Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-21T18:56:37.229Z Has data issue: false hasContentIssue false

VRK2 gene expression in schizophrenia, bipolar disorder and healthy controls

Published online by Cambridge University Press:  02 January 2018

Martin Tesli
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Katrine Verena Wirgenes
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Timothy Hughes
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Department of Medical Genetics, Oslo University Hospital, Oslo, Norway
Francesco Bettella
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Lavinia Athanasiu
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Department of Medical Genetics, Oslo University Hospital, Oslo, Norway
Eva S. Hoseth
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Mari Nerhus
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Trine V. Lagerberg
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Nils E. Steen
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Drammen District Psychiatric Centre, Clinic of Mental Health and Addiction, Vestre Viken Hospital Trust, Drammen, Norway
Ingrid Agartz
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Department of Psychiatric Research, Diakonhjemmet Hospital, Oslo, Norway
Ingrid Melle
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Norway, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Ingrid Dieset
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Norway, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
Srdjan Djurovic
Affiliation:
KG Jebsen Centre for Psychosis Research, Department of Clinical Science, University of Bergen, Bergen, Department of Medical Genetics, Oslo University Hospital, Oslo, Norway
Ole A. Andreassen*
Affiliation:
KG Jebsen Centre for Psychosis Research, Institute of Clinical Medicine, University of Oslo, Oslo, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway
*
Ole A. Andreassen, MD, PhD, NORMENT, KG Jebsen Centre for Psychosis Research, Building 49, Oslo University Hospital, Ullevål, Kirkeveien 166, PO Box 4956 Nydalen, 0424 Oslo, Norway. Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background

Common variants in the Vaccinia-related kinase 2 (VRK2) gene have been associated with schizophrenia, but the relevance of its encoded protein VRK2 in the disorder remains unclear.

Aims

To identify potential differences in VRK2 gene expression levels between schizophrenia, bipolar disorder, psychosis not otherwise specified (PNOS) and healthy controls.

Method

VRK2 mRNA level was measured in whole blood in 652 individuals (schizophrenia, n = 201; bipolar disorder, n = 167; PNOS, n = 61; healthy controls, n = 223), and compared across diagnostic categories and subcategories. Additionally, we analysed for association between 1566 VRK2 single nucleotide polymorphisms and mRNA levels.

Results

We found lower VRK2 mRNA levels in schizophrenia compared with healthy controls (P<10–12), bipolar disorder (P<10–12) and PNOS (P = 0.0011), and lower levels in PNOS than in healthy controls (P = 0.0042) and bipolar disorder (P = 0.00026). Expression quantitative trait loci in close proximity to the transcription start site of the short isoforms of the VRK2 gene were identified.

Conclusions

Altered VRK2 gene expression seems specific for schizophrenia and PNOS, which is in accordance with findings from genome-wide association studies. These results suggest that reduced VRK2 mRNA levels are involved in the underlying mechanisms in schizophrenia spectrum disorders.

Type
Papers
Copyright
Copyright © Royal College of Psychiatrists, 2016 

Schizophrenia is a severe psychiatric disorder with high heritability estimates Reference Lichtenstein, Yip, Bjork, Pawitan, Cannon and Sullivan1,Reference Sullivan, Kendler and Neale2 and polygenic inheritance. 3 Despite the identification of common genetic variants through large genome-wide association studies (GWAS), little is known about the relation between DNA variants, gene expression and the clinical manifestations of the disorder. We have previously demonstrated that expression levels of candidate genes identified through GWAS, such as NOTCH4, TCF4 and ANK3, are significantly altered in schizophrenia and bipolar disorder, Reference Dieset, Djurovic, Tesli, Hope, Mattingsdal and Michelsen4Reference Wirgenes, Tesli, Inderhaug, Athanasiu, Agartz and Melle6 thus providing evidence that mRNA levels in blood might be a useful marker for further exploration of underlying disease mechanisms. Among the most consistently reported schizophrenia risk genetic variants are single nucleotide polymorphisms (SNPs) in vaccinia-related kinase 2 (VRK2). 3,Reference Li, Wang, Zheng, Ikeda, Iwata and Luo7,Reference Steinberg, de Jong, Irish Schizophrenia Genomics, Andreassen, Werge and Borglum8 Although one family study implicated a rare VRK2 variant in bipolar disorder, Reference Kerner, Rao, Christensen, Dandekar, Yourshaw and Nelson9 stronger associations have been found in schizophrenia. 3,10 The VRK2 gene (chromosome 2p16) encodes a protein in the VRK family of serine/threonine protein kinases, first identified in highly proliferative cells, such as testis, thymus and fetal liver, Reference Nezu, Oku, Jones and Shimane11 and later shown to be expressed in human brain, through all stages of life (http://braincloud.jhmi.edu/). The VRK2 protein has been found to be involved in signaling pathways regulating apoptosis, tumor cell growth Reference Monsalve, Merced, Fernandez, Blanco, Vazquez-Cedeira and Lazo12 and the immune response, Reference Blanco, Sanz-Garcia, Santos and Lazo13 and could be relevant for neurological diseases. Reference Sanz-Garcia, Vazquez-Cedeira, Kellerman, Renbaum, Levy-Lahad and Lazo14 In particular, variants in VRK2 have been associated with epilepsy. Reference Helbig and Lowenstein15 These findings are of interest in the light of the associations found between immune-related genes in the major histocompatibility complex region at chromosome 6 and schizophrenia, 3 and the polygenic overlap between schizophrenia and neurological disorders. Reference Andreassen, Harbo, Wang, Thompson, Schork and Mattingsdal16 However, the relation between identified VRK2 schizophrenia risk SNPs, VRK2 mRNA level and the clinical phenotype remains to be elucidated. One study reported altered VRK2 expression in blood cells of patients with schizophrenia (n = 20) compared with healthy controls (n = 18), but the result was only trend significant and no expression quantitative trait loci (eQTL) were identified. Reference Li, Wang, Zheng, Ikeda, Iwata and Luo7

