Cysteine-to-Serine Mutants Dramatically Reorder the Active Site of Human ABO(H) Blood Group B Glycosyltransferase without Affecting Activity: Structural Insights into Cooperative Substrate Binding

A common feature in the structures of GT-A-fold-type glycosyltransferases is a mobile polypeptide loop that has been observed to participate in substrate recognition and enclose the active site upon substrate binding. This is the case for the human ABO(H) blood group B glycosyltransferase GTB, where amino acid residues 177-195 display significantly higher levels of disorder in the unliganded state than in the fully liganded state. Structural studies of mutant enzymes GTB/C80S/C196S and GTB/C80S/C196S/C209S at resolutions ranging from 1.93 to 1.40 Å display the opposite trend, where the unliganded structures show nearly complete ordering of the mobile loop residues that is lost upon substrate binding. In the liganded states of the mutant structures, while the UDP moiety of the donor molecule is observed to bind in the expected location, the galactose moiety is observed to bind in a conformation significantly different from that observed for the wild-type chimeric structures. Although this would be expected to impede catalytic turnover, the kinetics of the transfer reaction are largely unaffected. These structures demonstrate that the enzymes bind the donor in a conformation more similar to the dominant solution rotamer and facilitate its gyration into the catalytically competent form. Further, by preventing active-site closure, these structures provide a basis for recently observed cooperativity in substrate binding. Finally, the mutation of C80S introduces a fully occupied UDP binding site at the enzyme dimer interface that is observed to be dependent on the binding of H antigen acceptor analog.     

The Sesquiterpenes(E)-?-Farnesene and (E)-α-Bergamotene Quench Ozone but Fail to Protect the Wild Tobacco Nicotiana attenuata from Ozone,UVB, and Drought Stresses

Among the terpenes, isoprene (C₅) and monoterpene hydrocarbons (C₁₀) have been shown to ameliorate abiotic stress in a number of plant species via two proposed mechanisms: membrane stabilization and direct antioxidant effects. Sesquiterpene hydrocarbons (C₁₅) not only share the structural properties thought to lend protective qualities to isoprene and monoterpene hydrocarbons, but also react rapidly with ozone, suggesting that sesquiterpenes may similarly enhance tolerance of abiotic stresses. To test whether sesquiterpenes protect plants against ozone, UVB light, or drought, we used transgenic lines of the wild tobacco Nicotiana attenuata. The transgenic plants expressed a maize terpene synthase gene (ZmTPS10) which produced a blend of (E)-ß-farnesene and (E)-α-bergamotene, or a point mutant of the same gene (ZmTPS10M) which produced (E)-ß-farnesene alone,. (E)-ß-farnesene exerted a local, external, and transient ozone-quenching effect in ozone-fumigated chambers, but we found no evidence that enhanced sesquiterpene production by the plant inhibited oxidative damage, or maintained photosynthetic function or plant fitness under acute or chronic stress. Although the sesquiterpenes (E)-ß-farnesene and (E)-α-bergamotene might confer benefits under intermittent heat stress, which was not tested, any roles in relieving abiotic stress may be secondary to their previously demonstrated functions in biotic interactions.     

Postsynaptic decoding of neural activity: eEF2 as a biochemical sensor coupling miniature synaptic transmission to local protein synthesis

Activity-dependent regulation of dendritic protein synthesis is critical for enduring changes in synaptic function, but how the unique features of distinct activity patterns are decoded by the dendritic translation machinery remains poorly understood. Here, we identify eukaryotic elongation factor-2 (eEF2), which catalyzes ribosomal translocation during protein synthesis, as a biochemical sensor in dendrites that is specifically and locally tuned to the quality of neurotransmission. We show that intrinsic action potential (AP)-mediated network activity in cultured hippocampal neurons maintains eEF2 in a relatively dephosphorylated (active) state, whereas spontaneous neurotransmitter release (i.e., miniature neurotransmission) strongly promotes the phosphorylation (and inactivation) of eEF2. The regulation of eEF2 phosphorylation is responsive to bidirectional changes in miniature neurotransmission and is controlled locally in dendrites. Finally, direct spatially controlled inhibition of eEF2 phosphorylation induces local translational activation, suggesting that eEF2 is a biochemical sensor that couples miniature synaptic events to local translational suppression in neuronal dendrites.     

Identification of small molecule inhibitors of beta-amyloid cytotoxicity through a cell-based high-throughput screening platform

Calpain activation is hypothesized to be an early occurrence in the sequence of events resulting in neurodegeneration, as well as in the signaling pathways linking extracellular accumulation of beta-amyloid (Abeta) peptides and intracellular formation of neurofibrillary tangles. In an effort to identify small molecules that prevent neurodegeneration in Alzheimer's disease by early intervention in the cell death cascade, a cell-based assay in differentiated Sh-SY5Y cells was developed using calpain activity as a read-out for the early stages of death in cells exposed to extracellular Abeta. This assay was optimized for high-throughput screening, and a library of approximately 120,000 compounds was tested. It was expected that the compounds identified as calpain inhibitors would include those that act directly on the enzyme and those that prevented calpain activation by blocking an upstream step in the pathway. In fact, of the compounds that inhibited calpain activation by Abeta with IC(50) values of <10 microM and showed little or no toxicity at concentrations up to 30 microM, none inhibit the calpain enzyme directly.     

Tautomeric rearrangement of a dihydroflavin bound to monomeric sarcosine oxidase or N-methyltryptophan oxidase

Monomeric sarcosine oxidase (MSOX) and N-methyltryptophan oxidase (MTOX) are homologous bacterial flavoenzymes that contain covalently bound flavin [8alpha-(S-cysteinyl)FAD]. Reaction of MSOX or MTOX with a small excess of sodium borohydride results in immediate flavin reduction to a species that exhibits spectral properties (lambda(max) = 405 nm with a second broad peak at 332 nm) similar to those of 3,4-dihydroflavin. The borohydride-reduced enzymes retain full catalytic activity. Substrate reduction converts the 405 nm species to an air-sensitive tetrahydroflavin that reacts with oxygen to yield unmodified oxidized enzyme. Unexpectedly, the putative 3,4-dihydroflavin bound to MSOX or MTOX is unstable in the absence of substrate. An isosbestic conversion of the 405 nm species to yield unmodified, oxidized flavin is observed when the reaction is conducted under aerobic conditions (k(obs) = 4.9 x 10(-2) min(-1)). Under anaerobic conditions, an oxygen-sensitive species resembling 1,5-dihydroflavin is formed in an isosbestic reaction that occurs at a rate similar to that of the aerobic reaction (k(obs) = 5.3 x 10(-2) min(-1)). Possible reaction of the 3,4-dihydroflavin with a second molecule of borohydride to yield an air-sensitive tetrahydroflavin is unlikely since prior scavenging of residual borohydride with excess formaldehyde had no effect on the aerobic conversion to unmodified oxidized flavin. The observed instability is attributed to a tautomeric rearrangement of the 3,4-dihydroflavin to generate 1,5-dihydroflavin, a species that is also air-sensitive. Evidence in favor of an active site facilitated tautomerization reaction is provided by the fact that the stability of the 405 nm species formed with MSOX is enhanced 200-fold upon denaturation with urea or heat. The observed tautomeric rearrangement of 3,4-dihydroflavin may provide insight regarding a related flavin tautomerization reaction that has been proposed as a key step in the biosynthesis of covalent flavin linkages.