Narcolepsy type 1 (NT1) is caused by a loss of hypocretin/orexin transmission. Risk factors include pandemic 2009 H1N1 influenza A infection and immunization with Pandemrix®. Here, we dissect disease mechanisms and interactions with environmental triggers in a multi-ethnic sample of 6,073 cases and 84,856 controls. We fine-mapped GWAS signals within HLA (DQ0602, DQB1*03:01 and DPB1*04:02) and discovered seven novel associations (CD207, NAB1, IKZF4-ERBB3, CTSC, DENND1B, SIRPG, PRF1). Significant signals at TRA and DQB1*06:02 loci were found in 245 vaccination-related cases, who also shared polygenic risk. T cell receptor associations in NT1 modulated TRAJ*24, TRAJ*28 and TRBV*4-2 chain-usage. Partitioned heritability and immune cell enrichment analyses found genetic signals to be driven by dendritic and helper T cells. Lastly comorbidity analysis using data from FinnGen, suggests shared effects between NT1 and other autoimmune diseases. NT1 genetic variants shape autoimmunity and response to environmental triggers, including influenza A infection and immunization with Pandemrix®.
The sleep disorder type 1 narcolepsy (NT1) affects ~0.03% individuals across ethnic groups and populations1,2,3 and onset manifestation most commonly occurs in childhood or adolescence. As one of the symptoms, cataplexy, is almost entirely specific to NT1, diagnosis is clinical, although sleep recordings are performed for confirmation. Symptoms are caused by the autoimmune destruction of hypocretin/orexin (HCRT) neurons in the hypothalamus4. NT1 is 97% associated with HLA-DQA1*01:02~ DQB1*06:02, alleles encoding the DQ heterodimer DQ06025,6. Other predisposing loci include T-cell receptor (TCR) loci TRA and TRB, a type 1 interferon response receptor gene, IFNAR1, as well as other autoimmune-associated genes (CTSH, P2RY11, ZNF365, and TNFSF4)7,8,9,10. Recent studies identified HCRT, notably C-amidated fragments of secreted HCRT peptides (HCRTNH2), as CD4+ T-cell autoantigens11,12,13,14,15.
Triggers of NT1 autoimmunity point to Influenza-A9,16,17 and, secondarily, Streptococcus pyogenes infections18,19. Onset in children is abrupt and seasonal peaking between spring and summer16, presumably following a winter infection. Further, multiple countries have reported increased incidence of NT1 4–6 months following the 2009 H1N1 (pH1N1) “swine flu” pandemic16,17,20. Finally, immunization with Pandemrix®, a pH1N1 vaccine created to prevent the 2009 pandemic, is an established trigger for NT117,20,21. Increased incidence following Pandemrix® was first seen in Northern Europe, with incidence in children increasing from 0.79/100,000 to 6.3/100,00021. Specificity is striking, as increased NT1 was later detected in all European countries where Pandemrix® was used, whereas countries using other vaccine brands did not display vaccination-associated increases in incidence17,20. The reason for the vaccine brand specificity may involve differences in flu antigen preparations and/or timing of vaccination when infections peaked in some countries17,20. Frequency of other autoimmune diseases did not increase following Pandemrix® vaccination20.
In this study, we characterize novel genetic factors for NT1 across multiple ethnic groups, performing computational and functional fine mapping. Our findings establish a compelling pathophysiological mechanism for the disease that implicate antigen presentation by DQ0602 to specific CD4+ T cells and subsequent CD8+ T-cell activation, with applications in the autoimmune disease and vaccination fields.
GWAS discovers novel risk loci for NT1
5,848 cases and 61,153 controls derived from ten cohorts were used as the initial discovery GWAS sample (Table S1). We found associations in HLA (P < 10−216), confirmed previously identified loci (TRA, TRB, CTSH, IFNAR1, ZNF365, TNFSF4) and found 7 novel loci near CD207, NAB1, IKZF4-ERBB3, CTSC, DENND1B, SIRPG and PRF1 (Figs. 1A and 2A, B, Table 1; Supplementary Figs. 1 and 2). We observed that most associations were shared across all ethnic groups. Significance between-cohort heterogeneity was observed with TRA, SIRPG and DENND1B (Table S2). Finally, as both influenza infections and, in rare cases, immunization with Pandemrix®, associates with NT120, 245 vaccination induced NT1 cases identified in four countries were also studied. In this sub-sample, we found GWAS significant signals with HLA-DQB1*06:02 and TRA rs1154155, as well as shared polygenetic risk (Table 1 and Supplementary Fig. 3). The lack of association of other loci is likely due to the small number of individuals with vaccination-related narcolepsy.
Interestingly, GWAS results are unusually rich in missense variants. In addition to HLA polymorphisms, these include a TRAJ24 (F8V) substitution, polymorphisms in langerin (CD207 N288D and K313I), as well as variants in CTSC (I453L) and PRF1 (A91V); the last two are known hypomorphs involved in autosomal recessive conditions with abnormal sensitivity to viral infections. Finally, we found that the effects of some of these variants colocalized between NT1 and type 1 diabetes (CTSH G11R and SIRPG S286L, posterior probability = 1.0). Functional effects of these missense variants are detailed in Supplementary Data 1 and Supplementary Fig. 2.
Other polymorphisms found in the GWAS and associated with other autoimmune diseases include ZNF365 (atopic eczema, ankylosing spondylitis, Crohn’s disease, psoriasis, primary sclerosing cholangitis, ulcerative colitis, posterior probability = 1.0), TNFSF4 (eczema, asthma and allergic diseases, posterior probability = 1.0), NAB1 (primary biliary cholangitis r2 = 0.48, rheumatoid arthritis, r2 = 0.15) and IKZF4-ERBB (vitiligo and alopecia areata r2 = 0.36) (see Table Supplementary Data 1 and Supplementary Fig. 2 for functional descriptions and associations).
NT1 shares variants with other autoimmune diseases
Heritability in NT1 is similar to other pediatric autoimmune diseases22; GCTA estimated observed scale heritability to be h2SNP[ci] = 0.403 [0.015]. Using a prevalence of 0.03%1,3, we estimate population heritability at h2SNP[ci] = 0.231 [0.0088], consistent with twin studies23. We found that shared heritability was largest with sleepiness and daytime napping and with autoimmune traits including psoriasis, multiple sclerosis and systemic lupus erythematosus in particular (P < 0.05, Table S3, Fig. 1E). We computed enrichment of NT1-associated genes with publicly available GWAS data at gene and variant level, identifying overlap with immune and infectious traits such as asthma, type 1 diabetes, primary biliary cholangitis, plantar warts and hepatitis B (P < 0.001, Fig. 1D–F and Table S4). Almost all variants identified (ZNF365, TNFSF4, NAB1, IKZF4-ERBB3, CTSC, DENND1B, SIRPG, and PRF1) are the same or strongly linked with markers associated with other autoimmune diseases (Supplementary Data 1).
