Gut-homing CD4+ T cell receptor αβ+ T cells in the pathogenesis of murine inflammatory bowel disease

We studied which T cell subsets from the gut-associated lymphoid tissue (GALT) can migrate out of the gut mucosa and repopulate GALT compartments of an immunodeficient (semi)syngeneic host. Many distinct lymphocyte subsets were found in GALT of immunocompetent H-2^d (BALB/c, BALB/c^dm2, C. B-17+/+) mice. No antigen receptor-expressing lymphoid cells were found in GALT of congenic C. B-17 scid/scid (scid) mice. The heterotopic transplantation of a full-thickness gut wall graft from the ileum or colon of immunocompetent (C. B-17+/+, BALB/c^dm2) donor mice onto immunodeficient scid mice selectively reconstituted a CD3⁺ T cell receptor αβ⁺ CD4⁺ T cell subset. CD4⁺ cells of this subset expressed the surface phenotype of mucosa-seeking, memory T cells. In the immunodeficient scid host, this gut-derived CD4⁺ T cell subset was found in spleen, peritoneal cavity, mesenteric lymph nodes (LN), epithelial layer and lamina propria of the small and large intestine, but not in peripheral LN. Scid mice heterotopically transplanted with gut from a congenic, immunocompetent donor developed clinical and histological signs of inflammatory bowel disease (IBD). Hence, the selective repopulation of GALT compartments with CD4⁺ T cells from normal GALT plays an essential role in the pathogenesis of IBD in an immunodeficient host.     

Selective engraftment of memory CD4+ T cells with an unusual recirculation pattern and a diverse T cell receptor-Vβ repertoire into scid mice

Young (H-2^d, L^d+) severe combined immunodeficiency (scid) mice were injected intravenously with 10⁵ CD4+CD8^? T cells purified from spleen, thymus or lymph nodes (LN) of dm2 (H-2^d, L^d ) donor mice. In the immunodeficient recipients, the lymphoid compartment in the splenic white pulp was repopulated with donor-type T cells and cellularity in the red pulp was increased. In addition, donor-type CD4⁺ T cells repopulated the peritoneal cavity, mesenteric LN and the lamina propria of the small intestine of scid mice, but were undetectable in thymus and peripheral (inguinal, axillary) LN. Histological examination of repopulated mesenteric LN showed expanded subcapsular sinuses, repopulated cortical areas, but poorly developed high endothelial venules (HEV) indicating deficient blood-LN lymphocyte recirculation. The engrafted CD4⁺ T cell population had the surface phenotype of memory T cells (CD44/Pgp-l^high CD45RB^low) and expressed the Peyer's patch HEV-specific homing receptor CD49d (LPAM-1), but not the LN HEV-specific homing receptor LECAM-l. The CD4+ T cell population in spleen and mesenteric LN of transplanted scid mice displayed a diverse T cell receptor-V(3 repertoire. Transfer of titrated numbers (10³, 10⁴, 10⁵ cells per mouse) of CD4⁺ T cells into scid mice established donor-type T cell populations with this unusual homing pattern in all recipients. Repeated serial transfers of dm2 CD4⁺ T cells through young scid mice revealed an extensive in vivo expansion potential of transferred cells for > 18 months. The experimental system described represents an in vivo model to study the functional competence and the differentiation potential of a murine memory CD4⁺ T cell subset.     

α4β1 integrin promotes accumulation of tissue‐resident memory CD8+ T cells in salivary glands

The salivary glands (SGs) of virus‐immune mice contain substantial numbers of tissue‐resident memory CD8⁺ T cells (T_RM cells) that can provide immunity to local infections. Integrins regulate entry of activated T cells into nonlymphoid tissues but the molecules that mediate migration of virus‐specific CD8⁺ T cells to the SGs have not yet been defined. Here, we found that polyinosinic‐polycytidylic acid (poly(I:C)) strongly promoted the accumulation of P14 TCR‐transgenic CD8⁺ T_RM cells in SGs in an α₄β₁ integrin‐dependent manner. After infection with lymphocytic choriomeningitis virus, accumulation of P14 T_RM cells in SGs and intestine but not in kidney was also α₄ integrin dependent. Blockade of α₄β₇ by monoclonal antibodies (mAbs) inhibited lymphocytic choriomeningitis virus‐induced accumulation of P14 T_RM cells in the intestine but not in SGs. In conclusion, our data reveal that α₄β₁ integrin mediates CD8⁺ T_RM accumulation in SGs and that poly(I:C) can be used to direct activated CD8⁺ T cells to this organ.     

