Caracterização de mutantes condicionais do gene da desoxi-hipusina sintase em Saccharomyces cerevisiae

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Sensitivity to endothelin-1 is decreased in isolated livers of endothelial constitutive nitric oxide synthase knockout mice

ABSTRACT: BACKGROUND: Hepatic sinusoidal resistance is regulated by vasoactive factors including endothelin-1 (ET-1) and nitric oxide (NO). In the absence of NO, vasoconstrictor response to endothelin is expected to predominate. Therefore, we hypothesized sensitivity to endothelin to be increased in mice lacking the endothelial cell NO synthase gene. Response of vascular resistance to endothelin was assessed in the in situ perfused liver of endothelial constitutive nitric oxide synthase (ecNOS) knockout and wild type mice. Livers were also harvested for RNA and protein isolation for quantitative PCR and Western blotting, respectively. The expression of endothelin receptors, isoenzymes of NO synthase, heme-oxygenase and adrenomedullin was quantified. RESULTS: Endothelin increased hepatic vascular resistance in a dose-dependent manner in both strains; however, this increase was significantly less in ecNOS knockout mice at physiologic concentrations. Expression of heme-oxygenases and adrenomedullin was similar in both groups, whereas inducible nitric oxide synthase (iNOS) protein was not detectable in either strain. mRNA levels of pre-pro-endothelin-1 and ETB receptor were comparable in both strains, while mRNA for ETA receptor was decreased in ecNOS knockouts. CONCLUSION: Livers of ecNOS knockout mice have a decreased sensitivity to endothelin at physiologic concentrations; this is associated with a decreased expression of ETA receptors, but not with other factors, such as iNOS, ETB receptors, adrenomedullin or heme-oxygenase. Further studies targeting adaptive changes in ETA receptor distribution and/or intracellular signaling downstream of the receptor are indicated.

Identification of thyroid hormone response elements in the human fatty acid synthase promoter

To investigate the regulation of the human fatty acid synthase gene by the thyroid hormone triiodothyronine, various constructs of the human fatty acid synthase promoter and the luciferase reporter gene were transfected in combination with plasmids expressing the thyroid hormone and the retinoid X receptors in HepG2 cells. The reporter gene was activated 25-fold by the thyroid hormone in the presence of the thyroid hormone receptor. When both the thyroid hormone and the retinoid X receptors were expressed in HepG2 cells, there was about a 100-fold increase in reporter gene expression. 5′-Deletion analysis disclosed two thyroid hormone response elements, TRE1 (nucleotides −870 to −650) and TRE2 (nucleotides −272 to −40), in the human fatty acid synthase promoter. The presence of thyroid hormone response elements in these two regions of the promoter was confirmed by cloning various fragments of these two regions in the minimal thymidine kinase promoter−luciferase reporter gene plasmid construct and determining reporter gene expression. The results of this cloning procedure and those of electrophoretic mobility shift assays indicated that the sequence GGGTTAcgtcCGGTCA (nucleotides −716 to −731) represents TRE1 and that the sequence GGGTCC (nucleotides −117 to −112) represents TRE2. The sequence of TRE1 is very similar to the consensus sequence of the thyroid hormone response element, whereas the sequence of TRE2 contains only a half-site of the thyroid hormone response element consensus motif because it lacks the direct repeat. The sequences on either side of TRE2 seem to influence its response to the thyroid hormone and retinoid X receptors.

Coordinate regulation of lipogenic gene expression by androgens: Evidence for a cascade mechanism involving sterol regulatory element binding proteins

To gain more insight into the molecular mechanisms by which androgens stimulate lipogenesis and induce a marked accumulation of neutral lipids in the human prostate cancer cell line LNCaP, we studied their impact on the expression of lipogenic enzymes. Northern blot analysis of the steady-state mRNA levels of seven different lipogenic enzymes revealed that androgens coordinately stimulate the expression of enzymes belonging to the two major lipogenic pathways: fatty acid synthesis and cholesterol synthesis. In view of the important role of the recently characterized sterol regulatory element binding proteins (SREBPs) in the coordinate induction of lipogenic genes, we examined whether the observed effects of androgens on lipogenic gene expression are mediated by these transcription factors. Our findings indicate that androgens stimulate the expression of SREBP transcripts and precursor proteins and enhance the nuclear content of the mature active form of the transcription factor. Moreover, by using the fatty acid synthase gene as an experimental paradigm we demonstrate that the presence of an SREBP-binding site is essential for its regulation by androgens. These data support the hypothesis that SREBPs are involved in the coordinate regulation of lipogenic gene expression by androgens and provide evidence for the existence of a cascade mechanism of androgen-regulated gene expression.

