Abstract
Calcium- and protein-rich fermented milk products, such as concentrated yoghurts and fresh cheeses, may contain undesired bitter peptides, which are generated by the proteolytic cleavage of casein. Up to now, it is not clear whether this process is caused by endogenous milk enzymes, such as plasmin and cathepsin D, or whether proteolytic enzymes from applied starter cultures, such as the lactococcal cell-envelope peptidase PrtP, are involved. A sensory analysis of fresh cheese products made from milk concentrates fermented with prtP-negative and -positive Lactococcus lactis strains revealed bitterness in the products fermented with prtP-positive L. lactis strains. Two prtP-positive strains, LTH 7122 and LTH 7123, were selected to investigate the effect of increased calcium concentrations (additional 5 mM and 50 mM CaCl2) at neutral (pH 6.6) and acidic (pH 5.5) pH-values on the transcription of the prtP gene and its corresponding PrtP peptidase activity in milk citrate broth (MCB). For both strains, it was shown that prtP transcription was upregulated only under slightly elevated calcium conditions (5 mM CaCl2) after 5 h of growth. In concordance with these findings, PrtP peptidase activity also increased. When higher concentrations of calcium were used (50 mM), prtP expression of both strains decreased strongly by more than 50%. Moreover, PrtP peptidase activity of strain LTH 7123 decreased by 15%, but enzymatic activity of strain LTH 7122 increased slightly during growth under elevated calcium concentrations (50 mM CaCl2). Fermentations of reconstituted casein medium with 3.4% (w/v) and 8.5% (w/v) protein and different calcium concentrations using strain LTH 7122 revealed no clear relationship between prtP transcription and calcium or protein concentration. However, an increase in PrtP peptidase activity under elevated protein and calcium conditions was observed. The activity increase was accompanied by increased levels of bitter peptides derived from different casein fractions. These findings could be a possible explanation for the bitterness in fermented milk concentrates that was detected by a trained bitter panel.
Highlights
The production of fermented milk products, such as curd cheese, strained (Greek-style) yogurt, or different types of fresh cheese, generates acid whey
A sensory analysis of fresh cheese products made from milk concentrates fermented with prtP-negative and -positive Lactococcus lactis strains revealed bitterness in the products fermented with prtP-positive L. lactis strains
In order to produce fresh cheese (CoF) samples with prtP-positive and prtP-negative L. lactis strains for sensory evaluation, reconstituted casein medium with initial pH-values in a range of 6.6 to 6.8 were fermented until pH-values of 4.7 to 5.5 were reached (Table 2)
Summary
The production of fermented milk products, such as curd cheese, strained (Greek-style) yogurt, or different types of fresh cheese, generates acid whey. Due to its high content of lactic acid, insoluble whey proteins, minerals such as calcium, enzymes, microorganisms and their metabolites, acid whey is difficult to process [1,2,3,4,5]. To cope with the increasing interest in fermented milk products containing a high protein content (>8%), such as Skyr or strained yogurt, and to bypass issues regarding acid whey, fermentation of calcium-rich concentrated milk, yielding a precious neutral “ideal whey” or permeate instead, seems to be an interesting alternative. The elevated protein and calcium content of concentrated milk, when used for fermentation, may alter the proteolytic activities of either milk-endogenous peptidases or those produced by the bacterial starter cultures [6]
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