HAWAIIAN SKIRT: an F-box gene that regulates organ fusion and growth in arabidopsis

A fast neutron-mutagenized population of Arabidopsis ( Arabidopsis thaliana) Columbia-0 wild-type plants was screened for floral phenotypes and a novel mutant, termed hawaiian skirt ( hws), was identified that failed to shed its reproductive organs. The mutation is the consequence of a 28 bp deletion that introduces a premature amber termination codon into the open reading frame of a putative F-box protein ( At3g61590). The most striking anatomical characteristic of hws plants is seen in flowers where individual sepals are fused along the lower part of their margins. Crossing of the abscission marker, Pro(PGAZAT):beta-glucuronidase, into the mutant reveals that while floral organs are retained it is not the consequence of a failure of abscission zone cells to differentiate. Anatomical analysis indicates that the fusion of sepal margins precludes shedding even though abscission, albeit delayed, does occur. Spatial and temporal characterization, using Pro(HWS):beta-glucuronidase or Pro(HWS):green fluorescent protein fusions, has identified HWS expression to be restricted to the stele and lateral root cap, cotyledonary margins, tip of the stigma, pollen, abscission zones, and developing seeds. Comparative phenotypic analyses performed on the hws mutant, Columbia-0 wild type, and Pro(35S):HWS ectopically expressing lines has revealed that loss of HWS results in greater growth of both aerial and below-ground organs while overexpressing the gene brings about a converse effect. These observations are consistent with HWS playing an important role in regulating plant growth and development.

An ancestral MADS-box gene duplication occurred before the divergence of plants and animals

Changes in genes encoding transcriptional regulators can alter development and are important components of the molecular mechanisms of morphological evolution. MADS-box genes encode transcriptional regulators of diverse and important biological functions. In plants, MADS-box genes regulate flower, fruit, leaf, and root development. Recent sequencing efforts in Arabidopsis have allowed a nearly complete sampling of the MADS-box gene family from a single plant, something that was lacking in previous phylogenetic studies. To test the long-suspected parallel between the evolution of the MADS-box gene family and the evolution of plant form, a polarized gene phylogeny is necessary. Here we suggest that a gene duplication ancestral to the divergence of plants and animals gave rise to two main lineages of MADS-box genes: TypeI and TypeII. We locate the root of the eukaryotic MADS-box gene family between these two lineages. A novel monophyletic group of plant MADS domains (AGL34 like) seems to be more closely related to previously identified animal SRF-like MADS domains to form TypeI lineage. Most other plant sequences form a clear monophyletic group with animal MEF2-like domains to form TypeII lineage. Only plant TypeII members have a K domain that is downstream of the MADS domain in most plant members previously identified. This suggests that the K domain evolved after the duplication that gave rise to the two lineages. Finally, a group of intermediate plant sequences could be the result of recombination events. These analyses may guide the search for MADS-box sequences in basal eukaryotes and the phylogenetic placement of new genes from other plant species.

Symbiotic induction of a MADS-box gene during development of alfalfa root nodules.

In response to infection by Rhizobium, highly differentiated organs called nodules form on legume roots. Within these organs, the symbiotic association between the host plant and bacteria is established. A putative plant transcription factor, NMH7, has been identified in alfalfa root nodules. nmh7 contains a MADS-box DNA-binding region and shows homology to flower homeotic genes. This gene is a member of a multigene family in alfalfa and was identified on the basis of nucleic acid homology to plant regulatory protein genes (MADS-box-containing genes) from Antirrhinum and Arabidopsis. RNA analysis and in situ hybridization showed that expression of this class of regulatory genes is limited to the infected cells of alfalfa root nodules and is likely to be involved in the signal transduction pathway initiated by the bacterial symbiont, Rhizobium meliloti. The expression of nmh7 in a root-derived organ is unusual for this class of regulatory genes.

