Laboratory wheat beers were brewed with different wheat varieties of different protein content (8.7-14.4%) and with five different barley malts, varying in degree of modification (soluble protein: 3.9-6.9%). In a first series of experiments, it was investigated whether wheat positively influences the foam stability, a major characteristic of wheat beers. NIBEM and Rudin (CO 2 ) foam analyses revealed that the effect of wheat on foam stability depended on the barley malt used for brewing. When using malt with high foaming potential, wheat exerts a negative influence. However, wheat added to over-modified malt with less foam promoting factors, ameliorates beer foaming characteristics proving that wheat contains foam active compounds. In addition, Rudin (N 2 ) values suggested that wheat positively influences foam stability by decreasing liquid drainage, probably caused by a higher beer viscosity and /or a finer foam bubble size distribution.Furthermore, the haze in wheat beers, which is another important quality characteristic of these beers, was investigated. Permanent haze readings of the 40% wheat beers were lower than 1.5 EBC haze units. For 20% wheat beers, an inverse relation between the permanent haze (9.4-19.3 EBC haze units) and the protein content of the wheat was established. The barley malt used for brewing also influenced permanent haze readings. A positive correlation between the modification degree of the malt and the permanent haze intensity was found. It was concluded that the choice of raw materials for wheat beer brewing considerably influences the visual properties of the beer.
Yeast preoxygenation can confer important advantages to brewery fermentations by means of omitting the need to oxygenate the wort. However, the impact of yeast preoxygenation on yeast metabolism has never been assessed systematically. Therefore, expression analysis was performed of genes that are of importance in oxygen-dependent pathways, oxidative stress response and general stress response during 8 h of preoxygenation. The gene expressions of both the important transcription factors Hap1 and Rox1, involved in oxygen sensing, were mainly increased in the first 3 h, while YAP1 expression, which is involved in the oxidative stress response, increased drastically only in the first 45 min. The results also show that stress-responsive genes (HSP12, SSA3, PAU5, SOD1, SOD2, CTA1 and CTT1) were induced during the process, together with the accumulation of trehalose. The accumulation of ergosterol and unsaturated fatty acids was accompanied by the expression of ERG1, ERG11 and OLE1. Genes involved in respiration (QCR9, COX15, CYC1 and CYC7) also increased during preoxygenation. Yeast viability did not decrease during the process, and the fermentation performance of the yeast reached a maximum after 5 h of preoxygenation. These results suggest that yeast cells acquire a stress response along the preoxygenation period, which makes them more resistant against the stressful conditions of the preoxygenation process and the subsequent fermentation.
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