USING GENE THERAPY TO PREVENT ATRIAL FIBRILLATION

Liu, Zhao

08 February 2017

No description available.

Biomedical Engineering

Atrial fibrillation

gene therapy

atrial remodeling

CaMKII

post-operative atrial fibrillation

electrophysiology

KCNH2

Molecular mechanism of Arabidopsis CBF mediated plant cold-regulated gene transcriptional activation

Wang, Zhibin

22 September 2006

No description available.

Arabidopsis

CBF1

plant cold acclimation

transcriptional activation

mutational analysis

chromatin remodeling

Imaging of tissue injury-repair addressing the significance of oxygen and its derivatives

Ojha, Navdeep

10 December 2007

No description available.

Biomedical Imaging

Magnetic Resonance Imaging

Electron Paramagnetic Resonance

Stroke

Cardiac Remodeling

Wound healing

Ventricular Remodeling in a Large Animal Model of Heart Failure

Monreal, Gretel

24 June 2008

No description available.

Biomedical Research

heart failure

cardiac assist device

cytoskeleton

electrolytes

desmin

remodeling

Variation in Osteon Circularity and Its Impact on Estimating Age at Death

Goliath, Jesse Roberto

30 July 2010

No description available.

Biology

Microbiology

Physical Anthropology

age estimation

bone remodeling

osteon circularity

bone histomorphometry

cortical bone

Histomorphometry of Humeral Primary Bone: Evaluating the Endosteal Lamellar Pocket as an Indicator of Modeling Drift in Archaeological and Modern Skeletal Samples

Maggiano, Corey Michael

26 June 2012

No description available.

Archaeology

Biology

Histology

Physical Anthropology

Skeletal Biology

Bioarchaeology

Histology

Bone

Modeling

Remodeling

Drift

Plasticity of the Bony Carotid Canal and Its Clinical Use for Assessing Negative Remodeling of the Internal Carotid Artery / 頚動脈管の経時的狭小化と内頚動脈陰性リモデリング評価への応用

Oichi, Yuki

23 March 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23807号 / 医博第4853号 / 新制||医||1058(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 湊谷 謙司, 教授 YOUSSEFIAN Shohab, 教授 石見 拓 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

plasticity

carotid canal

moyamoya disease

remodeling

internal carotid artery

carotid artery ligation

490

TULA-2: A Novel Protein Tyrosine Phosphatase That Regulates Osteoclast Differentiation and Function

Back, Steven

January 2014

The human skeleton is a dynamic organ that serves multiple functions to maintain normal physiology and health. It protects vital organs, provides support for movement, houses marrow and maintains calcium homeostasis. The skeleton is maintained by the work of two cells with opposing functions: osteoblasts, cells that synthesize organic bone matrix and osteoclasts that degrade and resorb it. These cells interact with one another in a tightly regulated process known as the bone remodeling cycle. This cycle maintains the health of bone by removing and replacing weak or damaged bone and responding to stress loads by remodeling portions of the skeleton that require reinforcement. Osteoblasts differentiate from mesenchymal stem cells and respond to hormonal stimuli by synthesizing and secreting cytokines necessary for osteoclast differentiation. Osteoblasts may become embedded within mineralized matrix, becoming osteocytes, cells that can sense changes in mechanical loading and facilitate localization of the remodeling cycle. Osteoclasts differentiate from hematopoietic stem cells (HSC) when the cell surface receptors, c-FMS and RANK, are activated by ligands produced by osteoblasts, M-CSF and RANKL respectively. In addition to c-FMS and RANK stimulation, another calcium-mediated, co-stimulatory pathway must be activated to ensure proper osteoclast differentiation. This pathway is activated by two immunoreceptors, OSCAR and TREM-2 that interact with adaptor proteins termed FcRγ and DAP12 respectively. These adaptor proteins harbor immunoreceptor tyrosine-based activation motifs (ITAM), which exist on their cytoplasmic tail. Once the immunoreceptors are triggered, specific tyrosines within the ITAM motifs become phosphorylated and act as docking points for the tyrosine kinase, Syk. Once bound, Syk autophosphorylates and acts on its downstream targets. Syk dephosphorylation is, therefore, necessary to attenuate this signal to prevent over activation of osteoclasts. Recently, a novel tyrosine phosphatase, T-cell Ubiquitin ligand -2 (TULA-2) has been shown to dephosphorylate specific phosphotyrosine residues on Syk in various systems and has shown an increased specificity to dephosphorylate tyrosine 352. The goal of this project is to determine how TULA-2 mediated dephosphorylation of Syk regulates osteoclast differentiation and function. TULA-2 is a member of the TULA family of proteins, TULA and TULA-2. In spite of a significant homology and similar domain organization between TULA and TULA-2, only TULA-2 has significant phosphatase activity. Furthermore, whereas TULA is expressed only in lymphocytes, TULA-2 is expressed in most tissues albeit a higher level of expression is seen in cells of hematopoietic origin. In vivo analysis including Micro-computed tomography (Micro CT) and histomorphometry indicated that mice that lack both TULA and TULA-2 (DKO) have decreased bone mass compared to wild-type (WT) counterparts. An in vitro cell differentiation assay revealed that a larger population of osteoclast-like cells (OCL) could be cultivated from bone marrow isolated from DKO mice compared to OCL derived from WT bone marrow. An in vitro resorption pit assay revealed that DKO osteoclasts could resorb bone at a faster rate than WT counterparts. Additionally, over-expression of phosphatase-dead TULA-2 in WT osteoclasts increased the ability of the cells to resorb bone. At the molecular level, activation of the co-stimulatory pathway revealed increased tyrosine phosphorylation of Syk 352 in DKO pre-osteoclasts when compared to phosphorylation of Syk isolated from WT pre-osteoclasts. Cumulatively, the above data indicates that the absence of TULA-2 results in an increased signaling response leading to a larger population of hyperactive osteoclasts, which contributes to decreased bone mass in mice. These data suggest that the phosphatase activity of TULA-2 is required for negative regulation of bone resorption. / Cell Biology

