Lipid rafts alter the stability and activity of the cholera toxin A1 subunit

Cholera toxin (CT) travels from the cell surface to the endoplasmic reticulum (ER) as an AB holotoxin. ER-specific conditions then promote the dissociation of the catalytic CTA1 subunit from the rest of the toxin. CTA1 is held in a stable conformation by its assembly in the CT holotoxin, but the dissociated CTA1 subunit is an unstable protein that spontaneously assumes a disordered state at physiological temperature. This unfolding event triggers the ER-to-cytosol translocation of CTA1 through the quality control mechanism of ER-associated degradation. The translocated pool of CTA1 must regain a folded, active structure to modify its G protein target which is located in lipid rafts at the cytoplasmic face of the plasma membrane. Here, we report that lipid rafts place disordered CTA1 in a functional conformation. The hydrophobic C-terminal domain of CTA1 is essential for binding to the plasma membrane and lipid rafts. These interactions inhibit the temperature-induced unfolding of CTA1. Moreover, lipid rafts could promote a gain of structure in the disordered, 37 °C conformation of CTA1. This gain of structure corresponded to a gain of function: whereas CTA1 by itself exhibited minimal in vitro activity at 37 °C, exposure to lipid rafts resulted in substantial toxin activity at 37 °C. In vivo, the disruption of lipid rafts with filipin substantially reduced the activity of cytosolic CTA1. Lipid rafts thus exhibit a chaperone-like function that returns disordered CTA1 to an active state and is required for the optimal in vivo activity of CTA1.     

Co- and Post-translocation Roles for HSP90 in Cholera Intoxication

Cholera toxin (CT) moves from the cell surface to the endoplasmic reticulum (ER) where the catalytic CTA1 subunit separates from the rest of the toxin. CTA1 then unfolds and passes through an ER translocon pore to reach its cytosolic target. Due to its intrinsic instability, cytosolic CTA1 must be refolded to achieve an active conformation. The cytosolic chaperone Hsp90 is involved with the ER to cytosol export of CTA1, but the mechanistic role of Hsp90 in CTA1 translocation remains unknown. Moreover, potential post-translocation roles for Hsp90 in modulating the activity of cytosolic CTA1 have not been explored. Here, we show by isotope-edited Fourier transform infrared spectroscopy that Hsp90 induces a gain-of-structure in disordered CTA1 at physiological temperature. Only the ATP-bound form of Hsp90 interacts with disordered CTA1, and refolding of CTA1 by Hsp90 is dependent upon ATP hydrolysis. In vitro reconstitution of the CTA1 translocation event likewise required ATP hydrolysis by Hsp90. Surface plasmon resonance experiments found that Hsp90 does not release CTA1, even after ATP hydrolysis and the return of CTA1 to a folded conformation. The interaction with Hsp90 allows disordered CTA1 to attain an active state, which is further enhanced by ADP-ribosylation factor 6, a host cofactor for CTA1. Our data indicate CTA1 translocation involves a process that couples the Hsp90-mediated refolding of CTA1 with CTA1 extraction from the ER. The molecular basis for toxin translocation elucidated in this study may also apply to several ADP-ribosylating toxins that move from the endosomes to the cytosol in an Hsp90-dependent process.     

Order-disorder-order transitions mediate the activation of cholera toxin

Cholera toxin (CT) holotoxin must be activated to intoxicate host cells. This process requires the intracellular dissociation of the enzymatic CTA1 domain from the holotoxin components CTA2 and B5, followed by subsequent interaction with the host factor ADP ribosylation factor 6 (ARF6)-GTP. We report the first NMR-based solution structural data for the CT enzymatic domain (CTA1). We show that this free enzymatic domain partially unfolds at the C-terminus and binds its protein partners at both the beginning and the end of this activation process. Deviations from random coil chemical shifts (Δδ_coil) indicate helix formation in the activation loop, which is essential to open the toxin's active site and occurs prior to its association with human protein ARF6. We performed NMR titrations of both free CTA1 and an active CTA1:ARF6-GTP complex with NAD⁺, which revealed that the formation of the complex does not significantly enhance NAD⁺ binding. Partial unfolding of CTA1 is further illustrated by using 4,4′-bis(1-anilinonaphthalene 8-sulfonate) fluorescence as an indicator of the exposed hydrophobic character of the free enzyme, which is substantially reduced when bound to ARF6-GTP. We propose that the primary role of ARF6's allostery is to induce refolding of the C-terminus of CTA1. Thus, as a folded globular toxin complex, CTA1 escapes the chaperone and proteasomal components of the endoplasmic reticulum associated degradation pathway in the cytosol and then proceeds to ADP ribosylate its target G_sα, triggering the downstream events associated with the pathophysiology of cholera.     

