Project description:Cells must sense and respond to available nutrients to utilize available resources and establish fungal colonies. Saprophytic microbes harvest carbon from plant biomass, which contain insoluble, complex carbohydrates that must be degraded extracellularly prior to import into the cell. Filamentous fungi can degrade these complex carbohydrates. However, while many single cellular microbes can utilize the building blocks of these insoluble polysaccharides, they frequently are unable to degrade insoluble carbohydrates. Cellobiose is a disaccharide breakdown product of cellulose, the most abundant component of plant biomass. We investigated the genetic regulation of cellobiose utilization in the oleaginous, basidiomycete yeast Rhodotorula (Rhodosporidium) toruloides using a combination of phylogenetic, genetic, and genomic approaches. We tested the closest R. toruloides homolog of the cellulose degradation regulator CLR-2/ClrB for a role in cellobiose utilization. Deletion of this transcription factor, which we named Cbr1, eliminated the ability of cells to grow on media containing cellobiose as the sole carbon source. Although, the role of CLR-2/ClrB is limited to regulating the expression of genes involved in the utilization of cellulose and hemicellulose, Cbr1 plays a role not only in cellobiose utilization, but also utilization of tricarboxylic acid (TCA) cycle intermediates. Transcriptional profiling revealed that the genes activated by Cbr1 included genes encoding beta-glucosidases and transporters. These beta-glucosidases are secreted and are necessary and sufficient for cellobiose utilization, while one of the transporters is required for utilization of the TCA cycle intermediate, citrate. Additionally, Cbr1 inhibits carbon catabolite repression, specifically during utilization of disaccharides, which may have evolved to limit the repression of genes encoding secreted proteins that cleave disaccharides into glucose extracellularly. The co-regulation of cellobiose and TCA cycle utilization with carbon catabolite repression may shed light on alternative methods of the regulation of carbon catabolite repression in fungi.

Project description:The synthesis of cellulolytic enzymes by filamentous fungi are mainly regulated at the transcriptional level. The essential role of transcriptional activator ClrB/CLR-2 in the induction of cellulase genes has been reported in several fungal species. In this study, we identified the C-terminal region of ClrB in Penicillium oxalicum as a transcriptional activation domain using a yeast reporter gene system. Overexpression of a mutant ClrBID fusing the DNA-binding and transcriptional activation domains of ClrB together enabled cellulase production under cellulase non-inducing conditions. Strikingly, the ClrBID-overexpression strain produced cellulase in the presence of glucose at a level similar to that of reference strain on cellulose. Combination of ClrBID overexpression and deletion of carbon catabolite-repressor gene creA suggested an additive effect of the two manipulations on carbon catabolite de-repression. A similar modification of ClrB in Aspergillus niger also resulted in cellulase production on glucose. The results indicated that the post-transcriptional control of ClrB activity involves its central region, and provided a potential strategy for engineering Penicillium and Aspergillus strains for cellulase production on easy-to-use carbon sources.

Project description:Purpose: To explore conservation of gene regulation by the transcription factor clr-2/clrB in Neurospora crassa and Aspergillus nidulans Methods: mRNA from wild type and clr-2/clrB mutants were collected after a culture shift from sucrose/glucose to Avicel (crystaline cellulose) or no carbon media Results: We show that N. crassa and A. nidulans have similair global transcriptional responses to Avicel, with several hundred genes showing specific induction, though the induced genes are more specifically targeted at cellulose for N. crassa and more targeted at hemicellulose and pectin for A. nidulans. clr-2/clrB has a conserved fundamental function in cellulose induction, though the mechanism has diverged. Misexpression of clr-2 is sufficeint for inducer free cellulase secretion in N. crassa, but neither clrB or heterologous clr-2 is sufficient for inducer free cellulase secretion in A. nidulans. Conclusions: Our study demonstrates a conserved and essential role in cellulose utilization for the transcription factor clr-2 in filamentous ascomycetes and demonstrates that manipulation of clr-2 expression can be used to control cellulase expression in some species.

