金鱼草AmPDS基因克隆及调节类胡萝卜素合成功能分析

八氢番茄红素脱氢酶(phytoene desaturase,PDS)是类胡萝卜素进行生物合成途径中的关键酶。为了深入探究金鱼草PDS基因的功能,该研究以‘马里兰’金鱼草(Antirrhinum majus‘Maryland True Pink’)为材料,对其PDS基因(AmPDS)全长序列及蛋白结构进行分析,并克隆了AmPDS基因片段;采用qRT-PCR技术检测AmPDS基因在不同时期及部位的相对表达水平,利用VIGS技术验证AmPDS基因功能,用紫外分光法测定叶片中各类色素含量。结果显示:(1)成功克隆AmPDS基因片段(500 bp);AmPDS基因cDNA全长1743 bp,编码580个氨基酸;其蛋白分子量为64.75 kD,理论等电点6.66;同源比对分析显示AmPDS基因与芝麻(Sesamum indicum)的序列相似性最高。(2)qRT-PCR分析表明,AmPDS基因在全株均有表达,且在全盛期花朵的上瓣和叶片中表达量最高。(3)构建pTRV2-AmPDS载体,建立了金鱼草的VIGS沉默体系,AmPDS基因沉默效率约为53%,与阴性对照相比叶片中各类色素含量均显著降低。研究认为,AmPDS基因是金鱼草类胡萝卜素生物合成途径中的关键基因,可作为金鱼草VIGS沉默体系的指示基因,为后续研究金鱼草其他基因功能奠定基础。     

人源溶菌酶在大肠杆菌中的表达与复性研究

人源溶菌酶(Human lysozyme,HLZ)是一种糖苷水解酶,具有抗菌消炎的作用,其作为抗生素的替代品,已经被广泛应用于食品业、畜牧业和医疗等领域。如何获得高产量、高活性、高纯度的人源溶菌酶一直是亟待解决的技术问题。优化人源溶菌酶编码基因密码子,提高其在大肠杆菌中的适应度和表达量;将优化的基因克隆至大肠杆菌表达质粒pET21a,并将其在大肠杆菌表达菌株BL21(DE3)中诱导表达;利用8 mol/L尿素溶液对包涵体进行溶解变性后,探究一步透析、梯度透析和梯度稀释3种复性方式以及复性液中谷胱甘肽氧化还原对(GSSG/GSH)、精氨酸、甘油等复性物的浓度对重组人源溶菌酶复性的效果,获得最佳的复性方案。研究结果表明:37℃诱导温度下,利用0.5 mmol/L IPTG成功诱导了分子量约为14.7 kD的重组人源溶菌酶的表达,包涵体表达量约为380 mg/L(湿重)。包涵体经一步透析、梯度透析和梯度稀释3种复性方式复性后,测得比活力值分别为147 U/mg、335 U/mg、176 U/mg,表明最佳复性方法为梯度透析复性法。进一步探索了复性液中GSSG/GSH比值、精氨酸浓度、甘油浓度对人源溶菌酶复性效果的影响,表明当复性液中同时添加浓度比为1∶2的GSSG/GSH、4 mmol/L精氨酸和6%甘油时,复性后人源溶菌酶的最佳比活力值为1170 U/mg,显著高于3种复性物均不加时溶菌酶335 U/mg的比活力值,但低于溶菌酶标准品1732 U/mg的比活力值。成功地将人源溶菌酶基因在大肠杆菌中表达,并通过包涵体复性体系成功获得高活性重组人源溶菌酶。     

产瓦伦西亚烯酿酒酵母的表达载体适配及发酵碳氮源优化

瓦伦西亚烯是一种倍半萜类化合物,广泛应用于香水、香皂、食品和饮料等工业制造上。但由于其自然含量极低,且目前获取瓦伦西亚烯的方法较为麻烦且花费高,因而构建细胞工厂进行瓦伦西亚烯的生物合成是更为高效和环保的方法。选取酿酒酵母(Saccharomyces cerevisiae)作为宿主构建细胞工厂,先在酿酒酵母基因组上引入黄扁柏的瓦伦西亚烯合成酶(Valencene synthase from Callitropsis nootkatensis,CnVS),实现瓦伦西亚烯的初步合成,初始产量为4.16 mg/L。随后利用CRISPR/Cas9系统对酿酒酵母中Mevalonate(MVA)途径的erg9和rox1基因进行敲除,提高通往瓦伦西亚烯合成的碳流量。不同碳氮源浓度发酵的结果表明,细胞生长积累过高可能不利于瓦伦西亚烯的积累。最后探究了不同CnVS表达载体对瓦伦西亚烯产量的影响,并获得17.54 mg/L的最高产量,是出发菌株的4.2倍。     

