Regulation of intracellular formaldehyde toxicity during methanol metabolism of the methylotrophic yeast Pichia methanolica.

In this study we found that the methylotrophic yeast Pichia methanolica showed impaired growth on high methanol medium (>5%, or 1.56 M, methanol). In contrast, P. methanolica grew well on glucose medium containing 5% methanol, but the growth defects reappeared on glucose medium supplemented with 5 mM formaldehyde. During methanol growth of P. methanolica, formaldehyde accumulated in the medium up to 0.3 mM before it was consumed rapidly based on cell growth. These findings indicate that the growth defect of P. methanolica on high methanol media is not caused directly by methanol toxicity, but rather by formaldehyde, which is a key toxic intermediate of methanol metabolism. Moreover, during methanol growth of P. methanolica, expression of enzymes in the methanol-oxidation pathway were induced before the alcohol oxidase isozymes Mod1p and Mod2p, and Mod1p expression was induced before Mod2p. These results suggest that to avoid excess accumulation of formaldehyde-the toxic intermediate of methanol metabolism-P. methanolica grown on methanol strictly regulates the order in which methanol-metabolizing enzymes are expressed.

Reliable enzyme-linked immunosorbent assay for the determination of coconut milk proteins in processed foods.

This study was designed to develop a novel sandwich enzyme-linked immunosorbent assay (ELISA) for the detection and quantification of coconut milk proteins in processed foods. The developed sandwich ELISA was able to detect coconut milk proteins from various coconut milk products and did not show any cross-reactivity with 41 of 42 kinds of popularly used food ingredients, thus reflecting great specificity for coconut milk proteins. In addition, the established ELISA is highly sensitive and allowed the detection of 0.31 µg/g of coconut milk protein in complex food matrices. This proposed assay could serve as a useful tool for the detection of the presence of hidden coconut milk proteins in processed foods.

Novel ELISA for the detection of raw and processed egg using extraction buffer containing a surfactant and a reducing agent.

Enzyme-linked immunosorbent assay (ELISA) has been considered extremely useful for the detection of markers of allergenic substances in food, because it is simple, offers a suitable sensitivity, and is useful in providing quantitative results. Allergenic protein present in processed food can be denatured or altered, hindering therefore their possibility to be extracted and detected. This paper reports the development of an ELISA method that can be used for the determination of allergenic proteins in buffer solutions containing SDS, a surfactant, and 2-mercaptoethanol, a reducing agent. Measurement by ELISA in solutions containing 1% SDS and 7% 2-mercaptoethanol has been made possible by using an antibody prepared through immunization with an antigen denatured with SDS and 2-mercaptoethanol. This ELISA technique can be used to measure proteins in food that have been denatured by various manufacturing processes. An example is egg white albumin, which is susceptible to heat denaturation and has been difficult to recover from food in the past. Its recovery was improved 10- to 100-fold by the new ELISA method as compared with previous methods. This means that allergenic substances in food can now be detected quantitatively. This method can be very useful in allergy prevention and control strategies.

Molecular characterization of the glutathione-dependent formaldehyde dehydrogenase gene FLD1 from the methylotrophic yeast Pichia methanolica.

In this paper, we describe molecular characterization of the FLD1 gene, which encodes glutathione-dependent formaldehyde dehydrogenase (FLD), from the methylotrophic yeast Pichia methanolica. The P. methanolica FLD1 gene contains two exons corresponding to a gene product of 380 amino acid residues and a 225 bp intron, respectively, and its deduced amino acid sequence shows high similarity to those of Fld1ps from other methylotrophic yeasts (80-88%). In P. methanolica, FLD activity is mainly induced by methanol, and this induction is not completely repressed by glucose. Moreover, the expression of the PmFLD1 is strictly regulated, mainly at the mRNA level, its expression increasing with increasing methanol concentrations in the medium. These results suggest that FLD1 is involved in the detoxification of formaldehyde in methanol metabolism, and Fld1p coordinates the formaldehyde level in methanol-grown cells according to the methanol concentration on growth.

Physiological role of the second alcohol oxidase gene MOD2 in the methylotrophic growth of Pichia methanolica.

The methylotrophic yeast Pichia methanolica has nine multiple alcohol oxidase (AOD) isozymes, which can be detected on native electrophoretic polyacrylamide gel and are encoded by two genes, MOD1 and MOD2. The aim of this work is to reveal the physiological roles of these AOD subunits, especially that of Mod2p, encoded by the second AOD-encoding gene, MOD2. A strain expressing only MOD2 showed severe growth inhibition with a low concentration of methanol (0.1%), but its growth was restored with an increase in the methanol concentration (up to 3%). The expression of MOD2 using the CbAOD1 promoter in the Candida boidinii alcohol oxidase-depleted strain was more advantageous for methylotrophic growth with high methanol concentrations than that of MOD1. The expression of MOD2 was not observed under derepression conditions (0% methanol), and the expression level increased with an increase in the methanol concentration used for induction. The expression of MOD1 was observed under derepression conditions and was rather constant throughout the tested methanol concentration range. Therefore, the ratio of Mod2p to Mod1p in an active AOD octamer was proved to be mainly controlled by changes in the MOD2 mRNA level. These and other results show that Mod2p is a unique AOD subunit more adapted to methylotrophic growth with high methanol concentrations (3%) than Mod1p.