Elucidation of Jasmonate-Responsive Promoter Elements in the Calmodulin-Like Gene CML39 in Arabidopsis

Maj, DAVID

27 September 2013

All organisms require rapid and flexible signaling mechanisms in order to effectively respond to biotic and abiotic stress. Calcium ions (Ca2+) have proven to be important components of signaling networks. Observations of stimulus-specific oscillations of cytosolic Ca2+ during signal transduction suggest that Ca2+ signals directly encode information. These stimulus-specific oscillations, known as Ca2+ signatures, can be interpreted by an array of Ca2+-binding sensors and effectors, which subsequently regulate appropriate cellular responses. While progress has been made regarding the classic Ca2+-sensor calmodulin (CaM), less research has been directed towards the CaM-like family of Ca2+-sensors (CMLs). This family – unique to plants – is suspected to regulate a multitude of stress and developmental pathways; however, to date very few members of this family have had their functions elucidated by the identification of downstream targets and upstream regulators. In the present study, I investigate the regulation of CML39, which has previously been shown to strongly respond to the stress hormone jasmonic acid (JA) in Arabidopsis. Bioinformatic tools predict a large number of putative JA-responsive cis-elements within the CML39 promoter. Deletion analysis of CML39 promoter fragments in planta reveals that some cis-elements respond in a tissue-specific manner. Analysis of transgenic MYC2 loss-of-function (myc2) mutants demonstrates that MYC2 – the preeminent JA-responsive transcription factor – is not necessary for CML39 promoter activity. Collectively, these data reveal a complex tissue-specific pattern of CML39 regulation and provide a foundation for the future identification of relevant transcription factors. / Thesis (Master, Biology) -- Queen's University, 2013-09-24 21:06:30.592

Calcium Signaling

Calmodulin-Like

Cis-Element

Promoter

Jasmonic Acid

Cis-elements Affecting Disease-associated Repeat Sequences

Hagerman, Katharine Anne

03 March 2010

The expansion of repetitive sequences leads to more than 40 neurological, neurodegenerative and neuromuscular diseases. These diseases are frequently characterized by ongoing DNA repeat instability upon transmission, worsening of disease severity and decreasing age of onset with each successive generation. The mechanism of repeat instability and contribution of repeat instability to disease pathogenesis are unknown. My thesis examines the contribution of cis-elements – sequences around and within repeats as well as surrounding epigenetic environments – to repeat instability, and discusses their possible contribution to repeat diseases. Here I identify the first cis-element regulating repeat instability, a DNA binding site for a trans factor protein, CTCF. Loss of CTCF binding at the spinocerebellar ataxia type 7 disease locus induces somatic and germline instability in an age- and tissue-specific manner in mice. CTCF protects against instability in an epigenetic manner, and may function at other disease loci also possessing CTCF binding sites near the repeat. Given that CTCF flanks many repeat loci and is often situated between a replication origin and disease-associated repeat, I assess the role of CTCF on replication and instability at the myotonic dystrophy repeat locus. Templates with CTCF binding sites reduce overall replication efficiency in primate cells that may be partly due to replication fork stalling. Mutating CTCF binding sites can alter the stability of the repeat depending on the distance from the origin of replication to the repeat. Finally I examine chromatinization of (ATTCT)n repeats from the spinocerebellar ataxia type 10 locus. These repeats induce very strong nucleosome formation, and at physiological conditions form even more strongly on (ATTCT)n repeats with interruptions that are also found in some patients. These data contribute to the understanding of repeat instability in the causation of many diseases, and suggest that the presence of cis-elements at repeat-associated disease loci alter the behaviour of repeats.

