Dry entrapment of enzymes by epoxy or polyester resins hardened on different solid supports.

Embedding of enzymes was performed with epoxy or polyester resin by mixing in a dried enzyme preparation before polymerization was started. This fast and low-cost immobilization method produced enzymatically active layers on different solid supports. As model enzymes the well-characterized Thermomyces lanuginosus lipase and a new threonine aldolase from Ashbya gossypii were used. It was shown that T. lanuginosus lipase recombinantly expressed in Aspergillus oryzae is a monomeric enzyme with a molecular mass of 34kDa, while A. gossypii threonine aldolase expressed in Escherichia coli is a pyridoxal-5'-phosphate binding homotetramer with a mass of 180kDa. The enzymes were used freeze dried, in four different preparations: freely diffusing, adsorbed on octyl sepharose, as well as cross-linked enzyme aggregates or as suspensions in organic solvent. They were mixed with standard two-component resins and prepared as layers on solid supports made of different materials e.g. metal, glass, polyester. Polymerization led to encapsulated enzyme preparations showing activities comparable to literature values.

A developmental stage of hyphal cells shows riboflavin overproduction instead of sporulation in Ashbya gossypii.

The hemiascomycete Ashbya gossypii develops a mycelium. Nutritional stress leads to its differentiation into sporangia. These generate spores. In parallel, the yellow pigment riboflavin is produced. Intracellularly accumulated riboflavin, made visible as a bright green fluorescence, was observed in only 60% of the hyphal cells. For the remaining 40%, it was unclear whether these cells simply export riboflavin or its biosynthesis remains down-regulated in contrast to the accumulating cells. The approach followed in this work was to convert the hyphae into protoplasts by enzymatic degradation of the cell wall. Afterwards, the protoplasts were sorted by fluorescence-activated cell sorting on the basis of riboflavin accumulation. When a reporter strain expressing lacZ under the control of the most important riboflavin biosynthesis promoter, RIB3, was used, green protoplasts were found to have more than tenfold greater reporter activity than hyaline protoplasts. This was true on the basis of total protein as well as on the basis of hexokinase specific activity, a marker for constitutive expression. These results allow the conclusion that hyphal cells of A. gossypii differ in phenotype regarding riboflavin overproduction and accumulation.

Quantitative turbidity assay for lipolytic enzymes in microtiter plates.

A clearing assay for lipolytic enzymes has been realized in 96-well microtiter plates. A thin layer containing emulsified tributyrin as turbidity-generating substrate was placed on a thicker supporting aqueous layer. Both layers were stabilized by a gel-forming agent. Enzyme addition leads to clearing of the emulsion detected with a standard microtiter plate reader as a decrease of extinction. Dependencies of the signal kinetics on the substrate and enzyme concentrations were studied. For 0.5-1% tributyrin content the reaction rate is not substrate-limited. An initial slope of the signal kinetics is proportional to the lipase activity. A detailed characterization of the assay was performed. Lipolysis of tributyrin was confirmed by glycerol detection. Various gel-forming agents were compared and diffusion conditions in these gels were analyzed. Agar and agarose were found to be the most suitable gel-forming agents, which do not affect enzyme diffusion whereas polyacrylamide gels block lipase diffusion and therefore are not suitable for the assay. The optimized assay prepared from 1% tributyrin emulsion in 2% agar gel was tested with six microbial lipases and porcine pancreatic lipase. The detection limit is 20-60 ng/well which is equivalent to 30 µU/well for T. lanuginosus lipase.

Growth stress triggers riboflavin overproduction in Ashbya gossypii.

The filamentous fungus Ashbya gossypii is used for riboflavin biosynthesis on an industrial scale, but even the wild type displays overproduction. Because riboflavin overproduction was known to start at the transition between growth and stationary phase, it was suspected that overproduction was induced at low growth rates. However, chemostatic cultivations performed at different growth rates did not result in any detectable riboflavin formation. In this study, we report that it was not the final growth rate that triggered riboflavin overproduction but a decline in growth rate. Therefore, continuous fermenter cultivations with dilution rate shifts were performed. Peaks of riboflavin overproduction were observed in the wild type and in a RIB3placZ reporter strain after downshifts in dilution rate. Accumulation of riboflavin correlated with an increased expression of lacZ reporter activity. The step size of the downshifts corresponded to the peak size of riboflavin formation and reporter activity. Expression of further RIB genes encoding riboflavin biosynthetic enzymes was analyzed by RT-PCR. RIB mRNA levels of the ribulose-5-phosphate branch of the divided riboflavin biosynthesis pathway (RIB3, RIB4, and RIB5) were found to increase in the riboflavin production phase, whereas the RIB2 and RIB7 mRNA levels belonging to the GTP branch remained constant. We propose that a decline in growth rate triggers the increased expression of RIB3, RIB4, and RIB5 resulting in riboflavin overproduction. Because although a reduction in oxygen supply, temperature increase or decrease, or salt stress did affect growth, but neither did lead to riboflavin overproduction nor did induce RIB3 reporter expression, we conclude that declining nutrition must be the stress stimulus. Because about half of the cells in the hyphae of Ashbya gossypii did not accumulate riboflavin, the regulatory response on the cellular level can be estimated to be at least twice as great in comparison to what we detected as overall signals.

