ARTICLE

Received 21 Oct 2014 | Accepted 16 Nov 2015 | Published 2 Feb 2016

Chia-Ti Tsai1,2,3, Chia-Shan Hsieh4,5, Sheng-Nan Chang2,3, Eric Y. Chuang4,5, Kwo-Chang Ueng6,7,Chin-Feng Tsai6,7, Tsung-Hsien Lin8, Cho-Kai Wu1, Jen-Kuang Lee1, Lian-Yu Lin1, Yi-Chih Wang1, Chih-Chieh Yu1, Ling-Ping Lai1, Chuen-Den Tseng1, Juey-Jen Hwang1, Fu-Tien Chiang1,9 & Jiunn-Lee Lin1

Atrial brillation (AF) is the most common sustained cardiac arrhythmia. Previous genome-wide association studies had identied single-nucleotide polymorphisms in several genomic regions to be associated with AF. In human genome, copy number variations (CNVs) are known to contribute to disease susceptibility. Using a genome-wide multistage approach to identify AF susceptibility CNVs, we here show a common 4,470-bp diallelic CNV in the rst intron of potassium interacting channel 1 gene (KCNIP1) is strongly associated with AF in Taiwanese populations (odds ratio 2.27 for insertion allele; P 6.23 10 24). KCNIP1

insertion is associated with higher KCNIP1 mRNA expression. KCNIP1-encoded protein potassium interacting channel 1 (KCHIP1) is physically associated with potassium Kv channels and modulates atrial transient outward current in cardiac myocytes. Overexpression of KCNIP1 results in inducible AF in zebrash. In conclusions, a common CNV in KCNIP1 gene is a genetic predictor of AF risk possibly pointing to a functional pathway.

1 Division of Cardiology, Department of Internal Medicine, National Taiwan University College of Medicine and Hospital, No. 7, Chung-Shan South Road, Taipei 100, Taiwan. 2 Graduate Institute of Clinical Medicine, College of Medicine, National Taiwan University, No. 7, Chung-Shan South Road, Taipei 100, Taiwan.

3 Department of Internal Medicine, National Taiwan University Hospital Yun-Lin Branch, No. 579, Sec. 2, Yunlin Road, Douliou City, Yunlin County 640, Taiwan.

4 Department of Life Science, Genome and Systems Biology Degree Program, National Taiwan University, No. 1, Sec. 4, Rutherford Road, Taipei 10617, Taiwan.

5 Bioinformatics and Biostatistics Core, Center of Genomic Medicine, National Taiwan University, No. 2, Syu-jhou Road, Taipei 10055, Taiwan. 6 School of Medicine, Chung Shan Medical University, No. 110, Sec. 1, Jianguo North Road, Taichung City 40201, Taiwan. 7 Department of Medicine, Chung Shan Medical University Hospital, No. 110, Sec. 1, Jianguo North Road, Taichung City 40201, Taiwan. 8 Division of Cardiology, Department of Internal Medicine, Kaohsiung Medical University and Chung-Ho Memorial Hospital, No. 100, Shi-Chuan 1st Road, Kaohsiung City 807, Taiwan. 9 Department of Laboratory Medicine, National Taiwan University College of Medicine and Hospital, No. 7, Chung-Shan South Road, Taipei 100, Taiwan. Correspondence and requests for materials should be addressed to J.-J.H. (email: mailto:[email protected]

Web End [email protected] ) or to F.-T.C. (email: mailto:[email protected]

Web End [email protected] ) or to J.-L.L. (email: mailto:[email protected]

Web End [email protected] ).

NATURE COMMUNICATIONS | 7:10190 | DOI: 10.1038/ncomms10190 | http://www.nature.com/naturecommunications

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DOI: 10.1038/ncomms10190 OPEN

Genome-wide screening identies a KCNIP1 copy number variant as a genetic predictor for atrial brillation

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms10190

Atrial brillation (AF) is the most common sustained arrhythmia and a major risk factor for stroke, heart failure and cardiovascular death. In the past decade, genome-

wide association studies (GWASs) have identied single-nucleotide polymorphisms (SNPs) in several genomic regions associated with AF, for example, on chromosomes 4q25 (PITX2), 16q22 (ZFHX3) and 1q21 (KCNN3)13. However, these loci do not fully explain the genetic risk for AF, suggesting that additional genetic factors or variants remain to be discovered. In the human genome, copy number variation (CNV) is a variation in the DNA sequence and can affect the expression and function of nearby and distal genes4, causing phenotypic differences. It has been demonstrated that signals from SNPs and CNVs have little overlap4. Therefore, examining the genome for both SNP and CNV variants might be an effective means of determining the genetic causes of complex phenotypes and diseases in humans.

CNV regions have been estimated to cover 5% of the human genome5. Inherited CNVs underlie Mendelian diseases, and some copy number (CN) variable genes are associated with rare human diseases, such as schizophrenia and autism6,7. Although some studies have shown that CNVs may also contribute to the susceptibility to common diseases8, their inuence on phenotypic variability and disease susceptibility still remained poorly understood.

Whether CNVs may also contribute to the risk of AF has never been investigated before. Herein, we sought to explore this issue using a genome-wide approach and a three-stage study design with the attempt to minimize false positive ndings yet maximize power and efciency by examining samples with gradually increased phenotypic severity but with increasing sample size9. A similar approach had been used to efciently identify the genetic susceptibility loci associated with electrocardiographic QT interval by GWAS9.

In addition, so far there have been many genetic studies adopting different genome-wide technologies to identify causal variants or susceptibility genes for common diseases, for example, GWAS1,10 or whole exome sequencing11. However, few of the identied variants or loci have been linked to disease mechanisms with translational functional studies2,12. Hence, in the present study, we identify a common diallelic insertion/deletion CNV in the Kv channel interacting protein 1 gene (KCNIP1) as a strong predictor of AF susceptibility and, using the zebrash and cellular models, we also provide the possible functional mechanism to explain the genetic association. KCNIP1-encoded protein potassium channel interacting protein 1 (KCHIP1) may modulate atrial electrophysiology at high atrial rates.

