Accelerating cheese proteolysis by enriching Lactococcus lactis proteolytic system with lactobacilli peptidases

Abstract

The knowledge available on the genetics and proteolytic system of lactic acid bacteria makes it possible to genetically engineer starters with increased proteolytic properties. Our objective was to identify the best available strains capable of accelerating or modulating casein proteolysis during cheese ripening. To attain this goal, we used Lactococcus lactis strains expressing 5 different Lactobacillus peptidases to ripen a cheese model. At the end of ripening, free amino acids were quantitatively and qualitatively analysed. We identified the mixture of prolidase, PepQ, and X-prolyl dipeptidyl peptidase, PepX, as well as the peptidase PepW as the most efficient peptidases to increase, up to 3-fold, the overall level of amino acids at the end of ripening. The levels of threonine, asparagine, glycine, methionine, valine, glutamine, isoleucine and proline in particular increased (more than 3.5 fold). Grouping the amino acids produced according to the specific aroma compounds that each may give rise to following an enzymatic or chemical conversion, revealed that expression of PepW or PepX and PepQ increased the amounts of all groups of amino acids while expression of PepQ or PepN increased more especially those of aromatic amino acids/proline and glutamic acid, respectively. The combination of increased proteolysis and conversion of amino acids into aroma compounds now needs to be tested. In addition, the role of proline and its derived compounds in the overall flavour of cheese should be investigated.