In case/control studies, NT1 has been associated with various autoimmune diseases in some24,25, but not all26 studies. For example, Chen et al. (2021) found association of narcolepsy with asthma in the general Taiwanese population27. To further examine if autoimmune traits are associated with NT1 in epidemiological samples, we explored association between narcolepsy and autoimmune diseases and asthma in 342,499 participants of the FinnGen cohort, retrieving diagnosis of autoimmune diseases, asthma and narcolepsy. In this sample, narcolepsy (157 participants) was associated with psoriasis (OR = 2.29 [1.07–4.90], P = 0.033), hypothyroidism (OR = 4.61[2.39–8.93], P = 5.19*10−6), rheumatoid diseases (OR = 2.20[1.00–4.82], P = 0.049), asthma (OR = 4.58[3.04–6.89], P = 3.45*10−13) and “any” autoimmune disease (OR = 2.07[1.50–2.84], P = 8.31*10−6). Of note, since DQ0602 is extremely (OR = 0.03) protective against type 1 diabetes28 and strongly protective (OR = 0.64) against primary biliary cholangitis29; no narcolepsy cases had these dual pathologies. Taken together, these findings suggest shared effects between narcolepsy and other autoimmune diseases at both the epidemiological level and at multiple genetic loci, modulated by HLA genotypes.
Variants involved in antigenic stimulation and infections
The specific polymorphisms in langerin (CD207) we found associated with NT1 have previously been linked to interferon stimulus and influenza uptake by dendritic cells (DC) (Supplementary Data 1). Langerin is a type II transmembrane C-type lectin receptor expressed in Langerhans cells, a specialized type of dendritic cells located exclusively in the respiratory tract and the epidermis, and it recognizes mannose-rich sugars expressed by bacterial, fungal or viral pathogens, including HIV-1 and Influenza-A (Supplementary Data 1).
Our leading variant, rs3815556G, a rare allele, is in complete linkage disequilibrium (r2 = 1) with two coding variants, rs13383830C (N288D) and rs57302492A (K313I) that modulate recognition of bacterial versus viral antigens. The rare Asp-288/Ile-313 haplotype has langerin molecules with enhanced affinity for GlcNAc, present in influenza and other viruses, whereas the other haplotype has higher affinity for high-mannose structures and fucosylated glycans, as well as 6SO4-Gal binding activity. This may potentially allow for protection against a wider range of microorganisms, notably bacterial ones as well (Supplementary Data 1). The NT1-associated variants may thus affect disease predisposition by increasing influenza viral (as opposed to bacterial) uptake and antigen presentation to CD4+ T cells.
In addition to langerin, we identified a regulatory variant near IL10RB-IFNAR1, rs2096464T. The SNP is a strong eQTL for IFNAR1 expression in various tissues in GTEx. IFNAR1 controls dendritic cell responses to viral infections, notably Influenza-A. We therefore examined IFNAR1 expression in DC following H1N1 infection (PR8 delta NS1), finding that the exact NT1 predisposing SNP (rs2096464) is the major eQTL for this effect (P = 1.92 × 10−25, beta = 0.140), as well as for interferon stimulation (P = 10−33, beta = 0.215), as it is in perfect LD with the leading variant for the signal (rs6517159, r2 = 0.93, Supplementary Fig. 4). Taken together, these findings suggest that NT1-associated variants may affect disease predisposition by increasing influenza viral (as opposed to bacterial) uptake and antigen presentation to CD4+ T cells, although additional mechanisms could be involved.
Fine mapping of multi-loci association in the HLA region
To further fine map the HLA association, we imputed classical HLA class I (HLA-A, HLA-B, HLA-C) and class II (HLA-DRB1, HLA-DQA1, HLA-DQB1, HLA-DPA1 and HLA-DPB1) genes using HIBAG30 and HLA IMP:0231 and examined allele associations with NT1. As expected5,6, the strongest association was with DQA1*01:02~DQB1*06:02 (DQ0602). To delineate additional signals, we performed conditional analysis using stepwise forward regression. We discovered protective associations with DQA1*01:01 and DQA1*01:03 (OR = 0.30, P < 10−15 and OR = 0.30, P < 10−20, respectively) and confirmed predisposing effects of DQB1*03:01 and DQA1*01:02 across ethnic groups, as shown before5,6,32,33 (OR = 1.23, P < 0.001 and OR = 1.47 P < 1 × 10−6, respectively) (Table S5). Finally, controlling for both DQB1 and DQA1 effects, a protective association was seen with the DPB1*04:02 allele (P-value < 10−20), whereas smaller predisposing effects were found with DPB1*05:01 and at HLA class I with A*11:01, B*51:01, B*35:01 and B*35:03, and protective association with A*03:01 (P < 0.01, Table S5). Taken together, these findings confirm and extend results from previous studies6,33 and highlight independent association of both HLA class I and II alleles with NT1.
Antigen Presentation and T-cell involvement in NT1
We next examined whether associations with NT1 were enriched genome-wide on specific enhancers using stratified LD score regression (LDSC) on Epigenome Roadmap cell type and ENTEX tissue-specific annotations (n = 491 cell and tissue types)34. Partitioned heritability by cell type categories was enriched in hematopoietic cell lines (observed h2 at hematopoietic cells = 0.24[0.11], P = 0.018) and after partitioning the signal into specific cell subsets, ten cell types showed enrichment with P < 0.005. These were either helper or cytotoxic T cells or NK cells (Fig. 1C and Supplementary Data 2). As LDSC does not keep information on the HLA region due to ambiguous linkage disequilibrium, we next examined the contribution of different immune cell types using enrichment analysis with genes close to GWAS significant variants. This analysis further supported the enrichment with CD4+ T cells, but also implicated antigen-presenting cells such as monocytes and dendritic cells (P-enrichment < 0.01, Table S6), reflecting, in addition to langerin and IFNAR1, expression of GWA significant, independently associated HLA-associated genes DQB1 and DPB1 (Supplementary Data 1). Together, these results indicate involvement of antigen presentation to CD4+ and CD8+ T cells in NT1.
