In vivo accumulation of self-assembling dye Congo red in an area marked by specific immune complexes: possible relevance to chemotherapy.

Supramolecular micellar structures have been proposed as carriers in aim-oriented drug transportation to a target marked by specific immune complexes. In this study, the self-assembling dye Congo red was used as a model supramolecular carrier and its accumulation in the target was studied in vivo. The target was created in vivo as the local specific inflammation provoked by subcutaneous injection of antigen to the ear of a previously immunized rabbit. The color caused by accumulation of Congo red after its intravenous injection was registered by pictures of the ear with suitably filtered visible light shining through it to distinguish Congo red against the background color of hemoglobin. The results confirmed the expected accumulation and retention of Congo red in the inflammation area marked by deposits of specific immune complexes. The role of albumin and its possible interference with transportation of drugs through the blood by supramolecular carriers was also subjected to preliminary examination. The results revealed that albumin collaborates rather than interferes with drug transportation; this is another factor making the use of supramolecular carriers for aim-oriented chemotherapy highly promising

In vivo accumulation of self-assembling dye Congo red in an area marked by specific immune complexes : possible relevance to chemotherapy

Supramolecular micellar structures have been proposed as carriers in aim-oriented drug transportation to a target marked by specific immune complexes. In this study, the self-assembling dye Congo red was used as a model supramolecular carrier and its accumulation in the target was studied in vivo. The target was created in vivo as the local specific inflammation provoked by subcutaneous injection of antigen to the ear of a previously immunized rabbit. The color caused by accumulation of Congo red after its intravenous injection was registered by pictures of the ear with suitably filtered visible light shining through it to distinguish Congo red against the background color of hemoglobin. The results confirmed the expected accumulation and retention of Congo red in the inflammation area marked by deposits of specific immune complexes. The role of albumin and its possible interference with transportation of drugs through the blood by supramolecular carriers was also subjected to preliminary examination. The results revealed that albumin collaborates rather than interferes with drug transportation; this is another factor making the use of supramolecular carriers for aim-oriented chemotherapy highly promising

Molecular Lysine Tweezers Counteract Aberrant Protein Aggregation.

Molecular tweezers (MTs) are supramolecular host molecules equipped with two aromatic pincers linked together by a spacer (Gakh, 2018). They are endowed with fascinating properties originating from their ability to hold guests between their aromatic pincers (Chen and Whitlock, 1978; Zimmerman, 1991; Harmata, 2004). MTs are finding an increasing number of medicinal applications, e.g., as bis-intercalators for DNA such as the anticancer drug Ditercalinium (Gao et al., 1991), drug activity reverters such as the bisglycoluril tweezers Calabadion 1 (Ma et al., 2012) as well as radioimmuno detectors such as Venus flytrap clusters (Paxton et al., 1991). We recently embarked on a program to create water-soluble tweezers which selectively bind the side chains of lysine and arginine inside their cavity. This unique recognition mode is enabled by a torus-shaped, polycyclic framework, which is equipped with two hydrophilic phosphate groups. Cationic amino acid residues are bound by the synergistic effect of disperse, hydrophobic, and electrostatic interactions in a kinetically fast reversible process. Interactions of the same kind play a key role in numerous protein-protein interactions, as well as in pathologic protein aggregation. Therefore, these particular MTs show a high potential to disrupt such events, and indeed inhibit misfolding and self-assembly of amyloidogenic polypeptides without toxic side effects. The mini-review provides insight into the unique binding mode of MTs both toward peptides and aggregating proteins. It presents the synthesis of the lead compound CLR01 and its control, CLR03. Different biophysical experiments are explained which elucidate and help to better understand their mechanism of action. Specifically, we show how toxic aggregates of oligomeric and fibrillar protein species are dissolved and redirected to form amorphous, benign assemblies. Importantly, these new chemical tools are shown to be essentially non-toxic in vivo. Due to their reversible moderately tight binding, these agents are not protein-, but rather process-specific, which suggests a broad range of applications in protein misfolding events. Thus, MTs are highly promising candidates for disease-modifying therapy in early stages of neurodegenerative diseases. This is an outstanding example in the evolution of supramolecular concepts toward biological application

Screening and classifying small-molecule inhibitors of amyloid formation using ion mobility spectrometry-mass spectrometry

