Identification of side arm-modified DOTA scaffolds as multi-site binding ligands for cancer cells over normal cells

The metal-chelated 1,4,7,10-tetraazacyclododecan-1,4,7,10-tetraacetic acid-tetraamide (DOTA) scaffold has been widely used as a contrast agent for diagnostic purposes in positron emission tomography (PET) and magnetic resonance imaging (MRI), but not as a biomarker targetable ligand. While the oxygen atoms at the stem of the four arms of the DOTA scaffold are needed for metal chelation, we previously introduced various physiochemical properties to extend these arms in a chemical library fashion to enhance the imaging contrast mechanism. We developed two such on-bead libraries, with 80 and 76 DOTA derivatives, where one arm was used to attach the DOTA scaffold onto resin beads and the other three arms were chemically modified. We now hypothesized that the chemical moieties used to modify these three arms can also recognize biomarkers on a cell surface. Therefore in this current study, we used such 76 derivatives of DOTA library to screen against HeLa cervical cancer cells. We found that two of the four ‘hits’ identified displayed higher binding towards HeLa cells than the unmodified parent DOTA. Furthermore, one of those ‘hits’ displayed better binding towards cervical and prostate cancer cells than lung and breast cancer cells and normal HBEC-3KT and RWPE1 cells. This indicates that this derivative can recognize a biomarker specific for certain types of cancer cells. If the compound has intrinsic activity, this can be used as a theranostic agent for real time therapy monitoring applications in the future. We believe that our DOTA derivative-based library approach can be applied to other types of cell and protein screens on various disease types in the future.     

Development of a capillary electrophoretic separation of an N-(substituted)-glycine-peptoid combinatorial mixture

Capillary electrophoresis was used for the separation of a combinatorially synthesized N-(substituted)-glycine (NSG) peptoid mixture. This mixture consisted of 24 trimeric compounds sharing a common backbone structure but differing in the side chain attached at the N-terminal residue. Standards of the individual components were unavailable so that development of the separation was based on the mixture. A variety of buffer additives were investigated to enhance the CE resolution of this diverse mixture. Ion-pairing agents, cyclodextrins and organic modifiers were all evaluated as buffer additives. The best separations were achieved using a combination of buffer additives, each serving a different purpose in the separation. Heptane sulphonic acid (HSA) was used to reduce hydrophobic intramolecular interactions. Methyl-β-cyclodextrin was used to provide host–guest interactions in order to resolve the very hydrophobic components of the NSG-peptoid mixture. The optimized run buffer consisted of 250 mM sodium phosphate buffer, pH 2.0, with 25 mM HSA and 40 mg/ml BCD and resulted in the resolution of 21 peaks for the 24 peptoids in the combinatorial mixture.     

Fluorescent analogs of peptoid-based HDAC inhibitors: Synthesis,biological activity and cellular uptake kinetics

Fluorescent tagging of bioactive molecules is a powerful tool to study cellular uptake kinetics and is considered as an attractive alternative to radioligands. In this study, we developed fluorescent histone deacetylase (HDAC) inhibitors and investigated their biological activity and cellular uptake kinetics. Our approach was to introduce a dansyl group as a fluorophore in the solvent-exposed cap region of the HDAC inhibitor pharmacophore model. Three novel fluorescent HDAC inhibitors were synthesized utilizing efficient submonomer protocols followed by the introduction of a hydroxamic acid or 2-aminoanilide moiety as zinc-binding group. All compounds were tested for their inhibition of selected HDAC isoforms, and docking studies were subsequently performed to rationalize the observed selectivity profiles. All HDAC inhibitors were further screened in proliferation assays in the esophageal adenocarcinoma cell lines OE33 and OE19. Compound 2, 6-((N-(2-(benzylamino)-2-oxoethyl)-5-(dimethylamino)naphthalene)-1-sulfonamido)-N-hydroxyhexanamide, displayed the highest HDAC inhibitory capacity as well as the strongest anti-proliferative activity. Fluorescence microscopy studies revealed that compound 2 showed the fastest uptake kinetic and reached the highest absolute fluorescence intensity of all compounds. Hence, the rapid and increased cellular uptake of 2 might contribute to its potent anti-proliferative properties.     

