Rat RT1.B-transfected fibroblast lines process and present myelin antigens and activate T cells to induce experimental autoimmune encephalomyelitis.

The genes encoding the Lewis rat RT1.B molecule (MHC Class II I-A equivalent) were transfected and expressed in mouse DAP.3 fibroblast cells together with the gene encoding the mouse ICAM-1 molecule. Both molecules were stably expressed on the cell surface of DAP.3 cells under longterm culture conditions. The RT1.B/mICAM-1 transfectants presented antigen in a specific manner to a RT1. B-restricted rat T cell hybridoma specific for the 69-89 peptide of myelin basic protein (BP). In addition, the transfectants were able to present antigen to a BP69-89-specific rat T cell line. Presentation to a RT1.D (MHC Class II I-E equivalent)-restricted BP87-99-specific T cell line was minimal. Production of the Th1 cytokine IFN-gamma by BP69-89-specific T cells when stimulated by RT1.B/mICAM-1 transfectants correlated very well with proliferation to specific antigen. Moreover, RT1.B-transfected DAP.3 cells sufficiently stimulated BP69-89-specific T cells such that they were able to transfer experimental autoimmune encephalomyelitis (EAE) to Lewis rat recipients. Thus, the RT1.B molecule is functionally expressed on the surface of transfected Dap.3 fibroblasts and is capable of MHC Class II-restricted, antigen-specific presentation to rat T cells.

Role of amino- and carboxyl-terminal regions of G(alphaZ) in the recognition of Gi-coupled receptors.

Many Gi-coupled receptors are known to interact with the pertussis toxin (PTX)-insensitive Gz protein. Given that the alpha subunits of Gi and Gz share only 60% identity in their amino acid sequences, their receptor-interacting domains must be highly similar. By swapping the carboxyl termini of alpha i2 and alpha z with each other or with those of alpha t, alpha12, and alpha13, we examined the relative contributions of the carboxyl-end 36 amino acids of the alpha chains toward receptor recognition. Chimeric alpha chains lacking the site for PTX-catalyzed ADP-ribosylation were coexpressed with the type II adenylyl cyclase (AC II) and one of several Gi-coupled receptors (formyl peptide, dopamine D2, and delta-opioid receptors) in human embryonic kidney 293 cells. The alpha i2/alpha z chimera was able to interact with both aminergic and peptidergic receptors, resulting in betagamma-mediated stimulation of AC II in the presence of agonists and PTX. Functional and mutational analyses of alpha i2/alpha z revealed that this chimera can inhibit the endogenous ACs of 293 cells. Similarly, the alpha z/alpha i2 chimera seemed to retain the abilities to interact with receptors and inhibit cAMP accumulation. Fusion of the carboxyl-terminal 36 amino acids of alpha z to a backbone of alpha t1 produced a chimera, alpha t1/alpha z, that did not couple to any of the Gi-coupled receptors tested. Interestingly, an alpha13/alpha z chimera (with only the last five amino acids switched) displayed differential abilities to interact with receptors. Signals from aminergic, but not peptidergic, receptors were transduced by alpha13/alpha z. A similar construct, alpha12/alpha z, behaved just like alpha13/alpha z. These results indicated that "alpha i-like" or "alpha z-like" sequences at the carboxyl termini of alpha subunits are not always necessary or sufficient for specifying interaction with Gi-coupled receptors.

A TCR V alpha CDR3-specific motif associated with Lewis rat autoimmune encephalomyelitis and basic protein-specific T cell clones.

To investigate TCR V alpha gene expression in the Lewis rat model of experimental autoimmune encephalomyelitis, we obtained V alpha chain sequences from two V beta8.2+-encephalitogenic, BP72-89-specific T cell clones. Two different V alpha genes, a V alpha2 gene and a V alpha23 gene, are utilized, but both were found to contain an asparagine repeat (Asn3+) sequence present in the V alpha CDR3 region. This Asn3+ motif is also present in the previously reported sequence of a BP68-88-specific hybridoma, 510, which utilizes a different V alpha2 gene family member. In further experiments, spinal cord T cells were isolated at the onset of basic protein (BP)-induced disease and sorted for the OX-40 activation marker, which we have previously used to enrich for specifically activated T cells. Analysis of V alpha expression in the OX-40+ population revealed the biased use of three V alpha genes, V alpha1, V alpha2, and V alpha23. The Asn3+ motif was present in the V alpha CDR3 region of V alpha1, V alpha2, and V alpha23 cDNA derived from OX-40+ spinal cord T cells but found to be generally absent in the OX-40- spinal cord population. Since these Asn3+ motif-bearing V alpha chain sequences are nearly identical to those utilized by the BP-specific encephalitogenic clones described, it is likely that these V alpha sequences are derived from disease-associated T cells in the spinal cord. Thus, we demonstrate that the Asn3+ V alpha CDR3 motif is strongly associated with experimental autoimmune encephalomyelitis in the Lewis rat and propose that it plays a role in TCR recognition of a specific BP peptide/MHC complex.