trinucleotide

myotonic dystrophy

CTCF

Spinocerebellar ataxia

cis-element

0369

Cis-elements Affecting Disease-associated Repeat Sequences

Hagerman, Katharine Anne

03 March 2010

The expansion of repetitive sequences leads to more than 40 neurological, neurodegenerative and neuromuscular diseases. These diseases are frequently characterized by ongoing DNA repeat instability upon transmission, worsening of disease severity and decreasing age of onset with each successive generation. The mechanism of repeat instability and contribution of repeat instability to disease pathogenesis are unknown. My thesis examines the contribution of cis-elements – sequences around and within repeats as well as surrounding epigenetic environments – to repeat instability, and discusses their possible contribution to repeat diseases. Here I identify the first cis-element regulating repeat instability, a DNA binding site for a trans factor protein, CTCF. Loss of CTCF binding at the spinocerebellar ataxia type 7 disease locus induces somatic and germline instability in an age- and tissue-specific manner in mice. CTCF protects against instability in an epigenetic manner, and may function at other disease loci also possessing CTCF binding sites near the repeat. Given that CTCF flanks many repeat loci and is often situated between a replication origin and disease-associated repeat, I assess the role of CTCF on replication and instability at the myotonic dystrophy repeat locus. Templates with CTCF binding sites reduce overall replication efficiency in primate cells that may be partly due to replication fork stalling. Mutating CTCF binding sites can alter the stability of the repeat depending on the distance from the origin of replication to the repeat. Finally I examine chromatinization of (ATTCT)n repeats from the spinocerebellar ataxia type 10 locus. These repeats induce very strong nucleosome formation, and at physiological conditions form even more strongly on (ATTCT)n repeats with interruptions that are also found in some patients. These data contribute to the understanding of repeat instability in the causation of many diseases, and suggest that the presence of cis-elements at repeat-associated disease loci alter the behaviour of repeats.

trinucleotide

myotonic dystrophy

CTCF

Spinocerebellar ataxia

cis-element

0369

Analysis of Connections Between Host Cytoplasmic Processing Bodies and Viral Life Cycles

Beckham, Carla Jolene

January 2007

In the past few years, cytoplasmic processing bodies (P-Bodies) have been identified in eukaryotic cells. P-bodies have roles in translational repression, mRNA storage, mRNA decay and are conserved cytoplasmic aggregations of non-translating mRNAs in conjunction with translation repression and mRNA degradation factors. In this work, I, in collaboration with others provide evidence for a new biological role for P-bodies in viral life cycles. This work can be summarized thus:In a collaborative effort, I have identified connections between retrovirallike transposon life cycles and P-bodies. For example, genetic evidence in yeast indicates that key proteins within P-bodies are required for the life cycles of the Ty1 and Ty3 retrotransposons. Moreover, Ty3 genomic RNA (gRNA) as well as viral structural proteins accumulate in P-bodies, suggesting that P-bodies may serve as sites of viral assembly.Second, I have shown, with assistance of collaborators, that the positivestrand RNA virus, Brome Mosaic Virus (BMV) gRNA accumulates in P-bodies Moreover, viral RNA dependent RNA polymerase (RdRp) colocalizes with and co-immunoprecipitates with the P-body protein Lsm1p, suggesting that P-bodies may participate in viral replication. Remarkably, the accumulation BMV gRNA in P-bodies is dependent on cis-elements that have been demonstrated to play critical roles in viral RNA replication.The identification of P-bodies as sites of accumulation of viral gRNA and viral proteins of both retro-virus like elements and positive-stranded RNA viruses, expands the list of important biological roles played by P-bodies. Since P-body proteins and structure are highly conserved, these findings imply that Pbodies will be important for other RNA viruses.

RNA viruses

P-bodies

Retrovirus

cis-element

replication complex

DNA Replication and Trinucleotide Repeat Instability in Myotonic Dystrophy Type 1

Cleary, John

06 August 2010

The expansion of gene-specific trinucleotide repeats is responsible for a growing list of human disorders, including myotonic dystrophy type 1 (DM1). Repeat instability for most of these disorders, including DM1, is characterized by complex patterns of inherited and ongoing tissue-specific instability and pathogenesis. While the mechanistic basis behind the unique locus-specific instability of trinucleotide repeats is currently unknown, DNA metabolic processes are likely to play a role. My thesis involves investigating the contribution of DNA replication to the trinucleotide instability of myotonic dystrophy type 1. Herein I have designed an in vivo primate model system, based on the SV40 replication system, to assess the contribution of DNA replication to DM1 repeat instability. This system allows the assessment, under controlled conditions, and manipulation of variables that may affect replication-associated repeat instability, under a primate cellular system. Using the SV40 model system, I not only confirmed previous observations that repeat length and replication direction affect repeat instability, but also for the first time determined that the location of the replication origin relative to the repeat tract plays an important role in repeat instability. This novel observation allowed for the development of a fork-shift model of repeat instability, in which cis-elements adjacent to the repeat tract affect replication, in turn altering the propensity for repeat instability. To further my study of DNA replication in DM1 repeat instability, I have mapped the origin of replication adjacent to the DM1 locus in human patient cells and the tissues of DM1 transgenic mice actively undergoing repeat instability. The position of the replication origins adjacent to the repeat tract at the DM1 locus places several known cis-elements, including CTCF binding sites, in a position to alter replication as predicted by the fork-shift model. My analysis of the CTCF sites showed them capable of altering replication and repeat instability at the DM1 locus. Taken together these results suggest that the placement of replication origins, repeat tracts and cis-elements, may mark trinucleotide repeat tracts, such as the DM1, for locus-, tissue- and development-specific replication-associated repeat instability.

