Conformational stability of triazolyl functionalized collagen triple helices

Functionalized collagen is attractive for the development of synthetic biomaterials. Herein we present the functionalization of azidoproline containing collagen model peptides with various alkynes using click chemistry. The influence on the stability of the collagen triple helix of the stereochemistry of the introduced triazolyl prolines (4R or 4S), the position of their incorporation (Xaa or Yaa) and the substituents attached to them are shown. The results provide a useful guide for the optimal functionalization of collagen using click chemistry.     

由细胞质雄性不育系（CMS）配制的小麦F1杂种优势形成机理的比较蛋白质组分析

分别以苗期（分蘖）、拔节期、抽穗期叶片和花粉母细胞减数分裂期、小孢子双—三核期、花粉粒时期的花药为材料,对由小麦CMS与恢复系杂交F1杂种优势形成机理作了比较蛋白质组分析。结果表明,F1杂种中有超亲、亲二型和低亲三种蛋白质表达类型出现,出现频率为亲二型＞低亲＞超亲。对这三种类型共17个蛋白质斑点作了质谱分析,其功能涉及DNA和蛋白质合成、能量代谢、环境防御,基因转座及光合作用等。苗期生长特性如叶鲜重、叶干重、叶片数,F1杂种倾向于双亲,没有观察到杂种优势现象,这与F1叶片中蛋白质表达多数呈亲二型相吻合。但F1中分蘖数多于双亲,因此其总鲜重、干重、总叶片数明显呈现出杂种优势,然而这种杂种优势现象与蛋白质组的变化是否有关需进一步研究。     

大麦主栽品种亲缘系数和对叶斑病的抗性分析

为明确我国大麦主栽品种的遗传多样性及其对叶斑病的抗性来源,采用亲缘系数(COP,coefficient of parentage)分析方法对155个主栽大麦品种的遗传系谱进行聚类分析,同时对其中79个供试大麦品种在苗期和成株期分别接种2个强毒性菌株进行抗性鉴定。结果显示,155个品种聚为6个类群,有亲缘关系的品种占全部品种14.77%。在品种间组成的11935个组合中,1763个组合间存在亲缘关系,其COP值变化范围在0~0.7500之间,亲缘系数总和为157.5867,平均值为0.0132。根据系谱分析发现了不同育种单位所育品种的核心亲本,并追溯其主要的祖先亲本。此外,通过对叶斑病的抗性鉴定,发现大多数供试的大麦品种感叶斑病,高抗品种主要集中在垦啤麦系列品种和蒙啤麦3号,部分华大麦和驻大麦系列的品种在苗期或成株期中抗叶斑病。系谱分析及抗性鉴定结果揭示了我国大麦叶斑病抗性基因存在不同来源,分析结果有利于提高抗叶斑病基因筛选效率和缩小筛选范围,也将促进抗叶斑病新基因资源的发掘和利用。     

Low‐Temperature Solution‐Based Phosphorization Reaction Route to Sn4P3/Reduced Graphene Oxide Nanohybrids as Anodes for Sodium Ion Batteries

Different from previously reported mechanical alloying route to synthesize Sn _x P₃, novel Sn₄P₃/reduced graphene oxide (RGO) hybrids are synthesized for the first time through an in situ low‐temperature solution‐based phosphorization reaction route from Sn/RGO. Sn₄P₃ nanoparticles combining with advantages of high conductivity of Sn and high capacity of P are homogenously loaded on the RGO nanosheets, interconnecting to form 3D mesoporous architecture nanostructures. The Sn₄P₃/RGO hybrid architecture materials exhibit significantly improved electrochemical performance of high reversible capacity, high‐rate capability, and excellent cycling performance as sodium ion batteries (SIBs) anode materials, showing an excellent reversible capacity of 656 mA h g^?1 at a current density of 100 mA g^?1 over 100 cycles, demonstrating a greatly enhanced rate capability of a reversible capacity of 391 mA h g^?1 even at a high current density of 2.0 A g^?1. Moreover, Sn₄P₃/RGO SIBs anodes exhibit a superior long cycling life, delivering a high capacity of 362 mA h g^?1 after 1500 cycles at a high current density of 1.0 A g^?1. The outstanding cycling performance and rate capability of these porous hierarchical Sn₄P₃/RGO hybrid anodes can be attributed to the advantage of porous structure, and the synergistic effect between Sn₄P₃ nanoparticles and RGO nanosheets.