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Stick-slip unfolding favors self-association of expanded HTT mRNA
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Stick-slip unfolding favors self-association of expanded HTT mRNA
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Journal Article
Stick-slip unfolding favors self-association of expanded HTT mRNA
2024
Overview
In Huntington’s Disease (HD) and related disorders, expansion of CAG trinucleotide repeats produces a toxic gain of function in affected neurons. Expanded
huntingtin
(exp
HTT
) mRNA forms aggregates that sequester essential RNA binding proteins, dysregulating mRNA processing and translation. The physical basis of RNA aggregation has been difficult to disentangle owing to the heterogeneous structure of the CAG repeats. Here, we probe the folding and unfolding pathways of exp
HTT
mRNA using single-molecule force spectroscopy. Whereas normal
HTT
mRNAs unfold reversibly and cooperatively, exp
HTT
mRNAs with 20 or 40 CAG repeats slip and unravel non-cooperatively at low tension. Slippage of CAG base pairs is punctuated by concerted rearrangement of adjacent CCG trinucleotides, trapping partially folded structures that readily base pair with another RNA strand. We suggest that the conformational entropy of the CAG repeats, combined with stable CCG base pairs, creates a stick-slip behavior that explains the aggregation propensity of exp
HTT
mRNA.
Mechanical unfolding of huntingtin mRNA with optical tweezers reveals how CAG repeat expansion triggers base pair reshuffling and favors RNA aggregation that is a hallmark of Huntington’s Disease.
Publisher
Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio
Subject
/ 38/90
/ Humanities and Social Sciences
/ Humans
/ Huntingtin Protein - chemistry
/ Huntingtin Protein - genetics
/ Huntingtin Protein - metabolism
/ Huntington Disease - genetics
/ Huntington Disease - metabolism
/ mRNA
/ Science
/ Slip
/ Slippage
/ Trinucleotide repeat diseases
