Antimicrobial peptides (AMPs) are critical components of the innate immune system and exhibit bactericidal activity against a broad spectrum of bacteria. We investigated the use of N-substituted glycine peptoid oligomers as AMP mimics with potent antimicrobial activity. The antimicrobial mechanism of action varies among different AMPs, but many of these peptides can penetrate bacterial cell membranes, causing cell lysis. We previously hypothesized that amphiphilic cyclic peptoids may act through a similar pore formation mechanism against methicillin-resistant Staphylococcus aureus (MRSA). Peptoid-induced membrane disruption is observed by scanning electron microscopy and results in a loss of membrane integrity. We demonstrate that the antimicrobial activity of the peptoids is attenuated with the addition of polyethylene glycol osmoprotectants, signifying protection from a loss of osmotic balance. This decrease in antimicrobial activity is more significant with larger osmoprotectants, indicating that peptoids form pores with initial diameters of ∼2.0–3.8 nm. The initial membrane pores formed by cyclic peptoid hexamers are comparable in diameter to those formed by larger and structurally distinct AMPs. After 24 h, the membrane pores expand to >200 nm in diameter. Together, these results indicate that cyclic peptoids exhibit a mechanism of action that includes effects manifested at the cell membrane of MRSA.

Smith, P. T., Huang, M. L., Kirshenbaum, K. (2015), Osmoprotective polymer additives attenuate the membrane pore-forming activity of antimicrobial peptoids. Biopolymers, 103: 227–236. Link

Measuring the synthesis of new proteins in the context of a much greater number of pre-existing proteins can be difficult. To overcome this obstacle, bioorthogonal noncanonical amino acid tagging (BONCAT) can be combined with stable isotope labeling by amino acid in cell culture (SILAC) for comparative proteomic analysis of de novo protein synthesis (BONLAC). In the present study, we show that alkyne resin-based isolation of l-azidohomoalanine (AHA)-labeled proteins using azide/alkyne cycloaddition minimizes contamination from pre-existing proteins. Using this approach, we isolated and identified 7414 BONCAT-labeled proteins. The nascent proteome isolated by BONCAT was very similar to the steady-state proteome, although transcription factors were highly enriched by BONCAT. About 30% of the methionine residues were replaced by AHA in our BONCAT samples, which allowed for identification of methionine-containing peptides. There was no bias against low-methionine proteins by BONCAT at the proteome level. When we applied the BONLAC approach to screen for brain-derived neurotrophic factor (BDNF)-induced protein synthesis, 53 proteins were found to be significantly changed 2 h after BDNF stimulation. Our study demonstrated that the newly synthesized proteome, even after a short period of stimulation, can be efficiently isolated by BONCAT and analyzed to a depth that is similar to that of the steady-state proteome.

Zhang, G., Bowling, H.,  Hom, N., Kirshenbaum, K., Klann, E., Chao, M. V., Neubert, T. A. (2014), In-Depth Quantitative Proteomic Analysis of de Novo Protein Synthesis Induced by Brain-Derived Neurotrophic Factor. J Proteome Res., 13(12):5707-14. Link

The androgen receptor (AR) is a major therapeutic target in prostate cancer pharmacology. Progression of prostate cancer has been linked to elevated expression of AR in malignant tissue, suggesting that AR plays a central role in prostate cancer cell biology. Potent therapeutic agents can be precisely crafted to specifically target AR, potentially averting systemic toxicities associated with nonspecific chemotherapies. In this review, we describe various strategies to generate steroid conjugates that can selectively engage AR with high potency. Analogies to recent developments in nonsteroidal conjugates targeting AR are also evaluated. Particular focus is placed on potential applications in AR pharmacology. The review culminates with a description of future prospects for targeting AR.

Levine, P. M., Garabedian, M. J., Kirshenbaum, K. (2014), Targeting the Androgen Receptor with Steroid Conjugates. J. Med. Chem. 57 (20), 8224-8237. Link

Synthetic short interfering RNA (siRNA) oligonucleotides can trigger the RNA interference pathway and lead to selective gene silencing. Despite considerable enthusiasm and investment, formidable challenges remain that may deter translating this breakthrough discovery into clinical applications. In particular, the development of efficient, nontoxic, nonimmunogenic methods for delivering siRNA in vivo has proven to be exceptionally challenging. Thorough analysis of the relationship between the structure and function of siRNA carrier systems, both in isolation and in complex with RNA, will facilitate the design of efficient nonviral siRNA delivery vehicles. In this study, we explore the relationship between the physicochemical characteristics and the biological activity of “lipitoid” compounds as potent siRNA delivery vehicles. Lipitoids are cationic peptidomimetic oligomers incorporating a peptoid and a phospholipid moiety. Lipitoids can associate with siRNA oligonucleotides and self-assemble into spherical lipitoid-based nanoparticles (LNPs), with dimensions that are dependent upon the medium and the stoichiometric ratio between the cationic monomers of the lipitoid and anionic siRNA oligonucleotides. The morphology, gene silencing efficiency, and cytotoxicity of the siRNA-loaded LNPs are similarly sensitive to the stoichiometry of the complexes. The medium in which the LNPs are formed affects the assembled cargo particles’ characteristics such as particle size, transfection efficiency, and stability. Formation of the LNPs in the biological, serum-free medium OptiMEM resulted in LNPs an order of magnitude larger than LNPs formed in water, and were twice as efficient in siRNA transfection compared to LNPs formed in water. Inhibitor studies were conducted to elucidate the efficiency of lysosomal escape and the uptake mechanism of the siRNA-loaded LNPs. Our results suggest that these lipitoid-based, siRNA-loaded spherical LNPs are internalized through a lipid raft-dependent and dynamin-mediated pathway, circumventing endosomal and lysosomal encapsulation. The lipitoid-siRNA nanospheres proved to be suitable platforms for investigating the critical parameters determining the efficiency of transfection agents, revealing the necessity for conducting characterization studies in biological media. The investigation of the LNP internalization pathway points to an alternative uptake route that bypasses the lysosome, explaining the surprisingly high efficiency of LNPs and suggesting that the uptake mechanism should be probed rather than assumed for the next generation of rationally designed transfection agents.

Konca, Y. U.; Kirshenbaum, K.; Zuckermann, R. N. (2014) Nanometer-scale siRNA carriers incorporating peptidomimetic oligomers: Physical characterization and biological activity. Int. J. Nanomedicine. 9(1): 2271—2285 Link