Degradation of phytate by Pichia kudriavzevii TY13 and Hanseniaspora guilliermondii TY14 in Tanzanian togwa.

The fermented cereal-based gruel togwa is used as weaning food for children in Tanzania. Togwa is rich in minerals but these are often not available for uptake in the human intestine due to natural inhibitors, such as phytate (IP(6)). The yeasts Pichia kudriavzevii TY13, Hanseniaspora guilliermondii TY14 and TY20, isolated from Tanzanian togwa, and selected for high phytase activity in complex yeast medium YPD, were now studied regarding their ability to degrade IP(6) in maize-based model togwa. A modified constitutively high-phytase producing Saccharomyces cerevisiae BY80 and commercial Aspergillus ficuum phytase were included for comparison. In addition, a strain of Lactobacillus plantarum was included in the model-togwa set-up. All yeasts in the study grew and reached final cell density 1.5-2 log units higher than the start value. S. cerevisiae BY80 degraded 85% of the IP(6) in 48 h; the same degradation level as with A. ficuum phytase (89%). Of the togwa-isolated yeasts, P. kudriavzevii TY13 and H. guilliermondii TY14 showed strong phytate degradation in the model-togwa; 95% or more of the initial IP(6) was degraded after 48 h. This corresponds to a remaining level of 0.4 and 0.3µmol IP(6)/g dw. Co-inoculation with L. plantarum did not increase IP(6) degradation. Moreover, fermentation with P. kudriavzevii TY13 yielded a successive increase in inorganic phosphate (P(i)), from 0.7 to 5.4 mM, suggesting a phytase production in TY13 which is fairly insensitive to P(i) repression. The study shows that phytate in a model togwa is available for yeast phytase enzymes, and addresses the importance of strain selection for effectively degrading the phytate. Certain yeasts originating from togwa seem to have developed a natural high phytase production, and P. kudriavzevii TY13 and H. guilliermondii TY14 seem particularly well adapted to phytate degradation in togwa, and is our choice for further studies and strain improvement.

Biodiversity and phytase capacity of yeasts isolated from Tanzanian togwa.

The focus of the present investigation was on the Tanzanian fermented food togwa as a source for dietary iron and zinc, and the potential for mineral availability improvements using selected yeasts. To establish the content of target minerals and main inhibitor for intestinal uptake, iron and zinc as well as the mineral chelating phytic acid, (IP(6) or phytate) were determined in naturally fermented togwa. Yeasts were isolated from sorghum, maize and cassava based togwa, and identified by sequencing the D1/D2 region of the LSU rRNA gene. The isolated yeasts were subsequently screened for phytase activity. The total iron content in sorghum, maize and cassava based togwa were 41.5 (+/-7.2), 85.4 (+/-31.9) and 28.6 (+/-3.8) microg/g dw (dry weight) respectively. The zinc content was 12.3 (+/-3.1), 11.0 (+/-1.1) and 6.4 (+/-4.5) microg/g dw in sorghum, maize and cassava based togwa, and the phytate content in the three varieties were 2.6+/-1.2, 4.7+/-0.8 and 0.4+/-0.4 micromol/g dw respectively. The phytate levels in the sorghum and maize based togwa are expected to substantially reduce the availability of iron. The molar ratio phytate to iron for these two varieties were estimated to be 3.5:1 and 3.1:1 respectively. In general, a phytate to iron molar ratio below 1 is needed to increase the availability of iron. Among 26 isolates, 9 different species could be distinguished: Issatchenkia orientalis, Pichia anomala, Pichia norvegensis, Pichia burtonii, Pichia guilliermondii, Kluyveromyces marxianus, Saccharomyces cerevisiae, Hanseniaspora guilliermondii and Candida glabrata. The strains were screened for phytase activity in YPD supplemented with 0.5 mM IP(6). Of 26 screened strains, the phytase activity was most prominent in strains of I. orientalis and H. guilliermondii. The strains and data constitute a basis for further improvements of iron and zinc bioavailability in togwa.

Production of folates by yeasts in Tanzanian fermented togwa.

