Muthukumar Gunasekaran

Donor-Derived Exosomes With Lung Self-Antigens in Human Lung Allograft Rejection.

The immunological role of exosomes in allograft rejection remains unknown. We sought to determine whether exosomes are induced during lung allograft rejection and to define the antigenic compositions of HLA, lung‐associated self‐antigens (SAgs) and microRNAs (miRNAs). Exosomes were isolated from sera and bronchoalveolar lavage fluid from 30 lung transplant recipients (LTxRs) who were stable or who had acute rejection (AR) or bronchiolitis obliterans syndrome (BOS). Exosomes were defined by flow cytometry for CD63 and western blotting for annexin V SAgs, collagen V (Col‐V) and Kα1 tubulin were examined by electron microscopy; miRNAs were profiled by a miRNA array. Donor HLA and SAgs were detected on exosomes from LTxRs with AR and BOS but not from stable LTxRs. Exosomes expressing Col‐V were isolated from sera from LTxRs 3 mo before AR and 6 mo before BOS diagnosis, suggesting that exosomes with SAgs may be a noninvasive rejection biomarker. Exosomes isolated from LTxRs with AR or BOS also contained immunoregulatory miRNAs. We concluded that exosomes expressing donor HLA, SAgs and immunoregulatory miRNAs are present in the circulation and local site after human lung transplantation and play an important role in the immune pathogenesis of acute allograft rejection and BOS.

Exosomes expressing the self-antigens myosin and vimentin play an important role in syngeneic cardiac transplant rejection induced by antibodies to cardiac myosin

Long‐term success of heart transplantation is hindered by humoral and cell‐mediated immune responses. We studied preexisting antibodies to cardiac self‐antigens, myosin and vimentin, and exosomes induced by antibodies to self‐antigens in eliciting immune responses to cardiac grafts. After syngeneic heterotopic murine heart transplantation, rabbit anti‐myosin or normal rabbit immunoglobulin was administered at day 0 or 7. Sera were collected after heartbeat cessation, cellular infiltration was analyzed, and exosomes were isolated from sera. Histopathologic examination of the controls transplanted hearts demonstrated normal architecture, and their sera demonstrated neither antibodies to self‐antigens nor exosomes expressing self‐antigens. Administration of antibodies to cardiac myosin immediately posttransplantation (day 0) but not on day 7 triggered graft failure on day 7, and histopathologic examination revealed marked cellular infiltration with neutrophils and lymphocytes. Histopathologic examination of rejected hearts also demonstrated myocyte damage as sera had increased antibodies to myosin and vimentin and development of exosomes expressing self‐antigens. Administration of exosomes isolated from failed grafts containing self‐antigens induced graft dysfunction; exosomes isolated from stable mice did not induce graft failure. Antibodies to self‐antigens can induce exosomes containing self‐antigens, initiating an immune response and causing graft failure after cardiac transplantation.

Circulating Exosomes with Distinct Properties during Chronic Lung Allograft Rejection

Circulating exosomes containing donor HLA and lung-associated self-antigens (SAg) are thought to play an important role in allograft rejection after human lung transplantation. We characterized exosomes isolated from serum of 10 lung transplant recipients (LTxR) diagnosed with bronchiolitis obliterans syndrome (BOS) and compared them with exosomes isolated from serum of 10 stable LTxR. Lung-associated SAg (K-α-1-tubulin [Kα1T] and collagen V [Col-V]), MHC class II molecules, costimulatory molecules CD40, CD80, and CD86, and transcription factors class II MHC trans-activator, NF-κB, hypoxia-inducible factor 1-α, IL-1R–associated kinase 1, MyD88, and 20S proteasome were detected in exosomes from BOS, but not stable LTxR. In contrast, adhesion molecules were present in both groups. C57BL/6 mice immunized with exosomes from BOS but not stable LTxR demonstrated Ab to SAg (Col-V, 33.5 ± 15.7 versus 10.4 ± 6.4, p = 0.021; Kα1T, 925 ± 403 versus 317 ± 285, p = 0.044) and HLA (mean fluorescence intensity: BOS, 8450; stable, 632; p < 0.05). Furthermore, splenic lymphocytes demonstrated increased frequency of lung SAg-specific IL-17 (Col-V, 128 ± 46 versus 31 ± 21, p = 0.013; Kα1T, 194 ± 47 versus 67 ± 43, p = 0.014) and IFN-γ (Col-V, 165 ± 79 versus 38 ± 40, p = 0.042; Kα1T, 232 ± 64 versus 118 ± 39, p = 0.012). Reduced levels of IL-10–producing cells were seen in BOS exosome immunized mice compared with mice immunized with stable exosomes (Col-V, 59 ± 23 versus 211 ± 85, p = 0.016; Kα1T, 78 ± 49 versus 295 ± 104, p = 0.017). Owing to the unique immune-stimulating properties of exosomes induced during rejection, we propose that they play an important role in eliciting both alloantigen- and SAg-specific immunity, leading to chronic rejection after lung transplantation.

