Tag Archives: Obvious

Mars’ Mysterious Markings: The ‘Most Obvious Signs’ of Alien Life, According to NASA

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The unusual “leopard spot” markings on Mars’ rocks might finally indicate that alien microbes could have existed on the Red Planet.

A comprehensive analysis of these rocks has shown that the intricate patterns are “the clearest signs ever found on Mars,” as stated by Sean Duffy, a NASA representative.

These rocks, estimated to be about 3.5 billion years old, were discovered in July 2024 by NASA’s Perseverance rover. Since then, planetary scientists have been exploring various hypotheses to explain these markings.

Recent information from a Nature paper suggests that while the patterns may have a geological origin, the prevailing theory now points toward ancient Martian microbes as the likely culprits.

Perseverance collected rock samples, hoping to yield a more definitive answer. If all goes well, these samples will eventually return to Earth for a thorough examination of potential signs of past life.

Leopard Spots on Bright Angel

Currently, Mars is a barren, lifeless world, but this hasn’t always been the case. Until around 3 billion years ago, Mars’ surface was rich with flowing rivers and expansive lakes.

Wherever there is water on Earth, signs of life typically follow. For two decades, NASA’s rovers have been scouring Mars for evidence suggesting that the Red Planet could have once supported life.

The Perseverance rover is exploring a site known as Jezero Crater, which was a lake in Mars’ ancient history. Similar environments on Earth often serve as habitats for microorganisms.

Within rock formations referred to as the Bright Angel formation, Perseverance uncovered stunning patterns resembling leopard spots.

“We conducted extensive observations of the entire rock formation at Bright Angel,” said Professor Joel Hurowitz of Stony Brook University in the US, in an interview with BBC Science Focus.

While Perseverance’s cameras captured detailed images of the patterns, a spectrometer analyzed the mineral composition. The rover even utilized radar to map the structure of the subsurface outcrop.

“Essentially, we used every tool available on these rocks except for the kitchen sink,” Hurowitz remarked.

The analysis indicated that the patterns were formed by iron-rich minerals called vivianite and greygite. On Earth, these minerals typically arise from “redox reactions,” a process in which microorganisms exchange electrons with their environment.

“On Earth, these reactions are often facilitated by microorganisms residing in sediments, which derive energy from them for metabolic activity,” Hurowitz explained. The residuals from these processes create distinctive patterns in sedimentary rocks.

However, this doesn’t mean we should rush to celebrate the discovery of alien life just yet. There are other mechanisms that could account for the leopard spot patterns without any biological influence.

For instance, heat could have driven reactions between mud and organic matter, resulting in new minerals.

Yet, the research team did not find evidence indicating that the rocks were subjected to heat. Additionally, other methods they investigated also did not seem viable. Nonetheless, Hurowitz cautioned, “We cannot dismiss these entirely.”

One of the most surprising findings is the relatively young age of these rocks. At only 3.5 billion years old, the patterns formed while Mars was already entering a phase of decline, suggesting that the planet may have been habitable for much longer than previously assumed.

Unfortunately, Perseverance has an entire planet to explore and we continue our quest to find life beyond Earth.

Perseverance drilling and photographing rock samples – Credit: NASA/JPL -CALTECH/MSSS

“If I could revisit Jezero in the future, I would have follow-up questions that I would like to address using the rover’s instruments,” Hurowitz remarked.

“However, these follow-up analyses may not necessarily provide a more conclusive answer regarding whether these features were shaped by life.”

“Ultimately, determining whether life was involved will necessitate laboratory analysis back on Earth.”

Bringing Mars to Earth

Fortunately, Perseverance is part of the initial phase of Mars’ sample return mission. Not only is it studying the rocks on Mars, but it’s also preparing to bring samples back to Earth.

Before departing from Bright Angel, the rover collected and stored samples from the rocks along with numerous similar fragments obtained during its mission on Mars.

NASA aims to collaborate with the European Space Agency on follow-up missions to retrieve these samples and return them to Earth where they can be analyzed in top-tier laboratories.

After 3.5 billion years, finding definitive evidence is challenging. Instead, researchers will seek additional signs that microbes may have left behind.

“The first logical step is to analyze the isotopic composition of iron, sulfur, and carbon in the various mineral and organic components of the rock,” Hurowitz stated.

Isotopes can be thought of as different variants of the same element. Microorganisms tend to retain particular isotopes more than their non-biological counterparts, enabling researchers to narrow down their search for evidence of life.

“These variations in isotopic composition are essential tools for investigating biological signals in ancient rocks on Earth, and we aim to apply similar methods to this Martian sample,” Hurowitz noted.

The return mission is tentatively scheduled for the 2030s, although there is a risk of cancellation due to cuts to NASA’s planetary exploration budget during the Trump administration.

“NASA is examining strategies for retrieving these samples and others,” a NASA spokesperson told BBC Science Focus. “Having explored Mars for 60 years, we will continue to look into budgetary and timing considerations for a quick and cost-effective return of these samples.”

