An Aspartate-Specific Solute-Binding Protein Regulates Protein Kinase G Activity To Control Glutamate Metabolism in Mycobacteria.

Signaling by serine/threonine phosphorylation controls diverse processes in bacteria, and identification of the stimuli that activate protein kinases is an outstanding question in the field. Recently, we showed that nutrients stimulate phosphorylation of the protein kinase G substrate GarA in and and that the action of GarA in regulating central metabolism depends upon whether it is phosphorylated. Here we present an investigation into the mechanism by which nutrients activate PknG.

Comprehensive approach to high-resolution KIR typing.

Multiple studies suggest that prospective KIR typing may be beneficial for the outcome of bone marrow transplants, but to date no practical high-resolution KIR typing system has been developed. Here we propose a comprehensive high-resolution typing approach that provides allele level KIR typing. Based on the low-resolution typing obtained by SSO, the 14 KIR loci are divided in groups according to the level of polymorphism in exons coding for extracellular Ig-like domains and cytoplasmic tail.

Chain-terminating natural mutations affect the function of activating KIR receptors 3DS1 and 2DS3.

To determine the nucleotide polymorphism of activating killer-cell immunoglobulin-like receptors (aKIR) 3DS1 and 2DS3, we developed a novel direct-sequencing method and analyzed DNA samples of 175 KIR3DS1(+) individuals and 72 KIR2DS3(+) individuals from the white population. The putative ligand-binding extracellular immunoglobulin (Ig)-like domains of these aKIR receptors are highly conserved, a scenario contrary to inhibitory KIRs that recognize polymorphic human leukocyte antigen (HLA) class I molecules. Null alleles 3DS1*049N and 2DS3*003N that do not express cell-surface receptors were discovered, and they occur commonly in whites (3DS1*049N = 2%; 2DS3*003N = 0.