Metabolic Engineering of Fungal Strains for Conversion of
            <scp>d</scp>
            -Galacturonate to
            <i>meso</i>
            -Galactarate

Mojžita, Dominik; Wiebe, Marilyn G.; Hilditch, Satu; Boer, Harry; Penttilä, Merja; Richard, Peter

doi:10.1128/aem.02273-09

Cited by 63 publications

(101 citation statements)

References 21 publications

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“…Genetically modified bacteria have been used to produce ethanol from pectin-rich biomass (5,7). Using genetically modified fungi, D-galacturonic acid has been converted to galactaric acid (14) or to 2-keto-3-deoxy-L-galactonic acid (20).…”

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“…1) that includes reactions catalyzed by D-galacturonic acid reductase (10), L-galactonate dehydratase (9), 2-keto-3-deoxy galactonate aldolase (8), and L-glyceraldehyde reductase (11); the intermediates are L-galactonate, 2-keto-3-deoxy-L-galactonate (3-deoxy-L-threo-hex-2-ulosonate), and L-glyceraldehyde, and the products of the pathway are pyruvate and glycerol. D-Galacturonic acid can induce pectinolytic and D-galacturonic acid catabolic genes in A. niger, regardless of whether D-galacturonic acid is metabolized or not (4,14).By disrupting the native D-galacturonic acid catabolic pathway, it is possible to engineer fungal strains for alternative D-galacturonic acid conversions (14,20). In the case of galactaric acid production, the gene encoding D-galacturonic acid reductase was deleted and a gene encoding a D-galacturonic acid dehydrogenase expressed (14).…”

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“…By disrupting the native D-galacturonic acid catabolic pathway, it is possible to engineer fungal strains for alternative D-galacturonic acid conversions (14,20). In the case of galactaric acid production, the gene encoding D-galacturonic acid reductase was deleted and a gene encoding a D-galacturonic acid dehydrogenase expressed (14).…”

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Engineering Filamentous Fungi for Conversion of d -Galacturonic Acid to l -Galactonic Acid

Kuivanen

Mojžita

Wang

et al. 2012

Appl Environ Microbiol

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D-Galacturonic acid, the main monomer of pectin, is an attractive substrate for bioconversions, since pectin-rich biomass is abundantly available and pectin is easily hydrolyzed. L-Galactonic acid is an intermediate in the eukaryotic pathway for D-galacturonic acid catabolism, but extracellular accumulation of L-galactonic acid has not been reported. By deleting the gene encoding L-galactonic acid dehydratase (lgd1 or gaaB) in two filamentous fungi, strains were obtained that converted D-galacturonic acid to L-galactonic acid. Both Trichoderma reesei ⌬lgd1 and Aspergillus niger ⌬gaaB strains produced L-galactonate at yields of 0.6 to 0.9 g per g of substrate consumed. Although T. reesei ⌬lgd1 could produce L-galactonate at pH 5.5, a lower pH was necessary for A. niger ⌬gaaB. Provision of a cosubstrate improved the production rate and titer in both strains. Intracellular accumulation of L-galactonate (40 to 70 mg g biomass ؊1 ) suggested that export may be limiting. Deletion of the L-galactonate dehydratase from A. niger was found to delay induction of D-galacturonate reductase and overexpression of the reductase improved initial production rates. Deletion of the L-galactonate dehydratase from A. niger also delayed or prevented induction of the putative D-galacturonate transporter An14g04280. In addition, A. niger ⌬gaaB produced L-galactonate from polygalacturonate as efficiently as from the monomer. D-Galacturonic acid is the principal component of pectin, a major constituent of sugar beet pulp and citrus peel, which are abundant and inexpensive raw materials. The annual worldwide production of sugar beet and citrus fruit is about 250 ϫ 10 6 and 115 ϫ 10 6 metric tons, respectively. After beet processing, 5 to 10% of the sugar beet remains as dried sugar beet pulp. This pulp contains ca. 25% pectin (6). Citrus peel contains ca. 20% pectin on a dry mass basis. Sugar beet pulp and citrus peel are mainly used as cattle feed, or they are dumped. The use as cattle feed requires that the pulp and peel are dried since; otherwise, they rot rapidly. Disposal of the material is problematic because of the bad odor generated at the dumping sites. In the case of sugar beet pulp the energy consumption for drying and pelleting are 30 to 40% of the total energy used for beet processing (6). This process is only economical when done on a large scale and when energy costs are low. Other products, such as pectin and limonene, may be extracted from citrus peel. Pectin is used as a gelling agent in the food industry; limonene as a flavor compound. These are limited markets, and with increasing energy costs and alternative animal feed sources reducing the revenues from pectin-rich biomass for cattle feed sales, it is desirable to find new ways to convert this biomass to other useful products. This may be accomplished by microbial fermentation (16). Genetically modified bacteria have been used to produce ethanol from pectin-rich biomass (5, 7). Using genetically modified fungi, D-galacturonic acid has been converted to galactaric acid...

