Platelet microparticles inhibit IL-17 production by regulatory T cells through P-selectin.

Self-tolerance and immune homeostasis are orchestrated by FOXP3(+)regulatory T cells (Tregs). Recent data have revealed that upon stimulation, Tregs may exhibit plasticity toward a proinflammatory phenotype, producing interleukin 17 (IL-17) and/or interferon γ (IFN-γ). Such deregulation of Tregs may contribute to the perpetuation of inflammatory processes, including graft-versus-host disease. Thus, it is important to identify immunomodulatory factors influencing Treg stability. Platelet-derived microparticles (PMPs) are involved in hemostasis and vascular health and have recently been shown to be intimately involved in (pathogenic) immune responses. Therefore, we investigated whether PMPs have the ability to affect Treg plasticity. PMPs were cocultured with healthy donor peripheral blood-derived Tregs that were stimulated with anti-CD3/CD28 monoclonal antibodies in the presence of IL-2, IL-15, and IL-1ß. PMPs prevented the differentiation of peripheral blood-derived Tregs into IL-17- and IFN-γ-producing cells, even in the presence of the IL-17-driving proinflammatory cytokine IL-1ß. The mechanism of action by which PMPs prevent Treg plasticity consisted of rapid and selective P-selectin-dependent binding of PMPs to a CCR6(+)HLA-DR(+)memory-like Treg subset and their ability to inhibit Treg proliferation, in part through CXCR3 engagement. The findings that ~8% of Tregs in the circulation of healthy individuals are CD41(+)P-selectin(+)and that distinct binding of patient plasma PMPs to Tregs was observed support in vivo relevance. These findings open the exciting possibility that PMPs actively regulate the immune response at sites of (vascular) inflammation, where they are known to accumulate and interact with leukocytes, consolidating the (vascular) healing process.

A Conjugate of an Anti-Epidermal Growth Factor Receptor (EGFR) VHH and a Cell-Penetrating Peptide Drives Receptor Internalization and Blocks EGFR Activation.

Overexpression of (mutated) receptor tyrosine kinases is a characteristic of many aggressive tumors, and induction of receptor uptake has long been recognized as a therapeutic modality. A conjugate of a synthetically produced cell-penetrating peptide (CPP), corresponding to amino acids 38-59 of human lactoferrin, and the recombinant llama single-domain antibody (VHH) 7D12, which binds the human epidermal growth factor receptor (EGFR), was generated by sortase A mediated transpeptidation. The conjugate blocks EGF-mediated EGFR activation with higher efficacy than that of both modalities alone; a phenomenon that is caused by both effective receptor blockade and internalization. Thus, the VHH-CPP conjugate shows a combination of activities that implement a highly powerful new design principle to block receptor activation by its clearance from the cell surface.

Multivalent presentation of the cell-penetrating peptide nona-arginine on a linear scaffold strongly increases its membrane-perturbing capacity.

Arginine-rich cell-penetrating peptides (CPP) are widely employed as delivery vehicles for a large variety of macromolecular cargos. As a mechanism-of-action for induction of uptake cross-linking of heparan sulfates and interaction with lipid head groups have been proposed. Here, we employed a multivalent display of the CPP nona-arginine (R9) on a linear dextran scaffold to assess the impact of heparan sulfate and lipid interactions on uptake and membrane perturbation. Increased avidity through multivalency should potentiate molecular phenomena that may only play a minor role if only individual peptides are used. To this point, the impact of multivalency has only been explored for dendrimers, CPP-decorated proteins and nanoparticles. We reasoned that multivalency on a linear scaffold would more faithfully mimic the arrangement of peptides at the membrane at high local peptide concentrations. On average, five R9 were coupled to a linear dextran backbone. The conjugate displayed a direct cytoplasmic uptake similar to free R9 at concentrations higher than 10µM. However, this uptake was accompanied by an increased membrane disturbance and cellular toxicity that was independent of the presence of heparan sulfates. In contrast, for erythrocytes, the multivalent conjugate induced aggregation, however, showed only limited membrane perturbation. Overall, the results demonstrate that multivalency of R9 on a linear scaffold strongly increases the capacity to interact with the plasma membrane. However, the induction of membrane perturbation is a function of the cellular response to peptide binding.

