DNA methylation inhibits p53 mediated survivin repression in cancer cells

Survivin (BIRC5) is a member of the Inhibitor of Apoptosis (IAP) gene family and functions as a chromosomal passenger protein as well as a mediator of cell survival. Survivin is widely expressed during embryonic development then becomes transcriptionally silent in most highly differentiated adult tissues. It is also overexpressed in virtually every type of tumor. The survivin promoter contains a canonical CpG island that has been described as epigenetically regulated by DNA methylation. We observed that survivin is overexpressed in high grade, poorly differentiated endometrial tumors, and we hypothesized that DNA hypomethylation could explain this expression pattern. Surprisingly, methylation specific PCR and bisulfite pyrosequencing analysis showed that survivin was hypermethylated in endometrial tumors and that this hypermethylation correlated with increased survivin expression. We proposed that methylation could activate survivin expression by inhibit the binding of a transcriptional repressor. ^ The tumor suppressor protein p53 is a well documented transcriptional repressor of survivin and examination of the survivin promoter showed that the p53 binding site contains 3 CpG sites which often become methylated in endometrial tumors. To determine if methylation regulates survivin expression, we treated HCT116 cells with decitabine, a demethylation agent, and observed that survivin transcript and protein levels were significantly repressed following demethylation in a p53 dependent manner. Subsequent binding studies confirmed that DNA methylation inhibited the binding of p53 protein to its binding site in the survivin promoter. ^ We are the first to report this novel mechanism of epigenetic regulation of survivin. We also conducted microarray analysis which showed that many other cancer relevant genes may also be regulated in this manner. While demethylation agents are traditionally thought to inhibit cancer cell growth by reactivating tumor suppressors, our results indicate that an additional important mechanism is to decrease the expression of oncogenes. ^

The role of AKT-mediated phosphorylation in suppression of MAD1 and the development of new approach in protein complex detection

MAX dimerization protein 1 (MAD1) is a basic-helix-loop-helix transcription factors that recruits transcription repressor such as HDAC to suppress target genes transcription. It antagonizes to MYC because the promoter binding sites for MYC are usually also serve as the binding sites for MAD1 so they compete for it. However, the mechanism of the switch between MYC and MAD1 in turning on and off of genes' transcription is obscure. In this study, we demonstrated that AKT-mediated MAD1 phosphorylation inhibits MAD1 transcription repression function. The association between MAD1 and its target genes' promoter is reduced after been phosphorylated by AKT; therefore, consequently, allows MYC to occupy the binding site and activates transcription. Mutation of such phosphorylation site abrogates the inhibition from AKT. In addition, functional assays demonstrated that AKT suppressed MAD1-mediated transcription repression of its target genes hTERT and ODC. Cell cycle and cell growth were also been released from inhibition by MAD1 in the presents of AKT. Taken together, our study suggests that MAD1 is a novel substrate of AKT and AKT-mediated MAD1 phosphorylation inhibits MAD1function; therefore, activates MAD1 target genes expression. ^ Furthermore, analysis of protein-protein interaction is indispensable for current molecular biology research, but multiplex protein dynamics in cells is too complicated to be analyzed by using existing biochemical methods. To overcome the disadvantage, we have developed a single molecule level detection system with nanofluidic chip. Single molecule was analyzed based on their fluorescent profile and their profiles were plotted into 2 dimensional time co-incident photon burst diagram (2DTP). From this 2DTP, protein complexes were characterized. These results demonstrate that the nanochannel protein detection system is a promising tool for future molecular biology. ^

ARD1 stabilization of TSC2 suppresses tumorigenesis via the mTOR signaling pathway

Mammalian target of rapamycin (mTOR) plays an important role in regulating various cellular functions, and the tuberous sclerosis 1 (TSC1)/TSC2 complex serves as a major repressor of the mTOR pathway. Here we demonstrated that arrest-defective protein 1 (ARD1) physically interacts with, acetylates, and stabilizes TSC2, thereby reducing mTOR activity. The inhibition of mTOR by ARD1 suppresses cell proliferation and increases autophagy, which further impairs tumorigenicity. Correlation between the levels of ARD1 and TSC2 was found in multiple tumor types, suggesting the physiological importance of ARD1 in stabilizing TSC2. Moreover, evaluation of loss of heterozygosity (LOH) at Xq28 revealed allelic loss in 31% of tested breast cancer cell lines and tumor samples. Together, our findings suggest that ARD1 functions as a negative regulator of the mTOR pathway and that dysregulation of the ARD1/TSC2/mTOR axis may contribute to cancer development. To further explore the signaling pathway of ARD1, we provided evidence showing the phosphorylation of ARD1 by IKKβ, which mediated the destabilization of ARD1. Future work may be needed to study the biological effect of this post-translational modification. ^