Expression of pro-inflammatory cytokines by TCRαβ+ T and TCRγδ+ T cells in an experimental model of colitis

An inflammatory bowel disease (IBD) comparable to human ulcerative colitis is induced upon transfer of T cell-depleted wild-type (F1) bone marrow into syngeneic T cell-deficient (tgε26) mice (F1 → tgε26). Previously we have shown that activated CD4⁺ T cells predominate in transplanted tgε26 mice, and adoptive transfer experiments verified the potential of these cells to cause disease in immunodeficient recipient mice. Using flow cytometry for the detection of intracellular cytokine expression, we demonstrate in the present study that large numbers of CD4⁺ and CD8⁺ TCRαβ⁺ T cells from the intraepithelial region and lamina propria of the colon of diseased, but not from disease-free mice, produced interferon-γ (IFN-γ) and tumor necrosis factor-α (TNF-α). Large numbers of T cells from peripheral lymphoid tissues of these animals also expressed IFN-α and TNF-α, but few expressed interleukin-4, demonstrating g strong bias towards Th1-type T cell responses in these animals. TCRγδ⁺ T cells, typically minor constituents of the inflammatory infiltrate of the colon in F1 → tgε26 mice, also expressed IFN-γ at a high frequency upon CD3 stimulation. In light of these findings we examined the potential involvement of TCRγδ⁺ T cells by testing their ability to induce colitis in tgε26 mice. We report here that tgε26 mice transplanted with T cell-depleted bone marrow from TCRα^null and TCRβ^null animals developed IBD. Furthermore, disease in these mice correlated with the development of peripheral and colonic TCRαδ⁺ T cells capable of IFN-γ production. These results suggest that IFN-γ may be a common mediator of IBD utilized by pathogenic T cells of distinct phenotype.     

Polyclonal expansion of adoptively transferred CD4+ αβ T cells in the colonic lamina propria of scid mice with colitis

The adoptive transfer of low numbers of peripheral, non-fractionated CD4⁺ αβ T cells into histocompatible, severely immunodeficient (scid) hosts induces a colitis. This disease developed in C.B-17 scid/scid hosts after the injection of 10⁵CD4⁺ T cells purified from different peripheral lymphoid organs of immunocompetent C.B-17 +/+ or BALB/c^dm2 donor mice. Irrespective of their tissue origin, transferred CD4⁺ T cells selectively repopulated the scid host with gut-seeking CD4⁺ T cells. A chronic inflammatory bowel disease (IBD) developed as polyclonal populations of mucosa-seeking memory/effector CD4⁺ T cells accumulated in the gut lamina propria and epithelial layer of the adoptive host. The manifestation of colitis in the scid host correlated with the in situ polyclonal activation and expansion of adoptively transferred CD4⁺ T cells in the colonic lamina propria. Attempts were unsuccessful to select in vivo an oligoclonal CD4⁺ T cell population with an enhanced IBD-inducing potential by repeatedly reinjecting 10⁵ donor-type CD4⁺ T cells from the colonic lamina propria of transplanted scid mice with an early and severe IBD into new scid hosts. The data indicate that the preferential repopulation of gut-associated lymphoid tissues with immunocompetent CD4⁺ T cells, and their polyclonal activation and in situ expansion in the lamina propria of the histocompatible, immunodeficient host are critical events in the pathogenesis of an IBD in this model.     

Progenies of fetal thymocytes are the major source of CD4−CD8+ αα intestinal intraepithelial lymphocytes early in ontogeny

Present literature supports the view of an extrathymic origin for the subset of intestinal intraepithelial lymphocytes (IEL) that express the CD4^?CD8⁺ αα phenotype. This subset would include virtually all T cell receptor (TCR) γδ IEL and a portion of TCR αβ IEL. However, these reports do not exclude the possibility that some CD4^?CD8⁺ αα IEL are actually thymically derived. To clarify this issue, we examined the IEL day 3 neonatally thymectomized (NTX) mice. NTX resulted in as much as 80 % reduction in total TCR γδ IEL and in a nearly complete elimination of TCR αβ CD4^?CD8⁺ αα IEL early in ontogeny (3-to 5-week-old mice). The thymus dependency of TCR γδ IEL and TCR αβ CD4^?CD8⁺ IEL was less prominent in older mice (7- to 10-week-old mice), as the total number of these IEL increased in NTX mice, but still remained severalfold less than that in euthymic mice. Furthermore, we demonstrate, by grafting the fetal thymus of CBF1 (H-2^b/d) mice under the kidney capsule of congenitally nude athymic mice of BALB/c background (H-2^d), that a substantial number of TCR γδ IEL and TCR αβ CD4^?CD8⁺ αα IEL can be thymically derived (H-2^b+). In contrast, but consistent with our NTX data, grafting of adult thymi into nude mice generated virtually no TCR γδ IEL and relatively less TCR αβ CD4^?CD8⁺ αα IEL than did the grafting of fetal thymi. These results suggest that the thymus is the major source of TCR γδ and TCR αβ CD4^?CD8⁺ αα IEL early in ontogeny, but that the extrathymic pathway is probably the major source of these IEL later in ontogeny. A reassessment of the theory that most CD4^?CD8⁺ IEL are extrathymically derived is needed.     

