Tankyrase-1-mediated degradation of Golgin45 regulates glycosyltransferase trafficking and protein glycosylation in Rab2-GTP-dependent manner.

Altered glycosylation plays an important role during development and is also a hallmark of increased tumorigenicity and metastatic potentials of several cancers. We report here that Tankyrase-1 (TNKS1) controls protein glycosylation by Poly-ADP-ribosylation (PARylation) of a Golgi structural protein, Golgin45, at the Golgi. TNKS1 is a Golgi-localized peripheral membrane protein that plays various roles throughout the cell, ranging from telomere maintenance to Glut4 trafficking. Our study indicates that TNKS1 localization to the Golgi apparatus is mediated by Golgin45. TNKS1-dependent control of Golgin45 protein stability influences protein glycosylation, as shown by Glycomic analysis. Further, FRAP experiments indicated that Golgin45 protein level modulates Golgi glycosyltransferease trafficking in Rab2-GTP-dependent manner. Taken together, these results suggest that TNKS1-dependent regulation of Golgin45 may provide a molecular underpinning for altered glycosylation at the Golgi during development or oncogenic transformation.

Glycosphingolipid Biosynthesis Pathway in the Spinal Cord and Dorsal Root Ganglia During Inflammatory Pain: Early and Late Changes in Expression Patterns of Glycosyltransferase Genes.

Glycosphingolipids (GSLs) are abundant, ceramide-containing lipids in the nervous system that play key functional roles in pain and inflammation. We measured gene expression (Ugcg, St3gal5, St8sia1, B4galNT1, Ugt8a, and Gal3st1) of glycosyltransferases involved in GSL synthesis in murine dorsal root ganglion (DRG) and spinal cord after complete Freund's adjuvant (CFA)-induced unilateral hind-paw inflammation (1 day vs. 15 days). Chronic inflammation (15 days) sensitized both ipsilateral and contralateral paws to pain. One day of induced unilateral hind-paw inflammation (1d-IUHI) increased Ugcg, St8sia1, B4galnt1, and Gal3st1 expression in ipsilateral cord, suggesting that sulfatide and b-series gangliosides were also elevated. In addition, 1d-IUHI increased Ugcg, st3gal5 and Gal3st1 expression in contralateral cord, suggesting that sulfatide and a-/b-series gangliosides were elevated. By contrast, 1d-IUHI decreased Ugcg, St3gal5, and St8sia1 expression bilaterally in the DRG, suggesting that b-series gangliosides were depressed. Since intrathecal injection of b-series ganglioside induced mechanical allodynia in naïve mice, it seems reasonable that b-series gangliosides synthesized from upregulated St8sia1 in the ipsilateral spinal cord are involved in mechanical allodynia. By contrast, chronic inflammation led to a decrease of Ugcg, St3gal5, B4galnt1, and Gal3st1 expression in spinal cord bilaterally and an increase of St8sia1 expression in the ipsilateral DRG, suggesting that a-/b-series gangliosides in the spinal cord decreased and b-series gangliosides in ipsilateral DRG increased. These changes in glycosyltransferase gene expression in the DRG and the spinal cord may contribute to the modification of pain sensitivity in both inflamed and non-inflamed tissues and the transition from early to chronic inflammatory pain.

A mechanism for bistability in glycosylation.

Glycosyltransferases are a class of enzymes that catalyse the posttranslational modification of proteins to produce a large number of glycoconjugate acceptors from a limited number of nucleotide-sugar donors. The products of one glycosyltransferase can be the substrates of several other enzymes, causing a combinatorial explosion in the number of possible glycan products. The kinetic behaviour of systems where multiple acceptor substrates compete for a single enzyme is presented, and the case in which high concentrations of an acceptor substrate are inhibitory as a result of abortive complex formation, is shown to result in non-Michaelian kinetics that can lead to bistability in an open system. A kinetic mechanism is proposed that is consistent with the available experimental evidence and provides a possible explanation for conflicting observations on the ß-1,4-galactosyltransferases. Abrupt switching between steady states in networks of glycosyltransferase-catalysed reactions may account for the observed changes in glycosyl-epitopes in cancer cells.

An Israeli family with six cisAB members: serologic and enzymatic studies.

BACKGROUND: The cisAB blood type is a rare phenomenon in which both the A and B blood types are inherited from a single parent. Several forms of this phenotype have been characterized that differ with respect to serologic reactions and the activities of the gene-encoded blood group A and B transferases. STUDY DESIGN AND METHODS: The cisAB blood type was suspected when a baby typed as blood group O was born to a mother whose blood group was AB. Family studies revealed four generations in whom the pattern of inheritance could be explained only by the inheritance of the cisAB genotype. Blood and saliva samples from the family were tested serologically and assayed for the relevant glycosyltransferases. Samples suitable for DNA analysis were not available. RESULTS: Six family members were shown serologically to be of the cisAB type. The A and B transferases in the sera of these individuals were 20 to 35 and 25 to 50 percent of those obtained for A and B individuals, respectively. The enzymic characteristics of the A and B transferases were determined. The A transferase in the sera of the cisAB persons did not bind to agarose beads. CONCLUSION: The family described carries the cisAB gene, which encodes production of A and B transferases that differ from those of "normal" A, AB, and B controls. This variant has properties that are distinctly different from those described in other reports.