The recent ban on the use of antibiotics as a feed additive has led to the search for alternative sources of antibiotics in the feed industry. Presently, probiotics are considered as a potential substitute for antibiotic as a live biotherapeutic agent to improve animal health and performance. Accordingly, study was focused on evaluating the effect of Saccharomyces boulardii (Sb) and Bacillus subtilis B10 (Bs) on ultrastructure modulation and mucosal immunity development in broiler chickens. A total of three hundred 1-d-old Sanhuang broilers (a Chinese cross breed) were randomized into 3 groups, each group with 5 replications (n = 20). The control group (Ctr) was fed a basal diet containing an antibiotic (virginiamycin, 20 mg/kg). Meanwhile, broilers in experimental groups received Sb and Bs (1 × 10(8) cfu/kg of feed) in addition to the basal diet for 72 d. The results of the experimental groups revealed a significant improvement in live BW and relative weight of bursa of Fabricius and thymus. Also, intestinal villus height, width, and number of goblet cells increased in the Sb and Bs groups. Meanwhile, modulation in the intestinal ultrastructure and increased mRNA expression levels of occluding, cloudin2, and cloudin3 (P < 0.05) were observed in the Sb and Bs groups. Moreover, IgA-positive cells significantly increased in the jejunum of Sb- and Bs-supplemented groups (P < 0.05). Intestinal cytokines interleukin-6, tumor necrosis factor-α, interleukin-10, transforming growth factor-β, and secretory IgA concentrations were (P < 0.05) improved in the probiotic groups; however, Sb induced inflammatory and antiinflammatory cytokines (P < 0.05) in comparison with the Ctr group. The present findings conclusively revealed that Sb and Bs increased IgA-positive cells in the lumen of the intestinal villus and revealed that Sb and Bs could modulate intestinal ultrastructure through increasing occluding, cloudin2, and cloudin3 mRNA expression levels in broiler intestine.
Previously we showed that glutathione (GSH) can protect Lactococcus lactis against oxidative stress (Y. Li et al., Appl. Environ. Microbiol. 69:5739-5745, 2003). In the present study, we show that the GSH imported by L. lactis subsp. cremoris SK11 or produced by engineered L. lactis subsp. cremoris NZ9000 can protect both strains against a long-term mild acid challenge (pH 4.0) and a short-term severe acid challenge (pH 2.5). This shows for the first time that GSH can protect a gram-positive bacterium against acid stress. During acid challenge, strain SK11 containing imported GSH and strain NZ9000 containing self-produced GSH exhibited significantly higher intracellular pHs than the control. Furthermore, strain SK11 containing imported GSH had a significantly higher activity of glyceraldehyde-3-phosphate dehydrogenase than the control. These results suggest that the acid stress resistance of starter culture can be improved by selecting L. lactis strains capable of producing or importing GSH.Lactococcus lactis is a neutrophilic bacterium whose optimal growth occurs within an extracellular pH range of 6.3 to 6.9 (9). Growth of L. lactis is typified by the generation of acidic end products (mainly lactic acid), which results in medium acidification and subsequent acid stress. Acid stress has detrimental effects on the cellular physiology of L. lactis, including damage to the cell membrane and inhibition of enzymes and transport systems (14). Low pH is therefore considered a growth-limiting factor for L. lactis grown in milk or weakly buffered media. Consequently, the capability of L. lactis to survive, grow, and metabolize actively at a low pH will greatly influence its industrial performance as a starter.A number of acid stress resistance mechanisms in L. lactis have been identified and characterized. The primary mechanism of L. lactis for surviving low pH is to control the intracellular pH (pH i ) by membrane-bound F o F 1 ATPase, which translocates protons to the environment at the expense of ATP (9, 21). Other mechanisms include generation of alkaline substances by amino acid catabolism (e.g., deamination) (6, 24). L. lactis also develops a complex adaptive response to acid stress which is dependent on the synthesis of proteins such as heat shock proteins and proteinases (9). Although the native acid stress resistance mechanisms in L. lactis were extensively studied, improving the acid stress resistance of L. lactis by introducing a xenobiotic compound whose metabolism is not directly related to acid stress resistance has not been investigated.Glutathione (␥-Glu-Cys-Gly) (GSH) is the major nonprotein thiol compound in living cells. The major physiological role of GSH in living organisms is to maintain a redox balance (4). However, recent studies showed that GSH is also involved in bacterial acid stress resistance (23), osmotic-stress resistance (28), chlorine compound defense (5), and toxic electrophile detoxification (10). Most of these new physiological roles of GSH were found in gram-negative bacteria, such ...
Lipoxygenase (LOX; EC 1.13.11.12,) is an enzyme that is widely used in food industry to improve aroma, rheological, or baking properties of foods. In this study, we described the expression and characterization of Pseudomonas aeruginosa LOX in Escherichia coli. The recombinant LOX was successfully expressed and secreted by E. coli using its endogenous signal peptide. When induced with 1 mM isopropyl β-D-1-thiogalactopyranoside (final concentration) at 20 °C for 47 h, the titer of the recombinant enzyme reached 3.89 U/mL. In order to characterize the catalytic properties, the recombinant LOX was purified to homogeneity on Q High Performance and Mono Q5/50GL sequentially. The molecular weight of the LOX was estimated as 70 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The Km and Vmax of the recombinant enzyme were 48.9 μM and 0.226 μmol/min, respectively. The purified enzyme exhibited a maximum activity at 25 °C and pH 7.5. High-performance liquid chromatography analysis of the linoleic acid hydroperoxides produced by recombinant LOX revealed that the LOX from P. aeruginosa falls into linoleic acid 13(S)-LOX. To the best of our knowledge, this is the first report on the overexpression of extracellular LOX in microorganisms, and the achieved LOX yield is the highest ever reported.
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