Metal-Assembled Collagen Peptide Microflorettes as Magnetic Resonance Imaging Agents.

Magnetic resonance imaging (MRI) is a medical imaging technique that provides detailed information on tissues and organs. However, the low sensitivity of the technique requires the use of contrast agents, usually ones that are based on the chelates of gadolinium ions. In an effort to improve MRI signal intensity, we developed two strategies whereby the ligand DOTA and Gd(III) ions are contained within Zn(II)-promoted collagen peptide (NCoH) supramolecular assemblies. The DOTA moiety was included in the assembly either via a collagen peptide sidechain (NHdota) or through metal-ligand interactions with a His-tagged DOTA conjugate (DOTA-His6). SEM verified that the morphology of the NCoH assembly was maintained in the presence of the DOTA-containing peptides (microflorettes), and EDX and ICP-MS confirmed that Gd(III) ions were incorporated within the microflorettes. The Gd(III)-loaded DOTA florettes demonstrated higher intensities for the T1-weighted MRI signal and higher longitudinal relaxivity (r1) values, as compared to the clinically used contrast agent Magnevist. Additionally, no appreciable cellular toxicity was observed with the collagen microflorettes loaded with Gd(III). Overall, two peptide-based materials were generated that have potential as MRI contrast agents.

Dimeric unnatural polyproline-rich peptides with enhanced antibacterial activity.

We report a dimerization strategy to enhance the antibacterial potency of an otherwise weak cationic amphiphilic polyproline helical (CAPH) peptide. Overall, the dimeric CAPHs were more active against Escherichia coli and Staphylococcus aureus than the monomeric counterpart, reaching up to a 60-fold increase in potency. At their minimum inhibitory concentration (MIC), the dimeric peptides demonstrated no hemolytic activity or bacterial membrane disruption as monitored by ß-galactosidase release in E. coli. At higher concentrations the dimeric agents were found to induce ß-galactosidase release, but maintained negligible hemolytic activity, pointing to a potential shift in the mechanism of action at higher concentrations. Thus, discontinuous dimerization of an unnatural proline-rich peptide was a successful strategy to create potent de novo antibacterial peptides without membrane lysis.

Dimeric cationic amphiphilic polyproline helices for mitochondrial targeting.

PURPOSE: Efficient delivery of therapeutic biopolymers across cell membranes remains a daunting challenge. The development of cell-penetrating peptides (CPPs) has been useful; however, many CPPs are found trapped within endosomes, limiting their use as delivery agents. We optimize a class of CPPs, cationic amphiphilic polyproline helices (CAPHs), for direct transport into cells with mitochondrial localization through dimerization. METHODS: The CAPH P11LRR used for this study has been found to enter cells by two distinct pathways: an endocytotic pathway was favored at low concentrations; internalization by direct transport was observed at higher concentrations. CAPH was dimerized to probe if direct transport within cells may be enhanced through increased association of CAPH with the membrane and through the association of individual peptides within the membrane. RESULTS: The dimerization of the CAPH was found to significantly increase cellular uptake over its monomeric counterpart, with a concomitant lowering of the concentration threshold favoring direct transport. Evidence for direct transport within cells and mitochondrial localization was observed. CONCLUSIONS: CAPH cellular uptake efficiency can be significantly enhanced through peptide dimerization while favoring cell entry via direct transport at low concentration with low cell toxicity.

Cationic amphiphilic polyproline helix P11LRR targets intracellular mitochondria.

We demonstrate that P11LRR, a recently developed amphiphilic polyproline, cell penetrating agent, is able to locate inside the mitochondria of various cell lines when administrated at high concentrations. Mitochondrial targeting was verified by confocal fluorescence co-localization of P11LRR-fluorescein with Mitotracker Red. Elimination of mitochondrial membrane potential dramatically inhibits the localization of P11LRR to mitochondria. Concentration-dependency experiments suggest that cellular internalization of P11LRR occurs via two different pathways: endocytosis and direct transport. Results indicate that the latter pathway predominates at high concentrations of P11LRR, resulting in localization of the agent to the mitochondria. The membrane translocation pathway was further confirmed by two endocytosis inhibitors, cytochalasin D and phenylarsine oxide, and by modulation of plasma membrane potential. The potential of using P11LRR as a mitochondrial drug delivery vector was demonstrated through the delivery of a covalently linked small antioxidant, dimethyltyrosine (Dmt), which allowed for the reduction of chemically induced reactive oxygen species within the mitochondria.

Cationic amphiphilic polyproline helices: side-chain variations and cell-specific internalization.

Cell-penetrating peptides present an attractive and efficient tool for the delivery of a variety of cell impermeable cargoes across the cellular membrane. Cell-penetrating peptides usually consist of short basic peptide sequences that are internalized by a variety of cell lines. Most cell-penetrating peptides lack cell specificity, however, which greatly limits their use as efficient therapeutic agents. Herein, we present two cell-penetrating peptides displaying a type II polyproline helical backbone that are functionalized to contain six cationic moieties and two distinctive hydrophobic functionalities, namely isobutyl or benzyl groups. The uptake efficiency of these cationic amphiphilic polyproline helices was studied in seven different cell lines, six cancerous (MCF-7, HOS, HT1080, HeLa, KB-FD, KB3-1) and one non-cancerous (WI 38). The cationic amphiphilic polyproline helix P11LRR at 50 microM showed high specificity toward MCF-7 breast cancer cells. Co-culture experiments with P11LRR demonstrated almost exclusive internalization by MCF-7 cells and not WI38. The replacement of the isobutyl hydrophobic group with a benzyl moiety resulted in a shift in uptake efficiency and specificity across some cell lines. These results demonstrate that the type of hydrophobic residues utilized in the creation of cell-penetrating peptides can strongly influence the extent and specificity of cellular internalization.

Assembly of dithiocarbamate-anchored monolayers on gold surfaces in aqueous solutions.

Dithiocarbamates (DTCs) can be formed by the in situ condensation of polar alkylamines with CS 2, and assembled into dithiocarbamate-anchored monolayers (DAMs) on Au substrates in aqueous solutions. Primary and secondary amines can both be used to prepare DTCs, but have significant differences in their reactivities and product stabilities. Ultraviolet absorption spectroscopy provides a convenient method for monitoring in situ DTC formation as well as the formation of potential byproducts. The kinetics of DAM assembly on Au substrates as measured by second harmonic generation (SHG) indicated first-order rate processes and saturation coverages similar to those of alkanethiols on Au. However, the rate of adsorption did not change with DTC concentration in a manner expected of Langmuir kinetics, and is attributed to the competitive adsorption of alkylammonium counterions to the freshly oxidized Au substrate. These analyses establish a practical range of conditions for preparing DAMs from polar amines using in situ DTC formation.

Probing length effects and mechanism of cell penetrating agents mounted on a polyproline helix scaffold.

Cell penetrating peptides (CPP) displaying a type II polyproline helix backbone of different length and amphiphilic character were synthesized and their cellular uptake was compared. The longer CPP sequence, P14LRR, displayed a 7- to 12-fold higher uptake in MCF-7 cells as compared to its shorter counterpart, P11LRR, and a 35-fold higher uptake as compared to Tatp. These results demonstrate that an increased number of cationic and hydrophobic residues can strongly influence the extent of cellular internalization. Mechanistic investigations suggest internalization via a receptor independent endocytotic pathway with these agents.