• Loss of thymic ectopic self-antigen expression during murine acute GVHD is responsible for the de novo generation of autoreactive T cells.

  • Functional impairment of the thymus medulla mechanistically links acute GVHD to posttransplantation autoimmunity.

During acute graft-versus-host disease (aGVHD) in mice, autoreactive T cells can be generated de novo in the host thymus implying an impairment in self-tolerance induction. As a possible mechanism, we have previously reported that mature medullary thymic epithelial cells (mTEChigh) expressing the autoimmune regulator are targets of donor T-cell alloimmunity during aGVHD. A decline in mTEChigh cell pool size, which purges individual tissue-restricted peripheral self-antigens (TRA) from the total thymic ectopic TRA repertoire, weakens the platform for central tolerance induction. Here we provide evidence in a transgenic mouse system using ovalbumin (OVA) as a model surrogate TRA that the de novo production of OVA-specific CD4+ T cells during acute GVHD is a direct consequence of impaired thymic ectopic OVA expression in mTEChigh cells. Our data, therefore, indicate that a functional compromise of the medullary mTEChigh compartment may link alloimmunity to the development of autoimmunity during chronic GVHD.

Acute graft-versus-host disease (aGVHD) and chronic graft-versus-host disease (cGVHD) remain primary complications of allogeneic hematopoietic stem cell transplantation (alloHSCT).1,2  Acute graft-versus-host disease is initiated by alloreactive donor T cells, which target a restricted set of tissues including the thymus.3,4  Human aGVHD predisposes to cGVHD with autoimmune manifestations that are integral components of the disease.5,6  It remains uncertain how autoimmunity is mechanistically linked to alloimmunity, but the thymus may play a role in this process.1,4,7,8 

In the thymus, self-tolerance of the nascent T-cell receptor repertoire is attained through negative selection.9  Essential for clonal deletion is the exposure of developing T cells to self-antigens, including those with highly restricted tissue expression. Thymic ectopic expression of tissue-restricted peripheral self-antigens (TRA) is a distinct property of mature medullary thymic epithelial cells (mTEChigh) that express the transcription factor autoimmune regulator (Aire).10  Importantly, intimate associations exist between perturbations in TRA expression (independent of cause), and the susceptibility to autoimmunity in both animals and humans.10-12 

We and others have demonstrated that mTEChigh are targets of donor T-cell alloimmunity during aGVHD,3,7,13  and that thymic aGVHD interferes with the capacity of Aire+mTEChigh to sustain TRA diversity.14  Mechanistic links between altered thymic TRA expression and hence deviations in the TRA repertoire, the thymic production of autoreactive T-cells, and ultimately their peripheral appearance during aGVHD have not yet been established. Here we provide direct evidence in transgenic mice that de novo production of TRA-specific T-cells during aGVHD is a consequence of impaired ectopic TRA expression that results from a diminished mTEChigh cell pool.

Female C57BL/6 (H-2b), Balb/c (H-2d), CBy.PL(B6)-Thy1a/ScrJ (Balb/c-Thy1.1;H-2d), B6.Cg-Tg(TcraTcrb)425Cbn/J (OT-II;H-2b), and C57BL/6-Tg(Ins2-TFRC/OVA)296Wehi/WehiJ (rat insulin promoter [RIP]-membrane-bound form of ovalbumin [mOVA];H-2b) were purchased from the Jackson Laboratory and were kept in accordance with institutional regulations. RIP-mOVA mice express a membrane-bound form of OVA (mOVA; residues139-385) under control of the RIP.15  These mice express mOVA in the pancreas, but also in the thymus specifically in mTEC.16  We bred Rag2-deficient OT-II mice, producing transgenic Vα2Vβ5 T-cell receptor (TCR) specific for OVA323-339, with B6.SJL-PtprcaPep3b/BoyJ (B6.CD45.1;H-2b) on a CD45.1+ congenic background at the Benaroya Research Institute (Seattle, WA). Thymic aGVHD (H-2d→H-2b) was induced by transplantation of Balb/c T-cells into total body irradiated and fully major histocompatibility complex (MHC)-mismatched RIP-mOVA recipients (d→RIP-mOVAb; Figure 1A; see the supplemental Methods on the Blood Web site). The thymic epithelial cell compartment was analyzed at 2 and 4 weeks after alloHSCT by flow cytometry (FACSAria; Becton Dickinson, Mountain View, CA). The mTECs were identified as cells with a CD45EpCam+Ly51UEA1+MHCIIlow (mTEClow) or MHCIIhigh (mTEChigh) phenotype, respectively, as described.14  To study negative thymic selection, the d→RIP-mOVAb recipients were reirradiated 4 weeks after the first alloHSCT and infused with syngeneic, rigorously (>2 log) T cell depleted OT-II bone marrow cells (TCDBM) mixed with C57BL/6 wild-type TCDBM (designated as OT-IIb→[d→RIP-mOVAb]; Figure 1A). Emergence and function of OVA-specific CD4+ T cells (CD45.1+) was tested after the second syngeneic HSCT by flow cytometry (supplemental Methods). Immunohistochemistry, polymerase chain reaction, T-cell function, and statistical analyses were performed as described before14  and in the supplement Data.