Control of the master virulence regulatory gene atxA in Bacillus anthracis

Transcription of the Bacillus anthracis structural genes for the anthrax toxin proteins and biosynthetic operon for capsule are positively regulated by AtxA, a transcription regulator with unique properties. Consistent with the role of atxA in virulence factor expression, a B. anthracis atxA-null mutant is avirulent in a murine model for anthrax. In batch culture, multiple signals impact atxA transcript levels, and the timing and steady state level of atxA expression is critical for optimal toxin and capsule synthesis. Despite the apparent complex control of atxA transcription, only one trans-acting protein, the transition state regulator AbrB, has been demonstrated to directly interact with the atxA promoter. The AbrB-binding site has been described, but additional cis-acting control sequences have not been defined. Using transcriptional lacZ fusions, electrophoretic mobility shift assays, and Western blot analysis, the cis-acting elements and trans-acting factors involved in regulation of atxA in B. anthracis strains containing either both virulence plasmids, pXO1 and pXO2, or only one plasmid, pXO1, were studied. This work demonstrates that atxA transcription from the major start site P1 is dependent upon a consensus sequence for the housekeeping sigma factor SigA, and an A+T-rich upstream element (UP-element) for RNA polymerase (RNAP). In addition, the data show that a trans-acting protein(s) other than AbrB negatively impacts atxA transcription when it binds specifically to a 9-bp palindrome within atxA promoter sequences located downstream of P1. Mutation of the palindrome prevents binding of the trans-acting protein(s) and results in a corresponding increase in AtxA and anthrax toxin production in a strain- and culture-dependent manner. The identity of the trans-acting repressor protein(s) remains elusive; however, phenotypes associated with mutation of the repressor binding site have revealed that the trans-acting repressor protein(s) indirectly controls B. anthracis development. Mutation of the repressor binding site results in misregulation and overexpression of AtxA in conditions conducive for development, leading to a marked sporulation defect that is both atxA- and pXO2-61-dependent. pXO2-61 is homologous to the sensor domain of sporulation sensor histidine kinases and is proposed to titrate an activating signal away from the sporulation phosphorelay when overexpressed by AtxA. These results indicate that AtxA is not only a master virulence regulator, but also a modulator of proper B. anthracis development. Also demonstrated in this work is the impact of the developmental regulators AbrB, Spo0A, and SigH on atxA expression and anthrax toxin production in a genetically incomplete (pXO1+, pXO2-) and genetically complete (pXO1+, pXO2+) strain background. AtxA and anthrax toxin production resulting from deletion of the developmental regulators are strain-dependent suggesting that factors on pXO2 are involved in control of atxA. The only developmental deletion mutant that resulted in a prominent and consistent strain-independent increase in AtxA protein levels was an abrB-null mutant. As a result of increased AtxA levels, there is early and increased production of anthrax toxins in an abrB-null mutant. In addition, the abrB-null mutant exhibited an increase in virulence in a murine model for anthrax. In contrast, virulence of the atxA promoter mutant was unaffected in a murine model for anthrax despite the production of 5-fold more AtxA than the abrB-null mutant. These results imply that AtxA is not the only factor impacting pathogenesis in an abrB-null mutant. Overall, this work highlights the complex regulatory network that governs expression of atxA and provides an additional role for AtxA in B. anthracis development.

Potential REST Targets in Neural Stem Cells and Glioblastoma-Derived Stem Cells

Glioblastoma multiforme (GBM) tumors are the most common malignant primary brain tumors in adults. The current theory is that these tumors are caused by self-renewing glioblastoma-derived stem cells (GSCs). At the current time, the mechanisms that regulate self-renewal and other oncogenic properties of GSCs remain unknown. Recently, we found transcriptional repressor REST maintains self-renewal in neural stem cells (NSCs) and in GSCs. REST also regulates other oncogenic properties, such as apoptosis, invasion and proliferation. However, the mechanisms by which REST regulates these oncogenic properties are unknown. In an attempt to determine these mechanisms, we performed loss and gain-of-function experiments and genome-wide mRNA expression analysis in GSCs, and we were able to identify REST-regulated genes in GSCs. This was accomplished, after screening concordantly regulated genes in NSCs and GSCs, utilizing two RE1 databases, and setting two-fold expression as filters on the resulting genes. These results received further validation by qRT-PCR. Ingenuity Pathway Analysis (IPA) analysis further revealed the top REST target genes in GSCs were downstream targets of REST and/or involved in other cancers in other cell lines. IPA also revealed that many of the differentially-regulated genes identified in this study are involved in oncogenic properties seen in GBM, and which we believe are related to REST expression.

GENETIC INTERACTIONS OF FACTORS THAT REGULATE ALTERNATIVE RNA SPLICING IN THE MALE GERM LINE OF DROSOPHILA

Alternative RNA splicing is a critical process that contributes variety to protein functions, and further controls cell differentiation and normal development. Although it is known that most eukaryotic genes produce multiple transcripts in which splice site selection is regulated, how RNA binding proteins cooperate to activate and repress specific splice sites is still poorly understood. In addition how the regulation of alternative splicing affects germ cell development is also not well known. In this study, Drosophila Transformer 2 (Tra2) was used as a model to explore both the mechanism of its repressive function on its own pre-mRNA splicing, and the effect of the splicing regulation on spermatogenesis in testis. Half-pint (Hfp), a protein known as splicing activator, was identified in an S2 cell-based RNAi screen as a co-repressor that functions in combination with Tra2 in the splicing repression of the M1 intron. Its repressive splicing function is found to be sequence specific and is dependent on both the weak 3’ splice site and an intronic splicing silencer within the M1 intron. In addition we found that in vivo, two forms of Hfp are expressed in a cell type specific manner. These alternative forms differ at their amino terminus affecting the presence of a region with four RS dipeptides. Using assays in Drosophila S2 cells, we determined that the alternative N terminal domain is necessary in repression. This difference is probably due to differential localization of the two isoforms in the nucleus and cytoplasm. Our in vivo studies show that both Hfp and Tra2 are required for normal spermatogenesis and cooperate in repression of M1 splicing in spermatocytes. But interestingly, Tra2 and Hfp antagonize each other’s function in regulating germline specific alternative splicing of Taf1 (TBP associated factor 1). Genetic and cytological studies showed that mutants of Hfp and Taf1 both cause similar defects in meiosis and spermatogenesis. These results suggest Hfp regulates normal spermatogenesis partially through the regulation of taf1 splicing. These observations indicate that Hfp regulates tra2 and taf1 activity and play an important role in germ cell differentiation of male flies.

