Comprehensive analysis of insulin products complex disulfide bonds structure by high resolution mass spectrum / 药学学报

The correct pairing of disulfide bonds maintains the correct folding mode and high-level structure formation of peptides and protein drugs, which is crucial for the quality control of products. In order to ensure that the disulfide bonds are correctly paired, disulfide bond analysis is an essential part of peptides and protein drug characterization. Mass spectrometry can be used to analyze disulfide bonds. However, insulin and its analogues have two pairs of disulfide bonds without restriction enzyme cutting site. Conventional collision-induced dissociation (CID) and high-energy induced cleavage (HCD) cannot accurately locate the complex disulfide bond. In our study, three methods were used to localize the complex disulfide, including enzyme digestion combined with key peptide fragment in source decay (ISD) fragmentation method, enzyme digestion combined with partial reduction alkylation method, intact protein source ISD and electron transfer dissociation (ETD) cleavage method, The applicability of insulin aspart, insulin lispro and insulin glargine were also investigated. This study provides a new way for the quality control of disulfide bonding mode of insulin and its analogues, and also provides a reference for the disulfide bond localization of peptides or proteins containing this complex disulfide bond.

Design and synthesis of peptide-drug conjugates and fluorescent probe based on α-conotoxin ArIBV11L,V16D / 药学学报

italic>α-Conotoxin ArIB[V11L,V16D] is currently the most optimal selective inhibitor of α7 nicotinic acetylcholine receptor (nAChR) known. In order to explore chemical modification methods and enrich its application in targeting nAChR, this study utilized the linker to covalently connect camptothecin and 7-amino-4-methylcoumarin to the [2,4] disulfide bond of ArIB[V11L,V16D]. Therefore, two peptide-drug conjugates (PDCs), ArIB[V11L,V16D]-5 and ArIB[V11L,V16D]-6, and one fluorescent-labeled peptide, ArIB[V11L,V16D]-7 were constructed. Cytotoxicity evaluation showed that the IC50 values against non-small cell lung cancer cell line A549 of the two PDCs were respectively 1.3 and 4.1 times of camptothecin, indicating slight reduction in activity at the cellular level which was related to the linker structure. Fluorescence spectrum scanning revealed that the excitation and emission wavelength of the fluorescent-labeled peptide were 340 nm and 403 nm respectively, and the fluorescence features of 7-amino-4-methylcoumarin as a marker were retained without fluorescence quenching. This modification strategy laid a solid foundation for the further application of α-conotoxin ArIB[V11L,V16D] in PDCs and fluorescent probes.

Research progress on metabolism and efficacy of small molecular prodrug nanosystems responsive to tumor redox microenvironment / 药学学报

Compared with normal tissues and cells, the tumor microenvironment has significant differences. For example, glutathione-related metabolic enzymes and reactive oxygen species are highly expressed in different subcellular structures, resulting in an unbalanced redox state. Aiming at the specific redox state in tumor tissues and cells, a series of small molecule prodrug self-assembled nanoparticles can be designed and connected by intelligent response linkers including disulfide bonds, sulfide bonds, and selenium bonds, thioketal bonds, etc. The in vitro and in vivo efficiency and metabolic mode of these nanoparticles are related to the type of linker. This review will summarize the tumor redox microenvironment, the design of intelligent responsive small molecule prodrug nanoparticles, and the metabolic pathways of small molecule prodrug nanoparticles with different connecting linkers and their relationship with drug efficacy.

Elimination of a disulfide bond in the light chain of coagulation factor VIII improves secretion of a BDD-FVIII variant with an engineered inter-chain disulfide / 药学学报

The coagulation VIII factor (FVIII) contains eight pairs of disulfide bonds, which are involved in maintaining its structure and function. It has been demonstrated that the disulfide bond between Cys1899/Cys1903 of the A3 domain in the light chain impedes secretion. In our previous work, an engineered inter-chain disulfide in the B domain-deleted FVIII (BDD-FVIII) promoted heterodimer assembly and secretion of separately expressed heavy and light chains. In this study, we constructed two BDD-FVIII variants, one of which contains an engineered inter-chain disulfide bond (F8C) between Met662 > Cys and Asp1828 > Cys mutations and another contains an endogenous A3 domain with a disrupted disulfide bond from F8C (F8CG) by replacement of Cys1899 and Cys1903 with Gly in F8C. We explored their function and secretion. By transducing F8C and F8CG into HEK293 and COS-7 cells, the formation of disulfide bonds and the secretion and coagulation activity of the two variants in the culture media and their binding affinity for von Willebrand factor (vWF) could be observed. The results show that variants F8C and F8CG are mainly the disulfide bonded heavy and light chain dimer, while the wild type BDD-FVIII (F8) is dominated by the easily dissociated heavy and light chain dimer. The secretion and activity of F8C was significantly higher than that of F8, while the secretion and activity of F8CG was significantly higher than that of F8C. The vWF binding of the two variants is similar to F8. This indicates that the BDD-FVIII variant F8CG may be attractive molecule for protein replacement and as a transgene in gene-therapy strategies. These findings are encouraging for future studies targeting disulfide bond elimination for further enhancement of FVIII secretion.