mRNA表观修饰方式及m6A功能研究进展

mRNA上能发生100多种化学修饰,其中N~6-腺嘌呤(m~6A)是mRNA修饰中最广泛的表观修饰方式之一。在细胞分化、胚胎发育和应激等生物学过程中,特定的mRNA会发生包括N~1-腺嘌呤甲基化、N~5-胞嘧啶甲基化、假尿嘧啶以及N`6-腺嘌呤甲基化等修饰,它们共同形成了mRNA转录后调控的表观修饰转录组,实现对mRNA翻译成蛋白质过程的精确时空调控,特别是m~6A修饰能通过调控mRNA的代谢和翻译等进而调控细胞的一系列生物学过程。文中主要综述mRNA的表观修饰类型和特点,特别是m~6A修饰参与调控mRNA和细胞生物学功能的最新研究进展,并展望了将来m~6A表观修饰的研究重点和方向。     

珍稀濒危植物大花万代兰的花粉团发育及其分类学意义

万代兰属的属间界限划定及其亲缘关系重建是兰科分类系统中的难解之谜。该研究采用常规石蜡切片技术观察了珍稀濒危植物大花万代兰的一对深裂花粉团的形成机制、花药壁发育模式、小孢子发生及雄配子体发育等的胚胎学特征。结果表明：(1)大花万代兰早期的花药原基分化出一对侧生药室,每个药室的小孢子囊中央分化出一条在花药成熟时会降解的不育隔膜组织,形成两个不等深裂的花粉团。(2)发育完整的花药壁有5~9层,包括2~6层药室内壁,符合多层型花药壁发育类型;绒毡层细胞为单核,腺质型,在花药成熟时,表皮、中层和绒毡层皆降解,仅留下2~6层纤维性加厚的药室内壁。(3)小孢子母细胞经过连续型胞质分裂形成正四面体和左右对称的小孢子四分体,小孢子四分体继续保持在同一个胼胝质内,完成有丝分裂形成了2 细胞型的四合花粉;四合花粉两两紧密排列,且由于隔膜组织的降解,最终发育为一对深裂的花粉团。根据现有兰花花药发育资料,分析了大花万代兰花粉团发育的胚胎学特征的分类学意义,为万代兰属错综复杂的系统分类提供了新资料。     

畜禽中药-益生菌复合微生态制剂的研究进展

畜禽中药-益生菌复合微生态制剂是指采用现代发酵技术将益生菌与中药联合发酵,发挥两者的协同作用,以提高畜禽免疫功能、保护畜禽健康的一种新型动物微生态制剂。文中通过调研近几年关于益生菌及中药微生态制剂等方面的文献,综述了畜禽中药-益生菌复合微生态制剂的产生背景及菌种特点,并重点阐述了畜禽中药-益生菌复合微生态制剂的作用机制、在畜禽养殖中的应用及存在问题与建议,以期为畜禽中药-益生菌复合微生态制剂的深入研究提供参考和依据。     

靶向炎性细胞因子的生物制剂及其临床应用

细胞因子可介导许多生物学过程并受到机体的严格调节,其调节的失控可引发一系列疾病如自身免疫炎症和肿瘤。在过去的十几年中,一些能够有效调节细胞因子生物学作用的生物制剂如重组抗炎细胞因子、细胞因子受体以及中和性抗体等被广泛应用到由细胞因子失调引起的相关疾病的治疗。尤其是近年来,一些具有创新性的靶向细胞因子的新型生物制剂在不断涌现。文中对近年来国际上靶向炎症细胞因子(TNF-α、IL-1β、IL-6、IL-17)的生物制剂的研发和临床应用的相关进展进行了综述,指出其副作用和应用风险,并结合其他学者和自己的研究工作提出减少副作用和风险的途径和方法。利用现代生物技术提高抗细胞因子生物制剂针对炎症或肿瘤组织的特异性,是靶向炎性细胞因子生物制剂未来的重要发展方向。     

七姊妹山常绿落叶阔叶混交林物种多样性格局及其环境解释

依托七姊妹山自然保护区6 hm²森林动态监测样地研究平台,基于样地和物种基本信息数据,采用多元回归树和冗余分析研究方法,探讨地形因子对生境的塑造作用及物种分布特征,分析不同群丛类型下物种多样性的变化规律。结果表明：(1)依据“1 SE”规则,4次分割依次以海拔(1 453 m)、坡度(23.13°)、海拔(1 398 m)、凹凸度(4.094)为分界点可将150个样地分为5个群丛。(2)冗余分析表明地形因子对物种分布解释量为0.077 6,解释率为16.36%,各环境因子对物种分布的解释力度依次为：海拔>坡度>凹凸度;坡向与物种的分布无显著相关性。(3)5个群丛中立木密度与胸高截面积最高的均为群丛5(527.4株/400 m²;3.495 cm²/株),立木密度与平均胸高截面积最低为群丛4(225.4株/400 m²;3.057 cm²/株)。(4)5个群丛中Shannon Winener丰富度指数与Simpson优势度指数最高的均为群丛2,最低的为群丛5,物种多样性尺度效应明显;Pielou均匀度指数最高为群丛4,最低为群丛5。(5)两两群丛间Jaccard相似性系数最低为群丛1 群丛2(0.331),最高的为群丛4 群丛5(0.645),海拔对β多样性格局影响较大。研究认为,七姊妹山自然保护区6 hm²样地地形因子对该区域生境的塑造具有一定作用,海拔、坡度、凹凸度组成的“环境筛”影响了该区域的物种分布及多样性格局。     

