Characterization of N-ethylmaleimide-sensitive thiol groups required for the GTP-dependent fusion of endoplasmic reticulum membranes

Taking organelles apart, putting them back together and creating new ones: lessons from the endoplasmic reticulum

The endoplasmic reticulum (ER) is a highly dynamic organelle. It is composed of four subcompartments including nuclear envelope (NE), rough ER (rER), smooth ER (sER) and transitional ER (tER). The subcompartments are interconnected, can fragment and dissociate and are able to reassemble again. They coordinate with cell function by way of protein regulators in the surrounding cytosol. The activity of the many associated molecular machines of the ER as well as the fluid nature of the limiting membrane of the ER contribute extensively to the dynamics of the ER. This review examines the properties of the ER that permit its isolation and purification and the physiological conditions that permit reconstitution both in vitro and in vivo in normal and in disease conditions.

Dissecting the mechanism of Ca2+-triggered membrane fusion: probing protein function using thiol reactivity

1. Ca(2+)-triggered membrane fusion involves the coordinated actions of both lipids and proteins, but the specific mechanisms remain poorly understood. The urchin cortical vesicle model is a stage-specific native preparation fully enabling the directly coupled functional-molecular analyses necessary to identify critical components of fast triggered membrane fusion. 2. Recent work on lipidic components has established a direct role for cholesterol in the fusion mechanism via local contribution of negative curvature to readily enable the formation of transient lipidic fusion intermediates. In addition, cholesterol- and sphingomyelin-enriched domains regulate the efficiency of fusion by focally organizing other components to ensure an optimized response to the triggering Ca(2+) transient. 3. There is less known about the identity of proteins involved in the Ca(2+)-triggering steps of membrane fusion. Thiol reagents can be used as unbiased tools to probe protein functions. Comparisons of several thiol-reactive reagents have identified different effects on Ca(2+) sensitivity and the extent of fusion, suggesting that there are at least two distinct thiol sites that participate in the fusion mechanism: one that regulates the efficiency of Ca(2+) sensing/triggering and one that may function during the membrane merger event itself. 4. To identify the proteins that regulate Ca(2+) sensitivity, the fluorescent thiol reagent Lucifer yellow iodoacetamide was used to potentiate fusion and simultaneously tag the proteins involved. Ongoing work involves the isolation of cholesterol-enriched membrane fractions to reduce the complexity of the labelled proteome, narrowing the number of candidate proteins.

Endoplasmic reticulum architecture: structures in flux

The endoplasmic reticulum (ER) is a dynamic pleiomorphic organelle containing continuous but distinct subdomains. The diversity of ER structures parallels its many functions, including secretory protein biogenesis, lipid synthesis, drug metabolism and Ca2+ signaling. Recent studies are revealing how elaborate ER structures arise in response to subtle changes in protein levels, dynamics, and interactions as well as in response to alterations in cytosolic ion concentrations. Subdomain formation appears to be governed by principles of self-organization. Once formed, ER subdomains remain malleable and can be rapidly transformed into alternative structures in response to altered conditions. The mechanisms that modulate ER structure are likely to be important for the generation of the characteristic shapes of other organelles.

Augmentative effects of L-cysteine and methylmethionine sulfonium chloride on mucin secretion in rabbit gastric mucous cells

BACKGROUND

Our previous study showed that L-cysteine (Cys) and methylmethionine sulfonium chloride (MMSC) inhibited ethanol-induced gastric mucosal damage and increased the amount of surface mucin in rats. This study examined whether Cys and MMSC augmented mucin secretion and changed distribution of mucin vesicles ultrastructurally in mucous cells by using primary cultured mucous cells from rabbit glandular stomach. Changes in intracellular cyclic adenosine 3',5'-monophosphate (cAMP) and in levels of cytosolic free Ca2+ were investigated by treatment with Cys and MMSC.

METHODS

Mucin content was measured by an enzyme-linked lectin assay. Transmission electron micrography was used to examine ultrastructural distribution of mucin granules. The amount of cAMP or levels of free Ca2+ were measured by enzyme immunoassay or by fura-2. 16,16-Dimethyl prostaglandin E2 (dmPGE2) or ATP was used as the positive control.

