Importancia de la metilación y sumoilación de la coilina y del factor de supervivencia de las motoneuronas en el ensamblaje del cuerpo nuclear de Cajal

Tapia Martínez, Olga

08 October 2009

Los cuerpos nucleares de Cajal (CBs) son estructuras nucleares implicadas en la biogénesis de ribonucleoproteínas nucleares y nucleolares de pequeño tamaño (snRNPs y snoRNPs) requeridas para el procesamiento nuclear de pre-mRNAs y pre-rRNAs, respectivamente. El CB concentra la proteína coilina, un marcador molecular de esta estructura, snRNPs, el factor de supervivencia de las neuronas motoras (SNM) y las proteínas que comparte con el nucleolo Nopp140 y fibrilarina. Los CB son estructuras dependientes de transcripción, pero los mecanismos de ensamblaje molecular de estos cuerpos nucleares son poco conocidos.En este estudio se utilizan métodos de inmunofluorescencia, expresión ectópica de proteínas del CB y métodos bioquímicos para analizar la importancia de dos modificaciones postraduccionales, la metilación de la coilina y la conjugación con SUMO1 del factor SMN para el ensamblaje molecular de los CBs. Se ha utilizado la línea celular MCF7 como un modelo de hipometilación endógena debido al déficit del gen MTAP. La hipometilación de la coilina conduce al desensamblaje de los CBs y a la relocalización nucleolar de la coilina no metilada. Este efecto revierte en células transfectadas que expresan el gen MTAPwt, indicando que el grado de metilación de la coilina marca su destino nuclear.Respecto a la importancia de la sumoilación en el ensamblaje de los CBs, hemos demostrado la existencia de un subtipo de CBs que concentran SUMO1 y la conjugasa de SUMO Ubc9. En neuronas, hemos detectado la presencia de SUMO durante la fase de reformación de CBs, en la respuesta al estrés. Los experimentos de inmunoprecipitación confirman la interacción de SUMO-1 con el factor SMN y demuestran que la lisina K119, portadora de una secuencia consenso de sumoilación, es esencial para la regulación del número de CBs. / Cajal bodies (CBs) are nuclear structures involved in the biogenesis of small nuclear and nucleolar ribonucleoproteins (snRNPs and snoRNPs) required for nuclear processing of pre-mRNAs and pre-rRNAs, respectively. CBs concentrate the protein coilin, a molecular marker of this structure, snRNPs, the survival of motor neurons factor (SMN) and proteins shared with the nucleolus Nopp140 and fibrillarin. CBs are transcription-dependent structures, but the mechanisms of molecular assembly of these structures are poorly understood.In this study we used inmunofluorescence, ectopic expresion of CB proteins and biochemical methods to analyze the importance of two posttranslational modifications, methylation of coilin and conjugation of SMN with SUMO1, for the molecular assembly of CBs. The cell line MCF7 has been used as a model of endogenous hypomethylation due to the lack of MTAP gene. Coilin hypomethylation leads to the disassembly of CBs and nucleolar relocation of unmethylated coilin. This effect reverses in transfected cells expressing the gene MTAPwt, indicating that the degree of methylation of coilin directs its nuclear destination.On the importance of sumoylation in the assembly of CBs, we have demonstrated the existence of a subset of CBs which concentrate SUMO1 and the SUMO1 conjugase Ubc9. In neurons, we detected the presence of SUMO1 during the reformation of CBs in response to stress. Immunoprecipitation experiments confirm the molecular interaction of SUMO1 with SMN and demonstrate that lysine 119, carrying the SMN sumoylation consensus sequence, is essential for regulating the number of CBs.

Cajal body (CB)

cell nucleus

sumoilación

metilación

metiltioadenosina (MTA)

metiltioadenosina fosforilasa (MTAP)

SUMO1

coilina

MCF7

cuerpo de Cajal (CB)

nucleo celular

MCF7

coilin

survival of motor neurons factor (SMN)

SUMO1

methylthioadenosine phosphorylase (MTAP)

methylthioadenosine (MTA)

methylation

sumoylation

57

576

577

Recruitment of the complete hTREX complex is required for Kaposi's sarcoma-associated herpesvirus intronless mRNA nuclear export and virus replication

Boyne, J. R., Colgan, K. J., Whitehouse, A.

