Análise molecular de genes relacionados à síndrome de Pendred em indivíduos com surdez e estudo funcional da proteína pendrina = Molecular analysis of genes related to Pendred syndrome in individuals with deafness and functional study of pendrin protein / Molecular analysis of genes related to Pendred syndrome in individuals with deafness and functional study of pendrin protein

De Moraes, Vanessa Cristine Sousa, 1984-

23 August 2018

Orientador: Edi Lúcia Sartorato / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-23T15:12:43Z (GMT). No. of bitstreams: 1 DeMoraes_VanessaCristineSousa_D.pdf: 4935241 bytes, checksum: ce8c385da6e3872d30f08426c629d34d (MD5) Previous issue date: 2013 / Resumo: O alargamento do aqueduto vestibular (EVA) é uma malformação da orelha interna que pode ser identificado por tomografia computadorizada ou ressonância magnética. O EVA é um dos principais sinais clínicos da Síndrome de Pendred (PDS), uma doença genética com padrão de herança autossômico recessivo causada na maioria dos casos por mutações no gene SLC26A4. Além de EVA, o bócio e defeito na organificação do iodeto na tireóide são achados clínicos típicos da PDS. Por sua vez, mutações no gene SLC26A4 têm também sido observadas em indivíduos com surdez não sindrômica associada ao EVA. Recentemente os genes FOXI1 e KCNJ10 também foram implicados na PDS. O gene FOXI1 é um fator de transcrição do gene SLC26A4. Medições electrofisiológicas mostraram que a alteração da pendrina, proteína codificada pelo gene SLC26A4, em modelos animais levava indivíduos à surdez pela falta do potencial endococlear devido à perda de expressão de canais potássio. Sendo atribuído ao gene KCNJ10 a função de manutenção do potencial endococlear. Desta maneira, o presente estudo teve como objetivo avaliar a ocorrência de mutações nos genes SLC26A4, FOXI1 e KCNJ10 em 60 indivíduos brasileiros portadores de perda auditiva sensorioneural, associada ou não a alterações no aqueduto vestibular. Foram encontradas 14 diferentes alterações no gene SLC26A4, das quais 3 ainda não haviam sido descritas na literatura (P142L, G149R e C282Y) e 4 já haviam sido descritas, porém ainda não haviam sido caracterizadas funcionalmente (T193I, Q413R, L445W e R776C). Dessa forma, foi realizada a análise funcional e a co-localização celular da proteína Pendrina com estas 7 variações alélicas. Não foi encontrada nenhuma evidência de contribuição digênica relacionada ao gene FOXI1 e/ou KCNJ10, uma vez que nenhum paciente desta casuística com alteração no gene SLC26A4 apresentou mutações nesses genes. Além disso, no grupo composto por 30 indivíduos surdos que não apresentam EVA, ficou evidente que o rastreamento do gene SLC26A4 não foi suficiente para explicar a perda auditiva nesses pacientes, uma vez que foram encontradas apenas alterações em um alelo do gene. Por outro lado, no grupo formado por 30 indivíduos surdos que apresentam EVA, o rastreamento do gene SLC26A4 possibilitou o esclarecimento do diagnóstico etiológico da perda auditiva em 5 pacientes que apresentaram mutações nos dois alelos do gene SLC26A4 / Abstract: Enlargement of the vestibular aqueduct (EVA) is a malformation of the inner ear that can be identified by computed tomography or magnetic resonance imaging. EVA is the main feature of Pendred syndrome (PDS), a genetic disease with autosomal recessive inheritance pattern, in most cases caused by mutations in the SLC26A4 gene. Besides EVA, goiter and defective organification of iodide in the thyroid are other typical clinical signs of PDS. In turn, SLC26A4 gene mutations have been also observed in patients with non-syndromic deafness associated with EVA. Recently the genes FOXI1 and KCNJ10 were also implicated in the PDS. The FOXI1 gene is a transcription factor of SLC26A4 gene. Electrophysiological measurements in animal models showed that the mutated pendrin, the protein encoded by the SLC26A4 gene, led individuals to deafness by the lack of endocochlear potential due to loss of expression of potassium channels. Being assigned to the KCNJ10 gene the maintenance of endocochlear potential. Thus, the present study aimed to evaluate the occurrence of mutations in SLC26A4, and KCNJ10 FOXI1 genes in 60 Brazilian patients with sensorineural hearing loss, with or without changes in the vestibular aqueduct. We found 14 different mutations in SLC26A4 gene, of which 3 had not yet been described in the literature (P142L, G149R and C282Y) and 4 had already been described, but had not been characterized functionally yet (T193I, Q413R, L445W and R776C). Thus, we performed the functional analysis and cellular co-localization of Pendrin protein with these 7 allelic variants. We found no evidence of digenic contribution related to FOXI1 and/or KCNJ10 genes, since no patient in with mutations in SLC26A4 gene showed mutations in these genes. In addition, the screening of SLC26A4 gene in 30 deaf individuals with no EVA was not sufficient to explain the hearing loss in these patients, since mutations were found only in one allele of the gene. On the other hand, the screening of SLC26A4 gene in 30 deaf individuals with EVA allowed the elucidation of the etiology of hearing loss in 5 patients with mutations in both alleles of this gene / Doutorado / Genetica Animal e Evolução / Doutora em Genética e Biologia Molecular