DNA replication

neurodegeneration

triplet repeat

cis-element

instability

model system

0369

0307

Characterization and expression patterns of five Winter Rye ??-1,3-endoglucanases and their role in cold acclimation

McCabe, Shauna

January 2007

Winter rye produces ice-modifying antifreeze proteins upon cold treatment. Two of these antifreeze proteins are members of the large, highly conserved, ??-1,3-endoglucanase family. This project was designed to identify glucanase genes that are expressed during cold acclimation, wounding, pathogen infection, drought or treatment with the phytohormones ethylene and MeJa. Additionally, a more detailed proteomic analysis was to be carried out to evaluate the glucanase content of the apoplast of cold-acclimated (CA) winter rye. Results of 2D SDS-PAGE analysis revealed that non-acclimated whole leaf protein extracts contain at least two ??-1,3-endoglucanses while CA whole leaf protein extracts contain at least three ??-1,3-endoglucanses. Subsequent 2D SDS-PAGE analysis was conducted on the apoplast extracts of NA and CA winter rye plants revealed the limitations of standard 1D SDS-PAGE. The 2-dimensional gel analysis revealed that there is a minimum of 25 proteins within the apoplast of CA winter rye, including at least 5 ??-1,3-endoglucanases. Genome walking was used to isolate cold-responsive glucanase genes. The five genes isolated were designated scGlu6, scGlu9, scGlu10, scGlu11 and scGlu12. The cis-element pattern within the promoter of each gene was evaluated using online databases of documented plant cis elements. As expected, all of the promoters contained elements associated with cold, biotic and abiotic stresses, light regulation, and development. The expression patterns predicted by the cis elements in each promoter were compared to the mRNA abundance produced by each gene as detected by semi-quantitative reverse transcriptase PCR. In most cases, the abundance of transcripts arising from each gene loosely corresponded to the expression pattern predicted by the cis elements the corresponding promoter. Transcripts of scGlu9, 10 and 11 were present in cold-treated tissues and are candidates for ??-1,3-endoglucanases with antifreeze activity. The results presented in this thesis provide additional insight into the apoplast proteome of CA winter rye plants as well as the complexity of the signals controlling the proteins that reside there. Although there are still a number of unresolved questions, this research opens new directions for future studies in the cold acclimation process in winter rye and specifically for the contribution of ?? -1,3-endoglucanses.

antifreeze proteins

glucanase

promoter

cold-acclimation

winter rye

regulation

RT-PCR

2D SDS-PAGE

cis-element

DNA Replication and Trinucleotide Repeat Instability in Myotonic Dystrophy Type 1

Cleary, John

06 August 2010

The expansion of gene-specific trinucleotide repeats is responsible for a growing list of human disorders, including myotonic dystrophy type 1 (DM1). Repeat instability for most of these disorders, including DM1, is characterized by complex patterns of inherited and ongoing tissue-specific instability and pathogenesis. While the mechanistic basis behind the unique locus-specific instability of trinucleotide repeats is currently unknown, DNA metabolic processes are likely to play a role. My thesis involves investigating the contribution of DNA replication to the trinucleotide instability of myotonic dystrophy type 1. Herein I have designed an in vivo primate model system, based on the SV40 replication system, to assess the contribution of DNA replication to DM1 repeat instability. This system allows the assessment, under controlled conditions, and manipulation of variables that may affect replication-associated repeat instability, under a primate cellular system. Using the SV40 model system, I not only confirmed previous observations that repeat length and replication direction affect repeat instability, but also for the first time determined that the location of the replication origin relative to the repeat tract plays an important role in repeat instability. This novel observation allowed for the development of a fork-shift model of repeat instability, in which cis-elements adjacent to the repeat tract affect replication, in turn altering the propensity for repeat instability. To further my study of DNA replication in DM1 repeat instability, I have mapped the origin of replication adjacent to the DM1 locus in human patient cells and the tissues of DM1 transgenic mice actively undergoing repeat instability. The position of the replication origins adjacent to the repeat tract at the DM1 locus places several known cis-elements, including CTCF binding sites, in a position to alter replication as predicted by the fork-shift model. My analysis of the CTCF sites showed them capable of altering replication and repeat instability at the DM1 locus. Taken together these results suggest that the placement of replication origins, repeat tracts and cis-elements, may mark trinucleotide repeat tracts, such as the DM1, for locus-, tissue- and development-specific replication-associated repeat instability.