Three 1-Aminocyclopropane-1-Carboxylate Synthase Genes Regulated by Primary and Secondary Pollination Signals in Orchid Flowers1

The temporal and spatial expression patterns of three 1-aminocyclopropane-1-carboxylate (ACC) synthase genes were investigated in pollinated orchid (Phalaenopsis spp.) flowers. Pollination signals initiate a cascade of development events in multiple floral organs, including the induction of ethylene biosynthesis, which coordinates several postpollination developmental responses. The initiation and propagation of ethylene biosynthesis is regulated by the coordinated expression of three distinct ACC synthase genes in orchid flowers. One ACC synthase gene (Phal-ACS1) is regulated by ethylene and participates in amplification and interorgan transmission of the pollination signal, as we have previously described in a related orchid genus. Two additional ACC synthase genes (Phal-ACS2 and Phal-ACS3) are expressed primarily in the stigma and ovary of pollinated orchid flowers. Phal-ACS2 mRNA accumulated in the stigma within 1 h after pollination, whereas Phal-ACS1 mRNA was not detected until 6 h after pollination. Similar to the expression of Phal-ACS2, the Phal-ACS3 gene was expressed within 2 h after pollination in the ovary. Exogenous application of auxin, but not ACC, mimicked pollination by stimulating a rapid increase in ACC synthase activity in the stigma and ovary and inducing Phal-ACS2 and Phal-ACS3 mRNA accumulation in the stigma and ovary, respectively. These results provide the basis for an expanded model of interorgan regulation of three ACC synthase genes that respond to both primary (Phal-ACS2 and Phal-ACS3) and secondary (Phal-ACS1) pollination signals.

The five families of sucrose-phosphate synthase genes in Saccharum spp. are differentially expressed in leaves and stem

Sucrose-phosphate synthase (SPS) is a key enzyme in the pathway of sucrose synthesis. Five different gene families encoding SPS have been reported in the Poaceae [Castleden CK, Aoki N, Gillespie VJ, MacRae EA, Quick WP, Buchner P, Foyer CH, Furbank RT, Lunn JE (2004) Evolution and function of the sucrose-phosphate synthase gene families in wheat and othergrasses. PlantPhysiology 135, 1753-1764]. Expression of the five families in leaf and stem tissues of Saccharum spp. at different stages of development was determined by quantitative real-time PCR. The type B and C families of SPS genes were predominantly expressed in both immature and mature leaves, whereas the two subfamilies making up the type D family were expressed at similar levels in all tissues examined. In the type A family, expression was lowest in leaves and increased from the meristem region down to internode 7 of the stem.

Delayed flowering in pineapples (Ananas comosus (L.) Merr.) caused by co-suppression of the ACACS2 gene

Natural flower induction is a major pineapple industry problem. It usually occurs when shortening days and low temperatures give raise to increased ethylene production in the leaf tissue and plant stem apex which in turn stimulates flowering. Natural flowering fruit matures 4 to 6 weeks ahead of the normal summer harvest resulting in the need for extra harvest passes and considerable yield losses. Ethylene is produced through the sequential action of ACC synthase and ACC oxidase. Our team has cloned an ACC synthase gene from pineapple (ACACS2), which is expressed in meristems and activated under the environmental conditions that induce flowering in nature. Genetic constructs have been produced containing ACACS2 in sense orienta¬tion to induce silencing of the host gene in the plant by co-suppression mechanisms. Two independent lines of transgenic plants have been produced and field trials have been conducted in Queensland for four years in order to study the characteristics of the transgenic lines. We have identified a group of transgenic plants demonstrating inherited flowering delay and confirmed co-suppression of the ACACS2 gene due to methylation.