MARTX effector cross kingdom activation by Golgi‐associated ADP‐ribosylation factors

Vibrio vulnificus infects humans and causes lethal septicemia. The primary virulence factor is a multifunctional‐autoprocessing repeats‐in‐toxin (MARTX) toxin consisting of conserved repeats‐containing regions and various effector domains. Recent genomic analyses for the newly emerged V. vulnificus biotype 3 strain revealed that its MARTX toxin has two previously unknown effector domains. Herein, we characterized one of these domains, Domain X (DmX_Vv). A structure‐based homology search revealed that DmX_Vv belongs to the C58B cysteine peptidase subfamily. When ectopically expressed in cells, DmX_Vv was autoprocessed and induced cytopathicity including Golgi dispersion. When the catalytic cysteine or the region flanking the scissile bond was mutated, both autoprocessing and cytopathicity were significantly reduced indicating that DmX_Vv cytopathicity is activated by amino‐terminal autoprocessing. Consistent with this, host cell protein export was affected by Vibrio cells producing a toxin with wild‐type, but not catalytically inactive, DmX_Vv. DmX_Vv was found to localize to Golgi and to directly interact with Golgi‐associated ADP‐ribosylation factors ARF1, ARF3 and ARF4, although ARF binding was not necessary for the subcellular localization. Rather, this interaction was found to induce autoprocessing of DmX_Vv. These data demonstrate that the V. vulnificus hijacks the host ARF proteins to activate the cytopathic DmX_Vv effector domain of MARTX toxin.     

Guanine nucleotide dependent formation of a complex between choleragen (cholera toxin) a subunit and bovine brain ADP-ribosylation factor

Cholera toxin activates adenylyl cyclase by catalyzing the ADP-ribosylation of Gs alpha, the stimulatory guanine nucleotide binding protein of the cyclase system. This toxin-catalyzed reaction, as well as the ADP-ribosylation of guanidino compounds and auto-ADP-ribosylation of the toxin A1 protein (CTA1), is stimulated, in the presence of GTP (or GTP analogue), by 19-21-kDa proteins, termed ADP-ribosylation factors or ARFs. These proteins directly activate CTA1 in a reaction enhanced by sodium dodecyl sulfate (SDS) or dimyristoylphosphatidylcholine (DMPC)/cholate. To determine whether ARF stimulation of ADP-ribosylation is associated with formation of a toxin-ARF complex, these proteins were incubated with guanine nucleotides and/or detergents and then subjected to gel permeation chromatography. An active ARF-toxin complex was observed in the presence of SDS and GTP gamma S [guanosine 5'-O-(3-thiotriphosphate)] but not GDP beta S [guanosine 5'-O-(2-thiodiphosphate)]. Only a fraction of the ARF was capable of complex formation. The substrate specificities of complexed and noncomplexed CTA differed; complexed CTA exhibited markedly enhanced auto-ADP-ribosylation. In the presence of GTP gamma S and DMPC/cholate, an ARF-CTA complex was not detected. A GTP gamma S-dependent ARF aggregate was observed, however, exhibiting a different substrate specificity from monomeric ARF. These studies support the hypothesis that in the presence of guanine nucleotide and either SDS or DMPC/cholate, ARF and toxin exist as multiple species which exhibit different substrate specificities.     

