Product

Sunday, 14 March 2021

Evolution: Lab-Grown ‘Mini Brains’ Suggest One Mutation Might Have Rewired the Human Mind

 How we humans became what we are today is a question that scientists have been trying to answer for a long time. How did we evolve such advanced cognitive abilities, giving rise to complex language, poetry, and rocket science? In what way is the modern human brain different from those of our closest evolutionary relatives, such as Neanderthals and Denisovans?

By reintroducing ancient genes from such extinct species into human “mini brains”—clusters of stem cells grown in a lab that organize themselves into tiny versions of human brains—scientists have started to find new clues.

Most of what we know about human evolution comes from the study of ancient fossils and bones. We know that Neanderthals and Denisovans diverged from humans around 500,000-600,000 years ago, and that the last Neanderthals didn’t disappear from Europe until about 40,000 years ago.

Research has also shown that humans and Neanderthals interbred, and that Neanderthals were a lot more sophisticatedthan previously thought.

From studying the size and shape of fossilized skulls, we also know that brains from archaic humans were roughly the same size as modern human skulls, if not bigger, and appear to be different shapes. However, although such variations might be correlated with different cognitive abilities and functions, the fossils cannot alone explain how the shapes affect function. Luckily, recent technological advances have provided a new path to understanding how we differ from our extinct relatives.


Sequencing of ancient DNA has allowed scientists to compare genes of Neanderthals and Denisovans with those of modern humans. This has helped identify differences and similarities, revealing that we share most of our DNA with Neanderthals and Denisovans.

Still, in specific regions, there are gene variants exclusively carried by modern humans. These human-specific DNA regions may be responsible for traits that separate our species from our extinct relatives. By understanding how these genes work, we can therefore learn about the traits that are unique to modern humans.

Studies comparing archaic and modern DNA sequences have pinpointed differences in genes important for the function, behavior, and development of the brain—in particular genes involved in cell division and synapses (which transmit electric nerve impulses between cells). These have suggested the human brain matures more slowly than the Neanderthal one did.

Specifically, the development of the orbitofrontal cortex in infants, which is thought to be involved in higher-order cognition like decision-making, might have changed significantly but subtly since the split from Neanderthals. Humans also reach sexual maturity later than their ancestors did, which can help explain why we live longer.

Growing Brains

It has long been unclear which evolutionary changes have been the most important. A team of scientists led by Alysson Muotri at the University of California, San Diego, recently published a study in Science that shed some light on this question.

They did this by growing mini brains—which are known scientifically as “organoids”—from stem cells derived from skin. Brain organoids aren’t conscious in the way we are—they are very simple and do not reach sizes larger than around five or six millimeters, due to a lack of blood supply. But they can emit brainwaves and grow relatively complex neural networks that respond to light.

The team inserted an extinct version of a gene involved in brain development in the organoids using the Nobel-prize winningCRISPR-Cas9 technology, often described as “genetic scissors,” which allows precise editing and manipulation of genes.


We know that the old version of the gene was present in Neanderthals and Denisovans, whereas a mutation later changed the gene into the current version that modern humans carry.

The engineered organoids displayed several differences. They expanded more slowly than the human organoids and had altered formation of connections between neurons. They were also smaller and had rough, complex surfaces compared to the smooth and spherical modern human organoids.

One Driving Mutation?

The study identified 61 genes that are different between modern and archaic humans. One of these genes is NOVA1, which has an essential role in regulating other genes’ activity during early brain development. It also plays a role in the formation of synapses.

Altered activity of NOVA1 has previously been found to cause neurological disorders such as microcephaly (leading to a small head), seizures, severe developmental delay, and a genetic disorder called familial dysautonomia, suggesting it is important for normal human brain function. The version that modern humans carry has a change in one single letter of the code. This change causes the gene’s product, the NOVA1 protein, to have a different composition and possibly a different activity.

When analyzing the organoids, scientists found that the archaic NOVA1 gene changed the activity of 277 other genes—many of them are involved in creating synapses and connections between brain cells. As a result, the mini brains had a different network of cells to those of a modern human.

That means that the mutation in NOVA1 caused essential changes in our brains. A change in a single letter of the DNA code possibly sparking a new level of brain function in modern humans. What we don’t know is how exactly this happened.

The team has said they will follow up their fascinating finding by investigating the other 60 genes in more detail, to see what happens when you alter each one or a combination of several.

It’s no doubt an intriguing area of research, with the organoids giving important insight into these ancient species’ brains. But we are only at the beginning. Manipulation of a single gene will not capture the true Neanderthal and Denisovan genetics. But it could still help scientists understand how some human-specific genes work.





No comments:

Post a Comment

Connect broadband

AI:List AI views on when for a naive kin after prolonged life suppression coercive behaviour by family members after demise of father with trauma for kin ocd formed after forced to do rituals, family tribal values honor specific activities, utmost religious activities occult witchcraft enforced to do by elder sibling his wife and mother thrice with great celibacy turned the kundalini activated after deep celibacy penance shouting physical Mental financial Extortion by sibling with toxic behaviours and the wife mother and then mockery suppression asking about who’re your worth backbiting among relatives sector toon negligence of intelligence intuitive behaviour- all religious psychological traps when not work and lead to loss of consciousness of kin trance state recovered by governance with technocrats using AI - kin was asked by mother that he’s to go the male should not be seen in house he’s many absurd thought forcefully in brain mind and outsiders already feel awkward of this kin unresponsive behaviour due to TBI PTSD ocd cvt and tell at workplace social gathering he’s to go and asked for sector toon extortion and mockery in various sense due to un practical behaviour negligence of body building due to neglect ion if essential food nutrition and stubbed suppressed in every sense in religious psychological traps by family members AI humanoid using various neural networks and LLMs for kin and required steps.

  List AI views on when for a naive kin after prolonged life suppression coercive behaviour by family members after demise of father with tr...