Synthesis of Aromatic Monothiols and Aromatic Dithiols to Increase the Folding Rate and Yield of Disulfide Containing Proteins

Patel, Amar S

12 November 2010

Most pharmaceutically relevant proteins and many extracellular proteins contain disulfide bonds. Formation of the correct disulfide bonds is essential for stability in almost all cases. Disulfide containing proteins can be rapidly and inexpensively overexpressed in bacteria. However, the overexpressed proteins usually form aggregates inside the bacteria, called inclusion bodies, which contains inactive and non-native protein. To obtain native protein, inclusion bodies need to be isolated and resolubilized, and then the resulting protein refolded in vitro. In vitro protein folding is aided by the addition of a redox buffer, which is composed of a small molecule disulfide and/or a small molecule thiol. The most commonly used redox buffer contains reduced and oxidized glutathione. Recently, aliphatic dithiols and aromatic monothiols have been employed as redox buffers. Aliphatic dithiols improved the yield of native protein as compared to the aliphatic thiol, glutathione. Dithiols mimic the in vivo protein folding catalyst, protein disulfide isomerase, which has two thiols per active site. Furthermore, aromatic monothiols increased the folding rate and yield of lysozyme and RNase A relative to glutathione. By combining the beneficial properties of aliphatic dithiols and aromatic monothiols, aromatic dithiols were designed and were expected to increase in vitro protein folding rates and yields. Aromatic monothiols (1-4) and their corresponding disulfides (5-8), two series of ortho- and para-substituted ethylene glycol dithiols (9-15), and a series of aromatic quaternary ammonium salt dithiols (16-17) were synthesized on a multigram scale. Monothiols and disulfides (1-8) were utilized to fold lysozyme and bovine pancreatic trypsin inhibitor. Dithiols (11-17) were tested for their ability to fold lysozyme. At pH 7.0 and pH 8.0, and high protein concentration (1 mg/mL), aromatic dithiols (16, 17) and a monothiol (3) significantly enhanced the in vitro folding rate and yield of lysozyme relative to the aliphatic thiol, glutathione. Additionally, aromatic dithiols (16, 17) significantly enhance the folding yield as compared to the corresponding aromatic monothiol (3). Thus, the folding rate and yield enhancements achieved in in vitro protein folding at high protein concentration will decrease the volume of renaturation solution required for large scale processes and consequently reduce processing time and cost.

aromatic thiols

aromatic dithiols

protein folding

disulfide containing proteins

Folding Analysis of Reduced Bovine Pancreatic Trypsin Inhibitor (BPTI) with Aromatic Thiols and Disulfides In Vitro

Zhang, Na

05 November 2018

Almost all therapeutic proteins contain disulfide bonds to stabilize their native structure. Recombinant DNA technology enables many therapeutic proteins to be produced in bacteria, but the expression of native proteins is not always efficient due to the limited ability of bacteria to form disulfide bonds in vivo. It is often necessary to employ in vitro oxidative folding process to form the native disulfide bonds to obtain the native structure of disulfide-containing proteins. Aromatic disulfides are small molecules designed to match some of the physical properties of the active site of protein disulfide isomerase (PDI), which catalyzes the folding process of disulfide-containing proteins in eukaryotes. Three aromatic thiols with varying charges, PA, SA and QAS thiol, were used to fold reduced BPTI in vitro. Bovine pancreatic trypsin inhibitor (BPTI) is positively charged (pI = 10.5) at pH 7.3, and we hypothesized that mixed disulfide intermediates formed between BPTI and negatively charged small molecule thiols were more likely to precipitate due to their minimized net charge. Protein precipitation was observed during folding with negatively charged thiols, PA and SA, but not positively charged thiol QAS. At the folding pH of 7.3, almost 90% of native BPTI was produced in 2 h with the conditions of 0.25 mM QAS disulfide and 10 mM QAS thiol. Only 25% of native BPTI was produced in 2 h with the best conditions for glutathione and glutathione disulfide. Aromatic thiols with an elongated alkyl group on the aromatic ring, butyl, hexyl and octyl thiol, were hypothesized to increased interactions with the hydrophobic core of disulfide-containing proteins during folding, allowing more facile access to buried disulfide bonds. However, the longer the hydrocarbon chain, the more likely protein precipitation was to occur. About 90% native BPTI was formed in 1 h with 0.25 mM hexyl disulfide and 10 mM hexyl thiol. A method using capillary electrophoresis (CE) to analysis the oxidative folding process of reduced BPTI with small molecule thiols and disulfides was also developed. Folding of reduced BPTI with QAS disulfide was analyzed using CE in a shorter run time. The consumption of protein samples and solvent solutions was minimized.

Protein folding

Aromatic thiols

BPTI

HPLC

CE

Biotechnology

Folding of Bovine Pancreatic Trypsin Inhibitor (BPTI) is Faster using Aromatic Thiols and their Corresponding Disulfides

Marahatta, Ram Prasad

17 November 2017

Improvement in the in vitro oxidative folding of disulfide-containing proteins, such as extracellular and pharmaceutically important proteins, is required. Traditional folding methods using small molecule aliphatic thiol and disulfide, such as glutathione (GSH) and glutathione disulfide (GSSG) are slow and low yielding. Small molecule aromatic thiols and disulfides show great potentiality because aromatic thiols have low pKa values, close to the thiol pKa of protein disulfide isomerase (PDI), higher nucleophilicity and good leaving group ability. Our studies showed that thiols with a positively charged group, quaternary ammonium salts (QAS), are better than thiols with negatively charged groups such as phosphonic acid and sulfonic acid for the folding of bovine pancreatic trypsin inhibitor (BPTI). An enhanced folding rate of BPTI was observed when the protein was folded with a redox buffer composed of a QAS thiol and its corresponding disulfide. Quaternary ammonium salt (QAS) thiols and their corresponding disulfides with longer alkyl side chains were synthesized. These QAS thiols and their corresponding disulfides are promising small molecule thiols and disulfides to fold reduced BPTI efficiently because these thiols are more hydrophobic and can enter the core of the protein. Conformational changes of disulfide-containing proteins during oxidative folding influence the folding pathway greatly. We performed the folding of BPTI using targeted molecular dynamics (TMD) simulation and investigated conformational changes along with the folding pathway. Applying a bias force to all atoms versus to only alpha carbons and the sulfur of cysteines showed different folding pathways. The formation of kinetic traps N' and N* was not observed during our simulation applying a bias force to all atoms of the starting structure. The final native conformation was obtained once the correct antiparallel β-sheets and subsequent Cys14-Cys38 distance were decreased to a bond distance level. When bias force was applied to only alpha carbons and the sulfur of cysteines, the distance between Cys14-Cys38 increased and decreased multiple times, a structure similar to the confirmation of N*, NSH were formed and native protein was ultimately obtained. We concluded that there could be multiple pathways of conformational folding which influence oxidative folding.

Protein folding

glutathione (GSH)

glutathione disulfide (GSSG)

aromatic thiols

aromatic disulfides

BPTI

HPLC

molecular dynamics (MD)

Targeted MD (TMD)

conformational folding

Analytical Chemistry

Biological and Chemical Physics

Medicinal-Pharmaceutical Chemistry

Organic Chemistry