人胃粘膜G、D细胞与肠化生关系的研究

用免疫细胞化学和原位杂交技术探讨G、D细胞及胃泌素mRNA与肠化生的关系。标本来自胃镜活检的胃粘膜。结果显示,在与大肠化生区相邻的胃粘膜,G细胞突变消失,假幽门腺化生也缺乏G细胞,而淖肠化生仍保留少数G细胞;D细胞不仅见于小肠化生,而且也出现在假幽门腺化生以及某些大肠化生区。胃泌素mRNA仅限于G细胞分布区,未出现在大肠化生区和假幽门腺化生区,G细胞及胃泌素mRNA在大肠化生区的消失,可能由于局部杯状细胞分泌的硫酸粘蛋白改变了局部的微环境,从而影响了G细胞的分化与发育,至于假幽门腺化生区G细胞及胃泌素mRNA消失的原因还不清楚,应继续研究。     

达尔文把人类回归到自然界（1）——纪念达尔文《物种起源》出版150周年

1859年,达尔文的著作《物种起源》改变了人们对自己的看法：在1859年以前,人是上帝创造的产物：在1859年以后,人是自然选择的产物。而达尔文主张人是自然界的一部分。而不是在自然之外。他和T·H赫胥黎提出,人和大猿特别是非洲猿有近密的亲缘关系。E·海克尔甚至画出了包括某些似猿的人类祖先的系统树。然而,在20世纪,许多人类学家还是相信,人是独特的,是一种全新的生物。他们要寻找人类进化的特殊类型的解释。他们提出,脑必定引领着进化的方向,认为人和现代非洲猿之间的相似性是平行进化所造成的。后来,分子生物学的和化石的证据证实了达尔文原先的观点。今天,达尔文的理论对人类社会生活仍然具有重大意义。     

不同水肥一体化方式对苹果氮素吸收利用特性及产量和品质的影响

以‘嘎啦/八棱海棠’为试材,借助¹⁵N同位素示踪技术,研究了撒施(T₁)、滴灌施氮(T₂)和渗灌施氮(T₃)对嘎啦苹果氮素吸收利用、分配特性和产量品质的影响,以期进一步完善苹果园水肥一体化技术,挖掘提高氮素利用率的途径。结果表明: T₃处理苹果叶片的叶面积、叶绿素和氮含量显著高于T₁和T₂处理。各时期土壤矿化氮(N_min)含量在20~40 cm土层表现为T₃＞T₂＞T₁处理,在0~20 cm土层表现为T₂＞T₃＞T₁处理。同一器官的Ndff值(树体各器官从肥料中吸收到的¹⁵N占该器官全氮量的比例)在各时期均以T₃处理最高,T₂其次,T₁处理最低。果实成熟期的树体¹⁵N利用率表现为T₃＞T₂＞T₁处理,其中T₃处理的树体¹⁵N利用率为24.2%,分别是T₂和T₁处理的1.19和1.65倍。果实成熟期T₁处理的¹⁵N分配率在营养器官最高,T₂处理在贮藏器官最高,T₃处理在生殖器官最高。各处理的单果重、产量、可溶性固形物、硬度、可溶性糖及糖酸比均以T₃处理最高,T₂其次,T₁处理最低。渗灌施氮处理显著促进了嘎啦苹果树体叶片生长和氮素利用,并提高了果实产量和品质。     

核因子E2相关因子2在运动改善非酒精性脂肪性肝病中的作用

核因子E2相关因子2 (nuclear factor erythroid 2-related factor 2,Nrf2)信号通路在维持心血管疾病、神经系统退行性疾病以及慢性代谢性疾病中的细胞稳态方面起关键作用。研究表明,以氧化应激、炎症和线粒体功能失调为特征的慢性疾病可通过增加Nrf2表达来恢复机体氧化还原状态,治疗或预防疾病。非酒精性脂肪性肝病（nonalcoholic fatty liver disease,NAFLD）是一种由除酒精以外的其他多种因素导致的以肝脏脂肪变性为特征的慢性代谢性肝脏疾病,其患病率近年来在全球范围内逐渐增加。运动是防治NAFLD的有效手段,可通过运动方式、运动强度、运动环境和运动疲劳等因素影响Nrf2信号通路。本文通过阐述Nrf2信号通路的激活、其调控抗氧化的相关机制以及运动对Nrf2信号通路的影响,以NAFLD的发病机制为基础,探讨运动、Nrf2和NAFLD之间的关系,综述Nrf2在运动改善NAFLD中的作用及相关机制。为运动改善NAFLD的分子机制研究提供理论参考依据。     

