Breakage Of Disulfide Bonds Research Articles

Raman spectroscopy for monitoring free sulfhydryl formation during monoclonal antibody manufacturing

During production, harvested cell culture fluid (HCCF) can degrade due to reductases breaking interchain disulfide bonds, forming low molecular weight (LMW) impurities that contain free sulfhydryl and high molecular weight (HMW) impurities through disulfide shuffling. Thus, detecting and quantifying the free sulfhydryl increase in HCCF is critical. Herein, Raman spectroscopy is implemented as a process analytical technology, and multivariate data analysis is applied to characterize and quantify sulfhydryl formation in HCCF with disulfide-containing indicator molecules. Raman spectra qualitatively probe the presence or absence of disulfide bond breakage in antibodies, consistent with offline non-reduced capillary electrophoresis sodium dodecyl sulfate results. Between two antibodies studied, mAb A was identified for a higher risk of antibody reduction where sulfhydryl formation was observed within 16 h, while mAb B did not show similar concerns even after 1 week. The offline measurement of redox potential is below –100 mV in HCCF for mAb A, while the stable mAb B HCCF shows redox potentials above +20 mV. A multivariate partial least squares (PLS) model for quantification is developed using an offline free sulfhydryl assay, applying Raman spectra to predict free sulfhydryl concentration with high accuracy (R2 > 0.98) and expected mean error of 0.677 mM from the offline Ellman’s Assay. This work confirms the use of Raman PAT to monitor real-time disulfide reduction, enabling improvements to process understanding and product quality.

Dynamic Chemistry of DNA-Based Nanoassemblies in Living Cells.

ConspectusIn recent years, the controlled assembly/disassembly of exogenous chemical components inside cells has become an emerging approach to regulating cell functions. However, the construction of dynamic material chemistry systems in living cells always remains highly challenging due to the complicated intracellular microenvironment. Nucleic acid is a category of biological components that can achieve efficient molecular assembly via specific base-pairing and perform biological functions in the intracellular microenvironment. Deoxyribonucleic acid (DNA) molecules exhibit the superior performance of intracellular assembly, including sequence programmability, molecule recognition ability, and nanostructure predictability, as well as the unique biological functions that traditional synthetic polymers do not carry, showing great superiority in the construction of dynamic material chemistry systems. Moreover, the technologies of DNA synthesis are relatively mature, and the conjugation of DNA with functional small molecules can be achieved through established chemical synthesis methods, facilitating the construction of DNA-based dynamic materials with more functions. In addition, a few specific DNA molecules have been proven to show responsiveness toward different stimuli, functioning as dynamic modules.In this Account, we summarize our recent work in dynamic chemistry of DNA-based nanoassemblies in living cells from the perspective of stimulus types including enzyme, H+, glutathione (GSH), adenosine triphosphate (ATP), and light. Upon the specific stimuli, DNA-based nanoassemblies undergo precise assembly in living cells, executing disassembly or aggregation, which consequently affects the functions and behaviors of living cells. In the first part, we describe the interactions between DNA-based nanoassemblies and intracellular enzymes, namely the enzymatic cleavage of intracellular enzymes on the DNA or RNA sequences. In the second part, we summarize the effects of H+ in lysosomes on DNA-based nanoassemblies, including the formation of a tetraplex i-motif structure and the decomposition of acid-degradable polymeric coating. In the third part, we discuss the mechanism of GSH responsiveness of DNA-based nanoassemblies, including the breaking of disulfide bonds and reduction-responsive nanoparticles. In the fourth part, we describe the ATP-mediated conformational transition for the specific release of functional RNA sequences. In the fifth part, we demonstrate the light-mediated spatiotemporally dynamic chemistry of DNA-based nanoassemblies. In summary, based on the achievements of our group in the study of dynamic chemistry of DNA-based nanoassemblies, the assembly, disassembly, and reassembly in living cells are well-controlled, the regulation of cellular functions are explored, and the new strategies for cancer therapeutics are demonstrated. We envision that our work on the dynamic chemistry of DNA-based nanoassembly is a new paradigm for constructing dynamic material chemistry systems inside living cells, and will facilitate the development of precision medicine.

