Abdijapar Shamshiev

IL-21R on T Cells Is Critical for Sustained Functionality and Control of Chronic Viral Infection

Controlling Chronic Viral Infections Chronic viral infections such as HIV and hepatitis B and C viruses are major public health concerns. T cell—mediated immune responses are critical for controlling viral infections. In contrast to acute infections, chronic viral infections are characterized by “exhausted” cytotoxic CD8+ T cells, cells which exhibit reduced proliferative capacity, cytokine secretion, and cytotoxicity. Treatments that reverse exhaustion result in increased viral control. Despite their exhaustion, these CD8+ T cells eventually help to control chronic infections by killing virally infected cells, and require CD4+ T cell help to do so. How do CD4+ T cells provide help to CD8+ T cells during chronic infection (see the Perspective by Johnson and Jameson)? Elsaesser et al. (p. 1569, published online 7 May), Yi et al. (p. 1572, published online 14 May), and Fröhlich et al. (p. 1576, published online 28 May) now show that the cytokine, interleukin-21 (IL-21), known to be critical for the differentiation of certain CD4+ T cell effector subsets, is an essential factor produced by CD4+ T cells that helps CD8+ T cells to control chronic lymphocytic choriomeningitis virus infection in mice. Acute and chronic infections resulted in differing amounts of IL-21 production by virus-specific CD4+ T cells. CD8+ T cells required IL-21 directly, and when CD8+ T cells were unable to signal through IL-21 or IL-21 was not available, they were reduced in number, exhibited a more exhausted phenotype, and were not able to control the virus. In contrast, the absence of IL-21–dependent signaling did not affect primary CD8+ T cell responses to acute infection or responses to a viral rechallenge, suggesting that differentiation of memory CD8+ T cells is independent of IL-21. Thymus cells of the immune system require the cytokine interleukin-21 to control chronic viral infections. Chronic viral infection is often associated with the dysfunction of virus-specific T cells. Our studies using Il21r-deficient (Il21r–/–) mice now suggest that interleukin-21 (IL-21) is critical for the long-term maintenance and functionality of CD8+ T cells and the control of chronic lymphocytic choriomeningitis virus infection in mice. Cell-autonomous IL-21 receptor (IL-21R)–dependent signaling by CD8+ T cells was required for sustained cell proliferation and cytokine production during chronic infection. Il21r–/– mice showed normal CD8+ T cell expansion, effector function, memory homeostasis, and recall responses during acute and after resolved infection with several other nonpersistent viruses. These data suggest that IL-21R signaling is required for the maintenance of polyfunctional T cells during chronic viral infections and have implications for understanding the immune response to other persisting antigens, such as tumors.

Self glycolipids as T-cell autoantigens.

Multiple sclerosis (MS) is a chronic inflammatory disease of the central nervous system characterized by discrete areas of demyelination. An autoimmune response against components of myelin is thought to contribute to disease pathogenesis. Here we identify glycolipids as new targets recognized by T cells in multiple sclerosis patients. Circulating T cells reactive with glycolipids are more frequent in MS patients than in control donors as shown by enzyme‐linked immunospot assay. They specifically recognize different types of glycolipids, such as gangliosides, sulfatide and galactosylceramide and release IFN‐γ and TNF‐α. T cells specific for gangliosides were found to be CD8+, TCR α β+, restricted by the MHC‐like CD1b molecule and specific for epitopes residing in the carbohydrate moiety of gangliosides. Our findings suggest that in addition to self proteins, self glycolipids may represent potential source of autoantigens recognized by T cells in autoimmune diseases.

Presentation of the same glycolipid by different CD1 molecules.

Five CD1 molecules are expressed in humans and it is unclear whether they have specialized or redundant functions. We found that sulfatide is a promiscuous CD1-binding ligand and have isolated T cell clones that are specific for sulfatide and restricted by distinct CD1 molecules. These clones have been used to compare the capacity of different CD1 to present the same glycolipid, to induce effector functions, and to form persistent immunogenic complexes. CD1a, CD1b, and CD1c molecules similarly load sulfatide on the cell surface without processing, and prime Th1 and Th2 responses. Stimulation by sulfatide-loaded CD1a persists much longer than that by CD1b and CD1c in living cells. Use of recombinant soluble CD1a confirmed the prolonged capacity to stimulate T cells. Moreover, other glycosphingolipids bind to all CD1, which suggests the presence of additional promiscuous ligands. Thus, group I CD1 molecules present an overlapping set of self-glycolipids, even though they are quite divergent from an evolutionary point of view.

