A human RNase E-like activity that cleaves RNA sequences involved in mRNA stability control.

We have detected an endoribonucleolytic activity in human cell extracts that processes the Escherichia coli 9S RNA and outer membrane protein A (ompA) mRNA with the same specificity as RNase E from E. coli. The human enzyme was partially purified by ion-exchange chromatography, and the active fractions contained a protein that was detected with antibodies shown to recognize E. coli RNase E. RNA containing four repeats of the destabilizing motif AUUUA and RNA from the 3' untranslated region of human c-myc mRNA were also found to be cleaved by E. coli RNase E and its human counterpart in a fashion that may suggest a role of this activity in mammalian mRNA decay. It was also found that RNA containing more than one AUUUA motif was cleaved more efficiently than RNA with only one or a mutated motif. This finding of a eukaryotic endoribonucleolytic activity corresponding to RNase E indicates an evolutionary conservation of the components of mRNA degradation systems.

Interplay of Exoribonucleases, Hfq and Small RNAs Structural Determinants in the Control of Gene Expression

Dissertation presented to obtain the Ph.D degree in Biology

Strategies for revascularizing the ischemic retina

Les rétinopathies ischémiques (RI) sont la cause majeure de cécité chez les personnes âgées de moins de 65 ans. Il existe deux types de RIs soit la rétinopathie du prématuré (ROP) ainsi que la rétinopathie diabétique (RD). Les RIs sont décrites en deux phases soit la phase de vasooblitération, marquée par une perte importante de vaisseaux sanguins, et une phase de néovascularisation secondaire à lʼischémie menant à une croissance pathologique de vaisseaux. Cette seconde phase peut générer des complications cliniques telles quʼun oedème dans lʼhumeur vitré ainsi que le détachement de la rétine chez les patients déjà atteints dʼune RI. Les traitements approuvés pour les RIs visent à réduire la formation des vaisseaux pathologiques ou lʼoedème; mais ceux-ci malheureusement ne règlent pas les problèmes sous-jacents tels que la perte vasculaire et lʼischémie. La rétine est un tissu hautement vascularisé qui contribue à lʼirrigation et à lʼhoméostasie des neurones. Lʼinteraction neurovasculaire, comprenant de neurones, vaisseaux et cellules gliales, contribue au maintien de cette homéostasie. Durant le développement, les neurones et les cellules gliales jouent un rôle important dans la vascularisation de la rétine en sécrétant des facteurs qui stimulent l'angiogenèse. Cependant, nos connaissances sur lʼinteraction neurovasculaire dans les RIs sont limitées. En identifiant les interactions importantes entre les cellules composant cette unité neurovasculaire dans la rétine, nous pourrons viser des cibles qui engendreront une revascularisation seine afin de diminuer les signes pathologiques chez les patients atteints dʼune RI. Les travaux présentés dans cette thèse visent à mieux expliquer cette interaction neurovasculaire en soulignant des concepts importants propres aux RIs. En utilisant un modèle de rétinopathie induite par lʼoxygène chez la souris, qui reproduit les caractéristiques importantes de la ROP (et en certaines instances, la RD), nous identifions quelques molécules clés jouant un rôle significatif dans les RIs soit la sémaphorine 3A (sema3A), lʼIL-1β, ainsi que le récepteur PAR2. Nos résultats démontrent que Sema3A, sécrétée par les cellules ganglionnaires rétiniennes (CGRs) durant une ischémie, empêche la revascularisation normale et que cette expression est induite par lʼIL-1β provenant des microglies activées. En bloquant Sema3A directement ou via lʼinhibition de lʼIL- 1β, nous remarquons une revascularisation seine ainsi quʼune diminution importante des vaisseaux pathologiques. Cela nous indique que Sema3A est impliquée dans la guidance vasculaire et quʼelle contribue à la pathogenèse des RIs. Lʼactivation de façon exogène de PAR2, identifié aussi comme régulateur du récepteur de lʼIL-1β (IL- 1RI) sur les CGRs, se traduit par une diminution séquentielle de lʼIL-1RI et de Sema3A ce qui mène également à une revascularisation seine. En conclusion, ces travaux soulignent lʼimportance de lʼinteraction neurovasculaire ainsi que la guidance vasculaire dans les RIs. Ils renforcent lʼimportance de la communication entre neurone, vaisseau et microglie dans la pathogenèse des RIs. Finalement, nous identifions quelques molécules clés qui pourront servir comme cibles afin de lutter contre lʼischémie qui cause des problèmes vasculaires chez les patients atteints dʼune RI.

Is there a role for eIF5A in translation?

The putative translation factor eIF5A is essential for cell viability and is highly conserved from archaebacteria to mammals. This factor is the only cellular protein that undergoes an essential posttranslational modification dependent on the polyamine spermidine, called hypusination. This review focuses on the functional characterization of eIF5A. Although this protein was originally identified as a translation initiation factor, subsequent studies did not support a role for eIF5A in general translation initiation. eIF5A has also been implicated in nuclear export of HIV-1 Rev and mRNA decay, but these findings are controversial in the literature and may reflect secondary effects of eIF-5A function. Next, the involvement of eIF5A and hypusination in the control of the cell cycle and proliferation in various organisms is reviewed. Finally, recent evidence in favor of reconsidering the role of eIF5A as a translation factor is discussed. Future studies may reveal the specific mechanism by which eIF5A affects protein synthesis.