In silico investigation on the separation of disulfide bonds by N-heterocyclic carbene.

Herein, the separation of a disulfide bond using different nucleophilic agents like tri-methyl phosphine (TMP), tris (2-carboxyethyl) phosphine (TCEP), and N-heterocyclic carbene (NHC) has been investigated. Both TMP and TCEP have demonstrated their ability to break disulfide bonds through the SN2 mechanism. However, it is worth noting that these reactions are endothermic. While searching for a suitable nucleophile, it was observed that the NHC-mediated reaction was exothermic. The natural bond orbital (NBO), principal interacting orbital (PIO) and extended transition state-natural orbitals for chemical valence (ETS-NOCV) studies help understand the electron transfer process between interacting orbitals during the chemical reactions.

An adaptive waterborne fluorocarbon coatings with Anti-Flashing Rust, Antibiofouling, and Self-Repairing properties

Waterborne fluorocarbon coatings are gaining popularity as a more environmentally friendly replacement for traditional solvent-based coatings because of its corrosion resistance and antibiofouling properties. However, the environmental unfriendliness of small molecular emulsifiers used, the occurrence of flash rusting, and the inability to self-repair after accidental damage restrict its application in the marine industry. Here, a redox-responsive copolymer (PMx) was synthesized by the amphiphilic nature of waterborne polyurethane as microreactors, which was employed as coatings (PMx/WPU) with anti-flashing rust, antibiofouling, and self-repairing functions. The copolymer was polymerized from chlorotrifluoroethylene (CTFE), vinyl acetate (VA), and a special monomer conjugated to the corrosion inhibitor 2-benzothiazolethiol (MBT) through disulfide bonds, in which MBT can be released through disulfide bond breaking in a reducing environment, effectively preventing the occurrence of flash rusting. The combination of the repelling properties of the fluorinated groups and the bactericidal action of the MBT results in PMx/WPU coatings with excellent antibiofouling properties. Additionally, the reversible hydrogen bonds in the polyurethane provide the PMx/WPU coatings with excellent self-repairing ability (93.9%). Our study presents a new approach to polymerize fluoro-substituted ethylene monomers using polyurethane as microreactors, enabling the preparation of waterborne fluorocarbon coatings with anti-flashing rust, antibiofouling, and self-repairing properties for practical applications.

Disulfide bond cleavage combined with critical pH induced unfolding and assembly of soy protein and its encapsulation effect on curcumin

The limited water solubility and bioactivity of hydrophobic phytochemicals can be improved and preserved by encapsulation technologies. In this research, a low-cost and low-energy encapsulation method was explored based on the self-assembly characteristics of soy protein (SP). The disulfide bond of SP was broken by Na2S2O5, and then the pH of SP was adjusted to the critical pH 10.5 with NaOH, which was the critical point of protein unfolding. The treated protein was added to curcumin (Cur), which was encapsulated in self-assembled protein nanoparticles during the subsequent neutralization process to obtain the soy protein-curcumin complex (SP-Cur). This process was known as the disulfide bond breaking combined with critical pH-driven technology. The cleavage of SP disulfide bonds was studied by the methods of 4, 4′-dithiopyridine (DPS) and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). When the SP:Cur mass ratio was 1:1, the encapsulation efficiency (EE%) of Cur in SP-Cur obtained by disulfide bond breaking combined with the critical pH-driven method increased to 85.36 ± 1.03%. It was notably greater than the EE% of Cur in SP-Cur prepared by the pH-driven method (61.82 ± 1.54%) and the EE% of Cur in SP-Cur prepared by disulfide bond breaking treatment (66.38 ± 1.2%). The encapsulation of Cur in SP particles exhibited significant resistance to light and temperature, leading to enhanced stability. Soy protein treated with disulfide bond cleavage combined with critical pH-driven method can serve as a potential functional carrier to further incorporate hydrophobic compounds into food systems.