转基因植物与近缘种之间基因流的研究进展

随着转基因植物的大面积种植,转基因植物的生态风险受到广泛关注,其中主要的风险是转基因植物与近缘物种之间的基因流及其影响。本文综述了目前商业化种植的转基因作物油菜、棉花、玉米和大豆,以及未商业化种植的水稻、小麦的基因流研究进展;分析了不同转基因作物与其近缘种之间发生基因流的频率和最远发生距离;介绍了降低基因流发生的方法。基因流频率受物种亲缘关系、花期重叠时间、风速风向等因素的影响,最远发生距离受气候条件、传粉媒介、地理条件等因素的影响。转基因作物与其近缘种之间的基因流频率与距花粉源的距离呈负相关关系(y=-0.59x-0.46,R²=0.25,P<0.01),亲缘关系近的基因流频率高。为了降低转基因植物与其近缘物种之间的基因流风险,建议采取“分区管理”的策略,并加强基因流发生之后的生态风险评价研究。     

三裂叶薯NBS-LRR类抗病基因的筛选鉴定与结构分析

为发掘甘薯近缘野生种三裂叶薯(Ipomoea triloba)的NBS-LRR类抗病基因,从基因数据库中对三裂叶薯基因组序列进行了筛选、鉴定和分析。结果表明,从三裂叶薯的98 025个基因中,筛选到282个编码NBS-LRR类蛋白的基因,其中N型80个,NL型83个,CN型28个,CNL型57个,TN型10个,TNL型23个,RN型1个。三裂叶薯的16条染色体上均含有NBS-LRR家族基因,数量最多的染色体含有65个,最少的只有1个。三裂叶薯基因组共有55个基因簇,包含了63.5%的NBS-LRR家族基因。在NBS-LRR抗病基因家族中,CNL和TNL亚家族分别对应到7和11个保守结构域。这为三裂叶薯抗性资源的利用提供了科学参考。     

中国森林生态系统土壤呼吸温度敏感性空间变异特征及影响因素

土壤呼吸的温度敏感性(Q₁₀)是陆地碳循环与气候系统间相互作用的关键参数。尽管已有大量关于不同类型森林Q₁₀季节和年际变化规律的研究, 但是对Q₁₀在区域尺度的空间变异特征及其影响因素仍认识不足, 已有结果缺乏一致结论。该研究通过整合已发表论文, 构建了中国森林生态系统年尺度Q₁₀数据集, 共包含399条记录、5种森林类型(落叶阔叶林(DBF)、落叶针叶林(DNF)、常绿阔叶林(EBF)、常绿针叶林(ENF)、混交林(MF))。分析了不同森林类型Q₁₀的空间变异特征及其与地理、气候和土壤因素的关系。结果显示, 1) Q₁₀介于1.09到6.24之间, 平均值(±标准误差)为2.37 (± 0.04), 且在不同森林类型之间无显著差异; 2)当考虑所有森林类型时, Q₁₀随纬度、海拔、土壤有机碳含量(SOC)和土壤全氮含量(TN)的增加而增大, 随经度、年平均气温(MAT)、平均年降水量(MAP)的增加而减小。气候(MAT、MAP)和土壤(SOC、TN)因素间存在相互作用, 共同解释了33%的Q₁₀空间变异, 其中MAT和SOC是Q₁₀空间变异的主要驱动因素; 3)不同类型森林Q₁₀对气候和土壤因素的响应存在差异。在DNF中Q₁₀随MAP的增加而减小, 而其他类型森林中Q₁₀与MAP无显著相关性; 在EBF、DBF、ENF中Q₁₀随TN的增加而增大, 但Q₁₀对TN的敏感性在EBF中最高, 在ENF中最低。这些结果表明, 尽管Q₁₀有一定的集中分布趋势, 但仍有较大范围的空间变异, 在进行碳收支估算时应注意尺度问题。Q₁₀的主要驱动因素和Q₁₀对环境因素的响应随森林类型而变化, 在气候变化情景下, 不同森林类型间Q₁₀可能发生分异。因此, 未来的碳循环-气候模型还应考虑不同类型森林碳循环关键参数对气候变化的响应差异。     

