The misfolding of proteins and peptides potentially leads to a conformation transition from an αhelix or random coil to β-sheet-rich fibril structures, which are associated with various amyloid degenerative disorders. Inhibition of the β-sheet aggregate formation and control of the structural transition could therefore attenuate the development of amyloid-associated diseases. However, the structural transitions of proteins and peptides are extraordinarily complex processes that are still not fully understood and thus challenging to manipulate. To simplify this complexity, herein, the effect of metal ions on the inhibition of amyloid-like β-sheet dipeptide selfassembly is investigated. By changing the type and ratio of the metal ion/dipeptide mixture, structural transformation is achieved from a β-sheet to a superhelix or random coil, as confirmed by experimental results and computational studies. Furthermore, the obtained supramolecular metallogel exhibits excellent in vitro DNA binding and diffusion capability due to the positive charge of the metal/dipeptide complex. This work may facilitate the understanding of the role of metal ions in inhibiting amyloid formation and broaden the future applications of supramolecular metallogels in three-dimensional (3D) DNA biochip, cell culture, and drug delivery.
The formation of ordered nanostructures by metabolites is gaining increased interest due to the simplicity of the building blocks and their natural occurrence. Specifically, aromatic amino acids possess the ability to form ordered supramolecular interactions due to their limited solubility in aqueous solution. Unexpectedly, L-tyrosine (L-Tyr) is almost 2 orders of magnitude less soluble in water compared to L-phenylalanine (L-Phe). However, the underlying mechanism is not fully understood as L-Tyr is more polar. Here, we explore the utilization of insoluble tyrosine assemblies for technological applications and their molecular basis by manipulating the basic building blocks of tightly packed dimers. We show that the addition of an amyloid inhibition agent increases L-Tyr solubility due to the disruption of the dimer formation. The molecular organization grants the L-Tyr crystal higher thermal stability and mechanical properties between three amino acids. Additionally, L-Tyr crystals are shown to generate high and stable piezoelectric power outputs under mechanical pressure in a sandwich device. By incorporating the rigid L-Tyr crystals into a soft polymer, a mechanoresponsive bending composite was fabricated. Furthermore, the L-Tyr crystalline needles exhibit an active photowaveguiding property, making them promising candidates for the generation of photonic biomaterial-based devices. The present work exemplifies a feasible strategy to explore physical properties of supramolecular self-assemblies comprises minimalistic naturally occurring building blocks and their applications in energy harvesting, photonic devices, stretchable electronics, and soft robotics.
Breaking up is not hard to do with an α‐aminoisobutyric (Aib) acid β‐breaker, which has a remarkably restricted conformation. A novel approach to the inhibition of amyloid formation was developed that uses peptides modified with Aib (see figure). The similarity of Aib to hydrophobic amino acids, often found in amyloidogenic sequences, allows its integration into recognition motifs.
Nature's route for amyloid prevention: Insulin is a natural inhibitor of amyloid formation by the islet amyloid polypeptide (IAPP). The interacting domains of both proteins were identified by using a reductionist approach (see scheme). An understanding of the molecular mechanism of this physiological interaction may lead to the design of peptidomimetic drugs for type II diabetes.
Room-temperature,
long-range (300 nm), chirality-induced spin-selective
electron conduction is found in chiral metal–organic Cu(II)
phenylalanine crystals, using magnetic conductive-probe atomic force
microscopy. These crystals are found to be also weakly ferromagnetic
and ferroelectric. Notably, the observed ferromagnetism is thermally
activated, so that the crystals are antiferromagnetic at low temperatures
and become ferromagnetic above ∼50 K. Electron paramagnetic
resonance measurements and density functional theory calculations
suggest that these unusual magnetic properties result from indirect
exchange interaction of the Cu(II) ions through the chiral lattice.
Soluble oligomeric assemblies of amyloidal proteins appear to act as major pathological agents in several degenerative disorders. Isolation and characterization of these oligomers is a pivotal step towards determination of their pathological relevance. Here we describe the isolation of Type 2 diabetes-associated islet amyloid polypeptide soluble cytotoxic oligomers; these oligomers induced apoptosis in cultured pancreatic cells, permeated model lipid vesicles and interacted with cell membranes following complete internalization. Moreover, antibodies which specifically recognized these assemblies, but not monomers or amyloid fibrils, were exclusively identified in diabetic patients and were shown to neutralize the apoptotic effect induced by these oligomers. Our findings support the notion that human IAPP peptide can form highly toxic oligomers. The presence of antibodies identified in the serum of diabetic patients confirms the pathological relevance of the oligomers. In addition, the newly identified structural epitopes may also provide new mechanistic insights and a molecular target for future therapy.
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