Figure 1

Acute GVHD reduces thymic ectopic expression of the surrogate self-antigen OVA in RIP-mOVA recipients. The mTEC compartment was analyzed in a transgenic murine model of H-2d→H-2b allo-HSCT. (A). Acute GVHD was induced in 8-week-old, lethally irradiated RIP-mOVA recipients by transfer of TCDBM mixed with Thy1.2+ splenic T-cells from Balb/c donors (TCDBM + T group). This alloHSCT setting was designated as [d→RIP-mOVAb]. As controls without aGVHD, mice received Balb/c-Thy1.1+ TCDBM only (TCDBM group). Four weeks after the first alloHSCT, [d→RIP-mOVAb] mice were lethally reirradiated and retransplanted in a second syngeneic HSCT with H-2b TCDBM from CD45.1+ OT-II mice mixed at a 1:4 ratio with cells from wild-type CD45.2+ C57BL/6 mice (H-2b). This approach generated OT-IIb→[d→RIP-mOVAb] chimeric mice. (B) Flow cytometry analysis for identification of Epcam+Ly51 mTEClow and mTEChigh cells in [d→RIP-mOVAb] mice in the absence (TCDBM group; ○) and presence (TCDBM + T group; ●) of aGVHD at 2 and 4 weeks after the first alloHSCT. The numbers shown in each flow cytometry dot plot represent frequencies (%, mean ± standard deviation [SD]) of the respective population among total mTEC. Line graphs depict absolute cell numbers of mTEClow and mTEChigh. The figure represents data from 3 independent experiments with ≥3 mice per group analyzed. *P < .05, Mann-Whitney U test. (C) Expression of mOVA mRNA was determined by quantitative polymerase chain reaction in mTEChigh, which was purified from the total residual TEC pools isolated from mice with (●) or without (○) aGVHD at 2 and 4 weeks after the first alloHSCT. Expression is shown as relative expression normalized to GAPDH. Dashed lines indicate normal mOVA mRNA expression in naïve untransplanted RIP-mOVA mice. *P < .05, Mann-Whitney U test. (D) Expression of Aire mRNA was analyzed in purified mTEChigh cells in the alloHSCT groups above. Aire expression is shown as relative expression normalized to GAPDH. *P < .05, Mann-Whitney U test. To detect Aire protein, immunohistochemistry and confocal microscope analysis was performed on thymic frozen sections taken from [d→RIP-mOVAb] mice with or without aGVHD (2 weeks). Cytokeratin-18 (CK18, blue) and CD14-positive cells (red) define cortical thymic epithelial cells (cTEC) and mTEC, respectively. Aire+ cells are shown in yellow and localize to the thymus medulla. Thymic architecture and Aire are lost during aGVHD (lower right panel).

