Propojení signalizace PKN3 a p130Cas/BCAR1 / Crosstalk of PKN3 and p130Cas/BCAR1 signaling

Dibus, Michal

January 2016

Both p130Cas and PKN3 are important regulators of cellular signaling deregulation of which leads to malignant behavior of cancer cells. Recently we have found that SH3 domain of p130Cas mediates interaction with proline rich region of PKN3 suggesting their possible cooperation in regulation of these processes. In this work we have focused on the phosphorylation of p130Cas by PKN3 and identified serine 498 (S498) within the serine rich domain of p130Cas to be phosphorylated by PKN3 in vitro. Given that S498 is localized within the 14-3-3 binding motif and its phosphorylation is required for interaction of p130Cas with 14-3-3 proteins, we propose potential existence of novel PKN3/p130Cas/14-3-3 signaling axis. In the second part of the work we have studied this pathway in response to antiestrogen treatment in estrogen receptor positive breast cancer cell line MCF7. Although we have shown inactivation of PKN3 occurs as an early response to tamoxifen treatment, we do not rule out its possible role in further promotion of resistance to antiestrogens. Furthermore, understanding the signaling triggered by interaction of PKN3 with p130Cas and its possible downstream effects on promoting malignant growth of cancer cells would help in finding novel therapeutic targets.

Covalent modification and intrinsic disorder in the stability of the proneural protein Neurogenin 2

McDowell, Gary Steven

January 2011

Neurogenin 2 (Ngn2) is a basic Helix-Loop-Helix (bHLH) transcription factor regulating differentiation and cell cycle exit in the developing brain. By transcriptional upregulation of a cascade of other bHLH factors, neural progenitor cells exit the cell cycle and differentiate towards a neuronal fate. Xenopus laevis Ngn2 (xNgn2) is a short-lived protein, targeted for degradation by the 26S proteasome. I have investigated the stability of Ngn2 mediated by post-translational modifications and structural disorder. Firstly I will describe work focused on ubiquitylation of xNgn2, targeting it for proteasomal degradation. xNgn2 is ubiquitylated on lysines, the recognized site of modification. I will discuss the role of lysines in ubiquitylation and stability of xNgn2. In addition to canonical ubiquitylation on lysines, I describe ubiquitylation of xNgn2 on non-canonical sites, namely its amino-terminal amino group, and cysteine, serine and threonine residues. I show that the ubiquitylation of cysteines in particular exhibits cell cycle dependence and is also observed in mammalian cell lines, resulting in cell cycle-dependent regulation of stability. I will then discuss whether phosphorylation, a regulator of xNgn2 activity, also affects xNgn2 stability. I will provide evidence of cell cycle-dependent phosphorylation of cyclin dependent kinase (cdk) consensus sites affecting the stability of xNgn2. Finally I describe studies on the folding properties of Ngn2 to assess their role in protein stability. xNgn2 associates with DNA and its heterodimeric binding partner xE12 and may interact directly with the cyclin-dependent kinase inhibitor Xic1. I will discuss the role of these interaction partners in xNgn2 stability. xNeuroD, a downstream target of xNgn2, is a related bHLH transcription factor which is stable. Here I describe domain swapping experiments between these two proteins highlighting regions conferring instability on the chimeric protein. Finally I will provide nuclear magnetic resonance (NMR) data looking at the effect of phosphorylation on protein structure in mouse Ngn2 (mNgn2).

616.99

ROS & energy production pathways in the determination of resistance/sensitivity to glucocorticoids-induced apoptosis in acute lymphoblastic leukaemia

