Cell-penetrating peptides. A reevaluation of the mechanism of cellular uptake

Cellular uptake of a family of cationic cell-penetrating peptides (examples include Tat peptides and penetratin) have been ascribed in the literature to a mechanism that does not involve endocytosis. In this work we reevaluate the mechanisms of cellular uptake of Tat 48-60 and (Arg)(9). We demonstrate here that cell fixation, even in mild conditions, leads to the artifactual uptake of these peptides. Moreover, we show that flow cytometry analysis cannot be used validly to evaluate cellular uptake unless a step of trypsin digestion of the cell membrane-adsorbed peptide is included in the protocol. Fluorescence microscopy on live unfixed cells shows characteristic endosomal distribution of peptides. Flow cytometry analysis indicates that the kinetics of uptake are similar to the kinetics of endocytosis. Peptide uptake is inhibited by incubation at low temperature and cellular ATP pool depletion. Similar data were obtained for Tat-conjugated peptide nucleic acids. These data are consistent with the involvement of endocytosis in the cellular internalization of cell-penetrating peptides and their conjugates to peptide nucleic acids.     

Functionalization of osmium arene anticancer complexes with (poly)arginine: effect on cellular uptake, internalization, and cytotoxicity

Attaching peptides to metallodrugs may result in improved biological properties of the complexes. The potential use of cell penetrating peptides (CPPs) as cell delivery vectors is attractive, since directed cell uptake of (metallo)drugs remains a major challenge in anticancer drug design. In this work, we report the synthesis of peptide conjugates of the organometallic Os(II) anticancer complex [(η(6)-biphenyl)Os(picolinate)Cl] with different arginine (Arg) chain lengths. Complexes conjugated to Arg(5) or Arg(8) at the 5-position of the picoline ring increase Os uptake into A2780 human ovarian cancer cells by ca. 2× and 10×, respectively, whereas a single Arg had no effect. Furthermore, a 15-fold increase in binding of Os to DNA, a potential target for these complexes, was observed for Arg(8) compared to the Arg(1) conjugate. The Arg(5) and Arg(8) conjugates exhibited fast kinetics of binding to calf thymus DNA and an ability to precipitate DNA at very low concentrations. In serum-free medium, the Arg(8) complex was cytotoxic (IC(50) 33 μM) and appears to be a rare example of a bioactive organometallic peptide conjugate. Experiments on CHO cells deficient in DNA repair suggested that unrepaired DNA damage contributes to the cytotoxicity of the Arg(5) and Arg(8) conjugates. These studies demonstrate the potential for use of cell- and nucleus-penetrating peptides in targeting organometallic arene anticancer complexes.     

Possible existence of common internalization mechanisms among arginine-rich peptides.

Basic peptides such as human immunodeficiency virus type 1 (HIV-1) Tat-(48-60) and Drosophila Antennapedia-(43-58) have been reported to have a membrane permeability and a carrier function for intracellular protein delivery. We have shown that not only Tat-(48-60) but many arginine-rich peptides, including HIV-1 Rev-(34-50) and octaarginine (Arg(8)), efficiently translocated through the cell membranes and worked as protein carriers (Futaki, S., Suzuki, T., Ohashi, W., Yagami, T., Tanaka, S., Ueda, K., and Sugiura, Y. (2001) J. Biol. Chem. 276, 5836-5840). Quantification and time course analyses of the cellular uptake of the above peptides by mouse macrophage RAW264.7, human cervical carcinoma HeLa, and simian kidney COS-7 cells revealed that Rev-(34-50) and Arg(8) had a comparable translocation efficiency to Tat-(48-60). Internalization of Tat-(48-60) and Rev-(34-50) was saturable and inhibited by the excess addition of the other peptide. Typical endocytosis and metabolic inhibitors had little effect on the internalization. The uptake of these peptides was significantly inhibited in the presence of heparan sulfate or chondroitin sulfates A, B, and C. Treatment of the cells with the anti-heparan sulfate antibody or heparinase III also lowered the translocation of these peptides. These results strongly suggest that the arginine-rich basic peptides share a certain part of the internalization pathway.     

