Caracterização funcional dos elementos de transcrição do gene da glicogênio sintase (gsn) de Neurospora crassa

Freitas, Fernanda Zanolli [UNESP]

02 February 2007

Made available in DSpace on 2014-06-11T19:31:00Z (GMT). No. of bitstreams: 0 Previous issue date: 2007-02-02Bitstream added on 2014-06-13T21:01:54Z : No. of bitstreams: 1 freitas_fz_dr_araiq_prot.pdf: 4506629 bytes, checksum: 72017b1ea005ba3d7b6b2bb0d348f3cc (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / As células eucarióticas são capazes de responder e de se adaptar a diferentes condições ambientais estressantes tais como o choque térmico, modulando sua atividade metabólica. Na levedura Saccharomyces cerevisiae o choque térmico é conhecido por induzir múltiplos genes relacionados a esta forma de estresse, através dos elementos transativadores Hsf1p (Heat Shock Protein) e Msn2/4p, os quais se ligam, respectivamente, às seqüências consensos HSE e STRE, ativando a transcrição. A seqüência nucleotídica do gene da glicogênio sintase (gsn) de Neurospora crassa foi previamente isolada em nosso laboratório e uma análise da expressão gênica mostrou que a transcrição do gene foi diminuída na situação de choque térmico (30 para 45ºC). Uma análise da região 5' flanqueadora revelou a presença dos elementos de DNA CRE, HSE e STRE tanto na região promotora do gene quanto na 5'-UTR. Neste trabalho, nós investigamos o envolvimento destes elementos de DNA na regulação da transcrição na condição de choque térmico, através de ensaios de mobilidade em gel (EMSA) usando como sondas, fragmentos de DNA contendo os elementos transcricionais citados anteriormente. Para isto, foram utilizados como fonte de proteínas extratos nucleares brutos ou fracionados em coluna de Heparina-Sepharose, preparados a partir de micélios coletados antes e após choque térmico (amostras HS30). Os resultados obtidos mostraram a presença de proteínas capazes de reconhecer e ligar aos elementos de DNA testados sob a condição estressante analisada. A especificidade das bandas de mobilidade reduzida foi confirmada por diferentes ensaios de competição, tais como 1) adição prévia de sondas de DNA não marcadas antes da reação de ligação, 2) adição de oligonucleotídeo de DNA dupla fita contendo o elemento STRE do promotor gsn como competidor específico, 3) utilização... / Eukaryotic cells respond and adapt to environmental stressing conditions such as heat shock, by modulating metabolic responses to counteract them. In the yeast Saccharomyces cerevisiae heat shock activates multiple stressing related genes by the trans acting elements Hsfp (Heat shock factors) and Msn2/4p, which bind to the cis regulatory elements HSE (Heat Shock Element) and STRE (Stress Responsive Element), respectively, and activates the gene transcription. We have previously isolated the gene encoding the Neurospora crassa glycogen synthase (gsn) and demonstrated that the gene transcription was decreased under heat shock (30 to 45ºC). An analysis of the gsn 5' flanking region showed the presence of the DNA elements CRE, HSE, and STRE, in the promoter region and in the 5'-untranslated region. In this work we investigated the involvement of these DNA elements in gene transcription regulation under heat shock condition by performing electrophoretic mobility shift assays (EMSA) using, as probes, DNA fragments containing the regulatory elements, and crude or Heparin-Sepharose fractionated nuclear extracts prepared from mycelia collected before and after 30 min of heat shock (HS30 sample). Ours results showed the presence of nuclear proteins capable to recognize and bind to the DNA regulatory elements under heat stress. The specificity of the DNA shifts were confirmed by using 1) unlabelled DNA probes as specific competitor, 2) the gsn promoter STRE double-stranded oligonucleotide as specific competitor, 3) a mutated gsn promoter STRE probe, and 4) the HSE unlabelled probe in a cross-reaction competition assay with the gsn promoter STRE probe. The involvement of the regulatory CRE elements in the modulation of the gsn gene transcription was investigated by using EMSA in the wild type strain, and also in two N. crassa mutant strains defective in the cAMP-signaling pathway: one having hyperactive...(Complete abstract click electronic access below)