Síndrome de Pendred

Surdez

Análise funcional

Localização subcelular

Mutação

Pendred syndrome

Deafness

Functional analysis

Subcellular localization

Mutation

Conjugated Polymer Nanoparticles for Biological Labeling and Delivery

Mendez, Eladio A

18 March 2015

Cancer remains one of the world’s most devastating diseases, with more than 10 million new cases every year. However, traditional treatments have proven insufficient for successful medical management of cancer due to the chemotherapeutics’ difficulty in achieving therapeutic concentrations at the target site, non-specific cytotoxicity to normal tissues, and limited systemic circulation lifetime. Although, a concerted effort has been placed in developing and successfully employing nanoparticle(NP)-based drug delivery vehicles successfully mitigate the physiochemical and pharmacological limitations of chemotherapeutics, work towards controlling the subcellular fate of the carrier, and ultimately its payload, has been limited. Because efficient therapeutic action requires drug delivery to specific organelles, the subcellular barrier remains critical obstacle to maximize the full potential of NP-based delivery vehicles. The aim of my dissertation work is to better understand how NP-delivery vehicles’ structural, chemical, and physical properties affect the internalization method and subcellular localization of the nanocarrier. In this work we explored how side-chain and backbone modifications affect the conjugated polymer nanoparticle (CPN) toxicity and subcellular localization. We discovered how subtle chemical modifications had profound consequences on the polymer’s accumulation inside the cell and cellular retention. We also examined how complexation of CPN with polysaccharides affects uptake efficiency and subcellular localization. This work also presents how changes to CPN backbone biodegradability can significantly affect the subcellular localization of the material. A series of triphenyl phosphonium-containing CPNs were synthesized and the effect of backbone modifications have on the cellular toxicity and intracellular fate of the material. A mitochondrial-specific polymer exhibiting time-dependent release is reported. Finally, we present a novel polymerization technique which allows for the controlled incorporation of electron-accepting benzothiadiazole units onto the polymer chain. This facilitates tuning CPN emission towards red emission. The work presented here, specifically, the effect that side-chain and structure, polysaccharide formulation and CPN degradability have on material’s uptake behavior, can help maximize the full potential of NP-based delivery vehicles for improved chemotherapeutic drug delivery.

Conjugated Polymers

Nanoparticles

Drug Delivery

Cellular Labeling

Subcellular localization

Cytotoxicity

Materials Chemistry

Nanotechnology

Organic Chemistry

Caracterização da fosforilação de maspina no desenvolvimento da glândula mamária murina e a correlação com sua localização subcelular. / Characterization of maspin phosphorylation in the development of the murine mammary gland and the correlation with subcellular localization.

Magna Magalhães Silva

10 September 2015

Maspina é uma proteína supressora de tumor e metástase e sua localização subcelular está relacionada ao prognóstico do câncer de mama. Nosso grupo mostrou em MCF-10A que quando fosforilada maspina se acumula no citoplasma. Porém, esta correlação ainda não foi relatada in vivo. Aqui investigamos a expressão, fosforilação e localização subcelular de maspina ao longo do desenvolvimento da glândula mamária murina. Maspina foi detectada no estágio mais tardio da gestação, na lactação e na involução. Os níveis de fosforilação de maspina são maiores no período de lactação do que na involução. Interessantemente, a porcentagem de células que apresenta maspina no núcleo é maior na fase de involução do que na fase de lactação Estes dados mostram que a correlação entre níveis de fosforilação de maspina e localização subcelular também é observada in vivo e que esses processos são reguladas ao longo do desenvolvimento na glândula mamária murina. / Maspin is a protein with tumor and metastasis suppressing activity and its subcellular localization is related to breast cancer prognosis. Using MCF-10A cells as a model system, our group demonstrated a correlation between maspin phosphorylation and cytoplasmic accumulation. Here we investigated maspin expression, phosphorylation levels and subcellular localization in vivo during the murine mammary gland development. Maspin was detected in late pregnancy, during lactation and involution. Maspin phosphorylation levels is higher during lactation than during involution. Interestingly, the percentage of cells which present nuclear maspin is higher in the involution than in lactation. These data show that the correlation between maspin phosphorylation and subcellular localization is also observed in vivo and these processes are regulated during murine mammary gland development.

