Neurexin
Recent articles
Missing autism gene may affect time perception in mice
Mice missing a copy of the autism-linked gene NRXN1 appear to perceive some time intervals as shorter than control mice do, according to a new study.
Missing autism gene may affect time perception in mice
Mice missing a copy of the autism-linked gene NRXN1 appear to perceive some time intervals as shorter than control mice do, according to a new study.
Autism genes assign starring role to support cells in brain
Genes linked to autism are critical to the development of star-shaped brain cells called astrocytes, suggesting a key role for the cells in the condition.
Autism genes assign starring role to support cells in brain
Genes linked to autism are critical to the development of star-shaped brain cells called astrocytes, suggesting a key role for the cells in the condition.
Wi-Fi flap; obsessive-compulsive link; brain catalog and more
Two researchers balk at talk that Wi-Fi and autism are linked, changes in an autism risk gene are tied to obsessive-compulsive traits in three species, and scientists plan to conduct a census of all of the brain’s cell types.
Wi-Fi flap; obsessive-compulsive link; brain catalog and more
Two researchers balk at talk that Wi-Fi and autism are linked, changes in an autism risk gene are tied to obsessive-compulsive traits in three species, and scientists plan to conduct a census of all of the brain’s cell types.
Brain’s reward region may drive social problems in autism
Having too many copies of an autism gene called UBE3A mutes a brain region that may mediate the satisfaction a person derives from social interactions.
Brain’s reward region may drive social problems in autism
Having too many copies of an autism gene called UBE3A mutes a brain region that may mediate the satisfaction a person derives from social interactions.
Differences between rodents show limitations of models
The same autism-linked mutation can lead to dramatically different behaviors in rats and mice.
Differences between rodents show limitations of models
The same autism-linked mutation can lead to dramatically different behaviors in rats and mice.
Method isolates protein complexes from neuronal junctions
Researchers have for the first time isolated and characterized protein complexes found at the points of connection between neurons. Mutations in some of these proteins are linked to autism.
Method isolates protein complexes from neuronal junctions
Researchers have for the first time isolated and characterized protein complexes found at the points of connection between neurons. Mutations in some of these proteins are linked to autism.
Imaging lights up dynamics of neurons’ connections in mice
Researchers have developed a way to capture dynamic changes in the part of the neuron that sends out signals, they reported yesterday at the 2014 Society for Neuroscience annual meeting in Washington, D.C.
Imaging lights up dynamics of neurons’ connections in mice
Researchers have developed a way to capture dynamic changes in the part of the neuron that sends out signals, they reported yesterday at the 2014 Society for Neuroscience annual meeting in Washington, D.C.
Analysis of mouse brains maps subgroups of autism
A brain imaging study of 26 mouse models of autism reveals a broad range of structural abnormalities. The models cluster into groups with similar features, reports a study published 9 September in Molecular Psychiatry.
Analysis of mouse brains maps subgroups of autism
A brain imaging study of 26 mouse models of autism reveals a broad range of structural abnormalities. The models cluster into groups with similar features, reports a study published 9 September in Molecular Psychiatry.
Mutant protein causes reversible autism-like behaviors
Mice that begin expressing a mutant version of a protein called neurexin at 2 weeks of age develop autism-like behaviors that researchers can erase weeks or months later. The report, published 24 July in Cell Reports, suggests that it may be possible to treat autism symptoms even in adulthood.
Mutant protein causes reversible autism-like behaviors
Mice that begin expressing a mutant version of a protein called neurexin at 2 weeks of age develop autism-like behaviors that researchers can erase weeks or months later. The report, published 24 July in Cell Reports, suggests that it may be possible to treat autism symptoms even in adulthood.
Genetic background may alter behavior of autism mice
Differences in the background genetics of mouse strains may modify the effects of autism genes, suggests a study published 11 March in Autism Research. The study looked at the behavior of mice with a mutation in neuroligin-3, a strong autism candidate gene.
Genetic background may alter behavior of autism mice
Differences in the background genetics of mouse strains may modify the effects of autism genes, suggests a study published 11 March in Autism Research. The study looked at the behavior of mice with a mutation in neuroligin-3, a strong autism candidate gene.
Explore more from The Transmitter
Rajesh Rao reflects on predictive brains, neural interfaces and the future of human intelligence
Twenty-five years ago, Rajesh Rao proposed a seminal theory of how brains could implement predictive coding for perception. His modern version zeroes in on actions.
Rajesh Rao reflects on predictive brains, neural interfaces and the future of human intelligence
Twenty-five years ago, Rajesh Rao proposed a seminal theory of how brains could implement predictive coding for perception. His modern version zeroes in on actions.
In memoriam: Yves Frégnac, influential and visionary French neuroscientist
Frégnac, who died on 18 October at the age of 73, built his career by meeting neuroscience’s complexity straight on.
In memoriam: Yves Frégnac, influential and visionary French neuroscientist
Frégnac, who died on 18 October at the age of 73, built his career by meeting neuroscience’s complexity straight on.
Explaining ‘the largest unexplained number in brain science’: Q&A with Markus Meister and Jieyu Zheng
The human brain takes in sensory information roughly 100 million times faster than it can respond. Neuroscientists need to explore this perceptual paradox to better understand the limits of the brain, Meister and Zheng say.
Explaining ‘the largest unexplained number in brain science’: Q&A with Markus Meister and Jieyu Zheng
The human brain takes in sensory information roughly 100 million times faster than it can respond. Neuroscientists need to explore this perceptual paradox to better understand the limits of the brain, Meister and Zheng say.