Evidence for a Plasma Membrane-Mediated Permeability Barrier to Tat Basic Domain in Well-Differentiated Epithelial Cells: Lack of Correlation with Heparan Sulfate

Violini, Stefania; Sharma, Vijay; Prior, Julie L.; Dyszlewski, Mary; Piwnica‐Worms, David

doi:10.1021/bi026097e

Cited by 103 publications

(92 citation statements)

References 47 publications

(73 reference statements)

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“…Scrambled pVEC serving as another negative control showed significantly weak fluorescence (Figure 1). The present study corroborates that the extent of internalization of CPPs varies not only with the mammalian cell lines and different tissues but also the organisms [21][22][23][24].…”

Section: Resultssupporting

confidence: 89%

Cellular uptake of cell‐penetrating peptides pVEC and transportan in plants

Chugh

Eudes

2007

Journal of Peptide Science

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Internalization of fluorescently labeled CPPs, pVEC, transportan and scrambled pVEC, in a range of plant cells was investigated. Cellular uptake of the peptides was found to be tissue dependent. pVEC and transportan were distinctly internalized in triticale mesophyll protoplasts, onion epidermal cells, leaf bases and root tips of seven-day old triticale seedlings but showed negligible florescence in coleoptile and leaf tips as observed under a fluorescence microscope. Further, pVEC and transportan uptake studies were focused on mesophyll protoplasts as a system of investigation. In fluorimetric studies transportan showed 2.3 times higher cellular internalization than pVEC in protoplasts, whereas scrambled pVEC failed to show any significant fluorescence. Effect of various factors on cellular internalization of pVEC and transportan in protoplasts was also investigated. The cellular uptake of both the peptides was concentration dependent and nonsaturable. The cellular uptake of pVEC and transportan was enhanced at low temperature (4°C). The presence of endocytic/macropinocytosis inhibitors did not reduce the cellular uptake of the peptides, suggesting direct cell penetration, receptor-independent internalization of pVEC and transportan into the plant cells.

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Section: Resultssupporting

confidence: 89%

Cellular uptake of cell‐penetrating peptides pVEC and transportan in plants

Chugh

Eudes

2007

Journal of Peptide Science

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“…Similarly, PTD- 99 Tc administered in vivo failed to cross the epithelial lining of the urinary bladder [179]. Importantly, several years ago Melan and Sluder [180] emphasized that misleading apparent localization of soluble proteins can result from their redistribution during the preparation of cells for immunostaining.…”

Section: Limitations In Ptd-mediated Protein Transductionmentioning

confidence: 99%

The taming of the cell penetrating domain of the HIV Tat: Myths and realities

Chauhan

Tikoo²,

Kapur

et al. 2007

Journal of Controlled Release

155

136

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Protein transduction with cell penetrating peptides over the past several years has been shown to be an effective way of delivering proteins in vitro and now several reports have also shown valuable in vivo applications in correcting disease states. An impressive bioinspired phenomenon of crossing biological barriers came from HIV transactivator Tat protein. Specifically, the protein transduction domain of HIV-Tat has been shown to be a potent pleiotropic peptide in protein delivery. Various approaches such as molecular modeling, arginine guanidinium head group structural strategy, multimerization of PTD sequence and phage display system have been applied for taming of the PTD. This has resulted in identification of PTD variants which are efficient in cell membrane penetration and cytoplasmic delivery. Inspite of these state of the art technologies, the dilemma of low protein transduction efficiency and target specific delivery of PTD fusion proteins remains unsolved. Moreover, some misconceptions about PTD of Tat in the literature require considerations. We have assembled critical information on secretory, plasma membrane penetration and transcellular properties of Tat and PTD using molecular analysis and available experimental evidences.