Fosforilação

Glândula mamária

Localização subcelular

Maspina

Núcleo

Mammary gland

Maspin

Nucleus

Phosphorylation

Subcellular localization

The subcellular localization of Eucalyptus grandis sucrose synthase 1 (EgSUSY1) fusion proteins expressed in Arabidopsis thaliana

Sauer, Jamie-Lee

10 February 2012

Sucrose is the major transported photoassimilate in plants and is degraded concurrently by two enzymes: invertases and sucrose synthase. Sucrose synthase catalyzes the reversible conversion of UDP and sucrose to form fructose and UDP-glucose, the latter being the activated substrate for many metabolic processes including cellulose biosynthesis. There is evidence that sucrose synthase is phosphorylated as a regulatory mechanism of carbon allocation at a conserved N-terminal serine residue. The phosphorylation or dephosphorylation at this specific site has also been found to shift the protein localization in a tissue and species specific manner. A literature study of the functional regulation of sucrose synthase in plants has highlighted several scientific questions: Is sucrose synthase cellular localization regulated by phosphorylation of an N-terminal conserved serine residue? What are the regulatory mechanisms underlying within and between species variation in sucrose synthase localization? Does sucrose synthase associate with the cellulose synthase enzyme complex? Can cellulose biosynthesis be increased by over-expression of the membrane-associated form of sucrose synthase? The aim of this M.Sc study was to determine the subcellular localization of Eucalyptus grandis sucrose synthase 1 (EgSUSY1) fusion proteins expressed in Arabidopsis thaliana plants. This was investigated through modifying the 11th serine residue of EgSUSY1 into either a non-polar alanine residue that cannot be phosphorylated (S11A), or into a negatively charged glutamic acid residue which may mimic phosphorylation at this site (S11E). The modified proteins were translationally fused to green fluorescent protein (GFP) and expressed in transgenic Arabidopsis thaliana. The proteins’ subcellular localization were analysed in planta using laser scanning confocal microscopy (LSCM). Findings in this study point to the peripheral localization of modified and unmodified GFPEgSUSY1 proteins with a prominent cytoplasmic component. No evidence was found for the localization of modified or unmodified GFP-EgSUSY1 proteins within the extracellular matrix. The current study did not establish nor negate plasma membrane association of any of the GFP-EgSUSY1 fusion proteins. It was concluded that alternative methodologies need to be explored to further address issues surrounding subcellular localization of sucrose synthase. These studies will not only aid in defining the role of this enzyme in carbon allocation, but also add to our expanding knowledge of cellulose biosynthesis and cell wall formation. Copyright 2011, University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria. Please cite as follows: Sauer, J 2011, The subcellular localization of eucalyptus grandis sucrose synthase 1 (EgSUSY1) fusion proteins expressed in Arabidopsis thaliana, MSc dissertation, University of Pretoria, Pretoria, viewed yymmdd < http://upetd.up.ac.za/thesis/available/etd-02102012-102209 / > C12/4/111/gm / Dissertation (MSc)--University of Pretoria, 2011. / Genetics / unrestricted

Subcellular localization

Confocal microscopy

Gfp

Sucrose synthase

Eucalyptus grandis

Arabidopsis thaliana

UCTD

Antibody-based subcellular localization of the human proteome

Skogs, Marie

January 2016

This thesis describes the use of antibodies and immunofluorescence for subcellular localization of proteins. The key objective is the creation of an open-source atlas with information on the subcellular location of every human protein. Knowledge of the spatial distribution and the precise location of a protein within a cell is important for its functional characterization, and describing the human proteome in terms of compartment proteomes is important to decipher cellular organization and function.   Immunofluorescence and confocal microscopy of cultured cells were used for high-resolution detection of proteins on a high-throughput scale. Critical to immunofluorescence results are sample preparation and specific antibodies. Antibody staining of cells requires fixation and permeabilization, both of which can result in loss or redistribution of proteins and masking of epitopes. A high-throughput approach demands a standardized protocol suitable for the majority of proteins across cellular compartments. Paper I presents an evaluation of sample preparation techniques from which such a single fixation and permeabilization protocol was optimized. Paper II describes the results from applying this protocol to 4000 human proteins in three cell lines of different origin.   Paper III presents a strategy for application-specific antibody validation. Antibodies are the key reagents in immunofluorescence, but all antibodies have potential for off-target binding and should be validated thoroughly. Antibody performance varies across sample types and applications due to the competition present and the effect of the sample preparation on antigen accessibility. In this paper application-specific validation for immunofluorescence was conducted using colocalization with fluorescently tagged protein in transgenic cell lines. / <p>QC 20160509</p>

Human proteome

Subcellular localization

Organelles

Immunofluorescence

Fixation

Permeabilization

Antibody validation

Cell Biology

Cellbiologi

Subcellular Localization of Tobacco SABP2 under Normal and Stress Conditions

Das, Sanjeev

01 May 2020

Subcellular Localization of Tobacco SABP2 under Normal and Stress Conditions Salicylic acid (SA), a phytohormone, plays an important role in plant physiology. SA mediated innate immune pathway is an important pathway for plant immunity against pathogens. Plants resisting pathogen infection synthesize higher levels of Methyl Salicylate (MeSA), which is then converted to SA by the esterase activity of Salicylic Acid Binding Protein 2 (SABP2). The high level of the converted SA leads to enhanced pathogen resistance. The study of subcellular localization of a protein is critical in explaining its potential biochemical functions. SABP2 tagged with eGFP was expressed transiently in Nicotiana benthamiana leaves. The SABP2-eGFP expressing leaves were challenged with bacterial and viral pathogens and observed under confocal microscopy. Fluorescent signals were seen throughout the cell and more concentrated towards the cell periphery. To verify the localization, mCherry fluorescent organelle markers with specific targeting sequences were used. The results indicate that the SABP2 is likely a cytoplasmic protein, and there is no change in its localization upon infection by plant pathogens.