TLR Signaling Fine-Tunes Anti-Influenza B Cell Responses without Regulating Effector T Cell Responses

Influenza is a ssRNA virus that has been responsible for widespread morbidity and mortality; however, the innate immunological mechanisms that drive the adaptive anti-influenza immune response in vivo are yet to be fully elucidated. TLRs are pattern recognition receptors that bind evolutionarily conserved pathogen-associated molecular patterns, induce dendritic cell maturation, and consequently aid the development of effective immune responses. We have examined the role of TLRs in driving effective T and B cell responses against influenza virus. We found TLR3 and its associated adapter molecule, Toll/IL-R domain-containing adaptor-inducing IFN-β, did not play a role in the development of CD4+ or CD8+ T cell responses against influenza virus, nor did they influence influenza-specific B cell responses. Surprisingly, TLR7 and MyD88 also played negligible roles in T cell activation and effector function upon infection with influenza virus; however, their signaling was critical for regulating anti-influenza B cell Ab isotype switching. The induction of appropriate anti-influenza humoral responses involved stimulation of TLRs on B cells directly and TLR-induced production of IFN-α, which acted to reduce IgG1 and increase IgG2a/c class switching. Notably, direct TLR signaling on B cells or T cell help through the CD40-CD40L interaction was sufficient to support B cell proliferation and IgG1 production, whereas IFN-α was critical for fine-tuning the nature of the isotype switch. Taken together, these data reveal that TLR signaling is not required for anti-influenza T cell responses, but through both direct and indirect means orchestrates appropriate anti-influenza B cell responses.

The αβ T Cell Response to Self-Glycolipids Shows a Novel Mechanism of CD1b Loading and a Requirement for Complex Oligosaccharides

The structural basis for the T cell recognition of lipoglycans remains to be elucidated. We have described autoreactive T cells responsive to GM1 ganglioside presented by CD1b. We show that glycosphingolipids bind to CD1b on the cell surface at neutral pH and are recognized without internalization or processing. Furthermore, soluble GM-CD1b complexes stimulate specific T cells. Oligosaccharide groups containing five or more sugars are required to build a minimal epitope for TCR recognition. This suggests a mechanism for T cell recognition of glycosphingolipids in which much of the CD1b-bound ligand is exposed. Binding to CD1b is a highly reversible process and other ceramide-containing glycosphingolipids displace GM1. These nonantigenic compounds act as blockers and may prevent harmful autoreactivity in vivo.

Nrf2 is essential for cholesterol crystal-induced inflammasome activation and exacerbation of atherosclerosis.

Oxidative stress and inflammation — two components of the natural host response to injury — constitute important etiologic factors in atherogenesis. The pro‐inflammatory cytokine interleukin (IL)‐1 significantly enhances atherosclerosis, however, the molecular mechanisms of IL‐1 induction within the artery wall remain poorly understood. Here we have identified the oxidative stress‐responsive transcription factor NF‐E2‐related 2 (Nrf2) as an essential positive regulator of inflammasome activation and IL‐1‐mediated vascular inflammation. We show that cholesterol crystals, which accumulate in atherosclerotic plaques, represent an endogenous danger signal that activates Nrf2 and the NLRP3 inflammasome. The resulting vigorous IL‐1 response critically depended on expression of Nrf2, and Nrf2‐deficient apolipoprotein E (Apoe)−/− mice were highly protected against diet‐induced atherogenesis. Importantly, therapeutic neutralization of IL‐1α and IL‐1β reduced atherosclerosis in Nrf2+/−Apoe−/− but not in Nrf2−/−Apoe−/− mice, suggesting that the pro‐atherogenic effect of Nrf2‐signaling was primarily mediated by its permissive role in IL‐1 production. Our studies demonstrate a role for Nrf2 in inflammasome activation, and identify cholesterol crystals as disease‐relevant triggers of the NLRP3 inflammasome and potent pro‐atherogenic cytokine responses. These findings suggest a common pathway through which oxidative stress and metabolic danger signals converge and mutually perpetuate the chronic vascular inflammation that drives atherosclerosis.