Regulation of the {\it neu\/} oncogene by the GTG element binding proteins

A previous study in our lab has shown that the transforming neu oncogene ($neu\sp\*$) was able to initiate signals that lead to repression of the neu promoter activity. Further deletion mapping of the neu promoter identified that the GTG element (GGTGGGGGGG), located between $-$243 and $-$234 relative to the translation initiation codon, mediates such a repression effect. I have characterized the four major protein complexes that interact with this GTG element. In situ UV-crosslinking indicated that each complex contains proteins of different molecular weights. The slowest migrating complex (S) contain Sp1 or Sp1-related proteins, as indicated by the data that both have similar molecular weights, similar properties in two affinity chromatographies, and both are antigenically related in gel shift analysis. Methylation protection and interference experiments demonstrated these complexes bind to overlapping regions of the GTG element. Mutations within the GTG element that either abrogate or enhance complex S binding conferred on the neu promoter with lower activity, indicating that positive factors other than Sp1 family proteins also contribute to neu promoter activity. A mutated version (mutant 4) of the GTG element, which binds mainly the fastest migrating complex that contains a very small protein of 26-kDa, can repress transcription when fused to a heterologous promoter. Further deletion and mutation studies suggested that this GTG mutant and its binding protein(s) may cooperate with some DNA element within a heterologous promoter to lock the basal transcription machinery; such a repressor might also repress neu transcription by interfering with the DNA binding of other transactivators. Our results suggest that both positive and negative trans-acting factors converge their binding sites on the GTG element and confer combinatorial control on the neu gene expression. ^

Analysis of VirB4, a membrane-associated ATPase subunit essential for T -complex transport in Agrobacterium tumefaciens

Agrobacterium tumefaciens is a plant pathogen with the unique ability to export oncogenic DNA-protein complexes (T-complexes) to susceptible plant cells and cause crown gall tumors. Delivery of the T-complexes across the bacterial membranes requires eleven VirB proteins and VirD4, which are postulated to form a transmembrane transporter. This thesis examines the subcellular localization and oligomeric structure of the 87-kDa VirB4 protein, which is one of three essential ATPases proposed to energize T-complex transport and/or assembly. Results of subcellular localization studies showed that VirB4 is tightly associated with the cytoplasmic membrane, suggesting that it is a membrane-spanning protein. The membrane topology of VirB4 was determined by using a nested deletion strategy to generate random fusions between virB4 and the periplasmically-active alkaline phosphatase, $\sp\prime phoA$. Analysis of PhoA and complementary $\beta$-galactosidase reporter fusions identified two putative periplasmically-exposed regions in VirB4. A periplasmic exposure of one of these regions was further confirmed by protease susceptibility assays using A. tumefaciens spheroplasts. To gain insight into the structure of the transporter, the topological configurations of other VirB proteins were also examined. Results from hydropathy analyses, subcellular localization, protease susceptibility, and PhoA reporter fusion studies support a model that all of the VirB proteins localize at one or both of the bacterial membranes. Immunoprecipitation and Co$\sp{2+}$ affinity chromatography studies demonstrated that native VirB4 (87-kDa) and a functional N-terminally tagged HIS-VirB4 derivative (89-kDa) interact and that the interaction is independent of other VirB proteins. A $\lambda$ cI repressor fusion assay supplied further evidence for VirB4 dimer formation. A VirB4 dimerization domain was localized to the N-terminal third of the protein, as judged by: (i) transdominance of an allele that codes for this region of VirB4; (ii) co-retention of a His-tagged N-terminal truncation derivative and native VirB4 on Co$\sp{2+}$ affinity columns; and (iii) dimer formation of the N-terminal third of VirB4 fused to the cI repressor protein. Taken together, these findings are consistent with a model that VirB4 is topologically configured as an integral cytoplasmic membrane protein with two periplasmic domains and that VirB4 assembles as homodimers via an N-terminal dimerization domain. Dimer formation is postulated to be essential for stabilization of VirB4 monomers during T-complex transporter assembly. ^

Transcriptional repression of serum amyloid A1 by AP -2 contributes to its liver -specific expression

