Insulin-producing cells from human adipose tissue-derived mesenchymal stem cells detected by atomic force microscope

We successfully differentiated human adipose tissue-derived mesenchymal stem cells (haMSCs) into insulin-producing cells (IPCs) in vitro and did not use any insulin which might be absorbed by cells during in vitro culture. Expression of insulin gene was massively increased by 28,000-fold at day 12 compared with haMSCs (P < 0.05). IPCs could secrete insulin after glucose was stimulated. The higher the concentration of glucose, the more production of insulin was noted. We reported AFM images of IPCs for the first time. AFM images showed that the sizes of cells were similar to each other, and all IPC surface had a porous structure in the cytoplasm area. In sugar-free group, the size of holes was similar (diameter, 1,086.98 ± 156.70 nm; depth, 185.22 ± 52.14 nm). In higher sugar-stimulated group, there were more holes with bigger diameter and smaller depth. (diameter, 3,183.65 ± 2,229.18 nm; depth 109.42 ± 56.26 nm, P < 0.05). We found that the hole diameter and depth could change with the concentration of glucose in media. Concurrently, laser scanning confocal microscopy images indicated that cortical actin network beneath plasma membrane in IPCs was dense and continuous. After glucose stimulation, we found the actin web depolymerized and became discontinuous in IPCs. We speculated that diameter augmentation of holes located in the cytoplasm area in IPCs was one manifestation of excytosis increase.     

Age-Dependent Changes in the Sphingolipid Composition of Mouse CD4+ T Cell Membranes and Immune Synapses Implicate Glucosylceramides in Age-Related T Cell Dysfunction

To determine whether changes in sphingolipid composition are associated with age-related immune dysfunction, we analyzed the core sphingolipidome (i.e., all of the metabolites through the first headgroup additions) of young and aged CD4⁺ T cells. Since sphingolipids influence the biophysical properties of membranes, we evaluated the compositions of immune synapse (IS) and non-IS fractions prepared by magnetic immuno-isolation. Broadly, increased amounts of sphingomyelins, dihydrosphingomyelins and ceramides were found in aged CD4⁺ T cells. After normalizing for total sphingolipid content, a statistically significant decrease in the molar fraction of glucosylceramides was evident in both the non-IS and IS fractions of aged T cells. This change was balanced by less dramatic increases in the molar fractions of sphingomyelins and dihydrosphingomyelins in aged CD4⁺ T cells. In vitro, the direct or enzymatic enhancement of ceramide levels decreased CD4⁺ T cell proliferation without regard for the age of the responding T cells. In contrast, the in vitro inhibition of glucosylceramidase preferentially increased the proliferation of aged CD4⁺ T cells. These results suggest that reductions in glucosylceramide abundance contribute to age-related impairments in CD4⁺ T cell function.     

Improvement of landfill leachate biodegradability with ultrasonic process

Landfills leachates are known to contain recalcitrant and/or non-biodegradable organic substances and biological processes are not efficient in these cases. A promising alternative to complete oxidation of biorecalcitrant leachate is the use of ultrasonic process as pre-treatment to convert initially biorecalcitrant compounds to more readily biodegradable intermediates. The objectives of this study are to investigate the effect of ultrasonic process on biodegradability improvement. After the optimization by factorial design, the ultrasonic were applied in the treatment of raw leachates using a batch wise mode. For this, different scenarios were tested with regard to power intensities of 70 and 110 W, frequencies of 30, 45 and 60 KHz, reaction times of 30, 60, 90 and 120 minutes and pH of 3, 7 and 10. For determining the effects of catalysts on sonication efficiencies, 5 mg/l of TiO(2) and ZnO have been also used. Results showed that when applied as relatively brief pre-treatment systems, the sonocatalysis processes induce several modifications of the matrix, which results in significant enhancement of its biodegradability. For this reason, the integrated chemical-biological systems proposed here represent a suitable solution for the treatment of landfill leachate samples.     