Berrou, Ilhem

January 2012

Glucocorticoids have long been used in the treatment of acute lymphoblastic leukaemia due to their ability to cause cell cycle arrest and apoptosis of lymphoid cells. However, some patients do not respond to glucocorticoid treatment and the majority, who initially respond, may relapse upon prolonged hormone treatment. The inefficiency of the treatment is mainly attributed to the gradual loss of the cellular sensitivity to glucocorticoid-induced apoptosis. Therefore, the need to understand the molecular mechanisms of resistance/ sensitivity of acute lymphoblastic leukaemia cells to glucocorticoid-induced apoptosis is of vital importance, as this will help to develop better prognostic outcomes and improve glucocorticoids therapy. Several mechanisms have been proposed to explain the evasion of glucocorticoid mediated apoptosis in resistant cells. These include post-translational modifications of GR especially phosphorylation which modulates the GR transcriptional activity, and GR mediated signalling thereby affecting gene expression and hence the balance between pro- and anti-apoptotic Bcl-2 family members. In addition the concentration of components of the energy metabolism pathways (i.e. oxidative phosphorylation and glycolysis) and ROS generation are altered in the acute lymphoblastic leukaemia cells. The hypothesis that differentially phosphorylated GR in the resistant versus sensitive ALL cells modulate GR transcriptional activity and target selectively resulting in diverse pro- or anti-apoptotic Bcl-2 family members' gene expression in the two cell lines was tested. Furthermore, in a similar manner, the possibility that differential GR phosphorylation diversely affected gene expression of GR transcriptional target genes that are components of cellular energy production pathways in resistant versus sensitive cells, altering energy and ROS production levels in distinct ways in the two cell lines was explored. GR was found to be predominantly phosphorylated at S211 in the glucocorticoid-sensitive CEM C7-14, and at S226 in the glucocorticoid-resistant CEM C1-15 cells. Differential GR phosphorylation is presumably an indication of dominant p38 MAPK activity in CEM C7-14 and JNK kinase activity in CEM C1-15, which could lead to adverse gene expression of some pro- and anti-apoptotic Bcl-2 family members and particularly Mcl-1, in the two cell lines. Furthermore, differential GR phosphorylation at S211 and S226 in CEM C7-14 and CEM C1-15 affected the gene expression of the Cytochrome C Oxidase assembly factors Surf-1 and SCO2 as well as the nuclear encoded Cytochrome C Oxidase subunit COX-Va and the mitochondrial encoded COX-I, COX-II and COX-III. This effect was more pronounced in the glucocorticoid-sensitive CEM C7-14 cells, probably due to the fact that GR was predominantly phosphorylated at S211 and hence transcriptionally active in these cells. Moreover, in comparison to the resistant CEM C1-15 cells, the CEM C7-14 cells exhibited higher levels of ROS, increased number of active mitochondria and up-regulated glycolysis upon inhibition of oxidative phosphorylation. Glucocorticoids further reduced ROS levels in the CEM C1-15 cells, and increased the NADH/ NAD+ ratio. In conclusion results presented in this thesis provide evidence that differential GR phosphorylation in resistant versus sensitive to glucocorticoid induced apoptosis cells plays essential role in the regulation of programmed cell death and energy metabolism pathways, offering a potential explanation for the molecular events that determine resistance/sensitivity to glucocorticoid-induced apoptosis in ALL cells.

616.99419

Phosphorylation of Filamin A by Cdk1/cyclin B1 Regulates Filamin A Subcellular Localization and is Important for Daughter Cell Separation

Szeto, Sandy

January 2014

In cell culture, entry into mitosis of many adherent mammalian cells is accompanied by substantial changes in cellular architecture. Flat, spread-out interphase cells detach from the extracellular matrix and become more spherical. These changes in cell shape are mediated by rearrangements in the actin cytoskeleton, a dynamic network of actin filaments that are organized by actin-binding proteins. Filamin A (FLNa) is a 280 kD actin-binding protein that crosslinks actin filaments into parallel bundles or three-dimensional orthogonal networks. We previously identified FLNa as an in vitro substrate of cyclin-dependent kinase 1 (Cdk1), a kinase that regulates entry into mitosis, and hypothesized that Cdk1 phosphorylation of FLNa regulates mitotic actin remodelling. Using mass spectrometry and a p-FLNa antibody, we show that FLNa is phosphorylated in vivo in HeLa cells on multiple Cdk1 sites, including serines 1084, 1459 and 1533. All three sites match the phosphorylation consensus sequence of Cdk1. We further show that p-FLNa is almost fully dephosphorylated by anaphase, consistent with it being a cell cycle-regulated substrate. Using a phospho-specific antibody, we find that p-FLNa has decreased cortical actin localization compared to total FLNa in mitotic cells. To investigate the functional role of mitotic FLNa phosphorylation, we mutated serines 1084, 1459 and 1533 to nonphosphorylatable alanine and expressed this FLNa mutant (FLNa-S1084A, S1459A, S1533A, referred to as “FLNa-AAA GFP”) in FLNa-deficient human M2 melanoma cells. FLNa-AAA GFP-expressing cells have enhanced FLNa-AAA GFP localization at sites of contact between daughter cells and this correlates with defects in cell division and impaired cell migration. Therefore, mitotic delocalization of cortical FLNa is critical for successful cell division and interphase cell behaviour.