Development of immune response to tissue‐restricted self‐antigens in simultaneous kidney‐pancreas transplant recipients with acute rejection

Simultaneous kidney‐pancreas transplantation (SKP Tx) is a treatment for end‐stage kidney disease secondary to diabetes mellitus. We investigated the role of immune responses to donor human leukocyte antigens (HLA) and tissue‐restricted kidney and pancreas self‐antigens (KSAgs and PSAgs, respectively) in SKP Tx recipients (SKP TxRs). Sera collected from 39 SKP TxRs were used to determine de novo Abs specific for KSAgs (collagen‐IV, Col‐IV; fibronectin, FN) and PSAgs (insulin, islet cells, glutamic acid decarboxylase, and pancreas‐associated protein‐1) by ELISA. KSAg‐specific IFN‐γ, IL‐17, and IL‐10 cytokines were enumerated by ELISpot. Abs to donor HLA classes I and II were determined by Luminex assay. Abs to KSAgs and PSAgs were detectable in recipients with rejection compared with stable recipients (P<.05). Kidney‐only rejection recipients had increased Abs against KSAgs compared with stable (P<.05), with no increase in Abs against PSAgs. Pancreas‐only rejection recipients showed increased Abs against PSAgs compared to stable (P<.05), with no Abs against KSAgs. SKP TxRs with rejection showed increased frequencies of KSAg‐specific IFN‐γ and IL‐17 with reduction in IL‐10‐secreting cells. SKP TxRs with rejection developed Abs to KSAgs and PSAgs demonstrated increased frequencies of kidney or pancreas SAg‐specific IFN‐γ and IL‐17‐secreting cells with reduced IL‐10, suggesting loss of peripheral tolerance to SAgs.

Immunoglobulin isotype switching of antibodies to vimentin is associated with development of transplant glomerulopathy following human renal transplantation

BACKGROUNDnImmune responses to tissue-restricted self-antigens are thought to play a role in chronic rejection after solid organ transplantation. De novo development of antibodies (Abs) to vimentin have been reported to be associated with interstitial fibrosis/tubular atrophy after kidney transplant, and it has been suggested that immunoglobulin isotype switching of Abs to vimentin may occur during this process. We aimed to determine the correlation between immunoglobulin isotype switching of Abs to vimentin and development of transplant glomerulopathy (TG) after kidney transplant, and to determine whether citrullinated modification of vimentin is required for de novo anti-vimentin development.nnnMETHODSnSera were collected from 24 patients with TG (diagnosed on biopsy), 24 matched stable kidney transplant recipients (KTxRs) and 22 normal healthy subjects who did not undergo transplant. Serum vimentin Abs concentrations were measured using enzyme-linked immunosorbent assay (ELISA). Immunoglobulin isotypes of anti-vimentin were determined using isotype-specific Abs conjugated with horseradish peroxidase. Samples were considered positive to vimentin Abs if the values were above mean+2× standard deviations of the levels in the healthy control subjects. Specificities of anti-vimentin for mutated citrullinated vimentin and anti-mutated citrullinated vimentin were measured by ELISA.nnnRESULTSnIn this retrospective analysis of 24 KTxRs with TG, 16/24 (67%) patients with biopsy-proven TG developed Abs to vimentin (645±427ng/ml). In contrast, only 4/24 (17%) stable KTxRs had detectable Abs to vimentin (275±293ng/ml; p=0.001). Of the patients with TG, 15/24 (63%) developed Abs to vimentin of IgG isotype (572±276ng/ml), whereas only 6/24 (25%) stable KTxRs (310±288ng/ml) had anti-vimentin of IgG isotype (p=0.002). However, no significant difference was noted in the concentration of IgM isotype anti-vimentin between KTxRs with TG (9/24 [38%], 407±401ng/ml) and stable KTxRs (5/24 [21%], 348±439ng/ml; p=0.631). The serum concentration of Abs specific for the mutated form of citrullinated vimentin was not significantly different between KTxRs with TG and stable KTxRs.nnnCONCLUSIONSnPatients with biopsy-proven TG demonstrated significantly increased levels of anti-vimentin Abs of the IgG isotype compared with stable KTxRs. Anti-vimentin in stable KTxRs was primarily of IgM isotype. Therefore, the observed isotype switching of anti-vimentin from IgM to IgG isotype strongly suggests ongoing immune responses to vimentin in KTxRs diagnosed with TG. Furthermore, as opposed to patients with rheumatoid arthritis (who develop immune responses primarily to citrullinated vimentin), KTxRs diagnosed with TG developed immune responses to non-citrullinated vimentin, suggesting that modification of vimentin protein via citrullination is not required for the de novo anti-vimentin response seen in patients with TG.