Star-like oligo-arginyl-maltotriosyl derivatives as novel cell-penetrating enhancers for the intracellular delivery of colloidal therapeutic systems

A novel nonpeptide, multiarmed oligo-arginyl derivative was engineered as a cell-penetration enhancer for the delivery of bioactive macromolecules and colloidal drug systems. Hepta-arginyl-maltotriosylamido-N-acetyl-dodecanoyl acid (Arg(7)-Malt-NAcC(12) acid) was synthesized through a carefully designed multistep chemical protocol, as follows: (1) maltotriose derivatization with 12-amino-dodecanoic acid and acetylation of the free amino group; (2) esterification of the maltotriosyl hydroxyl groups with 2-bromo-isobutyryl bromide; and (3) synthesis of star-like oligomer bearing multiple copies of arginine moieties under atom transfer radical polymerization (ATRP) conditions. The intermediates and final product were characterized by (1)H NMR, IR, mass spectrometry, colorimetric assays, and elemental analysis. Cytotoxicity studies on the final polymeric material showed that this novel cell-penetrating enhancer does not have significant toxic effects on MCF-7 and MC3T3-E1 cell lines. The IC(50) was greater than 100 μM with both cell lines, while the polyethylenimine with similar average molecular mass (M(n)) that was used as a reference showed an IC(50) of 30 and 40 μM, for MCF-7 and MC3T3-E1, respectively. The biological properties of the novel bioconjugate were investigated using a fluorescein-labeled bovine serum albumin (FITC-BSA) as a hydrophilic cargo model. MCF-7 and MC3T3-E1 cells were incubated for 60 min with the Arg(7)-Malt-NAcC(12)-conjugated FITC-BSA [(Arg(7)-Malt-NAcC(12))(2)-FITC-BSA] or FITC-BSA, and the intracellular fluorescence level was analyzed by spectrofluorimetric analysis of cell lysate, cytofluorimetry, and confocal microscopy. The fluorescence of the lysate of MCF-7 and MC3T3-E1 cells that were incubated with (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA at 37 °C was approximately 4.5 times higher than the fluorescence obtained with cells incubated with FITC-BSA. At 4 °C, the cell uptake of (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA was only 2 times higher than that of FITC-BSA. Cytofluorimetric studies showed that, after (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA treatment, over 80% of MCF-7 cells and over 95% of MC3T3-E1 cells displayed enhanced fluorescence. Confocal investigations showed punctuated fluorescence within the cytosol in both cell lines, indicating that (Arg(7)-Malt-NAcC(12))(2)-FITC-BSA was confined to endosomes, with no fluorescence observed in the nucleus.     

Cutting edge: CD91-independent cross-presentation of GRP94(gp96)-associated peptides

GRP94(gp96) elicits CD8(+) T cell responses against its bound peptides, a process requiring access of its associated peptides into the MHC class I cross-presentation pathway of APCs. Entry into this pathway requires receptor-mediated endocytosis, and CD91 (low-density lipoprotein receptor-related protein) has been reported to be the receptor mediating GRP94 uptake into APC. However, a direct role for CD91 in chaperone-based peptide Ag re-presentation has not been demonstrated. We investigated the contribution of CD91 to GRP94 cell surface binding, internalization, and trafficking in APCs. Whereas a clear role for CD91 in alpha(2)-macroglobulin binding and uptake was readily obtained, the addition of excess CD91 ligand, activated alpha(2)-macroglobulin, or receptor-associated protein, an antagonist of all known CD91 ligands, did not affect GRP94 cell surface binding, receptor-mediated endocytosis, or peptide re-presentation. These data identify a CD91-independent, GRP94 internalization pathway that functions in peptide Ag re-presentation.     

Structure-activity relationship study of the cell-penetrating peptide pVEC

The peptide pVEC is a recently described cell-penetrating peptide, derived from the murine vascular endothelial-cadherin protein. In order to define which part of this 18-amino acid long peptide is important for the cellular translocation, we performed a structure-activity relationship study of pVEC. Together with the l-alanine substituted peptides, the retro-pVEC, D-pVEC and the scramble pVEC are studied for comparison. The peptide analogues are labeled with carboxyfluorescein at the N-terminus for monitoring the cellular uptake into human Bowes melanoma cells with different efficacy. We show that all the Fl-pVEC analogues internalize in live Bowes melanoma cells. l-Alanine substitution of the five respective N-terminal hydrophobic amino acids significantly decreases the translocation property, while replacing of Arg(6), Arg(8) or Ser(17) by alanine enhances the uptake. The uptake of pVEC is significantly reduced by treatment with an endocytosis inhibitor wortmannin. Treatment with heparinase III, nystatin and EIPA had no effect on the peptide uptake. The data presented here show that the N-terminal hydrophobic part of pVEC is crucial for efficient cellular translocation.     