Novel insight into metabolic reprogrammming in cancer radioresistance: A promising therapeutic target in radiotherapy

Currently, cancer treatment mainly consists of surgery, radiotherapy, chemotherapy, immunotherapy, and molecular targeted therapy, of which radiotherapy is one of the major pillars. However, the occurrence of radioresistance largely limits its therapeutic effect. Metabolic reprogramming is an important hallmark in cancer progression and treatment resistance. In radiotherapy, DNA breakage is the major mechanism of cell damage, and in turn, cancer cells are prone to increase the metabolic flux of glucose, glutamine, serine, arginine, fatty acids etc., thus providing sufficient substrates and energy for DNA damage repair. Therefore, studying the linkage between metabolic reprogramming and cancer radioresistance may provide new ideas for improving the efficacy of tumor therapy. This review mainly focuses on the role of metabolic alterations, including glucose, amino acid, lipid, nucleotide and other ion metabolism, in radioresistance, and proposes possible therapeutic targets to improve the efficacy of cancer radiotherapy.     

Regulation of myostatin expression is associated with growth and muscle development in commercial broiler and DMC muscle

Myostatin is a negative regulator of skeletal muscle growth. Muscle tissue is the largest tissue in the body and influences body growth. Commercial Avian broiler chickens are selected for high growth rate and muscularity. Daweishan mini chickens are a slow growing small-sized chicken breed. We investigated the relations between muscle (breast and leg) myostatin mRNA expression and body and muscle growth. Twenty chickens per breed were slaughtered at 0, 30, 60, 90, 120, and 150 days of age. Body and muscle weights were higher at all times in Avian chickens. Breast muscle myostatin expression was higher in Avian chickens than in Daweishan mini chickens at day 30. Myostatin expression peaked at day 60 in Daweishan mini chickens and expression remained higher in breast muscle. Daweishan mini chickens myostatin expression correlated positively with carcass weight, breast and leg muscle weight from day 0 to 60, and correlated negatively with body weight from day 90 to 150, while myostatin expression in Avian chickens was negatively correlated with carcass and muscle weight from day 90 to 150. The results suggest that myostatin expression is related to regulation of body growth and muscle development, with two different regulatory mechanisms that switch between days 30 and 60.     

姜黄素对过度训练致大鼠脾脏细胞凋亡的调控作用及其机制*

目的:研究姜黄素调控Keap1-Nrf2-ARE信号通路缓解大鼠过度训练所致脾脏氧化应激及细胞凋亡机制。方法:7周龄SPF级雄性Wistar大鼠分为对照组(C组,n=12)、过度训练组(OM组,n=11)、姜黄素+过度训练组(COM组,n=14)。C组不进行任何运动干预,OM组、COM组大鼠进行8周递增负荷游泳训练。训练期间,COM组以200 mg/(kg·d)、5 ml/kg姜黄素进行灌胃,其他组灌胃等体积0.5 %羧甲基纤维素纳助溶剂。末次训练后24 h,称重计算脾脏指数,光镜观察脾脏组织病理学改变,取血液、脾脏组织检测相关生化指标。结果:C组大鼠脾脏组织结构正常;OM组较C组脾脏指数极显著降低(P＜0.01),并出现明显病理学改变;COM组较OM组脾脏指数显著升高(P＜0.05),且组织形态学改变有所改善。与C组比较,OM组血清皮质酮(Cor)浓度和脾脏细胞凋亡水平、丙二醛(MDA)浓度均升高,促凋亡蛋白Bcl-2相关X蛋白(Bax)表达增强(P＜0.05或P＜0.01);体重、血清睾酮(T)水平及脾脏超氧化物歧化酶(SOD)活性降低,脾脏血红素氧合酶1(HO-1)、抗凋亡蛋白B淋巴细胞瘤因子-2(Bcl-2)表达减弱(P＜0.05或P＜0.01);脾脏核因子E2相关因子2(Nrf2)表达水平无显著变化(P＞0.05)。与OM组比较,COM组体重无显著变化(P＞0.05);血清T浓度升高,脾脏SOD活性升高,Bcl-2、Nrf2和HO-1表达增强(P＜0.05或P＜0.01);血清Cor浓度及脾脏MDA浓度、细胞凋亡水平、Bax表达均降低或减弱(P＜0.05或P＜0.01);组间T/Cor比值变化趋势与T变化相一致,Bcl-2/Bax比值变化趋势与Bcl-2变化相一致。结论:8周递增负荷过度游泳训练引发脾脏细胞凋亡加剧,脾脏组织发生病理改变及功能异常。姜黄素通过上调Nrf2、HO-1蛋白表达,在一定程度上缓解过度训练引发的氧化应激,增强抑凋亡蛋白Bcl-2表达,减弱促凋亡蛋白Bax表达,改善大鼠脾脏细胞过度凋亡,保护脾脏组织结构和功能正常。     

