The results showed that Fe was present (Additional file 1, Table S5) in purified MtsA; however, four other bivalent metallic elements Ca, Mg, Zn and Mn were not detected. The amount of iron present in purified GS-9973 MtsA (20 μM) was 1.43, 1.38, and 1.33 mg L-1, in three independent purification experiments respectively. In vivo production of MtsA during S. iniae HD-1 infection To determine whether MtsA is produced in vivo during S. iniae infection, we infected Kunming mice with S. iniae HD-1 and performed western blotting analysis with purified MtsA to determine the presence of anti-MtsA antibodies in infected sera (Figure 7). The results indicated that MtsA is produced in vivo during experimental S.
iniae HD-1 infection. Figure 7 Western blotting analysis of anti-MtsA antibodies in infected sera from Kunming mice with S. iniae HD-1 infection.
SDS-PAGE analysis showing the purification results of MtsA. The gel was transferred to a nitrocellulose membrane and blotted with infected sera from mice. The gels were stained with Coomassie brilliant blue. Lane 1, molecular mass marker; lane 2, E. coli with control pet-32a-c (+) vector; lane 3, E. coli lysate containing MtsA (approximately 49.5-kDa); lane 4, purified MtsA (approximately 49.5-kDa); lanes 5~7, western blot results of infected sera, lanes 8~10, western blot results of control sera; lanes 5 and 8, western blot results of E. coli with the control vector; lanes 6 and 9, E. coli lysate containing MtsA, and lanes 7 and 10, purified MtsA (approximately 49.5-kDa). Discussion Heme is an important nutrient for several bacteria and can serves as a source of essential iron. The most AZD6738 molecular weight cAMP abundant source of iron in the body is heme, so it is not surprising to find that pathogenic bacteria can use heme as an iron source [29]. The presence of the central iron atom in heme allows it to undergo reversible oxidative change and act as a virulence-regulated determinant [30–36]. It is necessary for bacterial pathogens to 10058-F4 purchase acquire sufficient iron from their surroundings, and scavenging heme
from the environment requires much less effort than synthesizing it de novo [30, 34]. Acquiring iron from the micro-environment is important for the growth of bacterial pathogens. Pathogens often use low environmental iron levels as a signal to induce virulence genes [14]. Many pathogenic bacteria secrete exotoxins, proteases, and siderophores to rapidly increase the local concentration of free heme [37], and it is common for pathogens to directly acquire iron from host iron-binding proteins by using receptor-mediated transport systems specific for host-iron complexes [38]. To define the role of MtsA in heme utilization, the binding activity and subcellular localization of purified MtsA were investigated. The coding sequence of mtsA was cloned into the expression vector pet-32a-c (+). The major induced protein in E. coli (BL21) migrated as a 49.