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Characterization of the Components of Carbon Catabolite Repression in Clostridium perfringensHorton, William Henry Clay 16 December 2004 (has links)
Clostridium perfringens is a versatile pathogen capable of causing a wide array of diseases, ranging from clostridial food poisoning to tissue infections such as gas gangrene. An important factor in virulence as well as in the distribution of C. perfringens is its ability to form an endospore. The symptoms of C. perfringens food poisoning are directly correlated to the release of an enterotoxin at the end of the sporulation process. The sporulation process in C. perfringens is subject to carbon catabolite repression (CCR) by sugars, especially glucose. CCR is a regulatory pathway that alters transcription based on carbon source availability. In Gram-positive bacteria, the HPr kinase/phosphatase is responsible for this nutritional sensing by phosphorylating or dephosphorylating the serine-46 residue of HPr. HPr-Ser-P then forms a complex with the transcriptional regulator CcpA to regulate transcription. We were able to show here that purified recombinant C. perfringens HPr kinase/phosphatase was able to phosphorylate the serine-46 residue of HPr. When the codon for this serine residue is mutated through PCR mutagenesis to encode alanine, phosphorylation could not take place. We have also shown that in gel retardation assays, CcpA and HPr-Ser-P were able to bind to two DNA fragments containing putative C. perfringens CRE-sites, sequences where CcpA binds to regulate transcription. The genome sequence of a food poisoning strain of C. perfringens was searched for potential CRE-sites using degenerate sequences designed to match those CRE-sites CcpA was shown to bind. DNA fragments containing these newly identified CRE-sites were then used in gel retardation assays to determine whether CcpA binds to these CRE-sites, making them candidates for CCR regulation. These results, combined with comparisons of metabolic characteristics of a ccpA- strain versus wild-type C. perfringens, provide evidence that CcpA participates in the regulation of carbon catabolite repression in the pathogenic bacterium C. perfringens / Master of Science
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The role of protein phosphorylation in regulation of carbon catabolite repression in Bacillus subtilis / The role of protein phosphorylation in regulation of carbon catabolite repression in Bacillus subtilisSingh, Kalpana 31 October 2008 (has links)
No description available.
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Identifying target proteins of the CreB deubiquitination enzyme in the fungus Aspergillus nidulans.Kamlangdee, Niyom January 2008 (has links)
Carbon catabolite repression in A. nidulans is a regulatory system which allows the organism to utilize the most preferable carbon source by repressing the expression of genes encoding enzymes utilizing alternative carbon sources. A ubiquitination pathway was shown to be one of the key mechanisms which regulate carbon source utilization, when creB was found to encode a deubiquitinating enzyme. Strains containing mutations in creB show loss of repression for some metabolic pathways in carbon catabolite repressing conditions, and also grow very poorly on several sole carbon sources such as quinate and proline, suggesting CreB plays multiple roles in the cell. This work describes the analysis of the interaction of CreB with CreA, and with PrnB and QutD. Various epitope-tagged versions of CreA were expressed in A. nidulans, and an internally located HA-epitope tag was found to allow detection of CreA using Western analysis. A diploid strain was constructed between strains containing HA-tagged CreA and FLAG-tagged CreB. When CreB was immunoprecipitated, HA-tagged CreA was also precipitated in the diploid, indicating that CreA and CreB are present in a complex in vivo. To determine whether CreA is a ubiquitinated protein, a version of CreA that was tagged with both an HA epitope and a His-tag was expressed in A. nidulans, and protein extracts were precipitated with an UbiQapture™-Q matrix. Western analysis was used to show that CreA was present in the precipitate. These findings suggest that CreA is a ubiquitinated protein, and a target of the CreB deubiquitination enzyme. To determine whether