ResultsGeneral CNV pattern and association with the risk of AF. Genome-wide detection of CNV was performed in the stage I discovery subjects, using the Illumina HumanOmni1-Quad BeadChip (1,014,075 SNPs) to obtain signal and allelic intensities and to generate CNV calls. After quality control ltering (removal of markers or subjects with call rateo99%), there was a total of 7,210 CNV calls. The CNV calls spanned between 1 and 2,288 SNP markers, with an average of 43 SNPs per CNV region and an average CNV region size of 119 kb.

Although the small stage I sample size, we still identied several CNV regions that were associated with AF (Table 1), probably because of the signicant phenotype contrast between cases (extreme phenotypes) and controls. All of the signicant CNVs were small CNVs (o500 kb) and, thus, there was no enrichment of large CNVs among the cases relative to controls as observed in Mendelian diseases. Because of the smaller case number in the stage I GWAS sample (because of very low

prevalence of extreme AF cases), false positive results were expected by chance, and further follow-up was critical.

We then replicated the signicant CNVs from the stage I discovery sample in the stage II replication sample with another 105 patients with symptomatic AF and 422 normal sinus rhythm (NSR) healthy controls. Interestingly, we found that the CNV region in an ionic channel/subunit gene, the Kv channel interacting protein 1 gene (KCNIP1), remained signicant in the stage II sample. We found a short (B4,470 bp) common insertion/deletion diallelic CN polymorphism in the rst intron of human KCNIP1 gene that was associated with the susceptibility to AF. The insertion allele of the diallelic CNV was associated with an increased risk of AF, and the deletion allele was protective from AF (harbouring insertion allele was associated with AF, P 1.8 10 5). This diallelic CNV has also been published

recently to be associated with the risk of type 2 diabetes13. Furthermore, it has also been published in the Database of Genomic Variants (http://projects.tcag.ca/variation

Web End =http://projects.tcag.ca/variation) and the 1,000 Genomes (http://www.1000genomes.org

Web End =http://www.1000genomes.org)(Supplementary Fig. 1).

CNVs may be linked to their neighbouring SNPs. We showed the regional plot around this KCNIP1 CNV region (Chr5:169,800,000170,300,000) (Supplementary Fig. 2). In this region, only rs11742875, which is B100 kb far from the CNV, was associated with AF based on the preset stage I threshold of 0.001 (P 1.05 10 4). However, the density of SNP in the

chip is sparse, and there may be other better SNP markers around the CNV14. Based on the 1000 Genomes data, this CNV (MERGED_DEL_2_33224) is in very strong linkage disequilibrium (r240.95) with three SNPs (rs1541665, rs2032863 and rs1363713). SNP rs1541665 was among the SNP list of our Illumina HumanOmni1-Quad BeadChip (Supplementary Fig. 2), but not rs2032863 and rs1363713. However, the r2 between rs1541665 and the CNV was not high(0.48) in our Taiwanese population, and therefore rs1541665 was not signicantly associated with AF trait (P 0.093)

(Supplementary Fig. 2). We also genotyped rs2032863 and rs1363713. SNP rs2032863 was in complete linkage disequilibrium with rs1363713 and therefore provided no additional information. The r2 between rs1363713 and the CNV was modestly high (0.78) in our Taiwanese population, but not as strong as found in other populations (40.95).

Therefore, the pattern of linkage disequilibrium between genetic marks may be variable in different ethnic populations15. Nevertheless, the association of rs1363713 with AF trait was highly signicant (P 3.34 10 5), but not as signicant as the

CNV. In conclusions, this CNV might be only partially tagged by surrounding SNPs, and therefore, genotyping of this common CNV was still necessary for the large-scale stage III association study.

Accordingly, we further validated the association of this common CNV with AF in the large stage III population. The distribution of KCNIP1 insertion/deletion genotypes was also in HardyWeinberg equilibrium in the stage III sample (Table 2). Similarly, the insertion allele was associated with an increased risk of AF (insertion allele frequency 0.36 versus 0.23, P 5.38 10 23). The association became even more signicant

because of the large case number. Harbouring at least one insertion allele was associated with a signicantly higher risk of AF (odds ratio 2.12, 95% condence interval 1.542.94, P 4.19 10 22).

Validation in different geographic areas. In stage III, we also genotyped this common insertion/deletion polymorphism in 821 subjects (275 AF cases and 546 NSR controls) in different geographic areas (Middle and Southern Taiwan). Power

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Table 1 | Signicant CNV regions in the stage I discovery sample.

Cytoband Start position (bp) Type Allele frequency Avg. CN Length (bps) Gene DGV P-value 1q12 141,622,815 Loss 0.21 1.58390 395,766 ANKRD20A12P 3.09E 07