Seawater carbonate chemistry, mass, length and gene expression of Sepia officinalis during experiments, 2011

The specific transporters involved in maintenance of blood pH homeostasis in cephalopod molluscs have not been identified to date. Using in situ hybridization and immuno histochemical methods, we demonstrate that Na+/K+-ATPase (soNKA), a V-type H+-ATPase (soV-HA), and Na+/HCO3- cotransporter (soNBC) are co-localized in NKA-rich cells in the gills of Sepia officinalis. mRNA expression patterns of these transporters and selected metabolic genes were examined in response to moderately elevated seawater pCO2 (0.16 and 0.35 kPa) over a time-course of six weeks in different ontogenetic stages. The applied CO2 concentrations are relevant for ocean acidification scenarios projected for the coming decades. We determined strong expression changes in late stage embryos and hatchlings, with one to three log2-fold reductions in soNKA, soNBCe, socCAII and COX. In contrast, no hypercapnia induced changes in mRNA expression were observed in juveniles during both short- and long-term exposure. However a transiently increased demand of ion regulatory demand was evident during the initial acclimation reaction to elevated seawater pCO2. Gill Na+/K+-ATPase activity and protein concentration were increased by approximately 15% in during short (2-11 day), but not long term (42 day) exposure. Our findings support the hypothesis that the energy budget of adult cephalopods is not significantly compromised during long-term exposure to moderate environmental hypercapnia. However, the down regulation of ion-regulatory and metabolic genes in late stage embryos, taken together with a significant reduction in somatic growth, indicates that cephalopod early life stages are challenged by elevated seawater pCO2.

Towards the biofortification of banana fruit for enhanced micronutrient content

In Uganda, vitamin A deficiency (VAD) and iron deficiency anaemia (IDA) are major public health problems with between 15-32% of children under 5 years of age showing VAD and 73% being anaemic. This is largely due to the fact that the staple food crop of the country, banana, is low in pro-vitamin A and iron, therefore leading to dietary deficiencies. Although worldwide progress has been made to control VAD and IDA through supplementation, food fortification and diet diversification, their long term sustainability and impact in developing countries such as Uganda is limited. The approach taken by researchers at Queensland University of Technology (QUT), Australia, in collaboration with the National Agricultural Research Organization (NARO), Uganda, to address this problem, is to generate consumer acceptable banana varieties with significantly increased levels of pro-vitamin A and iron in the fruit using genetic engineering techniques. Such an approach requires the use of suitable, well characterised genes and promoters for targeted transgene expression. Recently, a new banana phytoene synthase gene (APsy2a) involved in the synthesis of pro-vitamin A (pVA) carotenoids was isolated from a high â-carotene banana (F’ei cv Asupina). In addition, sequences of banana ferritin, an iron storage protein, have been isolated from Cavendish banana. The aim of the research described in this thesis was to evaluate the function of these genes to assess their suitability for the biofortification of banana fruit. In addition, a range of banana-derived promoters were characterised to determine their suitability for controlling the expression of transgenes in banana fruit. Due to the time constraints involved with generating transgenic banana fruit, rice was used as the model crop to investigate the functionality of the banana-derived APsy2a and ferritin genes. Using Agrobacterium-mediated transformation, rice callus was transformed with APsy2a +/- the bacterial-derived carotene desaturase gene (CrtI) each under the control of the constitutive maize poly-ubiquitin promoter (ZmUbi) or seed-specific rice glutelin1 (Gt1) promoter. The maize phytoene synthase (ZmPsy1) gene was included as a control. On selective media, with the exception of ZmUbi-CrtI-transgenic callus, all antibiotic resistant callus displayed a yellow-orange colour from which the presence of â-carotene was demonstrated using Raman spectroscopy. Although the regeneration of plants from yellow-orange callus was difficult, 16 transgenic plants were obtained and characterised from callus transformed with ZmUbi-APys2a alone. At least 50% of the T1 seeds developed a yellow-orange coloured callus which was found to contain levels of â-carotene ranging from 4.6-fold to 72-fold higher than that in non-transgenic rice callus. Using the seed-specific Gt1 promoter, 38 transgenic rice plants were generated from APsy2a-CrtI-transformed callus while 32 plants were regenerated from ZmPsy1-CrtI-transformed callus. However, when analysed for presence of transgene by PCR, all transgenic plants contained the APsy2a, ZmPsy1 or CrtI transgene, with none of the plants found to be co-transformed. Using Raman spectroscopy, no â-carotene was detected in-situ in representative T1 seeds. To investigate the potential of the banana-derived ferritin gene (BanFer1) to enhance iron content, rice callus was transformed with constitutively expressed BanFer1 using the soybean ferritin gene (SoyFer) as a control. A total of 12 and 11 callus lines independently transformed with BanFer1 and SoyFer, respectively, were multiplied and transgene expression was verified by RT-PCR. Pearl’s Prussian blue staining for in-situ detection of ferric iron showed a stronger blue colour in rice callus transformed with BanFer1 compared to SoyFer. Using flame atomic absorption spectrometry, the highest mean amount of iron quantified in callus transformed with BanFer1 was 30-fold while that obtained using the SoyFer was 14-fold higher than the controls. In addition, ~78% of BanFer1-transgenic callus lines and ~27% of SoyFer-transgenic callus lines had significantly higher iron content than the non-transformed controls. Since the genes used for enhancing micronutrient content need to be expressed in banana fruit, the activity of a range of banana-derived, potentially fruit-active promoters in banana was investigated. Using uidA (GUS) as a reporter gene, the function of the Expansin1 (MaExp1), Expansin1 containing the rice actin intron (MaExp1a), Expansin4 (MaExp4), Extensin (MaExt), ACS (MaACS), ACO (MaACO), Metallothionein (MaMT2a) and phytoene synthase (APsy2a) promoters were transiently analysed in intact banana fruit using two transformation methods, particle bombardment and Agrobacterium-mediated infiltration (agro-infiltration). Although a considerable amount of variation in promoter activity was observed both within and between experiments, similar trends were obtained using both transformation methods. The MaExp1 and MaExp1a directed high levels of GUS expression in banana fruit which were comparable to those observed from the ZmUbi and Banana bunchy top virus-derived BT4 promoters that were included as positive controls. Lower levels of promoter activity were obtained in both methods using the MaACO and MaExt promoters while the MaExp4, MaACS, and APsy2a promoters directed the lowest GUS activity in banana fruit. An attempt was subsequently made to use agro-infiltration to assess the expression of pVA biosynthesis genes in banana fruit by infiltrating fruit with constructs in which the ZmUbi promoter controlled the expression of APsy2a +/- CrtI, and with the maize phytoene synthase gene (ZmPsy1) included as a control. Unfortunately, the large amount of variation and inconsistency observed within and between experiments precluded any meaningful conclusions to be drawn. The final component of this research was to assess the level of promoter activity and specificity in non-target tissue. These analyses were done on leaves obtained from glasshouse-grown banana plants stably transformed with MaExp1, MaACO, APsy2a, BT4 and ZmUbi promoters driving the expression of the GUS gene in addition to leaves from a selection of the same transgenic plants which were growing in a field trial in North Queensland. The results from both histochemical and fluorometric GUS assays showed that the MaExp1 and MaACO promoters directed very low GUS activities in leaves of stably transformed banana plants compared to the constitutive ZmUbi and BT4 promoters. In summary, the results from this research provide evidence that the banana phytoene synthase gene (APsy2a) and the banana ferritin gene (BanFer1) are functional, since the constitutive over-expression of each of these transgenes led to increased levels of pVA carotenoids (for APsy2a) and iron content (for BanFer1) in transgenic rice callus. Further work is now required to determine the functionality of these genes in stably-transformed banana fruit. This research also demonstrated that the MaExp1 and MaACO promoters are fruit-active but have low activity in non-target tissue (leaves), characteristics that make them potentially useful for the biofortification of banana fruit. Ultimately, however, analysis of fruit from field-grown transgenic plants will be required to fully evaluate the suitability of pVA biosynthesis genes and the fruit-active promoters for fruit biofortification.

