “It’s currently quite slow and low-yielding, but that’s not a surprise,” says Holliger.

QT45 can also make more copies of itself from those complementary strands. “This is, for the first time, a piece of RNA that can make itself and its encoding strand, and those are the two constituent reactions of self-replication,” says Holliger. But so far, the team hasn’t managed to get both reactions to happen in the same container. The plan is now to both evolve the molecule further and experiment with conditions such as freeze-thaw cycles to see if both reactions could happen at once.

“The most exciting thing is, once the system begins to self-replicate, it should become self-optimising,” Holliger says. That’s because the error-ridden process will produce a lot of variations, a few of which may work better, producing more of themselves, and so on.

“The new results from the Holliger lab are exceptional and a significant advance, pushing things even closer to a fully self-replicating RNA,” says at the University of Greifswald in Germany.

“Perhaps the most significant aspect of this finding is to discover a moderately sized RNA oligomer sequence with these self-synthesising capabilities,” says at the University of Wisconsin-Madison.

The number of 45-nucleotide-long RNA sequences alone is “unimaginably large”, Adam points out, so the team did well to find QT45 from a starting point of just a trillion random sequences.

On the early Earth, molecules similar to QT45 might have been able to self-replicate in an environment a bit like modern-day Iceland, Holliger says, with ice present, but also hydrothermal activity to drive freeze-thaw cycles and create pH gradients. Some sort of compartmentalisation would be needed to isolate the key components, he thinks, but there are many ways this can happen, from pockets of meltwater in ice to cell-like vesicles forming spontaneously from fatty acids.

Journal reference:

Science

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How teaching molecules to think is revealing what a ‘mind’ really is /article/2513815-how-teaching-molecules-to-think-is-revealing-what-a-mind-really-is/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Tue, 10 Feb 2026 16:00:17 +0000 /?post_type=article&p=2513815 2513815 Comet 3I/ATLAS from beyond solar system carries key molecule for life /article/2507335-comet-3i-atlas-from-beyond-solar-system-carries-key-molecule-for-life/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Fri, 05 Dec 2025 17:00:43 +0000 /?post_type=article&p=2507335 2507335 A sinister, deadly brain protein could reveal the origins of all life /article/2505167-a-sinister-deadly-brain-protein-could-reveal-the-origins-of-all-life/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Mon, 01 Dec 2025 16:00:16 +0000 /?post_type=article&p=2505167 2505167 Protocells self-assembling on micrometeorites hint at origins of life /article/2486181-protocells-self-assembling-on-micrometeorites-hint-at-origins-of-life/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Tue, 01 Jul 2025 10:20:36 +0000 /?post_type=article&p=2486181 2486181 We’re getting close to recreating the first step in evolution of life /article/2482049-were-getting-close-to-recreating-the-first-step-in-evolution-of-life/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Wed, 28 May 2025 09:00:51 +0000 /?post_type=article&p=2482049
RNA is thought to have played a key role in life getting started
Shutterstock/nobeastsofierce
The goal of understanding how inert molecules gave rise to life is one step closer, according to researchers who have created a system of RNA molecules that can partly replicate itself. They say it should one day be possible to achieve complete self-replication for the first time. RNA is a key molecule when it comes to the origins of life, as it can both store information like DNA and catalyse reactions like proteins. While it isn’t as effective as either of these, the fact that it can do both means many researchers believe life began with RNA molecules that were capable of replicating themselves. “This was the molecule that ran biology,” says at University College London. But creating self-replicating RNA molecules has proved difficult. RNA can form double helices like DNA and can be copied in the same way, by splitting a double helix in two and adding RNA letters to each strand to create two identical helices. The problem is that RNA double helices stick together so strongly that it is hard to keep the strands separate for long enough to allow replication. Now, Attwater and his colleagues have found that sets of three RNA letters – triplets – bind strongly enough to each strand to prevent this rezipping. Three is the sweet spot, says Attwater, as longer sets are likely to introduce errors. So, in the team’s system, an RNA enzyme in double-helix form is mixed with triplets. The solution is made acidic and warmed to 80°C (176°F) to separate the helix, allowing the triplets to pair up and form the “rungs” of the double helix. The solution is then made alkaline and cooled to -7°C (19°F). As the water freezes, the remaining liquid becomes highly concentrated and the RNA enzyme becomes active and joins up the triplets, forming a new strand. So far, the researchers have only been able to replicate up to 30 letters of the 180-letter-long RNA enzyme, but they think that by improving the efficiency of the enzyme, they can achieve complete replication.
Attwater says this “very simple molecule system” has some intriguing properties. One is the possible link between the triplet RNA letters and the triplet code used to specify the sequence of proteins in cells today. “There might be a relationship between how biology used to copy its RNA and how biology uses RNA today,” he says. What’s more, the team found the triplets most likely to be involved in natural replication in the past are those that bind most strongly. The first genetic code is thought to have consisted of this set of triplets – another intriguing link. The researchers think the kind of conditions needed to drive this process could occur naturally. As it requires freshwater, it is most likely to have happened on land, perhaps in some geothermal system. “The ingredients can be found on the Earth today – Iceland hot springs can have mixed pHs, including some as acidic as those we use,” says Attwater. “RNA nucleotide triplets serve very specific informatic functions in translation in all cells,” says at the University of Wisconsin-Madison, meaning they are used to convey information. “This paper is interesting because it might point to a purely chemical role – a non-informatic function – for RNA nucleotide triplets that they could have served prior to the emergence of a living cell.”
Journal reference

Nature Chemistry

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Strange microbes give clues to the ancestor of all complex life /article/2479335-strange-microbes-give-clues-to-the-ancestor-of-all-complex-life/?utm_campaign=RSS|NSNS&utm_content=origins-of-life&utm_medium=RSS&utm_source=NSNS Wed, 07 May 2025 15:00:32 +0000 /?post_type=article&p=2479335 2479335