Design and evaluation of nanoscale materials with programmed responsivity towards epigenetic enzymes.
Priyanka RayAbbas SedighMatthew ConfeldLina AlhalhoolyKweeni IduokuGerardo M Casanola-MartinPham-The HaiBakhtiyor RasulevYongki ChoiZhongyu YangSanku MallikMohiuddin QuadirPublished in: Journal of materials chemistry. B (2024)
Self-assembled materials capable of modulating their assembly properties in response to specific enzymes play a pivotal role in advancing 'intelligent' encapsulation platforms for biotechnological applications. Here, we introduce a previously unreported class of synthetic nanomaterials that programmatically interact with histone deacetylase (HDAC) as the triggering stimulus for disassembly. These nanomaterials consist of co-polypeptides comprising poly(acetyl L-lysine) and poly(ethylene glycol) blocks. Under neutral pH conditions, they self-assemble into particles. The hydrodynamic diameters of particles were typically withing the range of 108-190 nm, depending on degree of acetylation of the hydrophobic block. However, their stability is compromised upon exposure to HDACs, depending on enzyme concentration and exposure time. Our investigation, utilizing HDAC8 as the model enzyme, revealed that the primary mechanism behind disassembly involves a decrease in amphiphilicity within the block copolymer due to the deacetylation of lysine residues within the particles' hydrophobic domains. To elucidate the response mechanism, we encapsulated a fluorescent dye within these nanoparticles. Upon incubation with HDAC, the nanoparticle structure collapsed, leading to controlled release of the dye over time. Notably, this release was not triggered by denatured HDAC8, other proteolytic enzymes like trypsin, or the co-presence of HDAC8 and its inhibitor. We also demonstrated the biocompatibility and cellular effects of these materials in the context of drug delivery in different types of anticancer cell lines, such as MIA PaCa-2, PANC-1, cancer like stem cells (CSCs), and non-cancerous HPNE cells. We observed that the release of a model drug (such as a STAT3 pathway inhibitor, Napabucasin) can be loaded into these nanoparticles, with >90% of the dosage can be released over 3 h under the influence of HDAC8 enzyme in a controlled fashion. Further, we conducted a comprehensive computational study to unveil the possible interaction mechanism between enzymes and particles. By drawing parallels to the mechanism of naturally occurring histone proteins, this research represents a pioneering step toward developing functional materials capable of harnessing the activity of epigenetic enzymes such as HDACs.
Keyphrases
- histone deacetylase
- drug delivery
- stem cells
- dna methylation
- gene expression
- induced apoptosis
- cancer therapy
- machine learning
- quantum dots
- squamous cell carcinoma
- drug release
- cell proliferation
- papillary thyroid
- oxidative stress
- cell death
- squamous cell
- walled carbon nanotubes
- bone marrow
- amino acid
- mass spectrometry
- young adults
- high resolution
- emergency department
- atomic force microscopy
- cancer stem cells