Cis- und trans-Regulation bei Drosophila-T-Box-Genen

Die räumliche und zeitliche Organisation von Genexpression ist für die Entwicklung und das Funktionieren eines jeden Lebewesens von immenser Bedeutung. Dazu laufen eine Vielzahl von Regulationsprozessen auf unterschiedlichen Ebenen ab. In dieser Arbeit wurden im ersten Teil Untersuchungen zur Genregulation des Drosophila optomotor-blind Genes und zur Funktion des Omb Proteins durchgeführt. Eine Mutante, der ein großer Teil der upstream regulatory region (URR) fehlt wurde erzeugt, aus einer Vielzahl von Linien isoliert und molekular charakterisiert. Die biologischen Auswirkungen dieser Deletion werden in Shen et al. (2008) beschrieben. Plasmide zur Erzeugung transgener Fliegen, mit deren Hilfe eine bereits von Sivasankaran et al. (2000) durchgeführte Enhancer-reporter-Analyse vervollständigt werden sollte, wurden hergestellt. Die bereits bekannte Inversion In(1)ombH31 wurde molekular kartiert. Eine Reihe von Konstrukten mit Punktmutationen in der Omb T-Domäne wurden generiert, die unter anderem über deren Funktion hinsichtlich DNA-Protein Interaktion und einer potentiellen Metallionenbindefähigkeit (ATCUN) hin Aufschluss geben sollen. Des Weiteren wurde eine Reihe von P-Element-Deletionslinien auf den Verlust eines alternativen omb Transkriptionsstartpunktes hin untersucht, mit dem Ziel eine vollständige Protein-Nullmutante zur Verfügung zu haben. Der zweite Abschnitt dieser Arbeit befasste sich mit der Erzeugung von Dpp-GFP-Fusionskonstrukten, mit deren Hilfe weitere Erkenntnisse über den Dpp-Langstreckentransport erhofft werden. Es wurde außerdem damit begonnen bei einem weitern Drosophila T-Box Transkriptionsfaktor, Optomotor-blind related gene-1 (Org-1), eine Reihe von Varianten mit homopolymeren polyAlanin und polyGlutamin Expansionen unterschiedlicher Länge herzustellen. Durch Experimente mit diesen Konstrukten soll Aufschluss darüber gewonnen werden, ob Glutamin-Expansionen, wie in der Literatur vorgeschlagen, aktivierend und Alanin-Expansionen in Transkriptionsfaktoren vielleicht reprimierend auf Genaktivität wirken. Letztlich wurden in dieser Arbeit im Rahmen des DROSDEL Projektes (Ryder et al., 2004, 2007) Deletionen in der distalen Hälfte des Chromosomenarms 3R hergestellt. Der DROSDEL Deletionskit, der durch eine Kooperation europäischer Labore entstand stellt der Drosophila Forschung einen umfassenden Satz molekular basengenau definierter Defizienzen zur Verfügung.

Improving chondrogenesis: potential and limitations of SOX9 gene transfer and mechanical stimulation for cartilage tissue engineering

Articular cartilage injuries and degeneration affect a large proportion of the population in developed countries world wide. Stem cells can be differentiated into chondrocytes by adding transforming growth factor-beta1 and dexamethasone to a pellet culture, which are unfeasible for tissue engineering purposes. We attempted to achieve stable chondrogenesis without any requirement for exogenous growth factors. Human mesenchymal stem cells were transduced with an adenoviral vector containing the SRY-related HMG-box gene 9 (SOX9), and were cultured in a three-dimensional (3D) hydrogel scaffold composite. As an additional treatment, mechanical stimulation was applied in a custom-made bioreactor. SOX9 increased the expression level of its known target genes, as well as its cofactors: the long form of SOX5 and SOX6. However, it was unable to increase the synthesis of sulfated glycosaminoglycans (GAGs). Mechanical stimulation slightly enhanced collagen type X and increased lubricin expression. The combination of SOX9 and mechanical load boosted GAG synthesis as shown by (35)S incorporation. GAG production rate corresponded well with the amount of (endogenous) transforming growth factor-beta1. Finally, cartilage oligomeric matrix protein expression was increased by both treatments. These findings provide insight into the mechanotransduction of mesenchymal stem cells and demonstrate the potential of a transcription factor in stem cell therapy.

Tbx19, a tissue-selective regulator of POMC gene expression

Pituitary cell types arise in a temporally and spatially specific fashion, in response to combinatorial actions of transcription factors induced by transient signaling gradients. The critical transcriptional determinants of the two pituitary cell types that express the pro-opiomelanocortin (POMC) gene, the anterior lobe corticotropes, producing adrenocorticotropin, and the intermediate lobe melanotropes, producing melanocyte-stimulating hormone (MSHα), have remained unknown. Here, we report that a member of the T-box gene family, Tbx19, which is expressed only in the rostral ventral diencephalon and pituitary gland, commencing on e11.5, marks pituitary cells that will subsequently express the POMC gene and is capable of altering progression of ventral cell types and inducing adrenocorticotropin in rostral tip cells. It is suggested that Tbx19, depending on the presence of synergizing transcription factors, can activate POMC gene expression and repress the α glycoprotein subunit and thyroid-stimulating hormone β promoters.

