Análise da expressão dos genes da subfamília DREB em resposta à seca em plantas de Coffea canephora Conilon

Coffea canephora is one of the most economically important coffee species and in Brazil, Conilon is the most widely cultivated plant of this species. Abiotic stresses such as temperature variations and drought periods are factors that significantly affect their production and tend to worsen with globally recognized climate changes. In an attempt to understand the molecular responses of coffee plants in water deficit conditions, recent studies have identified candidate genes (CGs) as CcDREB1D. This gene showed increased expression in response to drought in the leaves of clone 14 (drought tolerant) in relation to the clone 22 (sensitive to drought) of C. canephora Conilon. Based on these results, the identification of DREB genes and their subgroups (SGs) of C. canephora, the objective is to analyze in silico and also in vivo these genes expression in leaf and root of tolerant (14, 73 and 120) and sensitive clones (22) of C. canephora Conilon submitted or not to a water deficit. In silico expressions of all DREB genes were analyzed from the Coffee Genome Hub Database and in vivo expression was performed by the technique "reverse transcription-quantitative PCR" (RT-qPCR). In silico gene expression analysis was possible to identify DREB genes with potential responses to abiotic stresses, corroborating some validated in vivo results. In this analysis, several genes showed differential expression in response to drought among the SGs (IIV), the tolerant and sensitive clones and the leaf and root. These differentially expressed genes were identified as potential CGs and among them, it was found that most tolerant clones showed increased expression in relation to sensitive in response to drought, with higher expression levels for clones 14 and 73. These highest levels were observed in leaves compared to the roots and SG-I stood at greater number of genes expressed in response to drought. These results suggest that DREB CGs, as Cc05_g06840, Cc02_g03420 e Cc08_g13960, play an important role in the regulatory mechanisms of response to drought in C. canephora Conilon.

Expression profiling and sequence diversity of novel DREB genes from common bean (Phaseolus vulgaris L.) and their association with drought-related traits

Common bean is a major dietary component in several countries, but its productivity is negatively affected by abiotic stresses. Dissecting candidate genes involved in abiotic stress tolerance is a paramount step toward the improvement of common bean performance under such constraints. Thereby, this thesis presents a systematic analysis of the DEHYDRATION RESPONSIVE ELEMENT-BINDING (DREB) gene subfamily, which encompasses genes that regulate several processes during stress responses, but with limited information for common bean. First, a series of in silico analyses with sequences retrieved from the P. vulgaris genome on Phytozome supported the categorization of 54 putative PvDREB genes distributed within six phylogenetic subgroups (A-1 to A-6), along the 11 chromosomes. Second, we cloned four novel PvDREB genes and determined their inducibility-factors, including the dehydration-, salinity- and cold-inducible genes PvDREB1F and PvDREB5A, and the dehydration- and cold-inducible genes PvDREB2A and PvDREB6B. Afterwards, nucleotide polymorphisms were searched through Sanger sequencing along those genes, revealing a high number of single nucleotide polymorphisms within PvDREB6B by the comparison of Mesoamerican and Andean genotypes. The nomenclature of PvDREB6B is discussed in details. Furthermore, we used the BARCBean6K_3 SNP platform to identify and genotype the closest SNP to each one of the 54 PvDREB genes. We selected PvDREB6B for a broader study encompassing a collection of wild common bean accessions of Mesoamerican origin. The population structure of the wild beans was accessed using sequence polymorphisms of PvDREB6B. The genetic clusters were partially associated with variation in latitude, altitude, precipitation and temperature throughout the areas such beans are distributed. With an emphasis on drought stress, an adapted tube-screening method in greenhouse conditions enabled the phenotyping of several drought-related traits in the wild collection. Interestingly, our data revealed a correlation between root depth, plant height and biomass and the environmental data of the location of the accessions. Correlation was also observed between the population structure determined through PvDREB6B and the environmental data. An association study combining data from the SNP array and DREB polymorphisms enabled the detection of SNP associated with drought-related traits through a compressed mixed linear model (CMLM) analysis. This thesis highlighted important features of DREB genes in common bean, revealing candidates for further strategies aimed at improvement of abiotic stress tolerance, with emphasis on drought tolerance