N‐terminal autoprocessing and acetylation of multifunctional‐autoprocessing repeats‐in‐toxins (MARTX) Makes Caterpillars Floppy‐like effector is stimulated by adenosine diphosphate (ADP)‐Ribosylation Factor 1 in advance of Golgi fragmentation

Studies have successfully elucidated the mechanism of action of several effector domains that comprise the multifunctional‐autoprocessing repeats‐in‐toxins (MARTX) toxins of Vibrio vulnificus. However, the biochemical linkage between the cysteine proteolytic activity of Makes Caterpillars Floppy (MCF)‐like effector and its cellular effects remains unknown. In this study, we identify the host cell factors that activate in vivo and in vitro MCF autoprocessing as adenosine diphosphate (ADP)‐Ribosylation Factor 1 (ARF1) and ADP‐Ribosylation Factor 3 (ARF3). Autoprocessing activity is enhanced when ARF1 is in its active [guanosine triphosphate (GTP)‐bound] form compared to the inactive [guanosine diphosphate (GDP)‐bound] form. Subsequent to auto‐cleavage, MCF is acetylated on its exposed N‐terminal glycine residue. Acetylation apparently does not dictate subcellular localization as MCF is found localized throughout the cell. However, the cleaved form of MCF gains the ability to bind to the specialized lipid phosphatidylinositol 5‐phosphate enriched in Golgi and other membranes necessary for endocytic trafficking, suggesting that a fraction of MCF may be subcellularly localized. Traditional thin‐section electron microscopy, high‐resolution cryoAPEX localization, and fluorescent microscopy show that MCF causes Golgi dispersal resulting in extensive vesiculation. In addition, host mitochondria are disrupted and fragmented. Mass spectrometry analysis found no reproducible modifications of ARF1 suggesting that ARF1 is not post‐translationally modified by MCF. Further, catalytically active MCF does not stably associate with ARF1. Our data indicate not only that ARF1 is a cross‐kingdom activator of MCF, but also that MCF may mediate cytotoxicity by directly targeting another yet to be identified protein. This study begins to elucidate the biochemical activity of this important domain and gives insight into how it may promote disease progression.     

Conformational instability of the cholera toxin A1 polypeptide

Cholera toxin (CT) moves from the cell surface to the endoplasmic reticulum (ER) by vesicular transport. In the ER, the catalytic CTA1 subunit dissociates from the holotoxin and enters the cytosol by exploiting the quality control system of ER-associated degradation (ERAD). It is hypothesized that CTA1 triggers its ERAD-mediated translocation into the cytosol by masquerading as a misfolded protein, but the process by which CTA1 activates the ERAD system remains unknown. Here, we directly assess the thermal stability of the isolated CTA1 polypeptide by biophysical and biochemical methods and correlate its temperature-dependent conformational state with susceptibility to degradation by the 20S proteasome. Measurements with circular dichroism and fluorescence spectroscopy demonstrated that CTA1 is a thermally unstable protein with a disordered tertiary structure and a disturbed secondary structure at 37 °C. A protease sensitivity assay likewise detected the temperature-induced loss of native CTA1 structure. This protease-sensitive conformation was not apparent when CTA1 remained covalently associated with the CTA2 subunit. Thermal instability in the dissociated CTA1 polypeptide could thus allow it to appear as a misfolded protein for ERAD-mediated export to the cytosol. In vitro, the disturbed conformation of CTA1 at 37 °C rendered it susceptible to ubiquitin-independent degradation by the core 20S proteasome. In vivo, CTA1 was also susceptible to degradation by a ubiquitin-independent proteasomal mechanism. ADP-ribosylation factor 6, a cytosolic eukaryotic protein that enhances the enzymatic activity of CTA1, stabilized the heat-labile conformation of CTA1 and protected it from in vitro degradation by the 20S proteasome. Thermal instability in the reduced CTA1 polypeptide has not been reported before, yet both the translocation and degradation of CTA1 may depend upon this physical property.     