Studies on the transcriptional regulation of serum amyloid A1 (SAA1) gene, a liver specific acute-phase gene, identified a regulatory element in its promoter that functioned to repress (SAA1) gene transcription in nonliver cells. This silencer element interacts with a nuclear protein that is detectable in HeLa cells, fibroblasts and placental tissues but not in liver or liver-derived cells. As the expression pattern of this repressor is consistent with its potential regulatory role in repressing SAA1 expression, and that many other liver gene promoters also contain this repressor binding site, we sought to investigate whether this repressor may have a broader functional role in repressing liver genes. ^ We have utilized protein purification, cell culture, transient and stable gene transfection, and molecular biology approaches to identify this protein and investigate its possible function in the regulation of (SAA1) and other liver genes. Analyses of amino acid sequence of the purified nuclear protein, and western blot and gel shift studies identified the repressor as transcription factor AP-2 or AP-2-like protein. Using transient transfection of DNA into cultured cells, we demonstrate that AP-2 can indeed function as a repressor to inhibit transcription of SAA1 gene promoter. This conclusion is supported by the following experimental results: (1) overexpression of AP-2 in hepatoma cells inhibits conditioned medium (CM)-induced expression of SAA1 promoter; (2) binding of AP-2 to the SAA1 promoter is required for AP-2 repression function; (3) one mechanism by which AP-2 inhibits SAA1 may be by antagonizing the activation function of the strong transactivator NFκB; (4) mutation of AP-2 binding sites results in derepression of SAM promoter in HeLa cells; and (5) inhibition of endogenous AP-2 activity by a dominant-negative mutant abolishes AP-2's inhibitory effect on SAM promoter in HeLa cells. In addition to the SAM promoter, AP-2 also can bind to the promoter regions of six other liver genes tested, suggesting that it may have a broad functional role in restricting the expression of many liver genes in nonliver cells. Consistent with this notion, ectopic expression of AP-2 also represses CM-mediated activation of human third component of complement 3 promoter. Finally, in AP-2-expressing stable hepatoma cell lines, AP-2 inhibits not only the expression of endogenous SAA, but also the expression of several other endogenous liver genes including albumin, α-fetoprotein. ^ Our findings that AP-2 has the ability to repress the expression of liver genes in nonliver cells opens a new avenue of investigation of negative regulation of gene transcription, and should improve our understanding of tissue-specific expression of liver genes. In summary, our data provide evidence suggesting a novel role of AP-2 as a repressor, inhibiting the expression of liver genes in nonliver cells. Thus, the tissue-specific expression of AP-2 may constitute an important mechanism contributing to the liver-specific expression of liver genes. ^

PML tumor suppressor potentiates cell death through inhibition of the NF -kappa B survival pathway

The promyelocytic leukemia protein PML is a growth suppressor essential for induction of apoptosis by diverse apoptotic stimuli. The mechanism by which PML regulates cell death remains unclear. In this study we found that ectopic expression of PML potentiates cell death in the TNFα-resistant tumor line U2OS and significantly sensitized these cells to apoptosis induced by TNFα in a p53-independent manner. Our study demonstrated that both PML and PML/TNFα-induced cell death are associated with DNA fragmentation, activation of caspase-3, -7, -8, and degradation of DFF/ICAD. Furthermore, we found that PML-induced and PML/TNFα-induced cell death could be blocked by the caspase-8 inhibitors crmA and c-FLIP, but not by Bcl-2, the inhibitor of mitochondria-mediated apoptotic pathway. These findings indicate that this cell death event is initiated through the death receptor-dependent apoptosis pathway. Our study further showed that PML recruits NF-kappa B (NF-κB) to the PML nuclear body, blocks NF-κB binding to its cognate enhancer, and represses its transactivation function with the C-terminal region. Therefore PML inhibits the NF-κB survival pathway. Overexpression of NF-κB rescued cell death induced by PML and PML/TNFκ. These results imply that PML is a functional repressor of NF-κB. This notion was further supported by the finding that the PML−/− mouse embryo fibroblasts (MEFs) are more resistant than the wild-type MEFs to TNFκ-induced apoptosis. In conclusion, our studies convincingly demonstrated that PML potentiates cell death through inhibition of the NF-κB survival pathway. Activation of NF-κB frequently occurs during oncogenesis. Our study here suggests that a loss of PML function enhances the NF-κB survival pathway and this event may contribute to tumorigenesis. ^

Regulation of p53 antiproliferative function by transactivation domain phosphorylation at threonine 18 and serine 20

We investigated the induction and physiological role of Thr18 and Ser20 phosphorylation of p53 in response to DNA damage caused by treatment with ionizing (IR) or ultraviolet (UV) radiation. Polyclonal antibodies specifically recognizing phospho-Thr18 and phospho-Ser20 were used to detect p53 phosphorylation in vivo. Analyses of five wild-type (wt) p53 containing cell lines revealed lineage specific differences in phosphorylation of Thr18 and Ser20 after treatment with IR or UV. Importantly, the phosphorylation of p53 at Thr18 and Ser20 correlated with induction of the p53 downstream targets p21Waf1/Cip1 (p21) and Mdm-2, suggesting a transactivation enhancing role for Thr18 and Ser20 phosphorylation. Whereas Thr18 phosphorylation appears to abolish side-chain hydrogen bonding between Thr18 and Asp21, Ser20 phosphorylation may introduce charge attraction between Ser20 and Lys24. Both of these interactions could contribute to stabilizing α-helical conformation within the p53 transactivation domain. Mutagenesis-derived phosphorylation mimicry of p53 at Thr18 and Ser20 by Asp substitution (p53T18D/S20D) altered transactivation domain conformation and significantly reduced the interaction of p53 with the transactivation repressor Mdm-2. Mdm-2 interaction was also reduced with p53 containing a single site Asp substitution at Ser20 (p53S20D) and with the Thr18/Asp21 hydrogen bond disrupting p53 mutants p53T18A, p53T18D and p53D21A. In contrast, no direct effect was observed on the interaction of p53T18A, p53T18D and p53D21A with the basal transcription factor TAF II31. However, prior incubation of p53T18A, p53T18D and p53D21A with Mdm-2 modulated TAFII31 interaction, suggesting Mdm-2 blocks the accessibility of p53 to TAFII31. Consistently, p53-null cells transfected with p53S20D and p53T18A, p53T18D and p53D21A demonstrated enhanced endogenous p21 expression; transfection with p53T18D/S20D most significantly enhanced p21 and fas/APO-1 (fas ) expression. Expression of p53T18A, p53T18D and p53D21A in p53/Mdm-2-double null cells exhibited no discernible differences in p21 expression. Cell proliferation was also significantly curtailed in p53-null cells transfected with p53T18D/S20D relative to cells transfected with wt p53. We conclude the irradiation-induced phosphorylation of p53 at Thr18 and Ser20 alters the α-helical conformation of its transactivation domain. Altered conformation reduces direct interaction with the transrepressor Mdm-2, enhancing indirect recruitment of the basal transcription factor TAFII31, facilitating sequence-specific transactivation function resulting in proliferative arrest. ^