We aimed to identify any abnormal VRK2 mRNA blood levels in schizophrenia compared with healthy controls. Further, we wanted to determine potential diagnostic specificity by comparing schizophrenia with psychosis not otherwise specified (PNOS) and bipolar disorder, as PNOS can be regarded as a less severe schizophrenia spectrum disorder Reference Kendler and Walsh17,Reference Tesli, Espeseth, Bettella, Mattingsdal, Aas and Melle18 and bipolar disorder shares clinical features and genetic risk with schizophrenia. Reference Tesli, Espeseth, Bettella, Mattingsdal, Aas and Melle1820 Additionally, we performed association analyses between SNPs in the VRK2 region and mRNA level, to identify cis-acting eQTLs.

Method

Sample characteristics

Our sample consisted of 652 individuals, organised into the diagnostic categories schizophrenia, bipolar disorder, PNOS and healthy controls. The schizophrenia category (n = 201) (SZ group) included the subcategories schizophrenia (n = 158), schizophreni-form disorder (n = 17) and schizoaffective disorder (n = 26). The bipolar disorder category (n = 167) (BD group) included bipolar disorder type 1 (n = 103), bipolar disorder type 2 (n = 51) and bipolar disorder not otherwise specified (BDNOS) (n = 13). The PNOS category included 61 individuals, and 223 participants were included in the healthy control category (CTR group). The patients were diagnosed according to the Structured Clinical Interview for DSM-III-R (SCID Reference Spitzer, Williams, Gibbon and First21 ). Overall, 78 patients (75.7%) with bipolar disorder type 1, 11 patients (21.6%) with bipolar disorder type 2 and 8 patients (61.5%) with BDNOS had experienced at least one Structural Clinical Interview for DSM-III-R SCID-verified psychotic episode. Healthy controls were randomly recruited from the same catchment area as the patients, and underwent an interview where demographic and clinical information was obtained. Our sample consisted of White Northern European participants (mainly Norwegians). We have previously demonstrated our sample to be genetically homogeneous, based on linkage clustering as well as self-reports on ancestry. Reference Wirgenes, Tesli, Inderhaug, Athanasiu, Agartz and Melle6,Reference Athanasiu, Mattingsdal, Kahler, Brown, Gustafsson and Agartz22,Reference Djurovic, Gustafsson, Mattingsdal, Athanasiu, Bjella and Tesli23 Clinical evaluation of the patients and healthy controls participating in this study is described in detail in previous reports. Reference Wirgenes, Tesli, Inderhaug, Athanasiu, Agartz and Melle6 Demographical data are shown in Table 1.

Table 1 Demographics and clinical characteristics

ANOVA/χ2 analysis
SZ group
(n = 201)
BD group a
(n = 167)
PNOS group
(n = 61)
CTR group
(n = 223)
F2 P Post-hoc
Female, % 38.3 62.9 39.3 44.8 χ2 = 24.8 < 0.001
Age, years: mean (s.d.) 30.9 (9.6) 34.3 (11.5) 32.8 (10.3) 33.1 (9.3) F = 3.3 0.020 (BD > SZ)
Age at onset, years: mean (s.d.) 23.3 (8.3) 23.6 (10.1) 27.2 (10.2) F = 3.8 0.022 (PNOS > BD,SZ)
GAF symptom, mean (s.d.) 40.8 (11.0) 55.7 (11.3) 50.0 (14.1) F = −72.0 < 0.001 (BD > PNOS > SZ)
GAF function, mean (s.d.) 41.9 (9.9) 53.2 (12.4) 52.6 (14.9) F = −44.3 < 0.001 (BD,PNOS > SZ)
PANSS positive, mean (s.d.) 15.6 (5.4) 10.0 (3.6) 12.7 (4.1) F = 63.6 < 0.001 (SZ > PNOS > BD)
PANSS negative, mean (s.d.) 16.1 (6.2) 10.5 (3.7) 11.7 (5.1) F = 51.0 < 0.001 (SZ > PNOS,BD)
PANSS total, mean (s.d.) 65.0 (16.8) 46.4 (10.9) 53.7 (14.5) F = 71.6 < 0.001 (SZ > PNOS > BD)
IDS, mean (s.d.) 17.5 (11.9) 17.4 (12.8) 15.2 (11.4)
YMRS, mean (s.d.)   6.1 (5.1)   3.0 (4.0)   4.0 (4.1) F = 19.1 < 0.001 (SZ > PNOS,BD)
Nicotine, b % 57.9 58.8 54.4
AUDIT, c mean (s.d.)   6.4 (6.6)   7.7 (6.3)   8.2 (7.9) 5.4 (3.0) F = 5.1 0.002 (PNOS,BD > SZ,CTR)
DUDIT, d mean (s.d)   2.5 (5.9)   2.5 (6.3)   4.7 (8.0) 0.2 (0.8) F = 11.0 < 0.001 (PNOS,SZ,BD > CTR)
Medication status, %
    Medicated 90.7 83.9 78.9 F = 3.2 0.040
    Antipsychotics 77.1 49.7 67.2 F = 16.2 < 0.001 (SZ,PNOS > BD)
    Lithium   2.5 14.4   0.0 F = 13.5 < 0.001 (BD > SZ,PNOS)
    Anticonvulsants 17.4 42.5   9.8 F = 21.6 < 0.001 (BD > SZ,PNOS)
    Antidepressants 25.4 38.3 34.4 F = 3.7 0.026 (BD > SZ)
    Hypnotics 14.4 12.0   4.9
    Psychostimulants   0.0   1.2   1.6

