SummaryBacterial genomics revealed the widespread presence of eukaryotic-like protein kinases and phosphatases in prokaryotes, but little is known on their biochemical properties, regulation mechanisms and physiological roles. Here we focus on the catalytic domains of two trans -membrane enzymes, the Ser/ Thr protein kinase PknB and the protein phosphatase PstP from Mycobacterium tuberculosis . PstP was found to specifically dephosphorylate model phospho-Ser/Thr substrates in a Mn 2+ + + + -dependent manner. Autophosphorylated PknB was shown to be a substrate for Pstp and its kinase activity was affected by PstP-mediated dephosphorylation. Two threonine residues in the PknB activation loop, found to be mostly disordered in the crystal structure of this kinase, namely Thr171 and Thr173, were identified as the target for PknB autophosphorylation and PstP dephosphorylation. Replacement of these threonine residues by alanine significantly decreased the kinase activity, confirming their direct regulatory role. These results indicate that, as for eukaryotic homologues, phosphorylation of the activation loop provides a regulation mechanism of mycobacterial kinases and strongly suggest that PknB and PstP could work as a functional pair in vivo to control mycobacterial cell growth.
With the advent of the sequencing programs of prokaryotic genomes, many examples of the presence of serine/threonine protein kinases in these organisms have been identified. Moreover, these kinases could be classified as homologues of those belonging to the well characterized superfamily of the eukaryotic serine/threonine and tyrosine kinases. Eleven such kinases were recognized in the genome of Mycobacterium tuberculosis. Here we report the crystal structure of an active form of PknB, one of the four M. tuberculosis kinases that are conserved in the downsized genome of Mycobacterium leprae and are therefore presumed to play an important role in the processes that regulate the complex life cycle of mycobacteria. Our structure confirms again the extraordinary conservation of the protein kinase fold and constitutes a landmark that extends this conservation across the evolutionary distance between high eukaryotes and eubacteria. The structure of PknB, in complex with a nucleotide triphosphate analog, reveals an enzyme in the active state with an unprecedented arrangement of the Gly-rich loop associated with a new conformation of the nucleotide ␥-phosphoryl group. It presents as well a partially disordered activation loop, suggesting an induced fit mode of binding for the so far unknown substrates of this kinase or for some modulating factor(s).
N-acetylglucosamine 1-phosphate uridyltransferase (GlmU) is a cytoplasmic bifunctional enzyme involved in the biosynthesis of the nucleotide-activated UDPGlcNAc, which is an essential precursor for the biosynthetic pathways of peptidoglycan and other components in bacteria. The crystal structure of a truncated form of GlmU has been solved at 2.25 Å resolution using the multiwavelength anomalous dispersion technique and its function tested with mutagenesis studies. The molecule is composed of two distinct domains connected by a long α-helical arm: (i) an N-terminal domain which resembles the dinucleotidebinding Rossmann fold; and (ii) a C-terminal domain which adopts a left-handed parallel β-helix structure (LβH) as found in homologous bacterial acetyltransferases. Three GlmU molecules assemble into a trimeric arrangement with tightly packed parallel LβH domains, the long α-helical linkers being seated on top of the arrangement and the N-terminal domains projected away from the 3-fold axis. In addition, the 2.3 Å resolution structure of the GlmU-UDP-GlcNAc complex reveals the structural bases required for the uridyltransferase activity. These structures exemplify a three-dimensional template for the development of new antibacterial agents and for studying other members of the large family of XDP-sugar bacterial pyrophosphorylases.
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