High affinity copper binding by stefin B (cystatin B) and its role in the inhibition of amyloid fibrillation

Copper interaction with cystatin C: effects on protein structure and oligomerization

Human cystatin C (hCC), a small secretory protein, has gained attention beyond its classical role as a cysteine protease inhibitor owing to its potential involvement in neurodegenerative disorders. This study investigates the interaction between copper(II) ions [Cu(II)] and hCC, specifically targeting histidine residues known to participate in metal binding. Through various analytical techniques, including mutagenesis, circular dichroism, fluorescence assays, gel filtration chromatography, and electron microscopy, we evaluated the impact of Cu(II) ions on the structure and oligomerization of hCC. The results show that Cu(II) does not influence the secondary and tertiary structure of the studied hCC variants but affects their stability. To explore the Cu(II)-binding site, nuclear magnetic resonance (NMR) and X-ray studies were conducted. NMR experiments revealed notable changes in signal intensities and linewidths within the region 86His-Asp-Gln-Pro-His90, suggesting its involvement in Cu(II) coordination. Both histidine residues from this fragment were found to serve as a primary anchor of Cu(II) in solution, depending on the structural context and the presence of other Cu(II)-binding agents. The presence of Cu(II) led to significant destabilization and altered thermal stability of the wild-type and H90A variant, confirming differentiation between His residues in Cu(II) binding. In conclusion, this study provides valuable insights into the interaction between Cu(II) and hCC, elucidating the impact of copper ions on protein stability and identifying potential Cu(II)-binding residues. Understanding these interactions enhances our knowledge of the role of copper in neurodegenerative disorders and may facilitate the development of therapeutic strategies targeting copper-mediated processes in protein aggregation and associated pathologies.

Arabidopsis thaliana Phytocystatin 6 Forms Functional Oligomer and Amyloid Fibril States

Cystatins encode a high functional variability not only because of their ability to inhibit different classes of proteases but also because of their propensity to form oligomers and amyloid fibrils. Phytocystatins, essential regulators of protease activity in plants, specifically inhibit papain-like cysteine proteases (PLCPs) and legumains through two distinct cystatin domains. Mammalian cystatins can form amyloid fibrils; however, the potential for amyloid fibril formation of phytocystatins remains unknown. In this study, we demonstrate that Arabidopsis thaliana phytocystatin 6 (AtCYT6) exists as a mixture of monomeric, dimeric, and oligomeric forms in solution. Noncovalent oligomerization was facilitated by the N-terminal cystatin domain, while covalent dimerization occurred through disulfide bond formation in the interdomain linker. The noncovalent dimeric form of AtCYT6 retained activity against its target proteases, papain and legumain, albeit with reduced inhibitory potency. Additionally, we observed the formation of amyloid fibrils by AtCYT6 under acidic pH conditions and upon heating. The amyloidogenic potential could be attributed to the AtCYT6's N-terminal domain (AtCYT6-NTD). Importantly, AtCYT6 amyloid fibrils harbored inhibitory activities against both papain and legumain. These findings shed light on the oligomerization and amyloidogenic behavior of AtCYT6, expanding our understanding of phytocystatin biology and its potential functional implications for plant protease regulation.

Human stefin B: from its structure, folding, and aggregation to its function in health and disease

Mutations in the gene for human stefin B (cystatin B) cause progressive myoclonic epilepsy type 1 (EPM1), a neurodegenerative disorder. The most common change is dodecamer repeats in the promoter region of the gene, though missense and frameshift mutations also appear. Human stefin B primarily acts as a cysteine cathepsin inhibitor, and it also exhibits alternative functions. It plays a protective role against oxidative stress, likely via reducing mitochondrial damage and thus generating fewer mitochondrial reactive oxygen species (ROS). Accordingly, lack of stefin B results in increased inflammation and NLRP3 inflammasome activation, producing more ROS. The protein is cytosolic but also has an important role in the nucleus, where it prevents cleavage of the N terminal part of histone 3 by inhibiting cathepsins L and B and thus regulates transcription and cell cycle. Furthermore, it has been shown that stefin B is oligomeric in cells and that it has a specific role in the physiology of the synapse and in vesicular transport. On the basis of my research team's data on the structure, folding, and aggregation of stefin B, we have proposed that it might regulate proteostasis, possessing a chaperone-like function. In this review, I synthesize these observations and derive some conclusions on possible sources of EPM1 pathology. The interaction partners of stefin B and other gene mutations leading to EPM1-like pathology are discussed and common pathways are pinpointed.

