Protein and Peptide Letters - Volume 24, Issue 1, 2017

Manduca sexta stress response peptide-2 (SRP2) is predicted to be a 25-residue peptide (FGVKDGKCPSGRVRRLGICVPDDDY), which may function as an insect cytokine to regulate immune responses. Produced as an inactive precursor, endogenous proSRP2 is probably converted to active SRP2 by limited proteolysis in response to invading pathogens, along with prophenoloxidase and pro-Spätzle activation. In addition to immunity, SRP2 may control head morphogenesis or other developmental processes in the lepidopteran insect. We have examined the profiles of SRP2 gene expression in terms of immune induction capacity, tissue specificity, and developmental changes. To gain insights into its functions, we chemically synthesized SRP2, injected the peptide solution into naïve larvae, and detected significant up-regulation of several antimicrobial peptide genes. We determined the 3D molecular structure in solution of SRP2 by two-dimensional 1H-1H NMR spectroscopy. SRP2 has an ordered structure, which is composed of two short β-strands at regions R12 − R15 and I18 − V20, one type-I’ β-turn at region R15 − I18, and a half turn at region C8 − S10 in its welldefined core stabilized by a covalent disulfide bond between C8 and C19. The secondary and tertiary structures are further stabilized by hydrogen bonds. Possible relationships between the structure and function are also discussed.

Egg white proteins play an important role in avian reproductive systems and are an ideal resource for bioreactor construction. In this study, 1D electrophoresis and MALDI-TOF-MS were performed to analyze egg white proteins in four species. In total, 18, 11, 28, and 13 proteins were identified in the egg whites of the chicken, duck, goose, and pigeon, respectively. Egg white proteins in chickens have been studied previously; therefore, we focused on the proteins in goose and duck egg whites. Based on the amino acid sequence analysis and a comparison of the unique peptides, high similarity was observed between the goose and duck egg whites. Diversity in the regulatory region of the ovalbumin gene explained the higher ovalbumin expression in the duck and goose than in the chicken. These data clarify the evolutionary processes underlying to the unique peptides contributing to the differential expression of ovalbumin in avians.

Milk has a potent reducing environment with an important quantity of sugar levels. In the current study β-casein was glycated in the presence of D-glucose and sodium cyanoborohydride as a reducing agent. Then, the reduced glucitol adduct of β-casein was used for the structural and functional analyses using different spectroscopic techniques. The results of fluorescence and far ultraviolet circular dichroism assessments suggest important structural alteration upon non-enzymatic glycation of β-casein. In addition, the chaperone activity, micellization properties and antioxidant activity of this protein were altered upon glucose modification. Also, as a result of reduced glycation, the allergenicity profile of this protein remained largely unchanged. Additional to its energetic and nutritional values, β-casein has important functional properties. The native structure of this protein is important to perform accurately its biological functions. Non-enzymatic glycation under reducing state was capable to alter both structural and functional aspects of β-casein. Due to effective reducing environment and significant quantity of reducing sugar of human milk, similar structural and functional alterations are most likely to occur upon reducing glycation of β-casein in vivo. Also, these changes might be even intensified during chronic hyperglycemia in diabetic mothers.

Diabetic nephropathy (DN) is one of the most serious microvascular complications of diabetes mellitus and the leading cause of end stage renal disease. One of the key pathways activated in DN is the polyol pathway, in which glucose is converted to sorbitol (a relatively nonmetabolizable sugar) by the enzyme aldose reductase (AR). Shunting of glucose into this pathway causes disruption to glucose metabolism and subsequently damages the tissues via increased oxidative stress, protein kinase c activation and production of advanced glycation end products (AGE) in the kidney. This review aims to provide a comprehensive overview of the AR enzyme structure, substrate specificity and topology in normal physiology; to elaborate on the deleterious effects of AR activation in DN; and to summarize the potential therapeutic benefits and major challenges associated with AR inhibition in patients with DN.

The acute phase proteins are biochemically and functionally unrelated protein predominantly synthesized in the liver. The local inflammatory cells i.e. macrophages and neutrophils secretes various cytokines like IL-1, IL-6, IL-8 (interleukins) and TNF-α into bloodstream in response to injury and tissue damage, which stimulate hepatocytes to produce protein and release them into the circulation; these proteins are called as acute phase protein (e.g. C-reactive protein (CRP), serum amyloid A (SAA), metal binding protein, lysozyme, lectin, etc.). The acute phase proteins are involved in variety of defence related activities e.g., inactivation of proteolytic enzymes, preventing the distribution of infectious agents (i.e. either by destruction of microorganism or making microbial cell suitable for cell response by modifying surface targets) and restoration of damage tissue and healthy condition. A number of well-known acute phase proteins have disease prognosis importance and change in the APPs level reflects the presence and intensity of inflammation during infection or injury. Further studies are still necessary to develop our knowledge in diagnostic importance of different acute phase proteins in fish and more efforts are needed to differentiate the APPs levels in case of viral, bacterial and parasitic diseases.