Figure 1

Acute GVHD reduces thymic ectopic expression of the surrogate self-antigen OVA in RIP-mOVA recipients. The mTEC compartment was analyzed in a transgenic murine model of H-2d→H-2b allo-HSCT. (A). Acute GVHD was induced in 8-week-old, lethally irradiated RIP-mOVA recipients by transfer of TCDBM mixed with Thy1.2+ splenic T-cells from Balb/c donors (TCDBM + T group). This alloHSCT setting was designated as [d→RIP-mOVAb]. As controls without aGVHD, mice received Balb/c-Thy1.1+ TCDBM only (TCDBM group). Four weeks after the first alloHSCT, [d→RIP-mOVAb] mice were lethally reirradiated and retransplanted in a second syngeneic HSCT with H-2b TCDBM from CD45.1+ OT-II mice mixed at a 1:4 ratio with cells from wild-type CD45.2+ C57BL/6 mice (H-2b). This approach generated OT-IIb→[d→RIP-mOVAb] chimeric mice. (B) Flow cytometry analysis for identification of Epcam+Ly51 mTEClow and mTEChigh cells in [d→RIP-mOVAb] mice in the absence (TCDBM group; ○) and presence (TCDBM + T group; ●) of aGVHD at 2 and 4 weeks after the first alloHSCT. The numbers shown in each flow cytometry dot plot represent frequencies (%, mean ± standard deviation [SD]) of the respective population among total mTEC. Line graphs depict absolute cell numbers of mTEClow and mTEChigh. The figure represents data from 3 independent experiments with ≥3 mice per group analyzed. *P < .05, Mann-Whitney U test. (C) Expression of mOVA mRNA was determined by quantitative polymerase chain reaction in mTEChigh, which was purified from the total residual TEC pools isolated from mice with (●) or without (○) aGVHD at 2 and 4 weeks after the first alloHSCT. Expression is shown as relative expression normalized to GAPDH. Dashed lines indicate normal mOVA mRNA expression in naïve untransplanted RIP-mOVA mice. *P < .05, Mann-Whitney U test. (D) Expression of Aire mRNA was analyzed in purified mTEChigh cells in the alloHSCT groups above. Aire expression is shown as relative expression normalized to GAPDH. *P < .05, Mann-Whitney U test. To detect Aire protein, immunohistochemistry and confocal microscope analysis was performed on thymic frozen sections taken from [d→RIP-mOVAb] mice with or without aGVHD (2 weeks). Cytokeratin-18 (CK18, blue) and CD14-positive cells (red) define cortical thymic epithelial cells (cTEC) and mTEC, respectively. Aire+ cells are shown in yellow and localize to the thymus medulla. Thymic architecture and Aire are lost during aGVHD (lower right panel).

Close modal

We reported before that aGVHD causes a quantitative decline in the Aire+mTEChigh pool and consequently a less diverse TRA repertoire, thus impairing the molecular platform for central tolerance induction.14  It remained uncertain, however, whether such mechanism sufficed for the escape of TRA-specific TCR from thymic deletion. Because the precise antigen specificities of autoreactive effector T cells in cGVHD remain unidentified,17  we used mOVA as a surrogate self-antigen and tested whether loss of mOVA expression affected central deletion of OVA-specific T cells during aGVHD. We chose the OT-II→RIP-mOVA system because (1) thymic mOVA expression is restricted to mTEC16 ; (2) TCR selection against mOVA recapitulates physiological tolerance induction to TRA in the thymus medulla16,18-21 ; and (3) a reduction of mOVA mRNA in mTEC by <30% suffices for RIP-mOVA thymi to fail to delete OT-II cells.22 

We studied aGVHD in lethally irradiated RIP-mOVA recipients of fully MHC-mismatched Balb/c donors (designated [d→RIP-mOVAb]; Figures 1A and supplemental Figure 1). Consistent with previous data that reduction in mTEC compartment size is a universal manifestation of thymic aGVHD,14  total mTEClow, and mTEChigh, cells were diminished in numbers to ≤103 cells/mouse at 4 weeks after alloHSCT (Figure 1B). In addition, the presence of thymic aGVHD in [d→RIP-mOVAb] mice (supplemental Figure 1) reduced global OVA mRNA levels in total residual mTEChigh cell pools isolated after transplantation (Figure 1C). Our data also consistently demonstrated a reduction in the expression of both Aire mRNA and protein as a consequence of aGVHD-mediated TEC injury (Figure 1D). Because Aire regulates OVA expression19  and because the Aire+mTEChigh subset is reduced in numbers during aGVHD,14  our data argues that loss of Aire+mTEChigh was responsible for the deficiency in thymic OVA during aGVHD.