Synergy of the Inhibitory Action of Polyphenols Plus Vitamin C on Amyloid Fibril Formation: Case Study of Human Stefin B

In order to study how polyphenols and vitamin C (vitC) together affect protein aggregation to amyloid fibrils, we performed similar in vitro studies as before using stefin B as a model and a potentially amyloid-forming protein (it aggregates upon overexpression, under stressful conditions and some progressive myoclonus epilepsy of tape 1-EPM1-missense mutations). In addition to the chosen polyphenol, this time, we added a proven antioxidant concentration of 0.5 mM vitC into the fibrillation mixture and varied concentrations of resveratrol, quercetin, and curcumin. Synergy with vitC was observed with curcumin and quercetin.

Possible Mechanisms by which Stefin B could Regulate Proteostasis and Oxidative Stress

Human stefin B is a protease inhibitor from the family of cystatins. It was reported that it forms oligomers in cells. We have shown that it has a role in cell's response to misfolded proteins. We also have shown that its oligomers bind amyloid-beta (Aβ). Here, we discuss ways, how stefin B could reduce build-up of protein aggregates by other proteins and consequently reduces ROS and, how this might be connected to autophagy. When overexpressed, stefin B forms protein aggregates itself and these protein aggregates induce autophagy. Similarly, cystatin C was shown to bind Aβ and to induce autophagy. It is also suggested how more knowledge about the role of stefin B in a cell's response to misfolded proteins could be used to modulate progressive myoclonus epilepsy of type 1 EPM1 disease.

Lysosomal cathepsins and their regulation in aging and neurodegeneration

Lysosomes and lysosomal hydrolases, including the cathepsins, have been shown to change their properties with aging brain a long time ago, although their function was not really understood. The first biochemical and clinical studies were followed by a major expansion in the last 20 years with the development of animal disease models and new approaches leading to a major advancement of understanding of the role of physiological and degenerative processes in the brain at the molecular level. This includes the understanding of the major role of autophagy and the cathepsins in a number of diseases, including its critical role in the neuronal ceroid lipofuscinosis. Similarly, cathepsins and some other lysosomal proteases were shown to have important roles in processing and/or degradation of several important neuronal proteins, thereby having either neuroprotective or harmful roles. In this review, we discuss lysosomal cathepsins and their regulation with the focus on cysteine cathepsins and their endogenous inhibitors, as well as their role in several neurodegenerative diseases.

Putative alternative functions of human stefin B (cystatin B): binding to amyloid-beta, membranes, and copper

We describe studies performed thus far on stefin B from the family of cystatins as a model protein for folding and amyloid fibril formation studies. We also briefly mention our studies on aggregation of some of the missense EPM1 mutants of stefin B in cells, which mimic additional pathological traits (gain in toxic function) in selected patients with EPM1 disease. We collected data on the reported interactors of stefin B and discuss several hypotheses of possible cytosolic alternative functions.

Solving the Measurement Problem and then Steppin' Out over the Line Riding the Rarest Italian: Crossing the Streams to Retrieve Stable Bioactivity in Majorana Bound States of Dialy zed Human Platelet Lysates