Oscillatory genetic circuits: new designs and mathematical models

Introduction and motivation: A wide variety of organisms have developed in-ternal biomolecular clocks in order to adapt to cyclic changes of the environment. Clock operation involves genetic networks. These genetic networks have to be mod¬eled in order to understand the underlying mechanism of oscillations and to design new synthetic cellular clocks. This doctoral thesis has resulted in two contributions to the fields of genetic clocks and systems and synthetic biology, generally. The first contribution is a new genetic circuit model that exhibits an oscillatory behav¬ior through catalytic RNA molecules. The second and major contribution is a new genetic circuit model demonstrating that a repressor molecule acting on the positive feedback of a self-activating gene produces reliable oscillations. First contribution: A new model of a synthetic genetic oscillator based on a typical two-gene motif with one positive and one negative feedback loop is pre¬sented. The originality is that the repressor is a catalytic RNA molecule rather than a protein or a non-catalytic RNA molecule. This catalytic RNA is a ribozyme that acts post-transcriptionally by binding to and cleaving target mRNA molecules. This genetic clock involves just two genes, a mRNA and an activator protein, apart from the ribozyme. Parameter values that produce a circadian period in both determin¬istic and stochastic simulations have been chosen as an example of clock operation. The effects of the stochastic fluctuations are quantified by a period histogram and autocorrelation function. The conclusion is that catalytic RNA molecules can act as repressor proteins and simplify the design of genetic oscillators. Second and major contribution: It is demonstrated that a self-activating gene in conjunction with a simple negative interaction can easily produce robust matically validated. This model is comprised of two clearly distinct parts. The first is a positive feedback created by a protein that binds to the promoter of its own gene and activates the transcription. The second is a negative interaction in which a repressor molecule prevents this protein from binding to its promoter. A stochastic study shows that the system is robust to noise. A deterministic study identifies that the oscillator dynamics are mainly driven by two types of biomolecules: the protein, and the complex formed by the repressor and this protein. The main conclusion of this study is that a simple and usual negative interaction, such as degradation, se¬questration or inhibition, acting on the positive transcriptional feedback of a single gene is a sufficient condition to produce reliable oscillations. One gene is enough and the positive transcriptional feedback signal does not need to activate a second repressor gene. At the genetic level, this means that an explicit negative feedback loop is not necessary. Unlike many genetic oscillators, this model needs neither cooperative binding reactions nor the formation of protein multimers. Applications and future research directions: Recently, RNA molecules have been found to play many new catalytic roles. The first oscillatory genetic model proposed in this thesis uses ribozymes as repressor molecules. This could provide new synthetic biology design principles and a better understanding of cel¬lular clocks regulated by RNA molecules. The second genetic model proposed here involves only a repression acting on a self-activating gene and produces robust oscil¬lations. Unlike current two-gene oscillators, this model surprisingly does not require a second repressor gene. This result could help to clarify the design principles of cellular clocks and constitute a new efficient tool for engineering synthetic genetic oscillators. Possible follow-on research directions are: validate models in vivo and in vitro, research the potential of second model as a genetic memory, investigate new genetic oscillators regulated by non-coding RNAs and design a biosensor of positive feedbacks in genetic networks based on the operation of the second model Resumen Introduccion y motivacion: Una amplia variedad de organismos han desarro-llado relojes biomoleculares internos con el fin de adaptarse a los cambios ciclicos del entorno. El funcionamiento de estos relojes involucra redes geneticas. El mo delado de estas redes geneticas es esencial tanto para entender los mecanismos que producen las oscilaciones como para diseiiar nuevos circuitos sinteticos en celulas. Esta tesis doctoral ha dado lugar a dos contribuciones dentro de los campos de los circuitos geneticos en particular, y biologia de sistemas y sintetica en general. La primera contribucion es un nuevo modelo de circuito genetico que muestra un comportamiento oscilatorio usando moleculas de ARN cataliticas. La segunda y principal contribucion es un nuevo modelo de circuito genetico que demuestra que una molecula represora actuando sobre el lazo de un gen auto-activado produce oscilaciones robustas. Primera contribucion: Es un nuevo modelo de oscilador genetico sintetico basado en una tipica red genetica compuesta por dos genes con dos lazos de retroa-limentacion, uno positivo y otro negativo. La novedad de este modelo es que el represor es una molecula de ARN catalftica, en lugar de una protefna o una molecula de ARN no-catalitica. Este ARN catalitico es una ribozima que actua despues de la transcription genetica uniendose y cortando moleculas de ARN mensajero (ARNm). Este reloj genetico involucra solo dos genes, un ARNm y una proteina activadora, aparte de la ribozima. Como ejemplo de funcionamiento, se han escogido valores de los parametros que producen oscilaciones con periodo circadiano (24 horas) tanto en simulaciones deterministas como estocasticas. El efecto de las fluctuaciones es-tocasticas ha sido cuantificado mediante un histograma del periodo y la función de auto-correlacion. La conclusion es que las moleculas de ARN con propiedades cataliticas pueden jugar el misnio papel que las protemas represoras, y por lo tanto, simplificar el diseno de los osciladores geneticos. Segunda y principal contribucion: Es un nuevo modelo de oscilador genetico que demuestra que un gen auto-activado junto con una simple interaction negativa puede producir oscilaciones robustas. Este modelo ha sido estudiado y validado matematicamente. El modelo esta compuesto de dos partes bien diferenciadas. La primera parte es un lazo de retroalimentacion positiva creado por una proteina que se une al promotor de su propio gen activando la transcription. La segunda parte es una interaction negativa en la que una molecula represora evita la union de la proteina con el promotor. Un estudio estocastico muestra que el sistema es robusto al ruido. Un estudio determinista muestra que la dinamica del sistema es debida principalmente a dos tipos de biomoleculas: la proteina, y el complejo formado por el represor y esta proteina. La conclusion principal de este estudio es que una simple y usual interaction negativa, tal como una degradation, un secuestro o una inhibition, actuando sobre el lazo de retroalimentacion positiva de un solo gen es una condition suficiente para producir oscilaciones robustas. Un gen es suficiente y el lazo de retroalimentacion positiva no necesita activar a un segundo gen represor, tal y como ocurre en los relojes actuales con dos genes. Esto significa que a nivel genetico un lazo de retroalimentacion negativa no es necesario de forma explicita. Ademas, este modelo no necesita reacciones cooperativas ni la formation de multimeros proteicos, al contrario que en muchos osciladores geneticos. Aplicaciones y futuras lineas de investigacion: En los liltimos anos, se han descubierto muchas moleculas de ARN con capacidad catalitica. El primer modelo de oscilador genetico propuesto en esta tesis usa ribozimas como moleculas repre¬soras. Esto podria proporcionar nuevos principios de diseno en biologia sintetica y una mejor comprension de los relojes celulares regulados por moleculas de ARN. El segundo modelo de oscilador genetico propuesto aqui involucra solo una represion actuando sobre un gen auto-activado y produce oscilaciones robustas. Sorprendente-mente, un segundo gen represor no es necesario al contrario que en los bien conocidos osciladores con dos genes. Este resultado podria ayudar a clarificar los principios de diseno de los relojes celulares naturales y constituir una nueva y eficiente he-rramienta para crear osciladores geneticos sinteticos. Algunas de las futuras lineas de investigation abiertas tras esta tesis son: (1) la validation in vivo e in vitro de ambos modelos, (2) el estudio del potential del segundo modelo como circuito base para la construction de una memoria genetica, (3) el estudio de nuevos osciladores geneticos regulados por ARN no codificante y, por ultimo, (4) el rediseno del se¬gundo modelo de oscilador genetico para su uso como biosensor capaz de detectar genes auto-activados en redes geneticas.