水稻AP2/EREBP转录因子基因OsDRE和OsRAF的功能分析

AP2是一个大的转录因子家族，因其成员含有一个60-70 个氨基酸残基的保守结构域即AP2结构域而得名，它们的功能涉及植物花的发育以及植物对生物或非生物逆境的应答反应。根据它们所含的AP2 结构域的数目，这个家族可分为AP2亚家族和EREBP 亚家族。 AP2亚家族成员含两个AP2结构域，EREBP 亚家族成员含一个AP2结构域。一般来说，AP2 亚家族的成员主要参与植物发育过程的调控;EREBP 亚家族成员则主要参与对逆境的应答反应。按照它们响应外界刺激的类型和AP2结构域中结合顺式作用元件的核心氨基酸的不同，EREBP亚家族又可分为ERF和CBF/DREB两大类群，ERF 类主要响应生物类逆境的诱导，CBF/DREB类则响应干旱、低温等非生物胁迫的刺激。 根据AP2保守结构域搜索，水稻基因组中一共有147个AP2/EREBP成员，但其中功能得到证实的还非常有限。为了解更多AP2基因在植物生长发育过程中的功能，我们先从水稻基因组数据库中搜索到含有AP2/EREBP 结构域的推测基因序列，选择其中40个扩增并成功扩增出31个，将这些DNA片段点在尼龙膜上，然后用水稻叶片cDNA 作模板标记探针，与固定在膜上的推测基因杂交。杂交结果作为选择基因进行功能分析的重要依据。 OsDRE就是我们选择进行研究的一个表达较强的基因。首先，通过RACE 克隆得到OsDRE 的cDNA全长 1589bp，它编码318个氨基酸。Blast 搜索和保守结构域序列比对分析以及进化树分析显示它是一个新的ERF 基因。RT-PCR分析表明该基因在水稻各种组织中表达量比较一致，而且，OsDRE 既不对植物生长物质如乙烯，水杨酸（SA），茉莉酸甲酯（MJ），脱落酸（ABA），赤霉素（GA3），油菜素内酯（BR）的诱导起反应，同样也不响应环境因子如低温、干旱条件的处理。这些结果说明OsDRE是一个不响应胁迫相关因素的诱导的、组成型表达的水稻基因。用OsDRE的非保守区域构建的RNAi 载体转入水稻后未能使转基因水稻产生异常表型，然而，OsDRE在水稻和拟南芥中的过量表达都导致转基因植物出现植株矮小、开花延迟、生长周期延长以及育性降低等表型，说明OsDRE对生长和发育的影响在水稻和拟南芥中是一致的。 基于以上原因，我们选择在遗传分析方面有明显优势的拟南芥作为材料，对OsDRE基因功能进行研究并得出以下结论：（1）瞬时表达和随后的过量表达证明OsDRE定位于细胞核中，过量表达OsDRE引起转基因植株的生长周期变长、抽苔时间延迟和抽苔时莲座叶的数量增多;（2）过量表达OsDRE通过一种不影响细胞数量的方式抑制了细胞的膨胀从而导致植物器官以致整个植株变小，而且，在此过程中部分器官的形态也受到了影响;（3）OsDRE过量表达能激活已知位于乙烯信号途径下游的基因表达并且转基因植株幼苗在黑暗中出现下胚轴及根缩短变粗的现象，提示OsDRE 可能部分参与了乙烯信号途径下游的反应。 除此之外，我们还初步分析了另一个EREBP基因，并将其命名为OsRAF。氨基酸序列分析表明该基因与大麦的RAF 基因在蛋白水平上相似性最高。Northern 杂交结果进一步显示，与RAF 一样，OsRAF 也是根中优势表达的基因，并且它的表达量在乙烯或低温的诱导下增加。对转基因植株的观察和瞬时表达表明OsRAF 定位于细胞核中。 综上所述，对水稻基因OsDRE 和OsRAF的分析表明， OsDRE是一个新的ERF基因，它不受乙烯等因素的诱导并且过量表达该基因导致转基因植株出现细胞膨胀受到抑制等一系列的表型。另外，OsRAF在水稻根中优势表达并受乙烯和低温的诱导，目前，与之相关的功能研究正在进行。

