The consumption of food containing lactic acid bacteria (LAB) has been shown to exert immunomodulatory effects in humans. The specific cellular interaction of these bacteria with immuno-competent cells has not yet been fully understood. Since the TNF-α secretion of stimulated monocytes is an important initial response to a bacterial challenge, we investigated the potential of LAB originating from the human intestine or fermented food in comparison to the effect of invasive pathogens. The challenge of monocytes with three LAB strains,
Listeria monocytogenes or enterohaemorrhagic
Escherichia coli (EHEC) elicited a strain specific, dose-dependent biphasic TNF-α secretion. The concentration (ED
max) of bacteria or bacterial cell wall components necessary to induce maximal TNF-α secretion (TNF
max) by monocytes was mathematically approximated. It was shown for exponentially growing LAB strains that the maximal TNF-α secretion (TNF
max) was stronger (57 to 78%) upon stimulation with living bacteria than with heat killed cells. In contrast to log-phase bacteria, the maximal TNF-α secretion of monocytes (TNF
max) was higher (15 to 55%) after the stimulation with heat killed, stationary-phase bacteria when compared to that of live LAB. Thus, monocyte stimulation was clearly affected by the growth phase of bacteria. Purified cell walls of LAB straines revealed only a limited potential for monocyte stimulation. LPS exhibited a higher capacity to stimulate monocytes than purified Gram positive cell walls or muramyldipeptide. In comparison to pathogenic bacteria, the maximal secretory TNF-α response (TNF
max) was up to 2 fold higher with LAB strains. In general, the amount of bacteria (ED
max) necessary to induce maximal TNF-α secretion (TNF
max) was approximatly 1 to 3 log higher for heat killed bacteria when compared to live bacterial cells illustrating the significant lower potential of heat killed bacteria to activate monocytes.
抄録全体を表示