Fungos - Biotecnologia

Biologia molecular

Neurospora crassa

Metabolismo do glicogênio em Neurospora crassa: um estudo molecular e bioquímico e análise de interação proteína-proteína

Paula, Renato Magalhães de [UNESP]

03 September 2004

Made available in DSpace on 2014-06-11T19:31:00Z (GMT). No. of bitstreams: 0 Previous issue date: 2004-09-03Bitstream added on 2014-06-13T19:19:50Z : No. of bitstreams: 1 paula_rm_dr_araiq.pdf: 2077296 bytes, checksum: aa9a17baf3828015b873a455a57c08c8 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Glicogênio representa um dos principais carboidratos de reserva em muitos organismos e seu metabolismo está sob o controle de um complexo mecanismo envolvendo o balanço de nutrientes e sinais ambientais. A proteína glicogenina constitui a molécula iniciadora do processo de síntese de glicogênio, sendo as etapas seguintes efetuadas pelas enzimas glicogênio sintase e enzima ramificadora. Glicogênio sintase é a enzima limitante no processo e é regulada alosterismo e fosforilação reversível. Neste trabalho foi realizada uma caracterização do metabolismo de glicogênio no fungo N. crassa enfocando as enzimas glicogenina, glicogênio sintase e glicogênio sintase quinase-3. A proteína glicogenina (GNN) foi caracterizada do ponto de vista molecular, bioquímico e funcional. O cDNA codificando para esta proteína foi isolado e a seqüência polipeptídica deduzida mostrou uma proteína de 664 aminoácidos, uma das maiores proteínas glicogenina já isoladas. A inativação do gene gnn resultou em uma linhagem mutante incapaz de acumular glicogênio. A produção da proteína GNN em E. coli resultou em um polipeptídeo altamente susceptível à proteólise e formas truncadas da proteína mostraram ser mais estáveis e igualmente ativas nos processos de auto- e trans-glicosilação, além de servirem de substrato para ação da glicogênio sintase. Tais formas também foram capazes de complementar funcionalmente mutantes de S. cerevisiae. Além disso, a expressão do gene gnn foi mostrado ser regulado durante crescimento vegetativo e deprivação de carbono. Os resíduos Tyr196 e Tyr198 foram identificados como os sítios de glicosilação, os quais contribuem diferencialmente para este processo. Análise das interações entre GNN e a proteína glicogênio sintase de N. crassa (GSN) demonstrou que a região C-terminal da GNN é a mais importante para a interação. Entretanto, o... / Glycogen represents one of the main reserve carbohydrates in many organisms and its metabolism is under control of a complex mechanism involving the balance of nutrients and environmental signals. The protein glycogenin is the initiator molecule in glycogen biogenesis and the subsequent steps are carried out by the enzymes glycogen synthase and branching enzyme. Glycogen synthase is the rate-limiting enzyme in the process and is regulated both by alosterism and reversible phosphorylation. In this work we performed a characterization of the glycogen metabolism in the filamentous fungus Neurospora crassa, focusing on the enzymes glycogenin, glycogen synthase and glycogen synthase kinase-3. The protein glycogenin (GNN) was characterized under the molecular, biochemical and functional aspects. The cDNA encoding for this protein was isolated and the deduced polypeptide sequence showed a protein with 664 residues, one of the largest glycogenins isolated so far. The inactivation of the gnn gene rendered a mutant strain that was no longer able to accumulate glycogen. The production of GNN protein in E. coli cells resulted in a polypeptide highly susceptible towards proteolysis and truncated forms were more stable and equally active, judged by their abilities to self- and trans-glucosylate, and to serve as substrate for glycogen synthase elongation. These proteins were also able to recover the glycogen deficiency phenotype in a S. cerevisae mutant strain. Moreover, the gnn gene expression was shown to be ...(Complete abstract, click electronic access below)

Glicogenio

Neurospora crassa

Proteínas - Biotecnologia

Glycogen

Functional analysis of fluffy, a transcriptional regulator for conidial development in Neurospora crassa