Evidence for allosteric effects on p53 oligomerization induced by phosphorylation

p53 is a tetrameric protein with a thermodynamically unstable deoxyribonucleic acid (DNA)‐binding domain flanked by intrinsically disordered regulatory domains that control its activity. The unstable and disordered segments of p53 allow high flexibility as it interacts with binding partners and permits a rapid on/off switch to control its function. The p53 tetramer can exist in multiple conformational states, any of which can be stabilized by a particular modification. Here, we apply the allostery model to p53 to ask whether evidence can be found that the “activating” C‐terminal phosphorylation of p53 stabilizes a specific conformation of the protein in the absence of DNA. We take advantage of monoclonal antibodies for p53 that measure indirectly the following conformations: unfolded, folded, and tetrameric. A double antibody capture enzyme linked‐immunosorbent assay was used to observe evidence of conformational changes of human p53 upon phosphorylation by casein kinase 2 in vitro. It was demonstrated that oligomerization and stabilization of p53 wild‐type conformation results in differential exposure of conformational epitopes PAb1620, PAb240, and DO12 that indicates a reduction in the “unfolded” conformation and increases in the folded conformation coincide with increases in its oligomerization state. These data highlight that the oligomeric conformation of p53 can be stabilized by an activating enzyme and further highlight the utility of the allostery model when applied to understanding the regulation of unstable and intrinsically disordered proteins.     

Substrate-Induced Unfolding of Protein Disulfide Isomerase Displaces the Cholera Toxin A1 Subunit from Its Holotoxin

To generate a cytopathic effect, the catalytic A1 subunit of cholera toxin (CT) must be separated from the rest of the toxin. Protein disulfide isomerase (PDI) is thought to mediate CT disassembly by acting as a redox-driven chaperone that actively unfolds the CTA1 subunit. Here, we show that PDI itself unfolds upon contact with CTA1. The substrate-induced unfolding of PDI provides a novel molecular mechanism for holotoxin disassembly: we postulate the expanded hydrodynamic radius of unfolded PDI acts as a wedge to dislodge reduced CTA1 from its holotoxin. The oxidoreductase activity of PDI was not required for CT disassembly, but CTA1 displacement did not occur when PDI was locked in a folded conformation or when its substrate-induced unfolding was blocked due to the loss of chaperone function. Two other oxidoreductases (ERp57 and ERp72) did not unfold in the presence of CTA1 and did not displace reduced CTA1 from its holotoxin. Our data establish a new functional property of PDI that may be linked to its role as a chaperone that prevents protein aggregation.     

The Bordetella type III secretion system effector BteA contains a conserved N-terminal motif that guides bacterial virulence factors to lipid rafts

The Bordetella type III secretion system (T3SS) effector protein BteA is necessary and sufficient for rapid cytotoxicity in a wide range of mammalian cells. We show that BteA is highly conserved and functionally interchangeable between Bordetella bronchiseptica, Bordetella pertussis and Bordetella parapertussis . The identification of BteA sequences required for cytotoxicity allowed the construction of non-cytotoxic mutants for localization studies. BteA derivatives were targeted to lipid rafts and showed clear colocalization with cortical actin, ezrin and the lipid raft marker GM1. We hypothesized that BteA associates with the cytoplasmic face of lipid rafts to locally modulate host cell responses to Bordetella attachment. B. bronchiseptica adhered to host cells almost exclusively to GM1-enriched lipid raft microdomains and BteA colocalized to these same sites following T3SS-mediated translocation. Disruption of lipid rafts with methyl-β-cyclodextrin protected cells from T3SS-induced cytotoxicity. Localization to lipid rafts was mediated by a 130-amino-acid lipid raft targeting domain at the N-terminus of BteA, and homologous domains were identified in virulence factors from other bacterial species. Lipid raft targeting sequences from a T3SS effector (Plu4750) and an RTX-type toxin (Plu3217) from Photorhabdus luminescens directed fusion proteins to lipid rafts in a manner identical to the N-terminus of BteA.     

The mechanism of docosahexaenoic acid-induced phospholipase D activation in human lymphocytes involves exclusion of the enzyme from lipid rafts