Dyslipidemia inhibits Toll-like receptor–induced activation of CD8α-negative dendritic cells and protective Th1 type immunity

Environmental factors, including diet, play a central role in influencing the balance of normal immune homeostasis; however, many of the cellular mechanisms maintaining this balance remain to be elucidated. Using mouse models of genetic and high-fat/cholesterol diet–induced dyslipidemia, we examined the influence of dyslipidemia on T cell and dendritic cell (DC) responses in vivo and in vitro. We show that dyslipidemia inhibited Toll-like receptor (TLR)–induced production of proinflammatory cytokines, including interleukin (IL)-12, IL-6, and tumor necrosis factor-α, as well as up-regulation of costimulatory molecules by CD8α− DCs, but not by CD8α+ DCs, in vivo. Decreased DC activation profoundly influenced T helper (Th) cell responses, leading to impaired Th1 and enhanced Th2 responses. As a consequence of this immune modulation, host resistance to Leishmania major was compromised. We found that oxidized low-density lipoprotein (oxLDL) was the key active component responsible for this effect, as it could directly uncouple TLR-mediated signaling on CD8α− myeloid DCs and inhibit NF-κB nuclear translocation. These results show that a dyslipidemic microenvironment can directly interfere with DC responses to pathogen-derived signals and skew the development of T cell–mediated immunity.

The kinase activity of Rip2 determines its stability and consequently Nod1- and Nod2-mediated immune responses.

Rip2 (RICK, CARD3) has been identified as a key effector molecule downstream of the pattern recognition receptors, Nod1 and Nod2; however, its mechanism of action remains to be elucidated. In particular, it is unclear whether its kinase activity is required for signaling or for maintaining protein stability. We have investigated the expression level of different retrovirally expressed kinase-dead Rip2 mutants and the role of Rip2 kinase activity in the signaling events that follow Nod1 and Nod2 stimulation. We show that in primary cells expressing kinase-inactive Rip2, protein levels were severely compromised, and stability could not be reconstituted by the addition of a phospho-mimetic mutation in its autophosphorylation site. Consequently, inflammatory cytokine production in response to Nod1 and Nod2 ligands was abrogated both in vitro and in vivo in the absence of Rip2 kinase activity. Our results highlight the central role that Rip2 kinase activity plays in conferring stability to the protein and thus in the preservation of Nod1- and Nod2-mediated innate immune responses.

Locally inducible CD66a (CEACAM1) as an amplifier of the human intestinal T cell response

CD66a is an adhesion molecule member of the carcinoembryonic antigen immunoglobulin‐like family present on the surface of epithelial cells, granulocytes and IL‐2 activated T cells. We studied whether CD66a is expressed in vivo by T lymphocytes and whether it affects TCR‐mediated activation. CD66a was detected by histochemistry, flow cytometry analysis, reverse transcription PCR and Western blot on fresh colon biopsies and T cell clones. A fraction of T cells in the lamina propria express CD66a, which is induced by IL‐7 and IL‐15 cytokines. T cells express four different CD66a splice variants and at least two forms of the protein are glycosylated in a cell type‐specific manner. Triggering of CD66a on T cells with physiological ligands or with specific mAb increases TCR‐mediated lymphokine release, in an antigen dose‐independent manner. This effect requires the presence of the CD66a intracytoplasmic domain, which contains two immunoglobulin receptor family tyrosine‐based inhibitory motif‐like domains, as shown by stimulation of Jurkat cells transfected with different CD66a isoforms and is associated with increased induction of AP1 and NFκB transcription factors. These data indicate that CD66a amplifies T cell activation and thus could facilitate crosstalk between epithelial cells and T lymphocytes in intestinal immune response.

Molecular Recognition of Human CD1b Antigen Complexes: Evidence for a Common Pattern of Interaction with αβ TCRs

Ag-specific T cell recognition is mediated through direct interaction of clonotypic TCRs with complexes formed between Ag-presenting molecules and their bound ligands. Although characterized in substantial detail for class I and class II MHC encoded molecules, the molecular interactions responsible for TCR recognition of the CD1 lipid and glycolipid Ag-presenting molecules are not yet well understood. Using a panel of epitope-specific Abs and site-specific mutants of the CD1b molecule, we showed that TCR interactions occur on the membrane distal aspects of the CD1b molecule over the α1 and α2 domain helices. The location of residues on CD1b important for this interaction suggested that TCRs bind in a diagonal orientation relative to the longitudinal axes of the α helices. The data point to a model in which TCR interaction extends over the opening of the putative Ag-binding groove, making multiple direct contacts with both α helices and bound Ag. Although reminiscent of TCR interaction with MHC class I, our data also pointed to significant differences between the TCR interactions with CD1 and MHC encoded Ag-presenting molecules, indicating that Ag receptor binding must be modified to accommodate the unique molecular structure of the CD1b molecule and the unusual Ags it presents.