SignificanceThis work shows that the amidated terminal ends of the secreted hypocretin (HCRT) peptides (HCRTNH2) are autoantigens in type 1 narcolepsy, an autoimmune disorder targeting HCRT neurons. The autoimmune process is usually initiated by influenza A flu infections, and a particular piece of the hemagglutinin (HA) flu protein of the pandemic 2009 H1N1 strain was identified as a likely trigger. This HA epitope has homology with HCRTNH2 and T cells cross-reactive to both epitopes are involved in the autoimmune process by molecular mimicry. Genes associated with narcolepsy mark the particular HLA heterodimer (DQ0602) involved in presentation of these antigens and modulate expression of the specific T cell receptor segments (TRAJ24 and TRBV4-2) involved in T cell receptor recognition of these antigens, suggesting causality.
Objective: Previous studies suggested a role for the immune system in Parkinson disease (PD), and one of the hits in recent genome-wide association studies (GWASs) of PD is within the human leukocyte antigen (HLA) locus. Several associations of different HLA genes have been suggested, yet it is not clear which associations are relevant for PD. Methods: We performed a thorough analysis of the HLA locus in 13,770 PD patients, 20,214 proxy-cases and 490,861 controls of European origin. We used GWAS data to impute HLA types and performed multiple regression models to examine the association of specific HLA types, different haplotypes and specific amino acid changes. We further performed conditional analyses to identify specific alleles or genetic variants that drive the association with PD. Results: Four HLA types were associated with PD after correction for multiple comparisons, HLA-DQA1*03:01, HLA-DQB1*03:02, HLA-DRB1*04:01 and HLA-DRB1*04:04. Haplotype analyses followed by amino-acid analysis and conditional analyses suggested that the association is protective and primarily driven by three specific amino acid polymorphisms present in most HLA-DRB1*04 subtypes - 11V, 13H and 33H (OR=0.87 95%CI=0.83-0.90, p<8.23x10-9 for all three variants). No other effects were present after adjustment for these amino acids. Interpretation: Our results suggest that specific variants in the HLA-DRB1 gene are associated with reduced risk of PD, providing additional evidence for the role of the immune system in PD. Although effect size is small and has no diagnostic significance, understanding the mechanism underlying this association may lead to identification of new targets for therapeutics development.
Kleine-Levin Syndrome (KLS) is a rare disorder characterized by severe episodic hypersomnia, with cognitive impairment accompanied by apathy or disinhibition. Pathophysiology is unknown, although imaging studies indicate decreased activity in hypothalamic/thalamic areas during episodes. Familial occurrence is increased, and risk is associated with reports of a difficult birth. We conducted a worldwide case-control genome wide association study in 673 KLS cases collected over 14 years, and ethnically matched 15,341 control individuals. We found a strong genome-wide significant association (OR=1.48,rs71947865,p=8.6×10−9) with 20 single nucleotide polymorphisms encompassing a 35kb region located in the 3’ region of TRANK1 gene, previously associated with bipolar disorder and schizophrenia. Strikingly, KLS cases with TRANK1 rs71947865 variant had significantly increased reports of a difficult birth. As perinatal outcomes have dramatically improved over the last 40 years, we further stratified our sample by birth years and found that recent cases had a significantly reduced TRANK1 rs71947865 association. While theTRANK1 rs71947865 association did not replicate in the entire follow-up sample of 171 KLS cases, the TRANK1 rs71947865 was significantly associated with KLS in the subset follow-up sample of 59 KLS cases who reported birth difficulties (OR=1.54;p=0.01). Genetic liability of KLS as explained by polygenic risk scores was increased (pseudo r2=0.15;p<2.0×10−22 at p=0.5 threshold) in the follow-up sample. Pathway analysis of genetic associations identified enrichment of circadian regulation pathway genes in KLS cases. Our results suggest links between KLS, behavioral rhythmicity, and bipolar disorder, and indicates that the TRANK1 polymorphisms in conjunction with reported birth difficulties may predispose to KLS.Significance StatementGenetic markers in TRANK1 gene and its vicinity have been weakly associated with bipolar disorder and schizophrenia (10% increased risk). We found that the same polymorphisms are associated with Kleine-Levin Syndrome (50% increased risk), a rare sleep disorder characterized by recurrent episodes of severe hypersomnia and cognitive abnormalities. Response to lithium treatment are suggestive of a pathophysiological overlap between KLS and bipolar disorder. The study also shows that variants in the TRANK1 gene region may predispose to KLS when patients have had a difficult birth, suggesting that TRANK1 gene region modulate newborns’ response to brain injury, with consequences for mental and neurological health in adulthood. Another possibility may be that the polymorphism impact birth and KLS.