1p36.13 17,546,966 Loss 0.24 1.52439 4,858 PADI4 2.94E 06

1p36.21 13,306,366 Loss 0.23 1.57085 192,072 PRAMEF14 1.73E 06

1p36.21 13,167,437 Loss 0.22 1.56805 130,829 PRAMEF3 1.12E 07

1p36.32 2,573,413 Loss 0.22 1.55573 108,341 TTC34 1.03E 05

2p16.1 56,378,184 Loss 0.23 1.54534 120,493 CCDC85A 5.83E 07

2p22.3 33,077,316 Loss 0.23 1.54556 3,928 LTBP1 1.02E 03

2p25.3 1,506,306 Loss 0.23 1.59170 16,162 TPO 2.61E 07

3q29 199,289,792 Loss 0.25 1.51397 142,634 ANKRD18DP 6.27E 08

5q35.1 170,061,229 Gain 0.29 2.57862 4,470 KCNIP1 1.57E 06

6p21.32 33,140,517 Loss 0.22 1.56019 8,849 HLA-DPA1 1.88E 06

6p21.32 33,133,423 Loss 0.22 1.56438 7,095 HLA-DPA1 1.00E 06

6p21.32 33,158,459 Loss 0.21 1.57858 4,840 HLA-DPB1 7.36E 07

6p22.3 22,156,930 Loss 0.30 1.43742 4,981 LINC00340 3.94E 05

7q34 142,107,052 Loss 0.21 1.57438 69,930 PRSS1 1.58E 06

7q34 142,107,052 Loss 0.21 1.57438 69,930 PRSS3P2 1.58E 06

8q24.3 144,785,898 Loss 0.24 1.52527 27,257 ZNF623 3.63E 05

14q32.33 105,491,658 Gain 0.55 3.10113 19,535 ADAM6 5.23E 07

14q32.33 105,807,945 Gain 0.33 2.51647 37,608 LINC00226 3.38E 08

17p13.3 670,214 Loss 0.26 1.47994 2,402 NXN 1.79E 08

21q22.3 46,142,957 Loss 0.30 1.39238 27,264 PCBP3 1.56E 07

21q22.3 43,780,913 Loss 0.23 1.53278 23,647 HSF2BP 2.12E 04

21q22.3 46,171,463 Loss 0.31 1.37456 29,943 PCBP3 2.48E 07

21q22.3 43,728,391 Loss 0.23 1.54411 52,523 HSF2BP 7.05E 04

22q11.22 21,430,797 Gain 0.30 2.44319 139,593 MIR650 9.66E 08

22q11.22 21,430,797 Gain 0.30 2.44319 139,593 IGLL5 9.66E 08

22q11.23 22,694,904 Loss 0.39 1.22954 33,941 GSTT1 3.90E 08

22q11.23 22,629,805 Loss 0.37 1.25476 40,795 GSTT2 6.34E 07

Avg. CN, average copy number; bp, base pair; CNV, copy number variation; DGV, Database of Genomic Variants (http://projects.tcag.ca/variation/

Web End =http://projects.tcag.ca/variation/). Allele frequencies are inferred from the averaged CN based on a diallelic assumption for each variant.

The statistical signicance level was set at Po10 3 in the genome-wide CNV discovery stage; NCBI RefSeq (hg18; build 36) was used to annotate the location and coding region of each CNV region in the genome.

Table 2 | Genotype distributions of the human KCNIP1 gene insertion/deletion polymorphism in the study populations.

Genotype AF (N 105) NSR (N 422) P-value*

Genotype distribution in the stage II populationD/Dw 41 261 0.289/0.527 D/I, I/Iw 64 161 2.47 10 6

Genotype AF (N 1,022) NSR (N 2,025) P-value*

Genotype distribution in the stage III populationD/D 426 1,217 0.514/0.867 D/I, I/I 596 808 5.38 10 23

Genotype AF (N 275) NSR (N 546) P-value*

Genotype distribution in subjects from different geographic areasD/D 104 322 0.357/0.234 D/I, I/I 171 224 1.23 10 9

AF, atrial brillation; D, deletion allele (B4,470 bp) in the rst intron of the human KCNIP1 gene; I, insertion allele; NSR, normal sinus rhythm; SNP, single-nucleotide polymorphism.

The insertion (or gain) and deletion denote presence (insertion) and absence (deletion) of the same B4 kb chromosomal segment in the intron 1 of the KCNIP1 gene, respectively. This is a diallelic variant (same as an SNP). In the Taiwanese population, the deletion allele frequency is more than 0.5, and therefore the variant allele or minor allele is the insertion allele (gain in Table 1).*P values for HardyWeinberg equilibrium in AF (left-sided value in the top row) and NSR (right-sided value in the top row) populations, and comparison of genotype distribution between AF and NSR populations (bottom row).

wD/D, homozygous deletion or copy number 0; D/I, heterozygous deletion or insertion or copy

number 1; I/I, homozygous insertion or copy number 2.

estimation revealed that we had 495% power to replicate the association for an odds ratio of 2.0 at an alpha level of 0.05. The distribution of KCNIP1 insertion/deletion genotypes was also

in HardyWeinberg equilibrium (Table 2). Again, we observed a signicantly association between insertion allele and AF (autosomal dominant odds ratio 2.38, 95% condence interval1.753.23, P 1.08 10 8). Given this strong genetic association

between KCNIP1 gene and AF, we tried to investigate the possible underlying functional mechanism.

Expression of KCNIP1 in the mammalian atrium. KCNIP genes encode the potassium channel interacting proteins (KCHIPs). KCHIPs are small cytosolic, calcium-binding proteins that were initially identied as subunits for the voltage-gated A-type potassium current in neuronal tissue and the transient outward potassium current in cardiac tissue16. The pore-forming protein complex governing these potassium currents is the Kv4 protein. KCHIPs modulate the kinetics and current amplitudes of these Kv4 currents16. Four KCNIP genes have been identied in humans and mice, encoding KCHIP1-4 (refs 16,17). KCHIP1 is mainly expressed in neuronal tissues18, whereas KCHIP2 is mainly expressed in cardiac tissues16,17. However, whether KCHIP1 is expressed in the human atrium has never been investigated before.

We then tried to investigate the expression patterns of the four KCNIP mRNAs in the mammalian heart. We found that KCNIP1-3 are expressed in all the four chambers of the heart (Fig. 1). Interestingly, we observed that the CNV pattern in the rst intron of the KCNIP1 gene signicantly affected the expression level of KCNIP1 mRNA (Fig. 2). Homozygous insertion was associated with a signicantly higher KCNIP1 mRNA level. This result indicates that a higher KCNIP1 expression or higher KCHIP1 level/function may be associated with the mechanism of AF and increased susceptibility to AF. In the next step, we tried to address this possibility in animal studies.

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Figure 1 | Basal expressions of KCNIPs in the mammalian heart. Total RNA was isolated and PCR with reverse transcription (RT-PCR) products with primer pairs specic to rat KCNIPs were visualized by electrophoresis. (a) The RT-PCR results of a positive control for KCNIP1-4 (K1-4) from a representative sample of rat brain. (b) The RT-PCR results of representative left atrium (LA), right atrium (RA), left ventricle (LV) and right ventricle (RV). KCNIP1-3 mRNAs could be detected in the mammalian LA, RA, LV and RV. GP, glyceraldehyde 3-phosphate dehydrogenase; M, molecular weight maker. Data are representative of three independent experiments. Full-length blots are presented in Supplementary Fig. 4.

Figure 2 | Individuals with insertion in intron 1 of KCNIP1 have a higher KCNIP1 mRNA expression. (a) Top panel: The detection of insertion/deletion in intron 1 of human KCNIP1 was performed by PCR amplication of genomic DNA with primers targeting the sequences within the CNV segment in intron 1 of human KCNIP1. No PCR band indicates homozygous deletion (copy number (CN) 0) (patients 14, 9 and 10);

the presence of one PCR band (479 bp) indicates homozygous insertion (CN 2)(patients 58). Middle and lower panels: KCNIP1 and GAPDH

mRNA expressions were semiquantied by PCR with reverse transcription and visualized by electrophoresis. White blood cell mRNA samples from those with KCNIP1 intron homozygous insertion (patients 58) show higher PCR band density, indicating a higher KCNIP1 mRNA level. Arrows indicate the locations of PCR bands. (b) Quantication of KCNIP1 expression (normalized to GAPDH) in patients with CN 0 and those with CN 2.