三叶木通花发育相关基因的结构、功能和进化研究

花是被子植物最关键的创新（innovation）性状。在被子植物的不同类群中，其形态多种多样，尤其以基部真双子叶植物的花形态最为丰富。大量的系统发育分析表明，在核心真双子叶植物起源之前，几个与花发育相关的MADS-box基因亚家族均发生了大尺度的基因重复事件。因此，在被子植物的不同物种中，花发育相关基因的组成并不相同，并且它们经历了不同的进化历史，这意味着这些基因可能以不同的方式调控花的发育。基部真双子叶植物，作为基部被子植物和核心真双子叶植物之间的过渡类群，对于我们理解被子植物花的进化，揭示核心真双子叶植物花的起源以及基部真双子叶植物花多样性分化的分子机制非常重要。本文以基部真双子叶植物三叶木通为研究材料，着重进行了以下研究工作： 1. 花器官发生过程的观察。三叶木通的花为雌雄同序的单性花。而且，根据成熟花的形态，三叶木通的雌花和雄花都只有一轮花被器官，即三个花瓣状的萼片。扫描电镜的观察结果表明：1）在花器官的发生和发育过程中，在萼片和雄蕊原基之间，确实没有花瓣原基或另一轮萼片原基发生。2）雌花和雄花都是以两性花的方式发生发育的。3）单性花是由于在花发育的最后阶段，雌花中雄蕊或者雄花中心皮的退化而产生的。 2. 花发育相关基因的克隆。应用5’/3’ RACE的方法，我们从三叶木通不同发育阶段的混合花芽中共分离到九个与花发育相关的MADS-box基因： AktFL1、AktFL2、AktAP3_1、AktAP3_2、AktAP3_3、AktPI、AktAG1、AktAG2和AktSEP3。 3. A类MADS-box基因的进化。由于A类基因在进化过程中序列结构的改变，再加上取样的限制，使得A类基因间的进化历史一直不能被很好的理解。因此，本文对A类基因的研究从构建该基因亚家族的系统发育树开始。主要结果如下：1）通过扩大在基部真双子叶植物和被子植物其它重要类群的取样，我们的系统发育树基本上反映了现存被子植物的系统发育关系。2）核心真双子叶植物的A类基因由三个分支组成：euFUL、euAP1和AGL79，它们是通过发生在核心真双子叶植物起源之前的两次几乎同时的基因重复事件产生的。3）在基部真双子叶植物中，山龙眼目、毛茛目和黄杨科的A类基因各形成一支。而且，在这些类群内，发生了多次小尺度的独立的基因重复事件。4）来自单子叶植物的FUL-like基因明显地构成一个单系，并且包括三个分支：OsAMDS14、OsMADS15和OsMADS18。它们是由于两次不连续的基因重复事件产生的。5）不同类型的A类基因产物在C末端拥有不同的保守基元。6）从基因组结构上看，所有的A类基因都拥有八个外显子和七个内含子。7）通过对三叶木通中两个FUL-like型基因（AktFL1和AktFL2）表达式样的观察，我们发现它们在叶原基和发育早期的花原基以及发育着的花器官中都有表达。此外，A类基因表达式样的进化分析结果表明被子植物中该类基因的祖先可能具有广泛的功能，既在营养器官中表达又在生殖器官中表达 。 4. B类基因表达式样的保守性和多样性。通过对B类基因的系统发育和表达式样分析，得到以下结果：1）三叶木通中的三个paleoAP3基因是通过两次基因重复事件产生的。2）在木通科或木通属内，PI型基因并没有发生基因重复事件。3）RT-PCR结果表明，AktAP3_1在雌花中的表达量比雄花中高，而AktAP3_2则在雄花中的表达量比雌花中高。AktAP3_3和AktPI在雌花和雄花中的表达水平相似。4）原位杂交分析显示这些基因在发育着的雄蕊和心皮中表达。此外，AktAP3_3和AktPI还在萼片中表达，可能参与花瓣状萼片的发育。 5. 三叶木通C/D和E类基因的序列结构和表达分析。通过序列结构分析，我们发现，与其它被子植物AG同源基因编码的MADS-domain蛋白一样，AktAG1和AktAG2在MADS结构域的N末端都拥有一段氨基酸序列的延伸，AktAG1为20个氨基酸;AktAG2为7个氨基酸。原位杂交分析表明AktAG1和AktAG2主要在发育着的雄蕊和心皮中表达，说明它们具有决定生殖器官发育这一保守的功能。 AktSEP3属于AGL9型的E类基因。该基因在所有花器官中都有表达，说明和其它被子植物的E类基因一样，AktSEP3在三叶木通中对于所有花器官的发育都是必需的。 6. 各类MADS-domain蛋白间的相互作用。在前面工作的基础上，我们首次对三叶木通中上述MADS-domain蛋白间的作用方式进行了研究。酵母双杂交结果表明：1）AktSEP3的C末端具有转录激活功能。2）三个AktAP3蛋白与AktPI蛋白都能够形成异源二聚体，但是它们之间的作用能力并不相同。3）AktSEP3蛋白可以与AktFL1、AktPI、AktAG1和AktAG2形成异源二聚体，充分体现了E类基因产物作用式样的保守性。4）AktFL1与AktPI、AktSEP3和AktAG2也能形成异源二聚体，这与核心真双子叶植物的euFUL型蛋白在作用式样上是非常相似的。 综合以上结果，我们探讨了三叶木通花发育的分子机制。在三叶木通的三轮花器官中，与拟南芥等模式植物相似的是：E类（AktSEP3）基因在每一轮花器官中都起作用;此外，A类（AktFL1）和B类（AktAP3_3和AktPI）基因在花瓣状的萼片中有不同程度的表达，类似于拟南芥的第二轮;B类（AktAP3_1、AktAP3_2、AktAP3_3和AktPI）和C/D类（AktAG1和AktAG2）基因在雄蕊的发育过程中起作用;C/D类（AktAG1和AktAG2）基因对心皮的发育起作用。与拟 南芥等模式植物不同的是：1）虽然原位杂交分析表明，AktFL1、AktAP3_3、AktPI和AktSEP3都在花瓣状的萼片中有 不同程度的表达，但是它们的蛋白质产物AktFL1与AktSEP3和AktAP3_3与AktPI都只能形成较弱的异源二聚体。而 且，根据我们的研究结果，在三叶木通中没有找到euAP1型的A类基因，只有两个FUL-like型的A类基因。它们的功能 与核心真双子叶植物中的euFUL型基因相似。因此，AktFL1很可能与其它调控因子共同作用负责花分生组织的形成;AktFL1/AktAG2则可能在花发育的后期起作用。那么，三叶木通花瓣状萼片的发育是否需要AktFL1/AktSEP3和 AktAP3_3/AktPI的参与，还是另有其它转录因子的参与，仍然需要更深入的研究。2）虽然在三叶木通中，雄蕊的发 育同样需要B、C/D和E类基因的参与，但是由于小尺度的基因重复事件，在该物种中只拥有三个paleoAP3型基因，而没有euAP3型基因。而且，由于复制拷贝间的亚功能化，AktAP3_1/AktPI主要参与雌花的发育过程;而AktAP3_2/AktPI主要参与雄花的发育过程。