the proline permease (PrnB) is a direct substrate of CreB, plasmids to express epitope-tagged versions of PrnB were constructed and introduced into the prnB mutant strain. No tagged protein could be detected by Western analysis, even when these constructs were over-expressed from the gpdA promoter. However, a construct to express an HA epitope tagged version of quinate permease (QutD) fully complemented the qutD mutant strain, and HA-tagged QutD could be easily detected in Western analysis when probed with the anti-HA monoclonal antibody. A diploid strain was made between a complementing transformant and a strain expressing a FLAG-tagged CreB construct. When QutDHA was immunoprecipitated, CreBFLAG was detected in the immunoprecipitate of the diploid. A proportion of QutDHA was also co-precipitated in the diploid when CreBFLAG was immunoprecipitated. Thus, CreB is present in a complex with QutD in vivo. Further results showed that the concentration of QutD in the cell is lower in a creB null mutant background than in the wild-type background, indicating that deubiquitination is required to prevent protein turnover. Northern analysis of mRNA showed that the failure of creB mutant strains to grow on quinate medium was not due to a failure of transcriptional induction of qutD, as the amount of mRNA was not lower in a creB1937 mutant background compared to the wild-type. Furthermore, experiments were undertaken that showed that QutD is a ubiquitinated protein. These findings suggest that quinate permease is regulated through deubiquitination involving the CreB deubiquitination protein in A. nidulans. In addition to the candidate protein approach asking whether CreA is a substrate of CreB, a proteomics approach was also used to identify proteins that interact with CreA. However, no clear interacting proteins were identified using this approach. / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008
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Multiple regulatory inputs for hierarchical control of phenol catabolism by Pseudomonas putidaMadhushani, W. K. Anjana January 2015 (has links)
Metabolically versatile bacteria have evolved diverse strategies to adapt to different environmental niches and respond to fluctuating physico-chemical parameters. In order to survive in soil and water habitats, they employ specific and global regulatory circuits to integrate external and internal signals to counteract stress and optimise their energy status. One strategic endurance mechanism is the ability to choose the most energetically favourable carbon source amongst a number on offer. Pseudomonas putida strains possess large genomes that underlie much of their ability to use diverse carbon sources as growth substrates. Their metabolic potential is frequently expanded by possession of catabolic plasmids to include the ability to grow at the expense of seemingly obnoxious carbon sources such as phenols. However, this ability comes with a metabolic price tag. Carbon source repression is one of the main regulatory networks employed to subvert use of these expensive pathways in favour of alternative sources that provide a higher metabolic gain. This thesis identifies some of the key regulatory elements and factors used by P. putida to supress expression of plasmid-encoded enzymes for degradation of phenols until they are beneficial. I first present evidence for a newly identified DNA and RNA motif within the regulatory region of the gene encoding the master regulator of phenol catabolism – DmpR. The former of these motifs functions to decrease the number of transcripts originating from the dmpR promoter, while the latter mediates a regulatory checkpoint for translational repression by Crc – the carbon repression control protein of P. putida. The ability of Crc to form repressive riboprotein complexes with RNA is shown to be dependent on the RNA chaperone protein Hfq – a co-partnership demonstrated to be required for many previously identified Crc-targets implicated in hierarchical assimilation of different carbon sources in P. putida. Finally, I present evidence for a model in which Crc and Hfq co-target multiple RNA motifs to bring about a two-tiered regulation to subvert catabolism of phenols in the face of preferred substrates – one at the level of the regulator DmpR and another at the level of translation of the catabolic enzymes.