The search for therapeutic agents that bind specifically to precursor protein conformations and inhibit amyloid assembly is an important challenge. Identifying such inhibitors is difficult because many protein precursors of aggregation are partially folded or intrinsically disordered, which rules out structure-based design. Furthermore, inhibitors can act by a variety of mechanisms, including specific or nonspecific binding, as well as colloidal inhibition. Here we report a high-throughput method based on ion mobility spectrometry–mass spectrometry (IMS–MS) that is capable of rapidly detecting small molecules that bind to amyloid precursors, identifying the interacting protein species and defining the mode of inhibition. Using this method we have classified a variety of small molecules that are potential inhibitors of human ​islet amyloid polypeptide (​hIAPP) aggregation or ​amyloid-beta 1-40 aggregation as specific, nonspecific, colloidal or non-interacting. We also demonstrate the ability of IMS–MS to screen for inhibitory small molecules in a 96-well plate format and use this to discover a new inhibitor of ​hIAPP amyloid assembly

Supramolecular Systems for Gene and Drug Delivery

Dear Colleagues,Supramolecular systems (calixarenes, cyclodextrins, polymers, peptides, etc.) have attracted special attention due to their excellent therapeutic properties for biomedical applications such as gene and drug delivery. Numerous biomaterials-based supramolecular systems have been developed in the last decade for enhancing of biocompatibility and pharmacological activity. In particular, supramolecular nanomaterials are considered a hot research topic, because nanomedicine has become an interesting tool for the treatment of genetic diseases or cancer. Nevertheless, novel systems and their properties are being continuously studied, contributing to the development of efficient delivery systems.This Special Issue provides and highlights current progress in the use of the supramolecular systems for boosting gene and drug delivery. Preparation, characterization, and use of these systems, as well as the latest developments in this research field, are especially welcome.Authors are encorauged to submit original research articles and reviews in this promising research field

A Nanoparticle/enzyme System For The Simultaneous Detection And Decontamination Of Organophosphates

The need for a direct visual response system for the detection of organophosphorus compounds stems from the continued threat and use of these toxic agents in military and terrorist conflicts. The development of an enzyme-inhibitor triggered release system allows for direct visual detection with high specificity. Mesoporous silica nanoparticles (MSNs) have physical features that make them attractive as scaffolds for the construction of these systems, such as pore diameters (20-500 Á) that can be synthetically controlled, large surface areas (300-1500 m2g-1), large pore volumes, chemical inertness, stability at elevated temperatures, and surfaces that can be easily functionalized. In our studies, the dye Congo Red was loaded into the pores of MSNs, which were then capped by tethering an enzyme (organophosphorus hydrolase (OPH) or acetylcholinesterase (AChE)) to the external surfaces of MSNs through a competitive inhibitor (diethyl 4-aminobenzyl phosphonate (DEABP) or tacrine, respectively). OPH has been extensively studied for its ability to hydrolyze a wide range of organophosphorus compounds, rendering them non-toxic. AChE has been commonly used for organophosphate detection resulting from its sensitivity to phosphorylation. Upon addition of organophosphorus compounds to suspensions of the modified MSNs, the enzymes detached from the MSN surface, releasing the dye and providing a visual confirmation of organophosphate presence. Enzyme kinetics were studied using 31P NMR or UV-Visible spectroscopy; Congo Red release was also monitored by UV-Visible spectroscopy. The system was sensitive and specific for organophosphorus compounds both in phosphate-buffered saline and in human serum. The rate of dye release directly correlated with the rate of organophosphorus conversion for OPH and the rate of phosphorylation for AChE

Cyanine dyes derived inhibition of insulin fibrillization

The potential of novel cyanine dyes to inhibit the insulin amyloid formation was evaluated using thioflavin T fluorescence assay, quantum-chemical calculations, molecular docking and molecular dynamics simulations. According to the ability to suppress the insulin fibrillization under physiological conditions the examined compounds were found to follow the order: trimethines > pentamethines > monomethines > heptamethines. Of these, the trimethines 3-3 and 3-5, and pentamethines 5-3 and 5-9 almost completely prevented the protein aggregation by retarding both nucleation (except 3-3) and elongation processes. The quantum-chemical calculations revealed a complex relationship between the dye structure and its inhibitory effects. The molecular docking studies showed that most cyanines bind specifically to the L17 ladder of the B chain, located at the dry steric zipper of the insulin fibril protofilament, and form the stable complexes with the helices of the insulin monomer. The molecular dynamics simulations provided evidence for the increase of insulin helicity in the presence of cyanines. Collectively, the presented findings highlight two possible mechanisms by which cyanines can inhibit the insulin fibrillization: i) stabilization of the native protein structure followed by the retardation of the protein nucleation (all dyes); and ii) blocking the lateral extension of beta-sheets via the dye-protein stacking interactions (3-3, 3-5, 5-3, 5-9). Overall, the obtained results may prove of importance for the design of small molecules capable of preventing amyloid fibril formation by insulin and other proteins. (C) 2018 Elsevier B.V. All rights reserved.Peer reviewe