Actin cytoskeleton remodeling

Mitotic cell rounding

Filamin A

Cyclin-dependent kinase 1

Mitosis

Phosphorylation

Investigation of the role of rasgap in promoting neuronal survival in Drosophila

Rowshanravan, Behzad

January 2014

RasGAP is a GTPase activating protein (GAP) that deactivates Ras by promoting Ras-GTP hydrolysis to Ras-GDP. In Drosophila melanogaster, RasGAP is required for the long-term survival of neurons in the adult brain because mutants in the RasGAP gene (vap) show an age-related neurodegenerative phenotype, with dying neurons showing morphological features of autophagy. RasGAP was shown to have a GAP-independent role within fly neurons that is dependent on its SH2 domains. The aim of this study was to identify proteins that interact with the SH2 domains of RasGAP and to understand the roles of these proteins in neuronal survival. By using tagged RasGAP affinity purification and mass spectrometry of RasGAP protein complexes from S2 cells, Sprint, a Ras effector and putative activator of the endocytic GTPase Rab5, was identified as a novel SH2-dependent RasGAP interacting protein. The interaction between Sprint and RasGAP is phosphotyrosine-dependent, since it requires tyrosine phosphorylation of Sprint. In addition, Sprint and RasGAP interaction requires the SH2 domains of RasGAP but not Sprint or the conserved site of RasGAP tyrosine phosphorylation (pTyr363), indicating an association between these two molecules. RasGAP and Sprint co-localised with Rab5-positive early endosomes and this co-localisation depended on the SH2 domains of both RasGAP and Sprint. This study demonstrates a key role for this interaction in neurodegeneration: mutation of Sprint (or Rab5) suppressed the autophagic neuronal cell death caused by the loss of RasGAP. These results indicate that the long-term survival of adult neurons in Drosophila depends on a critical balance between Ras activation and endocytosis, and that this balance is maintained by the interplay between RasGAP and Sprint.

572

Metabolismo energético mitocondrial na proliferação de células de glioblastoma U-87MG e T98G em cultura / Mitochondrial energy metabolism in proliferation of cultured U-87MG and T98G glioblastoma cells

