Lysophosphatidic acid induces upregulation of Mcl-1 and protects apoptosis in a PTX-dependent manner in H19-7 cells.

Lysophosphatidic acid (LPA) is a lipid growth factor known to regulate diverse cell functions, including cell proliferation, survival, and apoptosis. Tight regulation of cell survival in neuronal precursor is essential during neurogenesis in both developing and adult brain. Increasing data show that diverse external factors including LPA play roles in controlling cell survival and apoptosis in early developing neurons. However, the underlying control mechanism remains unclear. To explore how LPA regulates cell survival or apoptosis in a developing neuron, mechanisms for cell survival and signaling cascades by LPA were investigated in H19-7 hippocampal progenitor cells. Here, we showed that LPA promotes cell survival by protection from apoptosis. Mcl-1 was demonstrated to be crucial in LPA-induced cell survival by transfection of the siRNA specific for Mcl-1 and overexpression of Mcl-1. LPA-induced cell survival was critically mediated by the upregulation of Mcl-1 which was regulated not only through a post-translational control but a transcriptional control. Mcl-1 stabilization by LPA-induced inhibitory phosphorylation of GSK-3 contributed predominantly to the Mcl-1 upregulation. Both LPA-induced cell survival and the GSK-3 phosphorylation were attenuated by PTX and by siRNA specific for LPA1 or LPA2 receptor. Taken together, these results showed that Mcl-1 stabilization by inhibitory phosphorylation of GSK-3 through Gi/o coupling of the LPA1 and LPA2 receptors following Mcl-1 upregulation plays a critical role in LPA-induced survival of H19-7 cells. In developing neurons, modulation of Mcl-1 levels may constitute a crucial mechanism for controlling their fates.

Convergent evolution of Amadori opine catabolic systems in plasmids of Agrobacterium tumefaciens.

Deoxyfructosyl glutamine (DFG, referred to elsewhere as dfg) is a naturally occurring Amadori compound found in rotting fruits and vegetables. DFG also is an opine and is found in tumors induced by chrysopine-type strains of Agrobacterium tumefaciens. Such strains catabolize this opine via a pathway coded for by their plasmids. NT1, a derivative of the nopaline-type A. tumefaciens strain C58 lacking pTiC58, can utilize DFG as the sole carbon source. Genes for utilization of DFG were mapped to the 543-kb accessory plasmid pAtC58. Two cosmid clones of pAtC58 allowed UIA5, a plasmid-free derivative of C58, harboring pSa-C that expresses MocC (mannopine [MOP] oxidoreductase that oxidizes MOP to DFG), to grow by using MOP as the sole carbon source. Genetic analysis of subclones indicated that the genes for utilization of DFG are located in a 6.2-kb BglII (Bg2) region adjacent to repABC-type genes probably responsible for the replication of pAtC58. This region contains five open reading frames organized into at least two transcriptional soc (santhopine catabolism) groups: socR and socABCD. Nucleotide sequence analysis and analyses of transposon-insertion mutations in the region showed that SocR negatively regulates the expression of socR itself and socABCD. SocA and SocB are responsible for transport of DFG and MOP. SocA is a homolog of known periplasmic amino acid binding proteins. The N-terminal half of SocB is a homolog of the transmembrane transporter proteins for several amino acids, and the C-terminal half is a homolog of the transporter-associated ATP-binding proteins. SocC and SocD could be responsible for the enzymatic degradation of DFG, being homologs of sugar oxidoreductases and an amadoriase from Corynebacterium sp., respectively. The protein products of socABCD are not related at the amino acid sequence level to those of the moc and mot genes of Ti plasmids responsible for utilization of DFG and MOP, indicating that these two sets of genes and their catabolic pathways have evolved convergently from independent origins.