Cell-dependent differential cellular uptake of PNA,peptides, and PNA-peptide conjugates

Peptide nucleic acid (PNA) oligomers were conjugated to cell-penetrating peptides: pAnt, a 17-residue fragment of the Drosophila protein Antennapedia, and pTat, a 14-amino acid fragment of HIV protein Tat. A 14-mer PNA was attached to the peptide by disulfide linkage or by maleimide coupling. The uptake of (directly or indirectly, via biotin) fluorescein-labeled peptides, PNAs, or PNA-peptide conjugates was studied by fluorescence microscopy, confocal laser scanning microscopy, and fluorometry in five cell types. In SK-BR-3, HeLa, and IMR-90 cells, the PNA-peptide conjugates and a T1, backbone-modified PNA were readily taken up (2 microM). The PNA was almost exclusively confined to vesicular compartments in the cytosol. However, the IMR-90 cells also showed a weak diffuse staining of the cytoplasm. In the U937 cells, we observed a very weak and exclusively vesicular staining with the PNA-peptide conjugates and the T(lys)-modified PNA. No evident uptake of the unmodified PNA was seen. In H9 cells, both peptides and the PNA-peptide conjugates quickly associated with the membrane, followed by a weak intracellular staining. A cytotoxic effect resulting in artificial staining of the cells was observed with fluoresceinated peptides and PNA-peptide conjugates at concentrations above 5-10 microM, depending on cell type and incubation time. We conclude that uptake of PNAs in many cell types can be achieved either by conjugating to certain peptides or simply by charging the PNA backbone using lysine PNA units. The uptake is time, temperature, and concentration dependent and mainly endocytotic. Our results also show that proper controls for cytotoxicity should always be carried out to avoid misinterpretation of visual data.     

Surface membrane biotinylation efficiently mediates the endocytosis of avidin bioconjugates into nucleated cells

Here we demonstrate that biotin covalently attached to cell surface obligates existing receptors to endocytose avidin bioconjugates into nucleated cells. Incubation of fluorescein-labeled avidin with biotinylated cell lines resulted in uniform and rapid surface attachment and endocytosis compared with no detectable association of the avidin-conjugated dye with unbiotinylated cells. Uptake was detected within minutes with efficiencies approaching 100% in cell lines and freshly obtained peripheral blood mononuclear cells. After 24 h, avidin was barely detectable on the surface of the nucleated cells. In marked contrast, fluorescent avidin remained exclusively on the external membrane of erythrocytes after 24 h. To investigate biotin-mediated endocytosis for the delivery of DNA, we prepared polyethylenimine-avidin (PEI-avidin) conjugates. Surface biotinylation significantly increased the transfection efficiencies of PEI-avidin condensed plasmid DNA coding green fluorescent protein (GFP) to the level of transferrin-receptor targeted gene delivery (15-20% GFP positive cells in culture after 48 h). The increase in transfection efficiency was blocked by the addition of free avidin or biotin to the culture medium. Biotin covalently bound to cell surface membrane proteins efficiently mediates the entry of avidin bioconjugates into nucleated cells.     

Arg9-peptide facilitates the internalization of an anti-CEA immunotoxin and potentiates its specific cytotoxicity to target cells

Arginines-containing membrane translocational signals (MTS), such as Tat(47-57) and VP22(267-300), and synthetic arginine-rich peptides have been reported to be efficient carriers for transporting various types of biomolecules into cytoplasmic and nuclear compartments of living cells. Among those arginines-containing MTS, a 9-mer arginine peptide (Arg9) was proved the most economical and efficient. We fused Arg9-peptide to an anti-CEA (Carcinoembryonic antigen) immunotoxin, PE35/CEA(Fv)/KDEL, at the position between the toxin moiety and the binding moiety. Strong binding and internalization of this fusion protein was observed in all detected cell lines, but little cytotoxicity to the cells that lack the CEA molecules on the cell surface was detected. However, the cytotoxicity besides the binding activity of the fusion protein to specific tumor cells expressing large amount of CEA molecules on the cell surface was improved markedly, indicating that the Arg9-peptide is capable of facilitating the receptor-mediated endocytosis of this immunotoxin, which leads to the increase of the specific cytotoxicity of this immunotoxin.     

