T cell repertoire in primary biliary cirrhosis: a common T cell clone and repertoire change after treatment

CD4+ T cells from patients with primary biliary cholangitis show T cell activation and differentially expressed T-cell receptor repertoires

AIM

Primary biliary cholangitis (PBC) is an autoimmune liver disease with unknown pathogenesis. In PBC, activation of T-cell receptor (TCR) signaling is associated with inflammatory cytokine production through N-Ras upregulation. Although the CD4⁺ T cell TCR repertoire could be associated with PBC pathogenesis, it has not been evaluated. Thus, we analyzed the PBC-CD4⁺ T cell TCR repertoire using next generation sequencing (NGS).

METHODS

Four PBC patients (one treatment-naïve and three receiving ursodeoxycholic acid) and three healthy individuals were enrolled. NRAS expression in CD4⁺ T cells was assessed by quantitative reverse transcription-polymerase chain reaction (qRT-PCR). N-Ras dynamics in CD4⁺ T cells were assessed by qRT-PCR and GTP-N-Ras activation assay. The TCR α- (TRA) and β-chain (TRB) repertoires on CD4⁺ T cells were analyzed by NGS and profiled using hierarchical analysis. Motif analysis was undertaken to elucidate the structure of PBC-specific TCRs.

RESULTS

NRAS was upregulated in PBC relative to control CD4⁺ T cells (P < 0.05), and N-Ras enhanced T cell activation in CD4⁺ T cells. Among 2668 TRAs and 841 TRBs, 20 and 11, respectively, were differentially expressed in PBC compared to that in controls (P < 0.05, fold-change >2). Among them, TRAV29/J22, TRBV6-5/J2-6, and TRBV10-1/J2-1 were expressed in PBC but the expression was negligible in the controls, with more mature and longer forms observed in PBC-CD4⁺ T cells.

CONCLUSIONS

N-Ras was upregulated in PBC-CD4⁺ T cells, and it enhanced TCR activation, indicating that PBC-CD4⁺ T cells were activated by N-Ras upregulation with differentially expressed TCR repertoires on their surfaces.

TCRβ repertoire of memory T cell reveals potential role for Escherichia coli in the pathogenesis of primary biliary cholangitis

BACKGROUND

Primary biliary cholangitis (PBC) is an organ-specific, T cell-mediated autoimmune disease which is characterized by the breakdown of self-tolerance to the highly conserved pyruvate dehydrogenase complex, especially the pyruvate dehydrogenase E2 complex (PDC-E2). However, the molecular mechanism of breakdown of self-tolerance is still unclear.

METHODS

A combination of multiplex-PCR and immune repertoire sequencing (IR-seq) was used for a standardized analysis of memory T cell receptor (TCR) β-chain repertoire of PBC patient and healthy volunteers. In vitro induction and expansion of human PDC-E2_163-176 (human PDC-E2)-specific T cells and E coli PDC-E2_{31-44/134-147/235-248} (E coli PDC-E2)-specific T cells, and identified the human (and E coli) PDC-E2-specific TCRβ repertoire by IR-seq.

RESULTS

Primary biliary cholangitis patients have shorter complementarity-determining region 3s (CDR3s), and higher degree of sequence overlap in the TCRβ repertoire of memory T cell. Moreover, altered insertion patterns and skewed TRBV segment usage were observed in PBC patients. With regard to the pathogenesis, the concentration of E coli was higher in PBC patients' faecal. The frequency of E coli (and human)-specific TCRs was higher in the memory TCRβ repertoire of PBC patients compared with healthy controls. Importantly, the TCRβ repertoire characteristics were almost identical between E coli PDC-E2-related TCRs and human PDC-E2-related TCRs, including the patterns of TRBV usage, CDR3 length and amino acid composition.

CONCLUSION

Our findings comprehensively revealed the TCRβ repertoire characterization of PBC patients, and provided a TCR molecular basis to understand the mechanism of cross-recognition between human PDC-E2 and E coli PDC-E2, and the imbalance of immune tolerance in PBC.

Cellular and humoral autoreactivity in idiopathic pulmonary fibrosis

Idiopathic pulmonary fibrosis (IPF) is a morbid, refractory lung disorder with an unknown pathogenesis. To investigate potential adaptive immune mechanisms in IPF, we compared phenotypes and effector functions of peripheral CD4 T cells, autoantibody production, and proliferative responses of pulmonary hilar lymph node CD4 T cells to autologous lung extracts from afflicted patients and normals. Our results show that greater proportions of peripheral CD4 T lymphocytes in IPF subjects expressed MHC class II and CD154 (CD40L), and they more frequently elaborated TGF-beta1, IL-10, and TNF-alpha. Abnormal CD4 T cell clonal expansions were found in all IPF patients, and 82% of these subjects also had IgG autoantibodies against cellular Ags. IPF lung extracts stimulated proliferations of autologous CD4 T cells, unlike preparations from normals or those with other lung diseases, and the IPF proliferative responses were enhanced by repeated cycles of stimulation. Thus, CD4 T cells from IPF patients have characteristics typical of cell-mediated pathologic responses, including augmented effector functions, provision of facultative help for autoantibody production, oligoclonal expansions, and proliferations driven by an Ag present in diseased tissues. Recognition that an autoreactive immune process is present in IPF can productively focus efforts toward identifying the responsible Ag, and implementing more effective therapies.

Immunoglobulin is a highly diverse self-molecule that improves cellular diversity and function during immune reconstitution

Paradoxically, human B cell immune deficiencies are associated with increased susceptibility to viral and fungi infections, which are T cell immunity related infections. Also, some viral infections occurring in immune depressed patients such as cytomegalovirus infections are recommended to be treated with intravenous immunoglobulin (IVIg) in combination with antiviral therapy. This fact has no clear biological explanation but it has been shown to be successful. Recently, B cells and immunoglobulin were identified as essential elements driving T cell receptor (TCR) diversity generation. Idiotype peptides of B cell immunoglobulin may be the driving force for the antigen presenting function of B cells and other antigen presenting cells to influence the T cell repertoire. This seems to be another relevance of Jerne's idiotypic network and another function of immunoglobulin. Since T cells function depends on the diversity of the TCR repertoire, means to increase the diversity of the T cell repertoire may improve T cell function in situations characterized by a contracted TCR repertoire, such as AIDS, primary immunodeficiency, cancer, autoimmunity and following chemotherapy and hematopoietic precursors transplantation. The clinical hypothesis here put forward is that B cells and/or immunoglobulin may be used therapeutically aiming to increase and potentially to restore T cell repertoire diversity improving T cell function in situations implicating a contracted T cell repertoire. The fact that immunoglobulin influence the composition of T cell repertoire by increasing its diversity allows a much wider application of this molecule in the clinical practice. Here is presented a novel reasoning for the use of IVIg in humans, which should be explored. All the situations where immune reconstitution occurs are potentially a target for this therapeutically mechanism, aiming to fast and improve the diversity of the reconstituted immune repertoires. This new role of Ig molecule, an old and widely therapeutically used molecule, may help to explain several effects that IVIg have in the T cell compartment, such as modulation of the activation and function of effectors T cells. The idea that immunoglobulin is essential in the generation and maintenance of a diverse compartment of T cells, affecting T cell function via that mechanism suggests a promising approach to medical conditions involving immune reconstitution. Furthermore, it represents a new paradigm of understanding the immune system as a complex, interdependent web of cells/cell products that inter-affect each other generation, function and survival.