Secondary metabolites in Gerbera hybrida

Plants produce a diversity of secondary metabolites, i.e., low-molecular-weight compounds that have primarily ecological functions in plants. The flavonoid pathway is one of the most studied biosynthetic pathways in plants. In order to understand biosynthetic pathways fully, it is necessary to isolate and purify the enzymes of the pathways to study individual steps and to study the regulatory genes of the pathways. Chalcone synthases are key enzymes in the formation of several groups of flavonoids, including anthocyanins. In this study, a new chalcone synthase enzyme (GCHS4), which may be one of the main contributors to flower colour, was characterised from the ornamental plant Gerbera hybrida. In addition, four chalcone synthase-like genes and enzymes (GCHS17, GCHS17b, GCHS26 and GCHS26b) were studied. Spatial expression of the polyketide synthase gene family in gerbera was also analysed with quantitative RT-PCR from 12 tissues, including several developmental stages and flower types. A previously identified MYB transcription factor from gerbera, GMYB10, which regulates the anthocyanin pathway, was transferred to gerbera and the phenotypes were analysed. Total anthocyanin content and anthocyanidin profiles of control and transgenic samples were compared spectrophotometrically and with HPLC. The overexpression of GMYB10 alone was able to change anthocyanin pigmentation: cyanidin pigmentation was induced and pelargonidin pigmentation was increased. The gerbera 9K cDNA microarray was used to compare the gene expression profiles of transgenic tissues against the corresponding control tissues to reveal putative target genes for GMYB10. GMYB10 overexpression affected the expression of both early and late biosynthetic genes in anthocyanin-accumulating transgenic tissues, including the newly isolated gene GCHS4. Two new MYB domain factors, named as GMYB11 and GMYB12, were also upregulated. Gene transfer is not only a powerful tool for basic research, but also for plant breeding. However, crop improvement by genetic modification (GM) remains controversial, at least in Europe. Many of the concerns relating to both human health and to ecological impacts relate to changes in the secondary metabolites of GM crops. In the second part of this study, qualitative and quantitative differences in cytotoxicity and metabolic fingerprints between 225 genetically modified Gerbera hybrida lines and 42 non-GM Gerbera varieties were compared. There was no evidence for any major qualitative and quantitative changes between the GM lines and non-GM varieties. The developed cell viability assays offer also a model scheme for cell-based cytotoxicity screening of a large variety of GM plants in standardized conditions.