SZ, schizophrenia; BD, bipolar disorder; PNOS, psychotic disorder not otherwise specified; CTR, healthy controls; PANSS, Positive and Negative Syndrome Scale; Reference Kay, Fiszbein and Opler29 IDS, Inventory of Depressive Symptomatology; Reference Rush, Gullian, Basco, Jarrett and Trivedi30 GAF, Global Assessment of Functioning; Reference Endicott, Spitzer, Fleiss and Cohen31 YMRS, Young Mania Rating Scale; Reference Young, Biggs, Ziegler and Meyer32 AUDIT, Alcohol Use Disorders Identification Test; DUDIT, Drug Use Disorders Identification Test.

a. n = 103 bipolar disorder type I (61.7%); n = 51 bipolar disorder type II (30.6%) and n = 13 bipolar disorder not otherwise specified (7.8%).

b. Daily use of nicotine.

c. Past 12 months, problematic use defined as score ⩾8 in males and ⩾7 in females.

d. Past 12 months, problematic use defined as score ⩾6 in males.

The Norwegian Scientific Ethical Committees and the Norwegian Data Protection Agency approved the study. All participants have given written informed consent prior to inclusion into the project.

RNA measurement

Blood samples were collected using Tempus Blood RNA Tubes (Life Technologies Corporation, Carlsbad, California, USA). Total RNA was extracted with ABI PRISM 6100 Nucleic Acid PrepStation (Life Technologies Corporation, Carlsbad, California, USA) and TEMPUS 12-port RNA Isolation Kit according to the manufacturer's protocol. High-Capacity cDNA Reverse Transcription Kit (Life Technologies Corporation, Carlsbad, California, USA) was used for reverse transcription of 1 μg RNA. Quantitative reverse transcriptase polymerase chain reaction was performed on ABI PRISM 7900HT Sequence Detection System by using TaqMan Gene Expression Assays (VRK2: Hs00241738_m1; Life Technologies Corporation, Carlsbad, California, USA) and the gene ACTB (Hs99999903_m1; Life Technologies Corporation, Carlsbad, California, USA) was used as endogenous control. We analysed the expression stability of 16 endogenous control genes in 16 samples (4 healthy controls, 4 bipolar disorder, 4 schizophrenia and 4 PNOS) using the geNorm method. Reference Hellemans, Mortier, De Paepe, Speleman and Vandesompele24 We found that all tested endogenous controls to be below the recommend M-value cutoff of 0.5 and ACTB is one of the most stable of these (see Fig. DS1 in the online supplement). The instruction protocol from the manufacturer was strictly followed. The results were processed in RQ Manager 1.2.1. VRK2 mRNA ÄCt (cycling threshold) in each individual was calibrated against mean VRK2 mRNA ΔCt in the CTR group. The following formula was used for statistical analyses in this report: 2(−ΔΔCt), as described previously. Reference Wirgenes, Tesli, Inderhaug, Athanasiu, Agartz and Melle6

Genotyping and SNP selection

The sample was genotyped at Expression Analysis (Durham, North Carolina, USA) using the Affymetrix Genome-Wide Human SNP array 6.0 (Affymetrix, Santa Clara, California, USA). Quality control was performed using PLINK (version 1.07; http://pngu.mgh.harvard.edu/purcell/plink/). Reference Purcell, Neale, Todd-Brown, Thomas, Ferreira and Bender25 Overall, significant plate-specific markers were set to missing (in that plate). One of two duplicates, one of two relatives (identity by descent >0.1875), samples with a reported gender differing from that determined by X chromosome marker homozygosity, mixup-samples (as calculated by pairwise genome-wide identity by state), samples with non-European ancestry (as calculated with HapMap3 (Wellcome Trust Sanger Institute, Cambridge, UK) and multidimensional scaling) and samples with individual genotyping below 95%, were excluded. SNPs were excluded if they had minor allele frequency <1%, low yield (<95%) or deviated from Hardy–Weinberg equilibrium (P<0.001).

MACH imputed data

Candidate SNPs were imputed with MACH Reference Li, Willer, Ding, Scheet and Abecasis26 using the European samples available in the Phase I release of the 1000 Genomes Project (www.sph.umich.edu/csg/abecasis/MACH/download/1000G-PhaseI-Interim.html) after the quality control described above. In addition, all SNPs not present in the 1000 Genomes reference, as well as all SNPs where strand alignment was ambiguous (A/T and G/C SNPs), were removed from the sample data-sets. Imputations were carried out in a three-stage process using the ChunkChromosome (http://genome.sph.umich.edu/wiki/ChunkChromosome), MACH (www.sph.umich.edu/csg/abecasis/MaCH/download/) and minimac programs (http://genome.sph.umich.edu/wiki/Minimac). First, the data-sets were broken into 2500 SNP pieces, with 500 SNP overlap using ChunkChromosome. Second, each piece was phased using MACH (40 rounds, 400 states). Third, each phased piece was imputed to the 1000 Genomes European reference panel using minimac (20 rounds, 400 states). Minimac provides an estimated r 2 score that provides a quality metric for each imputed SNP. All SNPs with r 2<0.5 were excluded from further analysis leaving 9 584 802 SNPs. 1566 imputed VRK2 SNPs based on UCSC (hg 19) Chr2: 57,900–58,600 were extracted for inclusion in the current analyses. This region was selected to cover all risk SNPs from the Psychiatric Genomics Consortium schizophrenia case–control study 3 in and around the VRK2 gene (based on summary statistics from www.broadinstitute.org/mpg/ricopili/).