A stepwise dissection of the intracellular fate of cationic cell-penetrating peptides

The role of endosomal acidification and retrograde transport for the uptake of the highly basic cell-penetrating peptides penetratin, Tat, and oligoarginine was investigated. The effect of a panel of drugs that interfere with discrete steps of endocytosis or Golgi-mediated transport on uptake and cellular distribution of fluorescein-labeled peptide analogues was probed by confocal microscopy, flow cytometry, and fluorescence spectroscopy of whole cell lysates. The analyses were carried out in MC57 fibrosarcoma cells and in HeLa cells. While MC57 fibrosarcoma cells showed some vesicular fluorescence and a pronounced cytoplasmic fluorescence, in HeLa cells little cytoplasmic fluorescence was observed. In MC57 cells the inhibitors of endosomal acidification chloroquine and bafilomycin A1 abolished the release of the peptides into the cytoplasm. Release into the cytosol preserved endosomal integrity. In addition, cellular uptake of the peptides was inhibited by brefeldin A, a compound interfering with trafficking in the trans-Golgi network. In contrast, nordihydroguaiaretic acid, a drug that stimulates the rapid retrograde movement of both Golgi stacks and trans-Golgi network to the endoplasmic reticulum, promoted a cytoplasmic localization of Tat peptides in peptide-pulsed HeLa cells. The effects of these drugs on trafficking shared characteristics with those reported for the trafficking of plant and bacterial toxins, such as cholera toxin, which reach the cytoplasm by means of retrograde transport. A sequence comparison revealed a common stretch of 8-10 amino acids with high sequence homology to the Tat peptide. The structural and functional data therefore strongly suggest a common mechanism of import for cationic cell-penetrating peptides and the toxins.     

Inhibition by glucocorticoids of endocytosis in a macrophage-like cell line

A macrophage-like cell line (P388D1) has been used to demonstrate that glucocorticoids inhibit the fluid-phase endocytosis of fluorescein-labeled dextran (FITC-dextran). Initial experiments demonstrated that the interaction of FITC-dextran with cells had all the features of fluid-phase uptake, ie, the amount taken up was proportional to the concentration in the medium, the uptake proceeded continuously with time and was blocked at 4 degrees C. Dexamethasone (10(-7) M) had no effect on endocytosis until 11 hours after addition of the steroid, when it inhibited the uptake of FITC-dextran by 35%. The amount of inhibition increased with longer exposure times to the hormone up to 50% after 22 hours. Although this effect on endocytosis was observed prior to any effect on growth of the cells, endocytosis as well as cell proliferation were inhibited in a dose dependent fashion. A preliminary survey of selected steroids has established that the inhibition of endocytosis was restricted to steroids of the glucocorticoid class. The key experiments were also performed using horseradish peroxidase instead of FITC-dextran with, essentially, identical results.     

Characterization of endocytic uptake of MK2‐inhibitor peptides

Cell penetrating peptides (CPP) have been widely used to increase the cellular delivery of their associated cargo. Multiple modes of uptake have been identified; however, they cannot be predicted a priori. Elucidating these mechanisms is important for understanding peptide function as well as further optimizing cellular delivery. We have developed a class of mitogen activated protein kinase activated protein kinase 2 (MK2) inhibitor peptides, named FAK and YARA that utilize CPP domains to gain cellular access. In this study, we investigate the mechanism of endocytosis of these MK2 inhibitors by examining the uptake of fluorescently labeled peptide in human monocyte (THP‐1) and mesothelial cells, and looking for colocalization with known markers of endocytosis. Our results indicate that uptake of the MK2 inhibitors was minimally enhanced by the addition of the fluorescent label, and that the type of endocytosis used by the inhibitor depends on several factors including concentration, cell type, and which CPP was used. We found that in THP‐1 cells, the uptake of YARA occurred primarily via macropinocytosis, whereas FAK entered via all three mechanisms of endocytosis examined in this study. In mesothelial cells, uptake of YARA occurred via caveolae‐mediated endocytosis, but became less specific at higher concentrations; whereas uptake of FAK occurred through clathrin‐mediated endocytosis. In all cases, the delivery resulted in active inhibition of MK2. In summary, the results support endocytic uptake of fluorescently labeled FAK and YARA in two different cell lines, with the mechanism of uptake dependent on extracellular concentration, cell type, and choice of CPP. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Intracellular delivery of proteins in complexes with oligoarginine-modified liposomes and the effect of oligoarginine length

