In this study, the chemical composition, proteolysis and in vitro angiotensin-converting enzyme-(ACE)-inhibitory and antioxidant activities of white cheeses made using probiotic adjunct cultures (Bifidobacterium bifidum DSMZ 20456 and Lactobacillus acidophilus DSMZ 20079) were investigated. The cheeses were ripened in a vacuum package or brine for 120 d at 4 °C. The cheese samples maintained the probiotic characteristics of the viable cells as >106 cfu/g even after ripening for 120 d. The proteolysis degrees in terms of water-soluble nitrogen/total nitrogen (WSN/TN), trichloroacetic acid-soluble nitrogen/total nitrogen (TCA-SN/TN) and phosphotungstic acid-soluble nitrogen/total nitrogen (PTA-SN/TN) values in the cheeses increased throughout the ripening. The highest levels of proteolysis were found in cheese made using Lb. acidophilus DSMZ 20079 and ripened in a vacuum package. ACE-inhibitory activity of the water soluble extracts (WSEs) of the cheeses increased significantly (P < 0·05) throughout the ripening (IC50 values 82·78–140·99 μg/ml). Use of Lb. acidophilus DSMZ 20079 and packaging under vacuum significantly increased the percentage of ACE inhibiting activity. WSEs had DPPH scavenging activity (the IC50 values were 2·41–5·39 mg/ml and the inhibition values were 5·10–10·38%), increasing up to 60 d ripening. In the present study, it was observed that Lb. acidophilus DSMZ 20079 was more effective than Bifido. bifidum DSMZ 20456 in terms of the cheese characteristics investigated.

This study demonstrated that both chymosin and salt-in-moisture (SM) were important factors for proteolysis in the manufacture of ultrafiltrated white-salted cheese, with significant effects on water-soluble nitrogen and nitrogen soluble in trichloroacetic acid. In contrast, the levels of free amino acids were not significantly affected by chymosin and salt treatments. The cheeses made using high levels of chymosin with low SM had lower levels of residual αs1- and β-casein at the end of ripening. On texture profile analysis, the hardness and fracturability of the cheeses significantly increased with SM and decreased during ripening. Increases in chymosin significantly contributed to the overall weakening of the structure throughout ripening. Bitter flavour was detected after 12 weeks in the cheese made with the higher chymosin level and lower SM, which could be the result of accumulation of γ-casein fractions. The sensory data indicated that the hedonic responses for low chymosin with low SM cheeses were good and acceptable in flavour, which may be due to the moderate levels of proteolysis products.