We have investigated the impact of different yeasts and fermentation time on folate content and composition in a fermented maize-based porridge, called togwa, consumed in rural areas in Tanzania. The yeasts studied, originally isolated from indigenous togwa, belong to Issatchenkia orientalis, Pichia anomala, Saccharomyces cerevisiae, Klyveromyces marxianus and Candida glabrata. The main folate forms found, detected and quantified by HPLC during the fermentations were 5-methyl-tetrahydrofolate (5-CH(3)-H(4)folate) and tetrahydrofolate (H(4)folate). The content of H(4)folate, per unit togwa, remained fairly stable at a low level throughout the experiment for all strains, whereas the 5-CH(3)-H(4)folate concentration was highly dependent on yeast strain as well as on fermentation time. The highest folate concentration was found after 46 h of fermentation with C. glabrata (TY26) (6.91+/-0.14 microg 100 mL(-1)), corresponding to a 23-fold increase compared with unfermented togwa. The cell concentration per se could not predict the togwa folate level, as shown by the much higher specific folate content (g folate CFU(-1)) in the S. cerevisiae strain (TY08) compared with the other species tested. This study provides useful data when trying to maximize folate content in togwa as well as in other yeast-fermented products.

Development of a simplified method for the determination of folates in baker's yeast by HPLC with ultraviolet and fluorescence detection.

A simplified HPLC method for rapid determination of folates in yeast with ultraviolet and fluorescence detection without sample purification has been developed. By use of the column Aquasil C(18), specially designed for polar analytes, and gradient elution, it was possible to separate and determine five folate derivatives: tetrahydrofolate, 5-methyltetrahydrofolate, and 5-formyltetrahydrofolate with fluorescence detection, and 10-formylfolic acid and folic acid with ultraviolet detection. The sample preparation required only a small amount of dry yeast (25-50 mg) and included an extraction of folates by heat treatment and deconjugation of folate polyglutamates to monoglutamates with the use of rat serum conjugase. Validation involved investigation of matrix effects, determination of recovery by standard addition method, repeatability, and stability tests. The dominating folate forms in commercial dry baker's yeast were found to be tetrahydrafolate and 5-methyltetrahydrofolate with a total folate content of 2890 microg/100 g (63.4 nmol/g). The simplicity of the method makes it suitable for folate screening studies of different yeast strains.

Metabolism of extracellular inositol hexaphosphate (phytate) by Saccharomyces cerevisiae.

Iron and zinc deficiencies are global problems, frequently leading to severe illness in vulnerable human populations. Addition of phytases can improve the bioavailability of iron and zinc in food. Saccharomyces cerevisiae would be an ideal candidate as a bioavailability improving food additive if it demonstrates significant phytase activity. The purpose of the paper was to study yeast phytase activity to obtain information required to improve strains. All yeasts tested readily degraded extracellular inositol hexaphosphate (phytate; IP6) in media with IP6 as the sole phosphorous source. Phosphate (Pi) addition yielded repression consistent with the PHO system. However, repression of IP6-degrading enzymes was not only dependent on level of Pi, but also on pH and medium composition. In complex medium, containing Pi at a concentration previously suggested to yield full repression of the secretory acid phosphatases (SAPs; e.g., [Mol. Biol. Cell 11 (2000) 4309]), and at relatively high pH, repression of phytate-degrading enzymes was weak. The capacity to degrade phytate, irrespective of Pi addition or not, was highest at the pH most distant from the pH optimum of the SAPs [Microbiol. Res. 151 (1996) 291], suggesting that expression rather than enzyme activity was affected by pH. In synthetic medium, repression was strong and pH-independent (no IP6 degradation within the range tested). The distinct difference between media shows that, in addition to known regulatory role of Pi for the PHO system, additional factors may be involved. Using a deletion strain, we further demonstrate that the main secretory acid phosphatase Pho5p is not essential for intact phytate-degrading capacity and growth without Pi, neither is Pho3p. However, when constitutively overexpressing PHO5 an increased net phytase activity was obtained, in repressing and non-repressing conditions. This proves that, although redundant in a wild type, Pho5p can catalyze hydrolysis of IP6 and that at least one more enzyme is capable of effective hydrolysis of IP6 (sufficient to provide the cell with phosphorous at a rate yielding maximum growth). Finally, a bread dough experiment showed that the typical concentrations of Pi during leavening exceed levels shown to repress phytate degradation by a wild-type S. cerevisiae.