NMR characterization of the Escherichia coli nitrogen regulatory protein IIANtr in solution and interaction with its partner protein, NPr

The solution form of IIA(Ntr) from Escherichia coli and its interaction with its partner protein, NPr, were characterized by nuclear magnetic resonance (NMR) spectroscopy. The diffusion coefficient of the protein (1.13 x 10(-6) cm/sec) falls between that of HPr (approximately 9 kDa) and the N-terminal domain of E. coli enzyme I (approximately 30 kDa), indicating that the functional form of IIA(Ntr) is a monomer (approximately 18 kDa) in solution. Thus, the dimeric structure of the protein found in the crystal is an artifact of crystal packing. The residual dipolar coupling data of IIA(Ntr) (covering residues 11-155) measured in the absence and presence of a 4% polyethyleneglycol-hexanol liquid crystal alignment medium fit well to the coordinates of both molecule A and molecule B of the dimeric crystal structure, indicating that the 3D structures in solution and in the crystal are indeed similar for that protein region. However, only molecule A possesses an N-terminal helix identical to that derived from chemical shifts of IIA(Ntr) in solution. Further, the (15)N heteronuclear nuclear Overhauser effect (NOE) data also support molecule A as the representative structure in solution, with the terminal residues 1-8 and 158-163 more mobile. Chemical shift mapping identified the surface on IIA(Ntr) for NPr binding. Residues Gly61, Asp115, Ser125, Thr156, and nearby regions of IIA(Ntr) are more perturbed and participate in interaction with NPr. The active-site His73 of IIA(Ntr) for phosphoryl transfer was found in the Ndelta1-H tautomeric state. This work lays the foundation for future structure and function studies of the signal transducing proteins from this nitrogen pathway.     

Dynamics of populations with individual variation in dispersal on bounded domains

Most classical models for the movement of organisms assume that all individuals have the same patterns and rates of movement (for example, diffusion with a fixed diffusion coefficient) but there is empirical evidence that movement rates and patterns may vary among different individuals. A simple way to capture variation in dispersal that has been suggested in the ecological literature is to allow individuals to switch between two distinct dispersal modes. We study models for populations whose members can switch between two different nonzero rates of diffusion and whose local population dynamics are subject to density dependence of logistic type. The resulting models are reaction–diffusion systems that can be cooperative at some population densities and competitive at others. We assume that the focal population inhabits a bounded region and study how its overall dynamics depend on the parameters describing switching rates and local population dynamics. (Traveling waves and spread rates have been studied for similar models in the context of biological invasions.) The analytic methods include ideas and results from reaction–diffusion theory, semi-dynamical systems, and bifurcation/continuation theory.     

Über neuritenähnliche intraventrikuläre Fortsätze und ihre Kontakte mit dem Ependym der Seitenventrikel der Katze

Zusammenfassung Ependym und subependymale Strukturen der Seitenventrikel von Katzen aus dem Bereich des Nucleus caudatus und des Corpus callosum wurden nach Perfusionsfixierung elektronenmikroskopisch untersucht. Dort findet sich eine Reihe von Neuritenanschnitten, deren kolbenförmige Auftreibungen leere Vesikel, dense core granula und Mitochondrien enthalten. Neben diesen neuronalen Elementen werden auch Zellfortsätze nichtneuronaler Natur im Ventrikellumen beobachtet, die Ependym- und intraventrikulären Zellen entstammen. An umschriebenen Stellen nehmen diese kolbig aufgetriebenen Fortsätze desmosomenartige Kontakte mit dem Ependym auf. An diesen Orten umgeben Mikrovilli die Fortsätze korbartig. Ob es sich bei diesen Kontakten um synapsenartige Strukturen handelt, oder um Rezeptoren für unbekannte chemische Stoffe, wird diskutiert. Die Kontakte sind unabhängig von der Form der Ependymzellen und davon, ob diesen graue oder weiße Substanz unterliegt. Zwischen und in den Ependymzellen finden sich — bedingt durch den unterschiedlichen Gehalt an Zellorganellen — drei verschiedene Arten von Fortsätzen. Die Zahl der neuronalen Fortsätze in diesem Bereich ist sehr viel kleiner als im Ventrikellumen.

---

On axon-like intraventricular processes and their contacts with ependyma of the lateral ventricles of catCorpus callosum and Nucleus caudatus

Summary Ependyma and subependymal regions of the lateral ventricles of cats (area of Nucleus caudatus and Corpus callosum) were fixed by perfusion and investigated electronmicroscopically. Intraventricular axons showing a beaded shape with smaller and thicker parts were found. The varicosities contain empty vesicles, dense core granules and mitochondria. Beside those certainly neuronal elements there exist intraventricular cell processes originating from ependymal cells and free cells. The neuronal processes make desmosome-like contacts with the ependyma. These regions of contact are surrounded by basket-like arranged microvilli. It is discussed, whether the contacts function like synapses or as receptors for a substance, which is still unknown. Contacts do not depend on the shape of ependymal cells. They exist with the ependyma of Nucleus caudatus (grey substance) as well as with the ependyma of Corpus callosum (white substance). Because of the different contents of cell-organelles one can differentiate three different sorts of processes situated inter- or intracellularly in the ependyma. Neuronal processes within the lateral ventricles are more numerous than those found within the ependymal layer.

