Scientists discover why large mammals vanished from North America 50,000 years ago

Around 50,000 years ago, North America was home to a diverse array of megafauna. Mammoths roamed the tundra, while towering mastodons and saber-toothed tigers prowled the forests. Enormous wolves, bison, and unusually tall camels moved in herds across the landscape. Giant beavers thrived in lakes and ponds, and immense ground sloths, each weighing over 1,000 kilograms, inhabited the regions east of the Rocky Mountains.

Then, as the Last Ice Age came to an end, most of these massive creatures vanished. The cause of this mass extinction remains one of the great scientific debates.

Some researchers argue that early humans played a significant role by hunting the megafauna, altering their habitats, or outcompeting them for resources. The timing of human arrival in North America roughly coincides with the disappearance of these animals, adding weight to this hypothesis.

Others believe that climate change was the primary factor. As the planet warmed and glacial ice retreated, ecosystems underwent rapid shifts. Some species may have struggled to adapt to new environments, leading to their eventual decline. However, the role of climate alone remains uncertain, as some megafauna persisted in certain regions while others disappeared entirely.

Despite decades of research, no single explanation has been definitively proven. Some scientists suggest that multiple factors may have contributed, including disease or even extraterrestrial events. One theory proposes that a comet impact triggered environmental changes severe enough to disrupt food chains and drive species to extinction.

One of the major challenges in solving this mystery is the poor preservation of megafaunal remains. While some sites contain well-preserved bones, many are too degraded for detailed analysis. Exposure to the elements, physical abrasion, and biomolecular decay often make it difficult to extract useful data.

Archaeologists and paleontologists continue to search for evidence that could clarify what happened. Advances in genetic analysis and radiocarbon dating have provided new insights, but the picture remains incomplete. More fossil discoveries and improved dating techniques may eventually help resolve the debate.

These preservation challenges leave critical gaps in our understanding of where specific megafaunal species lived, the exact timing of their disappearance, and their responses to human arrival and environmental changes during the Late Pleistocene.

To address these gaps, researchers are turning to advanced biomolecular methods. A significant effort involves examining the extensive collections of the Smithsonian National Museum of Natural History in Washington, DC.

This museum holds a vast array of animal bones from numerous archaeological excavations conducted over the past century. However, many of these bones are heavily fragmented and have remained largely unstudied until now.

Recent advancements in biomolecular archaeology have enabled researchers to extract valuable information from these old bones. One such technique is Zooarchaeology by Mass Spectrometry (ZooMS). This method capitalizes on the fact that while most proteins degrade quickly after an animal's death, some, like bone collagen, can persist for long periods.

Collagen sequences differ subtly between different animal groups and species, providing a molecular barcode that can help identify otherwise unidentifiable bone fragments. By extracting and analyzing collagen protein segments from tiny quantities of bone, ZooMS can identify species with remarkable precision.

A pilot study aimed to determine whether the Smithsonian's collections preserved enough collagen for useful analysis. Given the age of the bones and the conditions under which they were excavated and stored, the outcome was uncertain. The bones came from five archaeological sites in Colorado, dating from the Late Pleistocene to the earliest Holocene (approximately 13,000 to 10,000 years ago).

The earliest excavations occurred in 1934, with the latest in 1981. Many of the bones were highly fragmented and weathered, making traditional identification methods ineffective.

The study yielded surprising results. Despite the age and condition of the bones, 80% of the sampled fragments contained sufficient collagen for ZooMS analysis, with 73% identifiable to the genus level. The taxa identified included Bison, Mammuthus (mammoths), Camelidae (camels), and possibly Mammut (mastodons). Some specimens could only be assigned to broader taxonomic groups due to the lack of comprehensive ZooMS reference libraries for North American animals.

These findings have significant implications for museum collections. The fragmented and unidentifiable bones that make up much of the megafaunal record can now provide valuable data, thanks to ZooMS. This technique reveals the rich information hidden in neglected specimens that have received little attention from researchers or visitors for decades.

ZooMS also offers a promising tool for addressing longstanding questions about megafaunal extinctions. By enabling the analysis of fragmented bone material, this method can provide new data to help understand when, where, and how these animals disappeared. ZooMS is a relatively easy, rapid, and cost-effective way to extract information from long-ago excavated sites.

The study underscores the importance of preserving archaeological collections. In times of funding constraints, less glamorous artifacts and bones may be neglected or discarded.

Yet, as this research demonstrates, old material can yield new insights when modern techniques are applied. Museums must receive adequate funding to care for and house archaeological remains over the long term, ensuring that even the most unassuming specimens can contribute to our understanding of the past.

Techniques like ZooMS allow researchers to extract valuable information from fragmented and degraded bones, providing fresh data to address long-standing debates.

By preserving and studying these collections, we can inch closer to understanding why some of the largest animals ever to roam the Earth vanished from ancient North America's landscapes.

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