Protein nanofibrils from mung bean: The effect of pH on morphology and the ability to form and stabilise foams

Protein nanofibrils (PNFs) have potential food uses due to their favorable mechanical and rheological properties. In order to use plant-based protein nanofibrils (PNFs) in new sustainable food applications, a better under-standing is needed of the impact of pH on PNFs and their functional properties. In this study, we developed an improved method for generating PNFs from mung bean protein isolate and its globular 8S fraction. We then investigated how these PNFs are affected by increased pH and how pH affects their ability to form stable foams. PNFs were generated in acidic conditions (pH 2) by heating at 85 degrees C for 2-48 h. Formation of PNFs and the effect of increased pH on their stability were evaluated using thioflavin T fluorescence, electrophoretic gel separation, circular dichroism spectroscopy, atomic force microscopy and viscosity profiling. Foams were made by intense mixing with a homogeniser and evaluated for foam capacity, foam stability and bubble size distribution, using confocal imaging. The results showed that it is possible to optimise the fibrillation conditions for mung bean by generating a more pure initial protein isolate by salt extraction. The results also showed that pH alters the structure of PNFs by degradation and aggregation around the isoelectric point of the protein isolate. At neutral pH, the PNFs were slightly shorter than at the starting pH, but no longer formed aggregates. Fibrillated mung bean protein at pH 4-8 was found to have good foaming properties compared with non-fibrillated protein at the same conditions. The new knowledge generated in this study about how pH alters the structure and foaming properties of PNFs can pave the way for use of PNFs in new innovative food applications

Protein Nanofibrils from Fava Bean and Its Major Storage Proteins: Formation and Ability to Generate and Stabilise Foams

Protein nanofibrils (PNFs) have potential for use in food applications as texture inducers. This study investigated the formation of PNFs from protein extracted from whole fava bean and from its two major storage proteins, globulin fractions 11S and 7S. PNFs were formed by heating (85 degrees C) the proteins under acidic conditions (pH 2) for 24 h. Thioflavin T fluorescence and atomic force microscopy techniques were used to investigate PNF formation. The foaming properties (capacity, stability, and half-life) were explored for non-fibrillated and fibrillated protein from fava bean, 11S, and 7S to investigate the texturing ability of PNFs at concentrations of 1 and 10 mg/mL and pH 7. The results showed that all three heat-incubated proteins (fava bean, 11S, and 7S) formed straight semi-flexible PNFs. Some differences in the capacity to form PNFs were observed between the two globulin fractions, with the smaller 7S protein being superior to 11S. The fibrillated protein from fava bean, 11S, and 7S generated more voluminous and more stable foams at 10 mg/mL than the corresponding non-fibrillated protein. However, this ability for fibrillated proteins to improve the foam properties seemed to be concentration-dependent, as at 1 mg/mL, the foams were less stable than those made from the non-fibrillated protein

Food protein-derived amyloids do not accelerate amyloid β aggregation

The deposition of proteins in the form of amyloid fibrils is closely associated with several serious diseases. The events that trigger the conversion from soluble functional proteins into insoluble amyloid are not fully understood. Many proteins that are not associated with disease can form amyloid with similar structural characteristics as the disease-associated fibrils, which highlights the potential risk of cross-seeding of disease amyloid by amyloid-like structures encountered in our surrounding. Of particular interest are common food proteins that can be transformed into amyloid under conditions similar to cooking. We here investigate cross-seeding of amyloid-β (Aβ), a peptide known to form amyloid during the development of Alzheimer’s disease, by 16 types of amyloid fibrils derived from food proteins or peptides. Kinetic studies using thioflavin T fluorescence as output show that none of the investigated protein fibrils accelerates the aggregation of Aβ. In at least two cases (hen egg lysozyme and oat protein isolate) we observe retardation of the aggregation, which appears to originate from interactions between the food protein seeds and Aβ in aggregated form. The results support the view that food-derived amyloid is not a risk factor for development of Aβ pathology and Alzheimer’s disease

Protein Nanofibrils and Their Hydrogel Formation with Metal Ions

Protein nanofibrils (PNFs) have been prepared by whey protein fibrillation at low pH and in the presence of different metal ions. The effect of the metal ions was systematically studied both in terms of PNF suspension gelation behavior and fibrillation kinetics. A high valence state and a small ionic radius (e.g., Sn4+) of the metal ion resulted in the formation of hydrogels already at a metal ion concentration of 30 mM, whereas an intermediate valence state and larger ionic radius (Co2+, Ni2+, Al3+) resulted in the hydrogel formation occurring at 60 mM. A concentration of 120 mM of Na+ was needed to form a PNF hydrogel, while lower concentrations showed liquid behaviors similar to the reference PNF solution where no metal ions had been introduced. The hydrogel mechanics were investigated at steady-state conditions after 24 h of incubation/gelation, revealing that more acidic (smaller and more charged) metal ions induced ca. 2 orders of magnitude higher storage modulus as compared to the less acidic metal ions (with smaller charge and larger radius) for the same concentration of metal ions. The viscoelastic nature of the hydrogels was attributed to the ability of the metal ions to coordinate water molecules in the vicinity of the PNFs. The presence of metal ions in the solutions during the growth of the PNFs typically resulted in curved fibrils, whereas an upper limit of the concentration existed when oxides/hydroxides were formed, and the hydrogels lost their gel properties due to phase separation. Thioflavin T (ThT) fluorescence was used to determine the rate of the fibrillation to form 50% of the total PNFs (t(1/2)), which decreased from 2.3 to ca. 0.5 h depending on the specific metal ions added