SABP2

Subcellular Localization

Confocal Microscopy

Biochemistry

Botany

Molecular Biology

Molecular Genetics

Plant Biology

Plant Pathology

Plants

Synthesis and application of ω-ethynyl fatty acids to analyze the physiological functions of eicosapentaenoic acid / ω-エチニル型脂肪酸の合成とエイコサペンタエン酸の生理機能解析への応用

Tokunaga, Tomohisa

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第21161号 / 農博第2287号 / 新制||農||1060(附属図書館) / 学位論文||H30||N5135(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 栗原 達夫, 教授 小川 順, 教授 阪井 康能 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

eicosapentaenoic acid

w-ethynyl eicosapentaenoic acid analog

click chemistry

subcellular localization

lipoprotein

Shewanella livingstonensis Ac10

610

NtCDKG;2, uma proteína multifuncional, relacionada aos processos de transcrição, processamento de RNA e organização do fuso acromático no ciclo celular de Nicotiana tabacum / NtCDKG;2, a multifunctional protein, related to RNA transcription, RNA processing and achromatic spindle organization in Nicotiana tabacum cell cycle

Lubini, Greice

13 December 2016

Os estudos em reprodução e desenvolvimento das plantas, especialmente voltados ao pistilo, são de grande interesse agronômico, econômico e científico. Em nosso laboratório, recentemente, foi identificado e caracterizado SCI1 (Stigma/style Cell-cycle Inhibitor 1), um inibidor do ciclo celular que atua de forma tecido específica no pistilo de Nicotiana tabacum L. e Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). Foi identificada a proteína NtCDKG;2 (N. tabacum Cyclin-dependent Kinase 2) como parceira de interação de NtSCI1 (N . tabacum SCI1), em um ensaio de pull-down (STRINI, 2014). A literatura aponta que os inibidores de ciclo celular regulam o ciclo através da inibição de CDK, o que sugere que NtSCI1 possa regular o ciclo celular através da inibição de NtCDKG;2. O presente estudo mostra análises detalhadas da localização de GFP-NtCDKG;2 em células epiteliais de N. benthamiana. Verificou-se que a proteína NtCDKG;2 está presente no nucleoplasma e também co-localiza em speckles nucleares. Em cultura de células BY2 expressando GFP-NtCDKG;2 de forma estável, foi observado que, durante a metáfase e anáfase, a proteína NtCDKG;2 está junto ao fuso acromático. Adicionalmente, ensaios de BiFC (Bi-molecular Fluorescence Complementation) realizados neste trabalho mostram que a interação entre as proteínas NtCDKG;2 e NtSCI1 ocorre em uma região localizada na periferia nucleolar, durante a interfase. Também foram identificadas possíveis isoformas de NtCDKG;2. A possibilidade da ocorrência de isoformas sugere que, de maneira análoga à sua homóloga em humanos, as isoformas resultantes de NtCDKG;2 possam atuar em diferentes processos. Em busca de parceiros de interação de NtCDKG;2, para identificar em que vias esta proteína atua, foi realizado um screening de uma biblioteca de cDNAs de estigmas e estiletes de N. tabacum, no sistema de duplo-híbrido em leveduras (Y2H). Através desse ensaio, foram identificados diversos parceiros envolvidos com transcrição e processamento de RNA. Dentre as proteínas identificadas, cuja interação foi confirmada neste trabalho, destaca-se a proteína NtCDKF;1, uma proteína que fosforila o CTD da RNA Polimerase II e, dessa forma, auxilia a transcrição e o splicing cotranscricional (HAJHEIDARI et al., 2012). O presente trabalho mostra também a interação entre NtCDKG;2 e a proteína NtCBP1, uma proteína que possui um papel importante na regulação inicial da transcrição de proteínas mediadoras do crescimento do tubo polínico (LI et al., 2015). xx Adicionalmente, o screening de Y2H possibilitou a identificação da interação entre NtCDKG;2 e NtRanBP1, uma proteína chave na formação do fuso acromático que, em humanos, interage com uma isoforma homóloga a NtCDKG;2, a CDK11p46 (MIKOLAJCZYK et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011). Análises in silico realizadas com a sequência de aminoácidos de NtCDKG;2 apontaram motivos de interação com proteína do tipo F-Box, ciclina, CDK, fosfatase, 14-3-3, BRCA1 e indicaram o local provável de interação do complexo CDK-Ciclina com o respectivo inibidor. Foi testada e comprovada a interação entre NtCDKG;2 e a 14-3-3D, por Y2H, uma parceira de NtSCI1. Outra lacuna que precisava ser preenchida é referente à regulação da expressão de NtSCI1. Com este intuito, foram realizadas análises in silico para identificar elementos cis-regulatórios na sequência genômica de NtSCI1. Essas análises indicaram a presença de importantes elementos cis-regulatórios relacionados à identidade meristemática (como WUSCHEL e AINTEGUMENTA), identidade do carpelo (AGAMOUS, BELL) e progressão do ciclo celular (E2F e CDC5). Algumas considerações podem ser feitas associando os resultados obtidos a estudos feitos paralelamente em nosso laboratório: 1) Compilando a localização de NtCDKG;2 em splicing speckles e sua interação com os diferentes parceiros de interação relacionados à transcrição e splicing, sugere-se que NtCDKG;2 também atue nos processos transcricionais e de splicing. 2) Considerando a localização subcelular de NtCDKG;2 durante as diferentes fases do ciclo celular, às análises in silico dessa proteína que identificaram sua possível interação com BRCA1, além da interação confirmada com a proteína NtRanBP1, é possível sugerir que NtCDKG;2 atue, direta ou indiretamente, na organização do fuso acromático de plantas. 