金粟兰花发育相关基因的结构、功能和进化研究

花是被子植物区别于其它植物大类群的最重要的特征，其形态多种多样。花的发育取决于一个复杂的涉及到多个基因和过程的调控体系，因此花的起源和多样化过程实际上可以理解为这个调控体系的进化过程。在被子植物的不同物种中，花发育相关基因的组成并不相同，且经历了不同的进化历史，这意味着这些基因可能以不同的方式调控花的发育。相对于核心真双子叶植物相对稳定的花形态结构而言，基部被子植物的花具有丰富的多样性。因此，对基部被子植物花发育相关基因的研究对于我们理解被子植物花的进化非常重要。 金粟兰科（Chloranthaceae）是基部被子植物的代表类群之一。与研究得比较深入的模式植物相比，花被、雄蕊或雌蕊的缺失，使得该科植物的花比较简单。因此对该科植物中花发育基因的研究不仅有助于揭示花的起源以及花多样性分化的分子机制，还将为认识花部构造简单化的机制提供资料。本文以金粟兰（Chloranthus spicatus）为实验材料，取得了以下研究结果： 1.花发育相关基因的克隆 应用5’/3’RACE的方法，我们从金粟兰不同发育阶段的混合花芽中克隆到了与花发育相关的MADS-box基因：CsPI、CsAG1和CsAG2。 2. 两个A类MADS-box基因表达式样的对比分析 在营养分生组织向生殖分生组织的转变中，花原基的形成，以及随后雄蕊、心皮、花粉、胚珠和胚囊的发育中，CsAP1-1和 CsAP1-2基因均表达。唯一不同之处在于，在花发育成熟期，CsAP1-1在外珠被也有表达，而CsAP1-2在外珠被处没有表达，而只在内珠被处表达。这一结果反映了基因重复事件发生后，两个基因在功能上也有了一些分化。 3. B类基因功能的保守性和多样性 通过转基因实验和蛋白质相互作用研究对B类基因的功能和作用方式进行了研究，得到以下结果：1）金粟兰CsAP3基因的C末端的点突变所造成的paleoAP3基元的部分缺失对该基因的功能没有决定性的影响;2）金粟兰paleoAP3型基因CsAP3所编码蛋白的C末端以及paleoAP3基元，与拟南芥euAP3型基因AtAP3所编码蛋白的C末端以及euAP3基元没有功能上的不同;3）金粟兰paleoAP3型基因CsAP3与拟南芥euAP3型基因AtAP3 的主要功能存在一定差异，前者主要参与雄蕊形成，而后者既参与雄蕊的形成也参与花瓣的形成; 4）CsPI基因所编码的蛋白可以与AP3类蛋白相互作用进而影响花瓣的形成，因此该基因在功能上是保守的。 4. 金粟兰CsAG1基因的序列结构和功能分析 通过序列结构分析发现，CsAG1属于C类基因，具有保守的AG I基元和AG II基元。过量表达实验分析表明CsAG1的功能与A类基因的功能是相拮抗的。 5. 各类MADS-domain蛋白间的相互作用 在前面工作的基础上，我们首次对金粟兰中各类MADS-domain蛋白间的作用方式进行了研究。酵母双杂交结果表明：1）C末端的完整性对于MADS-domain蛋白二聚体的形成没有影响; 2）去掉M区的CsAP3蛋白与CsPI蛋白都能够形成异源二聚体，同时它们又可以各自形成同源二聚体; 3）E类蛋白既可以和A类或C类基因产物相互作用，也可以同AP3和PI型蛋白相互作用，充分体现了E类基因产物作用式样的保守性; 4）金粟兰中，FUL-like型基因所编码的蛋白CsAP1-1与CsSEP3和CsAG1也能形成异源二聚体，这与核心真双子叶植物的euFUL型蛋白在作用式样上是非常相似的。然而，金粟兰CsAP1-1蛋白不能形成同源二聚体。 综合以上结果发现，在无花被的金粟兰中，仍然存在着A、B、C/D、E类花发育相关的基因。这些基因的功能与核心真双子叶植物中同类基因的相比，有些是保守的，比如CsPI基因可以参与花被的形成;但也有一些是不同的，比如CsAP3基因主要参与雄蕊形成而非花被形成过程。由此可以看出被子植物花器官的发育是一个非常复杂的调控过程，不同植物中的调控机理及进化历程可能是不同的。