Statistical analyses

VRK2 mRNA across diagnostic categories

Using IBM's SPSS software package for Windows, version 21, differences in VRK2 mRNA levels between the diagnostic categories (bipolar disorder, schizophrenia, PNOS and healthy controls) were investigated with an ANOVA model, followed by pairwise comparisons adjusted with the Tukey method. Seven individuals were removed owing to deviant VRK2 mRNA levels defined as 3 standard deviations from the mean. Post-hoc analyses were performed with age, gender, alcohol use (Alcohol Use Disorders Identification Test, AUDIT) Reference Bohn, Babor and Kranzler27 and illegal drug use (Drug Use Disorders Identification Test, DUDIT) Reference Berman, Bergman, Palmstierna and Schlyter28 as covariates in an ANCOVA model in the total sample. Additionally, medication status (dichotomised because of non-normal distribution) for antipsychotics, antidepressants, anticonvulsants, lithium, hypnotics and psychostimulants were regressed against VRK2 mRNA level within the patients in a multiple hierarchical regression model with diagnostic category, gender and age as covariates. The same procedure was undertaken for daily use of nicotine (yes/no), as this information was not available in the CTR group. Effect sizes (Nagelkerke R 2) for the significant differences in mRNA level for pairwise comparisons between the BD, SZ, PNOS and CTR groups were estimated with logistic regressions. To assess the consistency of the findings, ANOVA analyses were undertaken in the diagnostic subcategories, as well as in males and females separately for the main diagnostic categories. Additionally, potential difference in VRK2 mRNA level between bipolar disorder with psychotic symptoms and bipolar disorder without psychotic symptoms was assessed with a t-test.

Genetic associations with VRK2 mRNA levels

Association analyses between 1566 imputed VRK2 SNPs and mRNA levels were performed with a linear regression model in PLINK (version 1.07; http://pngu.mgh.harvard.edu/purcell/plink/). Reference Purcell, Neale, Todd-Brown, Thomas, Ferreira and Bender25 These analyses were conducted in the total sample and in the BD, SZ, PNOS and CTR groups separately, with gender and age as covariates, as well as diagnostic category in the total sample. Gene-wide significance threshold for association between 1566 VRK2 SNPs and VRK2 mRNA was computed with the aid of matSpD Reference Li and Ji33 taking into account the SNP correlations reflected by the sample's linkage disequilibrium structure in the region of interest. The effective number (n = 174) of independent tests was computed using Li's procedure. Total sample size for these analyses after quality control procedures was 575 (schizophrenia, n = 169; bipolar disorder, n = 146; PNOS, n = 50; healthy controls, n = 210).

Results

VRK2 mRNA levels across diagnostic categories

VRK2 mRNA levels differ significantly between the SZ, BD, PNOS and CTR groups (ANOVA, F = 53.6, d.f. = 3, 648, P = 5.8×10−31) (Fig. 1 and Table 2). Pairwise comparisons reveal significantly lower VRK2 mRNA levels in the SZ group than the CTR (P<10−12, Nagelkerke R 2 = 0.30), BD (P<10−12, Nagelkerke R 2 = 0.42) and PNOS groups (P = 0.0011, Nagelkerke R 2 = 0.13), and significantly lower levels in PNOS than healthy controls (P = 0.0042, Nagelkerke R 2 = 0.051) and bipolar disorder (P = 0.00026, Nagelkerke R 2 = 0.11). Results from the post-hoc analyses (ANCOVA) remain largely unchanged after controlling for gender, age, alcohol and drug use (online Table DS1). There are no significant effects of antipsychotics, anticonvulsants, lithium, hypnotics or psychostimulants on VRK2 mRNA level within the patients. Antidepressants are associated with lower VRK2 mRNA levels (P = 0.007), but this cannot explain the effect of diagnostic category on VRK2 mRNA level, as more patients with bipolar disorder than those with schizophrenia used antidepressants (Table 1). Smoking status does not influence VRK2 mRNA levels within the patients. ANOVA analyses show a consistent pattern for the diagnostic subcategories compared with the main categories (online Fig. DS1 and Table DS2). Further, the results remain largely the same when analysed in males and females separately (online Table DS3). There were no significant differences in VRK2 mRNA level between bipolar disorder with psychotic symptoms and bipolar disorder without psychotic symptoms. In addition to significant differences in mean expression level between the diagnostic categories, the range of the distributions are only partially overlapping (Fig. 2), with no individuals with schizophrenia with relative expression value above 1.3, whereas 45 healthy controls (20.2%) and 25 patients with bipolar disorder (15.0%) have such expression levels. Moreover, only 18 individuals with schizophrenia have an expression value above 1.0 (9.0%), whereas 96 individuals with bipolar disorder (57.5%) and 99 healthy controls (44.4%) have a value above 1.0 (online Fig. DS3).

Fig. 1 VRK2 mRNA expression levels (mean value one standard error) according to diagnostic category.

VRK2 mRNA levels are significantly lower in schizophrenia (SZ) than healthy controls (CTR) (P<10−12), bipolar disorder (BD) (P<10−12) and psychosis not otherwise specified (PNOS) (P = 0.0011), and significantly lower in PNOS than CTR (P = 0.0042) and BD (P = 0.00026).

Fig. 2 Density plot for VRK2 expression in schizophrenia and healthy controls.

