Ancient microbial life used arsenic to thrive in a world without oxygen

0
Ancient microbial life used arsenic to thrive in a world without oxygen

Billions of years ago, life on Earth was mostly just sticky mats of great microbes living in shallow water. Sometimes, these microbial communities would manufacture carbon minerals that were grouped together over many years to become Layered limestone rocks called stromatolites. They are the oldest evidence of life on Earth. But the fossils do not tell researchers the details of how they formed.

Today, most of life is supported by oxygen. But these microbial mats have been around for a billion years Before there was oxygen in the atmosphere. So what did life use instead?

Our team consisting of GeologistsAnd the Physicists And the Biologists He found hints in fossil stromatolites that arsenic was the chemical of choice for archaic photosynthesis and respiration. But modern versions of these microbial communities still live on Earth today. Maybe one of those uses arsenic and could provide evidence for our theory?

So we joined an expedition of Chilean and Argentine scientists to search for live stromatolites in the harsh conditions of the high Andes mountains. In a deep little stream in Atacama DesertWe found a big surprise. The bottom of the channel was bright purple and made of microbial mats of stromatolite thriving in the complete absence of oxygen. Just as the evidence we found in ancient fossils suggested, these mats use two different forms of arsenic to perform photosynthesis and respiration. Our discovery provides the strongest evidence yet of how the oldest life on Earth survived in the pre-oxygen world.

Modern organisms produce oxygen during photosynthesis and use it for respiration, but other elements, such as arsenic, as shown here as As, can also act. Christoph Dobraz, Anthony Bouton, Peter FisherAnd the CC BY-ND

Converting sunlight into energy

Over the past 2.4 billion years, photosynthetic organisms such as plants and Cyanobacteria and green They used sunlight, water, and carbon dioxide to produce oxygen and organic matter. By doing this, they convert the energy from the sun into energy for life. Other organisms breathe oxygen as they digest organic carbon, and gain energy for their breathing in the process.

See also  Steps to download PUBG MOBILE KR Korean 1.4 full original version and the secret to install PUBG MOBILE KR Korean for all devices via the official links

Microbes in the ancient world also captured energy from sunlight, but from their primitive mechanisms You cannot make oxygen from water Or use oxygen to breathe. They needed another chemical to do this.

From a biochemical perspective, there are only a few potential candidates: iron, sulfur, hydrogen, or arsenic. There is no evidence in the fossil record and trace amounts of some of these chemicals In the primordial soup It is suggested that neither iron, sulfur, nor hydrogen are likely candidates for the first form of photosynthesis. This leaves the arsenic.

In 2014, our team found the first evidence that stromatolites were produced by photosynthesis and respiration with the help of arsenic. We collected pieces of Stromatolites are 2.72 billion years old From a pre-oxygen world by drilling into ancient coral reefs in Outback in Australia. Then we took these samples to France and cut them into thin slices. By measuring the x-rays that came out from these samples when we bombarded them with photons, We made a map of the chemical elements in the sample. If there are two types of arsenic in the map, this is evidence that life was using arsenic for photosynthesis and respiration. In the remnants of ancient life we ​​find plenty of both forms of arsenic, but not iron or sulfur.

This was baffling, but we wanted more evidence: a modern isotope to help prove our arsenic theory. No researcher has ever found a microbial mat community living in a place completely devoid of oxygen, but if we do find one, it could help explain how the first stromatolites formed when our planet’s oceans and atmosphere lacked oxygen.

Peter Fisher uses field equipment to measure the chemical composition of purple microbial mats.

Samples from microbial mats contain high levels of arsenic and lithium, but no oxygen. Dangelo DuranAnd the CC BY-ND

Modern microbes, ancient analogues

The Atacama Desert in Chile is the driest place on Earth, surrounded by volcanoes and exposed to extremely high UV rays. It’s not much different from what Earth looked like 3 billion years ago and it doesn’t fully support life as we know it. Here – with the help of a team that spanned across four continents and seven countries – we found what we were looking for.

Or the destination is Laguna La Brava, a shallow, very salty lake deep in the harsh desert. A shallow stream, fed by a volcanic groundwater spring, led to the lake. The riverbed was a unique deep purple. The color came from a microbial mat, which thrives quite happily in waters that contain unusually high amounts of arsenic, sulfur, and lithium, but lack one important element – oxygen.

Could these sticky purple blobs provide answers to an old question?

A purple and brown microbial cluster that sits on a white background.

A piece of microbial mat that lives at the bottom of the oxygen-free stream. Peter FisherAnd the CC BY-ND

We cut out a piece of the mat and looked for clues to the metal. A drop of acid made the minerals fizz – carbonate! – This microbial community was the stromatolite. So our team went to work, camping on site for several days at a time.

We measured water and mat chemistry with our field equipment during the day, night, summer and winter. We didn’t find the oxygen once, and back in the lab we confirmed that the sulfur and arsenic were ample. Through a microscope, we saw purple photosynthetic bacteria, but the oxygen-producing cyanobacteria were eerily absent. We also collected DNA samples from the mat and found genes for arsenic metabolism.

In the lab, we mixed the microbes from the mat, added arsenic, and exposed the mixture to sunlight. Photosynthesis was happening. Microbes used arsenic and sulfur, but preferred arsenic. When we added a small amount of organic matter, a different arsenic compound was used for respiration and preferred over sulfur.

All that remains is to show that the two types of arsenic can be detected in modern stromatolites. We returned to France, and using X-ray emission technology, we made chemical maps from Chilean samples. Every experiment we have had supports Having a strong arsenic cycle In the absence of oxygen in this unique modern stromatolite. This confirms, without a doubt, the idea that the fossil Australian specimens we studied in 2014 bear evidence of an active arsenic cycle in deep time on our young planet.

See also  Oculus Quest 2 is cheaper and better than the original, and will be released this week

The large Laguna La Brava lake with active volcanoes behind at sunset.

Laguna La Brava is closer to the Martian environment than most places on Earth. Peter FisherAnd the CC BY-ND

Answers are on Earth, leading to Mars

The extreme conditions at Atacama are very similar to the environments of early Mars and Earth NASA scientists and astrobiologists turn to Atacama To answer questions about how life began on our planet, and how it could start elsewhere. The arsenic cycling mats we discovered at Laguna La Brava provide solid clues to some basic questions about life.

On board the Mars 2020 Perseverance rover, which is currently blasting through space, is an instrument that can observe elements using the Exactly the same process we used to create our object maps. Perhaps he will discover that arsenic is abundant in layered rocks on Mars, indicating that life on Mars also uses arsenic. For more than a billion years, it did so on Earth. Under the harshest circumstances, life finds a way, and that is the way We are trying to understand.

Peter FisherProfessor of Marine Sciences University of Connecticut; Brendan Paul BurnsSenior Lecturer, UNSWAnd and Kimberly L Gallagher, Assistant Professor of Chemistry, Quinnipiac University

This article was republished from Conversation Under a Creative Commons license. Read the The original article.

Conversation

Leave a Reply

Your email address will not be published. Required fields are marked *