Hanna Nieznanska

Phosphorus dendrimers affect Alzheimer's (Aβ1-28) peptide and MAP-Tau protein aggregation.

Alzheimers disease (AD) is characterized by pathological aggregation of β-amyloid peptides and MAP-Tau protein. β-Amyloid (Aβ) is a peptide responsible for extracellular Alzheimers plaque formation. Intracellular MAP-Tau aggregates appear as a result of hyperphosphorylation of this cytoskeletal protein. Small, oligomeric forms of Aβ are intermediate products that appear before the amyloid plaques are formed. These forms are believed to be most neurotoxic. Dendrimers are highly branched polymers, which may find an application in regulation of amyloid fibril formation. Several biophysical and biochemical methods, like circular dichroism (CD), fluorescence intensity of thioflavin T and thioflavin S, transmission electron microscopy, spectrofluorimetry (measuring quenching of intrinsic peptide fluorescence) and MTT-cytotoxicity assay, were applied to characterize interactions of cationic phosphorus-containing dendrimers of generation 3 and generation 4 (CPDG3, CPDG4) with the fragment of amyloid peptide (Aβ(1-28)) and MAP-Tau protein. We have demonstrated that CPDs are able to affect β-amyloid and MAP-Tau aggregation processes. A neuro-2a cell line (N2a) was used to test cytotoxicity of formed fibrils and intermediate products during the Aβ(1-28) aggregation. It has been shown that CPDs might have a beneficial effect by reducing the system toxicity. Presented results suggest that phosphorus dendrimers may be used in the future as agents regulating the fibrilization processes in Alzheimers disease.

Prion protein region 23–32 interacts with tubulin and inhibits microtubule assembly

In previous studies we have demonstrated that prion protein (PrP) binds directly to tubulin and this interaction leads to the inhibition of microtubule formation by inducement of tubulin oligomerization. This report is aimed at mapping the regions of PrP and tubulin involved in the interaction and identification of PrP domains responsible for tubulin oligomerization. Preliminary studies focused our attention to the N‐terminal flexible part of PrP encompassing residues 23–110. Using a panel of deletion mutants of PrP, we identified two microtubule‐binding motifs at both ends of this part of the molecule. We found that residues 23–32 constitute a major site of interaction, whereas residues 101–110 represent a weak binding site. The crucial role of the 23–32 sequence in the interaction with tubulin was confirmed employing chymotryptic fragments of PrP. Surprisingly, the octarepeat region linking the above motifs plays only a supporting role in the interaction. The binding of Cu2+ to PrP did not affect the interaction. We also demonstrate that PrP deletion mutants lacking residues 23–32 exhibit very low efficiency in the inducement of tubulin oligomerization. Moreover, a synthetic peptide corresponding to this sequence, but not that identical with fragment 101–110, mimics the effects of the full‐length protein on tubulin oligomerization and microtubule assembly. At the cellular level, peptide composed of the PrP motive 23–30 and signal sequence (1–22) disrupted the microtubular cytoskeleton. Using tryptic and chymotryptic fragments of α‐ and β‐tubulin, we mapped the docking sites for PrP within the C‐terminal domains constituting the outer surface of microtubule. Proteins 2009.

Tau inhibits tubulin oligomerization induced by prion protein

In previous studies we have demonstrated that prion protein (PrP) interacts with tubulin and disrupts microtubular cytoskeleton by inducing tubulin oligomerization. These observations may explain the molecular mechanism of toxicity of cytoplasmic PrP in transmissible spongiform encephalopathies (TSEs). Here, we check whether microtubule associated proteins (MAPs) that regulate microtubule stability, influence the PrP-induced oligomerization of tubulin. We show that tubulin preparations depleted of MAPs are more prone to oligomerization by PrP than those containing traces of MAPs. Tau protein, a major neuronal member of the MAPs family, reduces the effect of PrP. Importantly, phosphorylation of Tau abolishes its ability to affect the PrP-induced oligomerization of tubulin. We propose that the binding of Tau stabilizes tubulin in a conformation less susceptible to oligomerization by PrP. Since elevated phosphorylation of Tau leading to a loss of its function is observed in Alzheimer disease and related tauopathies, our results point at a possible molecular link between these neurodegenerative disorders and TSEs.

