Isolation and identification of milk-clotting proteases from Prinsepia utilis Royle and its application in cheese processing.

The aim of this study was to isolate and identify the main milk-clotting proteases from Prinsepia utilis Royle. Protein isolates obtained using precipitation with 20 %-50 % ammonium sulfate (AS) showed higher milk-clotting activity (MCA) at 154.34 + 0.35 SU. Two milk-clotting proteases, namely P191 and P1831, with molecular weight of 49.665 kDa and 68.737 kDa, respectively, were isolated and identified using liquid chromatography-mass spectrometry (LC-MS/MS). Bioinformatic analysis showed that the two identified milk-clotting proteases were primarily involved in hydrolase activity and catabolic processes. Moreover, secondary structure analysis showed that P191 structurally consisted of 40.85 % of alpha-helices, 15.96 % of beta-strands, and 43.19 % of coiled coil motifs, whereas P1831 consisted of 70 % of alpha-helices, 7.5 % of beta-strands, and 22.5 % of coiled coil motifs. P191 and P1831 were shown to belong to the aspartic protease and metalloproteinase types, and exhibited stability within the pH range of 4-6 and good thermal stability at 30-80 °C. The addition of CaCl2 (<200 mg/L) increased the MCA of P191 and P1831, while the addition of NaCl (>3 mg/mL) inhibited their MCA. Moreover, P191 and P1831 preferably hydrolyzed kappa-casein, followed by alpha-casein, and to a lesser extent beta-casein. Additionally, cheese processed with the simultaneous use of the two proteases isolated in the present study exhibited good sensory properties, higher protein content, and denser microstructure compared with cheese processed using papaya rennet or calf rennet. These findings unveil the characteristics of two proteases isolated from P. utilis, their milk-clotting properties, and potential application in the cheese-making industry.

Identification, structure, and caseinolytic properties of milk-clotting proteases from Moringa oleifera flowers.

The protein extract of Moringa oleifera flowers is reported to have milk-clotting activity (MCA), but information regarding its protease is unclear. In this study, two milk-clotting proteases (MoFP 12 and MoFP 13) with molecular weights of 42.304 kDa and 31.741 kDa, respectively, were isolated and identified from M. oleifera flowers using liquid chromatography-mass spectrometry (LC-MS/MS). Bioinformatics analysis showed that these two milk-clotting proteases were primarily involved in hydrolase activity and catabolic process, and exhibited hydrophilicity. The secondary structure of MoFP 12 consisted of 43.65% helix, 13.23% strand, and 43.12% coil, and MoFP 13 consisted of 26.51% helix, 20.14% strand, and 53.35% coil. The proteases were stable in the pH range of 5.0 to 8.0 and showed their maximum MCA at 70℃. Additionally, by investigating the effect of proteases on caseins, κ-casein (CN) was observed to preferentially be hydrolyzed by the two proteases, followed by α-CN, and to a lesser extent ß-CN. These findings revealed the main milk-clotting proteases in M. oleifera flowers and its milk-clotting properties, indicating its potential for application in the dairy and food sectors, especially in the cheese-making industry.