RESULTS

L-Cysteine and MMSC increased mucin secretion and decreased cellular mucin content. The same was noted for dmPGE2. Accelerated mucin granule movements toward the plasma membrane were shown by these agents. Intracellular cAMP increased with exposure to dmPGE2 for 20 min, while neither Cys nor MMSC increased cAMP. No increase in cytosolic free Ca2+ levels occurred after treatment with Cys or MMSC, but an increase was induced 10 s after the addition of ATP.

CONCLUSIONS

The present findings indicate that the increase in mucin secretion by Cys and MMSC was not mediated through the cAMP or Ca2+ signal transduction pathway, but might occur through non-receptor-mediated mechanisms.

Stimulation of glycosylphosphatidylinositol biosynthesis in mammalian cell-free systems by GTP hydrolysis: evidence for the involvement of membrane fusion

The second step in glycosylphosphatidylinositol (GPI) biosynthesis, the deacetylation of GlcNAc-phosphatidylinositol (GlcNAc-PI), has been shown to be stimulated by GTP hydrolysis [Stevens (1993) J. Biol. Chem. 268, 9718-9724]. We have now developed a system to study this regulation that uses microsomes from cells defective in the first step in GPI biosynthesis (class A, C and H lymphoma mutants) and the second reaction in the pathway (G9PLAP.85). With this mixed-microsome system, the deacetylation of GlcNAc-PI was almost completely dependent on GTP hydrolysis. Because GlcNAc-PI synthesized by the G9PLAP.85 microsomes cannot readily move to the first-step-mutant microsomes to be deacetylated, this result indicated that the role of GTP was to facilitate the 'apparent' transfer of this substrate between membrane vesicles. The microsomes could be stably preactivated by pretreatment with GTP before GPI biosynthesis was initiated, indicating that fusion was the most likely mechanism for this regulation. GlcNAc-PI deacetylation could also be stably preactivated in EL4 microsomes, suggesting that fusion also occurred in wild-type membranes. Some differential localization of the GlcNAc-PI synthetic and deacetylation activities with the endoplasmic reticulum was found. Therefore fusion seems to stimulate GPI biosynthesis in mammalian microsomes by bringing together the first two enzymes in the pathway in the same membrane vesicle.

A Rab GTPase is required for homotypic assembly of the endoplasmic reticulum

To define the requirements for the homotypic fusion of mammalian endoplasmic reticulum (ER) membranes, we have developed a quantitative in vitro enzyme-linked immunosorbent assay. This assay measures the formation of IgG (H2L2) following the fusion of ER microsomes containing either the heavy or light chain subunits. Guanine nucleotide dissociation inhibitor (GDI), a protein that extracts Rab GTPases in the GDP-bound form from membranes, potently inhibits fusion. Inhibition was not observed using GDI mutants defective in Rab binding. Kinetic analysis of the inhibitory effects of GDI revealed that Rab activation is required immediately preceding or coincident with fusion and that this step is preceded by a priming event requiring a member of the AAA ATPase family. Our results suggest that homotypic fusion of ER membranes requires Rab and that Rab activation is a transient event necessary for the formation of a fusion pore leading to the mixing of luminal contents of ER microsomes.

Zinc blocks acetylcholine release but not vesicle fusion at the Torpedo nerve-electroplate junction

The combined effects of Zn2+ treatment and nerve stimulation were studied on cholinergic synapses of the Torpedo marmorata electric organ. Incubation of small pieces of electric tissue in 250 microM ZnCl2 for 2 h irreversibly blocked synaptic transmission by inhibiting the release of acetylcholine. This treatment, however, did not cause any significant fine structural alteration in the nerve-electroplate junctions. Preparations treated with Zn2+ were submitted to electrical stimulation. In spite of the fact that no transmitter was released, stimulation resulted in the accumulation of calcium in the tissue, and in marked ultrastructural changes. The density of synaptic vesicles was significantly reduced and many of the remaining vesicles were found in close proximity to the presynaptic membrane. Images of vesicles fused with the plasmalemma were abundant, indicating that numerous vesicles were caught in different phases of exocytosis or endocytosis. Freeze-fracture replicas made from quick-frozen or chemically fixed material showed a high number of vesicle openings (pits) in the presynaptic plasmalemma. No recovery occurred even after a prolonged period of rest, indicating that retrieval was impaired by zinc treatment. In conclusion, the present experimental paradigm created an unusual situation where fusion of synaptic vesicles to the plasma membrane could be activated independently from the release of transmitter.