Oligomerization and regulated proteolytic processing of angiopoietin-like protein 4

Angiopoietin-like protein 4 (Angptl4) is a recently identified circulating protein expressed primarily in adipose tissue and liver. Also known as peroxisome proliferator-activated receptor (PPAR)-gamma angiopoietin-related, fasting induced adipose factor, and hepatic fibrinogen/angiopoietin-related protein, recombinant Angptl4 causes increase of plasma very low density lipoprotein levels by inhibition of lipoprotein lipase activity. Similar to angiopoietins and other angiopoietin-like proteins, Angptl4 contains an amino-terminal coiled-coil domain and a carboxyl-terminal fibrinogen-like domain. We report here that Angptl4 is evolutionarily conserved among several mammalian species and that full-length Angptl4 protein is an oligomer containing intermolecular disulfide bonds. Oligomerized Angptl4 undergoes proteolytic processing to release its carboxyl fibrinogen-like domain, which circulates as a monomer. Angptl4's N-terminal coiled-coil domain mediates its oligomerization, which by itself is sufficient to form higher order oligomeric structure. Adenovirus-mediated overexpression of Angptl4 in 293 cells shows that conversion of full-length, oligomerized Angptl4 is mediated by a cell-associated protease activity induced by serum. These findings demonstrate a novel property of angiopoietin-like proteins and suggest that oligomerization and proteolytic processing of Angptl4 may regulate its biological activities in vivo.     

Mutational meltdown or controlled chain reaction: The dynamics of rapid plastome evolution in the hyperdiversity of Poaceae

The study of genomic structural evolution associated with accelerated evolutionary rates that result in avoidance of meltdown and increase biodiversity is becoming ever more possible as the number of available plastomes increases. To more comprehensively analyze rate heterogeneity among monocots and within Poaceae, we sequenced plastomes from four Poaceae species, combined them with publicly available data from ~200 plastomes, and conducted comparative analyses to quantify the pattern of rate heterogeneity between different lineages, functional groups, and periods of evolutionary time. We compared structural differences across the Poaceae to quantify how changes in plastome size correspond to different genomic subunits and the evolution of IR–SC junction boundaries. The substitution rates among ancestral Poaceae were inferred to be exceptionally rapid compared to other monocots but slowed after divergence into extant lineages, which could not be sufficiently explained by positive selection. As such, rapid rates in the ancestral lineage leading to Poaceae might be more closely linked to large-scale structural changes like the loss of ycf1 and ycf2. The total increase in plastome size across Poaceae was positively correlated with the total length of intergenic spacers, tandem repeats, and dispersed repeats as well as large single copy, and inverted repeats (IRs). The continuous evolution of IR–SC junction boundaries was asynchronous with sizes of total genome and subunits across Poaceae. Future work is needed to better understand what factors in ancestral Poaceae evolved to harness such rapid rates of plastome evolution, avoid a mutational meltdown, and escape the stagnation of strong purifying selection as well as if these factors could be utilized to synthetically control rates.