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In-cell NMR suggests that DNA i-motif levels are strongly depleted in living human cells

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VÍŠKOVÁ Pavlína IŠTVÁNKOVÁ Eva RYNEŠ Jan DŽATKO Šimon LOJA Tomáš LENARČIČ ŽIVKOVIC Martina RIGO Riccardo EL-KHOURY Roberto SERRANO-CHACON Israel DAMHA Masad J GONZALEZ Carlos MERGNY Jean-Louis TRANTÍRKOVÁ Silvie TRANTÍREK Lukáš

Rok publikování 2024
Druh Článek v odborném periodiku
Časopis / Zdroj Nature Communications
Fakulta / Pracoviště MU

Středoevropský technologický institut

Citace
www https://www.nature.com/articles/s41467-024-46221-y
Doi http://dx.doi.org/10.1038/s41467-024-46221-y
Klíčová slova CYTOSINE-RICH STRAND; G-QUADRUPLEX; HNRNP LL; MOLECULAR SWITCH; GENE-EXPRESSION; LOOP LENGTH; STABILITY; SEQUENCES; DOMAINS; PROTEIN
Přiložené soubory
Popis I-Motifs (iM) are non-canonical DNA structures potentially forming in the accessible, single-stranded, cytosine-rich genomic regions with regulatory roles. Chromatin, protein interactions, and intracellular properties seem to govern iM formation at sites with i-motif formation propensity (iMFPS) in human cells, yet their specific contributions remain unclear. Using in-cell NMR with oligonucleotide iMFPS models, we monitor iM-associated structural equilibria in asynchronous and cell cycle-synchronized HeLa cells at 37 degrees C. Our findings show that iMFPS displaying pH(T) < 7 under reference in vitro conditions occur predominantly in unfolded states in cells, while those with pH(T) > 7 appear as a mix of folded and unfolded states depending on the cell cycle phase. Comparing these results with previous data obtained using an iM-specific antibody (iMab) reveals that cell cycle-dependent iM formation has a dual origin, and iM formation concerns only a tiny fraction (possibly 1%) of genomic sites with iM formation propensity. We propose a comprehensive model aligning observations from iMab and in-cell NMR and enabling the identification of iMFPS capable of adopting iM structures under physiological conditions in living human cells. Our results suggest that many iMFPS may have biological roles linked to their unfolded states.
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