Risk variants in T-cell receptor loci modulate αβ TCR repertoire
NT1 is the only autoimmune disease with known associations in both HLA and T-cell receptor (TCR) loci (TRA and TRB) (Fig. 2A, B). TCRα and β chains heterodimerize to form biologically functional molecules that recognize peptides presented by HLA. We therefore examined the function of these leading variants by examining effects on T-cell receptor V- or J-gene chain usage using RNA sequencing in 895 individuals35, as well as in 130 individuals sequenced specifically in both memory CD4+ and CD8+ T cells.
As mentioned above, rs1154155 within TRA is entirely linked with multiple SNPs across ethnic groups (Fig. 2C), one of which, rs1483979, substitutes a leucine to a phenylalanine in the CDR3 area of J24, which is predicted to interact with peptides presented by HLA (Fig. 2D; Supplementary Data 5 and 6). This substitution makes it a prime candidate for a functional effect, should an F allele J24*01 CDR3 sequence interact more favorably with an autoantigen than in the presence of J24*02. Making the matter more complex, however, J24 usage is also modulated by rs1154155, such that the F-associated allele is associated with decreased usage in CD4+ cells, as shown by the eQTL plot in Fig. 2F (beta = 0.33, P < 0.001). We also computed association in memory CD4+T cells and in CD8+ T cells and observed a consistent effect on TRA-J28 expression specifically (P = 2.29 × 10−10 and P = 4.08 × 10−10, in CD4+ and in CD8+ T cells, respectively). Finally, we confirmed that these effects are cis mediated, as the ratio of J24*01 (F) over J24*02 (L) was only 0.4 in heterozygotes, indicating lower allele expression of F-alleles, with similar effects in other T-cell subpopulations (Supplementary Fig. 5).
In addition to J24-specific effects, rs1154155 is also strongly associated with TRA-J28 expression in total RNA sequencing from blood (P = 1.36 × 10−10, beta = −0.212, Fig. 2E) with posterior probability for shared variant pp = 0.958 (see Supplementary Data 3 for all rs1154155 effects) and the findings were also consistent when testing across CD4+ memory cells (P = 2.29 × 10). Interestingly, rs1154155 is entirely linked with rs3764159, a polymorphism located 14 bp upstream of TRAJ-28 within the 12-base pair recombination signal sequence spacer, possibly explaining the J28 usage effect (Fig. 2C). Controlling for the NT1 TCRA association by lead QTL SNPs for J24 and J28 usage abolishes all effects, except for a minor peak at rs72638479, itself a minor eQTL (r2 = 0.95 with TRAV8-6, Supplementary Fig. 6).
Within the TRB region, rs7458379 is an eQTL for increased expression of TRBV4-2. However, based on our functional analysis, rs1108955 has the strongest evidence for increasing TRBV4-2 usage (pp = 0.99, Table S7, Supplementary Data 4). Furthermore, rs1008955 is in partial LD with rs7458379, but tags independent haplotypes at the TRB locus (Supplementary Fig. 7). Both variants are eQTLs for TRBV4-2 expression but reflect independent signals with NT1, such that analysis conditioning for rs7458379 shows remaining association with rs1108955 (P = 0.00019), whereas conditioning the association for rs1108955 removed all association at both the TRB locus and with rs7458379 (P = 0.72) (Supplementary Fig. 8). Taken together, this indicates that higher expression of TRBV4-2 is related to NT1 and mediated by rs7458379 and rs1108955, with the latter as the potentially causal variant at this locus.
In this study, we explored genetic risk for NT1 and potential disease mechanisms of identified genetic risk factors. The strongest associations were seen within the HLA region. In addition, we confirmed six previously described risk loci (TRA, TRB, CTSH, IFNAR1, ZNF365 and TNFSF4) and discovered seven novel associations in CD207, IKZF4-ERBB3, NAB1, CTSC, DENND1B, SIRPG, and PRF1.
Individual associations and partitioned heritability enrichment analysis indicate a primary role of the immune system for all loci identified. Most of these loci, often to the exact same SNP, have also been involved in other autoimmune diseases (Supplementary Data 1). These findings, together with the fact that narcolepsy is associated with increased risk of other autoimmune diseases in FinnGen, suggest that NT1 is an autoimmune disease, even if it does not meet all accepted criteria36. Further, most variants identified have effects in antigen-presenting cells (HLA, CTSH, TNFSF4), e.g., dendritic cells (IFNAR1, CD207), T cells (TRA, TRB, SIRPG), T helper cells (HLA-DQ, HLA-DP) or cytotoxic T cells/NK cells (HLA-A, PRF1, NAB1), sketching a remarkably narrow potential disease pathway (Fig. 3). In addition to epidemiological data, examining genetic factors overcomes disease-associated ascertainment bias in the recruitment of constitutive cohorts. Finally, two loci were implicated at GWA significant level in 245 vaccination-associated NT1 (TRA and HLA), while five other loci replicated nominally at P < 0.05 (CD207, NAB1, TRB, IKZF4-ERBB3, and CTSH), with overall strong genetic correlation between sporadic and vaccination-associated cases. This indicates that vaccination-triggered narcolepsy is essentially identical to sporadic narcolepsy.
Unlike what is reported in other autoimmune diseases, however, narcolepsy is strongly associated with TCA and TCB genetic polymorphism that modulate the TCR repertoire in very specific ways. A logical explanation for this observation could be that a TCR-mediated reactivity that involves receptors containing TRAJ24F, TRAJ28 and TRBV4-2 is an important step in the development of narcolepsy, perhaps through TCR recognition of a viral trigger or an autoantigen by CD4+ or CD8+ cells. This hypothesis is supported by recent studies suggesting usage of TRAJ24 and TRBV4-2 in the DQ0602 recognition of amidated HCRT, a likely autoantigen, as well as to specific influenza peptides with increased reactivity in narcolepsy14.
Based on these observations, we propose that NT1 is an autoimmune process where influenza A contributes to risk in the presence of HLA-DQA1*01:02~DQB1*06:02 (DQ0602). The involvement of influenza-A may explain why genetic associations found are shared across ethnic groups, as influenza is one of few viruses that act worldwide on a seasonal basis. It also relates to IFNAR1 and that both affect and respond to influenza infections, although other infectious triggers cannot be excluded. Notably, the literature suggests that langerin with Asp-288 and Ile-313 shows no binding to 6SO4-Gal-terminated glycans, increased binding to GlcNAc-terminated structures and overall decreased binding to glycans. This would make langerin more restricted in its ability to bind complex carbohydrates and more able to bind GlcNAc-terminated structures, which overall would favor influenza, but also many other organisms. Similarly, IFNAR1 has been linked to antiviral immunity more generally as well, hence specificity to flu infections cannot be concluded with complete certainty.