The intracellular delivery of proteins using cell-penetrating peptides (CPPs) including oligoarginine (oligo-Arg) carriers raises the possibility of establishing novel therapeutic methods. We compared the effect of the length of oligo-Arg in modified liposomes ((Arg)(n)-L; n = 4, 6, 8, 10) on the delivery of proteins by flow cytometry, fluorescence microscopy, and spectrofluorimetry. As a free liposome, Arg4-modified liposome Arg4-L was most efficiently internalized in cells. The efficiency decreased depending on the length of oligo-Arg. For the intracellular delivery of proteins, (Arg)(n)-L was physically associated with proteins. Concerning the effect of oligo-Arg length, liposome/protein complexes showed a different behavior. Arg4-L carried bovine serum albumin (BSA, 66 kDa) and beta-galactosidase (beta-Gal, 120 kDa) 6-fold higher than free BSA and free beta-Gal. Arg10-L showed similar performance for these two proteins to Arg4-L. The enzymatic activity of beta-Gal in the cells showed that proteins were transported as a biologically active form. Arg10-L carried 100-fold more immunoglobulin G (IgG, 150 kDa) than free IgG, and 3-fold more than Arg4-L into cells. Shorter oligo-Arg chain on liposomes may be enough for liposomes alone to be taken up in cells, but more Arg residues may be needed to form a complex with high molecular weight proteins and deliver them into cells. This information will aid in the design of (Arg)(n)-L as a carrier for delivering proteins into cells.     

The signal peptide NPFSD fused to ricin A chain enhances cell uptake and cytotoxicity in Candida albicans

Microorganisms possess stringent cell membranes which limit the cellular uptake of antimicrobials. One strategy to overcome these barriers is to attach drugs or research reagents to carrier peptides that enter cells by passive permeation or active uptake. Here the short endocytosis signal peptide NPFSD was found to efficiently deliver both FITC and GFP into Saccharomyces cerevisiae and Candida albicans with uptake into the majority of cells in a population. The NPFSD signal is itself non-toxic, but when fused to the ricin A chain toxin (RTA) the peptide enhanced both cell uptake and toxicity against C. albicans, which like other yeasts is resistant to naked RTA. Cell entry required at least 1 h incubation, temperatures above 4 degrees C, and an energy source, and uptake was out-competed with free peptide. Therefore, the NPFSD peptide can carry a range of compounds into yeasts and this delivery route holds promise to enhance the activity of antifungals.     

Study of uptake of cell penetrating peptides and their cargoes in permeabilized wheat immature embryos

The uptake of five fluorescein labeled cell-penetrating peptides (Tat, Tat(2), mutated-Tat, peptide vascular endothelial-cadherin and transportan) was studied in wheat immature embryos. Interestingly, permeabilization treatment of the embryos with toluene/ethanol (1 : 20, v/v with permeabilization buffer) resulted in a remarkably higher uptake of cell-penetrating peptides, whereas nonpermeabilized embryos failed to show significant cell-penetrating peptide uptake, as observed under fluorescence microscope and by fluorimetric analysis. Among the cell-penetrating peptides investigated, Tat monomer (Tat) showed highest fluorescence uptake (4.2-fold greater) in permeabilized embryos than the nonpermeabilized embryos. On the other hand, mutated-Tat serving as negative control did not show comparable fluorescence levels even in permeabilized embryos. A glucuronidase histochemical assay revealed that Tat peptides can efficiently deliver functionally active beta-glucuronidase (GUS) enzyme in permeabilized immature embryos. Tat(2)-mediated GUS enzyme delivery showed the highest number of embryos with GUS uptake (92.2%) upon permeabilization treatment with toluene/ethanol (1 : 40, v/v with permeabilization buffer) whereas only 51.8% of nonpermeabilized embryos showed Tat(2)-mediated GUS uptake. Low temperature, endocytosis and macropinocytosis inhibitors reduced delivery of the Tat(2)-GUS enzyme cargo complex. The results suggest that more than one mechanism of cell entry is involved simultaneously in cell-penetrating peptide-cargo uptake in wheat immature embryos. We also studied Tat(2)-plasmid DNA (carrying Act-1GUS) complex formation by gel retardation assay, DNaseI protection assay and confocal laser microscopy. Permeabilized embryos transfected with Tat(2)-plasmid DNA complex showed 3.3-fold higher transient GUS gene expression than the nonpermeabilized embryos. Furthermore, addition of cationic transfecting agent Lipofectamine 2000 to the Tat(2)-plasmid DNA complex resulted in 1.5-fold higher transient GUS gene expression in the embryos. This is the first report demonstrating translocation of various cell-penetrating peptides and their potential to deliver macromolecules in wheat immature embryos in the presence of a cell membrane permeabilizing agent.     