Smooth density estimate computed with 1d kernel Reference Wickham35 using relative expression levels of VRK2 for the following diagnostic categories: schizophrenia (SZ) (n = 201) and healthy controls (CTR) (n = 223).

Table 2 Results from ANOVA pairwise comparisons of VRK2 mRNA level across diagnostic categories a

95% confidence Interval
Diagnostic category Mean difference s.e. P Lower limit Upper limit
CTR
    SZ   0.28 0.026 < 10−12   0.21   0.34
    BD −0.034 0.027 0.60 −0.10   0.036
    PNOS   0.13 0.038 0.0042   0.031   0.23
SZ
    CTR −0.28 0.026 < 10−12 −0.34 −0.21
    BD −0.31 0.028 < 10−12 −0.38 −0.24
    PNOS −0.15 0.034 0.0011 −0.25 −0.045
BD
    CTR   0.034 0.027 0.60 −0.036   0.10
    SZ   0.31 0.028 < 10−12   0.24   0.38
    PNOS   0.16 0.040 0.00026   0.061   0.27
PNOS
    CTR −0.13 0.038 0.0042 −0.23 −0.031
    SZ   0.15 0.039 0.0011   0.045   0.25
    BD −0.16 0.040 0.00026 −0.27 −0.061

SZ, schizophrenia; BD, bipolar disorder; PNOS, psychotic disorder not otherwise specified; CTR, healthy controls.

a. Correction pairwise comparison = Tukey.

Genetic associations with VRK2 mRNA levels

VRK2 SNPs in close proximity to the transcription start site of the short isoforms of the VRK2 gene are significantly associated with VRK2 mRNA levels in the total sample, with weaker effects in the BD, SZ, PNOS and CTR groups separately (online Table DS4 and Fig. 3). A distinct cluster of highly associated SNPs is located in the 25 kb immediately to the 5’ of the transcription start site which is slightly closer to the transcription start site than the tag SNP (rs2312147) previously identified as significantly associated with clinical phenotype. Reference Steinberg, de Jong, Irish Schizophrenia Genomics, Andreassen, Werge and Borglum8 Another region close to the VRK2 gene harboring three significant tag SNPs (at approximately chr2:57.9–58.0Mb), which has been previously reported, 3 does not appear to be an eQTL.

Fig. 3 VRK2 expression quantitative loci.

VRK2 expression quantitative loci identified in the total sample (n = 652), using a linear regression model with gender, age and diagnostic category as covariates. Blue dots: VRK2 single nucleotide polymorphisms (SNPs) included in our expression model which are genome-wide significant in the latest Psychiatric Genomics Consortium schizophrenia case–control study (PGC_SCZ52_may13) (www.broadinstitute.org/mpg/ricopili/) at significance level 5.0×10−8. Horizontal line: gene-wide significance threshold for association between 1566 VRK2 SNPs and VRK2 mRNA. This threshold was computed with the aid of matSpD Reference Li and Ji33 taking into account the SNP correlations reflected by sample's LD-structure in the region of interest. The effective number (n = 174) of independent tests was computed using Li's procedure. TSS, transcription start site.

Discussion

The main finding of the present study was a clear reduction in VRK2 mRNA levels in the SZ group compared with the CTR group. The gene expression levels in bipolar disorder were comparable to those in the CTR group, with the PNOS group intermediate between the SZ and BD/CTR groups. These findings are in accordance with results from recent GWAS, where VRK2 SNPs have been more strongly associated with schizophrenia than with bipolar disorder. 3,10 The finding of diagnostic specificity for reduced VRK2 mRNA levels in schizophrenia is interesting in light of recent evidence for genetic risk variants in the major histocompatibility complex region specific to schizophrenia and apparently not implicated in bipolar disorder. Reference Bergen, O'Dushlaine, Ripke, Lee, Ruderfer and Akterin34 The polygenic overlap in the major histocompatibility complex region between schizophrenia and neurological disorders also seems specific to schizophrenia and not bipolar disorder. Reference Andreassen, Harbo, Wang, Thompson, Schork and Mattingsdal16 The intermediate gene expression levels in PNOS between the SZ and CTR groups is in line with clinical observations, as PNOS is a less severe form of psychosis than schizophrenia.

Intriguingly, VRK2 variants have been associated with epilepsy, 36 and the encoded protein VRK2 has been found to be important for regulation of cell growth and inflammatory responses. Reference Sanz-Garcia, Vazquez-Cedeira, Kellerman, Renbaum, Levy-Lahad and Lazo14 More specifically, there is evidence that high VRK2 levels confer protection against apoptosis, Reference Monsalve, Merced, Fernandez, Blanco, Vazquez-Cedeira and Lazo12 and that VRK2 reduces the transcriptional response to interleukin-1b, Reference Blanco, Sanz-Garcia, Santos and Lazo13 a cytokine involved in inflammatory activity. Thus, one could speculate that reduced VRK2 levels might increase already elevated inflammatory response, in addition to inducing apoptosis, thereby inhibiting normal neurodevelopment during early stages of life, which has been suggested as an underlying mechanism in schizophrenia. Reference Altamura, Pozzoli, Fiorentini and Dell'osso37 This hypothesis is in accordance with findings of higher levels of inflammatory markers, Reference Hope, Ueland, Steen, Dieset, Lorentzen and Berg38 brain volume reductions Reference Rimol, Hartberg, Nesvag, Fennema-Notestine, Hagler and Pung39 and neurocognitive impairment in schizophrenia. Reference Simonsen, Sundet, Vaskinn, Birkenaes, Engh and Faerden40 Further, the VRK2 risk allele in rs2312147 has been associated with reduced total brain volume and white matter volume in healthy individuals. Reference Li, Wang, Zheng, Ikeda, Iwata and Luo7 The lack of association between antipsychotic medication and VRK2 mRNA levels in the current study further strengthens an argument for the role of VRK2 in the neurodevelopmental hypothesis.