Ca2+ binding to myosin regulatory light chain affects the conformation of the N-terminus of essential light chain and its binding to actin

We prepared a new type of skeletal myosin subfragment 1 (S1-MLC1F) containing both, the essential and the regulatory light chains, intact, by exchanging the essential light chains of papain S1 with bacterially expressed longer isoform (MLC1F) of this light chain. We then compared the enzymatic and structural properties of chymotryptic S1, papain S1, and S1-MLC1F in the presence and in the absence of Ca(2+) ions bound to the regulatory light chain. In the presence of Ca(2+), subfragment 1 containing both intact light chains exhibited lower V(max) and lower K(m) for actin activation of S1 ATPase. When S1-MLC1F was cross-linked to actin via the N-terminus of the essential light chain, the yield was much higher when Ca(2+) ions saturated the regulatory light chain. Limited proteolysis of the essential light chain in S1-MLC1F was significantly inhibited in the presence of calcium as compared to chymotryptic S1. We conclude that the effect of binding of Ca(2+) to the regulatory light chain is transmitted to the N-terminal extension of the longer isoform of the essential light chain. The resulting structure of the N-terminus is less susceptible to proteolytic digestion, binds tighter to actin, and has an inhibitory effect on actin-activated myosin ATPase. This new conformation of the N-terminus may be responsible for calcium induced myosin-linked modulation of striated muscle contraction.

Interaction between Prion Protein and Aβ Amyloid Fibrils Revisited

Recent studies indicate that the pathogenesis of Alzheimer disease may be related to the interaction between prion protein (PrP) and certain oligomeric species of Aβ peptide. However, the mechanism of this interaction remains unclear and controversial. Here we provide direct experimental evidence that, in addition to previously demonstrated binding to Aβ oligomers, PrP also interacts with mature Aβ fibrils. However, contrary to the recent claim that PrP causes fragmentation of Aβ fibrils into oligomeric species, no evidence for such a disassembly could be detected in the present study. In contrast, our data indicate that the addition of PrP to preformed Aβ fibrils results in a lateral association of individual fibrils into larger bundles. These findings have potentially important implications for understanding the mechanism by which PrP might impact Aβ toxicity as well as for the emerging efforts to use PrP-derived compounds as inhibitors of Aβ-induced neurodegeneration.

THE POSSIBLE ROLE OF MYOSIN A1 LIGHT CHAIN IN THE WEAKENING OF ACTIN-MYOSIN INTERACTION

The effects resulting from the removal of the N-terminus of myosin A1 by limited papain cleavage are investigated. The myosin and heavy meromyosin K+-ATPase and Ca2+-ATPase activities, and actin-activated ATPase activity of heavy meromyosin (HMM) and subfragment-1, are studied. Myosin and HMM preparations devoid of the A1 N-terminus exhibits lower Ca2+-ATPase activities at low ionic strength whereas no differences in K+- or Ca2+-ATPase activities are observed at high ionic strength. Direct binding of actin to monomeric myosin under K+-activated ATPase conditions is much more effective for myosin containing a shortened A1 light chain. The kinetic constants K(app) for actin and V(max) are calculated from actin-activation curves for HMM and subfragment-1. The kinetic constants for HMM are determined under conditions assuring saturation of regulatory light chains (RLC) either with Mg2+ or Ca2+. The removal of the A1 N-terminus influences the actin-myosin interaction in a Ca2+- and phosphorylation-dependent manner; in most cases, this leads to an increase in affinity. In the case of subfragment-1, the removal of the N-terminus of A1 led to a decrease in affinity. It is reasonable to assume that the intact A1 light chain may cause weakening of the actin-myosin interaction under certain conditions. This weakening may be regulated by RLC phosphorylation and RLC-bound calcium-for-magnesium exchange. Such an effect requires a structural minimum that is present in HMM but not in subfragment-1. Implications of such a role for the A1 N-terminus in the myosin-actin interaction are discussed.

Dual effect of actin on the accessibility of myosin essential light chain A1 to papain cleavage.

The influence of various amounts of actin on the proteolytic susceptibility of myosin essential light chain (ELC) A1, the binding of isolated A1 light chain and the N-peptide spanning N-terminal sequence of A1 to actin is studied to obtain more information on the role of the N-terminus of A1 light chain in the myosin-actin interaction. Low ratios of actin to myosin (1:1) lead to stimulate cleavage, whereas higher ratios (4:1) lead to protection of A1. Exposure of A1 by actin is especially seen in heavy meromyosin (HMM) and monomeric myosin and this is probably related to the full saturation of actin protomers with myosin heads. The protecting action of actin on A1 cleavage is more pronounced in myosin filaments. Conditions favoring the saturation of myosin regulatory light chain (RLC) with calcium ions instead of magnesium ions promotes the protection of A1. Cross-linking of HMM and actin results in higher yields of A1-actin product at high actin to myosin heads ratios. Isolated A1 light chain is pelleted by actin. A synthetic peptide spanning the N-terminal sequence of A1 can be cross-linked to actin. It is postulated that the protective action of actin on A1 papain cleavage is caused by the binding of the A1 N-terminus to actin. Changes in the RLC phosphorylation level and magnesium-for-calcium exchange in RLC may affect the probability of this interaction.

Stabilization of microtubular cytoskeleton protects neurons from toxicity of N-terminal fragment of cytosolic prion protein.