Cytotoxic reactivity of gut lamina propria CD4+ αβ T cells in SCID mice with colitis

Polyclonal, mucosa-seeking memory/effector CD4⁺ T cells containing a large fraction of blasts activated in situ accumulate in the gut lamina propria of severe-combined immunodeficient (SCID) mice developing colitis after CD4⁺ T cell transplantation. CD4⁺ T cells isolated from different repopulated lymphoid tissues of transplanted SCID mice proliferate in vitro in the presence of interleukin (IL)-2 + IL-7. CD3 ligation enhances this cytokine-supported proliferation in CD4⁺ T cells from the spleen and the mesenteric lymph node of transplanted SCID mice; CD3 ligation suppresses the cytokine-supported proliferation in CD4⁺ T cells from the gut lamina propria in a cell density- and dose-dependent manner. Almost all CD4⁺ T cells from repopulated lymphoid tissues of transplanted SCID mice express CD95 (Fas) on the cell surface, and a large fraction of CD4⁺ T cells from the gut lamina propria of transplanted SCID mice express the Fas ligand on the surface. Gut lamina propria CD4⁺ T cells show Fas-dependent cytotoxicity. A large fraction of gut lamina propria CD4⁺ T cells that infiltrate the inflamed colon in transplanted SCID mice are activated in situ and many CD4⁺ T cells are apoptotic. Hence, a large fraction of colitis-inducing CD4⁺ T cells undergo activation-induced cell death in situ and can damage other cells through Fas-dependent cytotoxicity.     

Developmental expression of the αIELβ7 integrin on T cell receptor γδ and T cell receptor αβ T cells

A novel monoclonal antibody, 2E7, was shown by immunoprecipitation to be reactive with the α_IELβ7 integrin and was employed to analyze the expression of this integrin in lymphocyte subsets and during T cell ontogeny. In adult lymph nodes, α_IEL was expressed at low levels by 40–70% of CD8⁺ T cells and < 5% of CD4⁺ T cells. However, virtually all intestinal intraepithelial lymphocytes and ?20% of lamina propria CD4⁺ T cells were 2E7⁺, indicating a preferential expression of this integrin on mucosal T cells. Examination of α_IEL integrin expression during thymus ontogeny revealed that ?3–5% of fetal or adult thymocytes were 2E7⁺. Interestingly, early in fetal thymus ontogeny, ?40% of 2E7⁺ cells expressed T cell receptor (TcR)-γδ and this subset persisted through birth. A developmental switch occurred such that 2E7⁺ TcR^? CD4^?8⁺ cells detected on fetal day 19 were followed by 2E7⁺ TcR-αβ CD4^?8⁺ cells in the neonatal thymus. The latter population persisted throughout thymus ontogeny into adulthood. Interestingly, a subset of TcR-γδ Vγ3⁺ day 16 fetal thymocyte dendritic epidermal cell (DEC) precursors were 2E7⁺, but all mature DEC expressed high levels of α_IEL integrin, suggesting that the α_IEL integrin was acquired late in DEC maturation. This possibility was strenghthened by immunohistochemical localization of the majority of 2E7⁺ γδ and αβ T cells to the medullary regions of the thymus. Overall, the results demonstrate a developmentally ordered expression pattern of the α_IELβ₇ integrin that suggests a common function for this integrin during TcR-γδ and -αβ CD4^?8⁺ T cell thymocyte development or perhaps in effector functions for these subsets.     