Ruas, Juliana Silveira, 1989-

26 August 2018

Orientador: Roger Frigério Castilho / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-26T14:26:13Z (GMT). No. of bitstreams: 1 Ruas_JulianaSilveira_M.pdf: 1871713 bytes, checksum: a20e3cd08d0b770aed3b059541e382e3 (MD5) Previous issue date: 2015 / Resumo: A maioria das células tumorais depende da glicólise para a ressíntese de ATP durante um processo de rápida proliferação, mesmo que haja disponibilidade de oxigênio para a transdução de energia mitocondrial (Efeito Warburg). O objetivo do presente estudo foi avaliar o papel do metabolismo oxidativo mitocondrial na proliferação de células de glioblastoma humano U-87MG e T98G. Quando as células foram cultivadas na presença de oligomicina (um inibidor da ATP sintase) ou antimicina A (um inibidor do complexo III da cadeia transportadora de elétrons), observou-se apenas uma inibição parcial da proliferação das células. Notadamente, a incubação dessas células com ambos os inibidores causou uma inibição quase completa na proliferação celular. Resultados semelhantes foram observados em cultura primária de astrócitos, havendo uma queda na proliferação celular somente quando ambos os inibidores mitocondriais estavam presentes. Medidas de consumo de oxigênio indicaram que células de glioblastoma utilizam parcialmente a fosforilação oxidativa para a ressíntese de ATP e apresentam uma respiração bem acoplada. Quando se inibiu, nestas células, a fosforilação oxidativa do ADP com oligomicina ou antimicina A, houve um pequeno aumento no consumo de glicose e na produção de lactato. No entanto, o tratamento com ambos os inibidores mitocondriais promoveu um menor consumo de glicose e produção de lactato, em comparação com os efeitos que a antimicina A promoveu. Isso indica que a cadeia transportadora de elétrons quando inibida pela presença de antimicina A, promove um funcionamento inverso da ATP sintase, promovendo a hidrólise de ATP para que haja um bombeamento de prótons para o espaço intermembranar mitocodrial. De acordo com os resultados acima descritos, uma queda quase completa do potencial de membrana mitocondrial foi observada apenas quando as células de glioblastoma foram incubadas na presença de ambos os inibidores mitocondriais, oligomicina e antimicina A. Quando a análise do ciclo celular foi realizada, observou-se uma diminuição da percentagem das células em G0-G1 e um aumento nas fases S e G2-M quando tratadas com oligomicina. Quando as células foram tratadas com antimicina A e oligomicina mais antimicina A foi constatado uma diminuição significativa nas fases G0-G1 e G2-M, e um aumento na fase S. Em conclusão, estes resultados indicam que a rápida proliferação de células de glioblastoma depende da existência do potencial de membrana mitocondrial, mas não da fosforilação oxidativa ou do transporte de elétrons na cadeia respiratória / Abstract: Most tumor cells rely on glycolysis for ATP resynthesis during rapid proliferation, despite the availability saturating levels of oxygen for mitochondrial energy transduction (Warburg effect). The aim of the present study was to evaluate the role of mitochondrial oxidative metabolism on proliferation of human glioblastoma cells U-87MG and T98G. When cells were cultured in the presence of oligomycin (ATP synthase inhibitor) or antimycin A (inhibitor of complex III of the electron transport chain), we observed only a partial inhibition of cell proliferation. Remarkably, incubation of cells with both inhibitors caused an almost complete inhibition of cell proliferation. Similar results were observed in primary culture of astrocytes, with a decrease in cell proliferation only when both mitochondrial inhibitors were present. Oxygen consumption measurements indicated that glioma cells partially rely on oxidative phosphorylation for ATP turnover and exhibit a well-coupled respiration. In fact, shutting down mitochondrial ADP phosphorylation in these glioma cells with either oligomycin or antimycin inhibitors slightly increased glucose consumption and lactate release. However, the treatment with both mitochondrial inhibitors promoted lower glucose consumption and lactate release as compared with the effects of antimycin alone, which indicates that ATP synthase is operating reversely and thus hydrolyzing ATP and pumping H+ out when the respiratory chain is inhibited by antimycin. In agreement, an almost complete collapse of mitochondrial membrane potential was only observed when the glioma cells were incubated in the presence of both antimycin and oligomycin, but not of only antimycin. When cell cycle analyses were performed in oligomycin-treated cells, a decrease in the percentage of cells in G0-G1 phase and an increase in S and G2-M phases were observed. When cells were treated with antimycin A or oligomycin plus antimycin A, it was observed a significant decrease in G0-G1 and G2-M cell phases and an increase in S phase. Overall, our results suggest that the rapid proliferation of glioblastoma cells is dependent on the mitochondrial membrane potential, but not on oxidative phosphorylation or electron transport in the respiratory chain / Mestrado / Biologia Estrutural, Celular, Molecular e do Desenvolvimento / Mestra em Ciências

Glicólise

Glioblastoma

Mitocôndria

Fosforilação oxidativa

Oxidative phosphorylation

Glycolysis

Glioblastoma

Membrane potential, Mitochondrial

Mitochondria

Caracterização estrutural e funcional da proteína UDP-glucose pirofosforilase envolvida na biossíntese e acúmulo de sacarose em cana de açúcar = Structural and functional characterization of the protein UDP-glucose pyrophosphorylase involved in the biosynthesis and accumulation of sucrose in sugarcane / Structural and functional characterization of the protein UDP-glucose pyrophosphorylase involved in the biosynthesis and accumulation of sucrose in sugarcane