Rerngsamran, Panan

29 August 2005

The fluffy gene of Neurospora crassa is required for asexual sporulation. It encodes an 88 kDa polypeptide containing a typical fungal Zn2Cys6 DNA binding motif. To identify the target genes on which FL may act, I sought to identify target sequences to which the FL protein binds. Several strategies were attempted to obtain purified FL protein. Purification was achieved by expressing the DNA binding domain of FL in Escherichia coli as a fusion with glutathione S-transferase followed by affinity purification using glutathione sepharose chromatography. DNA binding sites were selected by in vitro binding assays. Comparison of the sequences of selected clones suggested that FL binds to the motif 5??-CGG(N)9CCG-3??. A potential binding site was found in the promoter region of the eas (ccg-2) gene, which encodes a fungal hydrophobin. In vitro competitive binding assays revealed a preferred binding site for FL in the eas promoter, 5??-CGGAAGTTTCCTCCG-3??, which is located 1498 bp upstream of the eas translation initiation codon. In vivo experiments using a foreign DNA sequence tag confirmed that this sequence is a target site for FL regulation. Using Saccharomyces cerevisiae as an experimental system, I demonstrated that the C-terminal portion of FL functions in transcriptional activation. Microarray analysis was performed to study the role of fl in gene regulation on a large scale. mRNA levels in a fl mutant were compared to those in a strain overexpressing the fl gene. Experiments with cDNA microarray containing 13% of the total number of predicted N. crassa genes revealed 122 genes differentially expressed in response to overexpression of fl. Among these, eas displayed the greatest level of response. The cDNA microarray approach also revealed a number of genes that may be indirectly regulated by fl but may be involved in development. This information provides a foundation for further analysis of the role of fl in conidial development.

fungi

transcription factor

Neurospora

conidiation

sporulation

Uncovering the circadian output pathways of Neurospora crassa

Vitalini, Michael William

15 May 2009

The ubiquity of circadian systems has allowed their characterization in a broad range of model systems, which has greatly improved knowledge of how these systems are organized and the vast range of cellular and organismal processes under circadian control. Most of the advances, however, have come in describing the central oscillators of these systems, and, in some cases, the input pathways used to coordinate these oscillators to external time. Very little progress has been made in understanding the output pathways that allow circadian systems to regulate the breadth of processes shown to be clock-controlled. A genetic selection was designed to obtain mutations in genes involved in circadianregulated expression of the Neurospora crassa ccg-1 and ccg-2 genes. Some, but not all, of the strains obtained display altered regulation of more than one ccg as well as an ‘Easlike’ appearance on solid media, and altered circadian period on race tubes. The data suggest a model in which output from the clock to these two genes is through a single, bifurcated pathway. The cloning of the gene mutated (rrg-1) in one of the strains from the above selection led to the first molecular description of a circadian output pathway in Neurospora, the HOG MAP kinase pathway. The HOG pathway has been previously described with regard to its role in the osmotic-stress response. The discovery of the involvement of rrg-1 in circadian regulation of ccg-1 and ccg-2 led to the discovery of regulation of the HOG pathway by the circadian clock. The data indicate that osmotic stress information and time-of-day information are transduced through the HOG pathway and implicate a role for the clock in preparing the organism for daily occurrences of hyperosmotic stress associated with sun exposure. The genetic selection, and the description of the HOG pathway with regard to circadian output, provide a basis for further characterization of circadian output in Neurospora. The ubiquity of MAP kinase pathways, such as the HOG pathway, and the observed similarities in the mechanisms of circadian clock function across multiple phyla, indicate that these findings may well be applicable to other model systems.

