EmbR, a regulatory protein with ATPase activity, is a substrate of multiple serine/threonine kinases and phosphatase in Mycobacterium tuberculosis.

Phosphorylation of the mycobacterial transcriptional activator, EmbR, is essential for transcriptional regulation of the embCAB operon encoding cell wall arabinosyltransferases. This signaling pathway eventually affects the resistance to ethambutol (a frontline antimycobacterial drug) and the cell wall Lipoarabinomannan/Lipomannan ratio (an important determinant for averting the host immune response). In this study, further biochemical characterization revealed that EmbR, as a transcriptional regulator, interacts with RNA polymerase and possesses a phosphorylation-dependent ATPase activity that might play a role in forming an open complex between EmbR and RNA polymerase. EmbR was recently shown to be phosphorylated by the cognate mycobacterial serine/threonine (Ser/Thr) kinase, PknH. Using bioinformatic analysis and in vitro assays, we identified additional novel regulators of the signaling pathway leading to EmbR phosphorylation, namely the Ser/Thr protein kinases PknA and PknB. A previously unresolved question raised by this signaling scheme is the fate of phosphorylated kinases and EmbR at the end of the signaling cycle. Here we show that Mstp, a mycobacterial Ser/Thr phosphatase, antagonizes Ser/Thr protein kinase-EmbR signaling by dephosphorylating Ser/Thr protein kinases, as well as EmbR, in vitro. Additionally, dephosphorylation of EmbR reduced its ATPase activity, interaction with Ser/Thr protein kinases and DNA-binding activity, emphasizing the antagonistic role of Mstp in the EmbR-Ser/Thr protein kinase signaling system.

Influence of a mutation in the ATP-binding region of Ca2+/calmodulin-dependent protein kinase II on its interaction with peptide substrates.

CaMKII (Ca2+/calmodulin-dependent protein kinase II) is expressed in high concentrations in the brain and is found enriched in the postsynaptic densities. The enzyme is activated by the binding of calmodulin to the autoregulatory domain in the presence of high levels of intracellular Ca2+, which causes removal of auto-inhibition from the N-terminal catalytic domain. Knowledge of the 3D (three-dimensional) structure of this enzyme at atomic resolution is restricted to the association domain, a region at the extreme C-terminus. The catalytic domain of CaMKII shares high sequence similarity with CaMKI. The 3D structure of the catalytic core of CaMKI comprises ATP- and substrate-binding regions in a cleft between two distinct lobes, similar to the structures of all protein kinases solved to date. Mutation of Glu-60, a residue in the ATP-binding region of CaMKII, to glycine exerts different effects on phosphorylation of two peptide substrates, syntide and NR2B ( N -methyl-D-aspartate receptor subunit 2B) 17-mer. Although the mutation caused increases in the Km values for phosphorylation for both the peptide substrates, the effect on the kcat values for each was different. The kcat value decreased in the case of syntide, whereas it increased in the case of the NR2B peptide as a result of the mutation. This resulted in a significant decrease in the apparent kcat/Km value for syntide, but the change was minimal for the NR2B peptide. These results indicate that different catalytic mechanisms are employed by the kinase for the two peptides. Molecular modelling suggests structural changes are likely to occur at the peptide-binding pocket in the active state of the enzyme as a consequence of the Glu-60-->Gly mutation.

A conserved domain in prokaryotic bifunctional FAD synthetases can potentially catalyze nucleotide transfer.

Biosynthesis of flavin adenine dinucleotides in most prokaryotes is catalyzed by a family of bifunctional flavin adenine dinucleotide (FAD) synthetases. These enzymes carry out the dual functions of phosphorylation of flavin mononucleotide (FMN) and its subsequent adenylylation to generate FAD. Using various sequence analysis methods, a new domain has been identified in the N-terminal region that is well conserved in all the bacterial FAD synthetases. We also identify remote similarity of this domain to the nucleotidyl transferases and, hence, this domain is suggested to be invloved in the adenylylation reaction of FAD synthetases.