Soares, José Sérgio de Macedo, 1979-

18 December 2013

Orientadores: Marcelo Menossi Teixeira, Ricardo Aparicio / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-27T14:13:51Z (GMT). No. of bitstreams: 1 Soares_JoseSergiodeMacedo_D.pdf: 4995080 bytes, checksum: ad3458f447f7044749e0ee6cb95f4315 (MD5) Previous issue date: 2013 / Resumo: O agronegócio da cana de açúcar movimenta cerca de R$ 40 bilhões por ano no Brasil. A cadeia produtiva da cana de açúcar como atividade na economia é responsável por 1,5% do produto interno bruto (PIB) nacional e um dos principais componentes econômicos é a quantidade de sacarose acumulada nos colmos. No entanto, a síntese de sacarose e sua acumulação em plantas superiores é o resultado do produto de uma extensa rede de interações. Quando descarregada nas células do parênquima de armazenamento, a sacarose é metabolizada por diferentes enzimas, sendo a UDP-glucose pirofosforilase (UGPase) uma das enzimas responsáveis pela síntese de sacarose em cana de açúcar. O objetivo deste trabalho foi avaliar o padrão de expressão do gene ScUGPase-1 e os mecanismos regulatórios que controlam a atividade da proteína UGPase de cana de açúcar. Análises por RT-qPCR revelaram que a expressão do gene ScUGPase-1 diminui ao longo da maturação dos colmos e o gene é mais expresso nos entrenós em comparação com o tecido de folha. Porém, nenhuma diferença de expressão significativa foi observada entre dois cultivares contrastantes em teor de sacarose. In vivo, a localização subcelular da proteína ScUGPase-1 indicou uma associação à membrana nos tecidos de folha e colmo. Utilizando anticorpo primário fosfo-específico, observamos a fosforilação da proteína ScUGPase-1 apenas na fração solúvel e microssomal do tecido de folha. In vitro, a proteína ScUGPase-1 formou um complexo com a proteína recombinante caseína quinase 1 (CK1) e sua atividade foi afetada por agentes óxido-redutores. Para complementar os dados de óxido-redução, análises de espalhamento de luz a baixo ângulo (SAXS) forneceram o primeiro modelo estrutural do dímero da proteína ScUGPase-1 em solução, destacando que a interface de dimerização está localizada na região C-terminal. Os dados indicam que a fosforilação, interação protéica e oligomerização podem exercem um papel importante na regulação da proteína ScUGPase-1 durante a síntese de sacarose em cana de açúcar. / Abstract:The sugarcane agribusiness generates around R$ 40 billion per year in Brazil, while the entire supply chain of sugarcane is responsible for 1.5% of the gross domestic product (GDP). Sugarcane productivity is mainly determined by the accumulation of sucrose in the culms. However, the synthesis and accumulation of sucrose in plants is the result of an extensive network. When sucrose is unloaded in the storage parenchyma cells, it is metabolized by different enzymes, and UDP-glucose pyrophosphorylase (UGPase) is one of the enzymes responsible for the synthesis of sucrose in sugarcane. The objective of this work was to gain insights on the ScUGPase-1 expression pattern and the regulatory mechanisms that control protein activity. ScUGPase-1 transcript levels were negatively correlated with sucrose content in the internodes and only a slight difference in the expression pattern was observed between two cultivars that differ in their sucrose content. The intracellular localization of ScUGPase-1 indicated association with membranes in both leaves and internodes. Using a phospho-specific antibody, we observed that ScUGPase-1 was phosphorylated in vivo in the soluble and membrane fractions from leaves, but not from internodes. In vitro, the purified recombinant enzyme interacted with recombinant protein casein kinase 1 and its activity was affected by redox modification. To complement the redox data, Small-Angle X-ray Scattering provided the first structural model of the dimer of sugarcane UGPase in solution, highlighting that the dimer interface is located at the C-terminal. The data indicated that phosphorylation, protein interaction and oligomerization may play an important role in the regulation of ScUGPase-1 activity / Doutorado / Genetica de Microorganismos / Mestre em Genética e Biologia Molecular

Fosforilação

Oligomerização

Interação proteína-proteína

Regulação da expressão gênica

Phosphorylation

Oligomerization

Protein-protein interactions

Gene expression regulation

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

Regulação do acúmulo de sacarose em cana-de-açúcar e análise funcional de uma proteína quinase relacionada com o conteúdo de sacarose / Regulation of sugarcane sucrose acummulation and functional analysis of a kinase protein related to sucrose content

