Profiling non-HLA antibody responses in antibody-mediated rejection following heart transplantation.

Antibody-mediated rejection (AMR) driven by the development of donor-specific antibodies (DSA) directed against mismatched donor human leukocyte antigen (HLA) is a major risk factor for graft loss in cardiac transplantation. Recently, the relevance of non-HLA antibodies has become more prominent as AMR can be diagnosed in the absence of circulating DSA. Here, we assessed a single-center cohort of 64 orthotopic heart transplant recipients transplanted between 1994 and 2014. Serum collected from patients with ≥ pAMR1 (n = 43) and non-AMR (n = 21) were tested for reactivity against a panel of 44 non-HLA autoantigens. The AMR group had a significantly greater percentage of patients with elevated reactivity to autoantigens compared to non-AMR (P = .002) and healthy controls (n = 94, P < .0001). DSA-positive AMR patients exhibited greater reactivity to autoantigens compared to DSA-negative (P < .0001) and AMR patients with DSA and PRA > 10% were identified as the subgroup with significantly elevated responses. Reactivity to 4 antigens, vimentin, beta-tubulin, lamin A/C, and apolipoprotein L2, was significantly different between AMR and non-AMR patients. Moreover, increased reactivity to these antigens was associated with graft failure. These results suggest that antibodies to non-HLA are associated with DSA-positive AMR although their specific role in mediating allograft injury is not yet understood.

Polymorphism and linkage disequilibrium of immunoglobulin-like transcript 3 gene.

Immunoglobulin-like transcript 3 (ILT3) is an inhibitory receptor molecule expressed by dendritic cells, monocytes, and endothelial cells. Upon upregulation of ILT3 expression, antigen presenting cells (APCs) become tolerogenic, triggering the differentiation of antigen-specific CD8(+) and CD4(+) regulatory T cells. To analyze the polymorphism of ILT3, we screened DNA from a panel of 150 healthy subjects for single nucleotide polymorphisms (SNPs) within genomic region encoding the extracellular domain (exons 1-8). Here we report the identification of 15 SNPs, including nine nonsynonymous, three synonymous base-pair substitutions, and three intronic, including one deletion polymorphism within 3.6 kb of the ILT3 genomic region. Analysis of three physically linked SNP in healthy individuals indicates that c.356-41-46del, a 6-base-pair (bp) deletion located in intron 3/4, is predominantly associated with c.678A allele, a nonsynonymous SNP located in exon 5. Linkage studies in five nuclear families showed that these two minor alleles co-segregate. Our results demonstrate that ILT3 is highly polymorphic and may be associated with susceptibility to immune disorders.

New-onset graft dysfunction after heart transplantation--incidence and mechanism-related outcomes.

BACKGROUND: Graft dysfunction (GD) after heart transplantation (HTx) is a major cause of morbidity and mortality. The impact of different pathophysiologic mechanisms on outcome is unknown. In this large, single-center study we aimed to assess the incidence of GD and compare the outcomes with different histopathologic mechanisms of rejection. METHODS: We analyzed a data set of 1,099 consecutive patients after their HTx at Columbia University Medical Center between January 1994 and March 2008, and identified all patients hospitalized with new-onset GD. Based on the histopathologic data, patients were divided into GD-unexplained (Group-GD-U), GD-antibody-mediated rejection (Group-GD-AMR), GD-cardiac allograft vasculopathy (Group-GD-CAV) and GD-acute cellular rejection (Group-GD-ACR) groups. We compared the in-hospital and 3-, 6- and 12-month mortality across these groups using the chi-square test. We also compared the 3-, 6- and 12-month survival curves across groups using the log-rank test. RESULTS: Of 126 patients (12%) identified with GD, complete histology data were available for 100 patients. There were 21, 20, 27 and 32 patients identified in Group-GD-U, Group-GD-AMR, Group-GD-CAV and Group-GD-ACR, respectively. The in-hospital mortality rates were 52%, 20%, 15% and 6%, respectively. The in-hospital mortality rate was significantly higher in Group-GD-U compared with all other groups (p = 0.0006). The 3-, 6- and 12-month survival rate was also significantly lower in Group-GD-U compared with all other groups. CONCLUSION: A significant proportion of patients presenting with new-onset GD have unexplained histopathology. Unexplained GD is associated with a significantly higher mortality rate. New diagnostic tools are necessary to better understand and detect/predict this malignant phenotype.

Alloantibodies in heart transplantation.

The presence of complement fixing anti-human leukocyte antigen (HLA) antibodies in the circulation of organ transplant recipients may result in heart allograft rejection. Here, we assessed the clinical impact of pre- and post-transplantation allosensitization on long-term survival of heart allografts. Sequential samples of sera from heart allograft recipients were screened pretransplantation for panel reactive antibodies using the complement-dependent cytotoxicity test. Patients were monitored post-transplantation for donor specific anti-HLA class I and class II antibodies. Kaplan-Meier graft survival plots were generated to analyze the effect of anti-HLA antibodies on transplantation outcomes. Statistical analysis showed that the post-transplantation development of alloantibodies was a significant risk factor that was associated with low long-term survival rates; in contrast, recipients' gender, age, previous transplantations, and degree of HLA matching with the donor had no effect on long-term survival. The presence in pretransplantation sera of antibodies against more than 10% of the HLA reference panel (PRA >10%) was associated with AMR and with a relatively lower rate of graft survival after 1 year but did not affect 10-year survival. The present data underline the importance of monitoring the development of anti-HLA antibodies as a tool for early diagnosis and treatment of AMR.