Docosahexaenoic acid (DHA), an n-3 polyunsaturated fatty acid that inhibits T lymphocyte activation, has been shown to stimulate phospholipase D (PLD) activity in stimulated human peripheral blood mononuclear cells (PBMC). To elucidate the mechanisms underlying the DHA-induced PLD activation, we first characterized the PLD expression pattern of PBMC. We show that these cells express PLD1 and PLD2 at the protein and mRNA level and are devoid of oleate-dependent PLD activity. DHA enrichment of PBMC increased the DHA content of cell phospholipids, which was directly correlated with the extent of PLD activation. The DHA-induced PLD activation was independent of conventional protein kinase C but inhibited by brefeldin A, which suggests ADP-ribosylation factor (ARF)-dependent mechanism. Furthermore, DHA enrichment dose-dependently stimulated ARF translocation to cell membranes. Whereas 50% of the guanosine 5'-3-O-(thio)triphosphate plus ARF-dependent PLD activity and a substantial part of PLD1 protein were located to the detergent-insoluble membranes, so-called rafts, of non-enriched PBMC, DHA treatment strongly displaced them toward detergent-soluble membranes where ARF is present. Collectively, these results suggest that the exclusion of PLD1 from lipid rafts, due to their partial disorganization by DHA, and its relocalization in the vicinity of ARF, is responsible for its activation. This PLD activation might be responsible for the immunosuppressive effect of DHA because it is known to transmit antiproliferative signals in lymphoid cells.     

Host membrane glycosphingolipids and lipid microdomains facilitate Histoplasma capsulatum internalisation by macrophages

Recognition and internalisation of intracellular pathogens by host cells is a multifactorial process, involving both stable and transient interactions. The plasticity of the host cell plasma membrane is fundamental in this infectious process. Here, the participation of macrophage lipid microdomains during adhesion and internalisation of the fungal pathogen Histoplasma capsulatum (Hc) was investigated. An increase in membrane lateral organisation, which is a characteristic of lipid microdomains, was observed during the first steps of Hc–macrophage interaction. Cholesterol enrichment in macrophage membranes around Hc contact regions and reduced levels of Hc–macrophage association after cholesterol removal also suggested the participation of lipid microdomains during Hc–macrophage interaction. Using optical tweezers to study cell‐to‐cell interactions, we showed that cholesterol depletion increased the time required for Hc adhesion. Additionally, fungal internalisation was significantly reduced under these conditions. Moreover, macrophages treated with the ceramide‐glucosyltransferase inhibitor (P4r) and macrophages with altered ganglioside synthesis (from B4galnt1^?/? mice) showed a deficient ability to interact with Hc. Coincubation of oligo‐GM1 and treatment with Cholera toxin Subunit B, which recognises the ganglioside GM1, also reduced Hc association. Although purified GM1 did not alter Hc binding, treatment with P4 significantly increased the time required for Hc binding to macrophages. The content of CD18 was displaced from lipid microdomains in B4galnt1^?/? macrophages. In addition, macrophages with reduced CD18 expression (CD18^low) were associated with Hc at levels similar to wild‐type cells. Finally, CD11b and CD18 colocalised with GM1 during Hc–macrophage interaction. Our results indicate that lipid rafts and particularly complex gangliosides that reside in lipid rafts stabilise Hc–macrophage adhesion and mediate efficient internalisation during histoplasmosis.     

Compartmentalized DCC signalling is distinct from DCC localized to lipid rafts

Background information. Netrin‐1 is a bi‐functional cue that attracts or repels different classes of neurons during development. The netrin‐1 receptor DCC (deleted in colorectal cancer) acts as a tyrosine kinase‐associated receptor to mediate the attractive response towards netrin‐1. The lipid raft‐localized Src family kinase Fyn is required for DCC‐mediated axon guidance. DCC functions are also dependent on lipid rafts, membrane microdomains corresponding to a low‐density, detergent‐resistant membrane fraction. However, it remains unclear how the association of DCC with lipid rafts controls netrin‐1 signalling. Results. DCC targeted to lipid rafts represented a minor proportion of total DCC inside the cell, but predominated on the cell surface of both IMR‐32 human neuroblastoma cells and embryonic cortical neurons. Netrin‐1 accumulated in lipid rafts, but had no effect on the targeting of DCC to that compartment, with DCC remaining on the cell surface in lipid rafts through 60 min post‐treatment. However, DCC was able to interact with Fyn, both in the lipid rafts and soluble compartments isolated from embryonic E19 rat brains, whereas early downstream signalling components such as Nck‐1, and total and active focal adhesion kinase were mainly localized to the non‐lipid raft compartment. Conclusions. Together, these results suggest that DCC can be found in raft and non‐raft portions of the plasma membrane, with early signalling events propagated by non‐raft associated DCC.     

