Protein and Peptide Letters - Volume 24, Issue 3, 2017

Up to now, different protein vaccine modalities against human papillomavirus (HPV) have been designed to control cervical cancer. The important issue is to increase their immunogenicity using appropriate adjuvants. Among heat shock proteins (HSPs), glycoprotein 96 (Gp96) and its Nterminal region (NT-gp96) have attracted a specific interest in stimulation of antigen-specific immune responses in vivo. Furthermore, the potency of high mobility group box 1 (HMGB1) protein and its fragment (Hp91) was reported to enhance the desired immune responses against various disorders. In this study, the recombinant (r) HPV16 E7 and rNT-gp96 proteins were generated in bacterial expression system. Mice were vaccinated three times with E7 antigen mixed with Montanide, Hp91, and NT-gp96 as the adjuvant and their preventive and therapeutic efficiencies were evaluated in a murine tumor model. Mice vaccinated with E7 co-delivered by Hp91 peptide induced higher IgG2a and IFN-γ responses in comparison with E7 co-injected with Montanide and NT-gp96 protein suggesting a strong Th1 cellular immune response. The data showed that vaccination with noncovalent rE7 + rNT-gp96 complex delayed the tumor growth as compared to control groups. Mice immunized with rE7 + Montanide and rE7 + Hp91 protected 100% of mice versus 75% survival in groups vaccinated with rE7 + rNT-gp96 after TC-1 tumor challenge. The percentage of tumor free mice was decreased in group immunized with rE7 + rNT-gp96 in therapeutic experiments (~ 50%). These results demonstrated that Hp91 peptide is a safe and strong adjuvant against rNT-gp96 with the potent anti-tumor effects similar to Montanide adjuvant.

Naturally occurring antimicrobial peptides important for innate immunity are widely studied for their antimicrobial and anticancer activity. The primary target of these AMPs is believed to be the bacterial cytoplasmic membrane. However, the interaction between cytoplasmic membrane and the antimicrobial peptides remains poorly understood. Therefore to focus on the target membrane composition that is required by AMPs to interact with membranes, we have examined the interaction of the antimicrobial and anticancer active 11-residue GA-K4 (FLKWLFKWAKK) peptide with model and intact cell membranes. Effect on the structural conformational properties of GA-K4 peptide was investigated by means of far-UV CD and fluorescence spectroscopic methods. The different conformation of GA-K4 peptide in large unilamellar vesicles (LUV) bilayer and micelle environment suggest that the curvature has an influence on the secondary structure acquired by the peptide. Furthermore, the leakage experiment result confirmed that GA-K4 induced the leakage of cytoplasmic membrane in Staphylococcus аureus bacterial cells. Fluorescence data revealed the interfacial location of GA-K4 peptide in the model membranes. The blue-shift in emission wavelength by tryptophan residues in fluorescence data indicated the penetration of GA-K4 peptide in micelles and phospholipid bilayers. These results showed that the GA-K4 peptide is a membrane-active peptide and its activity depends on membrane curvature and lipid composition. Although further studies are required to confirm the mechanism of action, the data suggest mechanism of toroidal pore formation for the interaction of GA-K4 peptide with membranes. Our studies will be helpful in better understanding of the membrane requirment of peptides to express their therapeutic effects.

Predicting the unfolding rates of proteins remains complicated due to the intricacy present in the unfolding pathway of proteins and further it was observed that the experimental unfolding data were less while compared to folding kinetics. The aim of our present work is to show the variation in long-range contacts observed in various sequence separation bins belonging to all-α, all-β and mixed structural classes of 52 two-state proteins. In this work linear regression technique have been used and regression equations were developed using long-range contacts observed from various sequence separation bins. Also nine topological parameters developed from the 3-D structures of proteins are related with their experimental unfolding rates and their variation in correlation coefficient is observed before and after structural classification. The present work aims to show that long-range contacts formed between residues which are sequentially far and spatially close in the 3-D structure of proteins play a crucial role in the unfolding mechanism of proteins. Also importance of long-range contacts in various experimental and theoretical studies of protein folding along with NMR studies of the unfolded non-native states of proteins have been discussed.

