基于城市微气候模拟软件的城市道路绿化带对PM2.5消减作用的研究

随着经济的快速发展及机动车保有量的持续增长，车辆造成的道路污染问题日益严重。广州作为中国重要的经济发展城市，交通源排放问题高度集中，机动车排放是城市PM2.5的主要来源之一，开展减缓城市道路污染危害的研究具有重要意义。本研究为调查绿化带对广州城市道路PM2.5的影响，运用实测与城市微气候模拟软件（ENVI-met）模拟结合的研究方法，实测并分析城市道路空间PM2.5的浓度分布及其影响因素，使用实测数据对模拟软件进行验证分析，模拟研究理想道路模型下不同高宽比、风向等因素及绿化带植配类型对PM2.5的消减作用。研究表明：（1）城市道路空间PM2.5浓度分布受污染源、街道高宽比、风速风向、绿化带等综合影响，自然消减情况下，其主要受风速风向和高宽比双因素影响；（2）通常街道高宽比越大，越有利于道路空间PM2.5的扩散；（3）城市道路空间PM2.5自然沉降最小距离为12 m，0-12 m范围内应保持无障碍物的开敞环境，PM2.5消减的关键范围是12-24 m，此范围内可以利用生态手段沉降颗粒物；（4） PM2.5消减率受绿化带和风向的双控制，应根据主导风向选择绿化带植配方式。在主导风平行面和垂直迎风面绿化带对PM2.5有正消减效应，建议植配类型为"乔-乔+灌+草"；在主导风垂直背风面绿化带对PM2.5呈负消减效应，植配类型为"乔-灌"绿化带消减率接近于自然消减率，而植配类型为"乔-灌+草"和"乔-乔+灌+草"的绿化带加重了颗粒物在该区域的积聚。     

Aphid populations showing differential levels of virulence on Capsicum accessions

The green peach aphid,Myzus persicae,is one of the most threatening pests in pepper cultivation and growers would benefit from resistant varietices.Previously,we identified two Capsicum acessions as susceptible and three as resistant to M.persicae using an aphid population originating from the Netherlands(NL).Later on we identified an aphid population originating from a diferent gcographical region(Switserland,SW)that was virulent on all tested Capsicum acessions.The objeetive of the current work is to describe in detail diferent aspects of the interaction between two aphid populations and two sclected Capsicum acessions(one that was susceptible[PB2013046]and one that was resistant[PB2013071]to population NL),including biochemical processes involved.Electrical penetration graph(EPG)recordings showed similar feeding activities for both aphid populations on PB2013046.On acession PB2013071 the aphid population sw was able to devote significantly more time to phloem ingestion than population NL.We also studied plant defense response and found that plants of acession PB2013046 could not induce an accumulation of reactive oxygen species and callose formation after infestation with either aphid population.However,plants of PB2013071 induced a stronger defense response after infestation by population NL than after infestation by population SW.Based on these results,population SW of M.persicae seems to have overcome the resistance of PB2013071 that prevented feeding of aphids from NL population.The potential mechanism by which SW population overcomes the resistance is discussed.     

High levels of arbuscular mycorrhizal fungus colonization on Medicago truncatula reduces plant suitability as a host for pea aphids (Acyrthosiphon pisum)

This study sheds light on a poorly understood area in insect-plant-microbe interactions,focusing on aphid probing and feeding behavior on plants with varying levels of arbuscular mycorrhizal(AM)fungus root colonization.It investigates a commonly occurring interaction of three species:pea aphid Acyrthosiphon pisum,barrel medic Medicago truncatula,and the AM fungus Rhizophagus irregularis,examining whether aphid-feeding behavior changes when insects feed on plants at different levels of AM fungus colonization(42% and 84% root length colonized).Aphid probing and feeding behavior was monitored throughout 8 h of recording using the electrical penetration graph(EPG)technique,also,foliar nutrient content and plant growth were measured.Summarizing,aphids took longer to reach their 1st sustained phloem ingestion on the 84% AM plants than on the 42% AM plants or on controls.Less aphids showed phloem ingestion on the 84% AM plants relative to the 42% AM plants.Shoots of the 84% AM plants had higher percent carbon(43.7%)relative to controls(40.5%),and the 84% AM plants had reduced percent nitrogen(5.3%)relative to the 42% AM plants(6%).In conclusion,EPG and foliar nutrient data support the hypothesis that modifications in plant anatomy(e.g.,thicker leaves),and poor food quality(reduced nitrogen)in the 84% AM plants contribute to reduced aphid success in locating phloem and ultimately to differences in phloem sap ingestion.This work suggests that M.truncatula plants benefit from AM symbiosis not only because of increased nutrient uptake but also because of reduced susceptibility to aphids.     