Data are representative of three independent experiments. Error bars, s.d. MannWhitney U-test; *Po0.05. Full-length blots are presented in

Supplementary Fig. 5.

Effect of KCNIP1 knockdown and overexpression in hearts. Because KCNIP1 is expressed in the atrium, in the next step, we sought to investigate the role of KCHIP1 in the atrium. Recently, zebrash has become a powerful vertebrate genetic model system used to study the mechanism of cardiac arrhythmia because its fundamental electrophysiological properties, such as heart rates, action potential morphology and electrocardiogram morphology, are remarkably similar to those of human19. Therefore, in the present study, instead of mice which have extremely short action potential durations (APDs), we used zebrash to investigate the functional role of KCHIP1 in the mechanism of AF.

APD shortening at high rates is critical to maintain AF and is the major electrophysiological mechanism of AF20. Calcium plays a pivotal role in the mechanism of AF, because calcium overload is common at high rates in AF21. KCHIP1 is a calcium-binding protein and may mediate the interplay between intracellular calcium and modulation of potassium currents, which are the major repolarization currents and are essential to determine APD22. Therefore, it is logical to speculate that KCHIP1 may play an important role in the mechanism of APD shortening during AF. We then sought to evaluate the response of APD shortening at high rates when the KCNIP1 was knocked down or overexpressed, using zebrash as the genetic model system.

There are two homologues of KCNIP1 (KCNIP1a and KCNIP1b) in zebrash. The sequence of KCNIP1a is largely unknown, and KCNIP1b shares much sequence homology with mammalian KCNIP1. In the present study, our zebrash experiment targeted on KCNIP1b (zebrash chromosome 10). We have screened the CN of the zebrash KCNIP1b, and only one gene copy was noted. Whole-mount in situ hybridization

shows that the expression of KCNIP1b is rst detected on the third day post fertilization (Supplementary Fig. 3a). Grossly, KCNIP1b MO or mRNA overexpression did not cause signicant developmental delay in the zebrash (Supplementary Fig. 3b).

Regarding cardiac and electrophysiological phenotypes, the heart rates were comparable between control, KCNIP1 knockdown and overexpression hearts (17815 versus 17120 versus 17519 beats per min for control, knockdown and overexpression hearts, respectively). The baseline atrial action potentials for the three groups are shown in Fig. 3a. There was no signicant change of the atrial APD (20414 versus 2139 versus 19210 ms for control, knockdown and overexpression hearts, respectively) (Fig. 3b).

However, hearts with KCNIP1 knockdown showed less atrial APD shortening at increasing rates and could not sustain high atrial pacing rates as compared with control hearts. On the contrary, hearts with KCNIP1 overexpression showed more atrial APD shortening at increasing rates and could sustain higher atrial pacing rates as compared with control hearts (Fig. 4). Interestingly, one transient atrial tachycardia or AF could be induced in the KCNIP1 overexpression hearts during high-rate pacing (Fig. 4). AF could not be induced in control and KCNIP1 knockdown hearts.

Interaction of KCHIP1 protein with cardiac ionic channels. Previously KCHIP2 had been identied as the cardiac KCHIP assembled in macromolecular structures with the Kv4.2 channel

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to generate and regulate the cardiac transient outward current16,17. Recently it has also been shown that KCHIP2 is also associated with the Cav1.2 channel and modulate the cardiac L-type calcium current23. Whether KCNIP1-encoded protein KCHIP1 also interacts with cardiac ionic channels, such as Kv4.2, Kv4.3 or Cav1.2 in the atrium has never been investigated before.

Using co-immunoprecipitation, we demonstrated that KCHIP1 was also physically associated with the Kv4.2/4.3 proteins (Fig. 5a). However, not like KCHIP2, KCHIP1was not physically associated with the Cav1.2 protein in the atrium (Fig. 5b). These results raise the possibility that KCHIP1 can also modulate atrial transient outward current and thus modulate atrial repolarization properties, as shown in the zebrash experiments. In the next step, we tried to address this issue using cultured atrial myocytes.

Effect of KCHIP1 in atrial myocytes. Kv4.2 and Kv4.3 are the major pore-forming subunits of the cardiac transient outward current13. We sought to investigate the effect of KCHIP1 knockdown or overexpression on the cardiac transient outward current. To address this issue, we used a murine atrial cell line HL-1, which is the only available atrial myocyte cell line that continuously divides, maintains a differentiated atrial phenotype with spontaneous depolarization and has a high transfection efciency for genetic manipulation1820. We found that knockdown of KCNIP1 signicantly impaired the cardiac transient outward current (Fig. 6a,b). We failed to overexpress KCNIP1 because of the low efciency of the expression plasmid (no signicant change of KCHIP1 protein level after overexpression). Nevertheless, this result indicates that the KCNIP1-encoded protein KCHIP1 also modulates atrial potassium currents and, thus, may play a role in modulating atrial repolarization.

DiscussionThis is the rst study to investigate the role of genomic CNV in determining the susceptibility to AF and is also the rst genome-wide CNV study of AF. We identied a common CNV in human KCNIP1 gene that was a strong genetic predictor of AF. We demonstrated that intronic CNV in the human KCNIP1 gene determined the mRNA level of KCNIP1, and KCNIP1-encoded protein KCHIP1 was linked to the mechanism of maintaining

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Figure 3 | Atrial APDs of KCNIP1-knockdown or overexpression hearts are comparable to control hearts. (a) Representative atrial action potentials of KCNIP1-knockdown (KCNIP1 MO), overexpression (KCNIP1 OE) and control (CTL) hearts at a baseline pacing rate of 188 beats per min. Action potentials were recorded by using the microelectrode and disrupted patch method. (b) Quantication of atrial APD at 90% repolarization. The mean APD was comparable between KCNIP1 MO, KCNIP1 OE and the CTL hearts. N 3

experiments for each group. Error bars, s.d. MannWhitney U-test.