Chorismate synthase (Cs) catalyzes the last step of Shikimate pathway involving a unique biochemical reaction of anti-1,4 elimination of 3-phosphate group and the C-(6proR) hydrogen from 5-enolpyruvylshikimate-3-phosphate (EPSP) leading to the formation of chorismate, which is the common precursor for aromatic amino acid, ubiquinone, and folate biosynthesis in plants and several bacterial, fungal, and parasitic pathogens. Absence of Shikimate pathway in the vertebrate host, make Cs an appealing target for drug discovery against these pathogens. Here, we report a new method for detection of chorismate through a specific liquid chromatography, coupled with negative electrospray ionization high-resolution tandem mass spectrometry (ESI-HRMS) for determination of Cs enzyme activity. For this, we used a coupled enzyme reaction consisting of purified recombinant MtbEPSPs (EPSP synthase from Mycobacterium tuberculosis) for biosynthesis of EPSP, which is the substrate for Chorismate synthase along with MtbCs (Chorismate synthase both from Mycobacterium tuberculosis) for the formation of chorismate, followed by its detection through LC/HRMS. Since, the reaction components of Cs enzyme activity assay which otherwise may interfere with the other known spectrophotometric methods of checking Cs enzyme activity have no effect on this LC/HRMS based method, this method offer advantages over other existing methods for detection of Cs activity. Further, this LC/HRMS based method could be applicable for detection of enzyme activity of both monofunctional and bifunctional Cs from different species irrespective of their specific requirements of anaerobic or aerobic reaction conditions.

Scorpion venom contains a large variety of biologically active peptides. However, most of these peptides have not been identified and characterized. Peptides with three disulfide bridges, existing in the scorpion venom, have not been studied in detail and have been poorly characterized until now. Here, we report the recombinant expression and functional characterization of two kinds of venom peptides (BmKBTx and BmNaL-3SS2) with three disulfide bridges. This study adopted an effective Escherichia coli system. The genes for BmKBTx and BmNaL-3SS2 were obtained by polymerase chain reaction and cloned to the pSYPU-1b vector. After expression and purification, the two recombinant proteins were subjected to an analgesic activity assay in mice and whole-cell patchclamp recording of hNav1.7-CHO cell lines. Functional tests showed that BmKBTx and BmNaL- 3SS2 have analgesic activity in mice and can interact with the hNav1.7 subtype of the voltage-gated sodium channel (VGSC). Scorpion venom is rich in bioactive proteins, but most of their functions are unknown to us. This study has increased our knowledge of these novel disulfide-bridged peptides (DBPs) and their biological activities.

Non-enzymatic glycation is the addition of free carbonyl group of reducing sugar to the free amino groups of proteins and leads to the formation of early glycation products and further into advanced glycation end products (AGEs). Fructose reacts rapidly with the free amino groups of proteins to form AGEs. AGEs are believed to be involved in the pathogenesis of several diseases, particularly in diabetic complications. In this study, IgG was glycated with fructose monosaccharide at 10 mM concentration for varying time interval. The reaction mixture was kept at 37ºC. The early glycation of IgG was done by nitroblue tetrazolium assay (NBT), and the generation of AGEs was done by the extent of side chain modifications (lysine and arginine), N-carboxymethyl lysine, pentosidine and carbonyl content. The decrease in free lysine and arginine residues suggests that protein ‘IgG’ has undergone modification specifically on epsilon amino groups of lysine and arginine. Additionally, their fluorescence and absorbance characteristics were also systematically studied. The results suggest that the maximum Amadori product (ketoamine content) was formed on sixth day of the incubation. The conformational structural perturbation was observed within the glycated IgG protein as studied by using various physicochemical techniques. This study reports structural perturbation, formation of various intermediates and AGEs.

Recent advances in inductively coupled plasma mass spectrometry (ICP-MS) hyphenated to different separation techniques have promoted it as a valuable tool in protein/peptide quantification. These emerging ICP-MS applications allow absolute quantification by measuring specific elemental responses. One approach quantifies elements already present in the structure of the target peptide (e.g. phosphorus and sulphur) as natural tags. Quantification of these natural tags allows the elucidation of the degree of protein phosphorylation in addition to absolute protein quantification. A separate approach is based on utilising bi-functional labelling substances (those containing ICP-MS detectable elements), that form a covalent chemical bond with the protein thus creating analogs which are detectable by ICP-MS. Based on the previously established stoichiometries of the labelling reagents, quantification can be achieved. This technique is very useful for the design of precise multiplexed quantitation schemes to address the challenges of biomarker screening and discovery. This review discusses the capabilities and different strategies to implement ICP-MS in the field of quantitative proteomics.

Globulins are a major class of seed storage proteins which were thought to be enzymatically inactive. These proteins belong to the most ancient cupin superfamily. They can be graded into 11S legumin type and 7S vicilin type based on their sedimentation coefficients. Members from both classes share structural homology are thought to have evolved from either one-domain germin predecessor by duplication or by horizontal gene transfer of two-domain gene from bacteria to eukaryotes. Globulins are known to define the nutritional quality of the seeds, however, they are also involved in sucrose binding, desiccation, defense against microbes, hormone binding and oxidative stress etc. Major drawback with globulins is their tendency to bind to IgE. Studying structural-functional behavior of such protein can help in modifying proteins for enhanced functionality in food processing industries.