Functional and expression analysis of the metal-inducible dmeRF system from Rhizobium legumionosarum bv. viciae

A gene encoding a homolog to the cation diffusion facilitator protein DmeF from Cupriavidus metallidurans has been identified in the genome of Rhizobium leguminosarum UPM791. The R. leguminosarum dmeF gene is located downstream of an open reading frame (designated dmeR) encoding a protein homologous to the nickel- and cobalt-responsive transcriptional regulator RcnR from Escherichia coli. Analysis of gene expression showed that the R. leguminosarum dmeRF genes are organized as a transcriptional unit whose expression is strongly induced by nickel and cobalt ions, likely by alleviating the repressor activity of DmeR on dmeRF transcription. An R. leguminosarum dmeRF mutant strain displayed increased sensitivity to Co(II) and Ni(II), whereas no alterations of its resistance to Cd(II), Cu(II), or Zn(II) were observed. A decrease of symbiotic performance was observed when pea plants inoculated with an R. leguminosarum dmeRF deletion mutant strain were grown in the presence of high concentrations of nickel and cobalt. The same mutant induced significantly lower activity levels of NiFe hydrogenase in microaerobic cultures. These results indicate that the R. leguminosarum DmeRF system is a metal-responsive efflux mechanism acting as a key element for metal homeostasis in R. leguminosarum under free-living and symbiotic conditions. The presence of similar dmeRF gene clusters in other Rhizobiaceae suggests that the dmeRF system is a conserved mechanism for metal tolerance in legume endosymbiotic bacteria.