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“…The incubation medium was replaced with fresh medium containing 40 mM digitonin, 50 mM carvedilol, 20 mM rifamycin SV, or 50 mM L-carnitine, at 10 min before the addition of [ 3 H]quinidine. [14][15][16][17] The cells were incubated with also evaluated at 37°C in the presence of 100 mM quinidine. 8,9,18) The incubation medium was replaced with fresh medium containing 5 mM quinidine, 5 mM quinine, 20 mM diphenhydramine, 20 …”

Section: )mentioning

confidence: 99%

Pharmacokinetic Analysis of Transcellular Transport of Quinidine across Monolayers of Human Intestinal Epithelial Caco-2 Cells

Ishida

Takaai

Hashimoto

2006

Biological & Pharmaceutical Bulletin

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Quinidine, a tertiary amine compound with a site of ionization with a pK a value of pH 8.8, is classified as a type IA antiarrhythmic drug, and has been used for the management of ventricular arrhythmias.1,2) The drug is absorbed rapidly and almost entirely after oral administration, and is detected in the plasma within 15 min.3) Quinidine binds to both albumin and a 1 -acid glycoprotein, and the proportion that binds to plasma protein is 70 to 95%. 4) However, its apparent volume of distribution is quite large (2.0 to 3.5 liters/kg), because the drug is highly lipophilic.4) It is metabolized via 3-hydroxylation and N-oxygenation by cytochrome P450 3A4, and these metabolites are less electrophysiologically active than the parent drug. 5,6) The hepatic extraction ratio of quinidine is about 30%, and the bioavailability after oral administration is about 70%. 7) In addition, quinidine is partly excreted in the urine (15 to 40% of dose), suggesting that reabsorption at the distal tubules in the nephron is not complete. 4)The mechanism of intestinal absorption of lipophilic organic cations has been explained as passive diffusion of unionized compounds according to the pH-partition theory. On the other hand, Mizuuchi et al. investigated the mechanisms responsible for the transcellular transport of diphenhydramine in Caco-2 cells. 8,9) This cell line forms confluent monolayers of well differentiated enterocyte-like cells with functional properties of transporting epithelia, and is widely used as a model to study the absorption of drugs and other xenobiotics.10-12) The uptake of diphenhydramine at the apical membrane in Caco-2 cells was pH-and temperature-dependent, but was not inhibited by tetraethylammonium, biological amines, or neurotransmitters.8) On the other hand, the uptake was inhibited by chlorpheniramine, procainamide, and imipramine, and was trans-stimulated by the preloading of chlorpheniramine, dimethylaminochloride, and triethylamine.8,9) From these results, Mizuuchi et al. concluded that the uptake of diphenhydramine at the apical membrane in Caco-2 cells is mediated by a specific transport system, and that this system recognizes the N-dimethyl or N-diethyl moieties of compounds. 8,9) However, at present, it is unclear whether the transport system for diphenhydramine is involved in the intestinal absorption of other tertiary amine compounds, such as quinidine.During drug absorption in the intestine, therapeutic compounds or nutrients first enter intestinal epithelial cells from their apical side, then pass through the epithelia to the basolateral side, and finally appear in the blood stream. Therefore, to investigate intestinal drug absorption, it is important to separately assess these sequential processes. However, in many cases, drug transport on the apical and basolateral sides of the monolayer in Caco-2 cells was not separately examined, and the influx and efflux clearance rates were not evaluated.13) For the characterization of transcellular drug transport, a pharmacokinetic approach is useful. Tr...

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Evidence for a Plasma Membrane-Mediated Permeability Barrier to Tat Basic Domain in Well-Differentiated Epithelial Cells: Lack of Correlation with Heparan Sulfate

Cited by 103 publications

References 47 publications

Cellular uptake of cell‐penetrating peptides pVEC and transportan in plants

Cellular uptake of cell‐penetrating peptides pVEC and transportan in plants

The taming of the cell penetrating domain of the HIV Tat: Myths and realities

Pharmacokinetic Analysis of Transcellular Transport of Quinidine across Monolayers of Human Intestinal Epithelial Caco-2 Cells

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