The universal genetic association is especially clear for HLA-DQ0602, as it is found with different nearby located HLA-DRB1 alleles: DRB1*15:01 in individuals of primary European (Europe and USA) and Asian (China, Korea, Japan and India) descent, but DRB1*15:03 or DRB1*11:01 in individuals of primary Africa descent5,6. The primacy of DQ0602 over DRB1*15:01 (and thereby DRB5, as LD is complete) is also demonstrated by the fact that the DRB1*15:01~ DQA1*01:02~DQB1*06:01 haplotype is not associated with narcolepsy in China and by the fact additional DQ effects are mostly mediated by DQA1 alleles that interact in trans with DQB1*06:02 (i.e., DQA1*01:01 and DQB1*01:03)33. Consequently, the association with DRB1*15:01 was slightly less significant than association with DQ0602. In contrast to NT1, other autoimmune diseases, such as multiple sclerosis and type 1 diabetes, commonly have different HLA associations or disease presentations across countries, resulting in more complex HLA associations. Type 1 diabetes, for example, is well known to be mostly associated with HLA-DRB1*03:01 and DRB1*04 and associated DQ alleles in Europe, whereas DRB1*04:05-specific effects are evident in Japan, where the disease and these DRB1 alleles are rare37,38,39.
In this study, a hypomorph of perforin, a gene of critical importance to NK and T-cell cytotoxicity, was protective of NT1. Supporting this, we saw enrichment through tissue-specific partitioned heritability in cytotoxic NK and T cells. Although it is conceivable that NK cells or cytotoxic CD4+ T cell could be involved, the most likely explanation is involvement of CD8+ T cell in hypocretin cell killing. Indeed, neurons never express HLA class II, so expression of HLA class I and recognition of hypocretin neuronal antigens would be needed for hypocretin cell pathology to occur. This is also supported by the CTSC association, an enzyme of critical importance to cytotoxic CD8+ activation of pro-granzymes40. Further, Bernard-Valnet et al.41 used transgenic mice with expression of a neoantigen in HCRT neurons and found that infusion of CD8+ T-cell targeting the neoantigen were able to cause hypocretin cell destruction, while infusion of neoantigen-specific CD4+ T-cell alone was insufficient, although CD4+ T cells migrated closely to the target neurons. Pedersen et al. (2019) also found NT1-associated CD8+ T-cell targeting intracellular transcription factors such as RFX4 and LXH9, known to be enriched in HCRT cells15. Finally, CD8+ mediation of cell killing has also been suggested by observation of a CD8+ T-cell infiltrate in a paraneoplastic anti-Ma2 encephalitis case with symptomatic hypocretin cell destruction, although these cases are complex and not associated with DQ060242.
In summary, genetic data indicates T-cell autoimmunity in NT1 with genetic overlap of autoimmune traits. A particularity of the disease is involvement of polymorphisms such as in IFNAR1 and CD207 that regulate antigen-presenting cell responses to infection. Another peculiarity is strong association with TCR polymorphisms, possibly reflecting oligoclonality of T-cell responses. With epidemiological studies indicating seasonality of disease onset16, and increased incidence following vaccination with Pandemrix® in Europe17,20, a role of influenza or other infections is likely. CTSH implicates dendritic processing of antigens, perhaps of post-translationally modified HCRT itself11,12,13,14,15. Presentation by DQ0602 to CD4+ T cells ensue, with likely involvement of very few autoantigen epitopes and a restricted number of T-cell receptors, explaining the large effect of these loci. Subsequent cell killing of hypocretin neurons by CD8+ cells, may be through involvement of other, intracellular autoantigens43, complete the process. Altogether, this work illustrates how GWAS can identify the involvement of different cell types in a specific condition, thus ultimately providing further insight to the possible pathophysiological mechanisms underlying disease onset.
This study has been reviewed and approved by the Stanford University Institutional Review Board (IRB) on Medical Human Subjects (Protocol # 14325, genetic and blood markers in narcolepsy and hypersomnia, Registration # IRB00005136) and by respective IRB panels in each country providing samples for the study. Informed consent was obtained from each participant in accordance with governing institutions. Patients and control subjects in FinnGen provided informed consent for biobank research, based on the Finnish Biobank Act. Alternatively, separate research cohorts, collected prior the Finnish Biobank Act came into effect (in September 2013) and start of FinnGen (August 2017), were collected based on study-specific consents and later transferred to the Finnish biobanks after approval by Fimea, the National Supervisory Authority for Welfare and Health. Recruitment protocols followed the biobank protocols approved by Fimea. The Coordinating Ethics Committee of the Hospital District of Helsinki and Uusimaa (HUS) approved the FinnGen study protocol Nr HUS/990/2017. The FinnGen study is approved by Finnish Institute for Health and Welfare (THL), approval number THL/2031/6.02.00/2017, amendments THL/1101/5.05.00/2017, THL/341/6.02.00/2018, THL/2222/6.02.00/2018, THL/283/6.02.00/2019, THL/1721/5.05.00/2019, Digital and population data service agency VRK43431/2017-3, VRK/6909/2018-3, VRK/4415/2019-3 the Social Insurance Institution (KELA) KELA 58/522/2017, KELA 131/522/2018, KELA 70/522/2019, KELA 98/522/2019, and Statistics Finland TK-53-1041-17. The Biobank Access Decisions for FinnGen samples and data utilized in FinnGen Data Freeze 5 include: THL Biobank BB2017_55, BB2017_111, BB2018_19, BB_2018_34, BB_2018_67, BB2018_71, BB2019_7, BB2019_8, BB2019_26, Finnish Red Cross Blood Service Biobank 7.12.2017, Helsinki Biobank HUS/359/2017, Auria Biobank AB17-5154, Biobank Borealis of Northern Finland_2017_1013, Biobank of Eastern Finland 1186/2018, Finnish Clinical Biobank Tampere MH0004, Central Finland Biobank 1-2017, and Terveystalo Biobank STB 2018001. (for details, see supplementary materials 1.7 FinnGen). We confirm that all methods were carried out in accordance with relevant guidelines and regulations.