青蒿开花与青蒿素生物合成相关性的研究-金丝桃和百金花二苯甲酮合酶基因的克隆，异源表达及功能分析

第一部分：青蒿开花与青蒿素生物合成相关性的研究 青蒿素是从中药青蒿中分离出的倍半萜内酯化合物，目前是世界上唯一有效的治疗脑型疟疾和抗氯喹恶性疟疾的药物。青蒿植株中青蒿素含量在开花期最高，但是目前尚不清楚开花与青蒿素生物合成的关系。为此，我们用光周期（短日照）诱导青蒿提前开花，不仅同时获得了开花与不开花的青蒿植株，而且还成功地在同一植株上诱导部分分枝开花，另一部分分枝保持营养生长状态。这一实验体系为研究青蒿开花与青蒿素生物合成的相关性奠定了基础。实验结果表明，开花与不开花青蒿植株青蒿素含量有明显差异。开花植株的青蒿素含量在前2周内逐渐提高，第三周（开花期）达到最高，并保持一周左右，在随后的2周内下降。青蒿植株开花后，叶片便开始老化变黄，逐渐死亡。未开花青蒿植株的青蒿素含量动态在前三周内与开花植株类似，但是这种高青蒿素含量状态能保持较长时间，至少在随后的2周内没有下降。未开花植株的叶片依然保持绿色。这一结果表明，开花不是导致青蒿素含量提高的直接原因。 扫描电镜观察结果表明，幼嫩叶片上的毛状腺体( trichrome)结构是完整的，而在老化的叶片上，则观察到了相当比例(40-50%)破损的腺体。这可能是导致青蒿素含量下降的直接原因。 不同生态型青蒿对光周期的反应是不同的。在北京地区，本地青蒿在8月初便开始开花，而来自四川武陵的青蒿则要到9月份才能开花。根据这一特性，采用“南蒿北栽”的方法，能够使青蒿保持较长时间的营养生长状态，延长适于采收的时间。 第二部分：金丝桃和百金花二苯甲酮合酶基因的克隆，异源表达及功能分析 植物次生代谢物山屯酮( Xanthones)仅存在于龙胆科和藤黄科植物中。它们具有抑制单胺氧化酶，细胞毒素及抗肿瘤活性。 含有1 3个碳原子的二苯甲酮是山屯酮生物合成的中间产物，是由二苯甲酮合酶催化合成的，这一反应是山屯酮生物合成的关键步骤。二苯甲酮合酶已经在金丝桃和百金花细胞悬浮培养系统中检测到，并进行了细致的生化水平上的研究。本研究是在上述研究的基础上，进一步克隆该酶的基因，并进行异源表达及功能分析工作，以便更好地了解和调控山屯酮的生物合成。 用PCR和RT-PCR技术，从金丝桃cDNA文库和逆转录产物中分别克隆到一个基因HBPS1和HBPS2，从百金花cDNA文库中克隆到一个基因CBPS1。HBPS1含有1402个碱基，其开放阅读框架编码390个氨基酸，分子量为42.7 kDa，等电点为6.55。HBPS2含有1398个碱基，其开放阅读框架编码395个氨基酸，分子量为42.8 kDa，等电点为5.78。CBPS1含有1383个碱基，其开放阅读框架编码389个氨基酸，分子量为42.7 kDa，等电点为7.88。与GenBank中序列同源性比较结果表明：在氨基酸水平上，HBPS1与茶（Camellia sinensis）查尔酮合酶的同源性高达92%，HBPS2与萝卜（Raphanus sativus）查尔酮合酶的同源性为64%，CBPS1与茶（Camellia sinensis）查尔酮合酶的同源性为71%。HBPS1与HBPS2的同源性仅为62%。 将三个新克隆的基因的ORF整合到载体pGEX-G上的谷胱甘肽还原酶S基因下游，构建成转化质粒，并在大肠杆菌中诱导表达。结果表明，这三个基因的ORF片段均能被表达成约68 kDa的产物，这与期望的结果一致。 活性检测结果表明，HBPS1是查尔酮合成酶，其底物为香豆酰辅酶A和丙二酸单酰辅酶A，对这两种底物的亲和性KM分别为：香豆酰辅酶A 2.8μM，丙二酸单酰辅酶A，11.2μM。最适反应条件是350C，pH7.0，DTT浓度10 μM。 HBPS2是二苯甲酮合酶，其底物是苯甲丙氨酰辅酶A，和丙二酸单酰辅酶A，对这两种底物的亲和性KM分别为：苯甲丙氨酰辅酶A 2.4 μM，丙二酸单酰辅酶A 9.6μM。最适反应条件是350C，pH 6.5，DTT浓度50 μM。而CBPS1则没有检测到任何活性。从同一种植物中同时获得了查尔酮合酶和二苯甲酮合酶，对研究这两种十分相近的酶的差异表达，酶促反应机制等问题将非常有利。