Hierarchical propagation of structural features in protein nanomaterials

Natural high-performance materials have inspired the exploration of novel materials from protein building blocks. The ability of proteins to self-organize into amyloid-like nanofibrils has opened an avenue to new materials by hierarchical assembly processes. As the mechanisms by which proteins form nanofibrils are becoming clear, the challenge now is to understand how the nanofibrils can be designed to form larger structures with defined order. We here report the spontaneous and reproducible formation of ordered microstructure in solution cast films from whey protein nanofibrils. The structural features are directly connected to the nanostructure of the protein fibrils, which is itself determined by the molecular structure of the building blocks. Hence, a hierarchical assembly process ranging over more than six orders of magnitude in size is described. The fibril length distribution is found to be the main determinant of the microstructure and the assembly process originates in restricted capillary flow induced by the solvent evaporation. We demonstrate that the structural features can be switched on and off by controlling the length distribution or the evaporation rate without losing the functional properties of the protein nanofibrils

Robust Assembly of Cross-Linked Protein Nanofibrils into Hierarchically Structured Microfibers

Natural, high-performance fibers generally have hierarchically organized nanosized building blocks. Inspired by this, whey protein nanofibrils (PNFs) are assembled into microfibers, using flow-focusing. By adding genipin as a nontoxic cross-linker to the PNF suspension before spinning, significantly improved mechanical properties of the final fiber are obtained. For curved PNFs, with a low content of cross-linker (2%) the fiber is almost 3 times stronger and 4 times stiffer than the fiber without a cross-linker. At higher content of genipin (10%), the elongation at break increases by a factor of 2 and the energy at break increases by a factor of 5. The cross-linking also enables the spinning of microfibers from long straight PNFs, which has not been achieved before. These microfibers have higher stiffness and strength but lower ductility and toughness than those made from curved PNFs. The fibers spun from the two classes of nanofibrils show clear morphological differences. The study demonstrates the production of protein-based microfibers with mechanical properties similar to natural protein-based fibers and provides insights about the role of the nanostructure in the assembly process

Hierarchical propagation of structural features in protein nanomaterials

Natural high-performance materials have inspired the exploration of novel materials from protein building blocks. The ability of proteins to self-organize into amyloid-like nanofibrils has opened an avenue to new materials by hierarchical assembly processes. As the mechanisms by which proteins form nanofibrils are becoming clear, the challenge now is to understand how the nanofibrils can be designed to form larger structures with defined order. We here report the spontaneous and reproducible formation of ordered microstructure in solution cast films from whey protein nanofibrils. The structural features are directly connected to the nanostructure of the protein fibrils, which is itself determined by the molecular structure of the building blocks. Hence, a hierarchical assembly process ranging over more than six orders of magnitude in size is described. The fibril length distribution is found to be the main determinant of the microstructure and the assembly process originates in restricted capillary flow induced by the solvent evaporation. We demonstrate that the structural features can be switched on and off by controlling the length distribution or the evaporation rate without losing the functional properties of the protein nanofibrils

Molecular principles of protein stability and protein-protein interactions

Proteins with highly specific binding properties constitute the basis for many important applications in biotechnology and medicine. Immunoglobulins have so far been the obvious choice but recent advances in protein engineering have provided several novel constructs that indeed challenge antibodies. One class of such binding proteins is based on the 58 residues three-helix bundle Z domain from staphylococcal protein A (SPA). These so-called affibodies are selected from libraries containing Z domain variants with 13 randomised positions at the immunoglobulin Fc-binding surface. This thesis aims to describe the principles for molecular recognition in two protein-protein complexes involving affibody proteins. The first complex is formed by the ZSPA-1 affibody binding to its own ancestor, the Z domain (Kd ~1 μM). The second complex consists of two affibodies: ZTaq, originally selected to bind Taq DNA polymerase, and anti-ZTaq, an anti-idiotypic binder to ZTaq with a Kd ~0.1 μM. The basis for the study is the determination of the three-dimensional structures using NMR spectroscopy supported by biophysical characterization of the uncomplexed proteins and investigation of binding thermodynamics using isothermal titration calorimetry. The free ZSPA-1 affibody is a molten globule-like protein with reduced stability compared to the original scaffold. However, upon target binding it folds into a well-defined structure with an interface topology resembling that displayed by the immunoglobulin Fc fragment when bound to the Z domain. At the same time, structural rearrangements occur in the Z domain in a similar way as in the Fc-binding process. The complex interface buries 1632 Å2 total surface area and 10 out of 13 varied residues in ZSPA-1 are directly involved in inter-molecular contacts. Further characterization of the molten globule state of ZSPA-1 revealed a native-like overall structure with increased dynamics in the randomised regions (helices 1 and 2). These features were reduced when replacing some of the mutated residues with the corresponding wild-type Z domain residues. The nature of the free ZSPA-1 affects the thermodynamics of the complex formation. The contribution from the unfolding equilibrium of the molten globule was successfully separated from the binding thermodynamics. Further decomposition of the binding entropy suggests that the conformational entropy penalty associated with stabilizing the molten globule state of ZSPA-1 upon binding seriously reduces the binding affinity. The ZTaq:anti-ZTaq complex buries in total 1672 Å2 surface area and all varied positions in anti-ZTaq are directly involved in binding. The main differences between the Z:ZSPA-1 and the ZTaq:anti-ZTaq complexes are the relative subunit orientation and certain specific interactions. However, there are also similarities, such as the hydrophobic interface character and the role of certain key residues, which are also found in the SPA:Fc interaction. Structural rearrangements upon binding are also common features of these complexes. Even though neither ZTaq nor anti-ZTaq shows the molten globule behaviour seen for ZSPA-1, there are indications of dynamic events that might affect the binding affinity. This study provides not only a molecular basis for affibody-target recognition, but also contributions to the understanding of the mechanisms regulating protein stability and protein-protein interactions in general.QC 2010102