The expansion and selection of T cell receptor αβ intestinal intraepithelial T cell clones

In conventional mice, the T cell receptor (TCR)αβ⁺ CD8αα⁺ and CD8αβ⁺ subsets of the intestinal intraepithelial lymphocytes (IEL) constitute two subpopulations. Each comprise a few hundred clones expressing apparently random receptor repertoires which are different in individual genetically identical mice (Regnault, A., Cumano, A., Vassalli, P., Guy-Grand, D. and Kourilsky, P., J. Exp. Med. 1994. 180: 1345). We analyzed the repertoire diversity of sorted CD8αα and CD8αβ⁺ IEL populations from the small intestine of individual germ-free mice that contain ten times less TCRαβ⁺ T cells than conventional mice. The TCRβ repertoire of the CD8αα and the CD8αβ IEL populations of germ-free adult mice shows the same degree of oligoclonality as that of conventional mice. These results show that the intestinal microflora is not responsible for the repertoire oligoclonality of TCRαβ⁺ IEL. The presence of the microflora leads to an expansion of clones which arise independently of bacteria. To evaluate the degree of expansion of IEL clones in conventional mice, we went on to measure their clone sizes in vivo by quantitative PCR in the total and in adjacent sections of the small intestine of adult animals. We found that both the CD8αα and the CD8αβ TCRαβ IEL clones have a heterogeneous size pattern, with clones containing from 3 × 10³ cells up to 1.2 × 10⁶ cells, the clones being qualitatively and quantitatively different in individual mice. Cells from a given IEL clone are not evenly distributed throughout the length of the small intestine. The observation that the TCRαβ IEL populations comprise a few hundred clones of very heterogeneous size and distribution suggests that they arise from a limited number of precursors, which may be slowly but continuously renewed, and undergo extensive clonal expansion in the epithelium.     

CD8+ CD122+ regulatory T cells contain clonally expanded cells with identical CDR3 sequences of the T‐cell receptor β‐chain

We identified CD8⁺ CD122⁺ regulatory T cells (CD8⁺ CD122⁺ Treg cells) and reported their importance in maintaining immune homeostasis. The absence of CD8⁺ CD122⁺ Treg cells has been shown to lead to severe systemic autoimmunity in several mouse models, including inflammatory bowel diseases and experimental autoimmune encephalomyelitis. The T‐cell receptors (TCRs) expressed on CD8⁺ CD122⁺ Treg cells recognize the target cells to be regulated. To aid in the identification of the target antigen(s) recognized by TCRs of CD8⁺ CD122⁺ Treg cells, we compared the TCR diversity of CD8⁺ CD122⁺ T cells with that of conventional, naive T cells in mice. We analysed the use of TCR‐Vβ in the interleukin 10‐producing population of CD8⁺ CD122⁺ T cells marked by high levels of CD49d expression, and found the significantly increased use of Vβ13 in these cells. Immunoscope analysis of the complementarity‐determining region 3 (CDR3) of the TCR β‐chain revealed remarkable skewing in a pair of Vβ regions, suggesting the existence of clonally expanded cells in CD8⁺ CD122⁺ T cells. Clonal expansion in Vβ13⁺ cells was confirmed by determining the DNA sequences of the CDR3s. The characteristic TCR found in this study is an important building block for further studies to identify the target antigen recognized by CD8⁺ CD122⁺ Treg cells.     

Differential contribution of the FcRγ chain to the surface expression of the T cell receptor among T cells localized in epithelia: analysis of FcRγ-deficient mice

The function of the Fc receptors γ chain (FcR_γ) for the expression of the T cell receptor (TCR) complex and for T cell development, especially for T cells localized in epithelia, was investigated by analyzing FcR_γ-deficient mice. In wildtype mice, CD8αα⁺β^?TCRαβ⁺ T cells of intestinal intraepithelial lymphocytes (i-IEL) utilized CD3ζ homodimers and ζ-FcR_γ heterodimers, whereas CD8α α⁺β^?TCR_γδ⁺ i-IEL used ζ-FcR_γ and FcR_γ homodimers in the TCR complex. On the other hand, these T cells in FcR_γ-deficient mice contained only ζ homodimers. The surface expression of the TCR complex was reduced in CD8αα⁺β^?i-IEL and dendritic epidermal T cells (DETC) in these mice, whereas the development of these T cells was normal. The degree of reduction appeared to depend on the expression level of FcR_γ. In contrast to these populations, TCR_γδ⁺ intraepithelial T cells in reproductive organs (r-IEL) were dramatically decreased, suggesting that the development of r-IEL is FcR_γ-dependent, probably due to the predominant usage of FcR_γ homodimers in the TCR complex. These results indicate that the FcR_γ chain contributes differently to the TCR expression and to the development of T cells localized in epithelia.     