No entry for TAT(44-57) into liposomes and intact MDCK cells: novel approach to study membrane permeation of cell-penetrating peptides

Cell penetrating peptides (CPPs) have been postulated to carry macromolecules across cell plasma membranes without the need of receptors, transporters, endocytosis or any energy-consuming mechanism. We developed an assay to study lipid bilayer permeation of CPPs. HIV-1 TAT peptides were conjugated to N-(4-carboxy-3-hydroxyphenyl)maleimide (SAM) and incubated with Tb(3+)-containing liposomes. Upon chelation of Tb(3+) by an aromatic carboxylic acid, the fluorescence of Tb(3+) increases many fold. The CPP TAT(44-57)-SAM and TAT(37-53)-SAM, as a negative control, were unable to enter liposomes consisting of phosphatidylcholine (PC) or a mix of PC, negatively charged lipids and cholesterol. In parallel, cell entry of fluorescein-labeled TAT peptides was studied using confocal laser scanning microscopy (CLSM). TAT(44-57)-fluorescein did not enter Madin Darby canine kidney (MDCK) cells with intact plasma membranes but accumulated at their basal side. Only cells with impaired plasma membranes, as identified by nuclear staining with ethidium homodimer-1 (EthD-1), showed accumulation of TAT(44-57). Our findings change the perspectives of the potential use of TAT peptides as carriers for intracellular targeting. SAM- and fluorescein-labeled TAT(44-57) cannot penetrate lipid bilayers and intact plasma membranes of MDCK cells, respectively.     

Cellular uptake of antisense morpholino oligomers conjugated to arginine-rich peptides

Although the sequence specificity, biostability, and low toxicity of PMO (phosphorodiamidate morpholino oligomers) make them good antisense agents to study gene function, their limited ability to cross cell membranes limits their use in cell culture. In this paper we show that conjugation to arginine-rich peptides significantly enhanced the cellular uptake of PMO. The factors that affect the conjugate's cellular uptake and its antisense activity toward a targeted mRNA were investigated. Factors studied include the number of arginines in the peptide, the choice of cross-linker, the peptide conjugation position, the length of the PMO, and the cell culture conditions. Delivery of PMO to the cell nucleus and cytosol required conjugation rather than complexation of peptides to PMO. R(9)F(2)C was best suited to deliver a PMO to its target RNA resulting in the strongest antisense effect. By simply adding the R(9)F(2)C-PMO conjugate into the cell culture medium at low microM concentration, missplicing of pre-mRNA was corrected. This particular peptide-conjugated PMO was more effective than the PMO conjugated to the transmembrane transport peptides of HIV-1 Tat protein, Drosophila antennapedia protein, or to peptides with fewer arginines. Length of PMO did not affect a peptide's delivery efficacy, but all other factors were important. R(9)F(2)C peptide provided a simple and efficient delivery of PMO to a RNA target. Conjugation of peptide to PMO enhances the opportunities to evaluate gene functions in cell cultures.     

Cell surface proteoglycan-mediated uptake and accumulation of the Alzheimer's disease peptide Aβ(1–42)