Cellular Biology

Biochemistry

Biology, Molecular

Bone Remodeling

Kinase

Osteoclast

Phosphatase

Syk

Tula-2

Fundamental and applied research in ABA signaling: Regulation by ABA of the chromatin remodeling ATPase BRAHMA and biotechnological use of the PP2CA promoter

Peirats Llobet, Marta

13 June 2017

Optimal response to drought is critical for plant survival and will affect biodiversity and crop performance during climate change. Mitotically heritable epigenetic and dynamic chromatin state changes have been implicated in the plant response to the drought stress hormone abscisic acid (ABA). The Arabidopsis SWI/SNF chromatin-remodeling ATPase BRAHMA (BRM) modulates response to ABA by preventing premature activation of stress response pathways during germination. Here, we show that the core ABA signalosome formed by ABA receptors, PP2Cs and SnRK2s physically interact with BRM to regulate BRM activity and post-translationally modify BRM by phosphorylation/dephosphorylation. Genetic evidence suggests that BRM acts downstream of SnRK2.2/2.3 kinases and biochemical studies identified evolutionary conserved SnRK2 phosphorylation sites in the C-terminal region of BRM. Our data suggest that SnRK2-dependent phosphorylation of BRM leads to its inhibition, and PP2CA-mediated dephosphorylation of BRM restores the ability of BRM to repress ABA response. ABA plays a key role to regulate germination and post-germination growth and the AP2-type ABI4 and bZIP-type ABI5 transcription factors (TFs) are required for ABA-mediated inhibition of post-germination growth when the embryo encounters water stress. The growth arrest induced by ABI4 and ABI5 involves ABA signaling and in the case of ABI5, it has been demonstrated that ABA inhibits the activity of BRM to induce ABI5 transcription. Loss of BRM activity leads to destabilization of a nucleosome involved in repression of ABI5 transcription. Therefore reduction of BRM activity in the brm-3 allele leads to enhanced expression of ABI5 in 2-d-old seedlings and enhanced sensitivity to ABA. Novel genetic evidence obtained in this work indicates that ABI4 is one of the redundant TFs regulated by BRM that mediate ABA response during germination and early seedling growth. Thus, the association of BRM with the ABI4 locus together with the observed derepression of ABI4 expression in brm-3 suggests that BRM directly regulates ABI4 expression. Finally, this work provides a direct link between the ABA signalosome and the chromatin-remodeling ATPase BRM, which enables ABA-dependent modulation of BRM activity as a possible mechanism to enhance plant drought tolerance. Additionally, we identified and characterized the promoter of PP2CA as a stress-inducible promoter and we have used it to drive the expression of ABA receptors from Arabidopsis and Solanum lycopersicum. This technology appears to be promising for the expression of ABA receptors in an inducible manner and to generate drought tolerant plants. / La respuesta óptima a la sequía es crítica para la supervivencia de las plantas y afectará a la biodiversidad y al rendimiento de los cultivos durante el cambio climático. Las modificaciones epigenéticas y los cambios dinámicos del estado de la cromatina han sido implicados en la respuesta de la planta al ácido abscísico (ABA), la conocida como la hormona del estrés hídrico. La ATPasa remodeladora de cromatina de tipo SWI/SNF de Arabidopsis, BRAHMA (BRM), modula la respuesta al ABA mediante la prevención de la activación prematura de las vías de respuesta al estrés durante la germinación. Aquí, mostramos que el núcleo del señalosoma de ABA formado por los receptores de ABA, las PP2Cs y las SnRK2s interaccionan físicamente con BRM para regular su actividad y modificarla post-traduccionalmente por mecanismos de fosforilación/desfosforilación. La evidencia genética sugiere que BRM actúa aguas abajo de las quinasas SnRK2.2/2.3 y los estudios bioquímicos identificaron la presencia en la región C-terminal de BRM de sitios de fosforilación de las SnRK2 que estaban conservados evolutivamente. Nuestros datos sugieren que la fosforilación de BRM que depende de las SnRK2 conduce a su inhibición, y que la desfosforilación de BRM mediada por PP2CA restaura la capacidad de BRM para reprimir la respuesta a ABA. El ABA juega un papel clave en la regulación de la germinación y el crecimiento post germinativo y los factores de transcripción de tipo AP2 como ABI4 y de tipo bZIP como ABI5, son necesarios para la inhibición del crecimiento post germinativo mediado por ABA cuando los embriones encuentran estrés hídrico. La detención del crecimiento inducida por ABI4 y ABI5 implica la señalización de ABA y en el caso de ABI5, se ha demostrado que el ABA inhibe la actividad de BRM para inducir la