Jean Chmielewski

Fluorescence Imaging of Cellular Glutathione Using a Latent Rhodamine

Glutathione is a crucial component of the redox homeostasis of cells, and altered levels have been linked to human pathologies. We constructed a latent fluorophore (RhoSS) that responds to cellular thiols in vitro and in cyto following intracellular reduction by glutathione to yield rhodamine 110. Importantly, RhoSS was demonstrated to respond to changing levels of glutathione in cells. This compound represents a class of rationally designed latent fluorophores with exciting potential for monitoring cellular thiols.

Characterization of a novel pH-sensitive peptide that enhances drug release from folate-targeted liposomes at endosomal pHs

Although liposomes have proven useful for the delivery of drugs and gene therapy vectors, their potencies are often compromised by poor unloading following uptake into their target cells. We have consequently explored the properties of a novel 29-residue amphipathic peptide that was designed by arrangement of hydrophobic and hydrophilic residues to disrupt liposomes at lower peptide concentrations than previously tested peptides. The peptide was indeed found to promote pH-dependent liposome unloading with improved efficiency. A peptide of the same sequence, but half the length, however, promoted pH-dependent permeabilization only at much higher concentrations. Further characterization of the longer peptide revealed that release of liposome contents (i) occurred at a pH of approximately 6, (ii) became less efficient as the size of the encapsulated cargo increased, and (iii) was moderately suppressed in cholesterol-containing liposomes. Use of this peptide to enhance the cytotoxicity of cytosine arabinoside encapsulated in folate-targeted liposomes demonstrated an increase in drug potency of approximately 30-fold. Gene expression by a serum-stable folate-targeted liposomal vector was also measurably enhanced by inclusion of the peptide. We conclude that intracellular unloading of liposomal contents can be significantly improved by co-encapsulation of an optimally designed, pH-sensitive peptide.

Selective amplification by auto- and cross-catalysis in a replicating peptide system

Self-replication has been demonstrated in synthetic chemical systems based on oligonucleotides, peptides and complementary molecules without natural analogues. However, within a living cell virtually no molecule catalyses its own formation, and the search for chemical systems in which both auto- and cross-catalysis can occur has therefore attracted wide interest. One such system, consisting of two self-replicating peptides that catalyse each others production, has been reported. Here we describe a four-component peptide system that is capable of auto- and cross-catalysis and allows for the selective amplification of one or more of the products by changing the reaction conditions. The ability of this system selectively to amplify one or more molecules in response to changes in environmental conditions such as pH or salt concentration supports the suggestion that self-replicating peptides may have played a role in the origin of life.

Inhibiting the assembly of protein-protein interfaces.

Protein-protein association is found throughout mechanisms of cellular growth and differentiation, and viral replication. Inhibiting the assembly of protein complexes, therefore, presents itself as a novel means of inhibition for a wide variety of cellular and viral events. Peptides and small molecules that modify the overall quaternary structure of a selection of receptor-ligand interactions and oligomeric viral enzymes have been developed recently.

Self-assembly of Collagen Peptides into Microflorettes via Metal Coordination

The self-assembly of synthetic biomaterials, such as collagen peptides, can be harnessed for a range of biomedical applications. In an effort to obtain collagen-based macromolecular assemblies with temporal control, we designed a system that assembled only in the presence of external stimuli. We report a collagen triple helical peptide that is modified with a His(2) moiety on its C-terminus and a nitrilotriacetic acid unit on its N-terminus that rapidly and reversibly assembles in the presence of metal ions. Dynamic light scattering and turbidity experiments confirmed the presence of higher order aggregates in solution upon the introduction of Zn(2+), Cu(2+), Ni(2+), and Co(2+). This assembly process was found to be fully reversible using EDTA as a metal ion chelator. Control peptides that contain only a single ligand-modified terminus were not responsive to the same metal ions, thus demonstrating the requirement of both ligand modifications for peptide assembly. Scanning electron microscopy imaging of the peptide-metal assemblies revealed micrometer-sized florettes in addition to curved, stacked sheets. More detailed analysis of the Zn(2+)-generated microflorettes showed that the surface of these particles contains ruffled structures with a highly dense surface area. Potential folding intermediates in the formation of the microflorettes were observed at lower temperatures and at early time points in the assembly that are composed of curved layered sheets. Significantly, the assembly process proceeded under mild conditions using neutrally buffered aqueous solution at room temperature. These microscopic structures offer opportunities in many areas, including drug delivery, tissue engineering, and regenerative medicine.

