Regulation and localization of tyrosine216 phosphorylation of glycogen synthase kinase-3beta in cellular and animal models of neuronal degeneration.

Inactivation of glycogen synthase kinase-3beta (GSK3beta) by S(9) phosphorylation is implicated in mechanisms of neuronal survival. Phosphorylation of a distinct site, Y(216), on GSK3beta is necessary for its activity; however, whether this site can be regulated in cells is unknown. Therefore we examined the regulation of Y(216) phosphorylation on GSK3beta in models of neurodegeneration. Nerve growth factor withdrawal from differentiated PC12 cells and staurosporine treatment of SH-SY5Y cells led to increased phosphorylation at Y(216), GSK3beta activity, and cell death. Lithium and insulin, agents that lead to inhibition of GSK3beta and adenoviral-mediated transduction of dominant negative GSK3beta constructs, prevented cell death by the proapoptotic stimuli. Inhibitors induced S(9) phosphorylation and inactivation of GSK3beta but did not affect Y(216) phosphorylation, suggesting that S(9) phosphorylation is sufficient to override GSK3beta activation by Y(216) phosphorylation. Under the conditions examined, increased Y(216) phosphorylation on GSK3beta was not an autophosphorylation response. In resting cells, Y(216) phosphorylation was restricted to GSK3beta present at focal adhesion sites. However, after staurosporine, a dramatic alteration in the immunolocalization pattern was observed, and Y(216)-phosphorylated GSK3beta selectively increased within the nucleus. In rats, Y(216) phosphorylation was increased in degenerating cortical neurons induced by ischemia. Taken together, these results suggest that Y(216) phosphorylation of GSK3beta represents an important mechanism by which cellular insults can lead to neuronal death.

Ges, A human GTPase of the Rad/Gem/Kir family, promotes endothelial cell sprouting and cytoskeleton reorganization.

Rad, Gem/Kir, and mRem (RGK) represent a unique GTPase family with largely unknown functions (Reynet, C., and C.R. Kahn. 1993. Science. 262:1441-1444; Cohen, L., R. Mohr, Y. Chen, M. Huang, R. Kato, D. Dorin, F. Tamanoi, A. Goga, D. Afar, N. Rosenberg, and O. Witte. Proc. Natl. Acad. Sci. USA. 1994. 91:12448-12452; Maguire, J., T. Santoro, P. Jensen, U. Siebenlist, J. Yewdell, and K. Kelly. 1994. Science. 265:241-244; Finlin, B.S., and D.A. Andres. 1997. J. Biol. Chem. 272:21982-21988). We report that Ges (GTPase regulating endothelial cell sprouting), a human RGK protein expressed in the endothelium, functions as a potent morphogenic switch in endothelial cells (ECs). Ges function is sufficient to substitute for angiogenic growth factor/extracellular matrix (ECM) signals in promoting EC sprouting, since overexpression of Ges in ECs cultured on glass leads to the development of long cytoplasmic extensions and reorganization of the actin cytoskeleton. Ges function is also necessary for Matrigel-induced EC sprouting, since this event is blocked by its dominant negative mutant, Ges(T94N), predicted to prevent the activation of endogenous Ges through sequestration of its guanine nucleotide exchange factor. Thus, Ges appears to be a key transducer linking extracellular signals to cytoskeleton/morphology changes in ECs.

Structure-function studies on synthetic peptides derived from the 109-118 lectin domain of selectins.

Previously, we identified several peptides corresponding to amino acid sequences within the lectin domains of selectins that inhibit neutrophil (PMN) adhesion to P-selectin. Here we focused on one of the active regions, 109-118, which contains residues that have been identified as critical for E-selectin binding to the sialyl Lexis X (sLex) counter receptor. Analogues were synthesized and examined for their inhibitory effect on PMN binding to P-selectin and E-selectin immunoglobulin fusion proteins (P-IgG, E-IgG) and also on P-IgG and E-IgG binding to sLex coated surfaces. Peptide sequences which inhibited PMN binding to the fusion proteins were not necessarily those that inhibited fusion protein binding to sLex. In addition, various amino acid substitutions could be tolerated at the 111 and 113 positions without altering inhibitory activity. Modeling suggests that structural conformations of peptide analogues could explain the differences in biological activity of peptide analogues compared to mutants of the native protein.

Determination of the core sequence of an antagonist of selectin-dependent leukocyte adhesion and correlation of its structure with molecular modeling studies.

The sequence 36-50 from the lectin domain of human P-selectin has been previously identified as a weak inhibitor of selectin-dependent leukocyte adhesion. A series of C- and N-terminally truncated peptides was synthesized to determine the limits of the active core region within the parent sequence. Deletions from both the N- and C-termini gave significant increases in inhibitory activity and identified 41-50 or 36-49 as minimum active sequences, but surprisingly not the common 41-49 peptide. All peptides tested showed parallel inhibition of both P- and E-selectin-dependent adhesion. A molecular model of the lectin domain was constructed using homology modeling. Examination of this model suggests one hypothesis to explain the increase in activity on deletion of Asp36.

