Fossil study sheds light on famous spirals found in nature

Date:

Share post:

A 3D model of a 407-million-year-old plant fossil has overturned thinking on the evolution of leaves. The research has also led to fresh insights about spectacular patterns found in plants.

The research published in the journal Science overturns a long-held theory around a famous pattern in nature. Paleontology Ph.D. student at University College Cork (UCC) Holly-Anne Turner is the first author on the study and conducted the research while an undergraduate student and Research Assistant at the University of Edinburgh.

The findings indicate that the arrangement of leaves into distinctive spirals, that are common in nature today, were not common in the most ancient land plants that first populated the Earth’s surface.

Instead, the ancient plants were found to have another type of spiral. This negates a long-held theory about the evolution of plant leaf spirals, indicating that they evolved down two separate evolutionary paths.

Whether it is the vast swirl of a hurricane or the intricate spirals of the DNA double-helix, spirals are common in nature and most can be described by the famous mathematical series the Fibonacci sequence.

Named after the Italian mathematician, Leonardo Fibonacci, this sequence forms the basis of many of nature’s most efficient and stunning patterns.

Spirals are common in plants, with Fibonacci spirals making up over 90% of the spirals. Sunflower heads, pinecones, pineapples and succulent houseplants all include these distinctive spirals in their flower petals, leaves or seeds.

Why Fibonacci spirals, also known as nature’s secret code, are so common in plants has perplexed scientists for centuries, but their evolutionary origin has been largely overlooked.

Life reconstruction of fossil Asteroxylon mackiei [Credit: Matt Humpage, Northern Rogue Studios]

Based on their widespread distribution it has long been assumed that Fibonacci spirals were an ancient feature that evolved in the earliest land plants and became highly conserved in plants.

However, an international team led by the University of Edinburgh including University College Cork (UCC) Holly-Anne Turner and researchers at University Münster, Germany and Northern Rogue Studios, U.K., has overthrown this theory with the discovery of non-Fibonacci spirals in a 407-million-year-old plant fossil.

“The clubmoss Asteroxylon mackiei is one of the earliest examples of a plant with leaves in the fossil record. Using these reconstructions we have been able to track individual spirals of leaves around the stems of these 407-million-year-old fossil plants. Our analysis of leaf arrangement in Asteroxylon shows that very early clubmosses developed non-Fibonacci spiral patterns” stated Holly-Anne Turner.

Using digital reconstruction techniques the researchers produced the first 3D models of leafy shoots in the fossil clubmoss Asteroxylon mackiei—a member of the earliest group of leafy plants.

The exceptionally preserved fossil was found in the famous fossil site the Rhynie chert, a Scottish sedimentary deposit near the Aberdeenshire village of Rhynie.

The site contains evidence of some of the planet’s earliest ecosystems—when land plants first evolved and gradually started to cover the Earth’s rocky surface making it habitable.

The findings revealed that leaves and reproductive structures in Asteroxylon mackiei, were most commonly arranged in non-Fibonacci spirals that are rare in plants today.

This transforms scientists understanding of Fibonacci spirals in land plants. It indicates that non-Fibonacci spirals were common in ancient clubmosses and that the evolution of leaf spirals diverged into two separate paths.

The leaves of ancient clubmosses had an entirely distinct evolutionary history to the other major groups of plants today such as ferns, conifers and flowering plants.

The team created the 3D model of Asteroxylon mackiei, which has been extinct for over 400 million years, by working with digital artist Matt Humpage, using digital rendering and 3D printing.

Source: University College Cork [June 15, 2023]

ADVERTISEMENT

spot_img

Related articles

Diverse symbionts of reef corals have endured since ‘age of dinosaurs’

Coral-algal partnerships have endured numerous climate change events in their long history, and at least some are likely...

Researchers identify how the bacterial replicative helicase opens to start DNA replication process

DNA replication is a complex process in which a helicase ring separates the DNA molecule's two entwined and...

Discovery of new microscopic species expands the tree of life

Scientists have discovered several very rare species of microorganisms, some of which have never been seen before and...

Bird skull evolution slowed after the extinction of the dinosaurs

From emus to woodpeckers, modern birds show remarkable diversity in skull shape and size, often hypothesized to be...

In the beginning, there was sugar

Organic molecules formed the basis for the evolution of life. But how could inorganic precursors have given rise...

Scientists pinpoint our most distant animal relatives

Scientists from Trinity College Dublin believe they have pinpointed our most distant animal relative in the tree of...

Protein-like structures from the primordial soup

The story starts at least four billion years ago, when there was no living matter on the planet....

Did Earth’s early rise in oxygen support the evolution of multicellular life—or suppress it?

Scientists have long thought that there was a direct connection between the rise in atmospheric oxygen, which started...