水稻转录因子编码基因的表达谱和功能分析

水稻是重要的经济作物，也是单子叶植物分子遗传研究的模式植物。对水稻生长发育中基因的表达调控研究将为其遗传改良提供重要线索。转录因子在植物发育过程中对基因表达调控起关键作用，对其表达谱和功能的研究具有重要的理论和应用价值。 本研究一方面在水稻基因组水平上，利用cDNA芯片技术研究了水稻(中花11)种子发育过程中388个转录相关基因的表达谱;另一方面，在分离转录因子基因的基础上，利用分子生物学和遗传学方法研究了有关基因详细、具体的表达特征和功能。 利用cDNA芯片技术鉴定了123个种子优先表达、属于12类不同表达模式的转录相关基因。首次发现了许多主要在种子发育特定阶段表达的转录相关基因，还发现一些种子优先表达的转录相关基因参与了激素和非生物胁迫信号转导，为阐释水稻种子发育中的转录调节和信号网络的分子基础提供了很多有价值的线索。 在相关基因工作方面，分离了一个MADS-box类转录因子编码基因OsMDP（全长），表达模式析以及初步的功能分析揭示该基因作为一个负调控因子参与了BR控制的水稻叶节弯曲、胚芽鞘伸长、主根伸长等过程的信号转导，为水稻根、叶、胚芽鞘的发育、以及BR信号转导机制的研究提供了线索。 另外，从水稻的cDNA文库中分离并初步研究了三个分属BELL1、KNOX和HD-ZIP亚族的同源盒基因（片段），OsHB1主要和水稻种子发育相联系，OsHB2可能参与激素调节的发育或响应，OsHB3和水稻花药早期发育相关、对花药早期发育的调控研究有一定价值。

16q24.1 microdeletion in a premature newborn: Usefulness of array-based comparative genomic hybridization in persistent pulmonary hypertension of the newborn.

OBJECTIVE:: Report of a 16q24.1 deletion in a premature newborn, demonstrating the usefulness of array-based comparative genomic hybridization in persistent pulmonary hypertension of the newborn and multiple congenital malformations. DESIGN:: Descriptive case report. SETTING:: Genetic department and neonatal intensive care unit of a tertiary care children's hospital. INTERVENTIONS:: None. PATIENT:: We report the case of a preterm male infant, born at 26 wks of gestation. A cardiac malformation and bilateral hydronephrosis were diagnosed at 19 wks of gestation. Karyotype analysis was normal, and a 22q11.2 microdeletion was excluded by fluorescence in situ hybridization analysis. A cesarean section was performed due to fetal distress. The patient developed persistent pulmonary hypertension unresponsive to mechanical ventilation and nitric oxide treatment and expired at 16 hrs of life. MEASUREMENTS AND MAIN RESULTS:: An autopsy revealed partial atrioventricular canal malformation and showed bilateral dilation of the renal pelvocaliceal system with bilateral ureteral stenosis and annular pancreas. Array-based comparative genomic hybridization analysis (Agilent oligoNT 44K, Agilent Technologies, Santa Clara, CA) showed an interstitial microdeletion encompassing the forkhead box gene cluster in 16q24.1. Review of the pulmonary microscopic examination showed the characteristic features of alveolar capillary dysplasia with misalignment of pulmonary veins. Some features were less prominent due to the gestational age. CONCLUSIONS:: Our review of the literature shows that alveolar capillary dysplasia with misalignment of pulmonary veins is rare but probably underreported. Prematurity is not a usual presentation, and histologic features are difficult to interpret. In our case, array-based comparative genomic hybridization revealed a 16q24.1 deletion, leading to the final diagnosis of alveolar capillary dysplasia with misalignment of pulmonary veins. It emphasizes the usefulness of array-based comparative genomic hybridization analysis as a diagnostic tool with implications for both prognosis and management decisions in newborns with refractory persistent pulmonary hypertension and multiple congenital malformations.