水稻OsMYB3R-2 基因对逆境响应的功能研究

低温威胁水稻的生产，其中苗期和生殖阶段对寒害是最敏感的时期。在苗期，阶段性冷害使水稻幼苗生长延迟，甚至造成烂秧现象；在生殖阶段，无法预测的突然降温会导致水稻花粉不育，并致使水稻大幅减产。因此，对水稻逆境胁迫调控的分子机制的深入研究在理论和实践上具有重要的意义。本研究从东乡野生稻、栽培稻及其杂交后代的低温芯片中筛选对低温响应基因的分析着手，对其中一个受低温诱导上调的基因OsMYB3R-2 作进一步研究。生物信息学的分析表明OsMYB3R-2 编码一个R1R2R3 MYB 蛋白，利用基因枪瞬时转化法、酵母GAL4 系统和电泳迁移率变动分析发现OsMYB3R-2 蛋白能够定位在细胞核中、具有转录激活和DNA 结合特性，表现为MYB 转录因子的典型特征。 超表达OsMYB3R-2 的转基因水稻呈现幼苗的矮化和生长相对滞后的表型，对低温胁迫具有耐受性。盐抑制水稻种子的萌发，与野生型和反义的株系相比，OsMYB3R-2 超表达株系的萌发对盐敏感，表现为萌发过程及萌发之后幼苗的生长更加滞后。而OsMYB3R-2 转基因株系对干旱处理敏感。为了进一步寻找OsMYB3R-2 蛋白的靶序列及其调控的靶基因，我们利用电泳迁移率变动分析发现OsMYB3R-2 能够与有丝分裂特异的激活子（mitosis-specific activator）元件特异结合。在低温条件下，OsMYB3R-2 超表达能够激活水稻G2/M 期特异基因的表达，主要包括OsCycB1;1、OsCycB2;1、OsCycB2;2 和OsCDC20.1 等。另一方面，OsMYB3R-2 超表达能够增加根尖细胞的有丝分裂指数，这进一步说明OsMYB3R-2 参与了水稻细胞周期调控。EMSA、RT-PCR 和流式细胞仪分析的结果表明OsMYB3R-2 通过激活其靶基因OsCycB1;1 的表达参与水稻对低温胁迫的调控，该过程由细胞周期介导。 为了研究OsMYB3R-2 与水稻DREB/CBF 途径的关系，我们分析了转基因水稻中DREB/CBF 类基因及其可能调控的下游基因与OsMYB3R-2 的关系，RT-PCR 的结果表明超表达转基因植物中DREB 表达未见明显变化，而其下游基因OsCPT1 在低温条件下被激活表达。同时，转基因植物在低温条件下脯氨酸水平显著提高。这说明OsMYB3R-2 可能在水稻DREB/CBF 途径的下游参与调控。 总之，OsMYB3R-2 基因的超表达赋予转基因水稻在苗期对低温胁迫具有耐受性，并呈现矮化和生长滞后的表型。OsMYB3R-2 蛋白行使R1R2R3 MYB 转录因子的功能，在体外能够结合OsCycB1;1 和OsKNOLLE2 基因启动子中有丝分裂特异的激活子元件，在低温条件下激活了G2/M 期特异基因的表达，这些基因包括OsCycB1;1、OsCycB2;1、OsCycB2;2 和OsCDC20.1。低温条件下，在OsMYB3R-2 转基因超表达株系中OsCPT1 基因的转录被激活，细胞的游离脯氨酸的含量也显著增高。这些结果都表明OsMYB3R-2 基因在水稻的冷胁迫信号途径中起重要的作用，该过程受细胞周期及DREB/CBF 途径介导。 我们的实验结果暗示水稻对低温的耐受是通过分生组织细胞周期调控完成的，这个过程由OsMYB3R-2 等关键基因控制。