Six-thousand seventy-three unrelated individuals with NT1, some included in prior studies8,9, and 84,856 ancestry-matched controls were included in the study. In addition, 245 individuals with vaccination-related NT1 and 18,862 controls were recruited in Finland (N = 76 cases and 2796 controls), Sweden (N = 39 cases and 4894 controls), Norway (N = 82 cases and 429 controls) and United Kingdom and Ireland (N = 48 cases and 10,743 controls)44,45,46,47. All cases had documented immunization with Pandemrix®. All cases had narcolepsy with clear-cut cataplexy and were DQB1*06:02 positive or had narcolepsy with documented low hypocretin-1 in the cerebrospinal fluid. From FinnGen, we used ICD-10 code G47.4 and ICD-9 code 347, thus including individuals who have narcolepsy with or without cataplexy (for details, see Supplementary Materials 1.7 FinnGen).
Subjects were genotyped with Affymetrix Affy 5.0, Affy 6.0, Affymetrix Axiom CHB1, Affymetrix Axiom EUR, Axiom EAS, Axiom LAT, Axiom AFR, Axiom PMRA and Human Core Exome chip platforms (Table S1). Genotypes were called with Affypipe48, Affymetrix genotyping console or Genome Studio. Markers with genotyping quality (call rate < 0.95) or deviation from Hardy-Weinberg equilibrium (P-value < 10−6) were discarded. Samples were checked for relatedness by filtering based on proportion of identity-by-descent using cut off >0.2 in PLINK 1.9 PI_HAT score. One pair of related individuals was removed. If related individuals were a case and a control, cases were retained in the analysis. Three first principal components within each cohort were visualized and outliers removed.
We imputed samples by pre-phasing cases and controls together using SHAPEIT v2.2 and imputed with IMPUTE2 v2.3.249,50 and 1000 Genomes phase 1v3 build37 (hg19) in 5 Mb chunks across autosomes. Haplotype reference consortium data was used for the second Stanford collection. For variants having both imputed and genotyped values, the genotyped values were kept, whereas for those individuals where genotype was missing, imputed values were kept.
Genetic analyses and statistics
Analyses for all data sets were performed at Stanford University except for the Finnish and Swedish vaccination-related cases and European Narcolepsy Network samples, which were analyzed by respective study teams using the same analytical methods. GWAS was first performed in each case control group separately using SNPTEST v.2.5.251. To adjust for cohort-specific population stratification issues, we used linear regression implemented in SNPTEST method score adjusting for the first ten principal components. Standard post imputation quality control was done. Variants with info score <0.5 and minor allele frequency (MAF) < 0.01 were removed from the analysis. Signals specific for one genotyping platform only and variants in each locus with heterogeneity P-value < 10−20 were removed. We used a fixed-effects model implemented in METAv1.7 with an inverse-variance method based on a fixed-effects model for combining association results52. In total, 12,600,187 markers across studies were included in the final case/control meta-analysis. The significance level for statistically significant association was set to genome-wide significance (P-value < 5 × 10−8), controlling for multiple testing. Overall, test statistics showed no genomic inflation (lambda < 1.05). GCTA was used for heritability and gene-based tests53. Coloc analysis was done using coloc package in R version 3.4.2 (2017-09-28)54 and Manhattan and QQ-plots were created with QQman or FUMA. Shared and partitioned heritability was estimated using LD score regression. To compare the main characteristics of the participants, we used a multivariate logistic regression model as implemented in the R glm package. Lastly, we used FUMA and the curated list of GWAS as provided by FUMA to compute gene enrichment analysis for loci that were associated with narcolepsy at genome-wide significant level and to examine the association between narcolepsy loci and previous GWAS55. We also computed genetic correlation between autoimmune traits and narcolepsy using LD score regression and estimated PheWAS associations per lead variant in each locus using the Open targets resource https://genetics.opentargets.org/.
Comparison of vaccination and non-vaccination cases
Vaccination samples were studied separately for GWAS. To compare genetic architecture of narcolepsy cases following vaccination versus other cases, we first examined association of each GWAS significant SNPs of the primary (non-vaccinated) sample in the vaccination sample. In addition, we computed polygenic risk score in non-vaccination narcolepsy cases and vaccination-related narcolepsy using PRSice56 and looked at overlap.
Typing and imputation of HLA variants
High-resolution HLA imputation in 4-digit resolution (2-field, amino acid level) for HLA A, B, C, DRB1, DQA1, DQB1, DPA1 and DPB1 was performed using HLA*IMP:02 as implemented in Affymetrix HLA or the HIBAG package in R version 3.1.2 (2014-10-31). HIBAG is an HLA imputation tool that uses attribute bootstrap aggregation of several classifiers (SNPs) to select groups of SNPs that predict HLA type and allows for the use of own HLA reference panels30. Reference HLA types were used from published imputation models and for individuals of primary Asian and African descent obtained with Sirona sequencing57 in ethnic-specific populations (N = 500 individuals of African descent, N = 2000 individuals of European descent and N = 368 individuals of Asian descent). Imputation accuracy was further verified by Luminex HLA typing in a subset of samples and accuracy was over 95% for all ethnic groups and common alleles with >5% frequency in population. For all alleles, the accuracies for individuals of European descent were 98% for HLA-A, 97% for HLA-B, 98% for HLA-C, 96% for HLA-DRB1, 100% for HLA-DQA1, 100% for HLA-DQB1, 100% for HLA-DPA1 and 92% for HLA-DPB1. The accuracies for individuals of Asian descent, where allele typing was also available, were 95% for HLA-DRB1, 94% for HLA-DQA1 and 98% for HLA-DQB1.
Analysis of HLA variants
HLA effects in NT1 were analyzed as described before6 in 23,410 individuals, including 9789 individuals of primary Asian descent and 13,621 individuals of primary European descent as ancestry-matched cases and controls. Within each ancestry group, HLA alleles were analyzed using additive models and logistic regressions after adjusting for the first 10 population-specific principal components. We identify independent associations using conditional analysis (stepwise forward regression in each cohort). Fixed-effects meta-analysis was used to combine associations using Plink 1.958 and R version 3.2.2. We considered alleles sustaining Bonferroni correction for correction of number of alleles with minor allele frequency over 2% (N = 110 HLA alleles), thus significance resulting in Bonferroni cut-off P = 0.00045.
Analysis of expression quantitative trait loci (eQTL)
We used tissue-specific summary statistics from the GTEx consortium and from59 to examine total blood-specific effects of associating variants on gene expression59,60. We used Garfield to compute enrichments using enhancer annotation data from ENCODE provided by the Garfield software61 and stratified LD score regression to compute tissue-specific enrichment using ENCODE data as provided by the LCSC package34.