Metal-Triggered Radial Self-Assembly of Collagen Peptide Fibers

A metal-triggered self-assembling collagen peptide was designed and synthesized to generate fibers through a radial growth mechanism. The assembly of the fibers was made possible through the placement of a bipyridine ligands within the center of the triple helix and was triggered by the addition of Fe(II).

Cellular Import Mediated by Nuclear Localization Signal Peptide Sequences

The cellular delivery of therapeutic agents and their localization within cells is currently a great challenge in medicinal chemistry. A few cationic peptides have shown a strong propensity to cross the cytoplasmic membrane and enter cells. Nuclear localization signal (NLS) sequences are a class of highly cationic peptides that may be exploited for cellular import of linked cargo. A series of NLS sequence peptides were investigated for entry into different cancer cell lines by flow cytometry and confocal microscopy. All NLS peptides demonstrated rapid accumulation within cells when added to the cellular media. Covalent adducts of proteins and oligonucleotides with NLS peptides were also effectively imported within cells. An understanding of the structural and mechanistic properties of these sequences will provide great potential for the rational design of efficient and selective peptidic delivery systems.

Inhibition of P-Glycoprotein-Mediated Paclitaxel Resistance by Reversibly Linked Quinine Homodimers

P-glycoprotein (P-gp), an ATP-dependent drug efflux pump, has been implicated in multidrug resistance of several cancers as a result of its overexpression. In this work, rationally designed second-generation P-gp inhibitors are disclosed, based on dimerized versions of the substrates quinine and quinidine. These dimeric agents include reversible tethers with a built-in clearance mechanism. The designed agents were potent inhibitors of rhodamine 123 efflux in cultured cancer cell lines that display high levels of P-gp expression at the cell surface and in transfected cells expressing P-gp. The quinine homodimer Q2, which was tethered by reversible ester bonds, was particularly potent (IC50 ≈ 1.7 μM). Further studies revealed that Q2 inhibited the efflux of a range of fluorescent substrates (rhodamine 123, doxorubicin, mitoxantrone, and BODIPY-FL-prazosin) from MCF-7/DX1 cells. The reversibility of the tether was confirmed in experiments showing that Q2 was readily hydrolyzed by esterases in vitro (t½ ≈ 20 h) while demonstrating high resistance to nonenzymatic hydrolysis in cell culture media (t½ ≈ 21 days). Specific inhibition of [125I]iodoarylazidoprazosin binding to P-gp by Q2 verified that the bivalent agent interacted specifically with the drug binding site(s) of P-gp. Q2 was also an inhibitor of verapamil-stimulated ATPase activity. In addition, low concentrations of Q2 stimulated basal P-gp ATPase levels. Finally, Q2 was shown to inhibit the transport of radiolabeled paclitaxel (Taxol) in MCF-7/DX1 cells, and it completely reversed the P-gp-mediated paclitaxel resistance phenotype.

Metal-triggered collagen peptide disk formation.

A collagen peptide was designed for metal-triggered, hierarchical assembly through a radial growth mechanism. To achieve radial assembly, H-(byp)(2) containing Pro-Hyp-Gly repeating sequences and two staggered bipyridine ligands within the peptide was synthesized. Triple helix formation resulted in the placement of six bipyridine ligands along the triple helix, and the addition of metal ions resulted in the formation of nanometer-sized collagen peptide disks. These structures were found to disassemble upon the addition of EDTA, demonstrating that radial assembly of collagen peptide triple helices could be realized with the addition of metal ions.

A self-replicating peptide under ionic control

The chemical coupling of two peptide fragments to give the peptide K1 K2 (shown in the helical wheel diagram on the right) is autocatalytic at high NaClO4 concentrations (1 M). Under these conditions K1 K2 assumes a coiled-coil conformation, which can function as a template for the coupling. Autocatalysis is not observed under conditions that prevent formation of the coiled-coil conformation.