Matthew Bautista scite author profile

Understanding the pathogenicity of amyloid-beta (Ab) peptides constitutes a major goal in research on Alzheimer's disease (AD). One hypothesis entails that Ab peptides induce uncontrolled, neurotoxic ion flux through cellular membranes. The exact biophysical mechanism of this ion flux is, however, a subject of an ongoing controversy which has attenuated progress toward understanding the importance of Ab-induced ion flux in AD. The work presented here addresses two prevalent controversies regarding the nature of transmembrane ion flux induced by Ab peptides. First, the results clarify that Ab can induce stepwise ion flux across planar lipid bilayers as opposed to a gradual increase in transmembrane current; they show that the previously reported gradual thinning of membranes with concomitant increase in transmembrane current arises from residues of the solvent hexafluoroisopropanol, which is commonly used for the preparation of amyloid samples. Second, the results provide additional evidence suggesting that Ab peptides can induce ion channel-like ion flux in cellular membranes that is independent from the postulated ability of Ab to modulate intrinsic cellular ion channels or transporter proteins.

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Oligo(ethylene glycol) Derivatives of Thioflavin T as Inhibitors of Protein–Amyloid Interactions

Inbar

Takayama

et al. 2006

ChemBioChem

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Assay To Screen for Molecules That Associate with Alzheimer's Related β-Amyloid Fibrils

et al. 2008

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Small molecules that bind to aggregated forms of Abeta peptides show promise as potential in vivo labeling agents for the diagnosis and monitoring of Alzheimer's disease. A major challenge in developing potential imaging agents that target Abeta is to rapidly identify and evaluate the association of molecules with insoluble deposits of aggregated Abeta peptides. This paper describes a simple, parallel method to rapidly screen libraries of molecules for their ability to associate with fibrils formed from synthetic Abeta peptides by monitoring their ability to inhibit the interaction of a monoclonal anti-Abeta IgG with these fibrils. We demonstrate that this assay can detect the association of small molecules with Abeta fibrils at concentrations of small molecule in the nanomolar to millimolar range. By comparing results from the screening of a small set of 30 compounds, we illustrated that this assay can rapidly analyze the relative affinity of small molecules for Abeta fibrils and identified eight compounds that can bind to Abeta fibrils at <20 microM concentrations. Significant advantages of this assay are (1) the ability to screen structurally diverse molecules without requiring them to have specific spectroscopic or radiolabeled properties, (2) the ability to estimate the percentage of the surface of the fibrils covered by the small molecules, and (3) the ability to detect the association of small molecules that potentially bind to different sites along the fibril axis. This assay also has minimal requirements for equipment or specialized facilities and should, therefore, be useful for both academic and industrial laboratories.

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Inhibition of the HEG1–KRIT1 interaction increases KLF4 and KLF2 expression in endothelial cells

Lopez-Ramirez

McCurdy

et al. 2021

FASEB BioAdvances

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The transmembrane protein heart of glass1 (HEG1) directly binds to and recruits Krev interaction trapped protein 1 (KRIT1) to endothelial junctions to form the HEG1–KRIT1 protein complex that establishes and maintains junctional integrity. Genetic inactivation or knockdown of endothelial HEG1 or KRIT1 leads to the upregulation of transcription factors Krüppel‐like factors 4 and 2 (KLF4 and KLF2), which are implicated in endothelial vascular homeostasis; however, the effect of acute inhibition of the HEG1–KRIT1 interaction remains incompletely understood. Here, we report a high‐throughput screening assay and molecular design of a small‐molecule HEG1–KRIT1 inhibitor to uncover acute changes in signaling pathways downstream of the HEG1–KRIT1 protein complex disruption. The small‐molecule HEG1–KRIT1 inhibitor 2 (HKi2) was demonstrated to be a bona fide inhibitor of the interaction between HEG1 and KRIT1 proteins, by competing orthosterically with HEG1 through covalent reversible interactions with the FERM (4.1, ezrin, radixin, and moesin) domain of KRIT1. The crystal structure of HKi2 bound to KRIT1 FERM revealed that it occupies the same binding pocket on KRIT1 as the HEG1 cytoplasmic tail. In human endothelial cells (ECs), acute inhibition of the HEG1–KRIT1 interaction by HKi2 increased KLF4 and KLF2 mRNA and protein levels, whereas a structurally similar inactive compound failed to do so. In zebrafish, HKi2 induced expression of klf2a in arterial and venous endothelium. Furthermore, genome‐wide RNA transcriptome analysis of HKi2‐treated ECs under static conditions revealed that, in addition to elevating KLF4 and KLF2 expression, inhibition of the HEG1–KRIT1 interaction mimics many of the transcriptional effects of laminar blood flow. Furthermore, HKi2‐treated ECs also triggered Akt signaling in a phosphoinositide 3‐kinase (PI3K)‐dependent manner, as blocking PI3K activity blunted the Akt phosphorylation induced by HKi2. Finally, using an in vitro colocalization assay, we show that HKi6, an improved derivative of HKi2 with higher affinity for KRIT1, significantly impedes recruitment of KRIT1 to mitochondria‐localized HEG1 in CHO cells, indicating a direct inhibition of the HEG1–KRIT1 interaction. Thus, our results demonstrate that early events of the acute inhibition of HEG1–KRIT1 interaction with HKi small‐molecule inhibitors lead to: (i) elevated KLF4 and KLF2 gene expression; and (ii) increased Akt phosphorylation. Thus, HKi’s provide new pharmacologic tools to study acute inhibition of the HEG1–KRIT1 protein complex and may provide insights to dissect early signaling events that regulate vascular homeostasis.

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Fangchinoline exerts anticancer effects on colorectal cancer by inducing autophagy via regulation AMPK/mTOR/ULK1 pathway

Xiang

Tian

et al. 2021

Biochemical Pharmacology

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