The stoichiometry of peptide-heparan sulfate binding as a determinant of uptake efficiency of cell-penetrating peptides.

Binding to negatively charged heparan sulfates (HS) at the cell surface is considered the first step in the internalization of cationic cell-penetrating peptides (CPPs). However, little is known about the relation of the characteristics of the HS-CPP interaction such as affinity, stoichiometry, and clustering with uptake. In this study, we investigated a collection of mutants of a cyclic CPP derived from human lactoferrin with respect to HS binding and uptake. The thermodynamic parameters of HS binding were determined by isothermal titration calorimetry, clustering of HS was investigated by dynamic light scattering, and cellular uptake by flow cytometry and confocal microscopy. Whereas mutations of non-arginine amino acids that are conserved across lactoferrins of different mammalia only had a minor effect on uptake efficiency, changes in the number of arginine residues influenced the uptake significantly. In general, introduction of arginine residues and cyclization improved the HS affinity and the ability to cluster HS. In particular, there was a strong negative correlation between stoichiometry and uptake, indicating that crosslinking of HS is the driving force for the uptake of arginine-rich CPPs. Using glycan microarrays presenting a collection of synthetic HS, we show that a minimal chain length of HS is required for peptide binding.

Detecting Cytosolic Peptide Delivery with the GFP Complementation Assay in the Low Micromolar Range.

Transfection of cells with a plasmid encoding for the first ten strands of the GFP protein (GFP1-10) provides the means to detect cytosolic peptide import at low micromolar concentrations. Cytosolic import of the eleventh strand of the GFP protein either by electroporation or by cell-penetrating peptide-mediated import leads to formation of the full-length GFP protein and fluorescence. An increase in sensitivity is achieved through structural modifications of the peptide and the expression of GFP1-10 as a fusion protein with mCherry.

Exploration of the design principles of a cell-penetrating bicylic peptide scaffold.

Cell-penetrating peptides (CPPs) possess the capacity to induce cell entry of themselves and attached molecular cargo, either by endocytosis or by direct translocation. Conformational constraints have been described as one means to increase the activity of CPPs, especially for direct crossing of the plasma membrane. Here, we explored the structure-activity relationship of bicyclic peptides for cell entry. These peptides may be considered minimal analogues of naturally occurring oligocyclic peptide toxins and are a promising scaffold for the design of bioactive molecules. Increasing numbers of arginine residues that are primarily contributing to cell-penetrating activity were introduced either into the cycles, or as stretches outside the cycles, at both ends or at one end only. In addition, we probed for the impact of negatively charged residues on activity for both patterns of arginine substitution. Uptake was investigated in HeLa cells by flow cytometry and confocal microscopy. Overall, uptake efficiency showed a positive correlation with the number of arginine residues. The subcellular distribution was indicative of endocytic uptake. One linear stretch of arginines coupled outside the bicycle was as effective in promoting uptake as substituting the same number of arginines inside the bicycles. However, the internally substituted analogues were more sensitive to the presence of negatively charged residues. For a given bicyclic peptide, uptake was more effective than for the linear counterpart. Introduction of histidine and tryptophans further increased uptake efficiency to comparable levels as that of nonaarginine despite the larger size of the bicyclic backbone. The results demonstrate that both arginine clustering and spatial constraints are uptake-promoting structural principles, an observation that gives freedom in the introduction of cell-penetrating capacity to structurally constrained scaffolds.

Modulation of Orai1 by cationic peptides triggers their direct cytosolic uptake.

At concentrations exceeding 10 µM, arginine-rich cell-penetrating peptides (CPPs) trigger a rapid cytoplasmic import that involves activation of acid sphingomyelinase (ASMase). ASMase activation occurs through a variety of stress signals and has also been related to the reorganization of membrane microdomains during entry of pathogens. However, in none of these cases has the initial trigger for ASMase activation been established on a molecular level. We here show that rapid cytosolic CPP import depends upon an increase in intracellular calcium, likely caused by modulation of the Orai1 calcium channel. At low peptide concentration, cytoplasmic import could be induced by thapsigargin, a known activator of Orai1. Compounds known to block Orai1 inhibited rapid uptake. Peptide-mediated modulation of Orai1 involved cell surface sialic acids as inhibition of sialylation as well as chemical blocking of sialic acids reduced rapid cytoplasmic uptake, which could be reconstituted by thapsigargin. These results establish a link between the known propensity of arginine-rich CPPs to interact with the glycocalyx and calcium influx as the initial step triggering direct cytosolic peptide uptake.

