Modeling peptide formation during the hydrolysis of β-casein by Lactococcus lactis

► Quantitative analysis of peptide dynamics during protein hydrolysis. ► Hybrid model to describe kinetics of formation and breakdown of peptides. ► Identification of pools of peptides with similar dynamics. ► Connection between kinetics of low and high molecular weight peptides. Hydrolysis of milk...

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Bibliographic Details
Published in:Process biochemistry (1991) 2012, Vol.47 (1), p.83-93
Main Authors: Muñoz-Tamayo, Rafael, de Groot, Jolan, Wierenga, Peter A., Gruppen, Harry, Zwietering, Marcel H., Sijtsma, Lolke
Format: Article
Language:English
Subjects:
beta-casein
degradation
Hybrid model
hydrolysis
identification
Kinetics
Lactic acid bacteria
Lactococcus lactis
Life Sciences
micelles
molecular weight
peptides
proteinases
proteins
Proteolysis
stoichiometry
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Summary:► Quantitative analysis of peptide dynamics during protein hydrolysis. ► Hybrid model to describe kinetics of formation and breakdown of peptides. ► Identification of pools of peptides with similar dynamics. ► Connection between kinetics of low and high molecular weight peptides. Hydrolysis of milk proteins by lactic acid bacteria leads to the formation of a large number of peptides. In this work, the hydrolysis of β-casein by the protease PrtP I of Lactococcus lactis was studied. Experiments were carried out at different initial enzyme/substrate ratios. Identification and quantification of peptides were performed by MS and RP-UHPLC analyses. Nine low molecular weight (LMW) peptides were quantified absolutely. Additionally, semi-quantification of six high molecular weight peptides (HMW) was provided. To describe the dynamics of peptides concentrations, an aggregated model was developed. This model links peptide formation to the breakdown of intact protein by introducing the concept of virtual intermediate peptides (VIP). The model represented the experimental data with an average error of 14% (comparable with the experimental error). By using the model, three dynamic pools of peptides were identified. The model suggests that LMW peptides have similar dynamic characteristics as their counterpart HMW peptides in the β-casein sequence. This study indicates that the presence and structure of micelles affect the hydrolysis dynamics and that, for some peptides, the enzyme/substrate ratio appears to affect the hydrolysis stoichiometry. The model developed is parsimonious and has a basic mechanistic component. It allows for a rational study of protein hydrolysis.
ISSN:1359-5113
1873-3298
DOI:10.1016/j.procbio.2011.10.012