- Open Access
Association between 5q23.2-located polymorphism of CTXN3 gene (Cortexin 3) and schizophrenia in European-Caucasian males; implications for the aetiology of schizophrenia
Behavioral and Brain Functionsvolume 11, Article number: 10 (2015)
The objective of the study was to examine several polymorphisms in DISC1 and CTNX3 genes as possible risk factors in schizophrenia. DISC1 (disrupted-in-schizophrenia 1) has been studied extensively in relation to mental disease while CTXN3, has only recently emerged as a potential “candidate” gene in schizophrenia. CTXN3 resides in a genomic region (5q21-34) known to be associated with schizophrenia and encodes a protein cortexin 3 which is highly enriched in brain.
We used ethnically homogeneous samples of 175 male patients and 184 male control subjects. All patients were interviewed by two similarly qualified psychiatrists. Controls were interviewed by one of the authors (O.S.). Genotyping was performed, following amplification by polymerase chain reaction (PCR), using fragment analysis in a standard commercial setting (Applied Biosystems, USA).
We have found a statistically significant association between rs6595788 polymorphism of CTXN3 gene and the risk of schizophrenia; the presence of AG genotype increased the risk 1.5-fold. Polymorphisms in DISC1 gene showed only marginally statistically significant association with schizophrenia (rs17817356) or no association whatsoever (rs821597 and rs980989) while two polymorphisms (rs9661837 and rs3737597) were found to be only slightly polymorphic in the samples.
Evidence available in the literature suggests that altered expression of cortexin 3, either alone, or in parallel with changes in DISC1, could subtly perturb GABAergic neurotransmission and/or metabolism of amyloid precursor protein (APP) in developing brain, thus potentially exposing the affected individual to an increased risk of schizophrenia later in life.
There are numerous reports in the literature, including those on genome-wide association studies (GWAS), proposing putative links between particular genes and mental diseases such as schizophrenia. DISC1 (Disrupted-in-Schizophrenia 1) is one such “candidate” gene (reviews: [1,2]) and this is so despite extensive investigations having produced, to date, little evidence for a direct association between any structural changes in DISC1 and a specific disease (review: ). However, the protein which DISC1 encodes (DISC1) is known to be involved in the development of the central nervous system; neural proliferation and migration as well as neurite outgrowth are among the most often cited targets of DISC1 [2,4].
In contrast to DISC1, CTXN3, a three-exon (exons 1a, 1b, 2 and 3) gene spread over a 9.6-kb region of human chromosome 5q23.2, has been known and studied for only a few years [5-8]. In humans, CTXN3 translates into a protein (cortexin 3 also known as KABE: “Kidney And Brain Expressed” protein) which is present mainly in kidney and brain, including foetal brain tissue .
Recently, Panichareon et al.  described an association between two CTXN3 polymorphisms and schizophrenia in a sample of Thai Asian population. This finding is intriguing for a variety of reasons. Panichareon et al.  noted a linkage disequilibrium (albeit a moderate one) between SNP’s in CTXN3 and SLC12A2; both these genes are within the 5q23 region that has been identified as a “locus of vulnerability” or a “candidate region” with respect to genetic risk of schizophrenia [9-11]. Furthermore, genetic studies have associated a gene-interplay between SLC12A2 and DISC1 with an altered risk of schizophrenia . In fact, SLC12A2 has been linked to DISC1, also as a result of in vitro experiments  and following in vivo measurements of hippocampal activity in humans . By analogy with the putative role of DISC1, the above observations can be taken as implying that altered genetics of CTXN3, either individually or in conjunction with changes in DISC1, might represent a significant risk factor in schizophrenia. This conjecture forms the basis for our current hypothesis.
As we have previously carried out several successful case-control association studies between schizophrenia and SNP’s in OPRM1, DRD3, SNAP-25, MTHFR and ADRA2A genes in samples of typical European population [14-16] we decided to use a similar approach to test the present hypothesis and include both CTXN3 and DISC1 gene polymorphisms in our investigation. We now report on the rs6595788 polymorphism of CTXN3 gene and the rs17817356, rs821597, rs9661837, rs980989 and rs3737597 polymorphisms of DISC1 gene and discuss them as possible risk factors for pathophysiology of schizophrenia in a group of male patients and controls. All these polymorphisms have been studied by other authors in associations studies related to psychiatric diseases [17-21].