Self‐assembly of lipid rafts revealed by fluorescence correlation spectroscopy in living breast cancer cells

Lipids and proteins in the plasma membrane are laterally heterogeneous and formalised as lipid rafts featuring unique biophysical properties. However, the self‐assembly mechanism of lipid raft cannot be revealed even its physical properties and components were determined in specific physiological processes. In this study, two‐photon generalised polarisation imaging and fluorescence correlation spectroscopy were used to study the fusion of lipid rafts through the membrane phase and the lateral diffusion of lipids in living breast cancer cells. A self‐assembly model of lipid rafts associated with lipid diffusion and membrane phase was proposed to demonstrate the lipid sorting ability of lipid rafts in the plasma membrane. The results showed that the increased proportion of slow subdiffusion of G_M1‐binding cholera toxin B‐subunit (CT‐B) was accompanied with an increased liquid‐ordered domain during the β‐estradiol‐induced fusion of lipid rafts. And slow subdiffusion of CT‐B was vanished with the depletion of lipid rafts. Whereas the dialkylindocarbocyanine (DiIC₁₈) diffusion was not specifically regulated by lipid rafts. This study will open up a new insight for uncovering the self‐assembly of lipid rafts in specific pathophysiological processes.     

The lipid raft proteome of Borrelia burgdorferi

Eukaryotic lipid rafts are membrane microdomains that have significant amounts of cholesterol and a selective set of proteins that have been associated with multiple biological functions. The Lyme disease agent, Borrelia burgdorferi, is one of an increasing number of bacterial pathogens that incorporates cholesterol onto its membrane, and form cholesterol glycolipid domains that possess all the hallmarks of eukaryotic lipid rafts. In this study, we isolated lipid rafts from cultured B. burgdorferi as a detergent resistant membrane (DRM) fraction on density gradients, and characterized those molecules that partitioned exclusively or are highly enriched in these domains. Cholesterol glycolipids, the previously known raft‐associated lipoproteins OspA and OpsB, and cholera toxin partitioned into the lipid rafts fraction indicating compatibility with components of the DRM. The proteome of lipid rafts was analyzed by a combination of LC‐MS/MS or MudPIT. Identified proteins were analyzed in silico for parameters that included localization, isoelectric point, molecular mass and biological function. The proteome provided a consistent pattern of lipoproteins, proteases and their substrates, sensing molecules and prokaryotic homologs of eukaryotic lipid rafts. This study provides the first analysis of a prokaryotic lipid raft and has relevance for the biology of Borrelia, other pathogenic bacteria, as well as for the evolution of these structures. All MS data have been deposited in the ProteomeXchange with identifier PXD002365 ( http://proteomecentral.proteomexchange.org/dataset/PXD002365 ).     

Microbes and microbial Toxins: paradigms for microbial-mucosal toxins. V. Cholera: invasion of the intestinal epithelial barrier by a stably folded protein toxin

Cholera toxin (CT) produced by Vibrio cholerae is the virulence factor responsible for the massive secretory diarrhea seen in Asiatic cholera. To cause disease, CT enters the intestinal epithelial cell as a stably folded protein by co-opting a lipid-based membrane receptor, ganglioside G(M1). G(M1) sorts the toxin into lipid rafts and a retrograde trafficking pathway to the endoplasmic reticulum, where the toxin unfolds and transfers its enzymatic subunit to the cytosol, probably by dislocation through the translocon sec61p. The molecular determinants that drive entry of CT into this pathway are encoded entirely within the structure of the protein toxin itself.     