青蒿反义鲨烯合酶基因对烟草的转化

利用反义技术研究生物代谢途径以及对其生物合成进行调控成为植物次生代谢研究领域内一个重要手段之一，并与新兴的RNAi技术一起成为本领域内重要的研究热点。在植物类异戊二烯代谢途径中存在着羟甲基戊二酰辅酶A还原酶(HMGR)、法呢基焦磷酸合酶（FPS）和鲨烯合酶（SQS）等几种关键的分支酶，他们被认为在异戊二烯类的生物合成中发挥着关键的调节作用。其中，鲨烯合酶处于HMGR和FPS的下游，并与倍半萜合酶等利用共同的前体－法呢基二磷酸（FPP），以FPP起始合成一系列的下游产物。因此，FPP成为类异戊二烯途径中的关键调节点之一。本论文基于此目的，利用反义技术研究了FPP合成鲨烯这一途径受到抑制对其他以FPP为生物合成前体的代谢支路的影响。 利用植物双元转化载体pBI121，将青蒿中鲨烯合酶基因的cDNA（约1.5kb）序列插入到pBI121中，取代原有的GUS序列，构建成植物转化载体pBIASS。以根癌农杆菌为介导，将青蒿鲨烯合酶反义基因序列导入到烟草，整合到其基因组中 ，成功获得转基因植株。对转基因烟草进行分子检测表明，外源鲨烯合酶基因的序列已经稳定整合到烟草基因组中，并对内源的烟草鲨烯合酶基因表达产生影响。转基因烟草中检测到内源鲨烯合酶基因的mRNA的水平降低。对鲨烯合酶下游产物之一的胆固醇的含量分析显示，活性减低的鲨烯合酶使胆固醇的生物合成下降约40％左右。同时，另一条以FPP为共同前体的二萜代谢途径产物之一GA3的含量得到了提高，比对照提高约30％。

