Tag Archives: mammalian

The Pioneering Map of Mammalian Brain Activity Might Have Revealed Intuition

Posted on by
Reply

Map of mouse brain showing 75,000 neurons

Dan Berman, International Brain Research Institute

The initial comprehensive activity map of the mammalian brain has unveiled groundbreaking revelations regarding decision-making processes.

For many years, neuroscientists aspired to capture neuronal activity throughout the brain at an individual level. However, challenges persist, including the limitations on the number of neurons an electrode can record, the number of electrodes deployable in a single brain, and the number of animals that a solitary lab can study.

To address these hurdles, a collaboration among 12 laboratories is underway, with each conducting identical experiments and recording duplicates to ensure consistency in collected data. This joint effort, tracking the activity of over 650,000 neurons, has resulted in the first comprehensive brain activity map related to complex behaviors.

“This research exemplifies a novel approach to addressing intricate inquiries in contemporary neuroscience,” stated Benedetto de Martino of University College London, who was not a part of this study. “Similar to CERN, which unites physicists to tackle profound issues in particle physics, this project will bring together global laboratories to confront challenges too expansive for individual teams.”

In each facility, mice were trained to maneuver a small LEGO steering wheel to direct a striped target towards the center of the display. The target was easily distinguishable when the stripes contrasted sharply. As contrast dwindled, the target nearly vanished, compelling the mice to rely on prior knowledge to respond accurately for a reward.

Bias was factored into the experiment, impacting the mice’s expectations about the target’s location. For instance, it could appear on either side of the screen. When the bias was inverted, the mice adjusted their expectations accordingly.

The resulting activity map indicates that decision-related processes are dispersed throughout the brain, rather than localized in one specific area. “Many assertions claimed, ‘this region is responsible for this function.’ However, our findings reveal that decision-making involves numerous regions collaborating through a consensus,” remarked team member Alexandre Pouget from the University of Geneva, Switzerland.

Furthermore, the findings support earlier research indicating that decision-related signals form long before an action is executed. Pouget noted that even prior to the commencement of individual experiments, signals linked to forthcoming decisions are evident. These signals accumulate when the target is presented, prompting the mice to move the wheels until a threshold is reached.

The second study reveals that beliefs regarding the target’s position are encoded very early in the brain’s activity. Researchers discovered that whether the signal emerged from the eye or journeyed to the thalamus, the brain’s relay center, advanced expectations regarding the target’s left or right positioning were already established.

This suggests that from the moment sensory information is processed by our brains, it is inherently influenced by knowledge, altering the conscious decision-making process unconsciously, according to Pouget. “While speculative, this may align with what we interpret as intuition,” he added.

Interestingly, the encoding not only captures recent sensory experiences but also seems to document the recent history of choices made. Lawrence Hunt from Oxford University pointed out, “This indicates that our actions and subjective experiences shape our perceptions, rather than the true objective reality.”

Does this imply our decisions are predestined? “The brain and its environment operate as a deterministic system. People often resist this idea, but it is accurate,” Pouget stated. “This means one can predict, to an extent, what actions will be taken before a decision is made. Nevertheless, when new information arises, expectations must be recalibrated, remaining unaware of how the surrounding world will evolve,” he explained.

Looking ahead, researchers are optimistic that the findings and collaborative methodologies will enhance the understanding of conditions like autism. A mouse model of autism suggests these animals struggle to update previous expectations with new information, according to Pouget, which resonates with our behaviors and perceptions.

topic:

Source: www.newscientist.com

Paleontologists Discover Ancient Proteins in Mammalian Tooth Enamel from 18 Million Years Ago

Posted on by
Reply

Researchers have identified protein sequences within the dense enamel tissues of ancient nasal cavities and materials collected from the Burg and Lopelot sites in the Turkana Basin, Kenya.

The Turkana Basin within the East African lift system preserves fossil communities dating back more than 66 million years. Green et al. Powder samples were collected for paleontological skin analysis from the early Pleistocene back to the Oligocene (29 million years ago) from large herbivores. Image credit: Green et al., doi: 10.1038/s41586-025-09040-9.

“Teeth are the rocks in our mouths,” stated Dr. Daniel Green, a researcher at Harvard and Columbia University.

“They represent the most complex structures created by animals; hence, it’s possible to find teeth that are 100 million years old, offering geochemical records of animal life.”

“This includes insights into their diets, hydration, and habitats.”

“Previously, we believed that mature enamel, being the hardest part of teeth, should contain very little protein.”

Yet, by employing a novel proteomic technique known as liquid chromatography tandem mass spectrometry (LC-MS/MS), the researchers uncovered remarkable protein diversity in various biological tissues.

“The method comprises multiple stages where peptides are sorted according to size or chemistry, enabling detailed sequential analysis at unprecedented resolution,” explains Dr. Kevin Uno from Harvard and Columbia University.