Effect of magnetic fields on the structure, properties, baking performance of frozen wheat dough at different frozen stage

As an emerging physical technology, magnetic fields have been used to improve the quality of frozen and refrigerated foods. This study compared the effect of applying a static magnetic field (2 mT) at different stages of freezing and storage on the quality of frozen dough. Results suggested that the magnetic field significantly impacted frozen dough quality. It not only prevented the formation of ice crystals during the pre-freezing stage but also inhibited ice crystal growth during the following frozen storage. This effect helped to maintain the integrity of gluten proteins and their adhesion to starch granules by preventing the breakage of disulfide bonds and the depolymerization of gluten macromolecules. It was also observed that yeast inactivation and glutathione release were reduced, resulting in improved air retention and air production capacity of the dough. This, in turn, led to a more appealing volume and texture quality of the finished bread.

Fine-tuning the activation behaviors of ternary modular cabazitaxel prodrugs for efficient and on-target oral anti-cancer therapy

The disulfide bond plays a crucial role in the design of anti-tumor prodrugs due to its exceptional tumor-specific redox responsiveness. However, premature breaking of disulfide bonds is triggered by small amounts of reducing substances (e.g., ascorbic acid, glutathione, uric acid and tea polyphenols) in the systemic circulation. This may lead to toxicity, particularly in oral prodrugs that require more frequent and high-dose treatments. Fine-tuning the activation kinetics of these prodrugs is a promising prospect for more efficient on-target cancer therapies. In this study, disulfide, steric disulfide, and ester bonds were used to bridge cabazitaxel (CTX) to an intestinal lymph vessel-directed triglyceride (TG) module. Then, synthetic prodrugs were efficiently incorporated into self-nanoemulsifying drug delivery system (corn oil and Maisine CC were used as the oil phase and Cremophor EL as the surfactant). All three prodrugs had excellent gastric stability and intestinal permeability. The oral bioavailability of the disulfide bond-based prodrugs (CTX-(C)S-(C)S-TG and CTX-S-S-TG) was 11.5- and 19.1-fold higher than that of the CTX solution, respectively, demonstrating good oral delivery efficiency. However, the excessive reduction sensitivity of the disulfide bond resulted in lower plasma stability and safety of CTX-S-S-TG than that of CTX-(C)S-(C)S-TG. Moreover, introducing steric hindrance into disulfide bonds could also modulate drug release and cytotoxicity, significantly improving the anti-tumor activity even compared to that of intravenous CTX solution at half dosage while minimizing off-target adverse effects. Our findings provide insights into the design and fine-tuning of different disulfide bond-based linkers, which may help identify oral prodrugs with more potent therapeutic efficacy and safety for cancer therapy.

Redox-sensitive self-assembling polymer micelles based on oleanolic modified hydroxyethyl starch: Synthesis, characterisation, and oleanolic release

Our study aimed at developing polymer micelles that possess redox sensitivity and excellent controlled release properties. 3,3′-dithiodipropionic acid (DTDPA, Abbreviation in synthetic polymers: SS) was introduced as ROS (Reactive oxygen species)response bond and connecting arm to couple hydroxyethyl starch (HES) with oleanolic acid (OA), resulting in the synthesis of four distinct grafting ratios of HES-SS-OA. FTIR (Fourier Transform infrared spectroscopy) and 1H NMR (1H Nuclear magnetic resonance spectra) were used to verify the triumphant combination of HES-SS-OA. Polymer micelles were found to encapsulate OA in an amorphous form, as indicated by the results of XRD (X-ray diffraction) and DSC (Differential scanning calorimetry). When the OA grafting rate on HES increased from 7.72 % to 11.75 %, the particle size decreased from 297.79 nm to 201.39 nm as the polymer micelles became compact due to enhanced hydrophobicity. In addition, the zeta potential changed from −16.42 mv to −25.78 mv, the PDI (polydispersity index) decreased from 0.3649 to 0.2435, and the critical micelle concentration (CMC) decreased from 0.0955 mg/mL to 0.0123 mg/mL. Results of erythrocyte hemolysis, cytotoxicity and cellular uptake illustrated that HES-SS-OA had excellent biocompatibility and minimal cytotoxicity for AML-12 cells. Disulfide bond breakage of HES-SS-OA in the presence of H2O2 and GSH confirmed the redox sensitivity of the HES-SS-OA micelles and their excellent controlled release properties for OA. These findings suggest that HES-SS-OA can be potentially used in the future as a healthcare drug and medicine for the prevention or adjuvant treatment of inflammation.