We postulated that aGVHD interfered with negative selection of the OVA TCR because (1) Aire−/−RIP-mOVA mice cannot efficiently delete OT-II T-cells19  and (2) total thymic mOVA expression levels correlate with deletion efficacy of OVA-reactive TCR.16,18,19,21,22  To test our hypothesis, transgenic recipients with or without aGVHD were reirradiated and transplanted with syngeneic OT-II TCDBM (designated as OT-IIb→[d→RIP-mOVAb]; Figure 1A). Thymic OT-II CD4+ T-cell development was monitored by assessment of CD45.1+ cells. An adequate ratio (7:1)16,21  between CD45.1+ immature CD4+8+ (DP) and mature CD4+CD8 thymocytes (CD4SP) indicated regular deletion of OVA-specific TCR in OT-IIb→[d→RIP-mOVA] mice without disease, as expected (Figure 2A, top left). Much lower DP/CD4SP ratios were observed in transgenic recipients with aGVHD (low thymic mOVA), indicating inefficient deletion of OT-II cells. DP/CD4SP ratios were in the majority of these mice not distinguishable from ratios in OT-IIb→[d→C57BL/6] nondeleting controls (no thymic mOVA). Deficient elimination of OT-II cells in transgenic mice with aGVHD was substantiated by twofold to threefold higher frequencies of CD45.1+CD4SP among total thymic CD4SP cells when compared with mice without aGVHD (Figure 2A, top right; supplemental Figure 2). Thus, an aGVHD-mediated loss of OVA expression in mTEChigh resulted in an unopposed escape of “forbidden” OVA-specific Vα2+Vβ5+CD4+ T-cell clones (Barnden et al.23 ; supplemental Figure 2) within the host thymus. OT-II cells were also present in the lymph nodes and spleens of transgenic mice with aGVHD (Figure 2A, bottom). Because mature OT-II T-cells were not passively transferred from donor grafts (supplemental Figure 2), formation of the peripheral OT-II pool was thymus-dependent.

Figure 2

OVA-specific T-cell clones escape negative selection during aGVHD. Four weeks after their first alloHSCT, the [d→RIP-mOVAb] mice with (●) or without (○) aGVHD received TCDBM (H-2b) from CD45.1+ OT-II and CD45.2+ C57BL/6 mice in a second syngeneic HSCT as described in Figure 1A. A third group included a second syngeneic HSCT into nontransgenic GVHD- recipients of a first alloHSCT (⩾ TCDBM OT-IIb→[d→C57BL/6b]). OT-II CD4+ T-cells were analyzed in primary and secondary lymphoid organs 4 weeks later in all 3 groups. (A) Upper panels: Thymic OT-II CD4+ T-cell development. Top left: the DP/CD4SP ratios between immature and mature thymocytes derived from CD45.1+ OT-II bone marrow-derived cells were calculated and are shown as mean ± SD. The figure represents data from 3 independent experiments. *P < .05, Kruskall-Wallis test with Dunn’s multiple comparison test. Top right: Flow cytometric analysis of CD4SP thymocytes (live gate defined by 4,6 diamidino-2-phenylindole cells). The frequencies of CD45.1+ OT-II cells among total thymic CD4SP cells are shown as mean ± SD. Lower panels: Emergence of OT-II cells in the periphery. The frequencies of OT-II cells (CD45.1+CD4+) among total CD4+ T cells in the spleens and lymph nodes are shown as mean ± SD. The figure represents combined data from 3 independent experiments with ≥6 mice analyzed per group. *P < .05, Kruskall-Wallis test with Dunn’s multiple comparison test. (B) Intracellular Foxp3 expression was analyzed in splenic CD4+ T cells isolated from OT-IIb→[d→RIP-mOVAb] mice with or without aGVHD at 4 weeks after the second syngeneic HSCT. Flow cytometry plots depict surface CD45.1 and intracellular Foxp3 expression. (C) Quadrants [a], [b], [c], and [d] were further analyzed for surface expression of folate receptor 4 (FR4) and CD73. Data are representative of at least 2 independent experiments with ≥6 mice analyzed per group. (D) Cultures of carboxyfluorescein diacetate succinimidyl ester (CFSE)-labeled CD4+ T-cells isolated from spleens and lymph nodes of transplanted mice were used to detect ex vivo the proliferative response to OVA323-339 peptide presented by syngeneic APC (see supplemental Methods). Histograms of CFSE fluorescence in CD4+ responder cells are shown (log fluorescence intensity and cell numbers). Data are representative for ≥6 mice analyzed per group. The data substantiate that peripheral OT-II cells are responsive to their cognate antigen and therefore do not enter into an anergic state.

