芒果AP1同源基因的克隆及其生物信息学分析

我们采用RT-PCR方法克隆了2个A州同源基因全长cDNA,分别命名为MAPl—1（GenBankac—cession No．FJ529206）和MAPl—2（GenBankaccession No．FJ529207）。MAPl—1编码247个氨基酸,开放阅读框长度为741bp,蛋白质分子量为28．54kD,等电点为8．31;MAPl—2编码248个氨基酸,开放阅读框长度为744bp,蛋白质分子量为28．78kD,等电点为8．70。同源性分析表明,它们的核苷酸序列与其它木本植物A纠同源基因的一致性为72％～81％。实验分析表明,MAPl—1和MAPl—2第1至第61个氨基酸含有一个MADS盒结构域,第88至第178个为K盒结构域;两个基因均定位于细胞核,且功能位点分布存在着不同,推测这两个基因在花器官发育过程中的功能存在差异。蛋白二级结构预测显示,MAPl—1蛋白有12个α-螺旋,4个8折叠区,14个β-转角;而MAP1—2蛋白有11个α-螺旋,5个B折叠区,15个β-转角;其大多数氨基酸具有亲水性。本研究有助于进一步了解芒果的开花分子机理及成花的生物学发育阶段。     

东北黑土nirS型反硝化细菌群落和网络结构对长期施用化肥的响应

【目的】探明长期施用氮磷钾化肥对东北黑土农田土壤nirS型反硝化细菌群落和网络结构的影响,为更加合理的肥料配施提供理论依据。【方法】基于农业农村部黑龙江耕地保育与农业环境科学观测实验站平台,选取不施肥(NoF)、氮肥(N)、磷肥(P)、钾肥(K)、氮钾肥(NK)、氮磷肥(NP)、磷钾肥(PK)、氮磷钾肥(NPK)8个施肥处理,借助荧光定量PCR、Illumina MiSeq高通量测序和分子生态网络技术,分析东北黑土nirS型反硝化细菌丰度、群落及网络结构,及影响反硝化细菌群落变异的主要环境因子。【结果】1)长期施用氮肥均在显著增加nirS基因拷贝数的同时,降低了nirS型反硝化细菌的群落多样性,而磷、钾肥对其影响并不显著。2)Proteobacteria是所有处理中的优势反硝化细菌门,相对丰度为16.96%~27.34%,且氮肥的施用促进了隶属于该菌门中Bradyrhizobium的生长。3)PCoA分析结果显示,8个施肥处理nirS型反硝化细菌群落主要分成施氮肥和不施氮肥两组,说明长期氮肥的施用显著改变了东北黑土反硝化细菌的群落结构。结合Mantel test的结果可知,土壤pH是影响nirS型反硝化细菌群落改变的主要因素。4)分别构建施氮肥和不施氮肥的反硝化细菌分子生态网络,发现施氮肥和不施氮肥网络结构存在很大差异,长期施用氮肥明显简化了nirS型反硝化细菌的网络结构,同时使其网络结构稳定性降低,易受外界环境扰动。【结论】尽管施用化学氮肥有利于土壤养分的增加,但其土壤nirS型反硝化细菌群落及网络结构发生了较大改变,而磷、钾肥的施用对反硝化细菌群落无显著影响。本试验结果为进一步研究东北黑土区农田土壤反硝化微生物对不同施肥管理的响应机制提供了重要科学依据。     

Methanotrophy-driven accumulation of organic carbon in four paddy soils of Bangladesh

Biological methane oxidation is a crucial process in the global carbon cycle that reduces methane emissions from paddy fields and natural wetlands into the atmosphere.However,soil organic carbon accumulation associated with microbial methane oxidation is poorly understood.Therefore,to investigate methane-derived carbon incorporation into soil organic matter,paddy soils originated from different parent materials(Inceptisol,Entisol,and Alfisol) were collected after rice harvesting from four major rice-producing regions in Bangladesh.Following microcosm incubation with 5%(volume/volume)¹³ CH₄,soil¹³ C-atom abundances significantly increased from background level of 1.08% to 1.88%–2.78%,leading to a net methane-derived accumulation of soil organic carbon ranging from 120 to 307 mg kg^-1.Approximately 23.6%–60.0% of the methane consumed was converted to soil organic carbon during microbial methane oxidation.The phylogeny of¹³ C-labeled pmoA(enconding the alpha subunit of the particulate methane monooxygenase) and 16 S rRNA genes further revealed that canonical α(type II) and γ(type I) Proteobacteria were active methane oxidizers.Members within the Methylobacter-and Methylosarcina-affiliated type Ia lineages dominated active methane-oxidizing communities that were responsible for the majority of methane-derived carbon accumulation in all three paddy soils,while Methylocystis-affiliated type IIa lineage was the key contributor in one paddy soil of Inceptisol origin.These results suggest that methanotroph-mediated synthesis of biomass plays an important role in soil organic matter accumulation.This study thus supports the concept that methanotrophs not only consume the greenhouse gas methane but also serve as a key biotic factor in maintaining soil fertility.     

