Alzheimer's disease (AD) is currently one of the most difficult and challenging diseases to treat. Based on the ‘multi-target-directed ligands’ (MTDLs) strategy, we designed and synthesised a series of new compounds against AD by combining the pharmacophores of resveratrol and clioquinol. The results of biological activity tests showed that the hybrids exhibited excellent MTDL properties: a significant ability to inhibit self-induced β-amyloid (Aβ) aggregation and copper(II)-induced Aβ aggregation, potential antioxidant behaviour (ORAC-FL value of 0.9–3.2 Trolox equivalents) and biometal chelation. Among these compounds, (E)-5-(4-hydroxystyryl)quinoline-8-ol (10c) showed the most potent ability to inhibit self-induced Aβ aggregation (IC50 = 8.50 μM) and copper(II)-induced Aβ aggregation and to disassemble the well-structured Aβ fibrils generated by self- and copper(II)-induced Aβ aggregation. Note that 10c could also control Cu(I/II)-triggered hydroxyl radical (OH˙) production by halting copper redox cycling via metal complexation, as confirmed by a Cu–ascorbate redox system assay. Importantly, 10c did not show acute toxicity in mice at doses of up to 2000 mg kg−1 and was able to cross the blood–brain barrier (BBB), according to a parallel artificial membrane permeation assay. These results indicate that compound 10c is a promising multifunctional compound for the development of novel drugs for AD.
The application of ketoreductase-based biocatalytic reduction to access optically pure Prelog or anti-Prelog alcohols offers a valuable approach for asymmetric synthesis. Despite this, control of the stereopreferences of ketoreductases as desired remains challenging, since natural ketoreductases usually display Prelog preference and it is difficult to transfer the knowledge from engineered anti-Prelog ketoreductases to the others. Here, we present the discovery of a switch between Prelog and anti-Prelog reduction toward halogen-substituted acetophenones in six short-chain dehydrogenase/reductases (SDRs). Through carefully analysis of the structural information and multiple-sequence alignment of several reported SDRs with Prelog or anti-Prelog stereopreference, the key residues that might control their stereopreferences were identified using Lactobacillus fermentum short-chain dehydrogenase/reductase 1 (LfSDR1) as the starting enzyme. Protein engineering at these positions of LfSDR1 could improve its anti-Prelog stereoselectivity or switch its stereopreference to Prelog. Moreover, the knowledge obtained from LfSDR1 could be further transferred to the five other SDRs (four mined SDRs and one reported SDR) that have 21−48% sequence identities with LfSDR1. The stereopreferences of these SDRs were able to be switched either from anti-Prelog to Prelog or from Prelog to anti-Prelog by mutagenesis at related positions. In addition, further optimization of LfSDR1 can access stereocomplementary reduction of several halogen-substituted acetophenones with high stereoselectivity (up to >99%), resulting in some valuable chiral alcohols for the synthesis of pharmaceutical agents.
It is still relatively unclear how intervertebral disc (IVD) cells sense a mechanical stimulus and convert this signal into a biochemical response. Previous studies demonstrated that the cytoskeletal elements are mechano-responsive in many cell types and may contribute to mechano-signalling pathways. The objective of this study was to determine the response of cells from the outer annulus fi brosus (OAF) to physiological levels of cyclic tensile strain; further, cells from the nucleus pulposus (NP) were also subjected to an identical loading regime to compare biological responses across the IVD populations. We determined whether the organisation and expression of the major cytoskeletal elements and their associated accessory proteins are responsive to mechanical stimulation in these cells, and whether these changes correlated with either a catabolic or anabolic phenotype. OAF and NP cells from immature bovine IVD were seeded onto Flexcell® type I collagen coated plates. Cells were subjected to cyclic tensile strain (10 %, 1 Hz) for 60 minutes. Post-loading, cells were processed for immunofluorescence microscopy, RNA extracted for quantitative PCR and protein extracted for Western blotting analysis. F-actin reorganisation was evident in OAF and NP cells subjected to tensile strain; strain induced β-actin at the transcriptional and translational level in OAF cells. β-tubulin mRNA and protein synthesis increased in strained OAF cells, but vimentin expression was signifi cantly inhibited. Cytoskeletal element organisation and expression were less responsive to strain in NP cells. Tensile strain increased type I collagen and differentially regulated extracellular matrix (ECM)-degrading enzymes' mRNA levels in OAF cells. Strain induced type II collagen transcription in NP cells, but had no effect on the transcription of any other genes analysed. Tensile strain induces different mechano-responses in the organisation and/or expression of cytoskeletal elements and on markers of IVD metabolism. Differential mechano-regulation of anabolic and catabolic ECM components in the OAF and NP populations refl ects their respective mechanical environments in situ.
The smooth addition of phenylacetylene to aromatic ketones in the presence of catalytic amounts of Cu(OTf)2 and camphorsulfonamide provides the corresponding tertiary propargylic alcohols in high yields and with up to 97 % ee. This reaction represents a highly enantioselective catalytic addition of dialkynyl zinc reagents to simple ketones.
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