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Identifying target proteins of the CreB deubiquitination enzyme in the fungus Aspergillus nidulans.Kamlangdee, Niyom January 2008 (has links)
Carbon catabolite repression in A. nidulans is a regulatory system which allows the organism to utilize the most preferable carbon source by repressing the expression of genes encoding enzymes utilizing alternative carbon sources. A ubiquitination pathway was shown to be one of the key mechanisms which regulate carbon source utilization, when creB was found to encode a deubiquitinating enzyme. Strains containing mutations in creB show loss of repression for some metabolic pathways in carbon catabolite repressing conditions, and also grow very poorly on several sole carbon sources such as quinate and proline, suggesting CreB plays multiple roles in the cell. This work describes the analysis of the interaction of CreB with CreA, and with PrnB and QutD. Various epitope-tagged versions of CreA were expressed in A. nidulans, and an internally located HA-epitope tag was found to allow detection of CreA using Western analysis. A diploid strain was constructed between strains containing HA-tagged CreA and FLAG-tagged CreB. When CreB was immunoprecipitated, HA-tagged CreA was also precipitated in the diploid, indicating that CreA and CreB are present in a complex in vivo. To determine whether CreA is a ubiquitinated protein, a version of CreA that was tagged with both an HA epitope and a His-tag was expressed in A. nidulans, and protein extracts were precipitated with an UbiQapture™-Q matrix. Western analysis was used to show that CreA was present in the precipitate. These findings suggest that CreA is a ubiquitinated protein, and a target of the CreB deubiquitination enzyme. To determine whether the proline permease (PrnB) is a direct substrate of CreB, plasmids to express epitope-tagged versions of PrnB were constructed and introduced into the prnB mutant strain. No tagged protein could be detected by Western analysis, even when these constructs were over-expressed from the gpdA promoter. However, a construct to express an HA epitope tagged version of quinate permease (QutD) fully complemented the qutD mutant strain, and HA-tagged QutD could be easily detected in Western analysis when probed with the anti-HA monoclonal antibody. A diploid strain was made between a complementing transformant and a strain expressing a FLAG-tagged CreB construct. When QutDHA was immunoprecipitated, CreBFLAG was detected in the immunoprecipitate of the diploid. A proportion of QutDHA was also co-precipitated in the diploid when CreBFLAG was immunoprecipitated. Thus, CreB is present in a complex with QutD in vivo. Further results showed that the concentration of QutD in the cell is lower in a creB null mutant background than in the wild-type background, indicating that deubiquitination is required to prevent protein turnover. Northern analysis of mRNA showed that the failure of creB mutant strains to grow on quinate medium was not due to a failure of transcriptional induction of qutD, as the amount of mRNA was not lower in a creB1937 mutant background compared to the wild-type. Furthermore, experiments were undertaken that showed that QutD is a ubiquitinated protein. These findings suggest that quinate permease is regulated through deubiquitination involving the CreB deubiquitination protein in A. nidulans. In addition to the candidate protein approach asking whether CreA is a substrate of CreB, a proteomics approach was also used to identify proteins that interact with CreA. However, no clear interacting proteins were identified using this approach. / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008
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The Regulation of NAP4 in Saccharomyces cerevisiaeCapps, Denise 20 May 2011 (has links)
The CCAAT binding-factor (CBF) is a transcriptional activator conserved in eukaryotes. The CBF in Saccharomyces cerevisiae is a multimeric heteromer termed the Hap2/3/4/5 complex. Hap4, which contains the activation domain of the complex, is also the regulatory subunit and is known to be transcriptionally controlled by carbon sources. However, little is known about Hap4 regulation. In this report, I identify mechanisms by which Hap4 is regulated, including: (1) transcriptional regulation via two short upstream open reading frames (uORFs) in the 5' leader sequence of HAP4 mRNA; (2) proteasome-dependent degradation of Hap4; and (3) identification of two negative regulators of HAP4 expression, CYC8 and SIN4. I also report differential patterns of Hap4 cellular localization which depends on (1) carbon sources, (2) abundance of Hap4 protein, and (3) presence or absence of mitochondrial DNA (mtDNA).
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Estudos genéticos e moleculares da produção de celulases e hemicelulases em Aspergillus nidulans e Aspergillus niger / The genetic and molecular studies of cellulase and hemicellulase production in Aspergillus nidulans and Aspergillus niger.Gouvêa, Paula Fagundes de 31 July 2013 (has links)