Base genética do hábito de crescimento e florescimento em tomateiro e sua importânciana agricultura

Hybrids or open pollinated tomato cultivars used for sauces and ketchups production usually has determinate growth habit, while most of the genotypes used in the production to salads (in natura consumption) has indeterminate growth habit. Additionally, growth habit can have influence on culture management, productivity and total soluble solids (TSS) in fruits. The growth habit is mainly controlled by the gene SELF-PRUNING (SP), which is a component of a small gene family which is also part of the gene SINGLE FLOWER TRUSS (SFT), currently considered one of the components so sought after 'florigin'. Understanding the biochemical function and physiological effect of such genes in interaction with the environment and other genes (epistasis), allows the manipulation of parameters such as precocity and TSS. It also provides subsidies to understand the genetic basis of semideterminate growth, which combines the advantages of determinate and indeterminate habit and can be used for plant breeders to development of new cultivars.

TBX3-Mutationsanalysen und Konstruktion einer Zelllinie für TBX2-Inhibitorscreenings

Die nahe verwandten T-box Transkriptionsfaktoren TBX2 und TBX3 werden in zahlreichen humanen Krebsarten überexprimiert, insbesondere in Brustkrebs und Melanomen. Die Überexpression von TBX2 und TBX3 hat verschiedene zelluläre Effekte, darunter die Unterdrückung der Seneszenz, die Förderung der Epithelialen-Mesenchymalen Transition sowie invasive Zellmotilität. Im Gegensatz dazu führt ein Funktionsverlust von TBX3 und der meisten anderen humanen T-box-Gene zu haploinsuffizienten Entwicklungsdefekten. Durch Sequenzierung des Exoms von Brustkrebsproben identifizierten Stephens et al. fünf verschiedene Mutationen in TBX3, welche allesamt die DNA-bindende T-box-Domäne betrafen. Die In-Frame-Deletion N212delN wurde zweimal gefunden. Aus der Anhäufung der Mutationen innerhalb der T-box-Domäne wurde geschlossen, dass TBX3 bei Brustkrebs ein Treibergen ist. Da Mutationen innerhalb der T-box-Domäne im Allgemeinen zu einem Funktionsverlust führen, aber die onkogene Aktivität von TBX3 meist auf eine Überexpression zurückzuführen ist, wurden die potentiellen Treibermutationen hinsichtlich einer verminderten oder gesteigerten TBX3-Funktion geprüft. Getestet wurden zwei In-Frame Deletionen, eine Missense- sowie eine Frameshift-Mutante bezüglich der DNA-Bindung in vitro und der Zielgen-Repression in Zellkultur. Zusätzlich wurde eine in silico Analyse der im The Cancer Genome Atlas (TCGA) gelisteten somatischen TBX-Brustkrebsmutationen durchgeführt. Sowohl die experimentelle als auch die in silico Analyse zeigten, dass die untersuchten Mutationen vorwiegend zum Verlust der TBX3-Funktion führen. Um den Mechanismus der Genrepression durch TBX3 besser zu verstehen, wurden weitere TBX3-Mutanten bezüglich ihrer Wirkung auf die p21-Promotoraktivität (p21-Luc-Reporter und endogene p21-Expression) analysiert. Wildtypische p21-Luc-Repression zeigten die zwei Mutationen S674A (Phosphorylierung) und D275K (SUMOylierung), welche posttranslationale Modifikationen verhindern, sowie die Interaktion mit dem Tumorsuppressor Rb1 unterbindende M302A/V304A-Mutation. Erstaunlicherweise war die endogene p21-Repression dieser Mutanten stärker als die des wildtypischen TBX3-Proteins. Alle drei Mutationen führten zu einer Stabilisierung des TBX3-Proteins. Die ursprünglich in Patienten mit Ulna-Mamma Syndrom identifizierte, DNA-bindungsdefekte Y149S-Mutante konnte weder p21-Luc noch endogenes p21 reprimieren. Mutationen in potentiellen Interaktionsdomänen für die Bindung der Co-Repressoren Groucho und C-terminalem Bindeprotein zeigten sowohl auf p21-Luc als auch auf endogenes p21-Gen wildtypische Repressoraktivität, so dass diese Co-Repressoren in COS-7-Zellen wahrscheinlich nicht an der Repression dieses Gens beteiligt sind. Da TBX2 und TBX3 interessante Ziele zur direkten Krebsbekämpfung darstellen, sollte ein zelluläres Reportersystem zur Identifikation TBX2-inhibierender, pharmakologisch aktiver Substanzen etabliert werden. Dazu sollte eine stabile Zelllinie mit vom p21-Promotor reguliertem d2EGFP-Reporter und Doxyzyklin-induzierbarem TBX2-Protein erzeugt werden, da ektopische Expression von TBX2 genetische Instabilität und Toxizität induzieren kann. In dieser Zelllinie sollte die TBX2-Expression zur Reduktion der d2EGFP-Fluoreszenz führen. Zur Erzeugung der Zelllinie wurden die folgenden drei Konstrukte Schritt-für-Schritt stabil in das Genom der Zielzelllinie COS-7 integriert: pEF1alpha-Tet3G, pTRE3G-TBX2 und p21-d2EGFP. Während die Herstellung der doppelt stabilen COS-7-Zelllinie gelang, scheiterte die Herstellung der dreifach stabilen Zelllinie.