Contamination level and human health hazard assessment of heavy metals and polycyclic aromatic hydrocarbons (PAHs) in street dust deposited in Mahshahr,southwest of Iran

Mahshahr has a strategic position and is considered as industrial hub of Iran. Selected heavy metals and polycyclic aromatic hydrocarbons (PAHs) contamination and health risk, and the mineralogical composition of street dust from Mahshahr were investigated. Results indicated that geology is the main determinant of the dust mineralogical composition. Calculated enrichment factor (EF) and principal component analysis (PCA) showed that Pb, Hg, Zn, and Cu accumulations are greatly influenced by anthropogenic sources including traffic and industry. High heavy metals content poses great ecological risk in the study area and exposure doses revealed that ingestion is the main exposure route to street dust, especially for children in residential/commercial areas. It was found that the total amount of PAHs (∑PAHs) varies from 161 to 1996 µg/kg, dominated by four-ring PAHs. Diagnostic ratios and PCA showed that both petrogenic and pyrogenic sources of PAHs in Mahshahr street dust and traffic play important roles in this respect. Furthermore, toxic equivalents and incremental lifetime cancer risk of PAHs in street dust indicated a high potential carcinogenic risk for inhabitants mainly via dermal contact and ingestion pathways particularly for outdoor workers in industrial use scenario. Finally, distribution maps of total hazard index of heavy metals and cancer risk of PAHs indicated the most impacted zones for different groups and use scenarios.     

鲸类二次水生生境适应Epac1和Epac2基因的分子进化

心率即心脏跳动的速度,不仅反映了心脏的功能,还与寿命的长短及能量代谢有关。与大多数陆生哺乳动物相比,鲸类心率显著降低。降低的心率有助于鲸类寿命的延长及能量的高效利用,便于其适应极端的海洋环境,而这一适应的分子机制尚不清楚。鉴于此,本研究采用基于最大似然法的枝模型、枝位点模型结合蛋白质功能差异分析等方法,对控制心率的环状腺苷酸结合蛋白（Epac1 和Epac2）基因进行适应性探究。分析结果表明,Epac1在长寿鲸类即须鲸类和抹香鲸（Physeter macrocephalus）组合进化支中检测到加速进化过程,且枝位点模型在须鲸类祖先支中检测到的强烈的正选择位点均位于功能重要的催化区;另外,该蛋白质在鲸类中还发生了显著的功能修饰（θ=0.5296 ± 0.1300;P<0.001）。对Epac2进行相同的分析发现,该基因在寿命长达200年之久的弓头鲸（Balaena mysticetus）中检测到的正选择位点同样位于功能重要的催化区。上述结果提示Epac1和Epac2在鲸类中均产生了适应性进化,这一方面可能有助于鲸类心率降低,另一方面也可能与其较长的寿命及高效的能量利用有关。     

Imidazole-Bearing Polymeric Micelles for Enhanced Cellular Uptake,Rapid Endosomal Escape,and On-demand Cargo Release

The complex design of multifunctional nanomedicine is beneficial to overcome the multiple biological barriers of drug delivery, but it also presents additional hurdles to clinical translation (e.g., scaling-up and quality control). To address this dilemma, we employed a simple imidazole-bearing polymer micelle for enhanced cellular uptake, facilitated endosomal escape, and on-demand release of a model drug, SN-38. The micelles were crosslinked by the reversible imidazole/Zn²⁺ coordination with a drug loading of ca. 4% (w/w) and a diameter less than 200 nm. Under mimicked tumor microenvironment (pH 6.8), the surface charge of micelles reversed from negative to positive, leading to enhanced micelles uptake by model 4T1 cells. Such effect was verified by fluorescent labelling of micelles. Compared to imidazole-free nanocarriers, the charge-reversal micelles delivered significantly more SN-38 to 4T1 cells. Due to the proton sponge effect, imidazole-bearing micelles could rapidly escape from endosomes compared to the control micelles, as evidenced by the kinetic analysis of micelle/endosome co-localization. The coordination crosslinking also enabled the acid-triggered drug release. This work provides a “three birds with one stone” approach to achieve the multifunctionality of nanocarriers without complicated particle design, and opens new avenues of advancing nanomedicine translation via simple tailored nanocarriers.     

