A protein's stability may range from nonexistent, as in the case of intrinsically disordered proteins, to very high, as indicated by a protein's resistance to degradation, even under relatively harsh conditions. The stability of this latter group is usually under kinetic control because of a high activation energy for unfolding that virtually traps the protein in a specific conformation, thereby conferring resistance to proteolytic degradation and misfolding aggregation. The usual outcome of kinetic stability is a longer protein half-life. Thus, the protective role of protein kinetic stability is often appreciated, but relatively little is known about the extent of biological roles related to this property. In this Perspective, we will discuss several known or putative biological roles of protein kinetic stability, including protection from stressors to avoid aggregation or premature degradation, achieving long-term phenotypic change, and regulating cellular processes by controlling the trigger and timing of molecular motion. The picture that emerges from this analysis is that protein kinetic stability is involved in a myriad of known and yet to be discovered biological functions via its ability to confer degradation resistance and control the timing, extent, and permanency of molecular motion.
Kinetically stable proteins (KSPs) are resistant to the denaturing detergent sodium dodecyl sulfate (SDS). Such resilience makes KSPs resistant to proteolytic degradation and may have arisen in nature as a mechanism for organismal adaptation and survival against harsh conditions. Legumes are well-known for possessing degradation-resistant proteins that often diminish their nutritional value. Here we applied diagonal two-dimensional (D2D) SDS-polyacrylamide gel electrophoresis (PAGE), a method that allows for the proteomics-level identification of KSPs, to a group of 12 legumes (mostly beans and peas) of agricultural and nutritional importance. Our proteomics results show beans that are more difficult to digest, such as soybean, lima beans, and various common beans, have high contents of KSPs. In contrast, mung bean, red lentil, and various peas that are highly digestible contain low amounts of KSPs. Identified proteins with high kinetic stability are associated with warm-season beans, which germinate at higher temperatures. In contrast, peas and red lentil, which are cool-season legumes, contain low levels of KSPs. Thus, our results show protein kinetic stability is an important factor in the digestibility of legume proteins and may relate to nutrition efficiency, timing of seed germination, and legume resistance to biotic stressors. Furthermore, we show D2D SDS-PAGE is a powerful method that could be applied for determining the abundance and identity of KSPs in engineered and wild legumes and for advancing basic research and associated applications.
Nicotinamide phosphoribosyltransferase (NAMPT), also known as Visfatin and Pre B-cell colony enhancing factor (PBEF), is a rate-limiting enzyme in the salvage pathway required for nicotinamide adenine dinucleotide (NAD) biosynthesis. It is a highly conserved 52-kDa protein, found in living species from bacteria to humans [1]. The protein serves as a cytokine and is involved in cellular regulation influencing cancer, ischemia, obesity, and type-II diabetes [2, 3]. Despite being involved in many regulatory pathways, there is a paucity of information concerning the function of NAMPT, due to the limitations of in vivo assays, and lack of expression systems for the protein. Here, we successfully expressed the NAMPT protein using the pET-SUMO expression vector in E.coli strain SHuffle containing a hexa-His tag for protein purification. Activity assays demonstrated functionality of the protein. Moreover, initial biophysical characterization of the protein using circular dichroism revealed secondary structural elements consistent with crystallographic data. Dynamic light scattering showed the protein exists as large oligomeric units potentially involved in the NAMPT signal amplification pathway. Hydropathy analysis indicated possible hydrophobic patches on the protein surface that explains the native oligomeric state. Most striking, we discovered that NAMPT can be solubilized in n-dodecyl-b-D-maltopyranoside detergent in monomeric form. These findings open opportunities for further structural and functional investigations. Presently we are optimizing conditions for NMR experiments on NAMPT protein. These methods [4] are complementary to X-ray crystallography, and provide valuable information on the structure and dynamics, offering an important tool for understanding biological functioning. [1] T.
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