transcripción de ABI5. La pérdida de actividad de BRM conduce a la desestabilización de un nucleosoma implicado en la represión de la transcripción de ABI5. Por lo tanto, la reducción de la actividad de BRM en el alelo brm-3 conduce a una mayor expresión de ABI5 en plántulas de 2 días y una mayor sensibilidad a ABA. La nueva evidencia genética obtenida en este trabajo indica que ABI4 es uno de los factores de transcripción redundantes regulados por BRM que median la respuesta a ABA durante los estadios de germinación y crecimiento temprano de las plántulas. La asociación de BRM con el locus ABI4, junto con la desrepresión de la expresión de ABI4 observada en el mutante brm-3 sugiere que BRM regula directamente la expresión de ABI4. Por último, este trabajo proporciona una relación directa entre el señalosoma de ABA y la ATPasa remodeladora de cromatina BRM, que permite la modulación de la actividad de BRM de modo dependiente de ABA como un posible mecanismo para mejorar la tolerancia a sequía de las plantas. Además, hemos identificado y caracterizado el promotor de PP2CA como un promotor inducible por estrés y lo hemos utilizado para dirigir la expresión de los receptores de ABA de Arabidopsis y Solanum lycopersicum. Esta tecnología parece ser prometedora para la expresión de receptores de ABA de modo inducible y para generar plantas tolerantes a la sequía. / La resposta òptima a la sequera és crítica per a la supervivència de les plantes i afectarà la biodiversitat i al rendiment dels cultius durant el canvi climàtic. Les modificacions epigenètiques i els canvis dinàmics de l'estat de la cromatina han estat implicats en la resposta de la planta a l'àcid abscísic (ABA), la coneguda com hormona de l'estrès hídric. La ATPasa remodeladora de cromatina de tipus SWI/SNF d'Arabidopsis, BRAHMA (BRM), modula la resposta al ABA mitjançant la prevenció de l'activació prematura de les vies de resposta a l'estrès durant la germinació. Ací, mostrem que el nucli del senyalosoma d'ABA format pels receptors d'ABA, les PP2Cs i les SnRK2s interaccionen físicament amb BRM per regular la seva activitat i modificar-la post-traduccionalment per mecanismes de fosforilació/desfosforilació. L'evidència genètica suggereix que BRM actua aigües avall de les quinases SnRK2.2/2.3 i els estudis bioquímics van identificar la presència, a la regió C-terminal de BRM, de llocs de fosforilació de les SnRK2 que estaven conservats evolutivament. Les nostres dades suggereixen que la fosforilació de BRM que depèn de les SnRK2, condueix a la inhibició de BRM, i que la defosforilació de BRM mediada per PP2CA restaura la capacitat de BRM per reprimir la resposta a ABA. El ABA juga un paper clau en la regulació de la germinació i el creixement post-germinació i els factors de transcripció de tipus AP2 com ABI4 i de tipus bZIP com ABI5, són necessaris per a la inhibició del creixement post-germinació mediat per ABA quan els embrions pateixen estrès hídric. La detenció del creixement induïda per ABI4 i ABI5 implica la senyalització d'ABA i en el cas d'ABI5, s'ha demostrat que l'ABA inhibeix l'activitat de BRM per induir la transcripció d'ABI5. La pèrdua d'activitat de BRM condueix a la desestabilització d'un nucleosoma implicat en la repressió de la transcripció d'ABI5. Per tant, la reducció de l'activitat de BRM a l'al·lel brm-3 condueix a una major expressió d'ABI5 en plàntules de 2 dies i una major sensibilitat a l'ABA. La nova evidència genètica obtinguda en aquest treball indica que ABI4 és un dels factors de transcripció redundants que són regulats per BRM que medien la resposta a l'ABA durant els estadis de germinació i creixement primerenc de les plàntules. Per tant, l'associació de BRM amb el locus ABI4, juntament amb la desrepressió de l'expressió de ABI4 observada al mutant brm-3 suggereix que BRM regula directament l'expressió d'ABI4. Finalment, aquest treball proporciona una relació directa entre el senyalosoma d'ABA i l'ATPasa remodeladora de cromatina BRM, que permet la modulació de l'activitat de BRM de manera dependent d'ABA com un possible mecanisme per millorar la tolerància a sequera de les plantes. A més, hem identificat i caracteritzat el promotor de PP2CA com un promotor induïble per estrès i l'hem utilitzat per dirigir l'expressió dels receptors d'ABA d'Arabidopsis i Solanum lycopersicum. Aquesta tecnologia sembla ser prometedora per a l'expressió de receptors d'ABA de manera induïble i per generar plantes tolerants a la sequera. / Peirats Llobet, M. (2017). Fundamental and applied research in ABA signaling: Regulation by ABA of the chromatin remodeling ATPase BRAHMA and biotechnological use of the PP2CA promoter [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/82694 / Premios Extraordinarios de tesis doctorales