Neurospora

Circadian Rhythms

Genetic Selection

Output Pathways

Sugar sensing and regulation of conidiation in Neurospora crassa

Xie, Xin

15 November 2004

The orange bread mold Neurospora crassa is a useful model for the study of filamentous fungi. One of the asexual reproduction cycles in N. crassa, macroconidiation, can be induced by several environmental cues, including glucose starvation. The rco-3 gene is a regulator of sugar transport and macroconidiation in N. crassa and was proposed to encode a sugar sensor (Madi et al., 1997). To identify genes that are functionally related to RCO-3, three distinct suppressors of the sorbose resistance phenotype of rco-3 were isolated and characterized. The dgr-1 mutant phenotypically resembles rco-3 and may be part of the rco-3 signaling pathway. Epistatic relationship among rco-3, dgr-1 and the suppressors were carried out by analyzing rco-3; dgr-1 and sup; dgr-1 double mutants. These analyses indicate that rco-3 is epistatic to dgr-1. A cDNA microarray containing 1363 N. crassa genes was generated to examine the transcriptional response of wild type cells grown in the presence of glucose or starved for glucose for two hours. Comparing N. crassa profiling data with the published diauxic shift data from S. cerevisiae (DeRisi et al., 1997) revealed that S. cerevisiae and N. crassa share a similar, but not identical, transcriptional response pattern for genes belonging to central carbon metabolism. The microarray results indicate that N. crassa utilizes glucose through fermentation and respiration simultaneously in aerobic culture, a finding that is consistent with previous measurements of ethanol production and enzyme activities in N. crassa. The same microarray was used to examine the transcriptional response to glucose status in rco-3 and dgr-1 mutants. The two mutants display similar expression patterns for most of the genes on the microarray supporting a close functional relationship between them. In addition, I identified a high affinity glucose transport gene in N. crassa, whose transcription is under the control of glucose, rco-3 and dgr-1.

sugar sensing

conidiation

carbon repression

Neurospora crassa

Functional analysis of fluffy, a transcriptional regulator for conidial development in Neurospora crassa

Rerngsamran, Panan

29 August 2005

The fluffy gene of Neurospora crassa is required for asexual sporulation. It encodes an 88 kDa polypeptide containing a typical fungal Zn2Cys6 DNA binding motif. To identify the target genes on which FL may act, I sought to identify target sequences to which the FL protein binds. Several strategies were attempted to obtain purified FL protein. Purification was achieved by expressing the DNA binding domain of FL in Escherichia coli as a fusion with glutathione S-transferase followed by affinity purification using glutathione sepharose chromatography. DNA binding sites were selected by in vitro binding assays. Comparison of the sequences of selected clones suggested that FL binds to the motif 5??-CGG(N)9CCG-3??. A potential binding site was found in the promoter region of the eas (ccg-2) gene, which encodes a fungal hydrophobin. In vitro competitive binding assays revealed a preferred binding site for FL in the eas promoter, 5??-CGGAAGTTTCCTCCG-3??, which is located 1498 bp upstream of the eas translation initiation codon. In vivo experiments using a foreign DNA sequence tag confirmed that this sequence is a target site for FL regulation. Using Saccharomyces cerevisiae as an experimental system, I demonstrated that the C-terminal portion of FL functions in transcriptional activation. Microarray analysis was performed to study the role of fl in gene regulation on a large scale. mRNA levels in a fl mutant were compared to those in a strain overexpressing the fl gene. Experiments with cDNA microarray containing 13% of the total number of predicted N. crassa genes revealed 122 genes differentially expressed in response to overexpression of fl. Among these, eas displayed the greatest level of response. The cDNA microarray approach also revealed a number of genes that may be indirectly regulated by fl but may be involved in development. This information provides a foundation for further analysis of the role of fl in conidial development.

fungi

transcription factor

Neurospora

conidiation

sporulation

The role of the ERMES complex in the assembly of mitochondrial outer membrane proteins in the filamentous fungus Neurospora crassa

Wideman, Jeremy G

Unknown Date

No description available.

mitochondrial protein import

Neurospora

beta barrels

An in vivo approach to elucidating the function of mitochondrial porin by the characterisation of Neurospora crassa strains deficient in porin