January 2008

A cellular pre-mRNA undergoes various post-transcriptional processing events, including capping, splicing and polyadenylation prior to nuclear export. Splicing is particularly important for mRNA nuclear export as two distinct multi-protein complexes, known as human TREX (hTREX) and the exon-junction complex (EJC), are recruited to the mRNA in a splicing-dependent manner. In contrast, a number of Kaposi's sarcoma-associated herpesvirus (KSHV) lytic mRNAs lack introns and are exported by the virus-encoded ORF57 protein. Herein we show that ORF57 binds to intronless viral mRNAs and functions to recruit the complete hTREX complex, but not the EJC, in order assemble an export component viral ribonucleoprotein particle (vRNP). The formation of this vRNP is mediated by a direct interaction between ORF57 and the hTREX export adapter protein, Aly. Aly in turn interacts directly with the DEAD-box protein UAP56, which functions as a bridge to recruit the remaining hTREX proteins to the complex. Moreover, we show that a point mutation in ORF57 which disrupts the ORF57-Aly interaction leads to a failure in the ORF57-mediated recruitment of the entire hTREX complex to the intronless viral mRNA and inhibits the mRNAs subsequent nuclear export and virus replication. Furthermore, we have utilised a trans-dominant Aly mutant to prevent the assembly of the complete ORF57-hTREX complex; this results in a vRNP consisting of viral mRNA bound to ORF57, Aly and the nuclear export factor, TAP. Strikingly, although both the export adapter Aly and the export factor TAP were present on the viral mRNP, a dramatic decrease in intronless viral mRNA export and virus replication was observed in the absence of the remaining hTREX components (UAP56 and hTHO-complex). Together, these data provide the first direct evidence that the complete hTREX complex is essential for the export of KSHV intronless mRNAs and infectious virus production.

Active transport; Cell nucleus

Metabolism

DEAD-box RNA Helicases

Exodeoxyribonucleases

Herpesvirus 8; Human; Physiology

Humans

Multiprotein complexes

Nuclear cap-binding protein complex

Nuclear export signals

Nuclear proteins

Phosphoproteins

RNA Processing; Post-transcriptional

RNA Transport

Messenger

Viral

RNA-binding proteins

Transcription factors

Viral proteins

Virus replication

REF 2014

Intranuclear Trafficking of RUNX/AML/CBFA/PEBP2 Transcription Factors in Living Cells: A Dissertation

