G protein‐coupled estrogen receptor‐mediated effects on cytosolic calcium and nanomechanics in brain microvascular endothelial cells

G protein‐coupled estrogen receptor (GPER) is a relatively recently identified non‐nuclear estrogen receptor, expressed in several tissues, including brain and blood vessels. The mechanisms elicited by GPER activation in brain microvascular endothelial cells are incompletely understood. The purpose of this work was to assess the effects of GPER activation on cytosolic Ca²⁺ concentration, [Ca²⁺]_i, nitric oxide production, membrane potential and cell nanomechanics in rat brain microvascular endothelial cells (RBMVEC). Extracellular but not intracellular administration of G‐1, a selective GPER agonist, or extracellular administration of 17‐β‐estradiol and tamoxifen, increased [Ca²⁺]_i in RBMVEC. The effect of G‐1 on [Ca²⁺]_i was abolished in Ca²⁺‐free saline or in the presence of a L‐type Ca²⁺ channel blocker. G‐1 increased nitric oxide production in RBMVEC; the effect was prevented by NG‐nitro‐l ‐arginine methyl ester. G‐1 elicited membrane hyperpolarization that was abolished by the antagonists of small and intermediate‐conductance Ca²⁺‐activated K⁺ channels, apamin, and charibdotoxin. GPER‐mediated responses were sensitive to G‐36, a GPER antagonist. In addition, atomic force microscopy studies revealed that G‐1 increased the modulus of elasticity, indicative of cytoskeletal changes and increase in RBMVEC stiffness. Our results unravel the mechanisms underlying GPER‐mediated effects in RBMVEC with implications for the effect of estrogen on cerebral microvasculature.

     

Does whole‐organism performance constrain resource use? A community test with desert lizards

Discovering the mechanisms by which communities of co‐existing species exist has proven to be one of the greatest challenges for evolutionary ecologists. A recent perspective emphasizes the role of functional traits, such as whole‐organism performance, as key limiting factors in the evolution of communities, yet few studies have examined this possibility. We examine how bite force and morphology influence the ability of ten lizard species in a single community to access insect prey, as defined by prey type and prey hardness. We gathered over 3 years of data from a desert lizard community comprised of ten species and found significant variation among species for bite force and prey hardness, as well as significant differences in performance and niche breadth for each species. In general, higher levels of absolute bite force broadens resource accessibility (sizes of prey), and does not generally result in a reduced ability to access smaller prey. For example, large lizard species that are hard biters can still consume soft prey. On the other hand, small lizard species that are weak biters are more limited in their ability to access hard prey, although the overall decline in resource accessibility is modest. Our findings highlight how functional traits can influence which species can access key resources within a community of similar species. © 2015 The Linnean Society of London, Biological Journal of the Linnean Society, 2015, ●● , ●●–●●.     

Influence of force fields on the selective diffusion of para-xylene over ortho-xylene in 10-ring zeolites

A molecular dynamics study of diffusion of p-xylene and o-xylene has been performed over three different pure silica 10-ring zeolites, MFI, SFG and TUN. The shape selective properties of the frameworks of these three materials have been tested using four different types of force fields commonly used based on united atom, rigid-ion and core-shell approximations. The performance of each force field is analysed in order to find which force fields can give sufficiently accurate estimations that allow to select appropriate zeolites for selective separation of para/ortho xylene. This performance was found to depend on the quality of the structural properties of the zeolite, in particular the size and shape of the 10 rings which act as bottlenecks for the diffusion. The computational results allow us to define some optimum characteristics for the selective diffusion of p-xylene.     

Effective potentials between gold nano crystals – functional dependence on temperature

A method is presented that allows to combine the effective potential between two nano crystals (NC), the potential of mean force (PMF), as obtained from all-atomistic molecular dynamics simulations with perturbation theory. In this way, a functional dependence of the PMF on temperature is derived, which enables the prediction of the PMF in a wide temperature range. We applied the method to systems of capped gold NCs of different size. They show very good agreement with data from atomistic simulations.     