DNA replication

neurodegeneration

triplet repeat

cis-element

instability

model system

0369

0307

Characterization and expression patterns of five Winter Rye β-1,3-endoglucanases and their role in cold acclimation

McCabe, Shauna

January 2007

Winter rye produces ice-modifying antifreeze proteins upon cold treatment. Two of these antifreeze proteins are members of the large, highly conserved, β-1,3-endoglucanase family. This project was designed to identify glucanase genes that are expressed during cold acclimation, wounding, pathogen infection, drought or treatment with the phytohormones ethylene and MeJa. Additionally, a more detailed proteomic analysis was to be carried out to evaluate the glucanase content of the apoplast of cold-acclimated (CA) winter rye. Results of 2D SDS-PAGE analysis revealed that non-acclimated whole leaf protein extracts contain at least two β-1,3-endoglucanses while CA whole leaf protein extracts contain at least three β-1,3-endoglucanses. Subsequent 2D SDS-PAGE analysis was conducted on the apoplast extracts of NA and CA winter rye plants revealed the limitations of standard 1D SDS-PAGE. The 2-dimensional gel analysis revealed that there is a minimum of 25 proteins within the apoplast of CA winter rye, including at least 5 β-1,3-endoglucanases. Genome walking was used to isolate cold-responsive glucanase genes. The five genes isolated were designated scGlu6, scGlu9, scGlu10, scGlu11 and scGlu12. The cis-element pattern within the promoter of each gene was evaluated using online databases of documented plant cis elements. As expected, all of the promoters contained elements associated with cold, biotic and abiotic stresses, light regulation, and development. The expression patterns predicted by the cis elements in each promoter were compared to the mRNA abundance produced by each gene as detected by semi-quantitative reverse transcriptase PCR. In most cases, the abundance of transcripts arising from each gene loosely corresponded to the expression pattern predicted by the cis elements the corresponding promoter. Transcripts of scGlu9, 10 and 11 were present in cold-treated tissues and are candidates for β-1,3-endoglucanases with antifreeze activity. The results presented in this thesis provide additional insight into the apoplast proteome of CA winter rye plants as well as the complexity of the signals controlling the proteins that reside there. Although there are still a number of unresolved questions, this research opens new directions for future studies in the cold acclimation process in winter rye and specifically for the contribution of β -1,3-endoglucanses.

antifreeze proteins

glucanase

promoter

cold-acclimation

winter rye

regulation

RT-PCR

2D SDS-PAGE

cis-element

Biology

Deciphering the regulatory network controlling flavonoid biosynthesis by MYB-bHLH-WDR complexes in Arabidopsis seed / Caractérisation du réseau de régulation contrôlant la biosynthèse des flavonoïdes et impliquant des complexes MYB-bHLH-WDR dans la graine d'Arabidopsis