反义鲨烯合酶基因表达对青蒿素生物合成的影响

青蒿素是从中药青蒿中提取的新型抗疟药物，然而，青蒿素在青蒿中的含量非常低。近年来，随着青蒿素生物合成途径相关酶基因的克隆，基因工程成为提高青蒿素含量的有效途径之一。在对青蒿进行遗传转化过程中，高效稳定的丛生芽诱导体系是青蒿转化成功的关键。然而，随着继代次数的增多，青蒿丛生芽诱导能力存在退化现象。本文首先研究了滤纸对青蒿丛生芽诱导的影响和在遗传转化中的应用，进而研究了反义鲨烯合酶基因表达对青蒿素生物合成的影响。主要结果如下： 研究了在丛生芽诱导培养基上加铺滤纸对青蒿丛生芽诱导的影响，结果发现，加铺滤纸后青蒿丛生芽诱导率显著提高，丛生芽诱导率能够达到97%左右。在此高效丛生芽诱导体系的基础上，我们进一步探讨了滤纸在青蒿遗传转化中的应用。结果表明，在筛选培养基上加铺一层滤纸，青蒿的抗性丛生芽诱导率能够达到59.7%，其中在12.5%的抗性丛生芽中能够得到抗性生根植株，生根植株PCR检测均为阳性，在部分PCR检测阳性的植株中检测到了GUS的稳定表达。 利用上述改进的青蒿遗传转化体系，我们得到了反义鲨烯合酶基因的青蒿转化植株。PCR检测和Southern杂交检测结果证明了反义鲨烯合酶基因已经整合到青蒿基因组中。RT-PCR检测发现，在转基因株系ASQ3和ASQ5中鲨烯合酶基因在mRNA水平上得到部分抑制，鲨烯含量比对照降低了20%左右;青蒿素的含量分别提高了23.2%和21.5%，结果表明抑制鲨烯合酶表达能够有效促进青蒿中青蒿素的生物合成。

诱导子对水母雪莲次生代谢的影响及雪莲查耳酮合成酶基因克隆

水母雪莲(Saussurea medusa Maxim)为菊科凤毛菊属植物,是名贵中药材。为解决雪莲资源匮乏，我们实验室通过植物组织培养技术，成功的建立起水母雪莲细胞和毛状根体系。通过对它的药理实验及化学成分分析，主要成分为黄酮类物质和紫丁香甙单体。为了进一步提高这些物质在水母雪莲培养物中的含量，本文开展通过添加外源诱导子手段来调控水母雪莲次生代谢合成途径。 利用水杨酸（SA）和酵母提取物（YE）作为外源诱导子，添加到水母雪莲细胞系和毛状根系培养基中，研究诱导子不同添加浓度和不同添加时间对水母莲细胞系和毛状根系的生长及次生物质合成的诱导效应。实验结果发现：对于细胞系来说，SA比YE的诱导效果要好，低浓度SA处理时，不仅能促进细胞的生长，还能提高水母雪莲细胞中黄酮化合物和紫丁香甙的含量。其中，在细胞生长周期的第6天添加终浓度为20 μM的SA，诱导效果表现最佳。在此条件下，细胞内总黄酮产量达到532 mg/l，紫丁香甙为630 mg/l，分别比对照提高了130%，和150%。对于毛状根体系来说，SA和YE生长早期添加会抑制毛状根生长。总体上，YE的诱导效果比SA明显。在第10天添加终浓度为40 μg/ml的YE，总黄酮达到741 mg/l，紫丁香甙达到303 mg/l，分别是对照的2.8和2.5倍。 同时研究了20 μM和100 μM SA诱导下，黄酮合成途径中相关酶的变化。发现，低浓度的SA能在短时间内诱导CHS和CHI表达，24h后PAL酶活性升高到对照的7.5倍，而48 h总黄酮的含量检测到最高值。因此可以初步断定，SA诱导苯基苯丙烷类物质的积累与CHS和CHI表达，PAL酶活性提高有关。 另外，从水母雪莲cDNA中克隆到雪莲黄酮合成途径的第一个关键酶—查耳酮合成酶基因（SmCHS）全长cDNA。此cDNA序列全长为1313bp，其编码的蛋白为389个氨基酸，推测的氨基酸序列与许多物种都高度同源，同源性高达88%。生物信息学分析，SmCHS具有CHS－like保守结构域，其二级结构与苜蓿的CHS十分相似，且苜蓿中的CHS酶活性中心的关键氨基酸位点在SmCHS也一致对应相同，没有突变。因此可以初步推测这个SmCHS应该具有查耳酮合成酶功能。并进一步构建SmCHS植物表达载体，转化拟南芥chs突变体，通过功能互补分析研究此基因的功能。由于时间关系这部分研究尚在进行中。

