Lavender and coriander essential oils and their main component linalool exert a protective effect against amyloid‐β neurotoxicity

Alzheimer's disease (AD) is a neurodegenerative disorder leading to cognitive deficits and cognitive decline. Since no cure or preventing therapy is currently available to counteract AD, natural‐derived compounds are investigated to find new potential neuroprotective agents for its treatment. In the present study, we tested the neuroprotective effect of lavender and coriander essential oils (EOs) and their main active constituent linalool, against the neurotoxicity elicited by Aβ_1‐42 oligomers, a key molecular factor in the neurodegeneration of AD. Importantly, our findings on neuronally differentiated PC12 cells exposed to Aβ_1‐42 oligomers are in accordance with previous in vivo studies reporting the neuroprotective potential of lavender and coriander EOs and linalool. We found that lavender and coriander EOs at the concentration of 10 μg/mL as well as linalool at the same concentration were able to improve viability and to reduce nuclear morphological abnormalities in cells treated with Aβ_1‐42 oligomers for 24 hours. Lavender and coriander EOs and linalool also showed to counteract the increase of intracellular reactive oxygen species production and the activation of the pro‐apoptotic enzyme caspase‐3 induced by Aβ_1‐42 oligomers. Our findings provide further evidence that these EOs and their main constituent linalool could be natural agents of therapeutic interest against Aβ_1‐42‐induced neurotoxicity.     

G蛋白偶联受体高阶聚化和信号转导中蛋白复合体的时空动态检测进展

传统观点认为,G蛋白偶联受体与G蛋白、调节蛋白、GRKs以及arrestins间的相互作用是连续的,其中涉及多个蛋白质之间快速的集合和解聚。而实际上,GPCRs和相关靶分子之间的作用是通过一系列细胞内蛋白质-蛋白质相互作用的信号转导网络来实现的。近10年,随着一些新兴技术的出现,如FRET、BRET和BiFC,实时动态观测二个蛋白质间相互作用的研究成为热点。最近,一些技术结合的方法为从"时间、空间、动态、连续"检测更多蛋白质之间的相互作用的研究拉开新的帷幕。从横向来看,这些技术的结合可以用来研究细胞膜上3种甚至更多蛋白质的高阶寡聚化;从纵向来看,可以对细胞膜-细胞质-细胞核中所发生的信号转导网络的研究提供新的技术手段,多种技术结合所发挥作用是最近出现的几种技术所无法企及的,这对于疾病发病机制的研究及新的药物靶点的发现具有深远意义。因此,本文就一些技术的结合及其应用做一简要综述。     

Bivalent Ligands Targeting Multiple Pathological Factors Involved in Alzheimer's Disease

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Calcium-Sensing Receptors of Human Astrocyte-Neuron Teams: Amyloid-β-Driven Mediators and Therapeutic Targets of Alzheimer’s Disease

It is generally assumed that the neuropathology of sporadic (late-onset or nonfamilial) Alzheimer’s disease (AD) is driven by the overproduction and spreading of first Amyloid-β_x-42 (Aβ₄₂) and later hyperphosphorylated (hp)-Tau oligomeric “infectious seeds”. Hitherto, only neurons were held to make and spread both oligomer types; astrocytes would just remove debris. However, we have recently shown that exogenous fibrillar or soluble Aβ peptides specifically bind and activate the Ca²⁺-sensing receptors (CaSRs) of untransformed human cortical adult astrocytes and postnatal neurons cultured in vitro driving them to produce, accrue, and secrete surplus endogenous Aβ₄₂. While the Aβ-exposed neurons start dying, astrocytes survive and keep oversecreting Aβ₄₂, nitric oxide (NO), and vascular endothelial growth factor (VEGF)-A. Thus astrocytes help neurons’ demise. Moreover, we have found that a highly selective allosteric CaSR agonist (“calcimimetic”), NPS R-568, mimics the just mentioned neurotoxic actions triggered by Aβ●CaSR signaling. Contrariwise, and most important, NPS 2143, a highly selective allosteric CaSR antagonist (“calcilytic”), fully suppresses all the Aβ●CaSR signaling-driven noxious actions. Altogether our findings suggest that the progression of AD neuropathology is promoted by unceasingly repeating cycles of accruing exogenous Aβ₄₂ oligomers interacting with the CaSRs of swelling numbers of astrocyte-neuron teams thereby recruiting them to overrelease additional Aβ₄₂ oligomers, VEGF-A, and NO. Calcilytics would beneficially break such Aβ/CaSR-driven vicious cycles and hence halt or at least slow the otherwise unstoppable spreading of AD neuropathology     

Highly Efficient Synthesis of 1,3-Dihydroxy-2-carboxycarbazole and Its Neuroprotective Effects

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The modulation by xanthines of the DNA-damaging effect of polycyclic aromatic agents. Part II. The stacking complexes of caffeine with doxorubicin and mitoxantrone