The extent to which gene expression in blood can act as a proxy for brain expression remains unclear, Reference Sullivan, Fan and Perou41 however the use of blood RNA is a practical necessity if one wishes to study gene expression in a large number of individuals with psychiatric disorder and controls. Since we lack sufficient information on the nature of the blood–brain gene expression correlation, we cannot claim that what we observe in blood is an accurate reflection of expression in the brain. However, this does not detract from the fact that blood-based gene expression levels may be useful in diagnosis. Reference Takahashi, Hayashi, Watanabe, Sawamura, Fukui and Watanabe42 Gene expression in blood has been found to share significant similarities with multiple central nervous system tissues, and correlation between transcripts present in both whole blood and nervous system has been estimated to be around 0.5. Reference Sullivan, Fan and Perou41 Further, peripheral blood was recently validated as a valuable source of information for estimation of heritability through gene expression as well as identification of eQTLs in a large twin study. Reference Wright, Sullivan, Brooks, Zou, Sun and Xia43

VRK2 has nine transcripts in the RefSeq database, but these divide into two broad groups: the long isoforms with a transcription start site at approximately 58 134 kbp and the short forms with a transcription start site at approximately 58 273 kbp. The expression profile of VRK2 is very similar in brain and blood, with the short form being the dominantly expressed form in both tissues. The long form is also expressed in both these tissues, but at very low levels (online Fig. DS4).

The probe used for measuring VRK2 expression in this study was chosen so as to produce an aggregate measure of expression over all RefSeq transcripts. Since we know that the short form is the most abundantly expressed, it is not surprising to observe in our data a cluster of significant SNPs near the transcription start site of the short isoforms. However, the significant SNPs from the latest Psychiatric Genomics Consortium schizophrenia study 3 form a large cluster around the transcription start site of the longer form (Fig. 3). This suggests that it is one of the long isoforms of VRK2 that is involved in the aetiology of schizophrenia rather than one of the short isoforms. Future studies should aim to conclusively identify the exact transcript of VRK2 involved as well as confirm that the significant differences observed at the mRNA level are also present at the protein level.

In conclusion, our results give further support to the relevance of the VRK2 gene in schizophrenia susceptibility, and suggest that reduced gene expression might be involved in the underlying disorder mechanisms, potentially related to dysregulation of the immune system and impaired neurodevelopment. Moreover, we observed diagnostic specificity for schizophrenia (30% explained variance v. healthy controls), with a distribution range which differs substantially from that of bipolar disorder and healthy controls (Fig. 2 and Fig. DS3). Such differences in the distributions encourage further studies to test the possibility of using VRK2 as a biomarker for schizophrenia.

Acknowledgements

We thank all study participants for their involvement in the study, and the health professionals who facilitated our work. We also thank Thomas D. Bjella for assistance with the database. The work was supported by the Research Council of Norway, the South-East Norway Regional Health Authority and KG Jebsen Foundation.

Footnotes

These authors contributed equally to this work.

Declaration of interest

M.T. received speaker's honorarium from Medivir. O.A.A. received speaker's honoraria from GlaxoSmithKline, Lundbeck and Otsuka.

