国产萱草属夜间开花类群的分类研究

在《中国植物志》第14卷中,萱草属Hemerocallis夜间开花类群被处理为3个独立的物种,北黄花菜、黄花菜和小黄花菜。但是,它们之间因严重的性状重叠和交叉,用单个性状如花数、花被管长度、根的直径等区分它们极为困难。本文根据国产干标本和栽培材料,对9个常用检索性状以及核型做了定量分析。另外,这3个类群的地理分布式样表明,它们似乎是不同的地理宗,因为三者替代性分布在由暖湿到旱冷的气候梯度中。本文结论是,将三者处理为同一物种北黄花菜的3个亚种也许更令人信服,即原亚种北黄花菜,亚种黄花菜和亚种小黄花菜。     

Nitric Oxide Mediates Root K+/Na+ Balance in a Mangrove Plant,Kandelia obovata,by Enhancing the Expression of AKT1-Type K+ Channel and Na+/H+ Antiporter under High Salinity

It is well known that nitric oxide (NO) enhances salt tolerance of glycophytes. However, the effect of NO on modulating ionic balance in halophytes is not very clear. This study focuses on the role of NO in mediating K⁺/Na⁺ balance in a mangrove species, Kandelia obovata Sheue, Liu and Yong. We first analyzed the effects of sodium nitroprusside (SNP), an NO donor, on ion content and ion flux in the roots of K. obovata under high salinity. The results showed that 100 μM SNP significantly increased K⁺ content and Na⁺ efflux, but decreased Na⁺ content and K⁺ efflux. These effects of NO were reversed by specific NO synthesis inhibitor and scavenger, which confirmed the role of NO in retaining K⁺ and reducing Na⁺ in K. obovata roots. Using western-blot analysis, we found that NO increased the protein expression of plasma membrane (PM) H⁺-ATPase and vacuolar Na⁺/H⁺ antiporter, which were crucial proteins for ionic balance. To further clarify the molecular mechanism of NO-modulated K⁺/Na⁺ balance, partial cDNA fragments of inward-rectifying K⁺ channel, PM Na⁺/H⁺ antiporter, PM H⁺-ATPase, vacuolar Na⁺/H⁺ antiporter and vacuolar H⁺-ATPase subunit c were isolated. Results of quantitative real-time PCR showed that NO increased the relative expression levels of these genes, while this increase was blocked by NO synthesis inhibitors and scavenger. Above results indicate that NO greatly contribute to K⁺/Na⁺ balance in high salinity-treated K. obovata roots, by activating AKT1-type K⁺ channel and Na⁺/H⁺ antiporter, which are the critical components in K⁺/Na⁺ transport system.     

杆状病毒转导不同哺乳动物骨髓来源间充质干细胞

杆状病毒作为一种新型基因载体,若能有效转导不同哺乳动物骨髓来源间充质干细胞(bone marrow-derived mesenchymal stem cells, BMSCs),将会成为干细胞基因修饰研究领域中更理想的一种基因载体.本文探讨了重组杆状病毒(BacV-CMV-EGFP)对不同哺乳动物BMSCs的转导效率.体外原代培养小鼠、大鼠、猪、恒河猴及人的BMSCs.用培养3代以上的哺乳动物BMSCs进行病毒转导实验,转导2d后用倒置荧光显微镜观察绿色荧光蛋白在不同哺乳动物BMSCs中的表达,并用流式细胞仪检测重组杆状病毒对不同哺乳动物BMSCs的转导效率.结果显示:原代培养的小鼠、大鼠、猪、恒河猴及人的BMSCs于体外传代3次以上后,细胞呈现较均一的梭形,漩涡状生长;倒置荧光显微镜观察显示,与小鼠、大鼠、猪的BMSCs相比,恒河猴及人有更多BMSCs表达绿色荧光蛋白,且荧光强度较强;杆状病毒对小鼠、大鼠、猪、恒河猴及人的BMSCs的转导效率分别为(21.21±3.02)%、(22.51±4.48)%、(39.13±5.79)%、(71.16±5.36)%及(70.67±3.74)%.上述结果表明,重组杆状病毒对不同哺乳动物BMSCs的转导效率不同,对恒河猴及人的BMSCs转导效率较高,说明重组杆状病毒可作为人或灵长类动物BMSCs基因修饰研究领域中更理想的基因载体.     