In order to eliminate from our data possible confounding influence of sex-differences in the aetiology of schizophrenia , we used all-male samples of both patients and controls. The total of 359 males of Czech nationality (Caucasians) entered the study. The group of patients with schizophrenia included 175 males (mean age 35.5 ± 10.9) hospitalized at the Department of Psychiatry, Faculty Hospital, Brno and the Psychiatric Hospital, Jihlava. The patients were diagnosed according to ICD-10 criteria (International Classification of Diseases, 10th Edition) and according to DSM-IV criteria (APA, 1994). All patients underwent structured interviews with qualified psychiatrists (cf. Acknowledgments). Patients with psychiatric comorbidities were excluded from the study.
The control group included 184 males (mean age 48.2 ± 13.8). They were volunteers recruited from blood donors at Blood Bank Brno, patients treated for erectile dysfunction at Trauma Hospital Brno, among employees of private companies in Brno, agriculture farms in the area around Brno, university academics and employees of National Theatre in Brno. The Mini-International Neuropsychiatric Interview (M.I.N.I.) was performed with each member of the control group . Any individuals suspected of not being fully mentally healthy were excluded from the group. In order to minimize personal bias, all screening and interviewing was done by only two psychiatrists with similar backgrounds who closely communicated with each other, or, in the case of control subject, by one of the authors (O.S.) assisted by a qualified psychologist.
All participants, whether they entered as patients or controls, signed an informed consent to participate in the study. Genotypes of the participants were analysed only after the interviews with psychiatrists had been completed. The project was approved by the Ethical Committee of the Faculty Hospital, Brno.
DNA was extracted from 200 mL of EDTA-anticoagulated whole blood using an UltraClean Blood DNA Isolation Kit (Mobio, USA). Six SNPs (rs6595788, rs17817356, rs821597, rs9661837, rs980989 and rs3737597) were assayed using multiplexed polymerase chain reaction (PCR) amplification, followed by single base extension (SNaPshot, Applied Biosystems, USA). The primers used for multiplexed PCR and the SNaPshot method are listed in Table 1. Each multiplex polymerase chain reaction was done in a final volume of 20 mL. The reaction mixture consisted of 2 mL of DNA template (50 ng/mL), 0.2 mM primers (Table 1) and 2 x Kappa 2G FAST Ready Mix (Kappa Biosystems). After initial denaturation at 95°C for 3 min, samples were amplified through 40 cycles (95°C for 10 sec, 60°C for 20 sec with 50% ramp, 72°C for 50 sec), followed by holding at 72°C for 10 min in a Veriti thermal cycler (Applied Biosystems, USA). After purification with PCR ExoSAP (Fermentas, Lithuania), PCR products were mixed and 1 mL of mixture was added to SNaPshot reaction mix (Applied Biosystems, USA) in a total volume of 10 mL. Cycling conditions were set up according to the manufacturer’s instruction manual. After the SNaPshot reaction, SAP (Fermentas, Lithuania) treatment was carried out for 30 min at 37°C. One microliter of each sample was then added to 9 mL of deionized formamide and 0.4 mL of standard size LIZ 120 (Applied Biosystems, USA) before analysis on a 3100 DNA Fragment Analysis System (Applied Biosystems, USA) in a 36 cm capillary array using the POP-7 polymer.
The CSS Statistica software (StatSoft, USA) was used for statistical evaluation of the results. The chi-square test was used for the comparison of genotype frequencies in the studied groups. Odds ratios (OR’s) and 95% confidence intervals (95% CI) as estimates of relative risk for the schizophrenia associated with the genotypes were calculated using logistic regression. To minimize false-positive results potentially caused by multiple testing, we applied the Bonferroni correction for three independent loci genotyped. The level of statistical significance was adjusted to P = 0.008. Hardy-Weinberg equilibrium was tested by chi2 test.