Type 1 narcolepsy (T1N) is caused by hypocretin/orexin (HCRT) neuronal loss. Association with the HLA DQB1*06:02/DQA1*01:02 (98% vs. 25%) heterodimer (DQ0602), T cell receptors (TCR) and other immune loci suggest autoimmunity but autoantigens are unknown. Onset is seasonal and associated with influenza A, notably pandemic 2009 H1N1 (pH1N1) infection and vaccination (Pandemrix). Peptides derived from HCRT and influenza A, including pH1N1, were screened for DQ0602 binding and presence of cognate DQ0602 tetramer-peptide-specific CD4 + T cells tested in 35 T1N cases and 22 DQ0602 controls. Higher reactivity to influenza pHA 273-287 (pH1N1 specific), PR8 (H1N1 pre-2009 and H2N2)-specific NP 17-31 and C-amidated but not native version of HCRT 54-66 and HCRT 86-97 (HCRT NH2 ) were observed in T1N. Single-cell TCR sequencing revealed sharing of CDR3β TRBV4-2-CASSQETQGRNYGYTF in HCRT NH2 and pHA 273-287 -tetramers, suggesting molecular mimicry. This public CDR3β uses TRBV4-2, a segment modulated by T1N-associated SNP rs1008599, suggesting causality. TCR-α/β CDR3 motifs of HCRT 54-66-NH2 and HCRT 86-97-NH2 tetramers were extensively shared: notably public CDR3α, TRAV2-CAVETDSWGKLQF-TRAJ24, that uses TRAJ24, a chain modulated by T1N-associated SNPs rs1154155 and rs1483979. TCR-α/β CDR3 sequences found in pHA [273][274][275][276][277][278][279][280][281][282][283][284][285][286][287] , and HCRT NH2 tetramerpositive CD4 + cells were also retrieved in single INF-γ-secreting CD4 + sorted cells stimulated with Pandemrix, independently confirming these results. Our results provide evidence for autoimmunity and molecular mimicry with flu antigens modulated by genetic components in the pathophysiology of T1N. narcolepsy | TCR | autoimmunity | DQ0602 | tetramer W hereas genetic (1-6), epidemiological (7-11), and pathophysiological (12-14) studies implicate autoimmunity in response to flu infection in type 1 narcolepsy (T1N), a disease caused by hypocretin (HCRT) neuronal loss (15-17), the autoantigen involved is still unknown. Unlike other autoimmune diseases, autoantibodies to HCRT cell proteins, HCRT itself (18-21), or other targets, such as TRIB2 (22,23) or HCRT receptor 2 (HCRTR2) (24-27) have not been consistently found. This has led to the suggestion that HCRT cell loss may be T cellmediated, with limited or no involvement of autoantibodies.A large recent genome-wide association study analysis of over 5,500 patients across multiple ethnicities confirmed the primordial importance of the HLA DQ0602 heterodimer in disease predisposition, with important secondary associations in T cell receptor (TCR) loci α and β, and other immune loci, such as perforin (28). Of additional interest is the observation that TCR polymorphisms associated with T1N are quantitative trait loci (QTL) for TRAJ24 (decreasing), TRAJ28, and TRVB4-2 (increasing) usage in peripheral T cells in both controls and patients (28). A significant L to F coding polymorphism (underlined in sequences throughout the paper) located within the antigen binding complementarit...
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