苹果柠檬酸合酶3基因家族成员鉴定及表达分析

柠檬酸合酶(citrate synthase 3, CS3)是细胞代谢途径中的关键酶之一,其活性调节着生物体的物质和能量代谢过程。本研究旨在从苹果全基因组中鉴定CS3基因家族成员,并进行生物信息学和表达模式分析,为研究苹果CS3基因的潜在功能提供理论基础。利用BLASTp基于GDR数据库鉴定苹果CS3家族成员,通过Pfam、SMART、MEGA5.0、clustalx.exe、ExPASy Proteomics Server、MEGAX、SOPMA、MEME和WoLF PSORT等软件分析CS3蛋白序列基本信息、亚细胞定位情况、结构域组成、系统进化关系以及染色体定位情况。利用酸含量的测定和实时荧光定量PCR (real-time fluorescence quantitative polymerase chain reaction, qRT-PCR)技术检测苹果6个CS3的组织表达和诱导表达特性。苹果CS3基因家族包含6个成员,这些CS3蛋白包括473−608个不等的氨基酸残基,等电点分布在7.21−8.82。亚细胞定位结果显示CS3蛋白分别定位在线粒体和叶绿体。系统进化分析可将其分为3类,各亚家族基因数量分别为2个。染色体定位结果显示,CS3基因分布在苹果不同的染色体上。蛋白二级结构以a-螺旋为主,其次是无规则卷曲,b-转角所占比例最小。筛选的6个家族成员在不同苹果组织中均有表达,整体表达趋势从高到低依次为MdCS3.4相对表达含量最高,MdCS3.6次之,其他家族成员相对表达量依次为MdCS3.3>MdCS3.2>MdCS3.1>MdCS3.5。qRT-PCR结果显示,MdCS3.1和MdCS3.3基因在酸含量较低的‘成纪1号’果肉中相对表达量最高,酸含量较高的‘艾斯达’果肉中MdCS3.2和MdCS3.3基因相对表达量最高。因此,本研究对不同苹果品种中CS3基因相对表达量进行了检测,并分析了其在苹果果实酸合成过程中的作用。结果表明,CS3基因在不同苹果品种中的相对表达量存在差异,为后续研究苹果品质形成机制提供了参考。     

RUS家族对植物生长发育的调控作用

叶绿体基因组编码许多参与光合作用和其他代谢过程的关键蛋白质,在叶绿体中合成的代谢物对于植物正常的生长发育至关重要。根对紫外线-B辐射敏感[Root-UVB (ultraviolet radiation B)-sensitive, RUS]蛋白属于叶绿体蛋白,由高度保守的DUF647结构域组成,在参与植物形态发生、物质运输和能量代谢等多种生命活动的调控中发挥作用。本文就近年来关于RUS家族在植物的胚胎发育、光形态建成、维生素B6稳态、生长素转运和花药发育等生长发育过程中的相关研究进行回顾和总结,为深入研究其在植物生长发育中的分子调控机制提供了参考。     

抗菌药对鲍曼不动杆菌外膜囊泡产量及主要生物学特性的影响

【背景】细菌耐药性已成为全球健康卫生和经济发展的巨大威胁。替加环素是治疗多重耐药肠杆菌所致严重感染的主要药物之一,但在2019年发现了可介导其高水平耐药的可转移替加环素耐药基因tet（X3）。外膜囊泡作为介导水平基因转移的新型方式,在介导tet（X3）水平转移中的作用目前尚无报道。【目的】以tet（X3）阳性替加环素耐药鲍曼不动杆菌34AB为对象,探究不同抗菌药物对其外膜囊泡产量及主要生物学特性的影响。【方法】采用微量肉汤稀释法测定细菌药物敏感性,超速离心法提取细菌外膜囊泡,BCA法测定外膜囊泡产量,使用马尔文纳米粒度电位仪测定外膜囊泡的粒径与电位,PCR法（定性）及RT-qPCR法（定量）检测外膜囊泡中携带的tet（X3）基因。【结果】相较于无抗生素对照组[（0.64±0.04） mg/mL],在不同抗菌药物亚抑菌浓度（1/2 MIC和1/4 MIC）处理后,34AB外膜囊泡的产量均有所增加,以头孢他啶[1/2 MIC,（2.83±0.57） mg/mL;1/4 MIC,（2.38±0.29） mg/mL]和美罗培南[1/2 MIC,（2.19±0.11） mg/mL;1/4 MIC,（1.96±0.37） mg/mL]作用最为显著（p<0.01）。同时抗菌药物作用后,各组外膜囊泡粒径和电位均有所降低,而携带的tet（X3）基因拷贝数均有所上升（2.80×10⁴-2.63×10⁷copies/μL）。【结论】抗菌药物的临床应用可能会导致耐药细菌外膜囊泡产量及携带的耐药基因丰度增加,进而增强其作为水平基因转移载体传播耐药基因的风险。     