Xu, Wenjia

15 September 2014

Le contrôle combinatoire de l’ expression des gènes est une caractéristique importante du profil spatio-temporel de l'accumulation des flavonoïdes chez les plantes. Des résultats précédents avaient démontré chez Arabidopsis thaliana, que la régulation de l’accumulation des anthocyanes et des proanthocyanidines repose sur l'activité de facteurs de régulation de la transcription de type R2R3-MYB et bHLH qui forment des complexes ternaires ("MBW") avec la protéine TTG1 (WDR). L'objectif de la thèse était de caractériser les complexes MBW impliqués et leurs cibles, pour avoir une compréhension globale des mécanismes transcriptionnels qui contrôlent la biosynthèse des flavonoïdes.En utilisant différentes approches génétiques et moléculaires, nous avons montré que seuls les gènes « tardifs » (c’est à dire DFR, LDOX, BAN, TT19, TT12 et AHA10) sont des cibles directes des complexes MBW. Bien que le complexe de régulation impliquant les protéines TT2-TT8-TTG1 ait un rôle majeur dans la régulation de ces gènes structuraux dans la graine d’Arabidopsis, trois autres complexes contenant MYB5, GL3 ou EGL3 sont également impliqués de façon tissu-spécifique. Comme l’expression du gène TT8 joue un rôle clef dans ces régulations, une dissection fonctionnelle de son promoteur a été entreprise. Elle a montré la nature modulaire de ce promoteur avec deux domaines impliqués dans l’expression tissu-spécifique et un troisième dans la force du promoteur. Les résultats obtenus suggèrent également l’existence d’autres régulateurs qui restent à caractériser. Enfin, nous avons développé une nouvelle technique de caractérisation des interactions entre les facteurs de transcription et les promoteurs, basée sur l’expression transitoire dans des protoplastes de mousse (i.e. Physcomitrella patens). Nous avons ainsi pu identifier les éléments cis des promoteurs impliqués dans la régulation de l’expression de TT8 et de chacun des promoteurs cibles des complexes MBW.L’ensemble de ces travaux permet de fournir un modèle plus complet du réseau de régulations transcriptionnelles qui contrôle la biosynthèse des proanthocyanidines et des anthocyanes, ainsi que des outils et de nouvelles pistes pour poursuivre ces études chez Arabidopsis et d’autres plantes. / The combinatorial control of gene expression is a key feature of the spatio-temporal pattern of flavonoid accumulation in plants. Previous results have shown that the regulation of anthocyanins and proanthocyanidins (PAs or tannins) pigmentation relies on the transcriptional activity of R2R3-MYB and bHLH proteins that form “MBW” ternary complexes with TTG1 (WD-Repeats), in Arabidopsis thaliana. The purpose of the thesis was to figure out the nature and spatio-temporal activity of these MBW complexes and to identify their direct targets, which were essential steps toward a comprehensive understanding of the transcriptional mechanisms that control flavonoid biosynthesis. Using different molecular and genetic approaches this thesis has demonstrated that only late biosynthetic genes (namely DFR, LDOX, BAN, TT19, TT12 and AHA10) are direct targets of the MBW complexes. Interestingly, although the TT2-TT8-TTG1 complex was shown to play the major role in regulating the expression of these structural genes in developing seeds, three additional MBW complexes that contain MYB5, GL3 or EGL3 are also involved, in a tissue-specific manner. Because the expression of TT8 is largely involved in these regulations, a functional dissection of its promoter was carried out. Two modules drive the tissue-specific activity of the TT8 promoter in PA- and anthocyanin-accumulating cells, and a third module is responsible for the strength of the promoter. Interestingly, this regulation involves at least six different MBW complexes. Our results also suggest that some putative new regulators remain to be discovered. Last, use of a newly developed fast and sensitive transient expression system that relies on protoplasts of the moss Physcomitrella patens has allowed the identification of both, specific cis-regulatory elements through which TT8 expression is regulated and the minimal promoter for each of the genes that are targeted by the MBW complexes.Altogether, by answering fundamental questions and by demonstrating or invalidating previously made hypotheses, we have provided a new and comprehensive view of the regulatory mechanisms controlling PA and anthocyanin biosynthesis in Arabidopsis, as well as new clues and tools for further investigation of this pathway in Arabidopsis and other plant species.

Flavonoïdes

Anthocyanes

Arabidopsis thaliana

Cis-éléments

Proanthocyanidines

Facteur de transcription

Facteur de transcription

MYB

BHLH

MBW

Flavonoids

Anthocyanins

Arabidopsis thaliana

Cis-element

Proanthocyanidins

Transcription factor

Transparent testa

MYB

BHLH

MBW

Combining induced protease fragment assembly and microarray analysis to monitor signaling in living cells. / Combining induced protease fragment assembly and microarray analysis to monitor signaling in living cells.

Botvinnik, Anna

25 June 2009

No description available.

570 Biowissenschaften

Biologie

ERBB

Microarray

Signalübertragung

Hochdurchsatz

Reporter Gen

cis-element

TEV

ERBB

microarray

signal transduction

high throughput

reporter gene

cis-element

TEV

30.03

42.03

42.13

42.15

42.99

WA 700: Systeme in der Biologie

WH 000: Cytologie {Biologie}

WH 100: Cytologische Methoden

WHC 700: Zellrezeptoren

Zellrezeptoren

Membranrezeptoren

Zelluläre Kommunikation {Cytologie}

WR 000: Biotechnologie {Biologie}

WR 100: Methoden in der Biotechnologie

Bioverfahrenstechnik {Biologie}

WR 650

WR 870: Biosensoren

Biosensorik {Biologie

Biotechnologie}