3) Propõem-se que NtSCI1 regule a proliferação celular no pistilo através da interação com NtCDKG;2 que se dá no nucléolo das células. Dessa forma, NtSCI1 prenderia NtCDKG;2 no nucléolo e inibiria sua atuação, como na organização do fuso acromático, o que acarretaria inibição da divisão celular. 4) Devido aos motivos cis-regulatórios encontrados na sequência genômica de NtSCI1 e o efeito que a proteína possui desde as fases iniciais do desenvolvimento do pistilo, sugere-se que a expressão desse gene seja regulada por elementos diretamente envolvidos no controle do término do meristema floral e nas vias de desenvolvimento de órgãos florais. / Studies on plant reproduction and development, specifically those related to the pistil, are of great agronomic, economic and scientific interest. In our laboratory, we recently identified and characterized SCI1 (Stigma/style Cell-cycle Inhibitor 1), an inhibitor of the cell cycle which acts tissuespecifically in the pistil of Nicotiana tabacum L. and Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). The NtCDKG;2 (N. tabacum Cyclin-dependent Kinase G; 2) protein was identified as an interaction partner of NtSCI1 (N. tabacum SCI1) in a pulldown assay (STRINI, 2014). The literature suggests that cell cycle inhibitors control the cycle through the inhibition of CDKs, indicating that NtSCI1 might control cell cycle by inhibiting NtCDKG;2. This study shows detailed analysis of GFP-NtCDKG;2 localization in leaf cells of N. benthamiana. The analysis shows that NtCDKG;2 is present in the nucleoplasm and also co-localizes with nuclear speckles. In BY2 cell culture stably expressing GFP-NtCDKG;2, it was observed that NtCDKG;2 is at the achromatic spindle during metaphase and anaphase. Additionally, BiFC (Bimolecular Fluorescence Complementation) assays performed in this study have shown that the interaction of NtCDKG;2 and NtSCI1 occurs in the nucleolar periphery during interphase. Putative isoforms of NtCDKG;2 were also identified. The possible occurrence of these isoforms suggests that, in a similar way to its human homologue, NtCDKG;2 putative isoforms could act in different processes. To identify in which processes this protein could act, a search for NtCDKG;2 interaction partners was performed through the screening of a N. tabacum stigma and style cDNA library in the yeast two-hybrid (Y2H) system. Several partners identified through this assay have roles in RNA transcription and processing. Among the identified partners with interaction confirmed during this work, stands out the NtCDKF;1 protein, a CDK that phosphorylates the RNA polymerase II CTD, and thus, supports transcription and co-transcriptional splicing (HAJHEIDARI et al., 2012). This study also shows the interaction of NtCDKG;2 with NtCBP1, a protein which has an important role in the transcriptional regulation of genes encoding proteins mediating pollen tube growth (LI et al., 2015). Furthermore, the Y2H screening allowed the identification of the interaction of NtCDKG;2 with NtRanBP1, a key protein in the formation of the achromatic spindle which, in humans, interacts with the CDK11p46 isoform (MIKOLAJCZYK xxii et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011), a homologue of NtCDKG;2. In silico analysis of the amino acid sequence of NtCDKG;2 revealed motifs of predicted interaction with F-box proteins, cyclins, CDKs, phosphatases, 14-3-3s, BRCA1, and also pointed the region where the CDK-cyclin complex might interact with its respective inhibitor. The interaction of NtCDKG;2 with 14-3-3D, a known partner of NtSCI1, was tested and confirmed by Y2H. Another gap that needed to be filled is related to the regulation of NtSCI1 expression. To address this issue, in silico analysis to identify cis-regulatory elements was performed in NtSCI1 genomic region. These analyses revealed the presence of important cis-regulatory elements related to meristem identity (such as WUSCHEL and AINTEGUMENTA), carpel identity (AGAMOUS, BELL), and cell cycle progression (E2F and CDC5). Taken together results from this study and parallel studies performed in our laboratory, a few remarks can be made: 1) Taken the localization of NtCDKG;2 in splicing speckles, and its interaction with different proteins involved in transcription and splicing, it is suggested that NtCDKG;2 also has roles on these processes; 2) Considering the subcellular localization of NtCDKG;2 during the different cell cycle phases, the in silico analysis of this protein that predicts its interaction with BRCA1, and the confirmed interaction with NtRanBP1 protein, it is possible to suggest that NtCDKG;2 has a direct or indirect role in the organization of the achromatic spindle in plants; 3) It is proposed that NtSCI1 regulates cell proliferation in the pistil through its interaction with NtCDKG;2, which occurs in the nucleolus. Thus, NtSCI1 could hold NtCDKG;2 in the nucleolus, inhibiting its actions, such as in the organization of the achromatic spindle, resulting in cell division arrest. 4) Due to the cis-regulatory elements found in the genomic sequence of NtSCI1, and the effect of this protein since the initial stages of pistil development, it is suggested that its expression is regulated by elements directly involved in the control of the floral meristem termination and pathways of floral organ development.