References

1 Lichtenstein, P, Yip, BH, Bjork, C, Pawitan, Y, Cannon, TD, Sullivan, PF, et al. Common genetic determinants of schizophrenia and bipolar disorder in Swedish families: a population-based study. Lancet 2009; 373: 234–9.CrossRefGoogle ScholarPubMed
2 Sullivan, PF, Kendler, KS, Neale, MC. Schizophrenia as a complex trait: evidence from a meta-analysis of twin studies. Arch Gen Psychiatry 2003; 60: 1187–92.CrossRefGoogle ScholarPubMed
3 Schizophrenia Working Group of the Psychiatric Genomics C. Biological insights from 108 schizophrenia-associated genetic loci. Nature 2014; 511: 421–7.Google Scholar
4 Dieset, I, Djurovic, S, Tesli, M, Hope, S, Mattingsdal, M, Michelsen, A, et al. Upregulation of NOTCH4 gene expression in bipolar disorder. Am J Psychiatry 2012; 169: 1292–300.Google Scholar
5 Wirgenes, KV, Sonderby, IE, Haukvik, UK, Mattingsdal, M, Tesli, M, Athanasiu, L, et al. TCF4 sequence variants and mRNA levels are associated with neurodevelopmental characteristics in psychotic disorders. Transl Psychiatry 2012; 2: e112.Google Scholar
6 Wirgenes, KV, Tesli, M, Inderhaug, E, Athanasiu, L, Agartz, I, Melle, I, et al. ANK3 gene expression in bipolar disorder and schizophrenia. Br J Psychiatry 2014; 205: 244–5.Google Scholar
7 Li, M, Wang, Y, Zheng, XB, Ikeda, M, Iwata, N, Luo, XJ, et al. Meta-analysis and brain imaging data support the involvement of VRK2 (rs2312147) in schizophrenia susceptibility. Schizophr Res 2012; 142: 200–5.CrossRefGoogle ScholarPubMed
8 Steinberg, S, de Jong, S, Irish Schizophrenia Genomics, C, Andreassen, OA, Werge, T, Borglum, AD, et al. Common variants at VRK2 and TCF4 conferring risk of schizophrenia. Hum Mol Genet 2011; 20: 4076–81.CrossRefGoogle ScholarPubMed
9 Kerner, B, Rao, AR, Christensen, B, Dandekar, S, Yourshaw, M, Nelson, SF. Rare genomic variants link bipolar disorder with anxiety disorders to creb-regulated intracellular signaling pathways. Front Psychiatry 2013; 4: 154.Google Scholar
10 Psychiatric GWAS Consortium Bipolar Disorder Working group. Large-scale genome-wide association analysis of bipolar disorder identifies a new susceptibility locus near ODZ4. Nature Genet 2011; 43: 977–83.Google Scholar
11 Nezu, J, Oku, A, Jones, MH, Shimane, M. Identification of two novel human putative serine/threonine kinases, VRK1 and VRK2, with structural similarity to vaccinia virus B1R kinase. Genomics 1997; 45: 327–31.CrossRefGoogle ScholarPubMed
12 Monsalve, DM, Merced, T, Fernandez, IF, Blanco, S, Vazquez-Cedeira, M, Lazo, PA. Human VRK2 modulates apoptosis by interaction with Bcl-xL and regulation of BAX gene expression. Cell Death Dis 2013; 4: e513.Google Scholar
13 Blanco, S, Sanz-Garcia, M, Santos, CR, Lazo, PA. Modulation of interleukin-1 transcriptional response by the interaction between VRK2 and the JIP1 scaffold protein. PLoS One 2008; 3: e1660.CrossRefGoogle ScholarPubMed
14 Sanz-Garcia, M, Vazquez-Cedeira, M, Kellerman, E, Renbaum, P, Levy-Lahad, E, Lazo, PA. Substrate profiling of human vaccinia-related kinases identifies coilin, a Cajal body nuclear protein, as a phosphorylation target with neurological implications. J Proteomics 2011; 75: 548–60.CrossRefGoogle ScholarPubMed
15 Helbig, I, Lowenstein, DH. Genetics of the epilepsies: where are we and where are we going? Curr Opin Neurol 2013; 26: 179–85.Google Scholar
16 Andreassen, OA, Harbo, HF, Wang, Y, Thompson, WK, Schork, AJ, Mattingsdal, M, et al. Genetic pleiotropy between multiple sclerosis and schizophrenia but not bipolar disorder: differential involvement of immune-related gene loci. Mol Psychiatry 2015; 20: 207–14.Google Scholar
17 Kendler, KS, Walsh, D. Schizophreniform disorder, delusional disorder and psychotic disorder not otherwise specified: clinical features, outcome and familial psychopathology. Acta Psychiatr Scand 1995; 91: 370–8.CrossRefGoogle Scholar
18 Tesli, M, Espeseth, T, Bettella, F, Mattingsdal, M, Aas, M, Melle, I, et al. Polygenic risk score and the psychosis continuum model. Acta Psychiatr Scand 2014; 130: 311–7.Google Scholar
19 Andreassen, OA, Thompson, WK, Schork, AJ, Ripke, S, Mattingsdal, M, Kelsoe, J, et al. Improved detection of common variants associated with schizophrenia and bipolar disorder using pleiotropy-informed conditional false discovery rate. PLoS Genet 2013; 9: e1003455.CrossRefGoogle ScholarPubMed
20 International Schizophrenia Consortium. Common polygenic variation contributes to risk of schizophrenia and bipolar disorder. Nature 2009; 460: 748–52.Google Scholar
21 Spitzer, RL, Williams, JB, Gibbon, M, First, MB. The Structured Clinical Interview for DSM-III-R (SCID). I: History, rationale, and description. Arch Gen Psychiatry 1992; 49: 624–9.Google Scholar
22 Athanasiu, L, Mattingsdal, M, Kahler, AK, Brown, A, Gustafsson, O, Agartz, I, et al. Gene variants associated with schizophrenia in a Norwegian genome-wide study are replicated in a large European cohort. J Psychiatr Res 2010; 44: 748–53.CrossRefGoogle Scholar
23 Djurovic, S, Gustafsson, O, Mattingsdal, M, Athanasiu, L, Bjella, T, Tesli, M, et al. A genome-wide association study of bipolar disorder in Norwegian individuals, followed by replication in Icelandic sample. J Affect Disord 2010; 126: 312–6.CrossRefGoogle ScholarPubMed
24 Hellemans, J, Mortier, G, De Paepe, A, Speleman, F, Vandesompele, J. qBase relative quantification framework and software for management and automated analysis of real-time quantitative PCR data. Genome Biol 2007; 8: R19.Google Scholar
25 Purcell, S, Neale, B, Todd-Brown, K, Thomas, L, Ferreira, MA, Bender, D, et al. PLINK: a tool set for whole-genome association and population-based linkage analyses. Am J Hum Genet 2007; 81: 559–75.Google Scholar
26 Li, Y, Willer, CJ, Ding, J, Scheet, P, Abecasis, GR. MaCH: using sequence and genotype data to estimate haplotypes and unobserved genotypes. Genet Epidemiol 2010; 34: 816–34.Google Scholar
27 Bohn, MJ, Babor, TF, Kranzler, HR. The Alcohol Use Disorders Identification Test (AUDIT): validation of a screening instrument for use in medical settings. J Stud Alcohol 1995; 56: 423–32.Google Scholar
28 Berman, AH, Bergman, H, Palmstierna, T, Schlyter, F. Evaluation of the Drug Use Disorders Identification Test (DUDIT) in criminal justice and detoxification settings and in a Swedish population sample. Eur Addict Res 2005; 11: 2231.Google Scholar
29 Kay, SR, Fiszbein, A, Opler, LA. The Positive and Negative Syndrome Scale (PANSS) for schizophrenia. Schizophr Bull 1987; 13: 261–76.CrossRefGoogle ScholarPubMed
30 Rush, AJ, Gullian, CM, Basco, MR, Jarrett, RB, Trivedi, MH. The Inventory of Depressive Symptomatology (IDS): psychometric properties. Psychol Med 1996; 26: 477–86.CrossRefGoogle ScholarPubMed
31 Endicott, J, Spitzer, RL, Fleiss, JL, Cohen, J. The Global Assessment Scale. A procedure for measuring overall severity of psychiatric disturbance. Arch Gen Psychiatry 1976; 33: 766–71.CrossRefGoogle Scholar
32 Young, RC, Biggs, JT, Ziegler, VE, Meyer, DA. A rating scale for mania: reliability, validity and sensitivity. Br J Psychiatry 1978; 133: 429–35.Google Scholar
33 Li, J, Ji, L. Adjusting multiple testing in multilocus analyses using the eigenvalues of a correlation matrix. Heredity 2005; 95: 221–7.Google Scholar
34 Bergen, SE, O'Dushlaine, CT, Ripke, S, Lee, PH, Ruderfer, DM, Akterin, S, et al. Genome-wide association study in a Swedish population yields support for greater CNV and MHC involvement in schizophrenia compared with bipolar disorder. Mol Psychiatry 2012; 17: 880–6.Google Scholar
35 Wickham, H. ggplot2: Elegant Graphics for Data Analysis (1st edn). Springer, 2009.Google Scholar
36 Epicure Consortium, EMINet Consortium. Genome-wide association analysis of genetic generalized epilepsies implicates susceptibility loci at 1q43, 2p16.1, 2q22.3 and 17q21.32. Hum Mol Genet 2012; 21: 5359–72.Google Scholar
37 Altamura, AC, Pozzoli, S, Fiorentini, A, Dell'osso, B. Neurodevelopment and inflammatory patterns in schizophrenia in relation to pathophysiology. Prog Neuropsychopharmacol Biol Psychiatry 2013; 42: 6370.Google Scholar
38 Hope, S, Ueland, T, Steen, NE, Dieset, I, Lorentzen, S, Berg, AO, et al. Interleukin 1 receptor antagonist and soluble tumor necrosis factor receptor 1 are associated with general severity and psychotic symptoms in schizophrenia and bipolar disorder. Schizophr Res 2013; 145: 3642.Google Scholar
39 Rimol, LM, Hartberg, CB, Nesvag, R, Fennema-Notestine, C, Hagler, DJ Jr, Pung, CJ, et al. Cortical thickness and subcortical volumes in schizophrenia and bipolar disorder. Biol Psychiatry 2010; 68: 4150.Google Scholar
40 Simonsen, C, Sundet, K, Vaskinn, A, Birkenaes, AB, Engh, JA, Faerden, A, et al. Neurocognitive dysfunction in bipolar and schizophrenia spectrum disorders depends on history of psychosis rather than diagnostic group. Schizophr Bull 2011; 37: 7383.Google Scholar
41 Sullivan, PF, Fan, C, Perou, CM. Evaluating the comparability of gene expression in blood and brain. Am J Med Genet B Neuropsychiatr Genet 2006; 141B: 261–8.Google Scholar
42 Takahashi, M, Hayashi, H, Watanabe, Y, Sawamura, K, Fukui, N, Watanabe, J, et al. Diagnostic classification of schizophrenia by neural network analysis of blood-based gene expression signatures. Schizophr Res 2010; 119: 210–8.Google Scholar
43 Wright, FA, Sullivan, PF, Brooks, AI, Zou, F, Sun, W, Xia, K, et al. Heritability and genomics of gene expression in peripheral blood. Nature Genet 2014; 46: 430–7.Google Scholar
Figure 0