Genomic analyses of flowering transition and inflorescence development in grapevine = Análisis genómicos de la transición floral y del desarrollo de la inflorescencia en la vid

The general objective of this work is to analyze the regulatory processes underlying flowering transition and inflorescence and flower development in grapevine. Most of these crucial developmental events take place within buds growing during two seasons in two consecutive years. During the first season, the shoot apical meristem within the bud differentiates all the basic elements of the shoot including flowering transition in lateral primordia and development of inflorescence primordia. These events practically end with bud dormancy. The second season, buds resume shoot growth associated to flower formation and development. In grapevine, the lateral meristems can give rise either to tendril or inflorescence primordia that are homologous organs. With this purpose, we performed global transcriptome analyses along the bud annual cycle and during inflorescence and tendril development. In addition, we approach the genomic analysis of the MIKC type MADS-box gene family in grapevine to identify all its members and assign them putative biological functions. Regarding buds developmental cycle, the results indicate that the main factors explaining the global gene expression differences were the processes of bud dormancy and active growth as well as stress responses. Non dormant buds exhibited up-regulation in functional categories typical of actively proliferating and growing cells (photosynthesis, cell cycle regulation, chromatin assembly) whereas in dormant ones the main functional categories up-regulated were associated to stress response pathways together with transcripts related to starch catabolism. Major transcriptional changes during the dormancy period were associated to the para/endodormancy, endo/ecodormancy and ecodormancy/bud break transitions. Global transcriptional analyses along tendril and inflorescence development suggested that these two homologous organs share a common transcriptional program related to cell proliferation functions. Both structures showed a progressive decrease in the expression of categories such as cell-cycle, auxin metabolism/signaling, DNA metabolism, chromatin assembly and a cluster of five transcripts belonging to the GROWTH-REGULATING FACTOR (GRF) transcription factor family, that are known to control cell proliferation in other species and determine the size of lateral organs. However, they also showed organ specific transcriptional programs that can be related to their differential organ structure and function. Tendrils showed higher transcription of genes related to photosynthesis, hormone signaling and secondary metabolism than inflorescences, while inflorescences have higher transcriptional activity for genes encoding transcription factors (especially those belonging to the MADS-box gene family). Further analysis along inflorescence development evidenced the relevance of additional functions likely related to processes of flower development such as fatty acid and lipid metabolism, jasmonate signaling and oxylipin biosynthesis. The transcriptional analyses performed highlighted the relevance of several groups of transcriptional regulators in the developmental processes studied. The expression profiles along bud development revealed significant differences for some MADS-box subfamilies in relation to other plant species, like the members of the FLC and SVP subfamilies suggesting new roles for these groups in grapevine. In this way, it was found that VvFLC2 and VvAGL15.1 could participate, together with some members of the SPL-L family, in dormancy regulation, as was shown for some of them in other woody plants. Similarly, the expression patterns of the VvFLC1, VvFUL, VvSOC1.1 (together with VvFT, VvMFT1 and VFL) genes could indicate that they play a role in flowering transition in grapevine, in parallel to their roles in other plant systems. The expression levels of VFL, the grapevine LEAFY homolog, could be crucial to specify the development of inflorescence and flower meristems instead of tendril meristems. MADS-box genes VvAP3.1 and 2, VvPI, VvAG1 and 3, VvSEP1-4, as well as VvBS1 and 2 are likely associated with the events of flower meristems and flower organs differentiation, while VvAP1 and VvFUL-L (together with VvSOC1.1, VvAGL6.2) could be involved on tendril development given their expression patterns. In addition, the biological function ofVvAP1 and VvTFL1A was analyzed using a gene silencing approach in transgenic grapevine plants. Our preliminary results suggested a possible role for both genes in the initiation and differentiation of tendrils. Finally, the genomic analysis of the MADS-box gene family in grapevine revealed differential features regarding number and expression pattern of genes putatively involved in the flowering transition process as compared to those involved in the specification of flower and fruit organ identity. Altogether, the results obtained allow identifying putative candidate genes and pathways regulating grapevine reproductive developmental processes paving the way to future experiments demonstrating specific gene biological functions. RESUMEN El objetivo general de este trabajo es analizar los procesos regulatorios subyacentes a la inducción floral así como al desarrollo de la inflorescencia y la flor en la vid. La mayor parte de estos eventos cruciales tienen lugar en las yemas a lo largo de dos estaciones de crecimiento consecutivas. Durante la primera estación, el meristemo apical contenido