The study investigated the intracellular diffusion and distribution of a series of small molecule fluorescent drugs and proteins in HeLa cells. Key findings:
Acidic and neutral proteins diffused freely in the HeLa cell cytoplasm, with diffusion coefficients (Dconfocal) of 18-30 μm²/s and complete FRAP recovery.
Negatively charged small molecules like fluorescein and CCF2 also diffused relatively rapidly in cells, with Dconfocal values reduced by 2-3 fold compared to buffer due to cellular crowding.
In contrast, weakly basic small molecule drugs like the GSK3 inhibitor, quinacrine, mitoxantrone, primaquine, and amidoquine exhibited 10-20 fold slower diffusion (Dconfocal of 0.2-2 μm²/s) and lower fractional recovery after FRAP (0.2-0.5) compared to the acidic/neutral molecules.
The slow diffusion and low FRAP recovery of basic drugs correlated with their sequestration in acidic organelles, particularly lysosomes, due to cationic ion trapping.
Blocking lysosomal acidification with Bafilomycin A1 or sodium azide only slightly improved the diffusion and FRAP recovery of the basic drugs.
In contrast, blocking protonation by N-acetylation greatly enhanced the diffusion and FRAP recovery of the basic drugs, suggesting that protonation is the primary cause of their slow intracellular diffusion.
The findings highlight an important limitation in the standard rules for small molecule drug design, as the "stickiness" of basic drugs within the cell cytoplasm is not considered. Modulating the protonation state of basic drugs may improve their intracellular availability and distribution.
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biorxiv.org
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by DEY,D., Marc... : www.biorxiv.org 04-21-2023
https://www.biorxiv.org/content/10.1101/2023.04.19.537456v2Daha Derin Sorular