Small molecule probes of protein aggregation

Understanding the mechanisms of amyloid formation and toxicity remain major challenges. Whilst substantial progress has been made in the development of methods able to identify the species formed during self-assembly and to describe the kinetic mechanisms of aggregation, the structure(s) of non-native species, including potentially toxic oligomers, remain elusive. Moreover, how fibrils contribute to disease remains unclear. Here we review recent advances in the development of small molecules and other reagents that are helping to define the mechanisms of protein aggregation in molecular detail. Such probes form a powerful platform with which to better define the mechanisms of structural conversion into amyloid fibrils and may provide the much-needed stepping stone for future development of successful therapeutic agents

Selective observation of semi-rigid non-core residues in dynamically complex mutant huntingtin protein fibrils

Many amyloid-forming proteins, which are normally intrinsically disordered, undergo a disorder-to-order transition to form fibrils with a rigid β-sheet core flanked by disordered domains. Solid-state NMR (ssNMR) and cryogenic electron microscopy (cryoEM) excel at resolving the rigid structures within amyloid cores but studying the dynamically disordered domains remains challenging. This challenge is exemplified by mutant huntingtin exon 1 (HttEx1), which self-assembles into pathogenic neuronal inclusions in Huntington disease (HD). The mutant protein's expanded polyglutamine (polyQ) segment forms a fibril core that is rigid and sequestered from the solvent. Beyond the core, solvent-exposed surface residues mediate biological interactions and other properties of fibril polymorphs. Here we deploy magic angle spinning ssNMR experiments to probe for semi-rigid residues proximal to the fibril core and examine how solvent dynamics impact the fibrils' segmental dynamics. Dynamic spectral editing (DYSE) 2D ssNMR based on a combination of cross-polarization (CP) ssNMR with selective dipolar dephasing reveals the weak signals of solvent-mobilized glutamine residues, while suppressing the normally strong background of rigid core signals. This type of 'intermediate motion selection' (IMS) experiment based on cross-polarization (CP) ssNMR, is complementary to INEPT- and CP-based measurements that highlight highly flexible or highly rigid protein segments, respectively. Integration of the IMS-DYSE element in standard CP-based ssNMR experiments permits the observation of semi-rigid residues in a variety of contexts, including in membrane proteins and protein complexes. We discuss the relevance of semi-rigid solvent-facing residues outside the fibril core to the latter's detection with specific dyes and positron emission tomography tracers

Role of Withaferin A as a Neuroprotectant against Beta Amyloid Induced Toxicity and associated mechanism

Neurological disorders are the biggest concern globally and ageing contributes in worsening the disease scenarios. In AD or AD like diseases, there is abnormal accumulation of extracellular amyloid beta produced due to abnormal processing of the transmembrane amyloid precursor protein, by β and γ-secretases. It spreads in the cortical and limbic regions of the brain leading to neuronal toxicity, impairment in memory and neurological functions. Aβ deposition in the CNS is common in aging HIV patients. Neurotoxic protein Tat, results in increased Aβ in combination with drugs of abuse cocaine. We examined the role of Withaferin A, against Aβ induced neurotoxicity. Our in-vitro dose optimization study demonstrates that lower concentrations (0.5–2 μM) of WA significantly reduce the Aβ40, without inducing cytotoxicity in the APP plasmid transfected SH-SY5Y cells (SHAPP). We demonstrate that Aβ secretion is increased in the presence of Tat (50 ng/ml) and coc (0.1 μM), WA reduces the Tat and coc induced increase in Aβ40. Additionally, we studied the role of WA against NF-kB mediated neuroinflammation, and observed that WA inhibits the expression of NFkB2 and RELA transcription factors, which play a major role in the expression of inflammatory chemokines. Further, to address the issue of minimal drug bioavailability in the CNS, we developed the WA loaded liposomal nanoformulation (WA-LNF) and characterized its size (499+/-50nm), toxicity and drug binding efficacy (28%). Our in-vitro 3D BBB transmigration of WA-LNF demonstrated ~40% transmigration efficiency. Furthermore, it was imperative for us to understand the mechanism of action of WA, therefore we studied the molecular mechanism of interaction of WA with Aβ protein by in-silico molecular dynamics simulations. We demonstrated that WA binds to the middle region of Aβ protein and the amino acid motif involved were FAEDVGS highlighting the mid-region Aβ capture by WA. 3 Hydrogen bonds were formed between WA and the amino acids, ASN17, GLY15 and SER16. This study reports WA as a potent neuroprotectant against amyloid induced neurotoxicity. Our study may have an immense therapeutic potential to target Aβ in the CNS, in the ageing patients and/or PLWH and/or ageing drug abusers