Regulatory Genes Controlling Fatty Acid Catabolism and Peroxisomal Functions in the Filamentous Fungus
            <i>Aspergillus nidulans</i>

Hynes, Michael J.; Murray, Susan; Duncan, Anna E.; Khew, Gillian; Davis, Meryl A.

doi:10.1128/ec.5.5.794-805.2006

Cited by 109 publications

(177 citation statements)

References 89 publications

(99 reference statements)

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“…The FacB activator, which is similar to the Cat8/Sip4 proteins, is specific for the regulation of genes required for acetate utilization. The enzymes of the glyoxalate cycle that are required for growth on both acetate and fatty acids are additionally controlled by fatty acid induction independently of FacB, and regulatory genes involved in this have been identified (Hynes et al 2006). In S. cerevisiae, the glyoxalate cycle genes are not regulated by fatty acid induction but only by Cat8/Sip4 (Hiltunen et al 2003).…”

Section: Discussionmentioning

confidence: 99%

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Transcriptional Control of Gluconeogenesis in Aspergillus nidulans

et al. 2007

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Aspergillus nidulans can utilize carbon sources that result in the production of TCA cycle intermediates, thereby requiring gluconeogenesis. We have cloned the acuG gene encoding fructose-1,6 bisphosphatase and found that expression of this gene is regulated by carbon catabolite repression as well as by induction by a TCA cycle intermediate similar to the induction of the previously studied acuF gene encoding phosphoenolpyruvate carboxykinase. The acuN356 mutation results in loss of growth on gluconeogenic carbon sources. Cloning of acuN has shown that it encodes enolase, an enzyme involved in both glycolysis and gluconeogenesis. The acuN356 mutation is a translocation with a breakpoint in the 59 untranslated region resulting in loss of expression in response to gluconeogenic but not glycolytic carbon sources. Mutations in the acuK and acuM genes affect growth on carbon sources requiring gluconeogenesis and result in loss of induction of the acuF, acuN, and acuG genes by sources of TCA cycle intermediates. Isolation and sequencing of these genes has shown that they encode proteins with similar but distinct Zn(2) Cys(6) DNA-binding domains, suggesting a direct role in transcriptional control of gluconeogenic genes. These genes are conserved in other filamentous ascomycetes, indicating their significance for the regulation of carbon source utilization.

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Section: Discussionmentioning

confidence: 99%

“…Molecular techniques: Standard methods for DNA manipulations, RNA isolation, nucleic acid blotting, and hybridization have been described (Sambrook et al 1989;Todd et al 2005;Hynes et al 2006).…”

Section: Methodsmentioning

confidence: 99%

Transcriptional Control of Gluconeogenesis in Aspergillus nidulans

et al. 2007

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“…The regulatory proteins involved in this process comprise the transcription factors (TFs) Adr1, Cat8, Oaf1 and Pip2 [26]. In Aspergilus nidulans, the TFs FarA and FarB were recently identified as central regulators of lipid utilization genes and were shown to bind the CCGAGG sequence: a farA mutant has a reduced peroxisomal proliferation and perturbs the oleate gene expression response [27]. Interestingly, both the CCGAGG cisregulatory element and the FarA protein are conserved in most ascomycetes, with the exception of Ashbya gossypii, Kluvyeromyces lactis, C. glabrata, S. cerevisiae and other Saccharomyces species [27] (Figure 1a).…”

Section: Fatty-acid Catabolism and Phospholipid Biosynthesismentioning

confidence: 99%

“…In Aspergilus nidulans, the TFs FarA and FarB were recently identified as central regulators of lipid utilization genes and were shown to bind the CCGAGG sequence: a farA mutant has a reduced peroxisomal proliferation and perturbs the oleate gene expression response [27]. Interestingly, both the CCGAGG cisregulatory element and the FarA protein are conserved in most ascomycetes, with the exception of Ashbya gossypii, Kluvyeromyces lactis, C. glabrata, S. cerevisiae and other Saccharomyces species [27] (Figure 1a). The ortholog of FarA in C. albicans, Ctf1, is required for growth on oleate and different lipidic carbon sources while the TFs Cat8 and Adr1 are dispensable and Oaf1 and Pip2 are missing in C. albicans and related species [28,60].…”

Section: Fatty-acid Catabolism and Phospholipid Biosynthesismentioning

confidence: 99%

Rearrangements of the transcriptional regulatory networks of metabolic pathways in fungi

