But still the mass shift occurring on conversion of apo to holo KirAIIACP4 was clearly detectable in the MS data. PPTases of hybrid PKS/NRPS normally exhibit broad substrate specificity because they must activate both ACPs and PCPs. To test whether KirP also transfers phosphopantetheine to the PCP domains within the kirromycin PKS/NRPS, KirAIIIPCP and KirBPCP were expressed in E. coli and used
in in vitro activation assays. HPLC-ESI-MS analyses of the reaction mixtures revealed that KirP was able to activate these two apo-PCPs by addition of the 340 Da phosphopantetheine moieties. Control reactions without KirP confirmed that the conversion to their holo forms are the result of KirP phosphopantetheinylation activity, because in the control reaction lacking KirP, only apo-PCPs were detected by MS analyses. Sfp was reported to use different CoA derivatives (acetyl-CoA, desulfo-CoA, Epacadostat price benzoyl-CoA and phenylacetyl-CoA) as substrates (Quadri et al., 1998). A similar flexibility has also been described for AcpS
from E. coli, which uses acetyl-CoA, propionyl-CoA, butyryl-CoA, malonyl-CoA, benzoyl-CoA and phenylacetyl-CoA as substrates for phosphopantetheinylation of type II ACPs (Carreras et al., 1997). Therefore, the specificity of KirP with respect to its selleck kinase inhibitor CoA substrate was investigated. The purified apo-carrier proteins (KirAIIACP4, KirAIIACP5, KirAIIIPCP and KirBPCP) were incubated with [1,3-14C]methylmalonyl-CoA and KirP. Autoradiographic
analyses were performed to examine the incorporation of [1,3-14C]methylmalonyl-pantetheine moieties into the carrier proteins. Strong signals were detected in all tested carrier proteins, indicating efficient incorporation of the radioactively labeled substrate. In the absence of KirP, no incorporation of [1,3-14C]methylmalonyl-CoA was observed (Fig. 3). The utilization of modified CoAs by KirP was also detected in HPLC-ESI-MS analyses. Both malonyl- and methylmalonyl-CoA were found to be substrates for KirP (Fig. 2c and d). The enzyme transferred the acyl-phosphopantetheinyl group of each substrate to the carrier proteins Molecular motor KirAIIACP4, KirAIIACP5, KirAIIIPCP and KirBPCP. The observed mass shifts in the HPLC-MS data corresponded exactly to the expected values for attachment of a malonylated or methylmalonylated phosphopantetheinyl group (Table 1). The significant drop in kirromycin yield in S. collinus EP-P1, a kirP gene replacement mutant, shows that KirP plays an important role in kirromycin biosynthesis and can only be weakly complemented by other PPTases encoded elsewhere in the genome. In vitro phosphopantetheinylation assays demonstrated that KirP can activate both ACPs and PCPs within the kirromycin PKS/NRPS, thus exhibiting a broad specificity towards cognate ACP and PCP domains.