Ferroptosis is a form of cell death that results from the catastrophic accumulation of lipid reactive oxygen species (ROS). Oncogenic signaling elevates lipid ROS production in many tumor types and is counteracted by metabolites that are derived from the amino acid cysteine. In this work, we show that the import of oxidized cysteine (cystine) via system xC– is a critical dependency of pancreatic ductal adenocarcinoma (PDAC), which is a leading cause of cancer mortality. PDAC cells used cysteine to synthesize glutathione and coenzyme A, which, together, down-regulated ferroptosis. Studying genetically engineered mice, we found that the deletion of a system xC– subunit, Slc7a11, induced tumor-selective ferroptosis and inhibited PDAC growth. This was replicated through the administration of cyst(e)inase, a drug that depletes cysteine and cystine, demonstrating a translatable means to induce ferroptosis in PDAC.
Chemoselective oxime formation between aminooxy end-functional polymers and levulinyl-modified proteins is an attractive method to prepare well-defined bioconjugates. We demonstrate the synthesis of Boc-protected aminooxy initiators for atom transfer radical polymerization (ATRP) of acrylamide and methacrylate monomers. Copper-mediated ATRP of N-isopropylacrylamide (NIPAAm), 2-hydroxyethyl methacrylate (HEMA), and poly(ethylene glycol) methacrylate (PEGMA) resulted in polymers with polydispersity indices (PDIs) as low as 1.11, 1.18, and 1.24, respectively. Kinetic analysis indicated that ATRP of HEMA was well-controlled. The polymer end groups of polyNIPAAm were deprotected with trifluoroacetic acid, exposing α-aminooxy moieties. Complete removal of the Boc groups was confirmed by 1H NMR, and the ability to form oxime bonds was verified by conjugation to aldehyde fluorescent nanospheres. Chemospecific reaction with N ε-levulinyl lysine-modified bovine serum albumin (BSA) to form “smart” polymer conjugates was demonstrated.
When nanoparticles interact with their environment, the nature of that interaction is governed largely by the properties of its outermost surface layer. Here, we exploit the exceptional properties of a common disaccharide, trehalose, which is well known for its unique biological stabilization effects. To this end, we have developed a synthetic procedure that readily affords a polymer of this disaccharide, poly(methacrylamidotrehalose) or “poly(trehalose)” and diblock copolycations containing this polymer with 51 repeat units chain extended with aminoethylmethacrylate (AEMA) at three degrees of polymerization (n=34, 65, and 84). Two series of experiments were conducted to study these di block copolymers in detail and to compare their properties to two control polymer [PEG-P(AEMA) and P(AEMA)]. First, we demonstrate that the poly(trehalose)-coating ensures colloidal stability of polyplexes containing siRNA in the presence of high salt concentrations and serum proteins. Poly(trehalose) retains the ability of trehalose to lower the phase transition energy associated with water freezing and can protect siRNA polyplexes during freeze-drying allowing complete nanoparticle resuspension without loss of biological function. Second, we show that siRNA polyplexes coated with poly(trehalose) have exceptional cellular internalization into glioblastoma cells that proceeds with zero-order kinetics. Moreover, the amount of siRNA delivered by poly(trehalose) block copolycations can be controlled by the siRNA concentration in cell culture media. Using confocal microscopy we show that trehalose-coated polyplexes undergo active trafficking in cytoplasm upon internalization and significant siRNA-induced target gene down-regulation was achieved with an IC50 of 19 nM. These findings coupled with a negligible cytotoxicity suggests that poly(trehalose) has the potential to serve as an important component of therapeutic nanoparticle formulations of nucleic acids and has great promise to be extended as a new coating for other nano-based technologies and macromolecules, in particular, those related to nanomedicine applications.
Polymeric excipients are crucial ingredients in modern pills, increasing the therapeutic bioavailability, safety, stability, and accessibility of lifesaving products to combat diseases in developed and developing countries worldwide. Because many early-pipeline drugs are clinically intractable due to hydrophobicity and crystallinity, new solubilizing excipients can reposition successful and even failed compounds to more effective and inexpensive oral formulations. With assistance from high-throughput controlled polymerization and screening tools, we employed a strategic, molecular evolution approach to systematically modulate designer excipients based on the cyclic imide chemical groups of an important (yet relatively insoluble) drug phenytoin. In these acrylamide- and methacrylate-containing polymers, a synthon approach was employed: one monomer served as a precipitation inhibitor for phenytoin recrystallization, while the comonomer provided hydrophilicity. Systems that maintained drug supersaturation in amorphous solid dispersions were identified with molecular-level understanding of noncovalent interactions using NOESY and DOSY NMR spectroscopy. Poly(N-isopropylacrylamide-co-N,N-dimethylacrylamide) (poly(NIPAm-co-DMA)) at 70 mol % NIPAm exhibited the highest drug solubilization, in which phenytoin associated with inhibiting NIPAm units only with lowered diffusivity in solution. In vitro dissolution tests of select spray-dried dispersions corroborated the screening trends between polymer chemical composition and solubilization performance, where the best NIPAm/DMA polymer elevated the mean area-under-the-dissolution-curve by 21 times its crystalline state at 10 wt % drug loading. When administered to rats for pharmacokinetic evaluation, the same leading poly(NIPAm-co-DMA) formulation tripled the oral bioavailability compared to a leading commercial excipient, HPMCAS, and translated to a remarkable 23-fold improvement over crystalline phenytoin.
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