Extracellular Kir2.1C122Y Mutant Upsets Kir2.1-PIP2 Bonds and Is Arrhythmogenic in Andersen-Tawil Syndrome.

Andersen-Tawil syndrome type 1 is a rare heritable disease caused by mutations in the gene coding the strong inwardly rectifying K+ channel Kir2.1. The extracellular Cys (cysteine)122-to-Cys154 disulfide bond in the channel structure is crucial for proper folding but has not been associated with correct channel function at the membrane. We evaluated whether a human mutation at the Cys122-to-Cys154 disulfide bridge leads to Kir2.1 channel dysfunction and arrhythmias by reorganizing the overall Kir2.1 channel structure and destabilizing its open state. We identified a Kir2.1 loss-of-function mutation (c.366 A>T; p.Cys122Tyr) in an ATS1 family. To investigate its pathophysiological implications, we generated an AAV9-mediated cardiac-specific mouse model expressing the Kir2.1C122Y variant. We employed a multidisciplinary approach, integrating patch clamping and intracardiac stimulation, molecular biology techniques, molecular dynamics, and bioluminescence resonance energy transfer experiments. Kir2.1C122Y mice recapitulated the ECG features of ATS1 independently of sex, including corrected QT prolongation, conduction defects, and increased arrhythmia susceptibility. Isolated Kir2.1C122Y cardiomyocytes showed significantly reduced inwardly rectifier K+ (IK1) and inward Na+ (INa) current densities independently of normal trafficking. Molecular dynamics predicted that the C122Y mutation provoked a conformational change over the 2000-ns simulation, characterized by a greater loss of hydrogen bonds between Kir2.1 and phosphatidylinositol 4,5-bisphosphate than wild type (WT). Therefore, the phosphatidylinositol 4,5-bisphosphate-binding pocket was destabilized, resulting in a lower conductance state compared with WT. Accordingly, on inside-out patch clamping, the C122Y mutation significantly blunted Kir2.1 sensitivity to increasing phosphatidylinositol 4,5-bisphosphate concentrations. In addition, the Kir2.1C122Y mutation resulted in channelosome degradation, demonstrating temporal instability of both Kir2.1 and NaV1.5 proteins. The extracellular Cys122-to-Cys154 disulfide bond in the tridimensional Kir2.1 channel structure is essential for the channel function. We demonstrate that breaking disulfide bonds in the extracellular domain disrupts phosphatidylinositol 4,5-bisphosphate-dependent regulation, leading to channel dysfunction and defects in Kir2.1 energetic stability. The mutation also alters functional expression of the NaV1.5 channel and ultimately leads to conduction disturbances and life-threatening arrhythmia characteristic of Andersen-Tawil syndrome type 1.

Effect of benzoic acid-based and cinnamic acid-based polyphenols on foaming properties of ovalbumin at acidic, neutral and alkaline pH conditions

To broaden the application of ovalbumin (OVA) in food formulations, it is meaningful to improve its foaming characteristics. This study aimed to investigate the effect of benzoic acid-based (3,4-dihydroxybenzoic acid, DA) and cinnamic acid-based polyphenols (trans-2-hydroxycinnamic acid, T2A) on the foaming properties of OVA at acidic (pH 3.0), neutral (pH 7.4) and alkaline (pH 9.0) pH conditions. Both the addition of polyphenols and acid treatment enhanced the foaming properties of OVA. Surface hydrophobicity, circular dichroism, free sulfhydryl groups, and Fourier transform infrared spectroscopy results indicated that after acidic workup, the presence of stronger hydrophobic interactions in OVA-polyphenol aggregates induced more disordered protein conformation and conversion or breakage of disulfide bonds. Particle size and zeta potential indicated that acidic treatment neutralized protein surface charges, further inducing self-aggregation and swelling of OVA, ultimately enhancing foaming properties. Comparatively, T2A exhibited better foam-inducing capacity due to its stronger interaction with OVA, leading to the unfolding of the OVA structure and the exposure of more hydrophobic groups. The intrinsic and 3-D fluorescence spectra experiments also confirmed that OVA-T2A aggregates at pH 3.0 had greater altered non-covalent interaction forces and protein secondary and tertiary structures compared to other complexes. This study provides a theoretical basis for designing protein formulations with excellent foaming properties.