Allele and genotype frequencies of all analysed polymorphisms are displayed in Table 2. Preliminary statistical evaluation indicated no genetic linkages among the studied DISC1 gene polymorphisms (data not shown). We found a statistically significant association between schizophrenia and rs6595788 polymorphism of CTXN3 gene. The frequency of G allele is significantly higher in schizophrenic patients in comparison with control subjects (p = 0.0018). Genotype frequencies are significantly different between patients and controls (p = 0.004). The presence of G allele in the genotype increased the risk of schizophrenia (Odds Ratio = 1.6923; 95% CI of OR = 1.2231 - 2.3414, Risk Ratio = 1.1674; 95 % CI of OR = 1.0602 - 1.2855).
Only a marginal statistically significant difference between patients and controls was noted in rs17817356 polymorphism of DISC1 gene, with AG genotype apparently more frequent in patients (p = 0.01). When analysing rs9661837 polymorphism, we found no GG genotype in either schizophrenics or controls. AG genotype was present in 6 schizophrenic patients and in only one control subject and the statistical significance of difference in allele frequencies (p = 0.06) and in genotype frequencies (p = 0.048) could be considered as marginal at best. For rs9661837 and rs3737597 polymorphisms we did not perform OR and RR analyses because of too low minor allele frequencies. We detected no relationship between schizophrenia and rs821597, rs980989 and rs3737597 polymorphisms of the DISC1 gene.
Genotypic frequency of rs17817356 polymorphism (DISC1) in schizophrenic patients but not in the controls deviated from Hardy-Weinberg equilibrium (p < 0.03). The interaction between rs6595788 and rs17817356 polymorphisms appeared significant, too (p < 0.002); the genotype AGAG having been found to be about 2x more frequent in schizophrenic patients than in control subjects (Table 3). This genotype alone could, therefore, contribute to a higher risk of schizophrenia.
There have been two previous attempts to establish an association between polymorphisms of CTXN3 gene and schizophrenia. One was performed in the United States using brain in vivo imaging as a quantitative trait (QT) enhancement of statistical power in a genome-wide association study (QT-GWAS; ), the other one was a case-control association analysis of a group of Thai Asians . The present study is, therefore, the first one of its kind carried out entirely within Europe on a sample of typical European-Caucasian population . It is also, to date, the largest case-control study, in terms of the number of subjects surveyed, of association between a CTXN3 polymorphism and any mental disease.
Cortexin 3 belongs to “cortexin family” that includes three proteins: cortexin 1, cortexin 2 and cortexin 3. Cortexin 3 displays amino acid sequences very similar (about 43% homology in humans) to those found in a protein cortexin 1 (encoded by CTXN1 gene), previously identified in the cerebral cortex . Human CTXN1 gene is located on the chromosome 19p13.2 and it has 2 exons, CTXN2 with 5 exons is located in 15q21.1 chromosome region (according to recent information from GenBank). Two alternative variants of CTXN3 cDNA sequences differ in the 5′ untranslated region implying a possibility of alternative splicing regulating tissue-specific expression of the gene. Indeed, in silico cloning has indicated that brain and kidney each express own forms of cortexin 3 which differ from one another, particularly in the region encoded by exon 1 . Additional theoretical considerations  indicated that cortexin 3 could be an integral membrane protein involved in extracellular or intracellular signalling.
Using expressed sequence tag (EST) analyses of cDNA libraries, orthologs of cortexin 3 with highly conserved sequences have been identified in mouse, rat, cow, dog, zebrafish, chicken, chimpanzee, Rhesus monkey and frog (; cf. GenBank). Non-human forms of cortexin 3 have species-characteristic tissue distributions but seem to be always enriched in brain. Cortexins 1-3 should not be confused with another “cortexin” (“(r)-cortexin”), a 43 kDa nitric oxide synthase activating protein from kidney, studied mostly in the context of blood pressure regulation and related disorders [26,27]. “Cortexin” may promote growth of neurites  and it has been claimed that it can restore cognition after ischemic stroke .
While we found little or no association between the status of the subjects and polymorphisms in DISC1, in the case of CTXN3, there was a clear, statistically significant, albeit quantitatively modest, link between rs6595788 and schizophrenia. This observation could have implications for the aetiology of schizophrenia, at least for the male form(s) of the disease. What would be the most likely responsible mechanism(s)?