Simplified lipid II-binding antimicrobial peptides: Design,synthesis and antimicrobial activity of bioconjugates of nisin rings A and B with pore-forming peptides

New designs of antimicrobial peptides are urgently needed in order to combat the threat posed by the recent increase of resistance to antibiotics. In this paper, we present a new series of antimicrobial peptides, based on the key structural features of the lantibiotic nisin. We have simplified the structure of nisin by conjugating the lipid II-binding motif at the N-terminus of nisin to a series of cationic peptides and peptoids with known antibacterial action and pore-forming properties. Hybrid peptides, where a hydrophilic PEG4 linker was used, showed good antibacterial activity against Micrococcus luteus.     

Improved synthesis of 15-deoxyspergualin analogs using the Ugi multi-component reaction

Spergualin is a natural product that exhibits immunosuppressive, anti-tumor and anti-bacterial activities. Its derivatives, such as 15-deoxyspergualin (15-DSG), have been clinically approved for acute allograft rejection. However, the reported syntheses are cumbersome (>10 steps) and they suffer from low overall yields (∼0.3% to 18%). Moreover, spergualin and its derivatives are chemically unstable and rapidly hydrolyzed in aqueous buffer. Here, we have re-explored these issues and report a modified synthetic route with significantly improved overall yield (∼31% to 47%). The key transformation is a microwave-accelerated Ugi multi-component reaction that is used to generate the peptoid core in a single step. Using the products of this route, we found that modifications of the hemiaminal significantly increased chemical stability. Thus, we anticipate that this synthetic route will improve access to biologically active 15-DSG derivatives.     

Modulating amyloid-β aggregation: The effects of peptoid side chain placement and chirality

Alzheimer’s disease (AD) is characterized by the buildup of insoluble aggregated amyloid-β protein (Aβ) into plaques that accumulate between the neural cells in the brain. AD is the sixth leading cause of death in the United States and is the only cause of death among the top ten that cannot currently be treated or cured (Alzheimer’s Association, 2011; Selkoe, 1996). Researchers have focused on developing small molecules and peptides to prevent Aβ aggregation; however, while some compounds appear promising in vitro, the research has not resulted in a viable therapeutic treatment. We previously reported a peptoid-based mimic (JPT1) of the peptide KLVFF (residues 16–20 of Aβ) that modulates Aβ40 aggregation, specifically reducing the total number of fibrillar, β-sheet structured aggregates formed. In this study, we investigate two new variants of JPT1 that probe the importance of aromatic side chain placement (JPT1s) and side chain chirality (JPT1a). Both JPT1s and JPT1a modulate Aβ40 aggregation by reducing total β-sheet aggregates. However, JPT1a also has a pronounced effect on the morphology of fibrillar Aβ40 aggregates. These results suggest that Aβ40 aggregation may follow a different pathway in the presence of peptoids with different secondary structures. A better understanding of the interactions between peptoids and Aβ will allow for improved design of AD treatments.     

Identification of selective covalent inhibitors of platelet activating factor acetylhydrolase 1B2 from the screening of an oxadiazolone-capped peptoid–azapeptoid hybrid library

A potent and selective inhibitor of platelet-activating factor acetylhydrolase 1B2 (PAFAH1B2) is described. The compound was derived by improvement of a modest affinity primary hit isolated from the screening of a bead-displayed peptoid–azapeptoid hybrid library tethered to an oxadiazolone ‘warhead’. The oxadiazolone moiety of the inhibitors was found to react covalently with the active site serine residue of PAFAH1B2. This screening strategy may be useful for the identification of many selective, covalent inhibitors of serine hydrolases.