     

磁共振灌注加权成像与弥散加权成像在脑胶质瘤分级诊断中的应用

目的:探讨磁共振灌注加权成像(perfusion weighted imaging,PWI)与弥散加权成像(diffusion weighted imaging,DWI)在脑胶质瘤分级诊断中的应用价值。方法:选取2012年1月-2017年6月在我院就诊并经病理证实为脑胶质瘤患者100例,其中高、低级别胶质瘤患者各44、56例。对所有患者行PWI、DWI检查,比较肿瘤不同区域表观扩散系数(apparent diffusion coefficient,ADC)、局部脑血流量(regional cerebral blood flow,rCBF),不同级别肿瘤实质区、瘤周水肿区rADC、rrCBF,根据ROC曲线分析rADC、rrCBF对不同级别胶质瘤的诊断阈值、敏感性、特异性。结果:与对侧相应正常脑实质比较,瘤周水肿区及肿瘤实质区ADC、rCBF均显著升高(P0.05);与瘤周水肿区比较,肿瘤实质区ADC、rCBF均显著升高(P0.05)。高级别肿瘤实质区rADC显著低于低级别肿瘤实质区(P0.05),rrCBF显著高于肿瘤实质区(P0.05)。高级别瘤周水肿区与低级别瘤周水肿区rADC间无显著差异(P0.05),高级别瘤周水肿区rrCBF显著高于低级别瘤周水肿区(P0.05)。在对高、低级别脑胶质瘤的分级中,rADC、rrCBF的曲线下面积(under the receiver operating characteristic curve,AUC)分别为0.957、0.978,均0.9。rADC诊断不同分级胶质瘤的敏感度是90.12%,特异度是95.26%,诊断阈值是13.12;rrCBF诊断不同分级胶质瘤的敏感度是92.31%,特异度是98.57%,诊断阈值是2.62。rADC与rrCBF诊断不同分级胶质瘤敏感度、特异度间无显著差异(P0.05)。结论:PWI、DWI能够为脑胶质瘤的分级诊断提供参考依据。     

磁共振成像表观扩散系数与乳腺浸润性导管癌组织学分级及预后指标的相关性研究

目的:探讨磁共振成像(MRI)表观扩散系数(ADC)与乳腺浸润性导管癌组织学分级及其预后指标的相关性。方法:收集2016年5月至2017年5月于我院就诊的并经手术病理确诊为乳腺浸润性导管癌的患者112例作为研究对象,选取患者乳腺癌组织样本作为病例组,同时选取患者对侧正常乳腺组织样本作为对照组,所有患者均行常规MRI和磁共振扩散加权成像(DW-MRI)检查,分别测量两组样本的ADC值,比较不同乳腺浸润性导管癌组织学分级与正常乳腺组织的ADC值,分析乳腺浸润性导管癌组织的ADC值与肿瘤直径大小、淋巴结转移状态、有无远处转移及雌激素受体(ER)、孕激素受体(PR)和Ki-67表达的关系,并分析ADC值与组织学分级及预后指标的相关性。结果:乳腺浸润性导管癌病理分级I级的ADC值低于对照组,病理分级II级的ADC值低于病理分级I级及对照组,病理分级III级的ADC值低于病理分级II级、I级及对照组,差异均具有统计学意义(P0.05)。乳腺浸润性导管癌患者中,肿块直径2 cm、无淋巴结转移、ER阴性、PR阴性、Ki-67阴性患者的平均ADC值均高于肿块直径≥2 cm、有淋巴结转移、ER阳性、PR阳性、Ki-67阳性患者,差异均具有统计学意义(P0.05);而有无远处转移患者之间比较差异无统计学意义(P0.05)。经Spearman秩相关分析结果显示,乳腺浸润性导管癌患者的ADC值与病理组织学分级呈现负相关关系(rs=-0.716,P=0.000);与肿块直径大小、有无淋巴结转移及ER、PR、Ki-67的表达均呈负相关(rs=-0.316、-0.545、-0.667、-0.598、-0.443,P均0.05),与有无远处转移无相关性(rs=0.091,P=0.887)。结论:乳腺浸润性导管癌的ADC值与癌组织学分级和预后相关指标存在一定相关性,可作为一种临床诊断和判断预后的重要指标,具有重要临床价值。     