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Figure 4 | KCNIP1-knockdown and overexpression modulates APD shortening at high atrial rates. (a) Representative atrial action potential tracings at increasing pacing rates for KCNIP1-knockdown (KCNIP1 MO), overexpression (KCNIP1 OE) and control (CTL) hearts are shown. At pacing cycle length (PCL) 200 ms, the CTL and KCNIP1-overexpression hearts could sustain 1 to 1 pacing rate, but the KCNIP1-knockdown heart could not, and 2 to 1 capture is noted, indicating that the KCNIP1-knockdown heart could not maintain as higher rates as the CTL heart. At even shorter PCL (170 ms), only the KCNIP1-overexpression heart could sustain 1 to 1 high pacing rate, but the KCNIP1-knockdown and CTL hearts could not (2 to 1 capture), indicating that the KCNIP1-overexpression heart could maintain higher rates than the CTL heart. Interestingly, at this high-rate pacing, atrial tachyarrhythmia or AF could be induced in the KCNIP1-overexpression heart. (b) Summary data for three independent experiments demonstrating the relationship of PCL and APD from CTL, KCNIP1-knockdown and overexpression hearts are shown. With increasing rate (decreased PCL), APD shortens accordingly to facilitate maintenance of high rate in all the three groups. However, less APD shortening is observed in the KCNIP1-knockdown hearts. The maximal pacing rate is lower in the KCNIP1-knockdown hearts and higher in the KCNIP1-overexpression hearts, compared to that of the CTL hearts. N 3 experiments for each group. Error

bars, s.d.

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higher atrial rates, and is the possible future target for AF treatment.

KCNIP1-encoded protein KCHIP1 is a KCHIP and also a calcium-binding protein. It was traditionally thought an auxiliary subunit of the protein complex Kv4.3 potassium channel in neurons, and modulates the neural voltage-gated A-type Kv4.3 current18. In the present study, we rst demonstrated the

expression of KCNIP1 in the mammalian atrium. Previously, it has been demonstrated that KCHIP2 is the main cardiac KCHIP (mainly in ventricles), and KCHIP2 is a subunit protein of Kv4.2 and Cav1.2, modulating the ventricular transient outward potassium current and L-type calcium current, respectively23. In the present study, we rst demonstrated that in the mammalian atrium, KCHIP1 formed a protein complex with Kv4.2/4.3 and modulated the atrial transient outward current, thus modulating atrial repolarization properties.

KCHIP1 is a calcium-binding protein. The intracellular calcium level plays a pivotal role in the mechanism of AF24,25. At high atrial rates, the intracellular calcium level is accumulated and elevated due to the short time available for beat-to-beat diastolic calcium reuptake into the sarcoplasmic reticulum, thereby triggering atrial electrical remodelling (for example, APD shortening) and facilitating the maintenance of AF. Our results rst provide the possibility that KCHIP1 mediates the regulation of potassium channel by calcium in the mammalian atrium at high rates. It may be speculated that in response to elevated intracellular calcium at high atrial rates, KCHIP1 augments transient outward potassium current and shortens APD. Accordingly, in the zebrash model, we have shown that genetic overexpression of KCNIP1 resulted in facilitation of APD to shorten at high rates and promotes AF. The results of our human genetic study are also compatible with this nding because most of the AF patients harboured a KCNIP1 intron insertion, which is associated with higher KCNIP1 expression.

The results of the present study also suggest that targeting on KCHIP 1 may be a future therapeutic approach to treat human

a

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Figure 5 | Co-immunoprecipitation shows a biochemical association between KCHIP1 and KV4.2/4.3. (a,b) Tissue samples from adult rat heart were lysed and immunoprecipitated (IP) with anti-KCHIP1. The membranes were then immunoblotted (IB) using anti-KV4.2/4.3 (a) and anti-Cav1.2 (b). Beads conjugated with IgG isotype were used as negative control (NC). There is a biochemical association between KCHIP1 and KV4.2/4.3 (a), but no association between KCHIP1 and Cav1.2 (b). Data are representative of three independent experiments. Full-length blots are presented in Supplementary Fig. 6.

a Before 4-AP

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Figure 6 | Knockdown of KCNIP1 downregulates transient outward currents in atrial myocytes. (a) Transient outward current (Ito) was obtained by a family of depolarization steps from 80 mV, and was measured as the 4-aminopyridine (4-AP)-sensitive peak current (10 mM). (left upper) Voltage protocol. Right panel shows the representative recordings of 4-AP sensitive currents of the control (CTL) and KCNIP1 knockdown (KCNIP1 KD) atrial myocytes, respectively. (left lower) Efciency of knockdown represented by decreased KCHIP1 protein level. (b) Representative current densityvoltage relationships of 4-AP sensitive currents in CTL and KCNIP1 KD atrial myocytes. N 3 experiments for each group. Error bars, s.d. Full-length blots are

presented in Supplementary Fig. 7.

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AF. As mentioned before, we have demonstrated that over-expression of KCNIP1 may predispose to AF, implicating that inhibiting KCNIP1-encoded protein KCHIP1 may prevent AF. Because currently there has been no specic inhibitor of KCHIP1, developing anti-KCNIP1 RNA interference may be an option, and testing of this gene therapy in human clinical trials are warranted in the future to demonstrate the efcacy of inhibiting KCNIP1 expression to treat AF.

Four KCNIP genes have been identied in humans and mice, encoding KCHIP1-4 (refs 16,17). There are also four KCNIP genes identied in zebrash (sources from ZFIN). A well-known phenomenon in the cardiac electrophysiology is the compensatory mechanism to prevent perturbation of the normal electrophysiological function, even when a function of an ionic channel or its regulatory protein is markedly altered26. Therefore, since the four KCHIP paralogous proteins may function similarly to modulate the transient outward potassium current in the heart, it is logical to speculate that overexpression of KCNIP1 may trigger compensatory downregulation of the functions of other paralogous proteins, resulting in minimal change of the transient outward potassium current. Unfortunately, it is difcult to isolate single atrial cardiomyocytes from the small zebrash embryo atrium with KCNIP1 overexpression and measure the transient outward potassium current. Furthermore, we did not have the data of the expression of other paralogues. We could only evaluate gross action potential morphology or measure APD of the intact whole heart, and did nd no signicant change of resting action potential morphology or APD in the heart with KCNIP1 overexpression. However, we found that the change of APD could manifest at extreme conditions which the compensatory mechanism could not keep pace with, such as at very high rate. Therefore, we could only nd phenotypic change of APD by high-rate pacing.