achromatic spindle

BiFC

BiFC

CDK

CDK

cell cycle

ciclo celular

fuso acromático

localização subcelular

SCI1

SCI1

subcellular localization

Y2H

Y2H

NtCDKG;2, uma proteína multifuncional, relacionada aos processos de transcrição, processamento de RNA e organização do fuso acromático no ciclo celular de Nicotiana tabacum / NtCDKG;2, a multifunctional protein, related to RNA transcription, RNA processing and achromatic spindle organization in Nicotiana tabacum cell cycle

Greice Lubini

13 December 2016

Os estudos em reprodução e desenvolvimento das plantas, especialmente voltados ao pistilo, são de grande interesse agronômico, econômico e científico. Em nosso laboratório, recentemente, foi identificado e caracterizado SCI1 (Stigma/style Cell-cycle Inhibitor 1), um inibidor do ciclo celular que atua de forma tecido específica no pistilo de Nicotiana tabacum L. e Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). Foi identificada a proteína NtCDKG;2 (N. tabacum Cyclin-dependent Kinase 2) como parceira de interação de NtSCI1 (N . tabacum SCI1), em um ensaio de pull-down (STRINI, 2014). A literatura aponta que os inibidores de ciclo celular regulam o ciclo através da inibição de CDK, o que sugere que NtSCI1 possa regular o ciclo celular através da inibição de NtCDKG;2. O presente estudo mostra análises detalhadas da localização de GFP-NtCDKG;2 em células epiteliais de N. benthamiana. Verificou-se que a proteína NtCDKG;2 está presente no nucleoplasma e também co-localiza em speckles nucleares. Em cultura de células BY2 expressando GFP-NtCDKG;2 de forma estável, foi observado que, durante a metáfase e anáfase, a proteína NtCDKG;2 está junto ao fuso acromático. Adicionalmente, ensaios de BiFC (Bi-molecular Fluorescence Complementation) realizados neste trabalho mostram que a interação entre as proteínas NtCDKG;2 e NtSCI1 ocorre em uma região localizada na periferia nucleolar, durante a interfase. Também foram identificadas possíveis isoformas de NtCDKG;2. A possibilidade da ocorrência de isoformas sugere que, de maneira análoga à sua homóloga em humanos, as isoformas resultantes de NtCDKG;2 possam atuar em diferentes processos. Em busca de parceiros de interação de NtCDKG;2, para identificar em que vias esta proteína atua, foi realizado um screening de uma biblioteca de cDNAs de estigmas e estiletes de N. tabacum, no sistema de duplo-híbrido em leveduras (Y2H). Através desse ensaio, foram identificados diversos parceiros envolvidos com transcrição e processamento de RNA. Dentre as proteínas identificadas, cuja interação foi confirmada neste trabalho, destaca-se a proteína NtCDKF;1, uma proteína que fosforila o CTD da RNA Polimerase II e, dessa forma, auxilia a transcrição e o splicing cotranscricional (HAJHEIDARI et al., 2012). O presente trabalho mostra também a interação entre NtCDKG;2 e a proteína NtCBP1, uma proteína que possui um papel importante na regulação inicial da transcrição de proteínas mediadoras do crescimento do tubo polínico (LI et al., 2015). xx Adicionalmente, o screening de Y2H possibilitou a identificação da interação entre NtCDKG;2 e NtRanBP1, uma proteína chave na formação do fuso acromático que, em humanos, interage com uma isoforma homóloga a NtCDKG;2, a CDK11p46 (MIKOLAJCZYK et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011). Análises in silico realizadas com a sequência de aminoácidos de NtCDKG;2 apontaram motivos de interação com proteína do tipo F-Box, ciclina, CDK, fosfatase, 14-3-3, BRCA1 e indicaram o local provável de interação do complexo CDK-Ciclina com o respectivo inibidor. Foi testada e comprovada a interação entre NtCDKG;2 e a 14-3-3D, por Y2H, uma parceira de NtSCI1. Outra lacuna que precisava ser preenchida é referente à regulação da expressão de NtSCI1. Com este intuito, foram realizadas análises in silico para identificar elementos cis-regulatórios na sequência genômica de NtSCI1. Essas análises indicaram a presença de importantes elementos cis-regulatórios relacionados à identidade meristemática (como WUSCHEL e AINTEGUMENTA), identidade do carpelo (AGAMOUS, BELL) e progressão do ciclo celular (E2F e CDC5). Algumas considerações podem ser feitas associando os resultados obtidos a estudos feitos paralelamente em nosso laboratório: 1) Compilando a localização de NtCDKG;2 em splicing speckles e sua interação com os diferentes parceiros de interação relacionados à transcrição e splicing, sugere-se que NtCDKG;2 também atue nos processos transcricionais e de splicing. 2) Considerando a localização subcelular de NtCDKG;2 durante as diferentes fases do ciclo celular, às análises in silico dessa proteína que identificaram sua possível interação com BRCA1, além da interação confirmada com a proteína NtRanBP1, é possível sugerir que NtCDKG;2 atue, direta ou indiretamente, na organização do fuso acromático de plantas. 3) Propõem-se que NtSCI1 regule a proliferação celular no pistilo através da interação com NtCDKG;2 que se dá no nucléolo das células. Dessa forma, NtSCI1 prenderia NtCDKG;2 no nucléolo e inibiria sua atuação, como na organização do fuso acromático, o que acarretaria inibição da divisão celular. 