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Engineering Filamentous Fungi for Conversion of d -Galacturonic Acid to l -Galactonic Acid

Kuivanen

Mojžita

Wang

et al. 2012

Appl Environ Microbiol

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“…Nowadays, strains that are able to produce a variety of chemical compounds in concentrations as high as above 90% m/m of the theoretical maximum are available (Table 1) (Figure 2). The strategies to increase product formation generally include a series of modifications in the microorganism metabolism, achieved by overexpression or knockout of enzymes in the producing pathway [13,32], changing redox balancing of the cell by redirecting carbon fluxes from NADPH-to NADH consuming reactions [33][34][35][36], engineering global transcription machinery [37] and others (Table 1). All these types of modification were employed, for instance, to obtain S. cerevisiae strains that are able to produce ethanol from sugars that are present in lignocellulosic hydrolysates [38].…”

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Genetic improvement of microorganisms for applications in biorefineries

Paes

Almeida

2014

Chem. Biol. Technol. Agric.

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The development of biorefineries directed to the production of fuels, chemicals and energy is important to reduce economic dependence and environmental impacts of a petroleum-based economy. Microorganisms are essential in several industrial bioprocesses nowadays, and it is expected that new microbial bioprocesses will play a key role in biorefineries. However, the bioconversion process requires a robust and highly productive microorganism. In this scenario, several strategies to genetically improve microorganisms to overcome the bioprocesses challenges have been considered. In this work, we review microorganisms importance in the biorefineries concept, highlight the desirable traits they must hold in order to be employed, and discuss the main strategies to improve such traits. The focuses of this work are on four main targets in the improvement of microorganisms: driving carbon flux towards the desired pathway, increasing tolerance to toxic compounds, increasing substrate uptake range and new products generation.

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The transcriptional activator GaaR of Aspergillus niger is required for release and utilization of d‐galacturonic acid from pectin

et al. 2016

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We identified the d‐galacturonic acid (GA)‐responsive transcriptional activator GaaR of the saprotrophic fungus, Aspergillus niger, which was found to be essential for growth on GA and polygalacturonic acid (PGA). Growth of the ΔgaaR strain was reduced on complex pectins. Genome‐wide expression analysis showed that GaaR is required for the expression of genes necessary to release GA from PGA and more complex pectins, to transport GA into the cell, and to induce the GA catabolic pathway. Residual growth of ΔgaaR on complex pectins is likely due to the expression of pectinases acting on rhamnogalacturonan and subsequent metabolism of the monosaccharides other than GA.

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Metabolic Engineering of Fungal Strains for Conversion of d -Galacturonate to meso -Galactarate

Cited by 63 publications

References 21 publications

Engineering Filamentous Fungi for Conversion of d -Galacturonic Acid to l -Galactonic Acid

Engineering Filamentous Fungi for Conversion of d -Galacturonic Acid to l -Galactonic Acid

Genetic improvement of microorganisms for applications in biorefineries

The transcriptional activator GaaR of Aspergillus niger is required for release and utilization of d‐galacturonic acid from pectin

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