Myelin basic protein-specific and TCR V beta 8.2-specific T-cell lines from TCR V beta 8.2 transgenic mice utilize the same V alpha and V beta genes: specificity associated with the V alpha CDR3-J alpha region.

Our analysis of TCR V gene usage in mice transgenic for the V beta 8.2 gene has demonstrated that T cells isolated from the spinal cord of these transgenic mice during active experimental autoimmune encephalomyelitis were significantly biased for V alpha 2 expression. This V alpha 2 bias was noted in T cells derived from the periphery as well but only after stimulation with specific antigen. Thus, spinal cord-derived pathogenic T cells had already undergone activation and expansion within the central nervous system environment of these mice. As part of an investigation of regulatory function in these V beta 8.2 transgenic mice, two T cell lines were selected. The first T cell line is encephalitogenic and specific for the dominant myelin basic protein peptide NAc1-11, while the second T cell line is specific for the V beta 8.2 protein. Surprisingly, polymerase chain reaction and sequence analysis of the TCR from both the T cell lines demonstrated that they utilize identical V beta, D beta, J beta, and V alpha gene segments. The only difference found was in their use of the J alpha gene segment, indicating that this region of the TCR molecule can play a key role in determining antigen specificity.

Gi-mediated stimulation of type II adenylyl cyclase is augmented by Gq-coupled receptor activation and phorbol ester treatment.

Synergism between Gs- and Gi- or Gq-dependent signaling pathways has been demonstrated in the stimulation of type II adenylyl cyclase (AC-II). Provision of activated alpha s is known to allow numerous Gi-coupled receptors to stimulate AC-II and to potentiate the responses to Gq-coupled receptors. To explore possible interactions between Gi- and Gq-coupled receptors that are independent of alpha s, the activity of AC-II was determined after the activation of Gi- and Gq-regulated pathways. Human embryonic kidney 293 cells were transiently cotransfected with cDNAs encoding AC-II and various G-protein-coupled receptors. Agonist-bound Gi-coupled receptors (including the formyl peptide, dopamine-D2, and delta-opioid receptors) stimulated AC-II activity in the absence of activated alpha s, provided that the cells were treated with 100 nM phorbol 12-myristate 13-acetate. Activation of protein kinase C (PKC) thus appears to relieve the requirement for the presence of activated alpha s. Stimulation of PKC via Gq-coupled receptors also allowed Gi-coupled receptors to activate AC-II. Coexpression of the m1 muscarinic receptor with the dopamine-D2 receptor permitted dopamine to stimulate AC-II in the presence of carbachol. The phorbol ester-permissive and alpha s-independent stimulation was mediated by G-protein beta gamma subunits because it was blocked by the beta gamma scavengers alpha t and beta-adrenergic receptor kinase. These results show that AC-II can efficiently integrate signals generated by Gq- and Gi-coupled receptors via a mechanism that is independent of Gs.

Differential coupling of the formyl peptide receptor to adenylate cyclase and phospholipase C by the pertussis toxin-insensitive Gz protein.

In neutrophils, activation of receptors for the chemotactic peptide N-formylmethionyl-leucyl-phenylalanine (fMLP) leads to changes in intracellular events such as phosphoinositide turnover and Ca2+ mobilization. Studies have shown that activation of the cloned fMLP receptor can also lead to inhibition of cyclic AMP (cAMP) accumulation [Lang, Boulay, Li and Wollheim (1993) EMBO J. 12, 2671-2679; Uhing, Gettys, Tomhave, Snyderman and Didsbury (1992) Biochem. Biophys. Res. Commun. 183, 1033-1039]. These responses are apparently mediated through pertussis toxin-sensitive Gi proteins. Since other chemotactic factor receptors can couple to multiple G proteins, we examined the ability of the fMLP receptor to utilize a pertussis toxin-insensitive G protein, Gz, in its signal transduction pathways. The human fMLP receptor was transiently expressed in 293 and Ltk- cells, and subsequently assayed for receptor-mediated inhibition of cAMP accumulation and stimulation of phosphoinositide-specific phospholipase C. In transfected 293 cells, fMLP inhibited choriogonadotropin-stimulated cAMP accumulation by 50% and the response could be abolished by pertussis toxin. Co-expression of the fMLP receptor with the alpha subunit of Gz rendered the fMLP response pertussis toxin-insensitive, indicating that the endogenous Gi proteins can be substituted efficiently by Gz. In contrast, Ltk- cells expressing the fMLP receptor were able to respond to fMLP with an increase in the production of inositol phosphates, but this response was completely abolished by pertussis toxin even in cells co-expressing the alpha subunit of Gz. Thus, although both signalling pathways appeared to utilize Gi-like proteins, Gz can only replace Gi in mediating inhibition of cAMP accumulation, and not in the stimulation of phospholipase C. Differential interaction with Gz might represent a novel mechanism by which fMLP receptors regulate intracellular events.

