Distorted TCR repertoires define multisystem inflammatory syndrome in children.

While the majority of children infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) display mild or no symptoms, rare individuals develop severe disease presenting with multisystem inflammatory syndrome (MIS-C). The reason for variable clinical manifestations is not understood. Here, we carried out TCR sequencing and conducted comparative analyses of TCR repertoires between children with MIS-C (n = 12) and mild (n = 8) COVID-19. We compared these repertoires with unexposed individuals (samples collected pre-COVID-19 pandemic: n = 8) and with the Adaptive Biotechnologies MIRA dataset, which includes over 135,000 high-confidence SARS-CoV-2-specific TCRs. We show that the repertoires of children with MIS-C are characterised by the expansion of TRBV11-2 chains with high junctional and CDR3 diversity. Moreover, the CDR3 sequences of TRBV11-2 clones shift away from SARS-CoV-2 specific T cell clones, resulting in distorted TCR repertoires. In conclusion, our study reports that CDR3-independent expansion of TRBV11-2+ cells, lacking SARS-CoV-2 specificity, defines MIS-C in children.

Control of feeding behavior in C. elegans by human G protein-coupled receptors permits screening for agonist-expressing bacteria.

G protein-coupled receptors (GPCRs) have a key role in many biological processes and are important drug targets for many human diseases. Therefore, understanding the molecular interactions between GPCRs and their ligands would improve drug design. Here, we describe an approach that allows the rapid identification of functional agonists expressed in bacteria. Transgenic Caenorhabditis elegans expressing the human chemokine receptor 5 (CCR5) in nociceptive neurons show avoidance behavior on encounter with the ligand MIP-1alpha and avoid feeding on Escherichia coli expressing MIP-1alpha compared with control bacteria. This system allows a simple activity screen, based on the distribution of transgenic worms in a binary food-choice assay, without a requirement for protein purification or tagging. By using this approach, a library of 68 MIP-1alpha variants was screened, and 13 critical agonist residues involved in CCR5 activation were identified, four of which (T8, A9, N22, and A25) have not been described previously, to our knowledge. Identified residues were subsequently validated in receptor binding assays and by calcium flux assays in mammalian cells. This approach serves not only for structure/function studies as demonstrated, but may be used to facilitate the discovery of agonists within bacterial libraries.

Expression of mammalian GPCRs in C. elegans generates novel behavioural responses to human ligands.

BACKGROUND: G-protein-coupled receptors (GPCRs) play a crucial role in many biological processes and represent a major class of drug targets. However, purification of GPCRs for biochemical study is difficult and current methods of studying receptor-ligand interactions involve in vitro systems. Caenorhabditis elegans is a soil-dwelling, bacteria-feeding nematode that uses GPCRs expressed in chemosensory neurons to detect bacteria and environmental compounds, making this an ideal system for studying in vivo GPCR-ligand interactions. We sought to test this by functionally expressing two medically important mammalian GPCRs, somatostatin receptor 2 (Sstr2) and chemokine receptor 5 (CCR5) in the gustatory neurons of C. elegans. RESULTS: Expression of Sstr2 and CCR5 in gustatory neurons allow C. elegans to specifically detect and respond to somatostatin and MIP-1alpha respectively in a robust avoidance assay. We demonstrate that mammalian heterologous GPCRs can signal via different endogenous Galpha subunits in C. elegans, depending on which cells it is expressed in. Furthermore, pre-exposure of GPCR transgenic animals to its ligand leads to receptor desensitisation and behavioural adaptation to subsequent ligand exposure, providing further evidence of integration of the mammalian GPCRs into the C. elegans sensory signalling machinery. In structure-function studies using a panel of somatostatin-14 analogues, we identified key residues involved in the interaction of somatostatin-14 with Sstr2. CONCLUSION: Our results illustrate a remarkable evolutionary plasticity in interactions between mammalian GPCRs and C. elegans signalling machinery, spanning 800 million years of evolution. This in vivo system, which imparts novel avoidance behaviour on C. elegans, thus provides a simple means of studying and screening interaction of GPCRs with extracellular agonists, antagonists and intracellular binding partners.

A human TAPBP (TAPASIN)-related gene, TAPBP-R.

TAPASIN, a V-C1 (variable-constant) immunoglobulin superfamily (IgSF) molecule that links MHC class I molecules to the transporter associated with antigen processing (TAP) in the endoplasmic reticulum (ER) is encoded by the TAPBP gene, located near to the MHC at 6p21.3. A related gene was identified at chromosome position 12p13.3 between the CD27 and VAMP1 genes near a group of MHC-paralogous loci. The gene, which we have called TAPBP-R (R for related), also encodes a member of the IgSF, TAPASIN-R. Its putative product contains similar structural motifs to TAPASIN, with some marked differences, especially in the V domain, transmembrane and cytoplasmic regions. By using the mouse ortholog to screen tissue, we revealed that the TAPBP-R gene was broadly expressed. Sub-cellular localization showed that the bulk of TAPASIN-R is located within the ER but biotinylation experiments were consistent with some expression at thecell surface. TAPASIN-R lacks an obvious ER retention signal. The function of TAPASIN-R will be of interest in regards to the evolution of the immune system as well as antigen processing.