Photochemical and electrophysical production of radicals on millisecond timescales to probe the structure, dynamics and interactions of proteins.

The reaction of hydroxyl and other oxygen-based radicals with the side chains of proteins on millisecond timescales has been used to probe the structure of proteins, their dynamics in solution and interactions with other macromolecules. Radicals are generated in high flux within microseconds from synchrotron radiation and discharge sources and react with proteins on timescales that are less than those often attributed to structural reorganisation and folding. The oxygen-based radicals generated in aqueous solution react with proteins to effect limited oxidation at specific amino acids throughout the sequence of the protein. The extent of oxidation at these residue markers is highly influenced by the accessibility of the reaction site to the bulk solvent. The extent of oxidation allows protection levels to be measured based on the degree to which a reaction occurs. A map of a protein's three-dimensional structure is subsequently assembled as in a footprinting experiment. Protein solutions that contain various concentrations of substrates that either promote or disrupt structural transitions can be investigated to facilitate site-specific equilibrium and time-resolved studies of protein folding. The radical-based strategies can also be employed in the study of protein-protein interactions to provide a new avenue for investigating protein complexes and assemblies with high structural resolution. The urea-induced unfolding of apomyoglobin, and the binding domains within the ribonuclease S and calmodulin-melittin protein-peptide complexes are presented to illustrate the approach.     

Age-associated increase in PGE2 synthesis and COX activity in murine macrophages is reversed by vitamin E

We previouslyshowed that increased macrophage andPGE₂ production with age is due toenhanced cyclooxygenase (COX) activity and COX-2 expression. This studydetermined the effect of vitamin E supplementation on macrophagePGE₂ synthesis in young and old mice and its underlying mechanism. Mice were fed 30 or 500 parts permillion vitamin E for 30 days. Lipopolysaccharide (LPS)-stimulated macrophages from old mice produced significantly morePGE₂ than those from young mice.Vitamin E supplementation reversed the increasedPGE₂ production in old mice buthad no effect on macrophage PGE₂production in young mice. In both LPS-stimulated and unstimulated macrophages, COX activity was significantly higher in old than in youngmice at all intervals. Vitamin E supplementation completely reversedthe increased COX activity in old mice to levels comparable to those ofyoung mice but had no effect on macrophage COX activity of young miceor on COX-1 and COX-2 protein or COX-2 mRNA expression in young or oldmice. Thus vitamin E reverses the age-associated increase in macrophagePGE₂ production and COX activity.Vitamin E exerts its effect posttranslationally, by inhibiting COXactivity.

     

Unveiling the Microscopic Origin of Irreversible Capacity Loss of Hard Carbon for Sodium-Ion Batteries

The primary bottleneck hindering the application of hard carbon in sodium-ion batteries (SIBs) anodes lies in its inadequate initial Coulombic efficiency (ICE). Unclear causes of capacity loss at the microscopic level restrict the improvement of hard carbon anodes. Here, two pivotal stages that influence the structure and composition of hard carbon, namely synthesis, and storage are evaluated; subsequently identifying crucial determinants contributing to irreversible capacity loss. The results suggest that undergrown carbon layers allowing the intrusion of solvent molecules into the interior of the hard carbon is a key factor during the synthesis stage, while the gradual formation of oxygen-containing functional groups on the surface of the hard carbon is another factor leading to irreversible loss of capacity during storage stage. This research microscopically clarifies the irreversible capacity loss mechanism on hard carbon and provides guidelines for designing and applying high ICE hard carbon for SIBs.