Bacterial membrane vesicles deliver peptidoglycan to NOD1 in epithelial cells

Gram‐negative bacterial peptidoglycan is specifically recognized by the host intracellular sensor NOD1, resulting in the generation of innate immune responses. Although epithelial cells are normally refractory to external stimulation with peptidoglycan, these cells have been shown to respond in a NOD1‐dependent manner to Gram‐negative pathogens that can either invade or secrete factors into host cells. In the present work, we report that Gram‐negative bacteria can deliver peptidoglycan to cytosolic NOD1 in host cells via a novel mechanism involving outer membrane vesicles (OMVs). We purified OMVs from the Gram‐negative mucosal pathogens: Helicobacter pylori, Pseudomonas aeruginosa and Neisseria gonorrhoea and demonstrated that these peptidoglycan containing OMVs upregulated NF‐κB and NOD1‐dependent responses in vitro. These OMVs entered epithelial cells through lipid rafts thereby inducing NOD1‐dependent responses in vitro. Moreover, OMVs delivered intragastrically to mice‐induced innate and adaptive immune responses via a NOD1‐dependent but TLR‐independent mechanism. Collectively, our findings identify OMVs as a generalized mechanism whereby Gram‐negative bacteria deliver peptidoglycan to cytosolic NOD1. We propose that OMVs released by bacteria in vivo may promote inflammation and pathology in infected hosts.     

AGD5 is a GTPase-activating protein at the trans-Golgi network

ARF‐GTPases are important proteins that control membrane trafficking events. Their activity is largely influenced by the interplay between guanine nucleotide exchange factors (GEFs) and GTPase‐activating proteins (GAPs), which facilitate the activation or inactivation of ARF‐GTPases, respectively. There are 15 predicted proteins that contain an ARF‐GAP domain within the Arabidopsis thaliana genome, and these are classified as ARF‐GAP domain (AGD) proteins. The function and subcellular distribution of AGDs, including the ability to activate ARF‐GTPases in vivo, that remain largely uncharacterized to date. Here we show that AGD5 is localised to the trans‐Golgi network (TGN), where it co‐localises with ARF1, a crucial GTPase that is involved in membrane trafficking and which was previously shown to be distributed on Golgi and post‐Golgi structures of unknown nature. Taking advantage of the in vivo AGD5–ARF1 interaction at the TGN, we show that mutation of an arginine residue that is critical for ARF‐GAP activity of AGD5 leads to longer residence of ARF1 on the membranes, as expected if GTP hydrolysis on ARF1 was impaired due to a defective GAP. Our results establish the nature of the post‐Golgi compartments in which ARF1 localises, as well as identifying the role of AGD5 in vivo as a TGN‐localised GAP. Furthermore, in vitro experiments established the promiscuous interaction between AGD5 and the plasma membrane‐localised ADP ribosylation factor B (ARFB), confirming that ARF‐GAP specificity for ARF‐GTPases within the cell environment may be spatially regulated.     

Ionic strength‐dependent conformations of a ubiquitin‐like small archaeal modifier protein (SAMP1) from Haloferax volcanii

Eukaryotic ubiquitin and ubiquitin‐like systems play crucial roles in various cellular biological processes. In this work, we determined the solution structure of SAMP1 from Haloferax volcanii by NMR spectroscopy. Under low ionic conditions, SAMP1 presented two distinct conformations, one folded β‐grasp and the other disordered. Interestingly, SAMP1 underwent a conformational conversion from disorder to order with ion concentration increasing, indicating that the ordered conformation is the functional form of SAMP1 under the physiological condition of H. volcanii. Furthermore, SAMP1 could interact with proteasome‐activating nucleotidase B, supposing a potential role of SAMP1 in the protein degradation pathway mediated by proteasome.     

Cholera toxin binds to lipid rafts but has a limited specificity for ganglioside GM1

Lipid rafts and the formation of an immunological synapse are crucial for T-cell activation. Binding of cholera toxin B subunit (CTB) to ganglioside GM1 is a marker to identify lipid rafts. Primary human T cells were isolated from healthy donors and were stimulated with superantigen staphylococcus enterotoxin B (SEB) and stained with cholera toxin B-fluorescein isothiocyanate (CTB-FITC). An optimized staining procedure is required to stain lipid rafts exclusively on the cell surface. Unstimulated T cells show a few CTB binding spots on the cell surface. The size and number of CTB-binding lipid rafts are strongly upregulated during T-cell activation in SEB-stimulated CD4(+) T cells. However, our data show that the specificity of CTB for GM1 ganglioside is limited, because the binding capacity is partly resistant to inhibition of ganglioside synthesis and sensitive to trypsin digestion. Our results indicate that the binding of FITC-labeled CTB can be divided into at least three different categories: a specific binding of CTB to ganglioside GM1, a nonspecific binding of CTB probably to glycosylated surface proteins and a nonspecific binding of FITC to the cell surface.