O mundo se depara atualmente com a perspectiva de um significativo aumento na demanda por etanol combustível. O bagaço de cana está entre os maiores subprodutos agroindustriais no Brasil, sendo uma das alternativas na utilização para a produção do etanol de segunda geração. A degradação do bagaço de cana requer a ação de muitas enzimas diferentes que são reguladas transcripcionalmente. Considerando-se que o custo de celulases e hemicelulases contribuem substancialmente no preço do bioetanol, novos estudos visando o entendimento da eficiência e produtividade de celulases são de grande importância. Para entender como melhorar coquetéis de enzimas que podem hidrolizar o bagaço de cana-de-açúcar pré-tratado, uitlizou-se um experimento de genômica para investigar-se quais genes e vias são transcripcionalmente moduladas durante o crescimento de A. niger em bagaço de cana-de-açúcar explodido. Neste trabalho foram identificados genes que codificam celulases e hemicelulases com aumento da expresão durante o crescimento em bagaço de cana-de-açúcar explodido. Foi também realizada a determinação do acúmulo de mRNA de diversos genes que codificam transportadores para verificar se estes eram induzidos por xilose e por depedência de glicose. Foram identificados 18 genes que corresponde a 58% de celulases preditas em A. niger e 21 genes que correponde a 58% de hemicelulases preditas em A. niger os quias foram altamente expressos durante o crescimento em bagaço de cana-de-açúcar explodido. Foi investigado também o papel central realizado pelas proteínas quinases e fosfatases não essenciais (NPKs e NPPs, respectivamente) quando em presença de celulose como fonte de carbono, no sensoriamento do estado energético e na subsequente via de sinalização no fungo filamentoso modelo Aspergillus nidulans. O estudo com A. nidulans identificou 11 quinases e 7 fosfatases não essências, NPKs e NPPs, respectivamente, envolvidas na produção de celulases e em alguns casos, na produção também de hemicelulases. O envolvimento destas NPKs identificadas na resposta induzida por avicel e na desrepressão foram acessados pela análise do transcriptoma da cepa selvagem e por microscopia de fluorescência através da cepa de fusão CreA::GFP expressa no selvagem e no background dos mutantes de NPKs. A ausência das quinases snfA e schA reduziu dramaticamente a resposta transcricional induzida por celulose incluindo a expressão de enzimas hidrolíticas e transportadores, enquanto que a ausência de snfA resultou em uma quase completa modulação gênica induzida por celulose. O mecanismo pelo qual essas duas quinases controlam a transcrição gênica foi identificado, onde os dois mutantes de quinases foram capazes de desbloquear o CreA mediante a repressão catabólica do carbono (CCR), sob condições de desrepressão, como em baixa presença de carbono ou crescimento em celulose. Desta forma, este trabalho abriu novas possibilidades para o entendimento da sacarificação do bagaço de cana-de-açúcar por hidrolases de A. niger e para a construção de coquetéis de enzimas mais eficientes para a obtenção do etanol de segunda geração. Também possibilitou a identificação de muitas quinases e fosfatases envolvidas no sensoriamento do carbono e do estado energético, as quais demonstraram papéis sobrespostos e distintos de snfA e schA na regulação da desrepressão de CreA e na produção de enzimas hidrolíticas em A. nidulans. / The world today is faced with the prospect of a significant increase in demand for fuel ethanol. Sugarcane bagasse is among the largest agro-industrial by-products in Brazil, one of the alternatives in use for the production of second generation ethanol. Degradation of sugarcane bagasse requires the action of many different enzymes which are transcriptionally regulated. Considering that the costs of cellulases and hemicellulases contribute substantially to the price of bioethanol, new studies aimed at understanding and improving cellulase efficiency and productivity are of paramount importance. To understand how to improve enzymatic cocktails that can hydrolyze pretreated sugarcane bagasse, we used a genomics approach to investigate which genes and pathways are transcriptionally modulated during growth of A. niger on steam-exploded sugarcane bagasse. We also sought to determine whether the mRNA accumulation of several steam-exploded sugarcane bagasseinduced genes encoding putative transporters is induced by xylose and dependent on glucose. We identified 18 genes that corresponds to 58% of A. niger predicted cellulases and 21 genes that correspond to 58% of A. niger predicted hemicellulases, that were highly expressed during growth on sugarcane bagasse. The central role performed by nonessential protein kinases (NPK) and phosphatases (NPP) when grown on cellulose as a sole carbon source, in the sensing energetic status and the subsequent signalling pathways was assessed in the model filamentous fungus Aspergillus nidulans. This study identified multiple kinases and phosphatases (NPKs and NPPs, respectively) involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans. The involvement of the identified NPKs in avicel-induced responses and CreA derepression was assessed by genome-wide transcriptomics and fluorescent microscopy of a CreA::GFP fusion proteinexpressed in the wild-type and NPK-deficient mutant backgrounds. The absence of either the schA or snfA kinase dramatically reduced cellulose-induced transcriptional responses including the expression of hydrolytic enzymes and transporters, while the absence snfA resulted in a near complete loss of wild-typecellulose-induced gene modulation. The mechanism by which these two NPKs controlled gene transcription was identified, as neither of NPK-deficient mutants were able to unlock CreA-mediated carbon catabolite repression, under derepressing conditions, such as carbon starvation or growth on cellulose. Our presently reported work opens new possibilities for understanding sugarcane biomass saccharification by A. niger hydrolases and for the construction of more efficient enzymatic cocktails for second-generation bioethanol. This work also enable the identification of multiple kinases and phosphatases involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans.