Expression assessment in monocyte-derived dendritic cells
We examined how the genetic variants modulated T cell and antigen-presenting (dendritic cell and monocyte) gene expression by RNA sequencing and RNA expression. To examine environment-specific triggers for eQTLs, we challenged dendritic cells with an influenza-A infection or stimulated them with interferon. We recruited individuals free from earlier inflammatory disease, autoimmune disease, chronic metabolic disorders or chronic infectious disorders between 18 and 56 years of age (average 29.9), extracted blood mononuclear cells and differentiated into mononuclear dendritic cells, as previously described62. We then extracted RNA from the samples using the RNeasy 96 kit (Qiagen, CAT#74182), according to the manufacturer’s protocols and sequenced the samples under baseline, influenza infected and interferon beta 1 (IFNB1) stimulation (99 baseline, 250 influenza infected, and 227 IFNB1 stimulated). Five hundred fifty-two pass-filter samples (94 baseline, 243 influenza, and 215 interferon) were sequenced to an average depth of 38 million 76-bp paired-end reads using the Illumina TruSeq kit. We aligned reads to hg19 genome with TopHat, assembled transcriptomes for each sample using StringTie63 and computed transcript quantities using Kallisto64. We merged transcriptomes across the same condition and then across all three conditions and removed redundant isoforms using cuffcompare65. We performed QTL mapping using the Matrix eQTL66 package using an empirically determined number of principal components (PCs) as covariates in each analysis. We tested 0 to 44 PCs (local eQTLs) in increments of two and the number of PCs was chosen to maximize the number of local eQTLs detected. We computed empirical P-values by comparing the nominal P-values with null P-values determined by permuting each gene 1000 times. False-discovery rates were calculated using the qvalue package (https://github.com/StoreyLab/qvalue), as previously described67.
T-cell receptor eQTL analysis
For this analysis, we used data from 895 individuals that were originally genotyped and sequenced as part of the Depression Genes and Networks Project reported by68, identifying short range (cis) SNPs and trans HLA alleles association with TCR V and J usage as described before35. Briefly, expression/usage of each T-cell receptor alpha and beta V- and J-gene was calculated relative to total chain expression from peripheral blood RNA-sequencing. We mapped sequencing reads as in Battle et al. (Bowtie254 with Tophat55 default parameters) and counted the number of unique reads that mapped to each V/J/C-TCR/Ig gene with a modified version of HTSeq56, which allows reads to map to a sequence of more than one V/D/J/C-gene. We then removed individuals and genes with low read counts, normalized the reads using log transformation and regressed on technical and biological covariates as described in Battle et al. as well. Finally, we quantile-normalized the residuals to a normal distribution. Pearson correlations were used to test associations between genotypes and V- or J-gene expression.
Targeted TCR sequencing in NT1 cases and DQ0602-positive controls
In addition to using the data from Battle et al., (2014) we also conducted TCR sequencing in T cells in 60 individuals with NT1 and 60 healthy DQ0602 individuals using RNA from total CD4+ T cells, CD4+ T memory and CD8+ T-cell populations. We used fastqc to infer quality and trimmed low-quality reads. We then performed barcode demultiplexing, after which local blast was used to align and extract CDR3s. Linear regression was fit for TRA usage per genotype dosage adjusting for age and gender, RNA-sequencing lane and case/control status as covariates. We also separately analyzed coding consequences for each TRAJ24 containing productive CDR3 fragment, as one of the most significantly associated SNPs was a coding SNP (rs1483979) changing an amino acid Leucine to Phenylalanine. These “LQF” and “FQF” were extracted, and their frequencies were computed. Ratio of FQF/(LQF + FQF) was further computed across all samples.
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
The sumstats generated in this study have been deposited in the Dryad database under https://doi.org/10.5061/dryad.kd51c5b9b.
Hublin, C., Partinen, M., Kaprio, J., Koskenvuo, M. & Guilleminault, C. Epidemiology of narcolepsy. Sleep 17, S7–S12 (1994).
Ohayon, M. M., Priest, R. G., Zulley, J., Smirne, S. & Paiva, T. Prevalence of narcolepsy symptomatology and diagnosis in the European general population. Neurology 58, 1826–1833 (2002).
Silber, M. H., Krahn, L. E., Olson, E. J. & Pankratz, V. S. The epidemiology of narcolepsy in Olmsted County, Minnesota: a population-based study. Sleep 25, 197–202 (2002).
Peyron, C. et al. A mutation in a case of early onset narcolepsy and a generalized absence of hypocretin peptides in human narcoleptic brains. Nat. Med. 6, 991–997 (2000).
Mignot, E. et al. Complex HLA-DR and -DQ interactions confer risk of narcolepsy-cataplexy in three ethnic groups. Am. J. Hum. Genet. 68, 686–699 (2001).
Ollila, H. M. et al. HLA-DPB1 and HLA class I confer risk of and protection from narcolepsy. Am. J. Hum. Genet. 96, 136–146 (2015).
Faraco, J. et al. ImmunoChip study implicates antigen presentation to T cells in narcolepsy. PLOS Genet. 9, e1003270 (2013).
Hallmayer, J. et al. Narcolepsy is strongly associated with the T-cell receptor alpha locus. Nat. Genet. 41, 708–711 (2009).
Han, F. et al. Genome wide analysis of narcolepsy in China implicates novel immune loci and reveals changes in association prior to versus after the 2009 H1N1 influenza pandemic. PLoS Genet. 9, e1003880 (2013).
Kornum, B. R. et al. Common variants in P2RY11 are associated with narcolepsy. Nat. Genet 43, 66–71 (2011).
Cogswell, A. C. et al. Children with Narcolepsy type 1 have increased T-cell responses to orexins. Ann. Clin. Transl. Neurol. 6, 2566–2572 (2019).
Jiang, W. et al. In vivo clonal expansion and phenotypes of hypocretin-specific CD4(+) T cells in narcolepsy patients and controls. Nat. Commun. 10, 5247 (2019).
Latorre, D. et al. T cells in patients with narcolepsy target self-antigens of hypocretin neurons. Nature 562, 63–68 (2018).
Luo, G. et al. Autoimmunity to hypocretin and molecular mimicry to flu in type 1 narcolepsy. Proc. Natl Acad. Sci. USA 115, E12323–E12332 (2018).
Pedersen, N. W. et al. CD8(+) T cells from patients with narcolepsy and healthy controls recognize hypocretin neuron-specific antigens. Nat. Commun. 10, 837 (2019).
Han, F. et al. Narcolepsy onset is seasonal and increased following the 2009 H1N1 pandemic in China. Ann. Neurol. 70, 410–417 (2011).
Weibel, D. et al. Narcolepsy and adjuvanted pandemic influenza A (H1N1) 2009 vaccines—Multi-country assessment. Vaccine 36, 6202–6211 (2018).