Engineering of Mesoscale Pores in Balancing Mass Loading and Rate Capability of Hematite Films for Electrochemical Capacitors

Design and synthesis of metal oxide‐based pseudocapacitive materials to simultaneously achieve high mass loading (e.g., up to 10 mg cm^?2) and excellent rate capability for electrochemical capacitors is a long‐lasting challenge. These two characteristics are usually mutually exclusive due to the poor ion diffusion kinetics of most metal oxides. Here, a glucose‐assisted hydrothermal method to prepare thick hematite film (>1 µm) with engineerable mesopore size through controlled variation of glucose concentration is demonstrated. The capability of controlling the size of mesopores offers a unique opportunity to investigate for the first time the interplay between mesopore size and electrochemical performance of hematite films. The hematite film with an average mesopore size of 3 nm at an ultrahigh loading of 10 mg cm^?2 exhibits an areal capacitance of 1502 mF cm^?2 at 1 mA cm^?2, and retains 871.2 mF cm^?2 at 50 mA cm^?2. Such performance, to the best of the authors' knowledge, is at the top of the reported hematite electrodes with comparable or even lower mass loadings. The strategy demonstrated herein may be extended to fabricate diverse types of mesoporous metal oxide architectures with improved ion diffusion kinetics, which is critical for a broad range of devices for energy storage and conversion.     

Carbon Nitride/Reduced Graphene Oxide Film with Enhanced Electron Diffusion Length: An Efficient Photo‐Electrochemical Cell for Hydrogen Generation

Polymeric carbon nitride (CN) has emerged as a promising semiconductor for energy‐related applications. However, its utilization in photo‐electrochemical cells is still very limited owing to poor electron–hole separation efficiency, short electron diffusion length, and low absorption coefficient. Here the synthesis of a highly porous carbon nitride/reduced graphene oxide (CN‐rGO) film with good photo‐electrochemical properties is reported. The CN‐rGO film exhibits long electron diffusion length and high electrochemical active surface area, good charge separation, and enhanced light‐harvesting properties. The film displays a 20‐fold enhancement of photocurrent density over pristine CN, reaching up to 75 µA cm^?2 at 1.23 V versus reversible hydrogen electrode (RHE) in an alkaline solution, as well as stability over a wide pH range. Photocurrent measurements with a hole scavenger reveal a photocurrent density of 660 µA cm^?2 at 1.23 V versus RHE and a quantum efficiency of 60% at 400 nm, resulting in the production of 0.8 mol h^?1 g^?1 of hydrogen. The substantial photo‐electrochemical activity enhancement and hydrogen production together with the low price, high electrochemical surface area, long electron diffusion length, stability under harsh condition, and tunable photophysical properties of CN materials open many possibilities for their utilization in (photo)electrochemical and electronic devices.     

Revising the Concept of Pore Hierarchy for Ionic Transport in Carbon Materials for Supercapacitors

Rapid motion of electrolyte ions is a crucial requirement to ensure the fast charging/discharging and the high power densities of supercapacitor devices. This motion is primarily determined by the pore size and connectivity of the used porous carbon electrodes. Here, the diffusion characteristics of each individual electrolyte component, that is, anion, cation, and solvent confined to model carbons with uniform and well‐defined pore sizes are quantified. As a result, the contributions of micropores, mesopores, and hierarchical pore architectures to the overall transport of adsorbed mobile species are rationalized. Unexpectedly, it is observed that the presence of a network of mesopores, in addition to smaller micropores—the concept widely used in heterogeneous catalysis to promote diffusion of sorbates—does not necessarily enhance ionic transport in carbon materials. The observed phenomenon is explained by the stripping off the surrounding solvent shell from the electrolyte ions entering the micropores of the hierarchical material, and the resulting enrichment of solvent molecules preferably in the mesopores. It is believed that the presented findings serve to provide fundamental understanding of the mechanisms of electrolyte diffusion in carbon materials and depict a quantitative platform for the future designing of supercapacitor electrodes on a rational basis.     

Fast Diffusion of Multivalent Ions Facilitated by Concerted Interactions in Dual‐Ion Battery Systems

Sluggish solid‐phase diffusion has been an essential issue in developing intercalation electrode materials using multivalent ions. Compared to monovalent Li ions, the diffusion of multivalent ions is still not well understood. Here, combining first‐principles calculations with electrochemical experiments, it is shown that the diffusion of divalent Mg ions is significantly facilitated in Li–Mg dual‐ion systems, and the activation energy is remarkably reduced by the concerted interactions of the preceding Li ions and following Mg ions. Thus, making dual‐ion systems is a promising way to construct high‐energy‐density, rechargeable batteries with multivalent ions. This work will provide a new perspective on solid‐phase diffusion that is typically a rate‐controlling process in battery systems and fuel cell devices.