Recently accumulated statistical data indicate the protective effect of caffeine consumption against several types of cancer diseases. There are also reports about protective effect of caffeine and other xanthines against tumors induced by polycyclic aromatic hydrocarbons. One of the explanations of this phenomenon is based on biological activation of such carcinogens by cytochromes that are also known for metabolism of caffeine. In the accompanying paper [Kapuscinski et al., this issue] we provide evidence (flow cytometry and the cell cycle analysis) that the cytostatic effects of caffeine (CAF) on two DNA alkylating agents, which do not require the biological activation, depend on their ability to form stacking (pi-pi) complexes. In this study, we use physicochemical techniques (computer aided light absorption and microcalorimetry), and molecular modeling to examine previously published qualitative data. This is published both by our and other group's data, indicates that CAF is able to modify the cytotoxic and/or cytostatic action of the two well known antitumor drugs doxorubicin (DOX) and mitoxantrone (MIT). To obtain the quantitative results from the experimental data we used the statistical-thermodynamical model of mixed aggregation, to find the association constants K(AC) of the CAF-drug interaction (128+/-10 and 356+/-21M(-1) for DOX-CAF and MIT-CAF complex formation, respectively). In addition, the favorable enthalpy change of CAF-MIT (DeltaH=-11.3kcal/mol) was measured by microcalorimetry titration. The molecular modeling (semi-empirical and force field method) allowed us to obtain the geometry of these complexes, which indicated the favorable energy (DeltaE) of complex formation of the protonated drug's molecules in aqueous environment (-7.4 and -8.7kcal/mol for DOX-CAF.5H(2)O and MIT-CAF.8H(2)O complex, respectively). The molecular modeling calculation indicates the existence of CAF-drug complexes in which the MIT molecules are intercalated between two CAF molecules (DeltaE=-29.9kcal/mol). These results indicate that the attenuating effect of caffeine on cytotoxic or mutagenic effects of some polycyclic aromatic mutagens cannot be the result of metabolic activation in the cells, but simply is the physicochemical process of the sequestering of aromatic molecules (e.g. carcinogens or mutagens) by formation of the stacking complexes. The caffeine may then act as the "interceptor" of potential carcinogens (especially in the upper part of digesting track) where its concentration can reach the mM level). There is, however, no indication, both, in the literature or from our experiments, that the xanthines can reverse the damage to nucleic acids at the point when the damage to DNA has already occurred.     

Size and morphology of toxic oligomers of amyloidogenic proteins: a case study of human stefin B

Amyloid-induced toxicity is a well-known phenomenon but the molecular background remains unclear. One hypothesis relates toxicity to amyloid–membrane interactions, predicting that amyloid oligomers make pores into membranes. Therefore, the toxicity and membrane interaction of prefibrillar aggregates and individual oligomers of a non-pathological yet highly amyloidogenic protein human stefin B (cystatin B) was examined. By monitoring caspase-3 activity and by testing cell viability, we showed that the lag phase aggregates obtained at pH 5 and 3 were toxic to neuroblastoma cells. Of equal toxicity were the higher-order oligomers prepared at pH 7 by freeze–thaw cycles. The higher-order oligomers eluted on size-exclusion chromatography (SEC) as a broad peak comprising hexamers, octamers, 12- and 16-mers, well separated from monomers, dimers and tetramers. Only oligomers higher than the tetramers (Rh >3.5 nm) proved toxic, in contrast to dimers and tetramers. In accordance with data from SEC, dynamic light scattering and atomic force microscopy data indicate that the toxic oligomers have diameters larger than 4 nm. Critical pressure measurements showed that the toxic higher-order oligomers inserted more effectively into model lipid monolayers than dimers and tetramers. They also bound, similarly to prefibrillar aggregates, to the plasma membrane and became internalized. Taken together, our results confirm the importance of membrane interaction and perforation in the phenomenon of cytotoxicity.     

Synthesis and electrochemical investigation of oligo-(arylenevinylenes) intended for the preparation of two-dimensional polymer networks

Four phenylenevinylene oligomers (1–4) have been synthesized and characterized by cyclic voltammetry, absorption spectroscopy and photoluminescence (PL). Two of the oligomers contain a tri-substituted central benzene ring, while one contains a tetra-substituted central ring. These oligomers were prepared in an effort to increase hole and electron mobility in organic materials via extension of conjugation to two dimensions. Optical and electrochemical evidence is given for significant interactions of the alkoxy-substituted styryl units of 3 that are attached to the central benzene ring in meta positions. The tetra-substituted oligomer (4) also exhibits strong interactions between the pair of para substituted arms. The photoluminescence (PL) quantum yield for the tetra-substituted oligomer is high, indicating that it is an excellent candidate for the active layer in organic light-emitting diodes.     

Quantification of receptor tyrosine kinase transactivation through direct dimerization and surface density measurements in single cells

Cell signaling involves dynamic changes in protein oligomerization leading to the formation of different signaling complexes and modulation of activity. Spatial intensity distribution analysis (SpIDA) is an image analysis method that can directly measure oligomerization and trafficking of endogenous proteins in single cells. Here, we show the use of SpIDA to quantify dimerization/activation and surface transport of receptor protein kinases--EGF receptor and TrkB--at early stages of their transactivation by several G protein-coupled receptors (GPCRs). Transactivation occurred on the same timescale and was directly limited by GPCR activation but independent of G-protein coupling types. Early receptor protein kinase transactivation and internalization were not interdependent for all receptor pairs tested, revealing heterogeneity between groups of GPCRs. SpIDA also detected transactivation of TrkB by dopamine receptors in intact neurons. By allowing for time and space resolved quantification of protein populations with heterogeneous oligomeric states, SpIDA provides a unique approach to undertake single cell multivariate quantification of signaling processes involving changes in protein interactions, trafficking, and activity.