Table 1 Demographics and clinical characteristics

Figure 1

Fig. 1 VRK2 mRNA expression levels (mean value one standard error) according to diagnostic category.VRK2 mRNA levels are significantly lower in schizophrenia (SZ) than healthy controls (CTR) (P<10−12), bipolar disorder (BD) (P<10−12) and psychosis not otherwise specified (PNOS) (P = 0.0011), and significantly lower in PNOS than CTR (P = 0.0042) and BD (P = 0.00026).

Figure 2

Fig. 2 Density plot for VRK2 expression in schizophrenia and healthy controls.Smooth density estimate computed with 1d kernel35 using relative expression levels of VRK2 for the following diagnostic categories: schizophrenia (SZ) (n = 201) and healthy controls (CTR) (n = 223).

Figure 3

Table 2 Results from ANOVA pairwise comparisons of VRK2 mRNA level across diagnostic categoriesa

Figure 4

Fig. 3 VRK2 expression quantitative loci.VRK2 expression quantitative loci identified in the total sample (n = 652), using a linear regression model with gender, age and diagnostic category as covariates. Blue dots: VRK2 single nucleotide polymorphisms (SNPs) included in our expression model which are genome-wide significant in the latest Psychiatric Genomics Consortium schizophrenia case–control study (PGC_SCZ52_may13) (www.broadinstitute.org/mpg/ricopili/) at significance level 5.0×10−8. Horizontal line: gene-wide significance threshold for association between 1566 VRK2 SNPs and VRK2 mRNA. This threshold was computed with the aid of matSpD33 taking into account the SNP correlations reflected by sample's LD-structure in the region of interest. The effective number (n = 174) of independent tests was computed using Li's procedure. TSS, transcription start site.

Supplementary material: PDF

Tesli et al. supplementary material

Supplementary Material

Download Tesli et al. supplementary material(PDF)
PDF 2 MB
Submit a response

eLetters

No eLetters have been published for this article.