Figure 2

OVA-specific T-cell clones escape negative selection during aGVHD. Four weeks after their first alloHSCT, the [d→RIP-mOVAb] mice with (●) or without (○) aGVHD received TCDBM (H-2b) from CD45.1+ OT-II and CD45.2+ C57BL/6 mice in a second syngeneic HSCT as described in Figure 1A. A third group included a second syngeneic HSCT into nontransgenic GVHD- recipients of a first alloHSCT (⩾ TCDBM OT-IIb→[d→C57BL/6b]). OT-II CD4+ T-cells were analyzed in primary and secondary lymphoid organs 4 weeks later in all 3 groups. (A) Upper panels: Thymic OT-II CD4+ T-cell development. Top left: the DP/CD4SP ratios between immature and mature thymocytes derived from CD45.1+ OT-II bone marrow-derived cells were calculated and are shown as mean ± SD. The figure represents data from 3 independent experiments. *P < .05, Kruskall-Wallis test with Dunn’s multiple comparison test. Top right: Flow cytometric analysis of CD4SP thymocytes (live gate defined by 4,6 diamidino-2-phenylindole cells). The frequencies of CD45.1+ OT-II cells among total thymic CD4SP cells are shown as mean ± SD. Lower panels: Emergence of OT-II cells in the periphery. The frequencies of OT-II cells (CD45.1+CD4+) among total CD4+ T cells in the spleens and lymph nodes are shown as mean ± SD. The figure represents combined data from 3 independent experiments with ≥6 mice analyzed per group. *P < .05, Kruskall-Wallis test with Dunn’s multiple comparison test. (B) Intracellular Foxp3 expression was analyzed in splenic CD4+ T cells isolated from OT-IIb→[d→RIP-mOVAb] mice with or without aGVHD at 4 weeks after the second syngeneic HSCT. Flow cytometry plots depict surface CD45.1 and intracellular Foxp3 expression. (C) Quadrants [a], [b], [c], and [d] were further analyzed for surface expression of folate receptor 4 (FR4) and CD73. Data are representative of at least 2 independent experiments with ≥6 mice analyzed per group. (D) Cultures of carboxyfluorescein diacetate succinimidyl ester (CFSE)-labeled CD4+ T-cells isolated from spleens and lymph nodes of transplanted mice were used to detect ex vivo the proliferative response to OVA323-339 peptide presented by syngeneic APC (see supplemental Methods). Histograms of CFSE fluorescence in CD4+ responder cells are shown (log fluorescence intensity and cell numbers). Data are representative for ≥6 mice analyzed per group. The data substantiate that peripheral OT-II cells are responsive to their cognate antigen and therefore do not enter into an anergic state.

Close modal

In transgenic recipients with aGVHD, the fraction of C57BL/6 (CD45.1) donor bone marrow–derived Foxp3+ regulatory T-cells (Treg) among total splenic CD4+ cells were reduced in frequency from a normal average of 10% to an average <1% (Figure 2B, upper left quadrants [a]). Among Foxp3+CD45.1 cells, some were FR4highCD73high, documenting their anergic phenotype24  (Figure 2C, far left panels [a]). In contrast, emerging OT-II (CD45.1+) cells were exclusively Foxp3 conventional T-cells whose FR4CD73 phenotype suggested that they were nonanergic24  (Figure 2C, panels [c]). Indeed, CD45.1+CD4+ (OT-II) cells, but not CD45.1CD4+ (non-OT-II) cells, isolated from aGVHD mice vigorously responded to OVA peptide in culture (Figure 2D).