Ambati, A. et al. Increased beta-haemolytic group A streptococcal M6 serotype and streptodornase B-specific cellular immune responses in Swedish narcolepsy cases. J. Intern. Med. 278, 264–276 (2015).
Aran, A. et al. Elevated anti-streptococcal antibodies in patients with recent narcolepsy onset. Sleep 32, 979–983 (2009).
Edwards, K. et al. Meeting report narcolepsy and pandemic influenza vaccination: What we know and what we need to know before the next pandemic? A report from the 2nd IABS meeting. Biologicals 60, 1–7 (2019).
Partinen, M. et al. Increased incidence and clinical picture of childhood narcolepsy following the 2009 H1N1 pandemic vaccination campaign in Finland. PLoS ONE 7, e33723 (2012).
Yang, J., Lee, S. H., Goddard, M. E. & Visscher, P. M. GCTA: a tool for genome-wide complex trait analysis. Am. J. Hum. Genet. 88, 76–82 (2011).
Mignot, E. Genetic and familial aspects of narcolepsy. Neurology 50, S16–S22 (1998).
Feketeova, E. et al. Narcolepsy in Slovakia—epidemiology, clinical and polysomnographic features, comorbid diagnoses: a case-control study. Sleep. Med. 67, 15–22 (2020).
Martinez-Orozco, F. J., Vicario, J. L., De Andres, C., Fernandez-Arquero, M. & Peraita-Adrados, R. Comorbidity of narcolepsy type 1 with autoimmune diseases and other immunopathological disorders: a case-control study. J. Clin. Med. Res. 8, 495–505 (2016).
Barateau, L. et al. Comorbidity between central disorders of hypersomnolence and immune-based disorders. Neurology 88, 93–100 (2017).
Chen, T. Y. et al. The association between asthma and narcolepsy: a nationwide case-control study in Taiwan. Nat. Sci. Sleep. 13, 1631–1640 (2021).
Simmons, K. M. et al. Failed genetic protection: type 1 diabetes in the presence of HLA-DQB1*06:02. Diabetes 69, 1763–1769 (2020).
Darlay, R. et al. Amino acid residues in five separate HLA genes can explain most of the known associations between the MHC and primary biliary cholangitis. PLoS Genet. 14, e1007833 (2018).
Zheng, X. et al. HIBAG–HLA genotype imputation with attribute bagging. Pharmacogenomics J. 14, 192–200 (2014).
Dilthey, A. et al. Multi-population classical HLA type imputation. PLoS Comput. Biol. 9, e1002877 (2013).
Hor, H. et al. Genome-wide association study identifies new HLA class II haplotypes strongly protective against narcolepsy. Nat. Genet. 42, 786–789 (2010).
Ollila, H. M., Fernandez-Vina, M. & Mignot, E. HLA-DQ allele competition in narcolepsy: a comment on Tafti et al. DQB1 locus alone explains most of the risk and protection in narcolepsy with cataplexy in Europe. Sleep 38, 147–151 (2015).
Finucane, H. K. et al. Partitioning heritability by functional annotation using genome-wide association summary statistics. Nat. Genet. 47, 1228–1235 (2015).
Sharon, E. et al. Genetic variation in MHC proteins is associated with T cell receptor expression biases. Nat. Genet. 48, 995–1002 (2016).
Kornum, B. R. Narcolepsy Type I as an autoimmune disorder. Handb. Clin. Neurol. 181, 161–172 (2021).
Hu, X. et al. Additive and interaction effects at three amino acid positions in HLA-DQ and HLA-DR molecules drive type 1 diabetes risk. Nat. Genet. 47, 898–905 (2015).
Miyadera, H. & Tokunaga, K. Associations of human leukocyte antigens with autoimmune diseases: challenges in identifying the mechanism. J. Hum. Genet. 60, 697–702 (2015).
Tsutsumi, C. et al. Class II HLA genotype in fulminant type 1 diabetes: A nationwide survey with reference to glutamic acid decarboxylase antibodies. J. Diabetes Investig. 3, 62–69 (2012).
Perisic Nanut, M., Sabotic, J., Jewett, A. & Kos, J. Cysteine cathepsins as regulators of the cytotoxicity of NK and T cells. Front. Immunol. 5, 616 (2014).
Bernard-Valnet, R. CD8 T cell-mediated killing of orexinergic neurons induces a narcolepsy-like phenotype in mice. Proc. Natl Acad. SCi. USA 113, 10956–10961 (2016).
Dauvilliers, Y. et al. Hypothalamic immunopathology in anti-Ma-associated diencephalitis with narcolepsy-cataplexy. JAMA Neurol. 70, 1305–1310 (2013).
Wallenius, M. et al. Autoantibodies in Pandemrix(®)-induced narcolepsy: Nine candidate autoantigens fail the conformational autoantibody test. Autoimmunity 52, 185–191 (2019).
Bomfim, I. L. et al. The immunogenetics of narcolepsy associated with A(H1N1)pdm09 vaccination (Pandemrix) supports a potent gene-environment interaction. Genes Immun. 18, 75–81 (2017).
Heier, M. S. et al. Incidence of narcolepsy in Norwegian children and adolescents after vaccination against H1N1 influenza A. Sleep. Med. 14, 867–871 (2013).
O’Flanagan, D. et al. Investigation of an association between onset of narcolepsy and vaccination with pandemic influenza vaccine, Ireland April 2009-December 2010. Eur. Surveill. 19, 15–25 (2014).
Ollila, H. M. et al. Genetics of vaccination-related narcolepsy. https://doi.org/10.1101/169623 (2017).
Nicolazzi, E. L., Iamartino, D. & Williams, J. L. AffyPipe: an open-source pipeline for Affymetrix Axiom genotyping workflow. Bioinformatics 30, 3118–3119 (2014).
Howie, B., Marchini, J. & Stephens, M. Genotype imputation with thousands of genomes. G3 (Bethesda) 1, 457–470 (2011).
Howie, B., Fuchsberger, C., Stephens, M., Marchini, J. & Abecasis, G. R. Fast and accurate genotype imputation in genome-wide association studies through pre-phasing. Nat. Genet. 44, 955–959 (2012).
Wellcome Trust Case Control C. Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature 447, 661–678 (2007).
Liu, J. Z. et al. Meta-analysis and imputation refines the association of 15q25 with smoking quantity. Nat. Genet. 42, 436–440 (2010).
Lee, S. H., Wray, N. R., Goddard, M. E. & Visscher, P. M. Estimating missing heritability for disease from genome-wide association studies. Am. J. Hum. Genet. 88, 294–305 (2011).