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Etude de la dynamique des mécanismes de la répression catabolique : des modèles mathématiques aux données expérimentales / Study of the dynamics of catabolite repression : from mathematical models to experimental dataZulkower, Valentin 03 March 2015 (has links)
La répression catabolique désigne un mode de régulation très répandu chez les bactéries, par lequel les enzymes nécessaires à l'import et la digestion de certaines sources carbonées sont réprimées en présence d'une source carbonée avantageuse, par exemple le glucose dans le cas de la bactérie E. coli. Nous proposons une approche mathématique et expérimentale pour séparer et évaluer l'importance des différents mécanismes de la répression catabolique. En particulier, nous montrons que l'AMP cyclique et l'état physiologique de la cellule jouent tous deux un rôle important dans la régulation de gènes sujets à la ré- pression catabolique. Nous présentons également des travaux méthodologiques réalisés dans le cadre de cette étude et contribuant à l'étude des réseaux de régulation génique en général. En particulier, nous étudions l'applicabilité de l'approximation quasi-stationnaire utilisée pour la réduction de modèles, et présentons des méthodes pour l'estimation robuste de taux de croissance, activité de promoteur, et concentration de protéines à partir de données bruitées provenant d'expériences avec gènes rapporteur. / Carbon Catabolite Repression (CCR) is a wide-spread mode of regulation in bacteria by which the enzymes necessary for the uptake and utilization of some carbon sources are repressed in presence of a preferred carbon source, e.g., glucose in the case of Escherichia coli . We propose a joint mathematical and experimental approach to separate and evaluate the importance of the different components of CCR. In particular, we show that both cyclic AMP and the global physiology of the cell play a major role in the regulation of the cAMP-dependent genes affected by CCR. We also present methodological improvements for the study of gene regulatory networks in general. In partic- ular, we examine the applicability of the Quasi-Steady-State-Approximation to reduce mathematical gene expression models, and provide robust meth- ods for the robust estimation of growth rate, promoter activity, and protein concentration from noisy kinetic reporter experiments.
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Estudos genéticos e moleculares da produção de celulases e hemicelulases em Aspergillus nidulans e Aspergillus niger / The genetic and molecular studies of cellulase and hemicellulase production in Aspergillus nidulans and Aspergillus niger.Paula Fagundes de Gouvêa 31 July 2013 (has links)
O mundo se depara atualmente com a perspectiva de um significativo aumento na demanda por etanol combustível. O bagaço de cana está entre os maiores subprodutos agroindustriais no Brasil, sendo uma das alternativas na utilização para a produção do etanol de segunda geração. A degradação do bagaço de cana requer a ação de muitas enzimas diferentes que são reguladas transcripcionalmente. Considerando-se que o custo de celulases e hemicelulases contribuem substancialmente no preço do bioetanol, novos estudos visando o entendimento da eficiência e produtividade de celulases são de grande importância. Para entender como melhorar coquetéis de enzimas que podem hidrolizar o bagaço de cana-de-açúcar pré-tratado, uitlizou-se um experimento de genômica para investigar-se quais genes e vias são transcripcionalmente moduladas durante o crescimento de A. niger em bagaço de cana-de-açúcar explodido. Neste trabalho foram identificados genes que codificam celulases e hemicelulases com aumento da expresão durante o crescimento em bagaço de cana-de-açúcar explodido. Foi também realizada a determinação do acúmulo de mRNA de diversos genes que codificam transportadores para verificar se estes eram induzidos por xilose e por depedência de glicose. Foram identificados 18 genes que corresponde a 58% de celulases preditas em A. niger e 21 genes que correponde a 58% de hemicelulases preditas em A. niger os quias foram altamente expressos durante o crescimento em bagaço de cana-de-açúcar explodido. Foi investigado também o papel central realizado pelas proteínas quinases e fosfatases não essenciais (NPKs e NPPs, respectivamente) quando em presença de celulose como fonte de carbono, no sensoriamento do estado energético e na subsequente via de sinalização no fungo filamentoso modelo Aspergillus nidulans. O estudo com A. nidulans identificou 11 quinases e 7 