Characterization of CD4−CD8− T cell receptor αβ+ T cells appearing in the subarachnoid space of rats with autoimmune encephalomyelitis

Inflammation of the central nervous system (CNS) in experimental autoimmune encephalomyelitis (EAE) starts in the subarachnoid space (SAS) and spreads later to the adjacent CNS parenchyma. To characterize the nature of lesion-forming T cells in situ in more detail, T cells were isolated from the SAS and their surface phenotype and the nucleotide sequence of the junctional region of the T cell receptor (TCR) was determined and compared with those of the lymph node (LN) and spinal cord (SC) T cells. Characteristically, more than 70% of SAS TCR αβ⁺ T cells isolated at the early stage of EAE lacked both CD4 and CD8 molecules, whereas those from LN and SC were either CD4⁺ or CD8⁺. Analysis of nucleotide sequences of the junctional region of TCR revealed that T cells bearing a sequence identical to that for encephalitogenic T cell clones were found in both SAS and SC. Furthermore, purified CD4^?CD8^? T cells expressed CD4 molecules after culture. At the same time, these T cells acquired reactivity to myelin basic protein and induced passive EAE in naive animals after adoptive transfer. Our results suggest that CD4^?CD8^? T cells in the SAS are precursors of lesion-forming T cells in the SC and that phenotype switching takes place during the process of T cell infiltration into the CNS parenchyma. The double-negative nature of these T cells may explain an escape of encephalitogenic T cells from negative selection in T cell differentiation.     

MHC class II-independent CD25+ CD4+ CD8alpha beta+ alpha beta T cells attenuate CD4+ T cell-induced transfer colitis

CD4+ alpha beta T cell populations that develop in mice deficient in MHC class II (through 'knockout' of either the Aalpha, or the Abeta chain of the I-A(b) molecule) comprise a major 'single-positive' (SP) CD4+ CD8- subset (60-90%) and a minor 'double-positive' (DP) CD4+ CD8alpha beta+ subset (10-40%). Many DP T cells found in spleen, mesenteric lymph nodes (MLN) and colonic lamina propria (cLP) express CD25, CD103 and Foxp3. Adoptive transfer of SP but not DP T cells from Aalpha(-/-) or Abeta(-/-) B6 mice into congenic RAG(-/-) hosts induces colitis. Transfer of SP T cells repopulates the host with only SP T cells; transfer of DP T cells repopulates the host with DP and SP T cells. Anti-CD25 antibody treatment of mice transplanted with DP T cells induces severe, lethal colitis; anti-CD25 antibody treatment of mice transplanted with SP T cells further aggravates the course of severe colitis. Hence, regulatory CD25+ T cells within (or developing from) the DP T cell population of MHC class II-deficient mice control the colitogenic potential of CD25- CD4+ T cells.     

CD4-negative cytotoxic T cells with a T cell receptor α/βintermediate expression in CD8-deficient mice

Targeted disruption of the CD8 gene results in a profound block in cytotoxic T cell (CTL) development. Since CTL are major histocompatibility complex (MHC) class I restricted, we addressed the question of whether CD8–/– mice can reject MHC class I-disparate allografts. Studies have previously shown that skin allografts are rejected exclusively by T cells. We therefore used the skin allograft model to answer our question and grafted CD8–/– mice with skins from allogeneic mice deficient in MHC class II or in MHC class I (MHC-I or MHC-II-disparate, respectively). CD8–/– mice rejected MHC-I-disparate skin rapidly even if they were depleted of CD4⁺ cells in vivo (and were thus deficient in CD4⁺ and CD8⁺ T cells). By contrast, CD8+/+ controls depleted of CD4⁺ and CD8⁺ T cells in vivo accepted the MHC-I-disparate skin. Following MHC-I, but not MHC-II stimulation, allograft-specific cytotoxic activity was detected in CD8–/– mice even after CD4 depletion. A population expanded in both the lymph nodes and the thymus of grafted CD8–/– animals which displayed a CD4^?8^?3^intermediateTCRα/β^intermediate phenotype. Indeed its T cell receptor (TCR) density was lower than that of CD4⁺ cells in CD8–/– mice or of CD8⁺ cells in CD8+/+ mice. Our data suggest that this CD4^?8^?T cell population is responsible for the CTL function we have observed. Therefore, MHC class I-restricted CTL can be generated in CD8–/– mice following priming with MHC class I antigens in vivo. The data also suggest that CD8 is needed to up-regulate TCR density during thymic maturation. Thus, although CD8 plays a major role in the generation of CTL, it is not absolutely required.     