Dexamethasone Pretreatment Potentiates a Folic Acid-Functionalized Delivery System for Enhanced Lung Cancer Therapy.

Folic acid (FA) has been widely engineered to promote the targeted delivery of FA-modified nanoparticles (NPs) by recognizing the folate receptor α (FRα). However, the efficacy of FA-targeted therapy significantly varied with the abundance of FRα and natural immunoglobulin levels in different tumors. Therefore, a sequential therapy of dexamethasone (Dex)-induced FRα amplification and immunosuppression combined with FA-functionalized doxorubicin (DOX) micelles to synergistically suppress tumor proliferation was proposed in this study. In brief, a pH/reduction-responsive FA-functionalized micelle (FCSD) was obtained by grafting FA, derivatization-modified cholesterol, and 2,3-dimethylmaleic anhydride onto a chitosan oligosaccharide. The obtained FCSD/DOX NPs can effectively deliver DOX in tumors, and their targeting efficiency can be further improved with Dex pretreatment to decrease the immunoglobulin M (IgM) content in serum and amplify FRα levels on the surface of M109 cells. After internalization, charge reversal and disulfide bond breakage of FCSD vectors under the stimulation of tumor extracellular pH (pHe) and intracellular glutathione (GSH) would contribute to the disintegration of vectors and the rapid release of DOX. The sequential therapy that combined Dex pretreatment and targeted chemotherapy by FCSD/DOX NPs demonstrated superior tumor suppression compared with monotherapy, which is expected to provide a potential strategy for FRα-positive lung cancer patients.

CRISPR screen for protein inclusion formation uncovers a role for SRRD in the regulation of intermediate filament dynamics and aggresome assembly.

The presence of large protein inclusions is a hallmark of neurodegeneration, and yet the precise molecular factors that contribute to their formation remain poorly understood. Screens using aggregation-prone proteins have commonly relied on downstream toxicity as a readout rather than the direct formation of aggregates. Here, we combined a genome-wide CRISPR knockout screen with Pulse Shape Analysis, a FACS-based method for inclusion detection, to identify direct modifiers of TDP-43 aggregation in human cells. Our screen revealed both canonical and novel proteostasis genes, and unearthed SRRD, a poorly characterized protein, as a top regulator of protein inclusion formation. APEX biotin labeling reveals that SRRD resides in proximity to proteins that are involved in the formation and breakage of disulfide bonds and to intermediate filaments, suggesting a role in regulation of the spatial dynamics of the intermediate filament network. Indeed, loss of SRRD results in aberrant intermediate filament fibrils and the impaired formation of aggresomes, including blunted vimentin cage structure, during proteotoxic stress. Interestingly, SRRD also localizes to aggresomes and unfolded proteins, and rescues proteotoxicity in yeast whereby its N-terminal low complexity domain is sufficient to induce this affect. Altogether this suggests an unanticipated and broad role for SRRD in cytoskeletal organization and cellular proteostasis.

Dual-Responsive hollow mesoporous organosilicon nanocarriers for photodynamic therapy

Hypothesis: The nano-delivery platform, -SS-HMONs@MB@MnO2 nanoparticles (SMM NPs) loaded with methylene blue (MB) as photosensitizer have excellent photodynamic therapy (PDT) effect. The disulfide bond and MnO2 give the shell redox-responsive properties. SMM NPs consume glutathione (GSH) in tumor cells, reducing the scavenging of reactive oxygen species (ROS) by GSH and enhancing the PDT effect of MB.Experiments: The GSH dual-responsive nano-delivery platform, was designed and constructed by using disulfide-doped hollow mesoporous organosilicon nanoparticles (-SS-HMONs) as intermediate responsive layer, loaded with MB as photosensitizer and coated with MnO2 as shells. The MB photosensitizer release and GSH response were characterized. The PDT effect of nanoparticles was evaluated.Findings: The SMM NPs were uniform in size and well dispersed. The nanoparticles could react with GSH, leading to the decomposition of MnO2 shells and the breakage of disulfide bonds in -SS-HMONs, resulted in the release of MB photosensitizer. The cell experiment showed that SMM NPs had good ROS generating ability and PDT effect after being sucked by tumor cells, which could effectively kill tumor cells. However, in vivo experiments demonstrated that SMM NPs showed slight inhibition on tumor growth. The actual effect in animals was different from the effect in cells.