Lavoie

Hogues

Whiteway

2009

Current Opinion in Microbiology

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“…Infection of NOKs resulted in elevated expression of short-chain fatty acid CoA ligase (43 sequences) and glucosamine-6-phosphate isomerase (14 sequences) in the fungus, the high number of clones for these genes indicating that the main limitation to infection by P. brasiliensis is the acquisition of nutrients. Short-chain fatty acid CoA ligase, which catalyses the formation of acyl-CoA from a shortchain fatty acid, has a central role in the metabolism, development and pathogenicity of many fungi (Hynes et al, 2006). Fatty acids can serve as sole sources of carbon and energy, whilst acyl-CoAs serve as important intermediates in diverse metabolic functions such as fatty acid transport, oxidative degradation of fatty acids and phospholipid biosynthesis, as well as enzyme activation, cell signalling and transcriptional regulation (Morgan-Kiss & Cronan, 2004).…”

Section: R Peres Da Silva and Othersmentioning

confidence: 99%

Differential gene expression analysis of Paracoccidioides brasiliensis during keratinocyte infection

Silva

Matsumoto

Braz

et al. 2011

Journal of Medical Microbiology

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Paracoccidioides brasiliensis is the agent of paracoccidioidomycosis, one of the most important systemic fungal diseases in Latin America. This initiates in lung tissue and can subsequently disseminate to other tissues. Clinical manifestations range from localized forms to disseminated disease that can progress to lethality, probably depending on the relationships among the virulence of the fungus, the immune response and the ability to interact with the surface structures and invade epithelial cells and mononuclear cells of the host. It is generally regarded as a multifocal disease, with oral lesions as the prominent feature. The aim of this study was to evaluate P. brasiliensis yeast infection in normal oral keratinocytes (NOKs). The differential expression of mRNAs and proteins was also determined when the fungus was placed in contact with the cell in order to characterize differentially expressed genes and proteins during P. brasiliensis infection. After contact with NOKs, the fungus appeared to induce alterations in the cells, which showed cellular extensions and cavitations, probably resulting from changes in the actin cytoskeleton seen at 5 and 8 h after infection. Levels of protein expression were higher after reisolation of the fungus from infected NOK culture compared with culture of the fungus in medium. The analysis identified transcripts related to 19 proteins involved in different biological processes. Transcripts were found with multiple functions including induction of cytokines, protein metabolism, alternative carbon metabolism, zinc transport and the stress response during contact with NOKs. The proteins found suggested that the yeast was in a stress situation, as indicated by the presence of RDS1. Nevertheless, the yeast seemed to be proliferating and metabolically active, as shown by the presence of a proteasome, short-chain acetylator, glucosamine-6-phosphate isomerase and ADP/ATP carrier transcripts. Additionally, metabolic pathways may have been activated in order to eliminate toxic substances from the cell as a zinc transporter was detected, which is a potential target for the development of future drugs. INTRODUCTIONParacoccidioides brasiliensis is a thermodimorphic pathogenic fungus, the aetiological agent of paracoccidioidomycosis (PCM), an endemic disease geographically limited to Latin America and one of the most prevalent human deep systemic mycoses found in Brazil, Colombia and Venezuela (San-Blas et al., 2002). The transition from mycelium at 25 u C to yeast at 37 u C is essential for P. brasiliensis to establish the disease (Franco et al., 1997). P. brasiliensis may be inhaled and, once in the lungs, the fungus initiates a process of morphological transition into the pathogenic yeast form (San-Blas et al., 2002).PCM has a multiplicity of clinical presentations, from cutaneous to systemic forms, and can attack various tissues, especially the lungs (Benard & Franco, 2007). Oral mucosal lesions are commonly multiple, with a granular, mulberry-like surface and microulcerations, and ...

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Regulatory Genes Controlling Fatty Acid Catabolism and Peroxisomal Functions in the Filamentous Fungus Aspergillus nidulans

Cited by 109 publications

References 89 publications

Transcriptional Control of Gluconeogenesis in Aspergillus nidulans

Transcriptional Control of Gluconeogenesis in Aspergillus nidulans

Rearrangements of the transcriptional regulatory networks of metabolic pathways in fungi

Differential gene expression analysis of Paracoccidioides brasiliensis during keratinocyte infection

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