Genistein-3′-sodium sulfonate Attenuates Neuroinflammation in Stroke Rats by Down-Regulating Microglial M1 Polarization through α7nAChR-NF-κB Signaling Pathway

Microglial M1 depolarization mediated prolonged inflammation contributing to brain injury in ischemic stroke. Our previous study revealed that Genistein-3′-sodium sulfonate (GSS) exerted neuroprotective effects in ischemic stroke. This study aimed to explore whether GSS protected against brain injury in ischemic stroke by regulating microglial M1 depolarization and its underlying mechanisms. We established transient middle cerebral artery occlusion and reperfusion (tMCAO) model in rats and used lipopolysaccharide (LPS)-stimulated BV2 microglial cells as in vitro model. Our results showed that GSS treatment significantly reduced the brain infarcted volume and improved the neurological function in tMCAO rats. Meanwhile, GSS treatment also dramatically reduced microglia M1 depolarization and IL-1β level, reversed α7nAChR expression, and inhibited the activation of NF-κB signaling in the ischemic penumbra brain regions. These effects of GSS were further verified in LPS-induced M1 depolarization of BV2 cells. Furthermore, pretreatment of α7nAChR inhibitor (α-BTX) significantly restrained the neuroprotective effect of GSS treatment in tMCAO rats. α-BTX also blunted the regulating effects of GSS on neuroinflammation, M1 depolarization and NF-κB signaling activation. This study demonstrates that GSS protects against brain injury in ischemic stroke by reducing microglia M1 depolarization to suppress neuroinflammation in peri-infarcted brain regions through upregulating α7nAChR and thereby inhibition of NF-κB signaling. Our findings uncover a potential molecular mechanism for GSS treatment in ischemic stroke.     

An Optimal Free Energy Dissipation Strategy of the MinCDE Oscillator in Regulating Symmetric Bacterial Cell Division

Sustained molecular oscillations are ubiquitous in biology. The obtained oscillatory patterns provide vital functions as timekeepers, pacemakers and spacemarkers. Models based on control theory have been introduced to explain how specific oscillatory behaviors stem from protein interaction feedbacks, whereas the energy dissipation through the oscillating processes and its role in the regulatory function remain unexplored. Here we developed a general framework to assess an oscillator’s regulation performance at different dissipation levels. Using the Escherichia coli MinCDE oscillator as a model system, we showed that a sufficient amount of energy dissipation is needed to switch on the oscillation, which is tightly coupled to the system’s regulatory performance. Once the dissipation level is beyond this threshold, unlike stationary regulators’ monotonic performance-to-cost relation, excess dissipation at certain steps in the oscillating process damages the oscillator’s regulatory performance. We further discovered that the chemical free energy from ATP hydrolysis has to be strategically assigned to the MinE-aided MinD release and the MinD immobilization steps for optimal performance, and a higher energy budget improves the robustness of the oscillator. These results unfold a novel mode by which living systems trade energy for regulatory function.     

Karyotyping Human Chromosomes by Optical and X-Ray Ptychography Methods

Sorting and identifying chromosomes, a process known as karyotyping, is widely used to detect changes in chromosome shapes and gene positions. In a karyotype the chromosomes are identified by their size and therefore this process can be performed by measuring macroscopic structural variables. Chromosomes contain a specific number of basepairs that linearly correlate with their size; therefore, it is possible to perform a karyotype on chromosomes using their mass as an identifying factor. Here, we obtain the first images, to our knowledge, of chromosomes using the novel imaging method of ptychography. We can use the images to measure the mass of chromosomes and perform a partial karyotype from the results. We also obtain high spatial resolution using this technique with synchrotron source x-rays.