There are several studies using a zebrash model for the genetic studies of AF2730. Mller et al.27 knocked down a candidate gene, GREM2, in zebrash, and the morphants showed abnormal atrial development/differentiation. Overexpression of mutant GREM2 resulted in abnormal atrial rhythm27. Liang et al.28 knocked down candidate genes kcnk3a and kcnk3b, which resulted in lower heart rate and marked increase in atrial diameter. Sinner et al.29 knocked down genome widely identied NEURL and CAND2 genes, and the morphants showed prolonged atrial APD. All these phenotypes are surrogate phenotypes of AF or substrates that may predispose to the development of AF, but not real AF phenotype. The only studies that showed real electrophysiological AF were Rottbauers study30 and our study. Rottbauer et al.30 rst reported a zebrash model with loss of L-type calcium channel function (isl mutant), and spontaneous AF was recorded in ECG. In our study, we induced AF in one KCNIP1 (a GWAS-identied gene) overexpressed zebrash.

There are several limitations in our study. First, although most of the neighbouring SNPs were not better than the CNV in predicting AF risk and CNV genotypes predicted KCNIP1 expression level (probably functional or disease causing), we still could not rule out the possibility that there is another true disease causing variant. We did not nd the exact breaking points of the CNV. An intense effort to map the exact CNV breakpoints and dense ne mapping of SNPs around the breakpoints might well identify better SNP markers or even the disease causing variant. Second, we did not address all the molecular mechanisms experimentally. To address the full molecular mechanisms, how the CNV affects the expression of KCNIP1, the physiological function of KCNIP1-encoded protein KCHIP1 in the atrium and how loss of function or gain of function predisposes to AF in an animal model should be addressed. Although we showed that the CNV affects the expression level of KCNIP1 mRNA, we did not

show the mechanism by which this CNV regulates KCNIP1 expression. The lengths and sequences of intron 1 of the KCNIP1 gene are markedly different between sh and humans, and this 4-kb CNV segment found in humans does not exist in zebrash. To study the specic function of this 4-kb CNV segment, state-ofthe art technique CRISPR or TALEN may be adopted in large mammals that may also have this specic intron segment. We have experimentally shown that KCNIP1-encoded protein KCHIP1 is physically associated to atrial Kv proteins and modulates atrial transient outward current, which plays an important role in atrial electrophysiology. We have also experimentally proved that KCHIP1 mediates facilitation of APD shortening at high rates which may predispose to AF. Therefore, we only addressed part of the molecular mechanism experimentally. Finally, we could not rule out the possibility that KCNIP1 (also expressed in neurons) is linked to AF through a neurogenic mechanism.

In conclusions, the present study is a translational research in which we directly translated the results of genetic and molecular studies into a new idea of AF disease mechanism, which further implicates a therapeutic potential of targeting on KCHIP1 to treat human AF in the future.

Methods

Study population. The study participants were from the National Taiwan University AF Registry (Northern Taiwan). We used a three-stage study design with the attempt to minimize false positive ndings yet maximize power and efciency by examining samples with gradually increased phenotypic severity but with increasing sample size9. In stage I, we selected 50 younger AF patients with extremely severe phenotype, who were diagnosed as having symptomatic persistent AF with very frequent AF attacks (Z one attack per day), and no identiable underlying cardiovascular diseases responsible for the cause of AF (lone AF). Genotyping these patients with disease phenotypes at the extremes is more likely to identify underlying genetic causes although the case number may be small due to the lower prevalence of these patients9. The healthy controls had NSR and had no identiable cardiovascular diseases.

In stage II, we selected another 105 symptomatic persistent lone AF patients with less attack frequency than the stage I patients (Z one AF attack per week), and 422

NSR healthy controls to replicate the signicant CNVs in stage I. In stage III, we replicated the signicant CNVs in both stages I and II in a combined larger population. The signicant CNV was also validated in 275 AF cases and 546 NSR controls from different geographic areas (Middle and Southern Taiwan) in stage III.

The criteria for selection of case and control patients have been reported previously3134. Cases were patients with AF, whereas controls were those with NSR. Patients with AF due to hyperthyroidism were excluded. We also included those with highly suspicious but non-documented AF and those with other atrial arrhythmia for the large stage III population. Informed consent was obtained from participating subjects and the study was approved by the institutional review board of the National Taiwan University Hospital. The clinical data for the whole study participants are provided in Supplementary Table 1. The clinical data for the study participants in the Middle and Southern Taiwan are provided in Supplementary Table 2.

Genome-wide detection of CNV. Using the Illumina HumanOmni1-Quad BeadChip (1,140,419 markers) SNP-based probes and additional CNV intensity probes, genome-wide genotyping was performed to obtain signal and allelic intensities and CNV regions were rst identied through comparing with HapMap controls35,36. To increase the sensitivity of CNV identication, we incorporated multiple factors using PARTEK Genomic Suite 6.6 (PARTEK. Inc., St Louis, USA), a program that is based on the segmentation algorithm. The criteria forthe detected CNV segments were as previously reported criteria35,36:(1) neighbouring regions with signicantly different average intensities, and the signicant level of P value o0.001; (2) breakpoints (region boundaries) that yielded the optimal statistical signicance (smallest P value); and (3) signal-to-noise ratio Z0.3. SNPs with a smoothing value below and above 20.4 were considered loss and gain, respectively. The approximate CNV breakpoints were predicted in silico, and because the density of the SNPs in the Chip is sparse, the breakpoint is dened at the midpoint between two distinct genomic segments. These two genomic segments are also in silico predicted. When the average allelic intensity of two regions are signicant different, they are dened as two distinct regions or two distinct segments and a CNV region is called. Then the breakpoint is dened at the midpoint between the two adjacent boundaries of the two distinct segments. The size of the CNV is dened as the genomic length between the 50 and 30 breakpoints.

We identied a total of 7,210 CNVs. NCBI RefSeq (hg18; build 36) was used to annotate the location and coding region of each CNV region in the genome.