“Recent findings indicate that there are dozens, potentially hundreds, of different proteins present in tooth enamel,” remarked Dr. Green.

Recognizing that many proteins exist in modern teeth, researchers pivoted towards studying fossils of nasal mesentery and related materials.

As herbivores, these creatures exhibited large teeth to crush their plant-based diets.

“These mammals could have enamels measuring 2-3 millimeters in thickness, providing ample material for investigation,” Dr. Green noted.

“Our discovery — peptide fragments and amino acid chains representing proteins spanning around 18 million years — stands to transform the field.”

“No one has previously identified peptide fragments of such antiquity.”

The oldest published findings to date date back around 3.5 million years.

“The newly identified peptides encompass a diverse array of proteins, representing what is known as the proteome,” Dr. Green remarked.

“One reason we are thrilled about these ancient teeth is that we lack a complete proteome for all proteins that could potentially be extracted from the bodies of these extinct elephants and rhinos, yet we can identify distinct groups.”

“Such collections could yield more information from these groups than from a single protein alone.”

“This research opens a new chapter for paleontology, enabling scientists to reconstruct the molecular and physiological traits of extinct species, moving beyond just bones and morphology,” stated Dr. Emmanuel Nudiemma, a researcher at the National Museum of Kenya.

“These peptide fragments can be utilized to delve into the relationships among ancient animals, much like contemporary methods that map human DNA relations.”

“Though a few animals analyzed in studies are completely extinct without living descendants, in theory, proteins could be extracted from their teeth and added to a phylogenetic tree,” Dr. Green elaborated.

“This information may clarify long-standing debates among paleontologists concerning the relationships among various mammalian lineages, utilizing molecular evidence.”

Survey results Today, I will be featured in the journal Nature.

____

Dr. Green et al. Diverse enamel proteomes from rifts of East Africa over 108 million years. Nature Published online on July 9, 2025. doi:10.1038/s41586-025-09040-9

Source: www.sci.news

Discovery of a previously unknown Jurassic Shuotheriid species illuminates early mammalian evolution

Posted on by
Reply

In a new study, a team of paleontologists examined the structure of teeth. Feredkodon Chowi aims to better understand the phylogenetic relationships and evolutionary paths of a new species of Xuozalaid mammal that lived in what is now China during the Jurassic period.

rebuilding the life of Feredkodon Chowi (right) and Dianoconodon Yonggi (left). Image credit: Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences.

Professor Patricia Vickers-Rich, a researcher at Monash University and Museums Victoria, said: “Our study challenges current theory and provides a new perspective on the evolutionary history of mammals.”

“By describing the complex tooth shapes and occlusal patterns, we provide important insights into the phylogenetic relationships and evolutionary trajectory of the family Xenodiaceae, which was largely unknown until its recent discovery in China. ”

Shoeteraid a mammal-like animal from the Jurassic period, has baffled scientists because of its unique dental features.

These creatures have so-called pseudoclaws (basin-like structures) located in front of the triangular teeth of the mandibular molars, and the claws seen in modern therian mammals are similar to the triangular teeth of the lower molars. It is different from the claw-like pattern located at the back.

“This unique tooth pattern hinders our understanding of schootelid relationships and the first steps in the evolution of mammalian species,” Professor Vickersrich said.

Professor Vickers Rich and her colleagues examined the pseudotribosphene tooth of a new Jurassic schiotelid. Feredkodon Chowi represented by two skeletal specimens.

They were able to more completely dissect the tooth structure using a variety of analyses, and the results suggested that the tooth structure of schootherids is very similar to that of docodontans. Ta.

This study suggests that there are no true trigonids present in the basal teeth of Xuozalidae, indicating that they are more closely related to Docodontans than previously thought.

This reassessment of tooth structure not only resolves outstanding interpretations but also triggers a reconsideration of evolutionary connections within mammals.

“In 1982, a single small Jurassic mandible with four teeth was placed at a single point in the mammal family tree,” said Dr Thomas Rich, also from Monash University and Museums Victoria.

“We now have two virtually complete specimens analyzed in different ways, all of which place them in very different positions on the mammal family tree.”

“Additional specimens and different methods suggest different interpretations. Science often works like this.”

Based on new data, the Xuozidae appears to belong to a separate clade, the Docodontiformes, separate from the Auscutolibospheniformes, and are therefore grouped as follows: docodontance.

This finding highlights the importance of pseudotribosphenic characters in elucidating the initial diversification of mammals.

“This study highlights the presence of a huge variety of tooth morphologies in early mammals, demonstrating unique ecomorphological adaptations throughout the evolutionary development of mammals,” Professor Vickersrich said. Ta.

of findings Published in today's diary Nature.

_____

F. Mao other. The Jurassic family Xenotheliidae represents the earliest dental diversification of mammals. Nature, published online on April 3, 2024. doi: 10.1038/s41586-024-07258-7

Source: www.sci.news