To better understand the modification ability of the GlnJQ42H, GlnJK85R and Selleckchem NSC 683864 GlnJQ42HK85R variants we performed a time-course experiment (Figure 3). On a longer time scale the modification in the presence of Mg2+ is even more evident in these find more variants when compared
with GlnJ. Figure 3 Time-course uridylylation of GlnJ, GlnJ Q42H , GlnJ K85R and GlnJ Q42HK85R . At the time points indicated samples were withdrawn and analyzed by native PAGE. The number of uridylylated subunits (0–3) is indicated. Considering the results in Figure 2A and Figure 3, it is clear that the amino acid residues at position 42 and 85 influence the activity with respect to divalent cation added in the uridylylation reaction. It could be hypothesized that these residues are either involved in the direct binding of the divalent cation or influence the architecture of its binding site in the R. rubrum PII proteins. Even though there is no structural information available for either GlnB
or GlnJ from R. rubrum, a direct binding of the divalent cation by the residues at positions 42 and 85 is unlikely, based on the recent structural information for the homologous proteins from A. brasilense and S. elongatus[9, 10]. In these structures, the residues at positions 42 and 85 are not directly involved in the coordination of the divalent cation, which occurs through the ATP phosphates, the 2-oxo acid moiety of 2-OG and the carboxamide oxygen of the Q39 side chain. Even though PRIMA-1MET chemical structure these residues (Q42, K85) do not participate directly in the binding of the divalent cation, they are certainly in the vicinity of the binding site, and can influence this binding by changing the conformation of the binding site or affecting binding of ATP (that could subsequently affect divalent cation binding). This is visible in the structural model of GlnJ constructed based on the structure determined for A. brasilense GlnZ in the presence of ligands (Figure 4). Even though a sequence identity of 74% between GlnJ and GlnZ allows
the construction of a reliable model (specially for the backbone trace), the specific side chain rotamers cannot be predicted, and only a structural determination by x-ray crystallography would correctly address the influence Rutecarpine of these two residues in the properties of the divalent cation binding site. Figure 4 Cartoon representation of the structural model for GlnJ, constructed based on the determined structure of A. brasilense GlnZ, with ligands (PDB 3MHY). ATP is shown in gray, Magnesium ion in yellow, 2-OG in red and the residues K85 and Q42 are highlighted in blue and green respectively. GlnB variants H42Q and R85K show reduced uridylylation in the presence of Mg2+ Considering the influence of the residues at positions 42 and 85 we hypothesized that exchanging these residues in GlnB for the corresponding residues in GlnJ could affect Mg2+-dependent uridylylation. That was indeed the case, as shown in Figure 2B.