Soluble Lactobacillus delbrueckii subsp. bulgaricus 92059 PrtB proteinase derivatives for production of bioactive peptide hydrolysates from casein.

The proteinase-encoding prtB gene of Lactobacillus (Lb.) delbrueckii (d.) subsp. bulgaricus 92059 was cloned and sequenced. Two soluble, secreted, C-terminally His-tagged derivatives were constructed and expressed in Lactococcus lactis by means of the NICE® Expression System. In both obtained derivatives PrtBb and PrtB2, the C-terminal, cell wall-binding domain was deleted. In addition, in derivative PrtB2, the C-terminal part of the B domain was deleted and the signal sequence was replaced by a lactococcal export signal. The affinity-purified derivatives were both proteolytically active. Peptide hydrolysates produced from casein with each of the derivatives showed identical peptide composition, as determined by liquid chromatography-mass spectrometry. Comparison of the peptides generated to those generated with living Lb. d. subsp. bulgaricus 92059 cells (Kliche et al. Appl Microbiol Biotechnol 101:7621-7633, 2017) showed that ß-casein was the casein fraction most susceptible to hydrolysis and that some significant differences were observed between the products obtained by either the derivatives or living Lb. d. subsp. bulgaricus 92059 cells. When tested for biological activity, the hydrolysate obtained with PrtBb showed 50% inhibition of angiotensin-converting enzyme at a concentration of 0.5 mg/ml and immunomodulation/anti-inflammation in an in vitro assay of TNF-α induced NFκB activation at concentrations of 5 and 2.5 mg/ml, respectively. The enzymatically obtained hydrolysate did not show any pro-inflammatory or cytotoxic activity.

Short communication: Tryptic ß-casein hydrolysate modulates enteric nervous system development in primary culture.

The intestinal tract of the newborn is particularly sensitive to gastrointestinal disorders, such as infantile diarrhea or necrotizing colitis. Perinatal development of the gut also encompasses the maturation of the enteric nervous system (ENS), a main regulator of intestinal motility and barrier functions. It was recently shown that ENS maturation can be enhanced by nutritional factors to improve intestinal maturation. Bioactivity of milk proteins is often latent, requiring the release of bioactive peptides from inactive native proteins. Several casein-derived hydrolysates presenting immunomodulatory properties have been described recently. Furthermore, accumulating data indicate that milk-derived hydrolysate can enhance gut maturation and enrichment of milk formula with such hydrolysates has recently been proposed. However, the capability of milk-derived bioactive hydrolysate to target ENS maturation has not been analyzed so far. We, therefore, investigated the potential of a recently described tryptic ß-casein hydrolysate to modulate ENS growth parameters in an in vitro model of rat primary culture of ENS. Rat primary cultures of ENS were incubated with a bioactive tryptic ß-casein hydrolysate and compared with untreated controls or to cultures treated with native ß-casein or a Prolyve ß-casein hydrolysate (Lyven, Colombelles, France). Differentiation of enteric neurons and enteric glial cells, and establishment of enteric neural network were analyzed using immunohistochemistry and quantitative PCR. Effect of tryptic ß-casein hydrolysate on bone morphogenetic proteins (BMP)/Smad pathway, an essential regulator of ENS development, was further assessed using quantitative PCR and immunochemistry. Tryptic ß-casein hydrolysate stimulated neurite outgrowth and simultaneously modulated the formation of enteric ganglia-like structures, whereas native ß-casein or Prolyve ß-casein hydrolysate did not. Additionally, treatment with tryptic bioactive ß-casein hydrolysate increased the expression of the glial marker glial fibrillary acidic protein and induced profound modifications of enteric glial cells morphology. Finally, expression of BMP2 and BMP4 and activation of Smad1/5 was altered after treatment with tryptic bioactive ß-casein hydrolysate. Our data suggests that this milk-derived bioactive hydrolysate modulates ENS maturation through the regulation of BMP/Smad-signaling pathway. This study supports the need for further investigation on the influence of milk-derived bioactive peptides on ENS and intestinal maturation in vivo.

Identification of a NFκB inhibitory peptide from tryptic ß-casein hydrolysate.

Several bioactive peptides are encrypted within the sequence of major milk proteins, requiring enzymatic proteolysis for release and activation. The present study aimed at the identification of potential anti-inflammatory activities in tryptic hydrolysates of bovine ß-casein. Inflammatory processes involve in most cases an activation of Nuclear factor Kappa-light-chain enhancer of activated B cells (NFκB), which is a pro-inflammatory transcription factor of several genes. Hence, a NFκB reporter cell line was established, and TNF-α mediated activation of NFκB was used as a measurement. Bovine ß-casein (ß-CN) was hydrolysed by trypsin and fractionated by ultrafiltration. Total proteolysate as well as the fraction containing peptides between 1 and 5 kDa showed an inhibitory effect in the cell-based assay, while the fraction containing molecules smaller than 1 kDa did not. This anti-inflammatory effect was ascribed to a group of large, hydrophobic peptides, which were identified using LC-MS. The main peptide was synthesised and showed a significant anti-inflammatory effect in HEK(nfkb-RE)-cells. Thus, for the first time, a casein-derived peptide having an anti-inflammatory effect in vitro has been identified.