Pkc1 acts through Zds1 and Gic1 to suppress growth and cell polarity defects of a yeast eIF5A mutant

eIF5A is a highly conserved putative eukaryotic translation initiation factor that has been implicated in translation initiation, nucleocytoplasmic transport, mRNA decay, and cell proliferation, but with no precise function assigned so far. We have previously shown that high-copy PKCI suppresses the phenotype of tif51A-1, a temperature-sensitive mutant of eIF5A in S. cerevisiae. Here, in an attempt to further understand how Pkc1 functionally interacts with eIF-5A, it was determined that PKCI suppression of tif51A-1 is independent of the cell integrity MAP kinase cascade. Furthermore, two new suppressor genes, ZDS1 and GIC1, were identified. We demonstrated that ZDS1 and ZDS2 are necessary for PKC1, but not for GIC1 suppression. Moreover, high-copy GIC1 also suppresses the growth defect of a PKCI mutant (stt1), suggesting the existence of a Pkc1-Zds1-Gic1 pathway. Consistent with the function of Gic1 in actin organization, the tif51A-1 strain shows an actin polarity defect that is partially recovered by overexpression of Pkc1 and Zds1 as well as Gic1. Additionally, PCL1 and BNI1, important regulators of yeast cell polarity, also suppress tif51A-1 temperature sensitiviiy Taken together, these data strongly Support the correlated involvement of Pkc1 and eIF5A in establishing actin polarity, which is essential for bud formation and G1/S transition in S. cerevisiae.

MKK3/6-p38 MAPK signaling is required for IL-1 beta and TNF-alpha-induced RANKL expression in bone marrow stromal cells

Coupled bone turnover is directed by the expression of receptor-activated NF-kappa B ligand (RANKL) and its decoy receptor, osteoprotegerin (OPG). Proinflammatory cytokines, such as interleukin-1 beta (IL-1 beta) and tumor necrosis factor-alpha (TNF-alpha) induce RANKL expression in bone marrow stromal cells. Here, we report that IL-1 beta and TNF-alpha-induced RANKL requires p38 mitogen-activating protein kinase (MAPK) pathway activation for maximal expression. Real-time PCR was used to assess the p38 contribution toward IL-1 beta and TNF-alpha-induced RANKL mRNA expression. Steady-state RANKL RNA levels were increased approximately 17-fold by IL-1 beta treatment and subsequently reduced similar to 70%-90% when p38 MAPK was inhibited with SB203580. RANKL mRNA stability data indicated that p38 MAPK did not alter the rate of mRNA decay in IL-1 beta-induced cells. Using a RANKL-luciferase cell line receptor containing a 120-kB segment of the 5' flanking region of the RANKL gene, reporter expression was stimulated 4-5-fold by IL-1 beta or TNF-alpha treatment. IL-1 beta-induced RANKL reporter expression was completely blocked with specific p38 inhibitors as well as dominant negative mutant constructs of MAPK kinase-3 and -6. In addition, blocking p38 signaling in bone marrow stromal cells partially inhibited IL-1 beta and TNF-alpha-induced osteoclastogenesis in vitro. Results from these studies indicate that p38 MAPK is a major signaling pathway involved in IL-1 beta and TNF-alpha-induced RANKL expression in bone marrow stromal cells.

Genetic interactions of yeast eukaryotic translation initiation factor 5a (eIF5A) reveal connections to poly(A)-binding protein and protein kinase C signaling

The highly conserved eukaryotic translation initiation factor eIF5A has been proposed to have various roles in the cell, from translation to mRNA decay to nuclear protein export. To further our understanding of this essential protein, three temperature-sensitive alleles of the yeast TIF51A gene have been characterized. Two mutant eIF5A proteins contain mutations in a proline residue at the junction between the two eIFSA domains and the third, strongest allele encodes a protein with a single mutation in each domain, both of which are required for the growth defect. The stronger tif51A alleles cause defects in degradation of short-lived mRNAs, supporting a role for this protein in mRNA decay. A multicopy suppressor screen revealed six genes, the overexpression of which allows growth of a tif51A-1 strain at high temperature; these genes include PAB1, PKC1, and PKC1 regulators WSC1, WSC2, and WSC3. Further results suggest that eIFSA may also be involved in ribosomal synthesis and the WSC/PKC1 signaling pathway for cell wall integrity or related processes.

eIF5A: Uma proteína essencial para a viabilidade celular cuja função permanece obscura

The putative translation initiation factor 5A (eIF5A) is a highly abundant and conserved protein in all eukaryotes and archaebacteria. This factor is essential for cell viability and is the only cellular protein known to contain the unusual amino acid residue hypusine. In Saccharomyces cerevisiae eIF5A is expressed in aerobic conditions by the gene TIF51A. Although eIF5A has been known for almost 30 years, the biological role of this protein is still obscure. This article reviews the research on the function of eIF5A, discussing the evidence for its involvement in various steps of mRNA metabolism, including translation initiation, nucleocytoplasmic transport and mRNA decay. Moreover, it indicates other studies that have associated eIF5A with cell proliferation and cell cycle progression. Finally, this review presents recent results obtained in our laboratory that reemphasize the role of eIF5A in the translation scenario. Further experiments will be necessary to define the role played by eIF5A in the translational machinery.

