How did life begin? How did chemical reactions on the early Earth create complex, self-replicating structures that developed into living things as we know them?

According to one school of thought, before the current era of DNA-based life, there was a kind of molecule called RNA (or ribonucleic acid). RNA – which is still a crucial component of life today – can replicate itself and catalyse other chemical reactions.

But RNA molecules themselves are made from smaller components called ribonucleotides. How would these building blocks have formed on the early Earth, and then combined into RNA?

Chemists like me are trying to recreate the chain of reactions required to form RNA at the dawn of life, but it’s a challenging task. We know whatever chemical reaction created ribonucleotides must have been able to happen in the messy, complicated environment found on our planet billions of years ago.
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I have been studying whether “autocatalytic” reactions may have played a part. These are reactions that produce chemicals that encourage the same reaction to happen again, which means they can sustain themselves in a wide range of circumstances.

In our latest work, my colleagues and I have integrated autocatalysis into a well-known chemical pathway for producing the ribonucleotide building blocks, which could have plausibly happened with the simple molecules and complex conditions found on the early Earth.
The formose reaction


Autocatalytic reactions play crucial roles in biology, from regulating our heartbeats to forming patterns on seashells. In fact, the replication of life itself, where one cell takes in nutrients and energy from the environment to produce two cells, is a particularly complicated example of autocatalysis.

A chemical reaction called the formose reaction, first discovered in 1861, is one of the best examples of an autocatalytic reaction that could have happened on the early Earth.The formose reaction was discovered by Russian chemist Alexander Butlerov in 1861. Wikimedia
In essence, the formose reaction starts with one molecule of a simple compound called glycolaldehyde (made of hydrogen, carbon and oxygen) and ends with two. The mechanism relies on a constant supply of another simple compound called formaldehyde.

A reaction between glycolaldehyde and formaldehyde makes a bigger molecule, splitting off fragments that feed back into the reaction and keep it going. However, once the formaldehyde runs out, the reaction stops, and the products start to degrade from complex sugar molecules into tar.

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Abiogenesis through gradual evolution of autocatalysis into template-based replication

Polina Pavlinova, Camille N. Lambert, Christophe Malaterre, Philippe Nghe
First published: 06 October 2022

https://doi.org/10.1002/1873-3468.14507
Polina Pavlinova and Camille N. Lambert are joint first authors

Edited by Claus M. Azzalin
Abstract


How life emerged from inanimate matter is one of the most intriguing questions posed to modern science. Central to this research are experimental attempts to build systems capable of Darwinian evolution. RNA catalysts (ribozymes) are a promising avenue, in line with the RNA world hypothesis whereby RNA pre-dated DNA and proteins. Since evolution in living organisms relies on template-based replication, the identification of a ribozyme capable of replicating itself (an RNA self-replicase) has been a major objective. However, no self-replicase has been identified to date. Alternatively, autocatalytic systems involving multiple RNA species capable of ligation and recombination may enable self-reproduction. However, it remains unclear how evolution could emerge in autocatalytic systems. In this review, we examine how experimentally feasible RNA reactions catalysed by ribozymes could implement the evolutionary properties of variation, heredity and reproduction, and ultimately allow for Darwinian evolution. We propose a gradual path for the emergence of evolution, initially supported by autocatalytic systems leading to the later appearance of RNA replicases.

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Scientists studying structures that might be fossils of very early life follow careful standards to assess whether or not the structures are truly fossilized microorganisms. The scientists who studied the 3.42 billion-year-old fossils from South Africa analysed the specimens visually using a light microscope. Then they analysed the chemical composition of the specimens using several techniques, including mass spectrometry, Raman spectroscopy, electron energy loss spectroscopy, and x-ray fluorescence spectroscopy.

The results of this suite of analyses indicated that the structures, which look like modern thread-like microorganisms, are made of fossilized organic matter. The fossilized organic matter on the outside of structures is chemically different from the fossilized organic matter on the inside of the structures. The scientists who discovered the microstructures suggested that these chemical differences are because the outer layer of fossilized organic matter was once a sheath or cell-wall, similar to what is seen in modern thread-like microorganisms.

The analyses further revealed the presence of nickel associated with the organic matter of these structures. Nickel is found in the enzymes that some modern microorganisms living in hydrothermal vents use to produce energy and grow. The scientists also studied the minerals that these structures were preserved within and found that they fossilized when a type of quartz deposited on the walls of the deep sea vents where the ancient microorganisms lived.

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