汉防己甲素联合顺铂对乳腺癌细胞的作用

目的:汉防己甲素和顺铂联合作用乳腺癌细胞,来提高癌细胞对顺铂的敏感性.方法:运用原子力显微镜对乳腺癌细胞表面的超微结构进行表征;MTr法和流式细胞术检测细胞的生长抑制率和细胞周期变化.结果:顺铂和汉防己甲素分别作用乳腺癌细胞48h IC50值为26.33μmoL/l和5.6μmok/l;联合用药组的IC50值为汉防己甲素2.5μmol/L和顺铂13.32μmol/l,在低浓度的联合用药作用乳腺癌细胞24h细胞膜表面结构被破坏,产生孔洞,作用48h被严重破坏使细胞周期在S比例增加为51.7%±0.30%.结论:提高了癌细胞对抗癌药物的敏感性,联合用药通过改变了细胞膜的结构对癌细胞进行有效杀伤,抑制肿瘤细胞生长.     

d-Ribose glycates β2-microglobulin to form aggregates with high cytotoxicity through a ROS-mediated pathway

β₂-Microglobulin (β₂M) modified with advanced glycation end products (AGEs) is a major component of the amyloid deposits in hemodialysis-associated amyloidosis (HAA). However, the effect of glycation on the misfolding and aggregation of β₂M has not been studied so far. Here we examine the molecular mechanism of aggregate formation of HAA-related ribosylated β₂M in vitro. We find that the glycating agent d-ribose interacts with human β₂M to generate AGEs that form aggregates in a time-dependent manner. Ribosylated β₂M molecules are highly oligomerized compared with unglycated β₂M, and have granular morphology. Furthermore, such ribosylated β₂M aggregates show significant cytotoxicity to both human SH-SY5Y neuroblastoma and human foreskin fibroblast FS2 cells and induce intracellular reactive oxygen species (ROS). Presence of the antioxidant N-acetylcysteine (1.0 mM) attenuated intracellular ROS and prevented cell death induction in both SH-SY5Y and FS2 cells, indicating that the cytotoxicity of ribosylated β₂M aggregates depends on a ROS-mediated pathway in both cell lines. In other words, d-ribose reacts with β₂M and induces the ribosylated protein to form granular aggregates with high cytotoxicity through a ROS-mediated pathway. These findings suggest that ribosylated β₂M aggregates could contribute to the dysfunction and death of cells and could play an important role in the pathogenesis of β₂M-associated diseases such as HAA.     

In situ measurement of cell stiffness of Arabidopsis roots growing on a glass micropillar support by atomic force microscopy

Atomic force microscopy (AFM) can measure the mechanical properties of plant tissue at the cellular level, but for in situ observations, the sample must be held in place on a rigid support and it is difficult to obtain accurate data for living plants without inhibiting their growth. To investigate the dynamics of root cell stiffness during seedling growth, we circumvented these problems by using an array of glass micropillars as a support to hold an Arabidopsis thaliana root for AFM measurements without inhibiting root growth. The root elongated in the gaps between the pillars and was supported by the pillars. The AFM cantilever could contact the root for repeated measurements over the course of root growth. The elasticity of the root epidermal cells was used as an index of the stiffness. By contrast, we were not able to reliably observe roots on a smooth glass substrate because it was difficult to retain contact between the root and the cantilever without the support of the pillars. Using adhesive to fix the root on the smooth glass plane overcame this issue, but prevented root growth. The glass micropillar support allowed reproducible measurement of the spatial and temporal changes in root cell elasticity, making it possible to perform detailed AFM observations of the dynamics of root cell stiffness.     

Small diameter blood vessels with controllable micropore structure induced by centrifugal force for improved endothelialization

The micropore structure is prerequisite for fast and durable endothelialization of artificial small diameter blood vessels (ASDBVs). Although some methods, such as salt leaching, coagulation, and electrospinning, have been developed to construct micropores for ASDBVs, the uncontrollability of the structure and the complicated procedures of the process are still the issues to be concerned about. In this study, a compact device based on the principle of centrifugal force is established and used to prepare polyurethane (PU) ASDBVs with micropore structures by blasting different porogens. It is found that the glass beads could construct micropores with regular round shape, uniform distribution, and controllable size (60–350 µm), which significantly improves the endothelialization of PU‐based ASDBVs, especially when the pore size is about 60 µm. This method is easy‐accessible and wide‐applicable, which provides a new pathway for the research and development of ASDBVs.