中药青蒿紫穗槐二烯合酶基因表达及调控的研究

青蒿素是从我国传统药用植物中药青蒿（Artemisia annua L.）中提取的新型抗疟特效药，其生物合成途径属于植物类异戊二烯代谢途径。目前，青蒿素生物合成的组织部位及其调控机制仍不完全清楚。紫穗槐二烯合酶（amorpha-4， 11-diene synthase, ADS）作为青蒿素生物合成分支途径的第一个关键酶，催化倍半萜化合物的通用前体法呢基焦磷酸环化，生成紫穗槐二烯。本论文通过对ADS 表达特性的分析，研究了青蒿素生物合成的组织特异性及其调控机制，主要研究结果如下： 一．紫穗槐二烯合酶基因启动子功能的研究 从青蒿高产株系001 中克隆得到了2850 bp 的ADS 启动子调控区。通过比较5’RACE 的测序结果与启动子序列，确定转录起始位点位于翻译起始位点上游44 bp，TATA 盒下游27 bp。该启动子序列包含的顺式作用元件有脱落酸应答元件(ABRE )、乙烯应答元件(ERE)、生长素应答元件(AUXRE）等植物激素反应元件，以及低温应答元件（LTRE）、高温应答元件（HSE）等与逆境有关的反应元件，还有与真菌诱导有关的W-box 元件等。将不同长度ADS 启动子与报告基因GUS 融合，构建了植物表达载体，通过农杆菌介导的方法获得稳定整合的转基因烟草。经过组织化学、GUS 荧光活性检测及RT-PCR 分析，发现该启动子的转录活性很低，无法通过GUS 染色进行观察。GUS 荧光活性检测及RT-PCR 结果表明，转录起始位点上游346 bp 是ADS 基础表达所必需的。高温、低温、干旱、水杨酸、茉莉酸甲酯等处理均能促进青蒿中ADS 的表达，而脱落酸和乙烯的作用效果较小，与启动子序列分析的结果并不完全一致。 二．紫穗槐二烯合酶基因表达特性的研究 以青蒿高产株系001 为材料，在基因和蛋白水平揭示了ADS 的表达特性。RT-PCR 和Western 分析结果表明，ADS 在幼叶和花蕾中大量表达，在老叶和完全开放的花中表达量很低，而在青蒿的根和茎中几乎检测不到ADS 的表达。石蜡切片和整体原位杂交的结果表明，ADS 在顶端分生组织、叶原基及分泌腺毛中表达，在非分泌的T 型腺毛中不表达。当叶片完全展开后，ADS 只在分泌腺毛中表达，而且随着叶片的生长和老化，ADS 的表达量逐渐减少。另一个非常有趣的发现是同一叶片上的分泌腺毛，有些有ADS 的表达，有些则没有。用强光、低温、高温和水杨酸等因素处理后，有ADS 表达的分泌腺毛的比例没有明显的变化。 三．外源水杨酸促进青蒿素的生物合成 研究了外源水杨酸对青蒿素生物合成的影响，结果表明：1 mM 水杨酸处理后，青蒿叶片中的游离态水杨酸含量快速增加，处理后4 h 达到 0.79 μg g-1 FW，是对照的3.5 倍。外源水杨酸能够抑制青蒿中过氧化氢酶活性，提高抗坏血酸过氧化物酶活性，并通过对抗氧化酶活性的抑制引起青蒿体内活性氧水平的迅速升高。在处理后4 h，青蒿中H2O2 和O2-的含量分别达到对照的2.1 倍和2.4 倍。青蒿素含量在水杨酸处理后的前8 h 缓慢升高，随后升高的速度增加。外源水杨酸处理后8 h 和96 h，青蒿素含量分别达到9.1 mg g-1DW 和13.9 mg g-1DW，比对照高21.7%和75.8%。处理后8 h，青蒿酸的含量没有明显变化，随后开始增加。处理后16 h，青蒿酸的含量达到3.6 mg g-1DW，比对照高90%， 随后继续升高，至96 h 达到4.98 mg g-1 DW，比对照高127%。二氢青蒿酸的含量在处理后的8 h 内有所下降，随后缓慢升高。处理后8 h，二氢青蒿酸的含量降低了23.3%，随后二氢青蒿酸的含量开始升高，在处理后96 h，达到7.4 mg g-1DW，比对照高72.1%。外源SA 处理提高了青蒿素及其前体的总含量，在处理后1、2、4 天分别比对照提高了1.3、1.5 和1.8 倍。Northern 结果表明，水杨酸强烈诱导了青蒿素生物合成基因HMGR、ADS 的表达，但是对FPS、CYP71AV1 的诱导作用较小。这些研究结果表明，外源水杨酸至少通过两条途径诱导青蒿素的生物合成：一是通过诱导活性氧的产生促进二氢青蒿酸向青蒿素的转化；二是上调部分青蒿素生物合成相关基因的表达。根据这一研究成果，在青蒿田间栽培中，可以在收获前通过喷施水杨酸来快速、有效和低成本地提高青蒿素产量。