The AtCathB3 gene, encoding a cathepsin B-like protease, is expressed during germination of Arabidopsis thaliana and transcriptionally repressed by the basic leucine zipper protein GBF1.

Protein hydrolysis plays an important role during seed germination and post-germination seedling establishment. In Arabidopsis thaliana, cathepsin B-like proteases are encoded by a gene family of three members, but only the AtCathB3 gene is highly induced upon seed germination and at the early post-germination stage. Seeds of a homozygous T-DNA insertion mutant in the AtCathB3 gene have, besides a reduced cathepsin B activity, a slower germination than the wild type. To explore the transcriptional regulation of this gene, we used a combined phylogenetic shadowing approach together with a yeast one-hybrid screening of an arrayed library of approximately 1200 transcription factor open reading frames from Arabidopsis thaliana. We identified a conserved CathB3-element in the promoters of orthologous CathB3 genes within the Brassicaceae species analysed, and, as its DNA-interacting protein, the G-Box Binding Factor1 (GBF1). Transient overexpression of GBF1 together with a PAtCathB3::uidA (β-glucuronidase) construct in tobacco plants revealed a negative effect of GBF1 on expression driven by the AtCathB3 promoter. In stable P35S::GBF1 lines, not only was the expression of the AtCathB3 gene drastically reduced, but a significant slower germination was also observed. In the homozygous knockout mutant for the GBF1 gene, the opposite effect was found. These data indicate that GBF1 is a transcriptional repressor of the AtCathB3 gene and affects the germination kinetics of Arabidopsis thaliana seeds. As AtCathB3 is also expressed during post-germination in the cotyledons, a role for the AtCathB3-like protease in reserve mobilization is also inferred.

Factores transcripcionales de la clase DOF en Brachypodium distachyon: caracterización molecular de BdDOF24 durante la germinación de las semillas

