Nina Q. Meinander scite author profile

The influence of the factors acetic acid, furfural, and p-hydroxybenzoic acid on the ethanol yield (Y EtOH) of Saccharomyces cerevisiae, bakers' yeast, S. cerevisiae ATCC 96581, and Candida shehatae NJ 23 was investigated using a 2 3-full factorial design with 3 centrepoints. The results indicated that acetic acid inhibited the fermentation by C. shehatae NJ 23 markedly more than by bakers' yeast, whereas no significant difference in tolerance towards the compounds was detected between the S. cerevisiae strains. Furfural (2 g L −1) and the lignin derived compound p-hydroxybenzoic acid (2 g L −1) did not affect any of the yeasts at the cell mass concentration used. The results indicated that the linear model was not adequate to describe the experimental data (the p-values of curvatures were 0.048 for NJ 23 and 0.091 for bakers' yeast). Based on the results from the 2 3-full factorial experiment , an extended experiment was designed based on a central composite design to investigate the influence of the factors on the specific growth rate (µ), bio-mass yield (Y x), volumetric ethanol productivity (Q EtOH), and Y EtOH. Bakers' yeast was chosen in the extended experiment due to its better tolerance towards acetic acid, which makes it a more interesting organism for use in industrial fermentations of lignocellulosic hydrolysates. The inoculum size was reduced in the extended experiment to reduce any increase in inhibitor tolerance that might be due to a large cell inoculum. By dividing the experiment in blocks containing fermentations performed with the same inoculum preparation on the same day, much of the anticipated systematic variation between the experiments was separated from the experimental error. The results of the fitted model can be sum-marised as follows: µ was decreased by furfural (0-3 g L − 1). Furfural and acetic acid (0-10 g L − 1) also interacted negatively on µ. Furfural concentrations up to 2 g L −1 stimulated Y x in the absence of acetic acid whereas higher concentrations decreased Y x. The two compounds interacted negatively on Y x and Y EtOH. Acetic acid concentrations up to 9 g L −1 stimulated Q EtOH , whereas furfural (0-3 g L −1) decreased Q EtOH. Acetic acid in concentrations up to 10 g L −1 stimulated Y EtOH in the absence of furfural, and furfural (0-2 g L −1) slightly increased Y EtOH in the absence of acetic acid whereas higher concentrations caused inhibition. Acetic acid and furfural interacted negatively on Y EtOH .

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Fermentation strategies for improved heterologous expression of laccase in Pichia pastoris

Hong

Meinander

Jönsson

2002

Biotech & Bioengineering

199

104

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Improved expression of recombinant laccase by Pichia pastoris carrying the lcc1 cDNA isolated from Trametes versicolor was achieved by optimization of the cultivation conditions in a fermentor equipped with a methanol sensor system. The results indicated that the activity obtained in fermentor cultivations was at least 7 times higher than in shake-flask cultures. Three different strategies for fermentor cultivations were compared: A (30 degrees C, 1.0% methanol), B (20 degrees C, 1.0% methanol), and C (20 degrees C, 0.5% methanol). The laccase activity, particularly the specific activity, could be improved by decreasing the cultivation temperature. The mechanisms behind the temperature effect on the laccase activity may be ascribed to poor stability, release of more proteases from dead cells, and folding problems at higher temperature. The results showed that the methanol concentration had a marked effect on the production of active heterologous laccase. A fivefold higher volumetric laccase activity was obtained when the methanol concentration was kept at 0.5% instead of 1.0%. The detrimental effect of methanol on the production of recombinant laccase may be attributed to lower laccase stability, a higher proteolytic activity, and folding problems due to higher growth rate at 1.0% methanol.

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Main and interaction effects of acetic acid, furfural, andp-hydroxybenzoic acid on growth and ethanol productivity of yeasts

Palmqvist

Grage

Meinander

et al. 1999

Biotechnol. Bioeng.

365

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Fermentation of xylose/glucose mixtures by metabolically engineered Saccharomyces cerevisiae strains expressing XYL1 and XYL2 from Pichia stipitis with and without overexpression of TAL1

Meinander

Boels

Hahn‐Hägerdal

1999

Bioresource Technology

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Novel conserved hydrolase domain in the CLCA family of alleged calcium‐activated chloride channels

et al. 2006

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Advanced protein structure prediction methods combined with structure modeling show that the mammalian proteins, described until now as calcium-activated chloride channels (CLCAs), appear in fact to be membrane anchored metal-dependent hydrolases, possibly proteases. A metallohydrolase structural domain was predicted, unexpectedly, in the CLCA sequences. The well-conserved active site in the modeled structure of this hydrolase domain allows the prediction of catalytic action similar to that of metalloproteases. A number of protein structure prediction methods suggest the overall fold of the N-terminal hydrolase domain to be most similar to that of zinc metalloproteases (zincins), notably matrixins. This is confirmed by analysis of the three-dimensional structure model of the predicted CLCA1 hydrolase domain built using the known structure of the MMP-11 catalytic domain. Fragments of CLCA1 corresponding to the modeled hydrolase domain were expressed in Escherichia coli, and the resulting proteins were readily refolded into monomeric soluble protein, indicating formation of stable independent domains. The homology model was used to predict putative substrate sequences. Homologs of mammalian CLCA genes were detected in the genomes of a vast array of multicellular animals: lower vertebrates, tunicates, insects, crustaceans, echinoderms, and flatworms. The hydrolase prediction is discussed in the context of published experimentally determined effects of CLCA proteins on chloride conductance. Altered proteolytic processing of full-length CLCA1 containing a mutation abolishing the predicted hydrolase activity is shown as initial experimental evidence for a role of the hydrolase domain in processing of mature full-length CLCA1. The hydrolase prediction together with the presented experimental data add to doubts about the function of CLCAs as chloride channels and strengthen the hypothesis of channel-activating and/or channel-accessory roles.

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Nina Q. Meinander

Main and interaction effects of acetic acid, furfural, and p‐hydroxybenzoic acid on growth and ethanol productivity of yeasts

Fermentation strategies for improved heterologous expression of laccase in Pichia pastoris

Main and interaction effects of acetic acid, furfural, andp-hydroxybenzoic acid on growth and ethanol productivity of yeasts

Fermentation of xylose/glucose mixtures by metabolically engineered Saccharomyces cerevisiae strains expressing XYL1 and XYL2 from Pichia stipitis with and without overexpression of TAL1

Novel conserved hydrolase domain in the CLCA family of alleged calcium‐activated chloride channels

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