Proteoglycans (PGs) have been found in Alzheimer's disease amyloid-β (Aβ) plaques and their glycosaminoglycan chains reportedly influence Aβ aggregation, neurotoxicity and intracellular accumulation in cell and animal models, but their exact pathophysiological role(s) remain unclear. We have studied the cellular uptake of fluorescently labelled Aβ(1–42) and Aβ(1–40) peptides in normal CHO cells (K1) and the mutant cell line (pgsA-745) which lacks all protein-attached heparan and chondroitin sulfate chains. After 24 h of incubation, CHO-K1 accumulates more Aβ(1–42) and Aβ(1–40) compared with CHO-pgsA-745, consistent with the suggested role of PGs in Aβ uptake. However, after short incubation times (≤3 h) there was no difference; moreover, the time evolution of Aβ(1–42) accumulation in CHO-K1 followed an unusual sigmoidal-like trend, indicating a possible involvement of PG-mediated peptide aggregation in Aβ endocytosis. Neither Aβ(1–42) nor Aβ(1–40) could stimulate uptake of a 10 kDa dextran (a general endocytosis marker) suggesting that Aβ-induced upregulation of endocytosis does not occur. CHO-K1 cells contained a higher number of Aβ(1–42)-positive vesicles, but the intensity difference per vesicle was only marginal suggesting that the superior accumulation of Aβ(1–42) stems from a higher number of endocytic events. FRET imaging support that intracellular Aβ(1–42) is aggregated in both cell types. We also report that CHO-pgsA-745 cells perform less endocytosis than CHO-K1 and, albeit this does not explain their difference in Aβ internalisation, we discuss a general method for data compensation. Altogether, this study contributes new insights into the mechanisms of PG-mediated Aβ uptake that may be relevant for our understanding of their role in AD pathology.     

A comprehensive model for the cellular uptake of cationic cell-penetrating peptides

The plasma membrane represents an impermeable barrier for most macromolecules. Still some proteins and so-called cell-penetrating peptides enter cells efficiently. It has been shown that endocytosis contributes to the import of these molecules. However, conflicting results have been obtained concerning the nature of the endocytic process. In addition, there have been new findings for an endocytosis-independent cellular entry. In this study, we provide evidence that the Antennapedia-homeodomain-derived antennapedia (Antp) peptide, nona-arginine and the HIV-1 Tat-protein-derived Tat peptide simultaneously use three endocytic pathways: macropinocytosis, clathrin-mediated endocytosis and caveolae/lipid-raft-mediated endocytosis. Antennapedia differs from Tat and R9 by the extent by which the different import mechanisms contribute to uptake. Moreover, at higher concentrations, uptake occurs by a mechanism that originates from spatially restricted sites of the plasma membrane and leads to a rapid cytoplasmic distribution of the peptides. Endocytic vesicles could not be detected, suggesting an endocytosis-independent mode of uptake. Heparinase treatment of cells negatively affects this import, as does the protein kinase C inhibitor rottlerin, expression of dominant-negative dynamin and chlorpromazine. This mechanism of uptake was observed for a panel of different cell lines. For Antp, significantly higher peptide concentrations and inhibition of endocytosis were required to induce its uptake. The relevance of these findings for import of biologically active cargos is shown.     

Re-examination of CD91 function in GRP94 (glycoprotein 96) surface binding, uptake, and peptide cross-presentation

GRP94 (gp96)-peptide complexes can be internalized by APCs and their associated peptides cross-presented to yield activation of CD8(+) T cells. Investigations into the identity (or identities) of GRP94 surface receptors have yielded conflicting results, particularly with respect to CD91 (LRP1), which has been proposed to be essential for GRP94 recognition and uptake. To assess CD91 function in GRP94 surface binding and endocytosis, these parameters were examined in mouse embryonic fibroblast (MEF) cell lines whose expression of CD91 was either reduced via RNA interference or eliminated by genetic disruption of the CD91 locus. Reduction or loss of CD91 expression abrogated the binding and uptake of receptor-associated protein, an established CD91 ligand. Surface binding and uptake of an N-terminal domain of GRP94 (GRP94.NTD) was unaffected. GRP94.NTD surface binding was markedly suppressed after treatment of MEF cell lines with heparin, sodium chlorate, or heparinase II, demonstrating that heparin sulfate proteoglycans can function in GRP94.NTD surface binding. The role of CD91 in the cross-presentation of GRP94-associated peptides was examined in the DC2.4 dendritic cell line. In DC2.4 cells, which express CD91, GRP94.NTD-peptide cross-presentation was insensitive to the CD91 ligands receptor-associated protein or activated α(2)-macroglobulin and occurred primarily via a fluid-phase, rather than receptor-mediated, uptake pathway. These data clarify conflicting data on CD91 function in GRP94 surface binding, endocytosis, and peptide cross-presentation and identify a role for heparin sulfate proteoglycans in GRP94 surface binding.