“We hope these findings will further motivate the sample return mission,” Hurowitz added. “This will allow us to scrutinize the sample with the detail necessary to determine its historical record of life on Mars.”

“If it’s indeed life, that would suggest our planet is not the only one where life has evolved,” Frowitz concluded. “If life originated twice, how many other places might it have occurred?”

About Our Experts

Joel Hurowitz is an associate professor in the Department of Geoscience at Stony Brook University in New York, USA. He investigates the early history of Mars through measurements taken from planetary studies and Earth’s similar topographies.

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Source: www.sciencefocus.com

Do Trees Harbor Microbiomes? An Obvious Yet Profound Inquiry

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“Each tree on Earth houses a multitude of microorganisms, many of which remain unrecognized by science.”

ShutterStock/Emvat Mosakovskis

A few years back, I enjoyed an enlightening afternoon in an ancient forest near London, discovering the crucial link between aging trees and biodiversity. My guide, Lynn Bodhis, a mycologist from Cardiff University, explained that as trees age over centuries, the inner trunk begins to decompose due to fungal activity. This phenomenon, known as “heart rot,” is a natural aspect of a tree’s life cycle, creating invaluable habitats for various species of insects, birds, and mammals. Unfortunately, as older trees diminish, the heart rot phenomenon is also waning, lacking the necessary old trees to continue its role. Bodhy and her colleagues are dedicated to preserving this essential process by promoting the early aging of younger trees.

While it didn’t strike me at the moment, heart rot is part of the tree microbiome, akin to a diverse mix of bacteria, archaea, fungi, protists, and viruses. The concept of microbiomes wasn’t commonly discussed then, but groundbreaking research published in Nature has revealed that trees possess microbiota as varied and remarkable as our own.

We’ve known for some time that the surfaces of trees (trunks, roots, leaves, etc.) harbor diverse microbiota. However, recent studies indicate that their interiors are similarly diverse. Each tree on our planet contains myriad microorganisms, many of which are unfamiliar to the scientific community.

This discovery is both significant and enlightening. It’s intuitive to consider diversity in trees, given that microbiota thrive in various natural settings, including smaller plants. Yet, this research unveils microbial ecosystems that were previously overlooked, shedding new light on trees—not merely as individual organisms but as holobionts, integral components of Earth’s ecology.

Essentially, like humans, trees are composite entities, consisting of both hosts and their associated microorganisms. If the microbiota of trees proves as vital to their biology as human microbiota are to us, these communities could play a pivotal role in efforts to sustain biodiversity and combat climate change.

The researchers involved in this study examined wood samples from the trunks, branches, and roots of 150 living trees spanning 16 species in forests in northeastern United States. They conducted what is referred to as the Microorganism Census, discovering that the interior wood of trees is teeming with microorganisms, including not just bacteria associated with heart rot but also a variety of other bacteria, fungi, and archaea. Additionally, each tree species is home to its unique microbiota.

If the tree microbiota is essential to biology, it could aid in the fight to preserve biodiversity.

The interior of tree trunks consists of two types of wood: outer sapwood and inner heartwood. The sapwood is alive and primarily responsible for transporting water from the roots to the leaves, while heartwood is non-living and serves mainly structural purposes (which eventually deteriorate due to heart rot). Researchers have established that the microbial communities in these two wood types differ significantly.

While only a limited number of species were sampled, it is plausible that all trees harbor similar microbiota across various wood types. The studied 16 species represent 11 genera, all of which have a global presence.

What roles do these microorganisms fulfill? It’s still largely unknown, but researchers suggest they likely contribute to tree health and the overall health of forests. They are possibly involved in the essential ecosystem services trees provide, such as offering habitats for numerous plants and animals, producing clean water, and acting as carbon sinks. Globally, wood holds approximately 60 years’ worth of current emissions according to studies over the past six decades. Trees could absorb more, helping to cap global warming to less than 2°C above pre-industrial levels, necessitating healthy, expanding forests. A deeper understanding of tree microbiota may facilitate this goal, according to researchers.

This concept of mutualism is gaining traction. While microorganisms are often viewed as adversaries of biodiversity, they are foundational to the world’s ecosystems. As primary agents of organic matter decomposition, they drive vital biogeochemical cycles that supply the biosphere with essential elements like carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulfur. Moreover, they coexist with most plant species and are integral to what many refer to as Earth’s “life support system.” However, alarming trends suggest that the overall microbiota on Earth is declining.

It’s premature to conclude whether this trend extends to tree microbiota, but now that we are aware of their existence, we must ensure they are conserved.

What I’m reading

I’ll be diving into this as I plan my visit to Romania’s Carpathian Mountains next month.

What I’m watching

It resembles a storybook. I’m a huge fan of Mark Gattis, and his new drama is fantastic.

What I’m working on

For upcoming articles, we’re closely monitoring food intake again, including urine pH measurements.

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Source: www.newscientist.com