Topological localization of a segment of the eel voltage-dependent sodium channel primary sequence (AA 927-938) that discriminates between models of tertiary structure.

Antibodies were raised against a synthetic peptide corresponding to residues 927-938 of the eel electroplax sodium channel primary sequence. This segment, lying between putative internal repeat domains II and III, is postulated to be exposed on the cytoplasmic surface of the membrane in several recent models of channel tertiary structure and on the external surface in another. The antiserum and affinity-purified IgG derived from it specifically recognize the peptide and the eel sodium channel in a solid-phase radioimmunoassay and bind to a single diffuse band of 260-280 kDa on Western blots of eel electroplax membrane proteins. All reactions are blocked by co-incubation of the antibodies with the synthetic peptide (1 microM). The antibody immunoprecipitates the solubilized channel in a form that retains its characteristic high-affinity binding of saxitoxin. In eel electroplax, the antibodies label only the innervated membrane known to contain sodium channels; at the ultrastructural level, this labeling is exclusively associated with the cytoplasmic surface of the membrane. Sodium channels containing the epitope are not seen in the postsynaptic membrane or in the membrane of the presynaptic nerve terminal. Segment 927-938 of the eel sodium channel is accessible on the surface of the protein in its solubilized form and is exposed in the cytoplasmic face of the innervated membrane of the electroplax in situ. This location is consistent with 3 models of channel structure but not with a fourth.

Localization of sodium channel subtypes in adult rat skeletal muscle using channel-specific monoclonal antibodies.

Five monoclonal antibodies specific for the 260 kDa subunit of the rat skeletal muscle sodium channel were used to probe the distribution of this channel in adult muscle. All the antibodies reacted with the surface membrane of fast- and slow-twitch fibers in the rat anterior tibial and soleus muscles. Immunoreactivity was also present in the endplate region; this was significantly more intense than that in the surrounding extrajunctional membrane. At the electron microscopic level, this junctional immunoreactivity could be traced uniformly throughout the secondary folds of the post-synaptic membrane. Three of the monoclonal antibodies (A/B2, F/E4, and I/E3) exhibited an additional distinct immunoreactivity pattern, staining the interior of selected fibers in the anterior tibial muscle that were subsequently identified as slow-twitch fibers. An identical reactivity pattern was observed with most of the soleus muscle fibers. In longitudinal sections of slow fibers examined at the light microscopic level, transversely oriented, regularly spaced doublets of fluorescence were localized at the junction of the A and I bands in each sarcomere. In permeabilized slow fibers exposed to A/B2 and examined at the electron microscopic level, internal reactivity was associated exclusively with the membranes of the T-tubular system. A/B2 also strongly stained a transversely oriented pattern within cardiac muscle fibers exhibiting the characteristics of the T-tubular system in that tissue. We conclude that at least 3 subpopulations of sodium channels are present in adult skeletal muscle: those in the sarcolemma of fast and slow fibers, those in slow-twitch fiber T-tubular membranes, and those in the T-tubular system of fast fibers. The channels in the slow fiber T-system apparently share common epitopes with those in the T-system of cardiac fibers.

Topographical localization of the C-terminal region of the voltage-dependent sodium channel from Electrophorus electricus using antibodies raised against a synthetic peptide.

A peptide corresponding to amino acid residues 1783-1794 near the C terminus of the electric eel sodium channel primary sequence of the eel (Electrophorus electricus) sodium channel has been synthesized and used to raise an antiserum in rabbits. This antiserum specifically recognized the peptide in a solid-phase radioimmunoassay. Specificity of the antiserum for the native channel protein was shown by its specific binding to a 280-kDa protein in immunoblots of eel electroplax membrane proteins. The antiserum also specifically labeled the innervated membrane of the eel electroplax in immunofluorescent studies; noninnervated membrane was not labeled, consistent with the known distribution of sodium channels in this tissue. The membrane topology of the peptide recognized by this antiserum was probed in binding studies using oriented electroplax membrane vesicles. These vesicles were 98% "right-side-out" as determined by [3H]saxitoxin binding. Binding of the antipeptide antiserum to this fraction was measured before and after permeabilization with 0.01% saponin. Specific binding to intact vesicles was low, but this binding increased 10-fold after permeabilization, implying a cytoplasmic orientation for the peptide. Confirmation for this orientation was then sought by localizing the antibody bound to intact electroplax cells with immunogold electron microscopy. Gold particles identifying the antibody were found almost exclusively associated with the cytoplasmic surface of the innervated membrane. Our data imply that the region of the sodium channel primary sequence near the C terminus that is recognized by our antiserum is localized on the cytoplasmic side of the membrane; this localization provides some further constraints on models of sodium channel tertiary structure.