建立多重液相基因芯片方法快速检测狐狸、水貂成分

基于xMAP液相芯片新型生物技术平台,分别以狐狸线粒体DNA D-loop区序列、水貂线粒体DNA细胞色素b基因序列为模板设计特异扩增引物和探针,并对探针进行锁核酸修饰,建立了二重xMAP液相基因芯片方法,用于快速检测狐狸和水貂源性成分。该法能准确鉴定鉴别狐狸和水貂DNA,对其他18种动物物种DNA均呈检测阴性,对狐狸、水貂DNA的检测低限分别为2. 8pg/μl、0. 9pg/μl,对肉类混样检出限为0. 05%(m/m)。对目标源性DNA含量为1%(V/V)的32份饲料与食品核酸添加样本均呈对应目标检测阳性。结果表明,该方法特异性强、灵敏度高,适用于食品与饲料领域相关原料和产品的质量与安全检验。     

蝉棒束孢菌子实体对大鼠肾小管上皮细胞的影响

对蝉棒束孢菌子实体（0.75g/kg）重复灌胃SD雄性大鼠90d及恢复28d的早期肾损伤生物标记物肾损伤分子-1（KIM-1）和中性粒细胞明胶酶相关载脂蛋白（NGAL）进行测定,评估蝉棒束孢菌子实体对肾小管上皮细胞的影响;研究不同剂量蝉棒束孢菌子实体（0.25g/kg、0.5g/kg、1.0g/kg）对肾小管上皮细胞增殖和增生能力的影响。给药30、60、90d及恢复28d时,SD大鼠血清中KIM-1浓度与对照组相比均无显著差异（P>0.05）,给药30d、60d时,SD大鼠血清中NGAL浓度与对照组相比均无显著差异（P>0.05）,给药90d及恢复28d时,SD大鼠血清中NGAL浓度低于对照组（P<0.05）,且给药90d组与对照组相比有显著性差异（P<0.01）;免疫组化检测增殖细胞核抗原法（PCNA）及四甲基偶氮唑盐微量酶反应比色法（MTT）表明：与对照组相比,蝉棒束孢菌子实体能使肾小管上皮细胞增生能力增强,未导致肾小管上皮细胞凋亡。     

Reactive oxygen species accumulation patterns of alfalfa root nodules identified using an optimized method

ROS include superoxide anion radical (O2^-), hydrogen peroxide (H2O2), singlet oxygen (0-0), hydroxyl radical (OH ), and hydroxyl anion (OH-). O2^-, the radical with the highest oxidation compacity to produce H2O2, OH and OH^-, is a byproduct of aerobic respiration in organisms. Rhizobia and their legume hosts are aerobic organisms, and nitrogen-fixing nodules formed on legume roots are developed from their symbiotic in teractions. Therefore, ROS are generated in legume nodules through aerobic respiration by both symbiotic partners.     

The glutamate biosynthetic pathway in brain:a novel mechanism of moderate UV-induced neurobehavioral changes

Using single-cell mass spectrometry technology,Zhu et al.[1] recently revealed that a novel intra-neuronal glutamate(GLU)biosynthetic pathway contributes to sunlight ultraviolet(UV)-induced neurobehavioral effects.In the study,moderate UV exposure was found to increase blood levels of urocanic acid(UCA),which may cross the blood–brain barrier(BBB).Subsequently,UCA promotes GLU biosynthesis and release in various brain regions,including motor cortex and hippocampus.Strikingly,UV exposure improves motor learning and object recognition memory.The inhibitor against urocanase,an enzyme critical for the conversion of UCA to GLU,reverses the UV exposure-related neurological effects.Thus,the activation of UCA-GLU metabolic pathway mediates the process of UV-triggered neurobehavioral changes(Fig.1).