Taken together, we provide direct evidence in transgenic mice using OVA as model TRA that intrathymic de novo production of TRA-specific CD4+ T-cells during aGVHD is triggered by impaired ectopic TRA expression. These OVA-reactive T cells are exported into a periphery that is characterized by Treg deficiency. We advocate that functional compromise of the mTEC compartment may provide a pathogenic link between alloimmunity and the development of autoimmunity.25  The identification of the specificities of autoreactive effector T cells in cGVHD will allow to test whether such a mechanism operates not only for a surrogate TRA, but is universal for thymic ectopic expression of those TRA that are present in tissues known to be targets of cGVHD.

The online version of this article contains a data supplement.

There is an Inside Blood Commentary on this article in this issue.

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734.

The authors thank Dr Gabor Szinnai (University Children's Hospital, Basel) for his constructive review of our manuscript, Katrin Hafen (Basel) for expert technical help, and Nicole von Burg (Basel) for providing OVA peptide.

This work was supported by Swiss National Science Foundation (grants 310030-129838 [W.K.] and 310010-122558 [G.A.H.]), and by a grant from the Hematology Research Foundation, Basel, Switzerland (W.K.).

Contribution: S.D. and M.H.H. designed and performed the study; M.V. performed the study; W.K. and G.A.H. shared senior authorship; W.K. and G.A.H. designed the work; and S.D. and W.K. wrote the paper.

Conflict-of-interest disclosure: The authors declare no competing financial interests.

Correspondence: Simone Dertschnig, Department of Biomedicine, University of Basel, Mattenstrasse 28, 4058 Basel, Switzerland; e-mail: simone.dertschnig@unibas.ch.

1
Socié
 
G
Ritz
 
J
Current issues in chronic graft-versus-host disease.
Blood
2014
, vol. 
124
 
3
(pg. 
374
-
384
)
2
Blazar
 
BR
Murphy
 
WJ
Abedi
 
M
Advances in graft-versus-host disease biology and therapy.
Nat Rev Immunol
2012
, vol. 
12
 
6
(pg. 
443
-
458
)
3
Na
 
IK
Lu
 
SX
Yim
 
NL
et al. 
The cytolytic molecules Fas ligand and TRAIL are required for murine thymic graft-versus-host disease.
J Clin Invest
2010
, vol. 
120
 
1
(pg. 
343
-
356
)
4
Krenger
 
W
Blazar
 
BR
Holländer
 
GA
Thymic T-cell development in allogeneic stem cell transplantation.
Blood
2011
, vol. 
117
 
25
(pg. 
6768
-
6776
)
5
Pavletic
 
SZ
Fowler
 
DH
 
Are we making progress in GVHD prophylaxis and treatment? Hematology Am Soc Hematol Educ Program. 2012;2012:251-264
6
Flowers
 
ME
Inamoto
 
Y
Carpenter
 
PA
et al. 
Comparative analysis of risk factors for acute graft-versus-host disease and for chronic graft-versus-host disease according to National Institutes of Health consensus criteria.
Blood
2011
, vol. 
117
 
11
(pg. 
3214
-
3219
)
7
Wu
 
T
Young
 
JS
Johnston
 
H
et al. 
Thymic damage, impaired negative selection, and development of chronic graft-versus-host disease caused by donor CD4+ and CD8+ T cells.
J Immunol
2013
, vol. 
191
 
1
(pg. 
488
-
499
)
8
Teshima
 
T
Reddy
 
P
Liu
 
C
Williams
 
D
Cooke
 
KR
Ferrara
 
JL
Impaired thymic negative selection causes autoimmune graft-versus-host disease.
Blood
2003
, vol. 
102
 
2
(pg. 
429
-
435
)
9
Vicente
 
R
Swainson
 
L
Marty-Grès
 
S
et al. 
Molecular and cellular basis of T cell lineage commitment.
Semin Immunol
2010
, vol. 
22
 