The effect of subcellular localization on the efficiency of EGFR-targeted VHH photosensitizer conjugates.

Photodynamic therapy (PDT) is an emerging method to treat light-accessible malignancies. To increase specificity and allow dose reduction, conjugates of photosensitizers (PS) with antibodies against tumor-associated antigens have been developed for photoimmunotherapy (PIT). However, so far it is unclear whether cellular internalization of these conjugates after binding affects PIT efficacy. The use of low molecular weight llama single domain antibodies (VHHs, nanobodies) for PIT is preferred above full size antibodies because of better tumor penetration. Therefore, we functionalized the VHH 7D12, directed against the epidermal growth factor receptor (EGFR), with a PS (IRDye700DX). To assess the impact of cellular internalization on activity, the VHHs were additionally conjugated to a cell-penetrating peptide (VHH[PS]-CPP). Here we show that upon illumination with near-infrared (NIR) light, both VHH[PS] and VHH[PS]-CPP conjugates specifically induce cell death of EGFR expressing cancer cell lines and of EGFR-expressing cells derived from surgically obtained ascites from patients with high-grade serous ovarian cancer. However, VHH[PS] conjugates were significantly more effective compared to internalizing VHH[PS]-CPP suggesting that cell surface association is required for optimal therapeutic activity.

A critical assessment of the synthesis and biological activity of p53/human double minute 2-stapled peptide inhibitors.

BACKGROUND AND PURPOSE: Helix stapling enhances the activity of peptides that interact with a target protein in a helical conformation. These staples are also supposed to change the pharmacokinetics of the molecules and promote cytoplasmic targeting. We assessed the extent to which the pharmacokinetic characteristics are a function of the staple for a peptide inhibiting the interaction of p53 with the human double minute 2 (Hdm2) protein and differ from those of the standard cationic cell-penetrating peptide nona-arginine. EXPERIMENTAL APPROACH: Stapled peptides and linear counterparts were synthesized in free and fluorescently labelled forms. Activity was determined in biochemical time-resolved Förster resonance energy transfer experiments and cellular high-content assays. Cellular uptake and intracellular trafficking were visualized by confocal microscopy. KEY RESULTS: Peptides showed sub-nanomolar potency. For short-time incubation, uptake efficiencies for the stapled and linear peptides were similar and both were taken up less efficiently than nona-arginine. Only for SJSA-1 cells expressing the Hdm2 target protein, the stapled peptides showed an enhanced cytoplasmic and nuclear accumulation after long-term incubation. This was also observed for the linear counterparts, albeit to a lesser degree. For HeLa cells, which lack target expression, no such accumulation was observed. CONCLUSION AND IMPLICATIONS: Cytosolic and nuclear accumulation was not an intrinsic property of the stapled peptide, but resulted from capture by the target Hdm2 after endo-lysosomal release. Considering the rather poor uptake of stapled peptides, further development should focus on increasing the efficiency of uptake of these peptides.

Membrane permeation of arginine-rich cell-penetrating peptides independent of transmembrane potential as a function of lipid composition and membrane fluidity.

Cell-penetrating peptides (CPPs) are prominent delivery vehicles to confer cellular entry of (bio-) macromolecules. Internalization efficiency and uptake mechanism depend, next to the type of CPP and cargo, also on cell type. Direct penetration of the plasma membrane is the preferred route of entry as this circumvents endolysosomal sequestration. However, the molecular parameters underlying this import mechanism are still poorly defined. Here, we make use of the frequently used HeLa and HEK cell lines to address the role of lipid composition and membrane potential. In HeLa cells, at low concentrations, the CPP nona-arginine (R9) enters cells by endocytosis. Direct membrane penetration occurs only at high peptide concentrations through a mechanism involving activation of sphingomyelinase which converts sphingomyelin into ceramide. In HEK cells, by comparison, R9 enters the cytoplasm through direct membrane permeation already at low concentrations. This direct permeation is strongly reduced at room temperature and upon cholesterol depletion, indicating a complex dependence on membrane fluidity and microdomain organisation. Lipidomic analyses show that in comparison to HeLa cells HEK cells have an endogenously low sphingomyelin content. Interestingly, direct permeation in HEK cells and also in HeLa cells treated with exogenous sphingomyelinase is independent of membrane potential. Membrane potential is only required for induction of sphingomyelinase-dependent uptake which is then associated with a strong hyperpolarization of membrane potential as shown by whole-cell patch clamp recordings. Next to providing new insights into the interplay of membrane composition and direct permeation, these results also refute the long-standing paradigm that transmembrane potential is a driving force for CPP uptake.