Proteolytic activity in soil: A review

The aim of this work is to review current knowledge on inputs, sources and regulation of protease activities in soils from different ecosystems, while exploring limitations to proteolysis and N mineralisation. Extracellular proteases enter the soil via microbial production and other sources, including plant root exudates, animal excrements, decomposition processes and leaching from agro-industrial fertilisers. The synthesis and activities of proteases in soil are regulated by many factors, including climate, soil properties and the presence of organic compounds of plant and microbial origin. Two particularly important areas for future research are the regulation of proteolysis by low-molecular-weight organic compounds, including amino acids, sugars, flavonoids, plant hormones and siderophores, as well as the identification and characterisation of proteinaceous protease inhibitors of plant and microbial origin in the soil. Despite all the work that has been performed on soil proteases, our understanding of the roles of extracellular plant root proteases in N nutrition is weak. Furthermore, the regulation of soil proteolytic activities of different ecosystems, especially in terms of pollutant inputs and the impact of climate change, requires investigation. Other areas that pose important questions for the future include assessments of protease inhibitor inputs to the soil, regulation of these inhibitors via naturally occurring soil organic compounds and the interactions between soil organisms.     

Molecular analysis of the Arbuscular mycorrhiza symbiosis

The molecular analysis of the arbuscular mycorrhizal (AM) symbiosis started at the beginning of this decade. The paper summarises the work of the ‘Laboratorium für Molekulare Genetik arbuskulärer Mykorrhiza’ at the MPI für terrestrische Mikrobiologie in Marburg on three major topics. Firstly, the plant response to the mycorrhizal colonisation was analysed using both, targeted and non‐targeted approaches. As an example, the localisation of the gst1 mRNA in potato mycorrhiza is shown. Second, molecular techniques were established to analyse gene expression of the fungal partner of the symbiosis. We present a differential RNA display analysis of spore germination in two AM fungi and the cloning of a gene from Glomus mosseae that shows expression at all stages of the fungal life cycle. In the last part, we introduce the work we are carrying out with a new root endophytic fungus, Piriformospora indica. Infection experiments on maize showed that despite the fungus performs as a root necrotroph, it has a positive effect on plant growth.     

根癌农杆菌介导豇豆胰蛋白酶抑制剂基因转入苹果主栽品种

研究建立起一套简单、高效的苹果遗传转化系统。利用根癌农杆菌介导的叶圆片转化法将高效启动的豇豆胰蛋白抑制剂基因（ＣｐＴｌ）转入富士、齐纳金、王林、嘎拉等苹果主栽品种中,经卡那霉素抗性、ＰＣＲ、点杂交、Ｓｏｕｔｈｅｍ杂交检测证明了４个品种均获得转化再生植株,现已移栽成活。     

差异显示技术在马铃薯基因功能研究中的应用

近年来,包括马铃薯在内的植物功能基因组学研究得到飞速发展。基因差异表达技术的日趋完善,为探讨动植物特定的遗传现象、规律及抗逆机制研究提供了极大的方便。文章论述抑制性消减杂交技术、cDNA—AFLP技术、cDNA微阵列（也称为cDNA芯片）等技术在马铃薯基因功能研究中的最新进展。     

Role of beneficial microbial gene pool in mitigating salt/nutrient stress of plants in saline soils through underground phytostimulating signalling molecules

Soil salinity diminishes soil health and reduces crop yield, which is becoming a major global concern. Salinity stress is one of the primary stresses, leading to several other secondary stresses that restrict plant growth and soil fertility. The major secondary stresses induced in plants under saline-alkaline conditions include osmotic stress, nutrient limitation, and ionic stress, all of which negatively impact overall plant growth. Under stressed conditions, certain beneficial soil microflora ...     

不同还原剂预处理精子对水牛ICSI介导转基因效果影响的初步研究

本研究探讨了还原剂β-巯基乙醇（β-ME）、二硫苏糖醇（DTT）及谷胱甘肽（GSH）预处理水牛精子对水牛ICSI介导转基因（ICSI-mediated gene transfer,ICSI-Tr）效果的影响。结果显示,β-ME、DTT和GSH预处理水牛精子对提高ICSI介导转基因的效果不显著（p〉0.05）,但GSH能显著提高2原核（PN）的形成率（p〈0.05）。     

利用抗性基因替换的方法将两个拷贝外源基因表达单元整合到枯草芽孢杆菌染色体基因组同一位点

本研究提供了一种新的整合多拷贝外源基因表达单元到枯草芽孢杆菌染色体同一位点的方法。以β-淀粉酶表达单元作为应用实例,本方法包括以下步骤：首先,构建含有一个拷贝β-淀粉酶表达单元的整合质粒pMLK83-CTBA,通过同源双交换获得单拷贝β-淀粉酶表达单元整合到枯草芽孢杆菌1A751染色体α-淀粉酶基因位点的菌株1A751[CTBA]Neo＋;然后,利用抗性基因替换质粒pVK71,将新霉素抗性基因替换为状观霉素抗性基因,得到1A751[CTBA]Neo-Spe＋;最后,整合质粒pMLK83-CTBA再以同源单交换方式整合到1A751[CTBA]Neo-Spe＋染色体,通过新霉素抗性和状观霉素抗性筛选出两个拷贝β-淀粉酶基因整合的重组菌1A751[CTBA2]Neo＋Spe＋。结果显示,利用此方法增加β-淀粉酶基因的拷贝数,能够显著和稳定地提高β-淀粉酶的表达量。