Alanine : glyoxylate aminotransferase of Saccharomyces cerevisiae-encoding gene AGX1 and metabolic significance.

Alanine : glyoxylate aminotransferase is one of three different enzymes used for glycine synthesis in Saccharomyces cerevisiae. The open reading frame YFL030w (named AGX1 in the following), encoding this enzyme, was identified by comparing enzyme specific activities in knockout strains. While 100% activity was detectable in the parental strain, 2% was found in a YFL030w::kanMX4 strain. The ORF found at that locus was suspected to encode alanine : glyoxylate aminotransferase because its predicted amino acid sequence showed 23% identity to the human homologue. Since the YFL030w::kanMX4 strain showed no glycine auxtrophic phenotype, AGX1 was replaced by KanMX4 in a Delta GLY1 Delta SHM1 Delta SHM2 background. These background mutations, which cause inactivation of threonine aldolase, mitochondrial and cytosolic serine hydroxymethyltransferase, respectively, lead to a conditional glycine auxotrophy. This means that growth is not possible on glucose but on ethanol as the sole carbon source. Additional disruption of AGX1 revealed a complete glycine auxotrophy. Complementation was observed by transformation with a plasmid-encoded AGX1.

Disruption of the SHM2 gene, encoding one of two serine hydroxymethyltransferase isoenzymes, reduces the flux from glycine to serine in Ashbya gossypii.

Riboflavin overproduction in the ascomycete Ashbya gossypii is limited by glycine, a precursor of purine biosynthesis, and therefore an indicator of glycine metabolism. Disruption of the SHM 2 gene, encoding a serine hydroxymethyltransferase, resulted in a significant increase in riboflavin productivity. Determination of the enzyme's specific activity revealed a reduction from 3 m-units/mg of protein to 0.5 m-unit/mg protein. The remaining activity was due to an isoenzyme encoded by SHM 1, which is probably mitochondrial. A hypothesis proposed to account for the enhanced riboflavin overproduction of SHM 2-disrupted mutants was that the flux from glycine to serine was reduced, thus leading to an elevated supply with the riboflavin precursor glycine. Evidence for the correctness of that hypothesis was obtained from (13)C-labelling experiments. When 500 microM 99% [1-(13)C]threonine was fed, more than 50% of the label was detected in C-1 of glycine resulting from threonine aldolase activity. More than 30% labelling determined in C-1 of serine can be explained by serine synthesis via serine hydroxymethyltransferase. Knockout of SHM 1 had no detectable effect on serine labelling, but disruption of SHM 2 led to a decrease in serine (2-5%) and an increase in glycine (59-67%) labelling, indicating a changed carbon flux.

Inhibition of purified isocitrate lyase identified itaconate and oxalate as potential antimetabolites for the riboflavin overproducer Ashbya gossypii.

A specific isocitrate lyase (ICL) activity of 0.17 U (mg protein)-1 was detected in cultures of the riboflavin-producing fungus Ashbya gossypii during growth on soybean oil. Enzyme activity was not detectable during growth on glucose [<0.005 U (mg protein)-1], indicating a regulation. The enzyme was purified 108-fold by means of ammonium sulphate fractionation, gel filtration and cation-exchange chromatography. SDS-PAGE of the purified protein showed a homogeneous band with an M r of 66000. The M r of 254000 determined by gel-filtration chromatography indicated a tetrameric structure of the native protein. The enzyme was found to have a pH optimum for the isocitrate cleavage of 7.0, and the K m for threo-DL-isocitrate was determined as 550 µ. Enzyme activity was Mg2+- dependent. In regulation studies ICL was weakly inhibited by central metabolites. A concentration of 10 mM phosphoenolpyruvate or 6-phosphogluconate revealed a residual activity of more than 40%. On the other hand, oxalate (K i: 4 µM) and itaconate (K i: 170 µM) showed a strong inhibition and may therefore be interesting as antimetabolites.

Correlation of isocitrate lyase activity and riboflavin formation in the riboflavin overproducer Ashbya gossypii.

Isocitrate lyase (ICL) was assayed during batch cultivations of Ashbya gossypii on soybean oil or glucose as carbon source. On soybean oil, a correlation between enzyme activity and riboflavin synthesis was observed. On glucose as carbon source, riboflavin overproduction started in the late growth phase when glucose was exhausted. ICL activity appeared in parallel and reached a maximum of 0.41 U (mg protein)-1. This suggested synthesis of vitamin B2 from the intracellular reserve fat. ICL specific activity correlated with the enzyme concentration detected by specific antibodies. Itaconate, an efficient inhibitor of ICL, was used as an antimetabolite to screen mutants with enhanced ICL activity. Cultivations of an itaconate-resistant mutant on soybean oil revealed a 15% increase in enzyme specific activity and a 25-fold increase in riboflavin yield compared to the wild-type. On the other hand, growth experiments on glucose resulted in an eightfold increase in riboflavin yield but showed a 33% reduction in ICL specific activity compared to the wild-type grown on the same medium. These results support the idea of an ICL bottleneck in the riboflavin overproducer A. gossypii when plant oil is used as the substrate.