Project description:We have a cDNA microarray to investigate changes in gene expression following transfer of fungal cultures from growth on glucose to growth on pectin or no carbon source. Our goal was to asses the roles of release from carbon catabolite repression and specific induction on proteins needed for metabolism (or utilization) of a single class of complex polysaccharide. Keywords = Aspergillus Keywords = Pectin Keywords = central metabolism Keywords = pectin Keywords = carbon catabolite repression Keywords = polysaccharide Keywords = exopolygalacturonase Keywords: time-course

Project description:Purpose: To explore conservation of gene regulation by the transcription factor clr-2/clrB in Neurospora crassa and Aspergillus nidulans Methods: mRNA from wild type and clr-2/clrB mutants were collected after a culture shift from sucrose/glucose to Avicel (crystaline cellulose) or no carbon media Results: We show that N. crassa and A. nidulans have similair global transcriptional responses to Avicel, with several hundred genes showing specific induction, though the induced genes are more specifically targeted at cellulose for N. crassa and more targeted at hemicellulose and pectin for A. nidulans. clr-2/clrB has a conserved fundamental function in cellulose induction, though the mechanism has diverged. Misexpression of clr-2 is sufficeint for inducer free cellulase secretion in N. crassa, but neither clrB or heterologous clr-2 is sufficient for inducer free cellulase secretion in A. nidulans. Conclusions: Our study demonstrates a conserved and essential role in cellulose utilization for the transcription factor clr-2 in filamentous ascomycetes and demonstrates that manipulation of clr-2 expression can be used to control cellulase expression in some species. Biological triplicates of liquid culture N. crassa and A. nidulans were harvested at 4 hours and 6 hours, respectively, after a switch to media of interest. Global mRNA abundances from liquid cultures of N. crassa and A. nidulans were measured by sequencing on the Illumina Genome Analyzer IIx and HiSeq2000 platforms.

Project description:We have a cDNA microarray to investigate changes in gene expression following transfer of fungal cultures from growth on glucose to growth on pectin or no carbon source. Our goal was to asses the roles of release from carbon catabolite repression and specific induction on proteins needed for metabolism (or utilization) of a single class of complex polysaccharide. Keywords = Aspergillus Keywords = Pectin Keywords = central metabolism Keywords = pectin Keywords = carbon catabolite repression Keywords = polysaccharide Keywords = exopolygalacturonase

Project description:In the present study transcriptome and proteome of recombinant, xylose-utilising S. cerevisiae grown in aerobic batch cultures on xylose were compared with glucose-grown cells both in glucose repressed and derepressed states. The aim was to study at genome-wide level how signalling and carbon catabolite repression differed in cells grown on either glucose or xylose. The more detailed knowledge about is xylose sensed as a fermentable carbon source, capable of catabolite repression like glucose, or is it rather recognised as a non-fermentable carbon source is important in achieving understanding for further engineering this yeast for more efficient anaerobic fermentation of xylose.

Project description:Bacteria have evolved different mechanisms to catabolize carbon sources from a mixture of nutrients. They first consume their preferred carbon source, before others are used. Regulatory mechanisms adapt the metabolism accordingly to maximize growth and to outcompete other organisms. The human pathogen Campylobacter jejuni is an asaccharolytic Gram-negative bacterium that catabolizes amino acids and organic acids for growth. It prefers serine and aspartate as carbon sources, however it lacks all regulators known to be involved in regulating carbon source utilization in other organisms. In which manner C. jejuni adapts its metabolism towards the presence or absence of preferred carbon sources is unknown. In this study, we show with transcriptomic analysis and enzyme assays how C. jejuni adapts its metabolism in response to its preferred carbon source serine. In the presence of serine as well as lactate and pyruvate C. jejuni represses the utilization of other carbon sources, by repressing the expression of a number of central metabolic enzymes. The regulatory proteins RacR, Cj1000 and CsrA play a role in the regulation of these metabolic enzymes. This metabolism dependent transcriptional repression correlates with an accumulation of intracellular succinate. Hence, we propose a demand-based catabolite repression mechanism in C. jejuni, which depends on the intracellular succinate level.

Project description:Histidine is a good source of nutrient for many bacteria, but its utilization poses a significant challenge as it delivers excess nitrogen over carbon. The rate of histidine catabolism (hut) must thus be tightly regulated. Here, in Pseudomonas fluorescens SBW25, we show that the CbrAB two-component system directly activates the transcription of hut genes, while mediating succinate-induced carbon catabolite repression of hut at the translational level via the CbrAB-CrcYZ-Hfq/Crc regulatory cascade. When growing in minimal salt medium supplemented with histidine and succinate (the most preferred carbon source), the CbrAB-mediated promoter activity is weak; and the global nitrogen regulator NtrBC plays the dominant role in directly activating hut transcription.

Project description:Transcription factor reveals interconnected regulation of carbon source utilization and carbon catabolite repression in an oleaginous yeast