CD5− CD8αβ intestinal intraepithelial lymphocytes (IEL) are induced to express CD5 upon antigen-specific activation: CD5− and CD5+ CD8αβ IEL do not represent separate T cell lineages

We followed αβ T cell receptor (TCR) usage in subsets of gut intraepithelial lymphocytes (IEL) in major histocompatibility complex class I-restricted αβ TCR-transgenic (tg) mice. The proportion of tg αβ TCR⁺ CD8αβ IEL is reduced compared with CD8⁺ splenocytes of the same animal, particularly under conventional conditions of maintenance. Further fractionation of CD8αβ IEL according to the expression level of surface CD5 revealed that in conventionally housed animals tg TCR⁺ CD5^? CD8αβ IEL are as frequent as in specific pathogen-free (SPF) mice, whereas tg TCR⁺ CD5^int or, even more pronounced, tg TCR⁺ CD5^hi CD8αβ IEL are greatly diminished when compared with mice kept under SPF conditions. Upon antigen-specific stimulation of CD5^? CD8αβ IEL in vitro, CD5 surface expression is up-regulated on a large fraction of cells within 48 h. Up-regulation of CD5 surface expression is further enhanced by the presence of the anti-αIEL monoclonal antibody 2E7. This clearly demonstrates that CD5^?, and CD5⁺ CD8αβ IEL cannot be considered as separate T cell lineages.     

Peripheral Thy1+ lymphocytes rearranging TCR‐γδ genes in LAT‐deficient mice

Linker for activation of T cells (LAT) is an adaptor molecule indispensable for development of αβ and γδ T lymphocytes. Surprisingly, using a new model of LAT‐deficient mice we found that despite arrested thymic development, a discrete population of cells with active Lat promoter, expressing Thy1 molecules, accumulated in peripheral lymphoid organs of homozygous (Lat^Inv/Inv) mutant mice. By measuring frequencies of TCR gene rearrangements in conjunction with a panel of cell surface Ag, we dissected two subsets of these Thy1⁺ cells. Thy1^dull cells expressed markers of NK lymphocytes and contained low frequency of TCR‐γ gene rearrangements without detectable TCR‐δ rearrangements. Thy1^high cells resembled immature CD44⁺CD25⁺ thymocytes and contained high frequency of non‐productive TCR‐γ and TCR‐δ rearrangements, indicating that cells displaying molecular signatures of commitment toward γδ T‐cell lineage can develop and populate lymphoid tissues of LAT‐deficient mice. Phenotypically similar Thy1^high cells were also found in lymph nodes of lymphocyte‐deficient (Rag2^?/?) mice but not in T lymphocyte proficient, heterozygous Lat^+/Inv mice suggesting that Thy1^high cells of LAT‐deficient mice identified in this study accumulate in peripheral lymphoid organs as a result of congenital lymphopenia.     

CD8‐β ADP‐ribosylation affects CD8+ T‐cell function

The CD8αβ coreceptor is crucial for effective peptide: MHC‐I recognition by the TCR of CD8⁺ T cells. Adenosine diphosphate ribosyl transferase 2.2 (ART2.2) utilizes extracellular NAD⁺ to transfer ADP‐ribose to arginine residues of extracellular domains of surface proteins. Here, we show that in the presence of extracellular NAD⁺, ART2.2 caused ADP‐ribosylation of CD8‐β on murine CD8⁺ T cells in vitro and in vivo. Treatment with NAD⁺ prevented binding of anti‐CD8‐β mAb YTS156.7.7 but not of mAb H35–17.2, indicating that NAD⁺ caused modification of certain epitopes and not a general loss of CD8‐β. Loss of antibody binding was strictly dependent on ART2.2, because it was not observed on ART2‐deficient T cells or in the presence of inhibitory anti‐ART2.2 single‐domain antibodies. ADP‐ribosylation of CD8‐β occurred during cell isolation, particularly when cells were isolated from CD38‐deficient mice. Incubation of ART2‐expressing, but not of ART2‐deficient, OVA‐specific CD8⁺ T cells with NAD⁺ interfered with binding of OVA_257–264:MHC‐I tetramers. In line with this result, treatment of WT mice with NAD⁺ resulted in reduced CD8⁺ T‐cell mediated cytotoxicity in vivo. We propose that ADP‐ribosylation of CD8‐β can regulate the coreceptor function of CD8 in the presence of elevated levels of extracellular NAD⁺.