Plagnol, V., Smyth, D. J., Todd, J. A. & Clayton, D. G. Statistical independence of the colocalized association signals for type 1 diabetes and RPS26 gene expression on chromosome 12q13. Biostatistics 10, 327–334 (2009).
Watanabe, K., Taskesen, E., van Bochoven, A. & Posthuma, D. Functional mapping and annotation of genetic associations with FUMA. Nat. Commun. 8, 1826 (2017).
Choi, S. W. & O’Reilly, P. F. PRSice-2: Polygenic Risk Score software for biobank-scale data. Gigascience 8, giz082 (2019).
Wang, C. et al. High-throughput, high-fidelity HLA genotyping with deep sequencing. Proc. Natl Acad. Sci. USA 109, 8676–8681 (2012).
Chang, C. C. et al. Second-generation PLINK: rising to the challenge of larger and richer datasets. Gigascience 4, 7 (2015).
Westra, H. J. et al. Cell specific eQTL analysis without sorting cells. PLoS Genet. 11, e1005223 (2015).
Consortium, G. T. Human genomics. The genotype-tissue expression (GTEx) pilot analysis: multitissue gene regulation in humans. Science 348, 648–660 (2015).
Iotchkova, V. et al. GARFIELD classifies disease-relevant genomic features through integration of functional annotations with association signals. Nat. Genet. 51, 343–353 (2019).
Ye, C. J. et al. Genetic analysis of isoform usage in the human anti-viral response reveals influenza-specific regulation of ERAP2 transcripts under balancing selection. Genome Res. 28, 1812–1825 (2018).
Pertea, M. et al. StringTie enables improved reconstruction of a transcriptome from RNA-seq reads. Nat. Biotechnol. 33, 290–295 (2015).
Bray, N. L., Pimentel, H., Melsted, P. & Pachter, L. Near-optimal probabilistic RNA-seq quantification. Nat. Biotechnol. 34, 525–527 (2016).
Steijger, T. et al. Assessment of transcript reconstruction methods for RNA-seq. Nat. Methods 10, 1177–1184 (2013).
Shabalin, A. A. Matrix eQTL: ultra fast eQTL analysis via large matrix operations. Bioinformatics 28, 1353–1358 (2012).
Storey, J. D. & Tibshirani, R. Statistical significance for genomewide studies. Proc. Natl Acad. Sci. USA 100, 9440–9445 (2003).
Battle, A. et al. Characterizing the genetic basis of transcriptome diversity through RNA-sequencing of 922 individuals. Genome Res. 24, 14–24 (2014).
This study was primarily supported by grants from wake-up narcolepsy, Jazz Pharmaceuticals, donations from narcoleptic patients and, peripherally, by a previously funded NIH-23724 grant (EM). We thank GlaxoSmithKline (GSK) for a collaboration providing funds to examine effect of seasonal influenza vaccination and T-cell receptor sequencing in narcolepsy. Work was also supported by Academy of Finland (#309643), Sigrid Juselius Foundation, Finnish Cultural Foundation, Orion Farmos Research Foundation, Instrumentarium Science Foundation, Oskar Öfflund Foundation, Yrjö Jahnsson Foundation and Jalmari and Rauha Ahokas Foundation (HMO). This work was also supported by the United States Department of Defense (DoD) through the National Defense Science & Engineering Graduate Fellowship (NDSEG) program and by Stanford University through the Stanford Graduate Fellowship program. The work has been supported by the National Institute of Mental Health Grant 5RC2MH089916 for the Depression Genes and Networks Project. The Swedish post-pandemrix Narcolepsy genetics, with Tomas Olsson and Ingrid Kockum as PIs, received support from the Swedish medical product agency. Han Fang was supported by the Ministry of Science and Technology (2015CB856405) and NSFC (81420108002,81670087). Selina Yogeshwar received funding from the Einstein Center for Neurosciences and the German-Academic Exchange Service (DAAD). TCR sequencing eQTL data used sample genotype and sequence as part of the depression gene and networks project; NIMH 5RC2MH089916. We want to thank Dr. Mehdi Tafti for identifying overlapping samples from EU-NN and those genotyped at Stanford University. Some of the computing for this project was performed on the Sherlock cluster. We would like to thank Stanford University and the Stanford Research Computing Center for providing computational resources and support that contributed to these research results. We want to acknowledge the participants and investigators of FinnGen study. The FinnGen project is funded by two grants from Business Finland (HUS 4685/31/2016 and UH 4386/31/2016) and the following industry partners: AbbVie Inc., AstraZeneca UK Ltd, Biogen MA Inc., Bristol Myers Squibb (and Celgene Corporation & Celgene International II Sàrl), Genentech Inc., Merck Sharp & Dohme Corp, Pfizer Inc., GlaxoSmithKline Intellectual Property Development Ltd., Sanofi US Services Inc., Maze Therapeutics Inc., Janssen Biotech Inc, Novartis AG, and Boehringer Ingelheim. Following biobanks are acknowledged for delivering biobank samples to FinnGen: Auria Biobank (www.auria.fi/biopankki), THL Biobank (www.thl.fi/biobank), Helsinki Biobank (www.helsinginbiopankki.fi), Biobank Borealis of Northern Finland (https://www.ppshp.fi/Tutkimus-ja-opetus/Biopankki/Pages/Biobank-Borealis-briefly-in-English.aspx), Finnish Clinical Biobank Tampere (www.tays.fi/en-US/Research_and_development/Finnish_Clinical_Biobank_Tampere), Biobank of Eastern Finland (www.ita-suomenbiopankki.fi/en), Central Finland Biobank (www.ksshp.fi/fi-FI/Potilaalle/Biopankki), Finnish Red Cross Blood Service Biobank (www.veripalvelu.fi/verenluovutus/biopankkitoiminta) and Terveystalo Biobank (www.terveystalo.com/fi/Yritystietoa/Terveystalo-Biopankki/Biopankki/). All Finnish Biobanks are members of BBMRI.fi infrastructure (www.bbmri.fi). Finnish Biobank Cooperative-FINBB (https://finbb.fi/) is the coordinator of BBMRI-ERIC operations in Finland. The Finnish biobank data can be accessed through the Fingenious® services (https://site.fingenious.fi/en/) managed by FINBB.
The authors declare no competing interests.
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Ollila, H.M., Sharon, E., Lin, L. et al. Narcolepsy risk loci outline role of T cell autoimmunity and infectious triggers in narcolepsy. Nat Commun 14, 2709 (2023). https://doi.org/10.1038/s41467-023-36120-z
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