Susann Mende

Exopolysaccharide production by three different strains of Streptococcus thermophilus and its effect on physical properties of acidified milk

Physical and rheological properties of commercial low‐fat yogurt and of skim milk acidified with single strains of Streptococcus thermophilus were evaluated. Concentration of exopolysaccharides (EPS) varied from 40 to 168 mg glucose equivalents per liter, and EPS showed different degrees of ropiness. Further characterization of nonropy and ropy EPS from three S. thermophilus strains revealed intrinsic viscosity of 0.13–0.66 mL/mg, respectively, which had a significant impact on apparent viscosity and the ability of regaining structure after shearing. Compared with regular milk acidification, batch fermentation with supplemented skim milk at constant pH resulted in a strain‐dependent increase of EPS yield by a factor of 4–7.

Growth and exopolysaccharide yield of Lactobacillus delbrueckii ssp. bulgaricus DSM 20081 in batch and continuous bioreactor experiments at constant pH

Some Lactobacillus delbrueckii ssp. bulgaricus strains are able to synthesize exopolysaccharides (EPS) and are therefore highly important for the dairy industry as starter cultures. The aim of this study was to investigate the nutritional requirements for growth and EPS production of Lactobacillus delbrueckii ssp. bulgaricus DSM 20081. A medium was developed from a semi-defined medium (SDM) in which glucose was replaced by lactose and different combinations of supplements (nucleobases, vitamins, salts, sodium formate and orotic acid) were added. Constant pH batch fermentation with the modified medium resulted in an EPS yield of approximately 210 mg glucose equivalents per liter medium. This was a 10-fold increase over flask cultivation of this strain in SDM. Although not affecting cell growth, the mixture of salts enhanced the EPS synthesis. Whereas EPS production was approximately 12 mg/g dry biomass without salt supplementation, a significantly higher yield (approximately 20 mg/g dry biomass) was observed after adding the salt mixture. In continuous fermentation, a maximal EPS concentration was obtained at a dilution rate of 0.31/h (80 mg EPS/L), which corresponded to a specific EPS production of 49 mg/g dry biomass.

Concentration dependent effects of dextran on the physical properties of acid milk gels.

The effect of dextran from Leuconostoc mesenteroides (DEX500), added to milk prior to acidification with glucono-δ-lactone (GDL) or Streptococcus thermophilus DSM20259, was studied with respect to polysaccharide concentration. The incorporation of 5-30 g/kg DEX500 significantly affected gelation behavior. Increasing DEX500 concentrations resulted in a linear increase of gel stiffness (GDL gels: R(2)=0.96; microbial acidification: R(2)=0.94; P<0.05) and 30 g/kg DEX500 resulted in a 2-fold higher stiffness compared to gels without polysaccharide. The respective stirred gels depicted a significant reduction in syneresis, which decreased from 30.4% (0 g/kg DEX500) to 22.0% (30 g/kg DEX500) for chemically acidified gels after 1 d of storage. Physical characteristics of DEX500 in aqueous solution were helpful to explain its behavior in the complex system milk.

Model Studies on Protein Glycation

Mixtures of Nα‐hippurylarginin, Nα‐hippuryllysine, and glyoxal were incubated in the absence and presence of Nα‐acetylcysteine in order to assess the individual reactivity of these nucleophilic amino acid residues. The incubations were performed under atmospheric and high hydrostatic pressure (400 MPa), and, at the same time, β‐casein was reacted with glyoxal. The results showed that arginine is the main partner for glyoxal in the absence of cysteine, whereas a lysine derivatization was not apparent. In the presence of cysteine, however, arginine was almost completely protected from the reaction, whereas a noticeable formation of lysine derivatives, mainly carboxymethyllysine, was observed. Based on these findings, a reaction mechanism is proposed to explain the influence of cysteine on the reaction.

Shear treatment of starter culture medium improves separation behavior of Streptococcus thermophilus cells

A central step in the production of starter cultures is the separation of the cells from the fermentation medium, which is usually achieved by disk centrifuges. In case of microorganisms which produce exopolysaccharides (e.g., various strains of lactic acid bacteria), the properties of the respective exopolysaccharides may interfere with this separation step. By using six strains of Streptococcus thermophilus the hypothesis was tested that a shear treatment of the fermented culture medium improves subsequent cell separation markedly. Depending on the type of exopolysaccharides (freely present in the medium, or as capsules around the cells) an energy input of up to 2.5 kJ/mL generated with an Ultra‐Turrax affected cell chain length of the strains and viscosity of fermentation medium differently. For bacteria producing capsular exopolysaccharides, space‐ and time‐resolved centrifugation experiments revealed an increase of sedimentation velocity after shear treatment. In general, viability of the microorganisms, detected by flow cytometry measurements and fermentation experiments, was not affected by the shearing procedure. The results therefore indicate that strain‐targeted shearing is helpful to improve the separability of cells from the fermented media.