Mineralized aggregates based on native protein phase transition for non-destructive diagnosis of seborrheic skin by surface-enhanced Raman spectroscopy.

The non-homeostasis of sebum secretion by the sebaceous glands in a complicated microenvironment dramatically impacts the skin health of many people in the world. However, the complexity and hydrophobicity of sebum mean a lack of diagnostic tools, which makes it challenging to determine the reason behind cortical imbalances. Herein, a biomimetic mineralized aggregates (PTL@Au and PTB@Au) strategy has been proposed, which could obtain molecular information about sebum by surface-enhanced Raman spectroscopy (SERS). The breaking of disulfide bonds leads to changes in hydrogen bonding, which transform the natural protein into amyloid-like phase transition protein with β-sheets. It provides sites for the nucleation and crystallization of gold nanocrystals to build mineralized aggregates. The mineralized aggregates show robust adhesion stability at the interfaces of different materials through hydrogen bonding and electrostatic interactions. The stabilization, hydrophobicity (contact angle: 134°), and optical transmission (75%) of the structure could result in superior SERS performance for sebum analysis. It should be noted that this enables the sebum detection of clinical samples while ensuring safety. Such generalized bionic mineralization construction and diagnosis methods also serve as an advanced paradigm for a range of biomedical applications.

Effects of apple fiber on the physicochemical properties and baking quality of frozen dough during frozen storage

The effects of apple fiber on gluten structure and corresponding frozen dough quality during frozen storage were studied. The addition of 0.50% and 0.75% apple fiber effectively preserved gluten structure by inhibiting the breakage of disulfide bonds and promoting the formation of hydrogen bonds. Notably, the presence of 0.75% apple fiber increased the β-turn of gluten from 29.60% to 33.84%. Fiber-enriched frozen dough exhibited a smoother and more compact microstructure, but excessive fiber addition (more than 1.00%) had adverse effects. The freezable water content of frozen dough decreased as fiber addition increased. Correspondingly, the addition of 1.50% apple fiber resulted in a 56.08% increase in storage modulus, indicating improved viscoelasticity of the dough. Consequently, the addition of 0.50% and 0.75% apple fiber alleviated the quality deterioration of frozen dough bread in terms of larger specific volume, softer and more uniform crumb.

Synthesis and functionalization of scalable and versatile 2D protein films via amyloid-like aggregation.

Two-dimensional (2D) protein films can be used to modify the properties of surfaces, and find applications predominantly in the fields of biomaterials, lithography, optics and electronics. However, it is difficult to produce scalable homogeneous and robust protein films with an easy, low-cost, green and efficient method. Further challenges include encapsulating and releasing functional building blocks in the film without inactivating them, and maintaining or improving the bioactivities of proteins used for the formation of the films. Here we detail the process to prepare large 2D protein films with user-defined features and structures via the amyloid-like aggregation of commonly synthesized proteins. These films can be synthesized at meter scales, have high interface adhesion, high functional expansibility and tunable functional properties, obtained by controlling the position of the disulfide bond breakage. For example, we can retain or even enhance the natural antibacterial, biomineralization and antifouling activity of proteins involved in film formation, and the properties can also be expanded through the physical blending or chemical grafting of additional functional blocks on the surface of the film. A 2D protein film can be prepared in ~3 h using four alternative coating techniques: immersion, transfer, hydrogel stamping and spraying. The characterization process of the film requires ~5 d. The procedure can be carried out by users with basic expertise in materials science.

Synergistic Antimicrobial Hybrid Bio-Surface Formed by Self-Assembled BSA Nanoarchitectures with Chitosan Oligosaccharide.