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Verication of CNV regions. Quantitative PCR (qPCR) and semiquantitative conventional PCR with densitometry were performed to verify the CNV and determine the CN of the targeted gene (for example, KCNIP1) in the study samples. qPCR was performed with the TaqMan Copy Number Reference Assay RNase P following the TaqMan qPCR protocol. Each 15-ml reaction mixture comprised 50-ng genomic DNA and 1 TaqMan probe/primer mix in 1 TaqMan Master Mix, amplied on an Applied Biosystems QuanStudio 3D. qPCR data were collected and analysed by the ABI software (Life Technologies Co., CA, USA). Semiquantitative conventional PCR with densitometry were performed for large samples with designed primers targeting the sequences within the postulated deletion segment. There was no PCR product from those samples with zero copy and presence of PCR band from those with more or equal to one copy.

Zebrash experiments. Breeding and maintenance of TL strain zebrash,as well as collecting and staging of embryos, were done according to standard procedures37. Some embryos were reared in egg water treated with 0.003% 1-phenyl-2-thiourea to inhibit pigmentation37. Developmental times refer to days post-fertilization. All embryos were observed and photographed at specic stages under a microscope (MZFLIII, Leica) equipped with Nomarski differential interference contrast optics and a CMOS digital camera (Canon EOS-1DX)37. Zebrash embryos were obtained by natural mating. MO or in vitro synthesized mRNA microinjection was performed at the stage of 14 cells. The KCNIP1b-MO antisense oligonucleotide was designed to direct against the 50 untranslated region (transcription start site) of the KCNIP1b gene (50-TCAATGTGCCCACTACTGC TCCCAT -30). Capped zebrash KCNIP1 mRNA was synthesized with the mMESSAGE mMACHINE kit (Ambion Inc., Austin, TX). Embryos positioned in an agarose injection chamber were injected using a Narishige micromanipulator and needle holder (Narishige, Tokyo, Japan). The zebrash experiments were approved by the Institutional Animal Care and Use Committee of the National Taiwan University College of Medicine.

Whole-mount in situ hybridization. Whole-mount in situ hybridization was performed as our standard protocols37. The KCNIP1b probe was prepared from transOMIC clone BC086698 using primers PME18S F (50-TGTACGGAAGTGTT

ACTTCTGCTC-30) and PME 18S rev T3(50-GGATCCATTAACCCTCACTAA AGGGAAGGCCGCGACCTGCAGCTC-30) to prepare the template and T3 RNA polymerase for RNA synthesis. Embryos were xed overnight at 4 C in 4% paraformaldehyde buffered with 1 phosphate-buffered saline. After

permeabilization, embryos were hybridized overnight. Then embryos were incubated with anti-DIG antibody conjugated to AP, and developed with NBT-BCIP reagents.

Zebrash embryo heart electrophysiological recordings. The heart of zebrash embryos 3 days after fertilization was dissected from the thorax en bloc by using ne forceps and transferred to the recording chamber. Only spontaneously beating whole hearts were studied. All experiments were performed at room temperature. The recording chamber was superfused with a solution containing 140 mM NaCl, 4 mM KCl, 1.8 mM CaCl2, 1 mM MgCl2, 10 mM glucose and 10 mM Hepes(pH 7.4)19,37. Action potentials were recorded by using the microelectrode and disrupted patch method19,37. Atrial action potentials were measured by using an amplier (Axopatch 200B; Axon Instrument, USA) and digitized with a 12-bit analogue-to-digital converter (Digidata 1440A Interface; Molecular Devices, USA). Resting action potentials were rst validated and then triggered by incrementally injecting pulses of depolarizing current or eld pacing. APD was measured at 90% repolarization37,38.

Reverse transcription polymerase chain reaction. The extraction and quantication of mRNA by means of reverse transcription polymerase chain reaction (RT-PCR) were performed as our standard protocols24,25,3840. Total RNA was extracted from the cardiac tissues of male Wistar rats (weight 30020 g, aged 34 months). The experimental protocol conformed to ref. 41 and was approved by the Institutional Animal Care and Use Committee of the National Taiwan University College of Medicine. The tissue was homogenized with a Polytrone-Aggregate (Dispergierund Mischtechnik, Littau, Switzerland), and Trizol solution (Gibco BRL, Grand Island, NY) was added for RNA extraction. The extracted RNA was dissolved in diethyl pyrocarbonate-treated distilled water. Spectrophotometry at 260 and 280 nm was performed to measure the amount and quality of RNA. The RNA was then converted to complementary DNA by reverse transcription with random hexanucleotides and avian myeloblastosis virus reverse transcriptase (Boehringer, Mannheim, Germany). The primers are as follows: KCNIP1: forward: 50-CGACCCTCCAAAGATAAGATTG-30, reverse: 50-AGTTCCTCTCAGCAAA

ATCGAC-30; KCNIP2: forward: 50-GACTTTGTGGCTGGTTTGTC-30, reverse: 50-ATGGTCACCACACCATCCTT -30; KCNIP3: forward: 50-ATTTACGCGCA GTTCTTCCC-30, reverse: 50-GTAGCCATCCTTGTTAATGTC-30; KCNIP4: forward: 50-AGCGTGGAAGATGAACTGGA-30, reverse: 50-CCTGTGG AAAGAACTGCGAG-30.

Single-stranded complementary DNA was amplied with PCR. The PCR products were conrmed by means of direct sequencing. The glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene was used as the internal control

for equal loading. The reaction products were analysed with agarose gel electrophoresis. Optic densitometry was performed after the gel was stainedwith ethidium bromide for semiquantitative measurements of the DNA amount24,25,3840. The SYBR green method was used for quantitative measurement if necessary24,25,3840. Expression of mRNA was represented by its ratio to the mRNA of GAPDH.

Immunoprecipitation and immunoblotting assays. Preparations for protein extracts and western blot analyses were performed according to our standard protocols24,25,3840. Total proteins were extracted from the cardiac tissues of male Wistar rats (weight 30020 g, aged 34 months) according to the manufacturers instructions (Chemicon Compartment Protein Extraction Kit, Millipore, MA, USA). The experimental protocol conformed to the Guide for the Care and Use of Laboratory Animals (NIH Publication, 8th edition, 2011) and was approved by the Institutional Animal Care and Use Committee of the National Taiwan University College of Medicine. The primary antibodies used in the present study included rabbit polyclonal anti-KCHIP1 (1:500; Alomone Labs), rabbit polyclonal anti-Cav1.2 (1:5,000; Alomone Labs) and rabbit polyclonal anti-Kv4.2/4.3 (1:500; Santa Cruz). Rabbit peroxidase-conjugated secondary antibodies (1:4,000; Santa Cruz) were used for detection of the primary antibody.

