Recognition of carbohydrate by major histocompatibility complex class I-restricted, glycopeptide-specific cytotoxic T lymphocytes

6 pages, 5 figures.-- PMID: 8046349 [PubMed].-- PMCID: PMC2191607.Cytotoxic T cells (CTL) recognize short peptide epitopes presented by class I glycoproteins encoded by the major histocompatibility complex (MHC). It is not yet known whether peptides containing posttranslationally modified amino acids can also be recognized by CTL. To address this issue, we have studied the immunogenicity and recognition of a glycopeptide carrying an O-linked N-acetylglucosamine (GlcNAc) monosaccharide-substituted serine residue. This posttranslational modification is catalyzed by a recently described cytosolic glycosyltransferase. We show that glycosylation does not affect peptide binding to MHC class I and that glycopeptides can elicit a strong CTL response that is glycopeptide specific. Furthermore, glycopeptide recognition by cytotoxic T cells is dependent on the chemical structure of the glycan as well as its position within the peptide.We wish to thank Dr. Elena Sadovnikova and Dr. Hans J. Stanss (Imperial Cancer Research Foundation, London, UK) for their valuable help with raising antipeptide CTLs; and Professor Jens Chr. Jensenius (University of Aarbus, Denmark) for helpful discussions. J. S. Haurum is a Carlsberg-Wellcome Travelling Research Fellow, G. Asequell is an EC Fellow, and A. C. Lellouch is supported by a United States Public Health Service National Research Service Award F32 GM- 15811. This work was supported by the Carlsberg Foundation, the Wellcome trust, the Beckett Foundation, and Statens Sundhedsvidenskabelige Forskningsr~d, Denmark.Peer reviewe

Formation of polarized contractile interfaces by self-organized Toll-8/Cirl GPCR asymmetry

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Expression and Study of Recombinant ExoM, a β1-4 Glucosyltransferase Involved in Succinoglycan Biosynthesis in Sinorhizobium meliloti

Here we report on the overexpression and in vitro characterization of a recombinant form of ExoM, a putative β1-4 glucosyltransferase involved in the assembly of the octasaccharide repeating subunit of succinoglycan from Sinorhizobium meliloti. The open reading frame exoM was isolated by PCR and subcloned into the expression vector pET29b, allowing inducible expression under the control of the T7 promoter. Escherichia coli BL21(DE3)/pLysS containing exoM expressed a novel 38-kDa protein corresponding to ExoM in N-terminal fusion with the S-tag peptide. Cell fractionation studies showed that the protein is expressed in E. coli as a membrane-bound protein in agreement with the presence of a predicted C-terminal transmembrane region. E. coli membrane preparations containing ExoM were shown to be capable of transferring glucose from UDP-glucose to glycolipid extracts from an S. meliloti mutant strain which accumulates the ExoM substrate (Glcβ1-4Glcβ1-3Gal-pyrophosphate-polyprenol). Thin-layer chromatography of the glycosidic portion of the ExoM product showed that the oligosaccharide formed comigrates with an authentic standard. The oligosaccharide produced by the recombinant ExoM, but not the starting substrate, was sensitive to cleavage with a specific cellobiohydrolase, consistent with the formation of a β1-4 glucosidic linkage. No evidence for the transfer of multiple glucose residues to the glycolipid substrate was observed. It was also found that ExoM does not transfer glucose to an acceptor substrate that has been hydrolyzed from the polyprenol anchor. Furthermore, neither glucose, cellobiose, nor the trisaccharide Glcβ1-4Glcβ1-3Glc inhibited the transferase activity, suggesting that some feature of the lipid anchor is necessary for activity

Nano-clustering of ligands on surrogate antigen presenting cells modulates T cell membrane adhesion and organization

International audienceWe investigate the adhesion and molecular organization of the plasma membrane of T lymphocytes interacting with a surrogate antigen presenting cell comprising glass supported ordered arrays of antibody (alpha-CD3) nano-dots dispersed in a non-adhesive matrix of polyethylene glycol (PEG). The local membrane adhesion and topography, as well as the distribution of the T cell receptors (TCRs) and the kinase ZAP-70, are influenced by dot-geometry, whereas the cell spreading area is determined by the overall average density of the ligands rather than specific characteristics of the dots. TCR clusters are recruited preferentially to the nano-dots and the TCR cluster size distribution has a weak dot-size dependence. On the patterns, the clusters are larger, more numerous, and more enriched in TCRs, as compared to the homogeneously distributed ligands at comparable concentrations. These observations support the idea that non-ligated TCRs residing in the non-adhered parts of the proximal membrane are able to diffuse and enrich the existing clusters at the ligand dots. However, long distance transport is impaired and cluster centralization in the form of a central supramolecular cluster (cSMAC) is not observed. Time-lapse imaging of early cell-surface contacts indicates that the ZAP-70 microclusters are directly recruited to the site of the antibody dots and this process is concomitant with membrane adhesion. These results together point to a complex interplay of adhesion, molecular organization and activation in response to spatially modulated stimulation

Peptide microarrays for the detection of molecular interactions in cellular signal transduction.