Summers, William A T

10 September 2010

The mitochondria are the primary energy providers for most eukaryotic cells. The substrate and products of the mitochondria need to be translocated across the semi-permeable mitochondrial outer membrane (MOM). Mitochondrial porin is an aqueous channel in the MOM thought to provide the primary pathway for metabolite translocation. Porin is a nuclear encoded protein and therefore needs to be transported to the mitochondria, translocated across and assembled within the MOM. Of all the recognition signals required for successful transport, import and assembly, only the β-sorting signal used in assembly is known. In addition, this protein possesses the ability to gate, and in doing so can preferentially allow the passage of anions in the open state and cations in the closed state. However, the precise mechanism by which gating of porin occurs and a complete understanding of porin’s function in vivo remains elusive. The essentiality of porin was examined by constructing a strain of Neurospora crassa deficient for porin. This strain, denoted as WS004, exists as evidence that porin is non-essential for the survival of Neurospora crassa. However, the loss of porin results in a reduction in growth rate due to the dysfunction of the cytochrome mediated respiratory pathway, which was made evident by the reduction of cytochrome b and almost complete lack of cytochrome aa3. WS004 survives by inducing the expression of alternative oxidase, which funnels the electrons from the Q pool directly to oxygen, bypassing the cytochrome b and aa3 containing complexes III and IV respectively. Additional phenotypic differences observed included loss in ability to produce aerial hyphae, reduced amount of conidia produced and strains that were female sterile. It was determined, that additional genetic factors influenced the resulting phenotype due to the loss of porin. LC-MS/MS, in combination with iTRAQ labelling, was utilized to examine changes in the proteome profiles of porin containing and porin lacking mitochondria and showed several different proteins as significantly up- or down-regulated which lend to an explanation to some of the phenotypes observed. Taken together, these results demonstrate the central role of porin in regulating both mitochondrial and cellular processes.

Neurospora

Porin

Respiration

VDAC

Cytochromes

Fertility

An in vivo approach to elucidating the function of mitochondrial porin by the characterisation of Neurospora crassa strains deficient in porin

Summers, William A T

10 September 2010

The mitochondria are the primary energy providers for most eukaryotic cells. The substrate and products of the mitochondria need to be translocated across the semi-permeable mitochondrial outer membrane (MOM). Mitochondrial porin is an aqueous channel in the MOM thought to provide the primary pathway for metabolite translocation. Porin is a nuclear encoded protein and therefore needs to be transported to the mitochondria, translocated across and assembled within the MOM. Of all the recognition signals required for successful transport, import and assembly, only the β-sorting signal used in assembly is known. In addition, this protein possesses the ability to gate, and in doing so can preferentially allow the passage of anions in the open state and cations in the closed state. However, the precise mechanism by which gating of porin occurs and a complete understanding of porin’s function in vivo remains elusive. The essentiality of porin was examined by constructing a strain of Neurospora crassa deficient for porin. This strain, denoted as WS004, exists as evidence that porin is non-essential for the survival of Neurospora crassa. However, the loss of porin results in a reduction in growth rate due to the dysfunction of the cytochrome mediated respiratory pathway, which was made evident by the reduction of cytochrome b and almost complete lack of cytochrome aa3. WS004 survives by inducing the expression of alternative oxidase, which funnels the electrons from the Q pool directly to oxygen, bypassing the cytochrome b and aa3 containing complexes III and IV respectively. Additional phenotypic differences observed included loss in ability to produce aerial hyphae, reduced amount of conidia produced and strains that were female sterile. It was determined, that additional genetic factors influenced the resulting phenotype due to the loss of porin. LC-MS/MS, in combination with iTRAQ labelling, was utilized to examine changes in the proteome profiles of porin containing and porin lacking mitochondria and showed several different proteins as significantly up- or down-regulated which lend to an explanation to some of the phenotypes observed. Taken together, these results demonstrate the central role of porin in regulating both mitochondrial and cellular processes.

Neurospora

Porin

Respiration

VDAC

Cytochromes

Fertility

Molecular cloning and nucleotide sequencing of fructose 1,6 bisphosphate aldolase in Neurospora crassa

Yamashita, Roxanne

January 1996

Thesis (Ph. D.)--University of Hawaii at Manoa, 1996. / Includes bibliographical references (leaves 185-196). / Microfiche. / xii, 196 leaves, bound ill. (some col.) 29 cm

Fructose-1,6-bisphosphate

Neurospora crassa

Nucleotide sequence