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W813504917 abstract "Cell penetrating peptides have been the focus of drug delivery research for 15 years due to their apparent ability to deliver cargoes inside cells more readily than many other carriers. Using two of the most commonly studied peptides (tat47-57 and R9), the present study differs from previous work by deliberately choosing to observe uptake with lower peptide concentrations closer to potential therapeutic doses, and by implementing raster image correlation spectroscopy (RICS) on a commercial microscope to quantify uptake in parallel to other techniques such as fluorescence correlation spectroscopy (FCS), confocal microscopy, and mass spectroscopy.An initial study using mass spectrometry and ExPASy (Expert Protein Analysis System) revealed that the peptides are stable for at least one hour in PBS. Based on this initial information and other experimental conditions, the study took two main directions with regards to the peptide: the membrane interaction and accumulation in the cell.The peptides interaction with the cell membrane revealed that neither tat-TAMRA nor R9-TAMRA disrupts the membrane of cells: incorporation of FM2-10 in the membrane was not modified in K562 cells whilst it was in presence of the control lytic peptides GALA and mellitin. Based on this information confocal microscopy was utilised to assess the localisation on the cell membrane. Peptide binding to the membrane appeared to be heterogeneous in distribution at 1�M bulk concentration.Accumulation in cells of the peptides was observed incubated at 37�C, confocal microscopy showed punctuated distribution with intracellular aggregations of fluorescence measuring between 2.5-3.5�m in diameter. Co-staining with a nuclear dye revealed these aggregations to be focused around the nucleus of the cell. Initial FCS experiments indicated a concentration dependent accumulation of the peptide in the cells and a decrease of the intracellular diffusion coefficients at high concentration possibly corresponding with molecular crowding. Interestingly the anomalous diffusion model did not statistically improve the results.RICS was implemented to study the kinetics of entry of TAMRA labelled cell penetrating peptides in both Caco-2 and HeLa cells lines at concentrations between 500nM and 2�M. Concentrations above 1�M exhibited higher final intracellular concentrations, yet the measured diffusion coefficients were similarly independent of extracellular concentration. Both peptides appeared to enter the cell quickly with a fast initial uptake over the first 10 minutes, reaching a concentration maxima after 30 minutes.Overall, the study reveals that many published studies may be incorrect as they may only be reporting the presence of a fluorescent dye inside the cell not the peptide. The fast binding of the peptide to the membrane is likely to cause false positive results when traditionally studying internalisation kinetics such as using flow cytometry and confocal microscopy. Correlation spectroscopy techniques such as FCS, provide useful information on internalisation of the peptides, but the single spot measurement is limited when providing information on the entire cell. RICS is a progression of correlation spectroscopy and provides a more representative picture of the cell." @default.
W813504917 created "2016-06-24" @default.
W813504917 creator A5032656201 @default.
W813504917 date "2012-10-09" @default.
W813504917 modified "2023-09-27" @default.
W813504917 title "Quantification of Cell Penetrating Peptide Uptake By Fluorescent Techniques" @default.
W813504917 cites W104003787 @default.
W813504917 cites W1498617603 @default.
W813504917 cites W1504567142 @default.
W813504917 cites W1536886974 @default.
W813504917 cites W1573332568 @default.
W813504917 cites W1574601702 @default.
W813504917 cites W1584683177 @default.
W813504917 cites W1586954894 @default.
W813504917 cites W1590085201 @default.
W813504917 cites W1601798363 @default.
W813504917 cites W1616350046 @default.
W813504917 cites W1725134142 @default.
W813504917 cites W1896714280 @default.
W813504917 cites W1899761045 @default.
W813504917 cites W1963503258 @default.
W813504917 cites W1963667377 @default.
W813504917 cites W1964196663 @default.
W813504917 cites W1964922782 @default.
W813504917 cites W1965180796 @default.
W813504917 cites W1967561034 @default.
W813504917 cites W1968695777 @default.
W813504917 cites W1969073916 @default.
W813504917 cites W1970097079 @default.
W813504917 cites W1970948529 @default.
W813504917 cites W1973010584 @default.
W813504917 cites W1973796027 @default.
W813504917 cites W1973920331 @default.
W813504917 cites W1974012392 @default.
W813504917 cites W1974302927 @default.
W813504917 cites W1976258107 @default.
W813504917 cites W1976290510 @default.
W813504917 cites W1979047891 @default.
W813504917 cites W1979670787 @default.
W813504917 cites W1979968811 @default.
W813504917 cites W1980598017 @default.
W813504917 cites W1981277012 @default.
W813504917 cites W1981312603 @default.
W813504917 cites W1981765336 @default.
W813504917 cites W1982859702 @default.
W813504917 cites W1982865896 @default.
W813504917 cites W1983171533 @default.
W813504917 cites W1984470696 @default.
W813504917 cites W1984877105 @default.
W813504917 cites W1985113094 @default.
W813504917 cites W1986606329 @default.
W813504917 cites W1986752048 @default.
W813504917 cites W1987143040 @default.
W813504917 cites W1987349623 @default.
W813504917 cites W1988174220 @default.
W813504917 cites W1988328429 @default.
W813504917 cites W1988673148 @default.
W813504917 cites W1989652151 @default.
W813504917 cites W1989855380 @default.
W813504917 cites W1990220833 @default.
W813504917 cites W1990733397 @default.
W813504917 cites W1992095148 @default.
W813504917 cites W1992225866 @default.
W813504917 cites W1993338842 @default.
W813504917 cites W1993715367 @default.
W813504917 cites W1995197198 @default.
W813504917 cites W1996346894 @default.
W813504917 cites W1997388726 @default.
W813504917 cites W2000109796 @default.
W813504917 cites W2000729091 @default.
W813504917 cites W2001582257 @default.
W813504917 cites W2003021187 @default.
W813504917 cites W2005377089 @default.
W813504917 cites W2005558785 @default.
W813504917 cites W2005893192 @default.
W813504917 cites W2006519535 @default.
W813504917 cites W2006724257 @default.
W813504917 cites W2008576706 @default.
W813504917 cites W2009640317 @default.
W813504917 cites W2010181298 @default.
W813504917 cites W2010502236 @default.
W813504917 cites W2011899109 @default.
W813504917 cites W2012647985 @default.
W813504917 cites W2013481674 @default.
W813504917 cites W2013990977 @default.
W813504917 cites W2014001405 @default.
W813504917 cites W2015398987 @default.
W813504917 cites W2015704490 @default.
W813504917 cites W2016258902 @default.
W813504917 cites W2016987115 @default.
W813504917 cites W2019624766 @default.
W813504917 cites W2024343679 @default.
W813504917 cites W2026065678 @default.
W813504917 cites W2026277335 @default.
W813504917 cites W2026405782 @default.
W813504917 cites W2027028077 @default.
W813504917 cites W2027429271 @default.
W813504917 cites W2029508778 @default.
W813504917 cites W2029766213 @default.
W813504917 cites W2029825103 @default.