Innovation in green, convenient, and sustainable antimicrobial packaging materials for food is an inevitable trend to address global food waste challenges caused by microbial contamination. In this study, we developed a biogenic, hydrophobic, and antimicrobial protein network coating for food packaging. Experimental results show that disulfide bond breakage can induce the self-assembly of bovine albumin (BSA) into protein networks driven by hydrophobic interactions, and chitosan oligosaccharide (COS) with antimicrobial activity can be stably bound in this network by electrostatic interactions. The inherent antimicrobial activity of COS and the numerous hydrophobic regions on the surface of the BSA-network give the BSA@COS-network significant in vitro antimicrobial ability. More importantly, the BSA@COS-network coating can prolong the onset of spoilage of strawberries in various packaging materials by nearly 3-fold in storage. This study shows how surface functionalization via protein self-assembly is integrated with the biological functioning of natural antibacterial activity for advanced food packaging applications.

Insights into soy Protein-Based drug delivery vehicles via molecular dynamic simulation

Protein-based drug carriers have emerged as promising candidates for efficient drug delivery among various colloidal carrier systems due to their low cytotoxicity, abundance, renewability, diverse functional groups and interactions, and high drug loading capacity. In this study, the molecular dynamics (MD) simulations are conducted to investigate the surface-governed mechanisms of soy protein as a drug delivery vehicle using allyl isothiocyanate (AITC) as the model drug. The interaction strengths between protein and AITCs are characterized, and the loading capacities of the protein molecules are calculated and compared with experimental results. Our findings reveal that both nonpolar and polar functional groups on the protein have the ability to adsorb AITCs, but the polar residues primarily facilitate stable attachment of the drug molecules through the electrostatic (dipole–dipole) interactions. Furthermore, tunable loading capability of soy protein drug carrier is observed by modifying its surface through two types of denaturation treatments: heat denaturation and breaking of disulfide bonds. Both denaturation approaches are found to increase the exposure of polar active sites, thereby enhancing the loading efficiency of the protein carriers. These findings contribute to the advancement and application of biodegradable protein-based drug carriers.

Effect of a keratin coupling agent on the mechanical properties of a bovine hair-thermoplastic starch composite

A coupling agent (CA) was obtained through chemical modification of bovine hair. For that purpose, hair waste was treated using two concentrations of potassium hydroxide (KOH), 0.15 and 0.25 N. Treated and untreated hair waste was characterized. Fourier-transform infrared (FTIR) spectra showed that alkali treatment caused the formation of thiols (773 cm−1) and sulfonate groups (1063 cm−1 and 1041 cm−1) as a consequence of disulfide bond breakage. Furthermore, the keratin structure was disorganized (1697 cm−1), and functional groups –NH2 (1574 cm−1) were exposed. The vibrational analysis confirmed S–S bond cleavage to form S–H groups. Thermogravimetric analysis indicated an important disorganization of the keratin molecule. Additionally, differential scanning calorimetry (DSC) analysis corroborated the protein denaturation due to decomposition of the α-helix. Scanning electron microscopy (SEM) showed a clear effect on hair surface integrity, which promotes its interaction with the polymer matrix. Water absorption assays showed that alkaline treatment produces higher absorption due to a greater presence of polar functional groups. With the aim of assessing the CA's ability to act as a compatibilizer in a composite material, it was mixed with thermoplastic cornstarch (TPS) as a polymeric matrix and untreated hair fiber (UHF) as a reinforcing agent. The composites were processed by extrusion and injection molding. Young's modulus, tensile strength, and elongation at break were evaluated, showing higher values for the first two when the percentage of CA was increased.

Cleavage of disulfide bonds used to reveal manifestation of tertiary structure in the Raman spectra of proteins

Raman spectroscopy is used in the study of the tertiary structure of proteins. The effect of cleavage of disulfide bonds (using DTT and TCEP agents) on the molecular structure and, hence, vibrational spectra is studied. Spectra of two globular proteins (chymotrypsin and bovine serum albumin) are compared with the spectra of the two proteins the structure of which is modified due to cleavage of disulfide bonds. Changes in spectral intervals of 500–550 and 2500–2620 cm-1 indicate disulfide bond breaking. Based on the comparative analysis of the spectral changes in the fingerprint region (in particular, amide I, amide III, tyrosine doublet, bands of disulfide bonds) and low-frequency region, we assume that spectral intervals of 140–470, 500–550, and 800–1000 cm-1 can be used in the study of changes of the tertiary structure.