4) Devido aos motivos cis-regulatórios encontrados na sequência genômica de NtSCI1 e o efeito que a proteína possui desde as fases iniciais do desenvolvimento do pistilo, sugere-se que a expressão desse gene seja regulada por elementos diretamente envolvidos no controle do término do meristema floral e nas vias de desenvolvimento de órgãos florais. / Studies on plant reproduction and development, specifically those related to the pistil, are of great agronomic, economic and scientific interest. In our laboratory, we recently identified and characterized SCI1 (Stigma/style Cell-cycle Inhibitor 1), an inhibitor of the cell cycle which acts tissuespecifically in the pistil of Nicotiana tabacum L. and Arabidopsis thaliana (L.) Heynh. (DEPAOLI et al., 2011; DEPAOLI; DORNELAS; GOLDMAN, 2014). The NtCDKG;2 (N. tabacum Cyclin-dependent Kinase G; 2) protein was identified as an interaction partner of NtSCI1 (N. tabacum SCI1) in a pulldown assay (STRINI, 2014). The literature suggests that cell cycle inhibitors control the cycle through the inhibition of CDKs, indicating that NtSCI1 might control cell cycle by inhibiting NtCDKG;2. This study shows detailed analysis of GFP-NtCDKG;2 localization in leaf cells of N. benthamiana. The analysis shows that NtCDKG;2 is present in the nucleoplasm and also co-localizes with nuclear speckles. In BY2 cell culture stably expressing GFP-NtCDKG;2, it was observed that NtCDKG;2 is at the achromatic spindle during metaphase and anaphase. Additionally, BiFC (Bimolecular Fluorescence Complementation) assays performed in this study have shown that the interaction of NtCDKG;2 and NtSCI1 occurs in the nucleolar periphery during interphase. Putative isoforms of NtCDKG;2 were also identified. The possible occurrence of these isoforms suggests that, in a similar way to its human homologue, NtCDKG;2 putative isoforms could act in different processes. To identify in which processes this protein could act, a search for NtCDKG;2 interaction partners was performed through the screening of a N. tabacum stigma and style cDNA library in the yeast two-hybrid (Y2H) system. Several partners identified through this assay have roles in RNA transcription and processing. Among the identified partners with interaction confirmed during this work, stands out the NtCDKF;1 protein, a CDK that phosphorylates the RNA polymerase II CTD, and thus, supports transcription and co-transcriptional splicing (HAJHEIDARI et al., 2012). This study also shows the interaction of NtCDKG;2 with NtCBP1, a protein which has an important role in the transcriptional regulation of genes encoding proteins mediating pollen tube growth (LI et al., 2015). Furthermore, the Y2H screening allowed the identification of the interaction of NtCDKG;2 with NtRanBP1, a key protein in the formation of the achromatic spindle which, in humans, interacts with the CDK11p46 isoform (MIKOLAJCZYK xxii et al., 2003; YOKOYAMA et al., 2008; ZHANG; DAWE, 2011), a homologue of NtCDKG;2. In silico analysis of the amino acid sequence of NtCDKG;2 revealed motifs of predicted interaction with F-box proteins, cyclins, CDKs, phosphatases, 14-3-3s, BRCA1, and also pointed the region where the CDK-cyclin complex might interact with its respective inhibitor. The interaction of NtCDKG;2 with 14-3-3D, a known partner of NtSCI1, was tested and confirmed by Y2H. Another gap that needed to be filled is related to the regulation of NtSCI1 expression. To address this issue, in silico analysis to identify cis-regulatory elements was performed in NtSCI1 genomic region. These analyses revealed the presence of important cis-regulatory elements related to meristem identity (such as WUSCHEL and AINTEGUMENTA), carpel identity (AGAMOUS, BELL), and cell cycle progression (E2F and CDC5). Taken together results from this study and parallel studies performed in our laboratory, a few remarks can be made: 1) Taken the localization of NtCDKG;2 in splicing speckles, and its interaction with different proteins involved in transcription and splicing, it is suggested that NtCDKG;2 also has roles on these processes; 2) Considering the subcellular localization of NtCDKG;2 during the different cell cycle phases, the in silico analysis of this protein that predicts its interaction with BRCA1, and the confirmed interaction with NtRanBP1 protein, it is possible to suggest that NtCDKG;2 has a direct or indirect role in the organization of the achromatic spindle in plants; 3) It is proposed that NtSCI1 regulates cell proliferation in the pistil through its interaction with NtCDKG;2, which occurs in the nucleolus. Thus, NtSCI1 could hold NtCDKG;2 in the nucleolus, inhibiting its actions, such as in the organization of the achromatic spindle, resulting in cell division arrest. 4) Due to the cis-regulatory elements found in the genomic sequence of NtSCI1, and the effect of this protein since the initial stages of pistil development, it is suggested that its expression is regulated by elements directly involved in the control of the floral meristem termination and pathways of floral organ development.

