ivanovii ATCC19119, E. faecalis CGMCC1.130 and E. faecalis CGMCC1.2024 were sensitive to rEntA in the 16 tested strains. Other Gram-positive bacteria, such as E. faecium CGMCC1.2136, S. aureus ATCC25923, S. epidermidis ATCC26069, B. licheniformis CGMCC1.265, and B. coagulans selleck products CGMCC1.2407, were found to be resistant to rEntA. All of the Gram-negative bacteria strains were resistant to rEntA in this assay (Table 1). The MIC and MBC of rEntA against L. ivanovii ATCC19119 were 20 ng/ml
and 80 ng/ml, respectively, and were lower than those of ampicillin (390 ng/ml and 1560 ng/ml, respectively). Table 1 Antimicrobial spectrum of rEntA Strains Antimicrobial activity Gram-positive Listeria ivanovii ATCC19119 + Enterococcus faecium CGMCC1.2136 – Enterococcus faecalis CGMCC1.130 + Enterococcus
faecalis CGMCC1.2024 + Staphylococcus aureus ATCC 25923 – Staphylococcus epidermidis ATCC26069 – Bacillus licheniformis CGMCC1.265 – Bacillus coagulans CGMCC1.2407 – Bacillus subtilis ATCC6633 – Lactococcus lactis (Stored in our lab) – selleck chemicals Bifidobacterium bifidum CGMCC1.2212 – Gram-negative – E. coli ER2566 – E. coli CVCC 195 – E. coli CMCC 44102 – Pseudomonas aeruginosa CVCC 2087 – Salmonella enteritidis CVCC3377 – Note: “+” refers to positive antimicrobial activity (inhibition zone > 6 mm); “-” refers to negative antimicrobial activity (inhibition zone ≤ 6 mm). In-vitro killing curve assay The time-killing kinetics curve showed that the amount of L. ivanovii ATCC19119 increased from 6.63 log10CFU/ml to 9.48 log10CFU/ml within 10 h in the absence of AL3818 price rEntA. The decrease in the counts of L. ivanovii ATCC19119 varied considerably depending on the concentration of rEntA. For example, the maximum viability loss (MVL), which was approximately 0.44 log10 CFU/ml (~60% reduction in CFU), was reached within 2 h in 1 × MIC of rEntA. The 2 × MIC of rEntA could cause approximately 1.42 log10 CFU/ml viability loss (96% reduction) within 6 h. Moreover, the MVL of L. ivanovii treated by rEntA at 4 × MIC was approximately 2.03 log10 CFU/ml (>99% reduction in CFU) within 4 h. Although rEntA could inhibit the growth of L. ivanovii
ATCC19119, the survivors resumed growth at 1× and 2 × MIC of rEntA PIK3C2G and 2 × MIC ampicillin for L. ivanovii ATCC19119 after MVL was achieved (Figure 3). However, L. ivanovii ATCC19119 treated by 4 × MIC of rEntA did not show re-growth within 10 h, revealing that 80 ng/ml rEntA could effectively inhibit the growth of pathogenic bacteria for an extended time. Figure 3 Time-kill curves of rEntA. L. ivanovii ATCC19119 was incubated in the presence of medium alone or in the presence of 1×, 2×, or 4× MIC of rEntA. Ampicillin of 2 × MIC was used as a positive control. Three duplicate observations were made; bars represent the standard error of the mean. Effects of pH, temperature, proteolytic enzymes and NaCl on the activity of rEntA As shown in Figure 4A, rEntA was highly stable at a wide range of pH values.