Posts tagged neuronal function
Articles and news from the latest research reports.
Neuronal Morphology Goes Digital: A Research Hub for Cellular and System Neuroscience
The importance of neuronal morphology in brain function has been recognized for over a century. The broad applicability of ‘‘digital reconstructions’’ of neuron morphology across neuroscience subdisciplines has stimulated the rapid development of numerous synergistic tools for data acquisition, anatomical analysis, three-dimensional rendering, electrophysiological simulation, growth models, and data sharing. Here we discuss the processes of histological labeling, microscopic imaging, and semiautomated tracing. Moreover, we provide an annotated compilation of currently available resources in this rich research ‘‘ecosystem’’ as a central reference for experimental and computational neuroscience.
“Seq-ing” Insights into the Epigenetics of Neuronal Gene Regulation
The epigenetic control of neuronal gene expression patterns has emerged as an underlying regulatory mechanism for neuronal function, identity, and plasticity, in which short- to long-lasting adaptation is required to dynamically respond and process external stimuli. To achieve a comprehensive understanding of the physiology and pathology of the brain, it becomes essential to understand the mechanisms that regulate the epigenome and transcriptome in neurons. Here, we review recent advances in the study of regulated neuronal gene expression, which are dramatically expanding as a result of the development of new and powerful contemporary methodologies, based on next-generation sequencing. This flood of new information has already transformed our understanding of many biological processes and is now driving discoveries elucidating the molecular mechanisms of brain function in cognition, behavior, and disease and may also inform the study of neuronal identity, diversity, and neuronal reprogramming.
The evolution of human intellect: Human-specific regulation of neuronal genes
A new study published November 20 in the open-access journal PLOS Biology has identified hundreds of small regions of the genome that appear to be uniquely regulated in human neurons. These regulatory differences distinguish us from other primates, including monkeys and apes, and as neurons are at the core of our unique cognitive abilities, these features may ultimately hold the key to our intellectual prowess (and also to our potential vulnerability to a wide range of ‘human-specific’ diseases from autism to Alzheimer’s).
Exploring which features in the genome separate human neurons from their non-human counterparts has been a challenging task until recently; primate genomes comprise billions of base pairs (the basic building blocks of DNA), and comparisons between the human and chimpanzee genomes alone reveal close to 40 million differences. Most of these are thought to merely reflect random ‘genetic drift’ during the course of evolution, so the challenge was to identify the small set of changes that have functionally important consequences, as these might help to explain the genomic basis of the emergence of human-specific neuronal function.
The key to the present study, led by Dr Schahram Akbarian of the University of Massachusetts and the Mount Sinai School of Medicine, was not to focus on the “letters” of the DNA code, but rather on what might be called its “font” or “typeface”—the DNA strands of the genome are wrapped in protein to make a chromatin fiber, and the way in which they are wrapped, the “chromatin state”, in turn reflects the regulatory state of that region of the genome (e.g. whether a given gene is turned on or off). This is the field that biologists call “epigenetics”—the study of the “epigenome”.
Dr Akbarian and colleagues set out to isolate small snippets of chromatin fibers from the frontal cortex, a brain region involved in complex cognitive operations. They were then able to analyze these snippets for the chemical signals (histone methylation) that define the regulatory state (on/off) of the chromatin. The results of their analysis identified hundreds of regions throughout the genome which showed a markedly different chromatin structure in neurons from human children and adults, compared to chimpanzees and macaques.
This treasure trove of short genomic regions is now providing researchers with interesting new leads involving the evolution of the human brain. Although some of the regions have remained unchanged during primate evolution, some more tantalizing ones have recently changed, having a DNA sequence that is unique to humans and our close extinct relatives, the Neanderthals and the Denisovans.
The study also uncovered examples where several of these regulatory DNA regions appear to physically interact with each other inside the cell nucleus, despite being separated by hundreds of thousands of base pairs on the linear genome. This phenomenon of “chromatin looping” is implicated in controlling the expression of neighboring genes, including several with a critical role for human brain development. The study, from laboratories based in the United States, Switzerland and Russia, draws further attention to the role of epigenetics and the epigenome in our biology and our evolution. As Dr Akbarian notes, “Much about human biology and disease cannot be deduced by simply sequencing the genome. Mapping the epigenome of neurons and other cells will help us to better understand the inner workings of our brain, and where we are coming from.”
(Source: medicalxpress.com)