Exhaustive dialysis (ED) of lysed human platelets against dilute HCl yields stable angiogenic activity. Dialysis against a constrained external volume, with subsequent relaxation of the separation upon opening the dialysis bag, produces material able to maintain phenotypes and viability of human cells in culture better than ED material. Significant graded changes in MTT viability measurement tracked with external volume. The presence of elements smaller than the MW cutoff, capable of setting up cycling currents initiated by oriented flow of HCl across the membrane, suggests that maturation of bioactivity occurred through establishment of a novel type of geometric phase. These information-rich bound states fit recent descriptions of topological order and Majorana fermions, suggesting relevance in testing Penrose and Hameroff's theory of Orchestrated Objective Reduction, under conditions more general, and on finer scales, than those dependent on tubulin protein. The Berry curvature appears to be a good tool for building a general field theory of physiologic stress dependent on the quantum Hall effect. A new form of geometric phase, and an associated "geometric" quantum Hall effect underlying memory retrieval, dependent on the rate of path traversal and reduction from more than two initial field influences is described.

Olive flounder (Paralichthys olivaceus) cystatin B: cloning, tissue distribution, expression and inhibitory profile of piscine cystatin B

Among the cystatin superfamily, cystatin B, also known as stefin B, is an intracellular inhibitor that regulates the activities of cysteine proteases, such as papain and cathepsins. In this study, the 536 bp cystatin B cDNA (referred to hereafter as PoCystatin B) was cloned from olive flounder (Paralichthys olivaceus) using a combination of the rapid amplification of cDNA ends (RACE) approach and olive flounder cDNA library screening. To determine the tissue distribution of PoCystatin B mRNA, the expression of PoCystatin B in normal and lipopolysaccharide (LPS)-stimulated flounder tissues were compared with that of the inflammatory cytokines interleukin (IL)-1β, IL-6, and IL-8 by reverse transcription (RT)-polymerase chain reaction (PCR). The results of the RT-PCR analysis revealed ubiquitous PoCystatin B expression in normal and LPS-stimulated tissues. To characterize the enzymatic activity of PoCystatin B protein, recombinant PoCystatin B protein was overexpressed in Escherichia coli BL21(DE3) cells in the pCold™ TF DNA expression vector as a soluble fusion protein of 67-kDa. PoCystatin B inhibited papain cysteine protease, bovine cathepsin B, and fish cathepsins F and X to a greater extent, whereas fish cathepsins L, S, and K were inhibited to a lesser extent. These results indicate that the enzymatic characteristics of the olive flounder cystatin B are similar to those of mammalian cystatin B proteins, and provide a better understanding of the mechanisms of regulation of cathepsins and cystatins in marine organisms.

Mapping local structural perturbations in the native state of stefin B (cystatin B) under amyloid forming conditions

Unlike a number of amyloid-forming proteins, stefins, and in particular stefin B (cystatin B) form amyloids under conditions where the native state predominates. In order to trigger oligomerization processes, the stability of the protein needs to be compromised, favoring structural re-arrangement however, accelerating fibril formation is not a simple function of protein stability. We report here on how optimal conditions for amyloid formation lead to the destabilization of dimeric and tetrameric states of the protein in favor of the monomer. Small, highly localized structural changes can be mapped out that allow us to visualize directly areas of the protein which eventually become responsible for triggering amyloid formation. These regions of the protein overlap with the Cu (II)-binding sites which we identify here for the first time. We hypothesize that in vivo modulators of amyloid formation may act similarly to painstakingly optimized solvent conditions developed in vitro. We discuss these data in the light of current structural models of stefin B amyloid fibrils based on H-exchange data, where the detachment of the helical part and the extension of loops were observed.

The cross-road between the mechanisms of protein folding and aggregation; study of human stefin B and its H75W mutant

The role of the aromatic residue at site 75 to protein stability, the mechanism of folding and the mechanism of amyloid-fibril formation were investigated for the human stefin B variant (bearing Y at site 31) and its point mutation H75W. With an aim to reveal the conformation at the cross-road between folding and aggregation, first, the kinetics of folding and oligomer formation by human stefin B(Y31) variant were studied. It was found to fold in three kinetic phases at pH 4.8 and 10% TFE; the pH and solvent conditions that transform the protein into amyloid fibrils at longer times. The same pH leads to the formation of native-like intermediate (known from previous studies of this variant), meaning that the process of folding and amyloid-fibril formation share the same structural intermediate, which is in this case native-like and dimeric. At pH 5.8 and 7.0 stefin B folded to the native state in four kinetic phases over two intermediates. In distinction, the mutant H75W did not fold to completion, ending in intermediate states at all pH values studied: 4.8, 5.8 and 7.0. At pH 4.8 and 5.8, the mutant folded in one kinetic phase to the intermediate of the "molten globule" type, which leads to the conclusion that its mechanism of folding differs from the one of the parent stefin B at the same pH. At pH 7.0 the mutant H75W folded in three kinetic phases to a native-like intermediate, analogous to folding of stefin B at pH 4.8.