The formation of protein complexes is a hallmark of cellular signal transduction. Here, we show that peptide microarrays provide a robust and quantitative means to detect signalling-dependent changes of molecular interactions. Recruitment of a protein into a complex upon stimulation of a cell leads to the masking of an otherwise exposed binding site. In cell lysates this masking can be detected by reduced binding to a microarray carrying a peptide that corresponds to the binding motif of the respective interaction domain. The method is exemplified for the lymphocyte-specific tyrosine kinase 70 kDa zeta-associated protein binding to a bis-phosphotyrosine-motif of the activated T-cell receptor via its tandem SH2 domain. Compared to established techniques, the method provides a significant shortcut to the detection of molecular interactions

Lymphocytes can self-steer passively with wind vane uropods

International audienceA wide variety of cells migrate directionally in response to chemical or mechanical cues, however the mechanisms involved in cue detection and translation into directed movement are debatable. Here, we investigate a model of lymphocyte migration on the inner surface of blood vessels. Cells orient their migration against fluid flow, suggesting the existence of an adaptive mechano-tranduction mechanism. We find that flow detection may not require molecular mechano-sensors of shear stress and detection of flow direction can be achieved by the orientation in the flow of the non-adherent cell rear, the uropod. Uropods act as microscopic wind vanes that can transmit detection of flow direction into cell steering via the on-going machinery of polarity maintenance, without need for novel internal guidance signalling triggered by flow. Contrary to chemotaxis, which implies active regulation of cue-dependant signalling, upstream flow mechanotaxis of lymphocytes may only rely on a passive self-steering mechanism

Chemical inhibitors when timing is critical: a pharmacological concept for the maturation of T cell contacts.

Cellular signal transduction proceeds through a complex network of molecular interactions and enzymatic activities. The timing of these molecular events is critical for the propagation of a signal and the generation of a specific cellular response. To define the timing of signalling events, we introduce the combination of high-resolution confocal microscopy with the application of small-molecule inhibitors at various stages of signal transduction in T cells. Inhibitors of Src-family tyrosine kinases and actin dynamics were employed to dissect the role of the lymphocyte-specific tyrosine kinase Lck in the formation and maintenance of T cell receptor/CD3-dependent contacts. Anti-CD3epsilon-coated coverslips served as a highly defined stimulus. The kinetics of the recruitment of the yellow fluorescent protein-tagged signalling protein ZAP-70 were detected by high-resolution confocal microscopy. The analysis revealed that at 5 min after receptor engagement, Lck activity was required for maintenance of contacts. In contrast, after 20 min of receptor engagement, the contacts were Lck-independent. The relevance of the timing of inhibitor application provides a pharmacological concept for the maturation of T cell-substrate contacts

T Lymphocytes Orient against the Direction of Fluid Flow during LFA-1-Mediated Migration.

International audienceAs they leave the blood stream and travel to lymph nodes or sites of inflammation, T lymphocytes are captured by the endothelium and migrate along the vascular wall to permissive sites of transmigration. These processes take place under the influence of hemodynamic shear stress; therefore, we investigated how migrational speed and directionality are influenced by variations in shear stress. We examined human effector T lymphocytes on intercellular adhesion molecule 1 (ICAM-1)-coated surfaces under the influence of shear stresses from 2 to 60 dyn.cm(-2). T lymphocytes were shown to respond to shear stress application by a rapid (30 s) and fully reversible orientation of their migration against the fluid flow without a change in migration speed. Primary T lymphocytes migrating on ICAM-1 in the presence of uniformly applied SDF-1α were also found to migrate against the direction of shear flow. In sharp contrast, neutrophils migrating in the presence of uniformly applied fMLP and leukemic HSB2 T lymphocytes migrating on ICAM-1 alone oriented their migration downstream, with the direction of fluid flow. Our findings suggest that, in addition to biochemical cues, shear stress is a contributing factor to leukocyte migration directionality