For immunoprecipitation39, protein lysates were incubated with 1 mg ml 1 of the anti-KCHIP1 antibody (Alomone Labs) overnight at 4 C. Immunocomplexes were collected by incubation with 50 ml of protein A for 2 h. Immunoprecipitates were washed four times with ice-cold lysis buffer and the pellets were re-suspended in 2 sample buffer. The samples were then subjected to SDSpolyacrylamide gel

electrophoresis and immunoblotted with an anti-Kv4.2/4.3 (1:500; Santa Cruz) or anti-Cav1.2 (1:5,000; Alomone Labs) antibodies. The proteins were visualized by enhanced chemiluminescence (Amersham).

HL-1 atrial myocytes experiments. We used a murine atrial cell line HL-1 to study the effect of genetic manipulation of KCNIP1 on the change of atrial transient outward current. HL-1 atrial myocyte cell line is the only available atrial myocyte cell line that continuously divides, maintains a differentiated atrial phenotype with spontaneous depolarization and has a high transfection efciency for genetic manipulation24,25,38,39. HL-1 atrial myocytes were cultured as per our standard protocols24,25,38,39. HL-1 atrial myocytes were cultured in Claycomb medium supplemented with 10% fetal bovine serum, 100 units per ml penicillin,100 mg ml 1 streptomycin, 0.1 mM norepinephrine and 2 mM L-glutamine.

Transient transfection of HL-1 atrial myocytes was carried out using LipofectAMINE 2,000 (Invitrogen) according to the manufacturers instructions. Transfection efciency based on the GFP uorescence was 6080% for HL-1 cells24,25,38,39. Transmembrane currents in HL-1 atrial myocytes were measured by using the whole-cell recording technique with a patch-clamp amplier (Axopatch 200B; Axon Instrument, USA) and digitized with a 12-bit analogue-to-digital converter (Digidata 1440A Interface; Molecular Devices, USA) as previously described24,25. Transient outward current (Ito) was obtained by a family of depolarization steps from 80 mV, and was measured as the 4-aminopyridine

(4-AP)-sensitive peak current (10 mM).

Statistical analysis. CNV association analyses were performed using the logistic regression model to adjust non-genetic covariates. The statistical signicance level was set at Po10 3 in the genome-wide discovery stage. We used a more liberal threshold of Po10 3 in our stage I genome-wide discovery stage because of the small stage I sample size, and relied on subsequent validation in stages II and III with larger samples. Similar strategy with a liberal threshold in the stage I exploratory sample and then followed by critical validation in larger samples has been adopted in several genome-wide studies9. Furthermore, recently Panagiotou and Ioannidis42 also showed that a substantial proportion of the associations with borderline genome-wide signicance represent replicable and possible associations, and suggest a relaxation in the current GWS threshold. Finally, the resulting signicant CNVs were excluded if they resided on telomere- or centromere-proximal cytobands or on genomic regions with extremes of GC content, which produces hybridization bias.

The regional plot for the association of SNPs selected from the genome-wide humanOmni1-Quad BeadChip in the region anking the KCNIP1 intron 1 CNV, together with the KCNIP1 intron 1 CNV itself, with AF was created to nd possible signicant SNPs other than CNV itself. For each SNP, the chromosomal location was shown on the x axis and the signicance level for association with AF was indicated by a log10P value on the y axis. P values were expressed as log10(P)

(y axis) for every tested SNP ordered by chromosomal location (x axis). Genomic position was determined using the NCBI database (NSCI Build 36). Data were analysed with the R version 3.1.2 software (The R Project for Statistical Computing).

The statistical signicance level was set at Po0.05 after Bonferroni correction in the replication stages. Power estimation revealed that we had 495% power to replicate the association for an odds ratio of 2.0 at an alpha level of 0.05 with at least 250 cases and 500 controls in the replication population. Homogeneity of association across stages was tested using the MantelHaenszel method and the statistical signicance level was set at Po0.05.

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For the molecular and electrophysiological studies, all data were expressedas means.d. Data from independent group were compared using the MannWhitney U test for continuous data and Fishers exact test for categorical data. The statistical signicance level was set at Po0.05 after Bonferroni correction.

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Acknowledgements

We thank all individuals in this study for their generous participation. This work was supported by grants from the National Taiwan University Hospital, Taipei, Taiwan (grant numbers 100CGN10, 100-S1650, UN102-052, 102-S2155,102-P04, 103-P05 and 103-P06), the Ministry of Science and Technology, R.O.C. (grant numbers 99-2314-B-002-118-MY3, 101-2314-B-002-181-MY3, 102-2628-B-002 -035 -MY3 and 104-2314-B-002-194-MY3) the New Century Health Care Promotion Foundation and the Clinical Trial and Research Center of the National Taiwan University Hospital, Taipei, Taiwan. We also thank the core laboratories of the Department of Medical Research in the National Taiwan University Hospital for technical assistance and for providing major core facilities.

Author contributions

C.-T.T. designed the whole study, established the NTUH AF Registry, performed electrophysiological studies, directed the molecular biology studies and wrote the manuscript. C.-S.H. and E.Y.C. performed genetic data analyses. S.-N.C., K.-C.U., C.-F.T. and T.-H.L. established the validation cohort. C.-K.W., J.-K.L., L.-Y.L., Y.-C.W. andC.-C.Y. recruited and followed up the patients and provided valuable comments on the results. L.-P.L., J.-J.H., F.-T.C. and J.-L.L. directed the research.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/naturecommunications

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Competing nancial interests: The authors declare no competing nancial interests.

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How to cite this article: Tsai, C.-T. et al. Genome-wide screening identies a KCNIP1 copy number variant as a genetic predictor for atrial brillation. Nat. Commun. 7:10190 doi: 10.1038/ncomms10190 (2016).

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NATURE COMMUNICATIONS | 7:10190 | DOI: 10.1038/ncomms10190 | http://www.nature.com/naturecommunications

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