Mechanisms of amyloid fibril formation--focus on domain-swapping

Conformational diseases constitute a group of heterologous disorders in which a constituent host protein undergoes changes in conformation, leading to aggregation and deposition. To understand the molecular mechanisms of the process of amyloid fibril formation, numerous in vitro and in vivo studies, including model and pathologically relevant proteins, have been performed. Understanding the molecular details of these processes is of major importance to understand neurodegenerative diseases and could contribute to more effective therapies. Many models have been proposed to describe the mechanism by which proteins undergo ordered aggregation into amyloid fibrils. We classify these as: (a) templating and nucleation; (b) linear, colloid-like assembly of spherical oligomers; and (c) domain-swapping. In this review, we stress the role of domain-swapping and discuss the role of proline switches.

Amyloid fibril formation by human stefins: Structure, mechanism & putative functions

Many questions in the field of protein aggregation to amyloid fibrils remain open. In this review we describe predominantly in vitro studies of oligomerization and amyloid fibril formation by human stefins A and B. In human stefin B amyloidogenesis in vitro we have observed some general and many specific properties of its prefibrillar oligomers and amyloid fibrils. One characteristic feature in common to stefins and cystatins (and possibly some other amyloid proteins) is domain-swapping. In addition to solution structure of the domain-swapped dimer of stefin A, we recently have determined 3D structure of stefin B tetramer, which proved to be composed from two domain-swapped dimers, whose interaction occurs by a proline switch in the loop surrounding the conserved Pro 74. Studying the mechanism of fibril formation by stefin B, we found that the nucleation and fibril elongation reactions have energies of activation (E(a)'s) in the range of proline isomerisation, strongly indicating importance of the Pro at site 74 and/or other prolines in the sequence. Correlation between toxicity of the prefibrillar oligomers and their interaction with acidic phospholipids was demonstrated. Stefin B was shown to interact with amyloid-beta peptide of Alzheimer's disease in an oligomer specific manner, both in vitro and in the cells. It also has been shown that endogenous stefin B (with E at site 31) but especially the EPM1 mutant R68X and Y31-stefin B variant, and to a lesser extent EPM1 mutant G4R, are prone to form aggregates in cells.

Cystatin B and its EPM1 mutants are polymeric and aggregate prone in vivo

Progressive myoclonus epilepsy type 1 (EPM1) is a neurodegenerative disease correlating with mutations of the cystatin B gene. Cystatin B is described as a monomeric protein with antiprotease function. This work shows that, in vivo, cystatin B has a polymeric structure, highly resistant to SDS, urea, boiling and sensitive to reducing agents and alkaline pH. Hydrogen peroxide increases the polymeric structure of the protein. Mass spectrometry analysis shows that the only component of the polymers is cystatin B. EPM1 mutants of cystatin B transfected in cultured cells are also polymeric. The banding pattern generated by a cysteine-minus mutant is different from that of the wild-type protein as it contains only monomers, dimers and some very high MW bands while misses components of MW intermediate between 25 and 250 kDa. Overexpression of wild-type or EPM1 mutants of cystatin B in neuroblastoma cells generates cytoplasmic aggregates. The cysteine-minus mutant is less prone to the formation of inclusion bodies. We conclude that cystatin B in vivo has a polymeric structure sensitive to the redox environment and that overexpression of the protein generates aggregates. This work describes a protein with a physiological role characterized by highly stable polymers prone to aggregate formation in vivo.