en la yema diferencia los elementos básicos del pámpano, lo cual incluye la inducción de la floración en los meristemos laterales y el subsiguiente desarrollo de primordios de inflorescencia. Estos procesos prácticamente cesan con la entrada en dormición de la yema. En la segunda estación, se reanuda el crecimiento del pámpano acompañado por la formación y desarrollo de las flores. En la vid, los meristemos laterales pueden dar lugar a primordios de inflorescencia o de zarcillo que son considerados órganos homólogos. Con este objetivo llevamos a cabo un estudio a nivel del transcriptoma de la yema a lo largo de su ciclo anual, así como a lo largo del desarrollo de la inflorescencia y del zarcillo. Además realizamos un análisis genómico de la familia MADS de factores transcripcionales (concretamente aquellos del tipo MIKC) para identificar todos sus miembros y tratar de asignarles posibles funciones biológicas. En cuanto al ciclo de desarrollo de la yema, los resultados indican que los principales factores que explican las diferencias globales en la expresión génica fueron los procesos de dormición de la yema y el crecimiento activo junto con las respuestas a diversos tipos de estrés. Las yemas no durmientes mostraron un incremento en la expresión de genes contenidos en categorías funcionales típicas de células en proliferación y crecimiento activo (como fotosíntesis, regulación del ciclo celular, ensamblaje de cromatina), mientras que en las yemas durmientes, las principales categorías funcionales activadas estaban asociadas a respuestas a estrés, así como con el catabolismo de almidón. Los mayores cambios observados a nivel de transcriptoma en la yema coincidieron con las transiciones de para/endodormición, endo/ecodormición y ecodormición/brotación. Los análisis transcripcionales globales a lo largo del desarrollo del zarcillo y de la inflorescencia sugirieron que estos dos órganos homólogos comparten un programa transcripcional común, relacionado con funciones de proliferación celular. Ambas estructuras mostraron un descenso progresivo en la expresión de genes pertenecientes a categorías funcionales como regulación del ciclo celular, metabolismo/señalización por auxinas, metabolismo de ADN, ensamblaje de cromatina y un grupo de cinco tránscritos pertenecientes a la familia de factores transcripcionales GROWTH-REGULATING FACTOR (GRF), que han sido asociados con el control de la proliferación celular y en determinar el tamaño de los órganos laterales en otras especies. Sin embargo, también pusieron de manifiesto programas transcripcionales que podrían estar relacionados con la diferente estructura y función de dichos órganos. Los zarcillos mostraron mayor actividad transcripcional de genes relacionados con fotosíntesis, señalización hormonal y metabolismo secundario que las inflorescencias, mientras que éstas presentaron mayor actividad transcripcional de genes codificantes de factores de transcripción (especialmente los pertenecientes a la familia MADS-box). Análisis adicionales a lo largo del desarrollo de la inflorescencia evidenciaron la relevancia de otras funciones posiblemente relacionadas con el desarrollo floral, como el metabolismo de lípidos y ácidos grasos, la señalización mediada por jasmonato y la biosíntesis de oxilipinas. Los análisis transcripcionales llevados a cabo pusieron de manifiesto la relevancia de varios grupos de factores transcripcionales en los procesos estudiados. Los perfiles de expresión estudiados a lo largo del desarrollo de la yema mostraron diferencias significativas en algunas de las subfamilias de genes MADS con respecto a otras especies vegetales, como las observadas en los miembros de las subfamilias FLC y SVP, lo cual sugiere que podrían desempeñar nuevas funciones en la vid. En este sentido, se encontró que los genes VvFLC2 y VvAGL15.1 podrían participar, junto con algunos miembros de la familia SPL-L, en la regulación de la dormición. De un modo similar, los patrones de expresión de los genes VvFLC1, VvFUL, VvSOC1.1 (junto con VvFT, VvMFT1 y VFL) podría indicar que desempeñan un papel en la regulación de la inducción de la floración en la vid, como se ha observado en otros sistemas vegetales. Los niveles de expresión de VFL, el homólogo en vid del gen LEAFY de A. thaliana podrían ser cruciales para la especificación del desarrollo de meristemos de inflorescencia y flor en lugar de meristemos de zarcillo. Los genes VvAP3.1 y 2, VvPI, VvAG1 y 3, VvSEP1-4, así como VvBS1 y 2 parecen estar asociados con los eventos de diferenciación de meristemos y órganos florales, mientras que VvAP1 y VvFUL-L (junto con VvSOC1.1 y VvAGL6.2) podrían estar implicados en el desarrollo del zarcillo dados sus patrones de expresión. Adicionalmente, se analizó la función biológica de los genes VvAP1 y VvTFL1A por medio de una estrategia de silenciamiento génico. Los datos preliminares sugieren un posible papel para ambos genes en la iniciación y diferenciación de los zarcillos. Finalmente, el análisis genómico de la familia MADS en vid evidenció diferencias con respecto a otras especies vegetales en cuanto a número de miembros y patrón de expresión en genes supuestamente implicados en la inducción de la floración, en comparación con aquellos relacionados con la especificación de identidad de órganos florales y desarrollo del fruto. En conjunto, los resultados obtenidos han permitido identificar posibles rutas y genes candidatos a participar en la regulación de los procesos de desarrollo reproductivo de la vid, sentando las bases de futuros experimentos encaminados a conocer la funciones biológicas de genes específicos.