Use of a synthetic lethal screen to identify genes related to TIF51A in Saccharomyces cerevisiae

The putative eukaryotic translation initiation factor 5A (eIF5A) is an essential protein for cell viability and the only cellular protein known to contain the unusual amino acid residue hypusine. eIF5A has been implicated in translation initiation, cell proliferation, nucleocytoplasmic transport, mRNA decay, and actin polarization, but the precise biological function of this protein is not clear. However, eIF5A was recently shown to be directly involved with the translational machinery. A screen for synthetic lethal mutations was carried out with one of the temperature-sensitive alleles of TIF51A (tif51A-3) to identify factors that functionally interact with eIF5A and revealed the essential gene YPT1. This gene encodes a small GTPase, a member of the rab family involved with secretion, acting in the vesicular trafficking between endoplasmatic reticulum and the Golgi. Thus, the synthetic lethality between TIF51A and YPT1 may reveal the connection between translation and the polarized distribution of membrane components, suggesting that these proteins work together in the cell to guarantee proper protein synthesis and secretion necessary for correct bud formation during G1/ S transition. Future studies will investigate the functional interaction between eIF5A and Ypt1 in order to clarify this involvement of eIF5A with vesicular trafficking. ©FUNPEC-RP.

Estudo do Fator de Início de Tradução de Eucariotos 5A (eIF5A) na tradução específica e na ligação direta com ribossomo

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Estudo do papel de eIF5A na síntese proteica

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Análise estrutural e funcional de eIF5A selvagem e mutadas

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

New insights about the posttranscriptional mechanisms triggered by iodide excess on sodium/iodide symporter (NIS) expression in PCCl3 cells

Iodide excess acutely downregulates NIS mRNA expression, as already demonstrated. PCCl3 cells treated or not with Nal, Nal + NaClO4 or Nal + Methimazole, for 30 min to 24 h, were used to further explore how iodide reduces NIS gene expression. NIS mRNA expression was evaluated by Real-Time PCR; its poly(A) tail length, by RACE-PAT; its translation rate, by polysome profile; total NIS content, by Western blotting. NIS mRNA decay rate was evaluated in actinomycin-D-treated cells, incubated with or without Nal for 0-6 h. Iodide treatment caused a reduction in NIS mRNA expression, half-life, poly(A) tail length, recruitment to ribosomes, as well as NIS protein expression. Perchlorate, but not methimazole, prevented these effects. Therefore, reduced poly(A) tail length of NIS mRNA seems to be related to its decreased half-life, in addition to its translation impairment. These data provide new insights about the molecular mechanisms involved in the rapid and posttranscriptional inhibitory effect of iodide on NIS expression. (C) 2011 Elsevier Ireland Ltd. All rights reserved.

Regulation of Nox4 expression by histone deacetylases in human endothelial cells : involvement of epigenetic mechanisms

Nox4 is a member of the NADPH oxidase family, which represents a major source of reactive oxygen species (ROS) in the vascular wall. Nox4-mediated ROS production mainly depends on the expression levels of the enzyme. The aim of my study was to investigate the mechanisms of Nox4 transcription regulation by histone deacetylases (HDAC). Treatment of human umbilical vein endothelial cells (HUVEC) and HUVEC-derived EA.hy926 cells with the pan-HDAC inhibitor scriptaid led to a marked decrease in Nox4 mRNA expression. A similar down-regulation of Nox4 mRNA expression was observed by siRNA-mediated knockdown of HDAC3. HDAC inhibition in endothelial cells was associated with enhanced histone acetylation, increased chromatin accessibility in the human Nox4 promoter region, with no significant changes in DNA methylation. In addition, the present study provided evidence that c-Jun played an important role in controlling Nox4 transcription. Knockdown of c-Jun with siRNA led to a down-regulation of Nox4 mRNA expression. In response to scriptaid treatment, the binding of c-Jun to the Nox4 promoter region was reduced despite the open chromatin structure. In parallel, the binding of RNA polymerase IIa to the Nox4 promoter was significantly inhibited as well, which may explain the reduction in Nox4 transcription. In conclusion, HDAC inhibition decreases Nox4 transcription in human endothelial cells by preventing the binding of transcription factor(s) and polymerase(s) to the Nox4 promoter, most likely because of a hyperacetylation-mediated steric inhibition. In addition, HDAC inhibition-induced Nox4 downregulation may also involves microRNA-mediated mRNA destabilization, because the effect of the scriptaid could be partially blocked by DICER1 knockdown or by transcription inhibition.