Harrington, Kimberly Stacy

28 March 2003

The family of runt related transcription factors (RUNX/Cbfa/AML/PEBP2) are essential for cellular differentiation and fetal development. RUNX factors are distributed throughout the nucleus in punctate foci that are associated with the nuclear matrix/scaffold and generally correspond with sites of active transcription. Truncations of RUNX proteins that eliminate the C-terminus including a 31-amino acid segment designated the nuclear matrix targeting signal (NMTS) lose nuclear matrix association and result in lethal hematopoietic (RUNX1) and skeletal (RUNX2) phenotypes in mice. These findings suggest that the targeting of RUNX factors to subnuclear foci may mediate the formation of multimeric regulatory complexes and contribute to transcriptional control. In this study, we hypothesized that RUNX transcription factors may dynamically move through the nucleus and associate with subnuclear domains in a C-terminal dependent mechanism to regulate transcription. Therefore, we investigated the subnuclear distribution and mobility of RUNX transcription factors in living cells using enhanced green fluorescent protein (EGFP) fused to RUNX proteins. The RUNX C-terminus was demonstrated to be necessary for the dynamic association of RUNX with stable subnuclear domains. Time-lapse fluorescence microscopy showed that RUNX1 and RUNX2 localize to punctate foci that remain stationary in the nuclear space in living cells. By measuring fluorescence recovery after photobleaching, both RUNX1 and RUNX2 were found to dynamically and rapidly associate with these subnuclear foci with a half-time of recovery in the ten-second time scale. A large immobile fraction of RUNX1 and RUNX2 proteins was observed in the photobleaching experiments, which suggests that this fraction of RUNX1 and RUNX2 proteins are immobilized through the C-terminal domain by interacting with the nuclear architecture. Truncation of the C-terminus of RUNX2, which removes the NMTS as well as several co-regulatory protein interaction domains, increases the mobility of RUNX2 by at least an order of magnitude, resulting in a half-time of recovery equivalent to that of EGFP alone. Contributions of the NMTS sequence to the subnuclear distribution and mobility of RUNX2 were further assessed by creating point mutations in the NMTS of RUNX2 fused to EGFP. The results show that these point mutations decrease, but do not abolish, association with the nuclear matrix compared to wild-type EGFP-RUNX2. Three patterns of subnuclear distribution were similarly observed in living cells for both NMTS mutants and wild-type RUNX2. Furthermore, the NMTS mutations showed no measurable effect on the mobility of RUNX2. However, the mobility of RUNX proteins in each of the different subnuclear distributions observed in living cells were significantly different from each other. The punctate distribution appears to correlate with higher fluorescence intensity, suggesting that the protein concentration in the cell may have an effect on the formation or size of the foci. These findings suggest that the entire NMTS and/or the co-regulatory protein interaction domains may be necessary to immobilize RUNX2 proteins. Because RUNX factors contain a conserved intranuclear targeting signal, we examined whether RUNX1 and RUNX2 are targeted to common subnuclear domains. The results show that RUNX1 and RUNX2 colocalized in common subnuclear foci. Furthermore, RUNX subnuclear foci contain the co-regulatory protein CBFβ, which heterodimerizes with RUNX factors, and nascent transcripts as shown by BrUTP incorporation. These results suggest that RUNX subnuclear foci may represent sites of transcription containing multi-subunit transcription factor complexes. RUNX2 transcription factors induce expression of the osteocalcin promoter during osteoblast differentiation and to study both RUNX2 and osteocalcin function, it would be helpful to have transgenic mice in which OC expression could be easily evaluated. Therefore, to assess the in vivo regulation of osteocalcin by RUNX protein, we generated transgenic mice expressing EGFP controlled by the osteocalcin promoter. Our results show that EGFP is expressed from the OC promoter in a cultured osteosarcoma cell line, but not in a kidney cell line, and is induced by vitamin D3. Furthermore, the OC-EGFP transgenic mice specifically express EGFP in osteoblasts and osteocytes in bone tissues. Moreover, EGFP is expressed in mineralized bone nodules of differentiated bone marrow derived from transgenic mice. Thus, these mice produce a good model for studying the in vivo effects of RUNX-mediated osteocalcin regulation and for developing potential drug therapies for bone diseases. Taken together, our results in living cells support the conclusion that RUNX transcription factors dynamically associate with stationary subnuclear foci in a C-terminal dependent mechanism to regulate gene expression. Moreover, RUNX subnuclear foci represent transcription sites containing nascent transcripts and co-regulatory interacting proteins. These conclusions provide a mechanism for how RUNX transcription factors may associate with subnuclear foci to regulate gene expression. Furthermore, the OC-EGFP transgenic mice now provide a useful tool for studying the in vivo function and regulation of osteocalcin by RUNX proteins during osteoblast differentiation and possibly for developing therapeutic drugs for treatment of bone diseases in the future.