fosfatases não essências, NPKs e NPPs, respectivamente, envolvidas na produção de celulases e em alguns casos, na produção também de hemicelulases. O envolvimento destas NPKs identificadas na resposta induzida por avicel e na desrepressão foram acessados pela análise do transcriptoma da cepa selvagem e por microscopia de fluorescência através da cepa de fusão CreA::GFP expressa no selvagem e no background dos mutantes de NPKs. A ausência das quinases snfA e schA reduziu dramaticamente a resposta transcricional induzida por celulose incluindo a expressão de enzimas hidrolíticas e transportadores, enquanto que a ausência de snfA resultou em uma quase completa modulação gênica induzida por celulose. O mecanismo pelo qual essas duas quinases controlam a transcrição gênica foi identificado, onde os dois mutantes de quinases foram capazes de desbloquear o CreA mediante a repressão catabólica do carbono (CCR), sob condições de desrepressão, como em baixa presença de carbono ou crescimento em celulose. Desta forma, este trabalho abriu novas possibilidades para o entendimento da sacarificação do bagaço de cana-de-açúcar por hidrolases de A. niger e para a construção de coquetéis de enzimas mais eficientes para a obtenção do etanol de segunda geração. Também possibilitou a identificação de muitas quinases e fosfatases envolvidas no sensoriamento do carbono e do estado energético, as quais demonstraram papéis sobrespostos e distintos de snfA e schA na regulação da desrepressão de CreA e na produção de enzimas hidrolíticas em A. nidulans. / The world today is faced with the prospect of a significant increase in demand for fuel ethanol. Sugarcane bagasse is among the largest agro-industrial by-products in Brazil, one of the alternatives in use for the production of second generation ethanol. Degradation of sugarcane bagasse requires the action of many different enzymes which are transcriptionally regulated. Considering that the costs of cellulases and hemicellulases contribute substantially to the price of bioethanol, new studies aimed at understanding and improving cellulase efficiency and productivity are of paramount importance. To understand how to improve enzymatic cocktails that can hydrolyze pretreated sugarcane bagasse, we used a genomics approach to investigate which genes and pathways are transcriptionally modulated during growth of A. niger on steam-exploded sugarcane bagasse. We also sought to determine whether the mRNA accumulation of several steam-exploded sugarcane bagasseinduced genes encoding putative transporters is induced by xylose and dependent on glucose. We identified 18 genes that corresponds to 58% of A. niger predicted cellulases and 21 genes that correspond to 58% of A. niger predicted hemicellulases, that were highly expressed during growth on sugarcane bagasse. The central role performed by nonessential protein kinases (NPK) and phosphatases (NPP) when grown on cellulose as a sole carbon source, in the sensing energetic status and the subsequent signalling pathways was assessed in the model filamentous fungus Aspergillus nidulans. This study identified multiple kinases and phosphatases (NPKs and NPPs, respectively) involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans. The involvement of the identified NPKs in avicel-induced responses and CreA derepression was assessed by genome-wide transcriptomics and fluorescent microscopy of a CreA::GFP fusion proteinexpressed in the wild-type and NPK-deficient mutant backgrounds. The absence of either the schA or snfA kinase dramatically reduced cellulose-induced transcriptional responses including the expression of hydrolytic enzymes and transporters, while the absence snfA resulted in a near complete loss of wild-typecellulose-induced gene modulation. The mechanism by which these two NPKs controlled gene transcription was identified, as neither of NPK-deficient mutants were able to unlock CreA-mediated carbon catabolite repression, under derepressing conditions, such as carbon starvation or growth on cellulose. Our presently reported work opens new possibilities for understanding sugarcane biomass saccharification by A. niger hydrolases and for the construction of more efficient enzymatic cocktails for second-generation bioethanol. This work also enable the identification of multiple kinases and phosphatases involved in the sensing of carbon or energetic status, while demonstrating the overlapping and distinct roles of snfA and schA in the regulation of CreA derepression and hydrolytic enzyme production in A.nidulans.
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