BIOQUIMICA Y BIOLOGIA MOLECULAR

Analysis of Plant Homeodomain Proteins and the Inhibitor of Growth Family Proteins in Arabidopsis thaliana

Safaee, Natasha Marie

04 January 2010

Eukaryotic organisms require the ability to respond to their environments. They do so by utilizing signal transduction pathways that allow for signals to effect final biological responses. Many times, these final responses require new gene expression events that have been stimulated or repressed within the nucleus. Thus, much of the understanding of signal transduction pathways converges on the understanding of how signaling affects gene expression alterations (Kumar et al., 2004). The regulation of gene expression involves the modification of chromatin between condensed (closed, silent) and expanded (open, active) states. Histone modifications, such as acetylation, can determine the open versus closed status of chromatin. The PHD (Plant HomeoDomain) finger is a structural domain primarily found in nuclear proteins across eukaryotes. This domain specifically recognizes the epigenetic marks H3K4me2 and H3K4me3, which are di- and tri-methylated lysine 4 residues of Histone H3 (Loewith et al., 2000; Kuzmichev et al., 2002; Vieyra et al. 2002; Shiseki et al., 2003; Pedeux et al., 2005, Doyon et al., 2006). It is estimated that there are ~150 proteins that contain the PHD finger in humans (Solimon and Riabowol, 2007). The PHD finger is conserved in yeast and plants, however an analysis of this domain has only been performed done in Arabidopsis thaliana (Lee et al., 2009). The work presented in this report aims to extend the analysis of this domain in plants by identifying the PHD fingers of the crop species Oryza sativa (rice). In addition, a phylogenetic analysis of all PHD fingers in Arabidopsis and rice was undertaken. From these analyses, it was determined that there are 78 PHD fingers in Arabidopsis and 70 in rice. In addition, these domains can be categorized into classes and groups by defining features within the conserved motif. In a separate study, I investigated the function of two of the PHD finger proteins from Arabidopsis, ING1 (INhibitor of Growth1) and ING2. In humans, these proteins can be found in complexes associated with both open and closed chromatin. They facilitate chromatin remodeling by recruiting histone acetyltransferases and histone deacetylases to chromatin (Doyon et al., 2006, Pena et al., 2006). In addition, these proteins recognize H3K4me2/3 marks and are believed to be "interpreters" of the histone code (Pena et al., 2006, Shi et al., 2006). To understand the function of ING proteins in plants, I took a reverse genetics approach and characterized ing1 and ing2 mutants. My analysis revealed that these mutants are altered in time of flowering, as well as their response to nutrient and stress conditions. Lastly, I was able to show that ING2 protein interacts in vitro with SnRK1.1, a nutrient/stress sensor (Baena-Gonzalez et al., 2007). These results indicate a novel function for PHD proteins in plant growth, development and stress response. / Master of Science

Inhibitor of Growth

H3K4me3

Arabidopsis thaliana

Oryza sativa

chromatin remodeling

Plant Homeodomain