Methods to Study the Role of the Glycocalyx in the Uptake of Cell-Penetrating Peptides.

Cells are covered by a layer of negatively charged oligo- and polysaccharides, the glycocalyx. Cell-penetrating peptides and other drug delivery vehicles first encounter these polyanions before contacting the lipid bilayer of the plasma membrane. While a large body of data supports the notion that interactions with the glycocalyx promote or even trigger uptake, in some cases, the glycocalyx compromises delivery. As a consequence there is a need to address the role of the glycocalyx in delivery for each specific delivery vehicle and for each particular type of cell. Here, we describe protocols to obtain information on the composition and dynamics of the glycocalyx, and the role of individual glycocalyx components in the uptake of drug delivery vehicles.

Glycosaminoglycans in the cellular uptake of drug delivery vectors - bystanders or active players?

The implementation of efficient strategies for cellular delivery is the most significant hurdle in the development of oligonucleotide and protein-based nanomedicines. Unlike small molecule drugs that enter cells by virtue of hydrophobicity or by being substrates of transporters, these macromolecules lack the capacity to cross the plasma membrane in a non-disruptive way, therefore requiring the combination with carriers that mediate entry. Remarkably, for the major part, these carriers lack distinct structural features except for a high density of positive charge. Uptake has been attributed to the ability to engage in electrostatic interactions with the lipid bilayer and negatively charged glycosaminoglycans (GAGs) of the cellular glycocalyx. However, conflicting evidence has been obtained to which degree the interaction with GAGs contributes to uptake and the molecular mechanisms involved in uptake. Also, it is not clear to which extent the same molecular mechanisms apply for the different types of cationic delivery vectors. Here, we review the available data for cationic delivery vectors, including lipoplexes, polyplexes and cell-penetrating peptides (CPPs). We show that in spite of their different molecular size and degree of positive charge, all types of vectors share major characteristics with respect to the suggested role of GAGs in uptake. Moreover, by a comparison with the role of heparan sulfates in viral uptake we propose new avenues in the search for molecular mechanisms that trigger uptake of drug delivery vehicles and discuss how these insights may translate into new design principles for nanomedicines.

Activation of cell-penetrating peptides by disulfide bridge formation of truncated precursors.

A small library of oligoarginine peptides equipped with terminal cysteines was studied with respect to their cell-penetrating properties. The peptides themselves were inactive but gained the ability to enter cells upon extension of their sequence through disulfide bridge formation.

Cell surface clustering of heparan sulfate proteoglycans by amphipathic cell-penetrating peptides does not contribute to uptake.

For arginine-rich cell-penetrating peptides (CPPs), an association with heparan sulfate (HS) chains is considered the first step in the stimulation of uptake for many cells. Much less is known about the role of HS chains in the cell-association and internalization of arginine-free amphipathic CPP such as transportan-10 (TP10). Here, we report that various TP10 analogs differ in their capacity to accumulate on HS-rich plasma membranes in an HS-dependent manner. No accumulation was observed on HS-poor plasma membranes or when HS was removed by enzymatic cleavage. The TP10 analog that strongly clustered on the cell surface, also showed a pronounced capacity to form clusters with HS chains in solution. However, aggregation occurred in a thermodynamically different way compared to the interaction of arginine-rich CPP with HS. To monitor the impact of the peptide on the aggregation of the glycocalyx by time-lapse microscopy, sialic acids were visualized by metabolic labeling using copper-free click chemistry to attach fluorophores to metabolically incorporated azido sugars. Strikingly, a highly enhanced HS-mediated accumulation on the plasma membrane of a particular TP10 analog did not correlate with a better uptake. These findings illustrate that the mode of interaction between cell-penetrating peptides and HS chains has important functional consequences regarding peptide internalization and that there is no direct coupling of interaction, accumulation and uptake.