La semilla es el órgano que garantiza la propagación y continuidad evolutiva de las plantas espermatofitas y constituye un elemento indispensable en la alimentación humana y animal. La semilla de cereales acumula en el endospermo durante la maduración, mayoritariamente, almidón y proteínas de reserva. Estas reservas son hidrolizadas en la germinación por hidrolasas sintetizadas en la aleurona en respuesta a giberelinas (GA), siendo la principal fuente de energía hasta que la plántula emergente es fotosintéticamente activa. Ambas fases del desarrollo de la semilla, están reguladas por una red de factores de transcripción (TF) que unen motivos conservados en cis- en los promotores de sus genes diana. Los TFs son proteínas que han desempeñado un papel central en la evolución y en el proceso de domesticación, siendo uno de los principales mecanismos de regulación génica; en torno al 7% de los genes de plantas codifican TFs. Atendiendo al motivo de unión a DNA, éstos, se han clasificado en familias. La familia DOF (DNA binding with One Finger) participa en procesos vitales exclusivos de plantas superiores y sus ancestros cercanos (algas, musgos y helechos). En las semillas de las Triticeae (subfamilia Pooideae), se han identificado varias proteínas DOF que desempeñan un papel fundamental en la regulación de la expresión génica. Brachypodium distachyon es la primera especie de la subfamilia Pooideae cuyo genoma (272 Mbp) ha sido secuenciado. Su pequeño tamaño, ciclo de vida corto, y la posibilidad de ser transformado por Agrobacterium tumefaciens (plásmido Ti), hacen que sea el sistema modelo para el estudio de cereales de la tribu Triticeae con gran importancia agronómica mundial, como son el trigo y la cebada. En este trabajo, se han identificado 27 genes Dof en el genoma de B. distachyon y se han establecido las relaciones evolutivas entre estos genes Dof y los de cebada (subfamilia Pooideae) y de arroz (subfamilia Oryzoideae), construyendo un árbol filogenético en base al alineamiento múltiple del dominio DOF. La cebada contiene 26 genes Dof y en arroz se han anotado 30. El análisis filogenético establece cuatro grupos de genes ortólogos (MCOGs: Major Clusters of Orthologous Genes), que están validados por motivos conservados adicionales, además del dominio DOF, entre las secuencias de las proteínas de un mismo MCOG. El estudio global de expresión en diferentes órganos establece un grupo de nueve genes BdDof expresados abundantemente y/o preferencialmente en semillas. El estudio detallado de expresión de estos genes durante la maduración y germinación muestra que BdDof24, ortólogo putativo a BPBF-HvDOF24 de cebada, es el gen más abundante en las semillas en germinación de B. distachyon. La regulación transcripcional de los genes que codifican hidrolasas en la aleurona de las semillas de cereales durante la post‐germinación ha puesto de manifiesto la existencia en sus promotores de un motivo tripartito en cis- conservado GARC (GA-Responsive Complex), que unen TFs de la clase MYB-R2R3, DOF y MYBR1-SHAQKYF. En esta tesis, se ha caracterizado el gen BdCathB de Brachypodium que codifica una proteasa tipo catepsina B y es ortólogo a los genes Al21 de trigo y HvCathB de cebada, así como los TFs responsables de su regulación transcripcional BdDOF24 y BdGAMYB (ortólogo a HvGAMYB). El análisis in silico del promotor BdCathB ha identificado un motivo GARC conservado, en posición y secuencia, con sus ortólogos en trigo y cebada. La expresión de BdCathB se induce durante la germinación, así como la de los genes BdDof24 y BdGamyb. Además, los TFs BdDOF24 y BdGAMYB interaccionan en el sistema de dos híbridos de levadura e in planta en experimentos de complementación bimolecular fluorescente. En capas de aleurona de cebada, BdGAMYB activa el promotor BdCathB, mientras que BdDOF24 lo reprime; este resultado es similar al obtenido con los TFs ortólogos de cebada BPBF-HvDOF24 y HvGAMYB. Sin embargo, cuando las células de aleurona se transforman simultáneamente con los dos TFs, BdDOF24 tiene un efecto aditivo sobre la trans-activación mediada por BdGAMYB, mientras que su ortólogo BPBF-HvDOF24 produce el efecto contrario, revirtiendo el efecto de HvGAMYB sobre el promotor BdCathB. Las diferencias entre las secuencias deducidas de las proteínas BdDOF24 y BPBF-HvDOF24 podrían explicar las funciones opuestas que desempeñan en su interacción con GAMYB. Resultados preliminares con líneas de inserción de T-DNA y de sobre-expresión estable de BdGamyb, apoyan los resultados obtenidos en expresión transitoria. Además las líneas homocigotas knock-out para el gen BdGamyb presentan alteraciones en anteras y polen y no producen semillas viables. ABSTRACT The seed is the plant organ of the spermatophytes responsible for the dispersion and survival in the course of evolution. In addition, it constitutes one of the most importan elements of human food and animal feed. The main reserves accumulated in the endosperm of cereal seeds through the maturation phase of development are starch and proteins. Its degradation by hydrolases synthetized in aleurone cells in response to GA upon germination provides energy, carbon and nitrogen to the emerging seedling before it acquires complete photosynthetic capacity. Both phases of seed development are controlled by a network of transcription factors (TFs) that interact with specific cis- elements in the promoters of their target genes. TFs are proteins that have played a central role during evolution and domestication, being one of the most important regulatory mechanisms of gene expression. Around 7% of genes in plant genomes encode TFs. Based on the DNA binding motif, TFs are classified into families. The DOF (DNA binding with One Finger) family is involved in specific processes of plants and its ancestors (algae, mosses and ferns). Several DOF proteins have been described to play important roles in the regulation of genes in seeds of the Triticeae tribe (Pooideae subfamily). Brachypodium distachyon is the first member of the Pooideae subfamily to be sequenced. Its small size and compact structured genome (272 Mbp), the short life cycle, small plant size and the possibility of being transformed with Agrobacterium tumefaciens (Ti-plasmid) make Brachypodium the model system for comparative studies within cereals of the Triticeae tribe that have big economic value such as wheat and barley. In this study, 27 Dof genes have been identified in the genome of B. distachyon and the evolutionary relationships among these Dof genes and those frome barley (Pooideae subfamily) and those from rice (Oryzoideae subfamily) have been established by building a phylogenetic tree based on the multiple alignment of the DOF DNA binding domains. The barley genome (Hordeum vulgare) contains 26 Dof genes and in rice (Oryza sativa) 30 genes have been annotated. The phylogenetic analysis establishes four Major Clusters of Orthologous Genes (MCOGs) that are supported by additional conserved motives out of the DOF domain, between proteins of the same MCOG. The global expression study of BdDof genes in different organs and tissues classifies BdDof genes into two groups; nine of the 27 BdDof genes are abundantly or preferentially expressed in seeds. A more detailed expression analysis of these genes during seed maturation and germination shows that BdDof24, orholog to barley BPBF-HvDof24, is the most abundantly expressed gene in germinating seeds. Transcriptional regulation studies of genes that encode hydrolases in aleurone cells during post-germination of cereal seeds, have identified in their promoters a tripartite conserved cis- motif GARC (GA-Responsive Complex) that binds TFs of the MYB-R2R3, DOF and MYBR1-SHAQKYF families. In this thesis, the characterization of the BdCathB gene, encoding a Cathepsin B-like protease and that is ortholog to the wheat Al21 and the barley HvCathB genes, has been done and its transcriptional regulation by the TFs BdDOF24 and BdGAMYB (ortholog to HvGAMYB) studied. The in silico analysis of the BdCathB promoter sequence has identified a GARC motif. BdCathB expression is induced upon germination, as well as, those of BdDof24 and BdGamyb genes. Moreover, BdDOF24 and BdGAMYB interact in yeast (Yeast 2 Hybrid System, Y2HS) and in planta (Bimolecular Fluorecence Complementation, BiFC). In transient assays in aleurone cells, BdGAMYB activates the BdCathB promoter, whereas BdDOF24 is a transcriptional repressor, this result is similar to that obtained with the barley orthologous genes BPBF-HvDOF24 and HvGAMYB. However, when aleurone cells are simultaneously transformed with both TFs, BdDOF24 has an additive effect to the trans-activation mediated by BdGAMYB, while its ortholog BPBF-HvDOF24 produces an opposite effect by reducing the HvGAMYB activation of the BdCathB promoter. The differences among the deduced protein sequences between BdDOF24 and BPBF-HvDOF24 could explain their opposite functions in the interaction with GAMYB protein. Preliminary results of T-DNA insertion (K.O.) and stable over-expression lines of BdGamyb support the data obtained in transient expression assays. In addition, the BdGamyb homozygous T-DNA insertion (K.O.) lines have anther and pollen alterations and they do not produce viable seeds.