Paloma Mieko Sato

11 April 2012

A cana-de-açúcar é uma gramínea C4 da família das Poaceae. Sua principal característica é a capacidade de estocar altas concentrações de sacarose no colmo. Devido à sua alta atividade fotossintética, ela consegue converter uma boa parte da radiação solar em biomassa. Assim, ela pode ser considerada um dos melhores modelos para os estudos da relação fonte-dreno. O Brasil é um dos maiores produtores e exportadores de álcool do mundo, e por isso a cana-de-açúcar é considerada uma das principais culturas atuais. A ausência de informações sobre a sua sequência genômica levou à criação do programa SUCEST no final de 1990, onde foram disponibilizadas aproximadamente 240,000 sequências denominadas ESTs (Expression Sequence Tags), uma cobertura de quase 90% do genoma expresso da cana-de-açúcar. Desta forma, foi possível desenvolver uma plataforma de microarranjo Agilent de oligonucleotídeos com componentes do SUCEST. Por meio do programa de melhoramento da RIDESA e a análise por microarranjos, foi possível a identificação de vias metabólicas que podem estar relacionadas com a regulação do acúmulo de sacarose em cana-de-açúcar, principalmente aquelas que envolvem os fitormônios auxina e etileno. A obtenção de dados agrotecnológicos e de fisiologia permitiu a observação de um trade off metabólico, onde o acúmulo de sacarose parece ocorrer em detrimento do acúmulo de fibra. A obtenção de plantas silenciadas e superexpressando uma quinase da família da SnRK1 levou, através da análise de microrarranjos, a identificação de genes diferencialmente expressos envolvidos no estresse por seca como uma PP2C e deidrina. Nas plantas superexpressando uma SnRK1, há um aumento do conteúdo de sacarose na planta 88, que talvez indique que a superexpressão dessa quinase leve a um aumento do conteúdo de sacarose em cana. Com a obtenção de sequências genômicas acima do sítio de início da transcrição dessa mesma SnRK1, e de uma subunidade regulatória Akinβγ, foi possível identificar por análise computacional sequências conservadas envolvidas na regulação hormonal, resposta à seca e reações de luz, indicando que a transcrição desse gene pode resultar de diferentes respostas da planta. Esse trabalho permitiu novas diretrizes no estudo do acúmulo de sacarose no colmo, indicando que vias de transdução de sinais conservadas, mediadas por hormônios e fosforilação, podem ser as principais responsáveis por esse fenômeno em cana-de-açúcar. / The sugarcane is a C4 grass of the Poaceae family. Its main feature is the ability to store high sucrose concentrations in the culm. Due to the elevated photosynthetic activity, it can convert a great portion of solar radiation into biomass. Thus, it can be considered one of the best models for studies of source-sink relationship. Brazil is one of the largest alcohol producers and exporters in the world, and sugarcane is considered one of the main current cultivars. The absence of information about its genome sequence led to the creation of the SUCEST program in late 1990, from which approximately 240,000 sequences called ESTs (Expression Sequence Tags) were made available, with a coverage of almost 90% of the sugarcane expressed genome. Thus, it was possible to develop a microarray platform with Agilent oligonucleotide with SUCEST components. Through the RIDESA improvement program and microarray analysis, it was possible to identify metabolic pathways that may be related to the regulation of sugarcane sucrose accumulation, especially those involving the plant hormones auxin and ethylene. The agro-technological and physiology data allowed the observation of a metabolic trade-off, where the sucrose accumulation appears to occur at the expense of fiber accumulation. The production of plants that are silenced or overexpressing a kinase from SnRK1 family, led by microrarray analysis, allowed the identification of differentially expressed genes that are involved in drought stress, such as a PP2C and dehydrin. In plants overexpressing a SnRK1, there is an increased sucrose content in the plant 88, which may indicate that overexpression of this kinase leads to an increase in leaf sucrose content. After obtaining the genomic sequence above the transcription start site of the same SnRK1, and a regulatory subunit Akinβγ, it was possible to identify by computer analysis conserved sequences involved in regulating hormonal response to dry and light responses, indicating that the gene transcription may arise from different plant responses. This work allowed new guidelines in the study of sucrose accumulation in the culm, suggesting that conserved signal transduction pathways and hormone mediated phosphorylation may be the main reason for this phenomenon in sugarcane.

Acúmulo de sacarose

Cana-de-açúcar

Fitormônios

Fosforilação

Sacarose

Transcriptoma

Phosphorylation

Phytohormones

Sucrose

Sucrose accumulation

Sugarcane

Transcriptome

Histone modifications and their role in splicing

Wettermark, Anna

January 2020

Splicing is the process when introns gets removed and exons are spliced together. This is an important step to form a clean mRNA with no unnecessary sequences that could interrupt protein synthesis. There are different types of splicing and some of them need a complex called spliceosome. The spliceosome requires ATP, small nuclear RNAs and splicing factors. The spliceosome and the process splicing can be regulated by epigenetics, and one epigenetic mechanism is histone modification. There are four types of histone modifications; methylation, phosphorylation, ubiquitination and acetylation. They regulate splicing to different extents by altering the chromatin structure, affect the assembly of the spliceosome and regulate the attraction of splicing factors. This review will investigate if histone modifications affect splicing and to what extent. Suggestions for further research regarding the relationship between splicing and histone modifications will also be provided. The review is based on 30 articles and two books and the search was conducted between 30th of March 2020 and 13th of April 2020. Ubiquitination and phosphorylation have a minor effect on splicing meanwhile methylation and acetylation affect splicing in great extent.

Splicing

Spliceosome

Histone modifications

epigenetics

histone methylation

histone acetylation

histone phosphorylation

histone ubiquitination

Genetics

Genetik