TP53BP1 regulates chromosome alignment and spindle bipolarity in mouse oocytes

Meiotic oocytes lack classic centrosomes; therefore, bipolar spindle assembly depends on the clustering of acentriolar microtubule‐organizing centers (MTOCs) into two poles. The bipolar spindle is an essential cellular component that ensures accurate chromosome segregation during anaphase. If the spindle does not form properly, it can result in aneuploidy or cell death. However, the molecular mechanism by which the bipolar spindle is established is not yet fully understood. Tumor suppressor p53‐binding protein 1 (TP53BP1) is known to mediate the DNA damage response. Several recent studies have indicated that TP53BP1 has noncanonical roles in processes, such as spindle formation; however, the role of TP53BP1 in oocyte meiosis is currently unclear. Our results show that TP53BP1 knockdown affects spindle bipolarity and chromatin alignment by altering MTOC stability during oocyte maturation. TP53BP1 was localized in the cytoplasm and displayed an irregular cloud pattern around the spindle/chromosome region. TP53BP1 was also required for the correct localization of MTOCs into the two spindle poles during pro‐meiosis I. TP53BP1 deletion altered the MTOC‐localized Aurora Kinase A. TP53BP1 knockdown caused the microtubules to detach from the kinetochores and increased the rate of aneuploidy. Taken together, our data show that TP53BP1 plays crucial roles in chromosome stability and spindle bipolarity during meiotic maturation.     

Acentriolar microtubule organization centers and Ran‐mediated microtubule formation pathways are both required in porcine oocytes

Mammalian oocytes lack centrioles but can generate bipolar spindles using several different mechanisms. For example, mouse oocytes have acentriolar microtubule organization centers (MTOCs) that contain many components of the centrosome, and which initiate microtubule polymerization. On the contrary, human oocytes lack MTOCs and the Ran‐mediated mechanisms may be responsible for spindle assembly. Complete knowledge of the different mechanisms of spindle assembly is lacking in various mammalian oocytes. In this study, we demonstrate that both MTOC‐ and Ran‐mediated microtubule nucleation are required for functional meiotic metaphase I spindle generation in porcine oocytes. Acentriolar MTOC components, including Cep192 and pericentrin, were absent in the germinal vesicle and germinal vesicle breakdown stages. However, they start to colocalize to the spindle microtubules, but are absent in the meiotic spindle poles. Knockdown of Cep192 or inhibition of Polo‐like kinase 1 activity impaired the recruitment of Cep192 and pericentrin to the spindles, impaired microtubule assembly, and decreased the polar body extrusion rate. When the Ran^GTP gradient was perturbed by the expression of dominant negative or constitutively active Ran mutants, severe defects in microtubule nucleation and cytokinesis were observed, and the localization of MTOC materials in the spindles was abolished. These results demonstrate that the stepwise involvement of MTOC‐ and Ran‐mediated microtubule assembly is crucial for the formation of meiotic spindles in porcine oocytes, indicating the diversity of spindle formation mechanisms among mammalian oocytes.     

芽孢杆菌dhs-330-021菌粉的制备及稳定性研究

目的:利用喷雾干燥工艺制备芽孢杆菌dhs-330-021菌粉,并研究菌粉的活性及稳定性。方法:以脱脂乳、海藻糖、β-环糊精和谷氨酸钠为保护剂,采用喷雾干燥(条件为:进口温度100℃,出口温度50～60℃,进样速度2～4mL/min)制备芽孢杆菌菌粉,以喷干存活率和菌粉活菌数为指标,选择最佳制备条件。结果:获得喷干保护剂配方为脱脂乳10.0%、海藻糖6.0%、β-环糊精13.0%、谷氨酸钠15.0%,喷干存活率为65.9%,菌粉活菌数为1.38×109CFU/g,存放180 d后菌粉活菌数为1.03×10~9CFU/g。结论:喷雾干燥工艺可以用于芽孢杆菌dhs-330-021菌粉的制备,获得的菌粉稳定性较好。     

Structural and functional insights into the role of a cupin superfamily isomerase in the biosynthesis of Choi moiety of aeruginosin

The 2-carboxy-6-hydroxyoctahydroindole (Choi) moiety is a hallmark of aeruginosins, a class of cyanobacterial derived bioactive linear tetrapeptides that possess antithrombotic activity. The biosynthetic pathway of Choi has yet to be resolved. AerE is a cupin superfamily enzyme that was shown to be involved in the biosynthesis of Choi, but its exact role remains unclear. This study reports the functional characterization and structural analyses of AerE. Enzymatic observation reveals that AerE can dramatically accelerate 1,3-allylic isomerization of the non-aromatic decarboxylation product of prephenate, dihydro-4-hydroxyphenylpyruvate (H₂HPP). This olefin isomerization reaction can occur non-enzymatically and is the second step of the biosynthetic pathway from prephenate to Choi. The results of comparative structural analysis and substrate analogue binding geometry analysis combined with the results of mutational studies suggest that AerE employs an induced fit strategy to bind and stabilize the substrate in a particular conformation that is possibly favorable for 1,3-allylic isomerization of H₂HPP through coordinate bonds, hydrogen bonds, π–π conjugation interaction and hydrophobic interactions. All of these interactions are critical for the catalytic efficiency.