Transcription

Genetic

Transcription Factors

DNA-Binding Proteins

Focal Adhesions

Cell Nucleus

Nuclear Localization Signals

Osteocalcin

Osteocytes

Osteoblasts

Bone Diseases

Models

Animal

Microscopy

Fluorescence

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cell and Developmental Biology

Cells

Genetic Phenomena

Investigative Techniques

Musculoskeletal Diseases

Tissues

Transcript-Specific Cytoplasmic Degradation of YRA1 Pre-mRNA Mediated by the Yeast EDC3 Protein: A Dissertation

Dong, Shuyun

17 December 2007

mRNA degradation is a fundamental process that controls both the level and the fidelity of gene expression. Using a combination of bioinformatic, genomic, genetic, and molecular biology approaches, we have shown that Edc3p, a yeast mRNA decay factor, controls the stability of the intron-containing YRA1 pre-mRNA. We found that Edc3p-mediated degradation of YRA1 pre-mRNA: 1) is a component of a negative feedback loop involved in the autoregulation of YRA1, 2) takes place in the cytoplasm, 3) is independent of translation, 4) occurs through a deadenylation-independent decapping and 5΄ to 3΄ exonucleotic decay mechanism, and 5) is controlled by specific cis-acting elements and trans-regulatory factors. Cis-regulation of YRA1 pre-mRNA degradation is complicated and precise. Sequences in exon1 inhibit YRA1 pre-mRNA splicing and/or promote pre-mRNA export in a size-dependent but sequence-independent manner. Sequences in the intron dictate the substrate specificity for Edc3p-mediated decay. Five structurally different but functionally interdependent modules were identified in the YRA1 intron. Two modules, designated Edc3p-responsive elements (EREs), are required for triggering an Edc3p-response. Three other modules, designated translational repression elements (TREs), are required for repressing translation of YRA1 pre-mRNA. TREs enhance the efficiency of the response of the EREs to Edc3p by inhibiting translation-dependent nonsense-mediated mRNA decay (NMD). Trans-regulation of YRA1 pre-mRNA is governed by Yra1p, which inhibits YRA1 pre-mRNA splicing and commits the pre-mRNA to nuclear export, and the RNP export factors, Mex67p and Crm1p, which jointly promote YRA1 pre-mRNA export. Mex67p also appears to interact with sequences in the YRA1 intron to promote translational repression and to enhance the Edc3p response of YRA1 pre-mRNA. These results illustrate how common steps in the nuclear processing, export, and degradation of a transcript can be uniquely combined to control the expression of a specific gene and suggest that Edc3p-mediated decay may have additional regulatory functions in eukaryotic cells.

Gene Expression

Cell Nucleus

Feedback

Biochemical

Nuclear Proteins

RNA Stability

RNA Precursors

RNA-Binding Proteins

Saccharomyces cerevisiae

Amino Acids, Peptides, and Proteins

Biochemistry

Bioinformatics

Cells

Computational Biology

Fungi

Genetic Phenomena

Genetics

Genetics and Genomics

Genomics

Molecular Biology

Molecular Genetics

Resveratrol suppresses interleukin-1beta-induced inflammatory signaling and apoptosis in human articular chondrocytes: potential for use as a novel nutraceutical for the treatment of osteoarthritis

Shakibaei, M., Csaki, C., Nebrich, S., Mobasheri, A.

January 2008

No / Osteoarthritis is an inflammatory disease of load-bearing synovial joints that is currently treated with drugs that exhibit numerous side effects and are only temporarily effective on pain, the main symptom of the disease. Consequently, there is an acute need for novel, safe and more effective chemotherapeutic agents for the treatment of osteoarthritis and related arthritic diseases. Resveratrol is a phytoalexin stilbene produced naturally by plants including red grapes, peanuts and various berries. Recent research in various cell models has demonstrated that resveratrol is safe and has potent anti-inflammatory properties. However, its potential for treating arthritic conditions has not been explored. In this study we provide experimental evidence that resveratrol inhibits the expression of VEGF, MMP-3, MMP-9 and COX-2 in human articular chondrocytes stimulated with the pro-inflammatory cytokine IL-1beta. Since these gene products are regulated by the transcription factor NF-kappaB, we investigated the effects of resveratrol on IL-1beta-induced NF-kappaB signaling pathway. Resveratrol, like N-Ac-Leu-Leu-norleucinal (ALLN) suppressed IL-1beta-induced proteasome function and the degradation of IkappaBalpha (an inhibitor of NF-kappaB) without affecting IkappaBalpha kinase activation, IkappaBalpha-phosphorylation or IkappaBalpha-ubiquitination which suppressed nuclear translocation of the p65 subunit of NF-kappaB and its phosphorylation. Furthermore, we observed that resveratrol as well as ALLN inhibited IL-1beta-induced apoptosis, caspase-3 activation and PARP cleavage in human articular chondrocytes. In summary, our results suggest that resveratrol suppresses apoptosis and inflammatory signaling through its actions on the NF-kappaB pathway in human chondrocytes. We propose that resveratrol should be explored further for the prophylactic treatment of osteoarthritis in humans and companion animals.

