Christie joined The Scientist‘s team as newsletter editor in 2021, after more than a decade of science writing. She has a PhD in cell and molecular biology, and her debut book Venomous: How Earth’s Deadliest Creatures Mastered Biochemistry, received widespread acclaim.
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Bursts in microRNA (miRNA) diversity often line up with sudden increases in morphological complexity, especially in the context of the nervous system. In a 2022 bioRxiv preprint, researchers uncovered an miRNA repertoire expansion (orange) in the ancestor of coleoid cephalopods—the group that includes squids and octopuses, generally thought to be more intelligent than any other invertebrates—on par with ones seen in the ancestors of vertebrates (blue) and placental mammals (green).
The term “noncoding RNA” is a catch-all for sequences in the genome that are transcribed but typically not translated. These molecules, which account for the majority of the transcribed sequences in the genome, are now thought to play key roles in brain evolution and function. Noncoding RNAs can be classified based on their size, structure, location, or function, with dozens of different kinds described to date. Here are four types of noncoding RNA frequently studied in brain tissues.
Long noncoding RNAs (lncRNAs) are generally described as any noncoding RNAs greater than 200 nucleotides in length. Because of their variable size and composition, they can have complex shapes and perform a variety of cellular activities, though most lncRNAs await functional investigation.
Example: The human and chimpanzee versions of a lncRNA called HAR1 differ by 18 nucleotides, which impacts the molecule’s secondary structure. The human version is predicted to be more stable, but exactly how that translates into differences in brain form or function isn’t yet clear.
MicroRNAs (miRNAs) are small noncoding RNAs of just ~20–26 nucleotides (teal) that are cleaved from larger precursors. Their most well-described function is the regulation of gene expression via binding to messenger RNAs, where they generally inhibit translation and, therefore, reduce the amount of protein produced from a given gene.
Example: Overexpression of miRNA-124 leads to Alzheimer’s-like pathologies in mice, and elevated levels of the miRNA are found in the brains of people who died from the disease.
As the name suggests, circular RNAs (circRNAs) are noncoding RNAs with joined ends, creating a more stable, circular molecule. Many questions remain as to the functions of circRNAs, but some are known to bind miRNAs, likely acting as sponges to modulate the miRNAs’ translation-suppressing effects.
Example: The circRNA CDR1-AS fine tunes neuronal development in humans, binding microRNAs (teal) highly expressed in secretory neurons that regulate developmental gene expression.
Transfer RNAs’ primary job is to shuttle amino acids to growing peptide chains during translation. In the brain specifically, there’s emerging evidence that modifications to tRNAs play important roles in neuronal health and disease. Furthermore, tRNA fragments—small chunks from tRNA breakdown—seem to have their own functions, including in neurodegeneration.
Example: When researchers exposed Drosophila neuron cultures to synthetic tRFGln-CTG (teal)—a fragment of the tRNA for glutamine—the cells swelled and died, suggesting the fragment could play a role in neuronal necrosis.
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Infographic: Noncoding RNA in the Brain – The Scientist