地锦（Parthenocissus tricuspidata）的遗传转化及抑菌活性研究

地锦（Parthenocissus tricuspidata）为葡萄科（Vitaceae）地锦属（Parthenocissus）多年生大型落叶木质藤本植物，集绿化、环境保护、药用价值为一体，开发利用前景非常广阔。为了进一步有效地利用及增加它的适应性，本论文对地锦的遗传转化及其抑菌活性进行了初步研究。 利用根癌农杆菌（Agrobacterium tumefaciens）介导对地锦进行遗传转化。所转外源目的基因为干旱应答因子结合蛋白DREB基因，克隆自拟南芥，受干旱应答基因启动子rd29Bp驱动。将此基因与pCAMBIA2301重组构建得到植物表达载体p2326。p2326携报告基因b-葡萄糖苷酸酶基因（gus）和选择基因新霉素磷酸转移酶基因（npt II）。然后将p2326导入根癌农杆菌EHA105，对地锦愈伤组织及外植体茎段进行转化。经3-4轮卡那霉素选择培养后，PCR及GUS组织染色验证，表明成功获得了转基因愈伤组织。 对地锦愈伤组织进行耐盐及脯氨酸含量测定。结果表明，转基因愈伤组织与非转基因愈伤组织相比，对高盐的耐受力有较大提高。在250 mM NaC1的继代培养基中，携DREB基因的愈伤组织能够存活20 d以上，而对照在10 d后大多数褐化死亡。高盐胁迫时转基因材料脯氨酸含量高于对照，并能够维持较长时间。 研究还发现，来自室外自然生长的地锦茎、叶，对根癌农杆菌有极强的抑制作用。 因此，对地锦的抑菌作用进行初步研究。 对一年中不同时期（分别采于4月、8月、12月）的地锦茎、叶进行抑菌活性初步研究。结果表明，12月份地锦叶片对所选细菌抑制作用最强。然后对其进行分溶剂萃取。分别用极性递增的有机溶剂依次提取地锦中的有效成分、逐级分离、浓缩干燥，得到石油醚部、乙酸乙酯部、正丁醇部和水部等不同极性溶剂萃取物。选择革兰氏阳性菌和阴性菌共5种对得到的各部分粗提物分别做抑菌实验，表明正丁醇部的抑菌活性最强，水部提取物有一定抑制作用，而石油醚部、乙酸乙酯部没有表现出明显抑菌作用。 地锦正丁醇提取物对大肠杆菌、枯草杆菌、短小芽孢杆菌、农杆菌及酵母菌的最低抑制浓度（MIC）分别为0.25，0.3，0.25，0.3，1g/mL。其抑菌活性随着浓度增加而增强，而且抑菌活性具有较好的热稳定性。 研究发现地锦所产生的抑菌物质不仅对无耐药性的细菌具有抑制作用，而且还对某些耐药性细菌具有抑制作用。目前，细菌对抗生素的耐药性已成为全球关注的问题，寻找新型抗生素已迫在眉捷，地锦抑菌物质的研究为新抗菌药物的研制开发提供了新思路。 上述研究结果，为地锦的遗传改良及开发利用打下基础。

Validation of reference genes for RT-qPCR normalization in common bean during biotic and abiotic stresses

Selection of reference genes is an essential consideration to increase the precision and quality of relative expression analysis by the quantitative RT-PCR method. The stability of eight expressed sequence tags was evaluated to define potential reference genes to study the differential expression of common bean target genes under biotic (incompatible interaction between common bean and fungus Colletotrichum lindemuthianum) and abiotic (drought; salinity; cold temperature) stresses. The efficiency of amplification curves and quantification cycle (C (q)) were determined using LinRegPCR software. The stability of the candidate reference genes was obtained using geNorm and NormFinder software, whereas the normalization of differential expression of target genes [beta-1,3-glucanase 1 (BG1) gene for biotic stress and dehydration responsive element binding (DREB) gene for abiotic stress] was defined by REST software. High stability was obtained for insulin degrading enzyme (IDE), actin-11 (Act11), unknown 1 (Ukn1) and unknown 2 (Ukn2) genes during biotic stress, and for SKP1/ASK-interacting protein 16 (Skip16), Act11, Tubulin beta-8 (beta-Tub8) and Unk1 genes under abiotic stresses. However, IDE and Act11 were indicated as the best combination of reference genes for biotic stress analysis, whereas the Skip16 and Act11 genes were the best combination to study abiotic stress. These genes should be useful in the normalization of gene expression by RT-PCR analysis in common bean, the most important edible legume.

Superexpressão do gene dehidrina de Arachis duranensis em plantas transgênicas de Arabidopsis thaliana

Dissertação (mestrado)—Universidade de Brasília, Departamento de Botânica, Programa de Pós-Graduação em Botânica, 2016.