Apoptosis

Drug effects

Physiology

Blotting

Western

Cartilage

Articular

Cytology

Metabolism

Cell nucleus

Cells

Cultured

Chondrocytes

Ultrastructure

Dietary supplements

Dose-response relationship

Extracellular matrix

Humans

Inflammation mediators

Interleukin-1beta

Microscopy

Electron

Transmission

NF-kappa B

Osteoarthritis

Resveratrol

Protein transport

Signal transduction

Stilbenes

REF 2014

Molecular Regulation of Interleukin-13 and Monocyte Chemoattractant Protein-1 Expression in Human Mast Cells by Interleukin-1beta

Lee, Steven A., Fitzgerald, S M., Huang, Shau K., Li, Chuanfu, Chi, David S., Milhorn, Denise M., Krishnaswamy, Guha

01 September 2004

Mast cells play pivotal roles in immunoglobulin (Ig) E-mediated airway inflammation, expressing interleukin (IL)-13 and monocyte chemoattractant protein-1 (MCP-1), which in turn regulate IgE synthesis and/or inflammatory cell recruitment. The molecular effects of IL-1beta on cytokine expression by human mast cells (HMC) have not been studied well. In this report, we provide evidence that human umbilical cord blood-derived mast cells (CBDMC) and HMC-1 cells express the type 1 receptor for IL-1. We also demonstrate that IL-1beta and tumor necrosis factor-alpha are able to induce, individually or additively, dose-dependent expression of IL-13 and MCP-1 in these cells. The induction of IL-13 and MCP-1 gene expression by IL-1beta was accompanied by the activation of IL-1 receptor-associated kinase and translocation of the transcription factor, nuclear factor (NF) kappaB into the nucleus. Accordingly, Bay-11 7082, an inhibitor of NF-kappaB activation, inhibited IL-1beta-induced IL-13 and MCP-1 expression. IL-1beta also induced IL-13 promoter activity while enhancing the stability of IL-13 messenger RNA transcripts. Dexamethasone, a glucocorticoid, inhibited IL-1beta-induced nuclear translocation of NF-kappaB and also the secretion of IL-13 from mast cells. Our data suggest that IL-1beta can serve as a pivotal costimulus of inflammatory cytokine synthesis in human mast cells, and this may be partly mediated by IL-1 receptor-binding and subsequent signaling via nuclear translocation of NF-kappaB. Because IL-1beta is a ubiquitously expressed cytokine, these findings have important implications for non-IgE-mediated signaling in airway mast cells as well as for innate immunity and airway inflammatory responses, such as observed in extrinsic and intrinsic asthma.

active transport

cell nucleus (drug effects

genetics)

cell line

chemokine CCL2 (genetics

immunology

metabolism)

dexamethasone (pharmacology)

dose-response relationship

drug

drug synergism

enzyme inhibitors (pharmacology)

gene expression regulation (drug effects

genetics)

humans

interleukin-1 (immunology

metabolism

pharmacology)

interleukin-13 (genetics

immunology

metabolism)

mast cells (drug effects

immunology

metabolism)

NF-kappa B (metabolism)

protein kinases (metabolism)

RNA

messenger (drug effects

metabolism)

receptors

interleukin-1 (immunology

metabolism)

receptors

interleukin-1 type I

tumor necrosis factor-alpha (immunology

metabolism

pharmacology)

Internal Medicine