Prion protein (PrP) mislocalized in the cytosol has been presumed to be the toxic entity responsible for the neurodegenerative process in transmissible spongiform encephalopathies (TSE), also called prion diseases. The mechanism underlying the neurotoxicity of cytosolic PrP (cytoPrP) remains, however, unresolved. In this study we analyze toxic effects of the cell-penetrating PrP fragment, PrP1-30--encompassing residues responsible for binding and aggregation of tubulin. We have found that intracellularly localized PrP1-30 disassembles microtubular cytoskeleton of primary neurons, which leads to the loss of neurites and, eventually, necrotic cell death. Accordingly, stabilization of microtubules by taxol reduced deleterious effects of cytosolic PrP1-30. Furthermore, we have demonstrated that decreased phosphorylation level of microtubule-associated proteins (MAPs), which also increases stability of microtubular cytoskeleton, protects neurons from the toxic effects of PrP1-30. CHIR98014 and LiCl--inhibitors of glycogen synthase kinase 3 (GSK-3), a major kinase responsible for phosphorylation of MAPs, inhibited PrP1-30-induced disruption of microtubular cytoskeleton and increased viability of peptide-treated neurons. We have also shown that the N-terminal fragment of cytoPrP may cause the loss of dendritic spines. PrP1-30-induced changes at the level of spines have also been prevented by stabilization of microtubules by taxol as well as LiCl. These observations indicate that the neurotoxicity of cytoPrP is tightly linked to the disruption of microtubular cytoskeleton. Importantly, this study implies that lithium, the commonly used mood stabilizer, may be a promising therapeutic agent in TSE, particularly in case of the disease forms associated with accumulation of cytoPrP.

Covalent defects restrict supramolecular self-assembly of homopolypeptides: case study of β2-fibrils of poly-L-glutamic acid.

Poly-L-glutamic acid (PLGA) often serves as a model in studies on amyloid fibrils and conformational transitions in proteins, and as a precursor for synthetic biomaterials. Aggregation of PLGA chains and formation of amyloid-like fibrils was shown to continue on higher levels of superstructural self-assembly coinciding with the appearance of so-called β2-sheet conformation manifesting in dramatic redshift of infrared amide I′ band below 1600 cm−1. This spectral hallmark has been attributed to network of bifurcated hydrogen bonds coupling C = O and N-D (N-H) groups of the main chains to glutamate side chains. However, other authors reported that, under essentially identical conditions, PLGA forms the conventional in terms of infrared characteristics β1-sheet structure (exciton-split amide I′ band with peaks at ca. 1616 and 1683 cm−1). Here we attempt to shed light on this discrepancy by studying the effect of increasing concentration of intentionally induced defects in PLGA on the tendency to form β1/β2-type aggregates using infrared spectroscopy. We have employed carbodiimide-mediated covalent modification of Glu side chains with n-butylamine (NBA), as well as electrostatics-driven inclusion of polylysine chains, as two different ways to trigger structural defects in PLGA. Our study depicts a clear correlation between concentration of defects in PLGA and increasing tendency to depart from the β2-structure toward the one less demanding in terms of chemical uniformity of side chains: β1-structure. The varying predisposition to form β1- or β2-type aggregates assessed by infrared absorption was compared with the degree of morphological order observed in electron microscopy images. Our results are discussed in the context of latent covalent defects in homopolypeptides (especially with side chains capable of hydrogen-bonding) that could obscure their actual propensities to adopt different conformations, and limit applications in the field of synthetic biomaterials.

On the Heat Stability of Amyloid-Based Biological Activity: Insights from Thermal Degradation of Insulin Fibrils

Formation of amyloid fibrils in vivo has been linked to disorders such as Alzheimer’s disease and prion-associated transmissible spongiform encephalopathies. One of the characteristic features of amyloid fibrils is the high thermodynamic stability relative both to native and disordered states which is also thought to underlie the perplexingly remarkable heat resistance of prion infectivity. Here, we are comparing high-temperature degradation of native and fibrillar forms of human insulin. Decomposition of insulin amyloid has been studied under helium atmosphere and in the temperature range from ambient conditions to 750°C using thermogravimetry and differential scanning calorimetry coupled to mass spectrometry. While converting native insulin into amyloid does upshift onset of thermal decomposition by ca. 75°C, fibrils remain vulnerable to covalent degradation at temperatures below 300°C, as reflected by mass spectra of gases released upon heating of amyloid samples, as well as morphology and infrared spectra of fibrils subjected to incubation at 250°C. Mass spectra profiles of released gases indicate that degradation of fibrils is much more cooperative than degradation of native insulin. The data show no evidence of water of crystallization trapped within insulin fibrils. We have also compared untreated and heated amyloid samples in terms of capacity to seed daughter fibrils. Kinetic traces of seed-induced insulin fibrillation have shown that the seeding potency of amyloid samples decreases significantly already after exposure to 200°C, even though corresponding electron micrographs indicated persisting fibrillar morphology. Our results suggest that amyloid-based biological activity may not survive extremely high temperature treatments, at least in the absence of other stabilizing factors.