BiFC

CDK

ciclo celular

fuso acromático

localização subcelular

SCI1

Y2H

achromatic spindle

BiFC

CDK

cell cycle

SCI1

subcellular localization

Y2H

Physico-chimie de méso-tétraphénylporphyrines glycoconjuguées pour la photothérapie dynamique : vers une meilleure compréhension de la distribution plasmatique et de la localisation subcellulaire ? / Physicochemistry of glycoconjugated meso-tetraphenylporphyrins in photodynamic therapy : towards a better understanding of plasma distribution and of subcellular localization ?

Chauvin, Benoît

19 October 2011

La photothérapie dynamique (PDT) consiste en la destruction d’une tumeur par l’association de l’administration d’un photosensibilisateur et de l’exposition à la lumière visible. Ce travail comporte : i) une étude de l’ionisation et de la lipophilie d’une série de photosensibilisateurs, des méso-tétraphénylporphyrines (TPP) glycoconjuguées, ii) une évaluation de l’impact de ces deux propriétés sur la distribution plasmatique et la localisation subcellulaire du photosensibilisateur.La protonation des azotes tétrapyrroliques a été étudiée par spectroscopie électronique, combinéeà une analyse chimiométrique, tandis que la lipophilie a été évaluée par chromatographie liquide haute performance. L’impact de différents effets de substitution (position, nombre ou nature du substituant) sur ces deux propriétés physico-chimiques a été mis en évidence.Dans le plasma, les TPP glycoconjuguées se lient principalement aux lipoprotéines de haute densité. La lipophilie de ces dérivés permet d'expliquer leur affinité pour les lipoprotéines, mais pas pour l'albumine. L’étude de localisation subcellulaire, combinant approche expérimentale et modélisation, a conduit à proposer une hypothèse expliquant la localisation de la TPP(pODEGOαManOH)3 au niveau du réticulum endoplasmique, hypothèse accordant un rôle central à la lipophilie de la TPP . A l'issue de ce travail, avant d'appliquer nos hypothèses à la synthèse de nouvelles molécules, il apparaît nécessaire de mieux explorer l'impact de la distribution plasmatique et de la localisation subcellulaire sur l'efficacité PDT. / Photodynamic Therapy (PDT) is based on the destruction of a tumor tissue through a combinationof administration of a photosensitizer and exposure to visible light. This work includes : i) a study of ionization and hydrophobicity of a series of candidate sensitizers, glycoconjugated mesotetraphenylporphyrins (TPP), ii) an evaluation of the impact of those two physico-chemicalproperties on sensitizer's plasma distribution and subcellular localization. Protonation of tetrapyrrolic nitrogens has been studied by electronic spectroscopy combined with chemometric analysis whereas hydrophobicity has been evaluated by high-performance liquid chromatography. The effect of substitution modalities (position, number and nature of pendantgroups) on both physico-chemical properties has been evidenced.In human plasma, glycoconjugated TPPs mainly bind to high density lipoproteins. Hydrophobicity accounts for differences in affinities towards lipoproteins, but not towards albumin. Subcellular localization studies, combining computational and experimental approaches, led to formulate some assumptions explaining localization of TPP(pODEGOαManOH)3 in endoplasmic reticulum,assumptions centered on a major role of sensitizer's hydrophobicity. At the end of this work, before trying to use our conclusions for the design of new sensitizers, it remains necessary to better explore the effect of plasma distribution and subcellular localization on sensitizer's photo-efficiency.

Photothérapie Dynamique

Méso-tétraphénylporphyrine

Distribution plasmatique

Localisation subcellulaire

Photodynamic therapy

Meso-tetraphenylporphyrin

Ionization

Hydrophobicity

Plasma distribution

Subcellular localization

Chemometrics

Modelling