Multiple chromosomal inversions contribute to adaptive divergence of a dune sunflower ecotype

Both models and case studies suggest that chromosomal inversions can facilitate adaptation and speciation in the presence of gene flow by suppressing recombination between locally adapted alleles. Until recently, however, it has been laborious and time‐consuming to identify and genotype inversions in natural populations. Here we apply RAD sequencing data and newly developed population genomic approaches to identify putative inversions that differentiate a sand dune ecotype of the prairie sunflower (Helianthus petiolaris) from populations found on the adjacent sand sheet. We detected seven large genomic regions that exhibit a different population structure than the rest of the genome and that vary in frequency between dune and nondune populations. These regions also show high linkage disequilibrium and high heterozygosity between, but not within, arrangements, consistent with the behaviour of large inversions, an inference subsequently validated in part by comparative genetic mapping. Genome–environment association analyses show that key environmental variables, including vegetation cover and soil nitrogen, are significantly associated with inversions. The inversions colocate with previously described “islands of differentiation,” and appear to play an important role in adaptive divergence and incipient speciation within H. petiolaris.     

Taxonomic differences shape the responses of freshwater aerobic anoxygenic phototrophic bacterial communities to light and predation

Aerobic anoxygenic phototrophic (AAP) bacteria are a phylogenetically diverse and ubiquitous group of prokaryotes that use organic matter but can harvest light using bacteriochlorophyll a. Although the factors regulating AAP ecology have long been investigated through field surveys, the few available experimental studies have considered AAPs as a group, thus disregarding the potential differential responses between taxonomically distinct AAP assemblages. Here, we used sequencing of the pufM gene to describe the diversity of AAPs in 10 environmentally distinct temperate lakes, and to investigate the taxonomic responses of AAP communities in these lakes when subjected to similar experimental manipulations of light and predator removal. The studied communities were clearly dominated by Limnohabitans AAP but presented a clear taxonomic segregation between lakes presumably driven by local conditions, which was maintained after experimental manipulations. Predation reduction (but not light exposure) caused significant compositional shifts across most assemblages, but the magnitude of these changes could not be clearly related to changes in bulk AAP abundances or taxonomic richness of AAP assemblages during experiments. Only a few operational taxonomic units, which differed taxonomically between lakes, were found to respond positively during experimental treatments. Our results highlight that different freshwater AAP communities respond differently to similar control mechanisms, highlighting that in‐depth knowledge on AAP diversity is essential to understand the ecology and potential role of these photoheterotrophs.     

Population studies of the wild tomato species Solanum chilense reveal geographically structured major gene-mediated pathogen resistance

Natural plant populations encounter strong pathogen pressure and defence-associated genes are known to be under selection dependent on the pressure by the pathogens. Here, we use populations of the wild tomato Solanum chilense to investigate natural resistance against Cladosporium fulvum, a well-known ascomycete pathogen of domesticated tomatoes. Host populations used are from distinct geographical origins and share a defined evolutionary history. We show that distinct populations of S. chilense differ in resistance against the pathogen. Screening for major resistance gene-mediated pathogen recognition throughout the whole species showed clear geographical differences between populations and complete loss of pathogen recognition in the south of the species range. In addition, we observed high complexity in a homologues of Cladosporium resistance (Hcr) locus, underlying the recognition of C. fulvum, in central and northern populations. Our findings show that major gene-mediated recognition specificity is diverse in a natural plant-pathosystem. We place major gene resistance in a geographical context that also defined the evolutionary history of that species. Data suggest that the underlying loci are more complex than previously anticipated, with small-scale gene recombination being possibly responsible for maintaining balanced polymorphisms in the populations that experience pathogen pressure.