Regulation of multiple effectors by the cloned delta-opioid receptor: stimulation of phospholipase C and type II adenylyl cyclase.

The delta-opioid receptor is known to regulate multiple effectors in various tissues. When expressed in human embryonic kidney 293 cells, the cloned delta-opioid receptor inhibited cyclic AMP (cAMP) accumulation in response to the delta-selective agonist [D-Pen2,D-Pen5]-enkephalin. The inhibitory response of [D-Pen2,D-Pen5]-enkephalin was dependent on the expression of the delta-opioid receptor and exhibited an EC50 of 1 nM. The receptor showed ligand selectivity and a pharmacological profile that is appropriate for the delta-opioid subtype. The inhibition was blocked by the opiate antagonist naloxone or by pretreatment of the cells with pertussis toxin. Co-transfection of the delta-opioid receptor with type II adenylyl cyclase and an activated mutant of alpha s converted the delta-opioid signal from inhibition to stimulation of cAMP accumulation. It is interesting that when transfected into Ltk-fibroblasts, the cloned delta-opioid receptor was able to stimulate the formation of inositol phosphates (EC50 = 8 nM). This response was sensitive to pertussis toxin. The opioid-mediated formation of inositol phosphates exhibited the same ligand selectivity as seen with the inhibition of cAMP accumulation. The ability of the delta-opioid receptor to couple to G proteins other than Gi was also examined. Cotransfection studies revealed that the delta-opioid receptor can utilize Gz to regulate cAMP accumulation and to stimulate the formation of inositol phosphates.

Stimulation of type II adenylyl cyclase by chemoattractant formyl peptide and C5a receptors.

The capacity of N-formylmethionyl-leucyl-phenylalanine (fMLP) and C5a receptors to regulate type II adenylyl cyclase was examined in transient transfection studies. Coexpression of either one of the chemoattractant receptors with type II adenylyl cyclase in human embryonic kidney 293 cells allowed the corresponding chemotactic factor to stimulate cAMP accumulation in a dose-dependent manner. The chemoattractant-induced stimulation of type II adenylyl cyclase was absolutely dependent on the presence of GTP-bound alpha subunit of GS, as revealed by the coexpression of alpha s-Q227L, a constitutively activated mutant of alpha s. Stimulation of type II adenylyl cyclase by either fMLP or C5a was mediated via pertussis toxin-sensitive Gi-like proteins, because the response was abrogated by the toxin. The ability of Gz (a pertussis toxin-insensitive G protein that can couple to a number of Gi-linked receptors) to replace Gi in chemoattractant-induced stimulation of type II adenylyl cyclase was examined. The chemoattractant-induced response became insensitive to pertussis toxin upon coexpression of the alpha subunit of Gz. Interestingly, coexpression of alpha z significantly enhanced the chemotactic factor-stimulated type II adenylyl cyclase activities. When other G protein alpha subunits were tested under similar experimental conditions, all three forms of alpha 1 and alpha o1 were able to potentiate the fMLP response to various extents, whereas alpha q and alpha t slightly inhibited the fMLP response. The alpha subunit-mediated potentiation of the type II adenylyl cyclase response appears to reflect a productive coupling between alpha subunits and the fMLP receptor, because such enhancements were not seen with the constitutively activated alpha subunit mutants. Coexpression of the constitutively activated mutants of alpha z, alpha q, alpha 01, and alpha i1-3 neither enhanced nor inhibited the fMLP-stimulated cAMP accumulation. These results indicated that the observed enhancement of type II adenylyl cyclase responses was dependent on the ability of the wild-type alpha subunits to functionally interact with the fMLP receptor and that the fMLP receptor can couple to Gi1-3, Gz, and Go1 but not to Gs, Gq, or Gt.