DNA framework-engineered electrochemical biosensors

Self-assembled DNA nanostructures have shown remarkable potential in the engineering of biosensing interfaces, which can improve the performance of various biosensors. In particular, by exploiting the structural rigidity and programmability of the framework nucleic acids with high precision, molecular recognition on the electrochemical biosensing interface has been significantly enhanced, leading to the development of highly sensitive and specific biosensors for nucleic acids, small molecules,proteins, and cells. In this review, we summarize recent advances in DNA framework-engineered biosensing interfaces and the application of corresponding electrochemical biosensors.     

Berberine ameliorates cellular senescence and extends the lifespan of mice via regulating p16 and cyclin protein expression

Although aging and senescence have been extensively studied in the past few decades, however, there is lack of clinical treatment available for anti‐aging. This study presents the effects of berberine (BBR) on the aging process resulting in a promising extension of lifespan in model organisms. BBR extended the replicative lifespan, improved the morphology, and boosted rejuvenation markers of replicative senescence in human fetal lung diploid fibroblasts (2BS and WI38). BBR also rescued senescent cells with late population doubling (PD). Furthermore, the senescence‐associated β‐galactosidase (SA‐β‐gal)‐positive cell rates of late PD cells grown in the BBR‐containing medium were ~72% lower than those of control cells, and its morphology resembled that of young cells. Mechanistically, BBR improved cell growth and proliferation by promoting entry of cell cycles from the G₀ or G₁ phase to S/G₂‐M phase. Most importantly, BBR extended the lifespan of chemotherapy‐treated mice and naturally aged mice by ~52% and ~16.49%, respectively. The residual lifespan of the naturally aged mice was extended by 80%, from 85.5 days to 154 days. The oral administration of BBR in mice resulted in significantly improved health span, fur density, and behavioral activity. Therefore, BBR may be an ideal candidate for the development of an anti‐aging medicine.     

浙江省葡萄属野生葡萄资源调查与开发利用研究

浙江是中国野生葡萄属资源分布较广泛、种类较多的地区之一,但对野生葡萄属资源的深入研究和合理开发利用不多。我们在野外调查和民间走访的基础上,结合查询文献资料,分析浙江境内野生葡萄资源的特点,并提出野生葡萄资源创新利用的思路。     

The asymmetric relationships of the distribution of conspecific saplings and adults in forest fragments

随着土地利用方式变化的加剧,生境片段化已成为影响植物多样性的主要因子之一。通常,当成年树个体的密度越高,其周边同种幼树个体的存活率可能会下降,从而为其它物种提供了空间和资源,进而可以维持较高的局域物种多样性。因此,同种成年树和幼树个体的空间分布格局关系和作用强度可以调节植物多样性。然而,对于在片段化森林中,同种成年树和幼树个体空间分布关系的研究却很少报道,迄今尚不清楚片段化景观中同种个体的空间分布关系与物种多样性之间的联系。本研究选择千岛湖陆桥岛屿系统中的27个岛屿,基于岛屿上幼树和成年树个体的空间分布数据,利用混合效应模型分析它们之间的作用强度。同种幼树和成年树个体的空间作用强度越大,说明它们之间的负相互作用越强,即幼树和成年树个体空间分布越分散。此外,本研究分析了岛屿属性(岛屿面积、与大陆的距离和与最近岛屿的距离)与同种个体空间作用强度及物种多样性之间的关系。结果表明,同种个体的空间作用强度随着与最近岛屿距离的增加而增加。同时,物种多样性随着同种个体的空间作用强度的增加而显著增加,且岛屿面积和同种个体的空间作用强度分别解释了岛屿间物种多样性差异的26%和6%,共同解释了8%。耐阴种和非常见种比非耐阴种和常见种的同种幼树和成年树的空间分布更为分散。本研究表明,同种个体的空间分布可能会影响多度较低物种在片段化森林中的生存,反映了生物相互作用对于维持片段化森林中的植物多样性具有重要作用。 本研究也强调在检验同种密度制约时应考虑森林之间的连接度。