Human-Specific Brain Genes Tied to Developmental Disorders
Author: Vlaams Instituut voor Biotechnologie
Published: 2024/10/14 - Updated: 2025/10/20
Publication Details: Peer-Reviewed, Experimental Study
Category Topic: Anthropology and Disability - Academic Publications
Page Content: Synopsis - Introduction - Main - Insights, Updates
Synopsis: This research reports a peer-reviewed experimental study that identifies two human-specific genes (SRGAP2B and SRGAP2C) and reveals how they interact with the gene SYNGAP1 — known to be mutated in intellectual disability and autism spectrum disorders. The authors show that the human-specific genes normally slow synapse maturation in human neurons, and when they are turned off, synaptic development accelerates in ways that mirror features seen in certain neurodevelopmental conditions. Because synaptic timing is a hallmark of our extended human brain development (neoteny), the finding provides a direct molecular link between the evolution of our larger, slower-maturing brain and heightened vulnerability to neurodevelopmental disorders.
For people with disabilities, seniors, or anyone interested in brain health and development, this offers a richly informative perspective: genes that contributed to our cognitive edge may also underlie risk factors for disability, pointing toward new avenues for understanding, diagnosis, or interventions - Disabled World (DW).
Defining Dendrite
- Dendrite
A dendrite is defined as the afferent component of a neuron that branches extensively into a dendritic tree, tapering distally with each successive branch. Dendrites are rich in microtubules and microfilaments, lack neurofilaments, and play a crucial role in receiving and processing synaptic signals in the brain. The main function of dendrites is to receive information from other neurons, called pre-synaptic neurons, or from the environment. Dendrites are one of two types of cytoplasmic processes that extrude from the cell body of a neuron, the other type being an axon. Axons can be distinguished from dendrites by several features including shape, length, and function. Dendrites often taper off in shape and are shorter, while axons tend to maintain a constant radius and can be very long.
Introduction
Human Cortical Neuron Neoteny Requires Species-Specific Balancing of Srgap2-Syngap1 Cross-Inhibition at the Synapse
The human brain's remarkably prolonged development is unique among mammals and is thought to contribute to our advanced learning abilities. Disruptions in this process may explain certain neurodevelopmental diseases. Now, a team of researchers led by Prof. Pierre Vanderhaeghen (VIB-KU Leuven), together with scientists of Columbia University and Ecole Normale Supérieure has discovered a link between two genes, present only in human DNA, and a key gene called SYNGAP1, which is mutated in intellectual disability and autism spectrum disorders. Their study, published in Neuron, provides a surprisingly direct link between human brain evolution and neurodevelopmental disorders.
Main Content
The human brain stands out among mammals for its remarkably prolonged development. Synapses - critical connections between neurons of the cerebral cortex, the brain's main hub for cognition - take years to mature in humans, compared to just months in species like macaques or mice. This extended development, also known as neoteny, is thought to be central to humans' advanced cognitive and learning abilities. On the other hand, it has been hypothesized that disruptions of brain neoteny could be linked to neurodevelopmental disorders such as intellectual disability and autism spectrum disorder.
The lab of Pierre Vanderhaeghen at the VIB-KU Leuven Center for Brain & Disease Research previously discovered that the prolonged development of the human cerebral cortex is mainly due to human-specific molecular mechanisms in neurons. Now, they are investigating these molecular timers in human neurons.
Unlocking the Secrets to Slow Synapse Development
In their latest study, the team tested the involvement of two genes, SRGAP2B and SRGAP2C, which are unique to humans. First identified by Cécile Charrier in the laboratory of Prof. Franck Polleux (Columbia University, USA), these genes have been found to slow down synapse development when artificially introduced into mouse neurons of the cerebral cortex. The question if these genes function the same way in human neurons has remained unanswered.
To address this, Dr. Baptiste Libé-Philippot, a Postdoctoral Fellow in the Vanderhaeghen lab, switched off SRGA2B and SRGAP2C in human neurons, transplanted them into mouse brains, and carefully monitored synapse development over an 18-month period.
"We discovered that when you turn off these genes in human neurons, synaptic development speeds up at remarkable levels," says Dr. Libé-Philippot. "By 18 months, the synapses are comparable to what we would expect to see in children between five and ten years old! This mirrors the accelerated synapse development observed in certain forms of autism spectrum disorder."
Clues to Human-specific Brain Disorder Susceptibility
The team then investigated the underlying genetic mechanisms behind the pronounced effects of SRGAP2B and SRGAP2C on human neuron neoteny. They focused on the SYNGAP1 gene, an important disease gene known to be involved in intellectual disability and autism spectrum disorder.
Remarkably, they discovered that the SRGAP2 and SYNGAP1 genes act together to control the speed of human synapse development. Most strikingly, they found that SRGAP2B and SRGAP2C increase the levels of the SYNGAP1 gene and can even reverse some defects in neurons lacking SYNGAP1. This finding increases our understanding of how human-specific molecules influence neurodevelopmental disease pathways, shedding light on why such disorders are more prevalent in our species.
Prof. Pierre Vanderhaeghen is looking forward to the future:
"This work gives us a clearer picture of the molecular mechanisms that shape the slow development of human synapses. It is amazing to find out that the same genes that are involved in the evolution of the human brain also have the potential to modify the expression of specific brain diseases. This could have important clinical relevance: more research is needed to understand how human-specific mechanisms of brain development affect learning and other behaviors and how their dysregulation can lead to brain disorders. It becomes conceivable that some human-specific gene products could become innovative drug targets."
Publication and Funding
Human cortical neuron neoteny requires species-specific balancing of SRGAP2-SYNGAP1 cross-inhibition at the synapse. Libé-Philippot, et al. Neuron, 2024.
This work was performed in collaboration with VIB, KU Leuven, Columbia University (NY, US), and Ecole Normale Supérieure (Paris, France). It was supported by the European Research Council, the C1 KU Leuven Internal Funds Programme, the EOS Programme, ERA-NET NEURON, Research Foundation Flanders (FWO), the EU network NSC-Reconstruct, the Generet Foundation, the National Institutes of Health (NIH), the NOMIs Foundation, and the Belgian Queen Elizabeth Foundation.
Insights, Analysis, and Developments
Editorial Note: In conclusion, this article underscores a compelling evolutionary-trade-off narrative: the same genetic innovations that extend human brain development and support higher cognition may simultaneously predispose to developmental vulnerabilities when regulation is disrupted. Recognizing this duality can reshape how we think about neurodevelopmental conditions—not merely as malfunctions, but as by-products of our species’ unique developmental program—and invites more nuanced research into therapeutic strategies aligned with the evolutionary roots of brain wiring - Disabled World (DW).Attribution/Source(s): This peer reviewed publication was selected for publishing by the editors of Disabled World (DW) due to its relevance to the disability community. Originally authored by Vlaams Instituut voor Biotechnologie and published on 2024/10/14, this content may have been edited for style, clarity, or brevity.