5
(pg. 
270
-
275
)
10
Anderson
 
MS
Su
 
MA
 
Aire and T cell development. Curr Opin Immunol. 2011;23(2):198-206
11
Liston
 
A
Gray
 
DH
Lesage
 
S
et al. 
Gene dosage—limiting role of Aire in thymic expression, clonal deletion, and organ-specific autoimmunity.
J Exp Med
2004
, vol. 
200
 
8
(pg. 
1015
-
1026
)
12
Klein
 
L
Hinterberger
 
M
Wirnsberger
 
G
Kyewski
 
B
Antigen presentation in the thymus for positive selection and central tolerance induction.
Nat Rev Immunol
2009
, vol. 
9
 
12
(pg. 
833
-
844
)
13
Hauri-Hohl
 
MM
Keller
 
MP
Gill
 
J
et al. 
Donor T-cell alloreactivity against host thymic epithelium limits T-cell development after bone marrow transplantation.
Blood
2007
, vol. 
109
 
9
(pg. 
4080
-
4088
)
14
Dertschnig
 
S
Nusspaumer
 
G
Ivanek
 
R
Hauri-Hohl
 
MM
Holländer
 
GA
Krenger
 
W
Epithelial cytoprotection sustains ectopic expression of tissue-restricted antigens in the thymus during murine acute GVHD.
Blood
2013
, vol. 
122
 
5
(pg. 
837
-
841
)
15
Kurts
 
C
Heath
 
WR
Carbone
 
FR
Allison
 
J
Miller
 
JF
Kosaka
 
H
Constitutive class I-restricted exogenous presentation of self antigens in vivo.
J Exp Med
1996
, vol. 
184
 
3
(pg. 
923
-
930
)
16
Gallegos
 
AM
Bevan
 
MJ
Central tolerance to tissue-specific antigens mediated by direct and indirect antigen presentation.
J Exp Med
2004
, vol. 
200
 
8
(pg. 
1039
-
1049
)
17
Hess
 
AD
Equal opportunity targeting in chronic GVHD.
Blood
2012
, vol. 
119
 
26
(pg. 
6183
-
6184
)
18
Derbinski
 
J
Schulte
 
A
Kyewski
 
B
Klein
 
L
Promiscuous gene expression in medullary thymic epithelial cells mirrors the peripheral self.
Nat Immunol
2001
, vol. 
2
 
11
(pg. 
1032
-
1039
)
19
Anderson
 
MS
Venanzi
 
ES
Chen
 
Z
Berzins
 
SP
Benoist
 
C
Mathis
 
D
The cellular mechanism of Aire control of T cell tolerance.
Immunity
2005
, vol. 
23
 
2
(pg. 
227
-
239
)
20
Suen
 
AY
Baldwin
 
TA
Proapoptotic protein Bim is differentially required during thymic clonal deletion to ubiquitous versus tissue-restricted antigens.
Proc Natl Acad Sci USA
2012
, vol. 
109
 
3
(pg. 
893
-
898
)
21
Hu
 
Q
Nicol
 
SA
Suen
 
AY
Baldwin
 
TA
 
Examination of thymic positive and negative selection by flow cytometry. J Vis Exp. 2012;(68):4269
22
Hubert
 
FX
Kinkel
 
SA
Davey
 
GM
et al. 
Aire regulates the transfer of antigen from mTECs to dendritic cells for induction of thymic tolerance.
Blood
2011
, vol. 
118
 
9
(pg. 
2462
-
2472
)
23
Barnden
 
MJ
Allison
 
J
Heath
 
WR
Carbone
 
FR
Defective TCR expression in transgenic mice constructed using cDNA-based alpha- and beta-chain genes under the control of heterologous regulatory elements.
Immunol Cell Biol
1998
, vol. 
76
 
1
(pg. 
34
-
40
)
24
Martinez
 
RJ
Zhang
 
N
Thomas
 
SR
et al. 
Arthritogenic self-reactive CD4+ T cells acquire an FR4hiCD73hi anergic state in the presence of Foxp3+ regulatory T cells.
J Immunol
2012
, vol. 
188
 
1
(pg. 
170
-
181
)
25
Parkman
 
R
A 2-hit model for chronic GVHD.
Blood
2013
, vol. 
122
 
5
(pg. 
623
-
624
)
Sign in via your Institution