Fragmented deoxyribonucleic acid could be extractable from Mars’s surface rocks

Maria Paz Zorzano; Jyothi Basapathi Raghavendra; Daniel Carrizo; Fuencisla Cañadas; Mariana Reyes-Prieto; Giuseppe D’Auria; Javier Martin-Torres

doi:10.1038/s43247-025-02809-w

Fragmented deoxyribonucleic acid could be extractable from Mars’s surface rocks

Maria Paz Zorzano^*, Jyothi Basapathi Raghavendra, Daniel Carrizo, Fuencisla Cañadas, Mariana Reyes-Prieto, Giuseppe D’Auria, Javier Martin-Torres

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Detecting biomolecules in rocks is vital for understanding life’s evolution on Earth and its possible existence on Mars. The Curiosity rover measured Total Organic Carbon (TOC) levels of 201–273 ppm in 3500 million years (Ma)-old Martian mudstones exposed to radiation for 78 ± 30 Ma. Here we investigate whether deoxyribonucleic acid (DNA), a unique biological polymer, can be recovered under comparable conditions. We extracted and sequenced DNA from terrestrial sedimentary rocks with TOC ranging from 182 to 63,000 ppm, yielding 184,000 to 3.8 million nucleobases from a 0.5 g rock sample. After exposure to 10.45 MGy of gamma radiation, equivalent to 136 Ma on the Martian surface, we measured a radiolytic constant of K = 0.17 MGy⁻¹ in microbialite (2800-year-old) and oxide iron formation (2930 Ma old) samples. Despite fragmentation, 1.48–8.45% of sequences remained taxonomically identifiable, demonstrating that DNA fragments can persist in rocks for over 100 Ma. (Figure presented.)

Original language	English
Article number	838
Number of pages	13
Journal	Communications Earth and Environment
Volume	6
Issue number	1
DOIs	https://doi.org/10.1038/s43247-025-02809-w
Publication status	Published - 24 Oct 2025
Externally published	Yes

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title = "Fragmented deoxyribonucleic acid could be extractable from Mars{\textquoteright}s surface rocks",

abstract = "Detecting biomolecules in rocks is vital for understanding life{\textquoteright}s evolution on Earth and its possible existence on Mars. The Curiosity rover measured Total Organic Carbon (TOC) levels of 201–273 ppm in 3500 million years (Ma)-old Martian mudstones exposed to radiation for 78 ± 30 Ma. Here we investigate whether deoxyribonucleic acid (DNA), a unique biological polymer, can be recovered under comparable conditions. We extracted and sequenced DNA from terrestrial sedimentary rocks with TOC ranging from 182 to 63,000 ppm, yielding 184,000 to 3.8 million nucleobases from a 0.5 g rock sample. After exposure to 10.45 MGy of gamma radiation, equivalent to 136 Ma on the Martian surface, we measured a radiolytic constant of K = 0.17 MGy⁻¹ in microbialite (2800-year-old) and oxide iron formation (2930 Ma old) samples. Despite fragmentation, 1.48–8.45\% of sequences remained taxonomically identifiable, demonstrating that DNA fragments can persist in rocks for over 100 Ma. (Figure presented.)",

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AU - Zorzano, Maria Paz

AU - Basapathi Raghavendra, Jyothi

AU - Carrizo, Daniel

AU - Cañadas, Fuencisla

AU - Reyes-Prieto, Mariana

AU - D’Auria, Giuseppe

AU - Martin-Torres, Javier

PY - 2025/10/24

Y1 - 2025/10/24

N2 - Detecting biomolecules in rocks is vital for understanding life’s evolution on Earth and its possible existence on Mars. The Curiosity rover measured Total Organic Carbon (TOC) levels of 201–273 ppm in 3500 million years (Ma)-old Martian mudstones exposed to radiation for 78 ± 30 Ma. Here we investigate whether deoxyribonucleic acid (DNA), a unique biological polymer, can be recovered under comparable conditions. We extracted and sequenced DNA from terrestrial sedimentary rocks with TOC ranging from 182 to 63,000 ppm, yielding 184,000 to 3.8 million nucleobases from a 0.5 g rock sample. After exposure to 10.45 MGy of gamma radiation, equivalent to 136 Ma on the Martian surface, we measured a radiolytic constant of K = 0.17 MGy⁻¹ in microbialite (2800-year-old) and oxide iron formation (2930 Ma old) samples. Despite fragmentation, 1.48–8.45% of sequences remained taxonomically identifiable, demonstrating that DNA fragments can persist in rocks for over 100 Ma. (Figure presented.)

AB - Detecting biomolecules in rocks is vital for understanding life’s evolution on Earth and its possible existence on Mars. The Curiosity rover measured Total Organic Carbon (TOC) levels of 201–273 ppm in 3500 million years (Ma)-old Martian mudstones exposed to radiation for 78 ± 30 Ma. Here we investigate whether deoxyribonucleic acid (DNA), a unique biological polymer, can be recovered under comparable conditions. We extracted and sequenced DNA from terrestrial sedimentary rocks with TOC ranging from 182 to 63,000 ppm, yielding 184,000 to 3.8 million nucleobases from a 0.5 g rock sample. After exposure to 10.45 MGy of gamma radiation, equivalent to 136 Ma on the Martian surface, we measured a radiolytic constant of K = 0.17 MGy⁻¹ in microbialite (2800-year-old) and oxide iron formation (2930 Ma old) samples. Despite fragmentation, 1.48–8.45% of sequences remained taxonomically identifiable, demonstrating that DNA fragments can persist in rocks for over 100 Ma. (Figure presented.)

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DO - 10.1038/s43247-025-02809-w

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Fragmented deoxyribonucleic acid could be extractable from Mars’s surface rocks

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