CTXN3 - in analogy to DISC1 - has been shown to interact with SLC12A2 [6,8,10,12,13]. CTXN3 and SLC12A2 genes are located at chromosome 5, in the region that is highlighted as the second most important region linked to the schizophrenia in a meta-analytical study by Lewis et al. . It is also within the region linked to neurocognitive traits associated with higher risk of schizophrenia as reported by Almasy et al. . According to our in silico analysis, both polymorphism described by Panichareon  as associated with the schizophrenia (rs 698172 and rs245178) are located in an intergenic region adjacent to CTXN3 gene that has recently been shown to contain a sequence corresponding to a non-coding RNA of unknown function. The rs6595788 polymorphism, which is a subject of our study, is located directly at 5′-end of CTXN3 gene, its precise locus being at a distance of 16787 bp from the proximate polymorphism studied by Panichareon  (rs698172) found in the intergenic region at the opposite side of the CTXN3 sequence i.e. downstream of 3′-end of the gene.
SLC12A2 encodes a transporter which co-transports Cl-, Na+ and K+ (NKCC1 a.k.a. SLC12A2; solute carrier 12A2). NKCC1 carries Cl- into the cells and is functionally closely linked to the ionotropic GABA receptors (iGABAR’s) which function as Cl--permeable ligand- (GABA-) gated channels. However, the relationship between iGABAR’s and NKCC1 exists mainly in the developing brain tissue, resulting in GABA acting on iGABAR’s as a neuron-depolarizing (i.e. “excitatory”) signalling molecule. In fact, it has been known for some time that, in the developing rat cortex, GABA is released in a controlled, stimulus-coupled, Ca2+-dependent fashion well before the formation of GABAergic synapses , probably as a regulator of neuronal network development . Transition to the adult function of GABA as an inhibitory neurotransmitter occurs when NKCC1 is supplanted by KCC2 (SLC12A5), a transporter that carries Cl- out of the cells thus allowing iGABAR’s to become hyperpolarizing (review: ). It has been suggested that perturbations in the timing of the transition from NKCC1 to KCC2 and the ensuing switch from depolarization to hyperpolarisation could cause subtle structural and functional changes in brain tissue eventually leading to mental disease  (review: ). This could constitute the mechanism for the polymorphisms in the SLC12A2-associated genes DISC1 and CTNX3 to influence the developmental process and contribute to the aetiology of schizophrenia. Moreover, there is a male v. female difference in the developmental timing of the depolarization/hyperpolarization switch . If this difference translates into sex-specific effects on the brain development (and a sex-specific effect on the risk of schizophrenia), our choice of all male population increased homogeneity of the sample and could have significantly improved the statistical power of the present study.
Presence of another potentially relevant mechanism involving cortexin 3 has been indicated by a recent report by Chouraki et al. . They performed a genome-wide association meta-analysis on more than three thousand healthy subjects studying plasma levels of amyloid beta (Aβ) peptides. They established that the plasma levels of Aβ 1-42 were most closely associated with the rs11241936 polymorphism of CTXN3 gene. Subsequent in vitro studies showed that cortexin 3 interfered with amyloid precursor protein (APP) metabolism and decreased the secretion of Aβ-fragments. Involvement of APP and Aβ fragments in Alzheimer's disease is well known (reviews: [37-39]) but their role in the normal brain, particularly during the development, has been given less attention . In fact, APP is present in growth cones and it has a role in the formation of neurites and synaptogenesis . Mice lacking APP displayed dramatically altered brain morphology  possibly as a result of disrupted migration of neural precursor cells in the developing cortex . DISC1 has also been studied in the context of neuronal development and migration and shown to interact with APP  thus providing another biochemical locus where cortexin 3 and DISC1 could act together.
APP has also been shown to influence the expression of NR1, a protein subunit of critical importance in the formation of functional NMDA receptors . Changes in cortexin 3/DISC1/APP interactions could, therefore, result in altered expression and distribution of NMDA receptors as has been observed in schizophrenia  (review: ). Any such relationships are, however, likely to be extremely complex and involve additional genetic (or epigenetic) mechanisms ; their detection may depend on the development and application of new analytical technologies (review: ).
In conclusion, we report a strong association between schizophrenia and a single nucleotide polymorphism in the CTXN3 gene (cortexin 3) in an ethnically homogenous group of male patients. In contrast, we found only weak or no associations between schizophrenia and several polymorphisms in DISC1 gene. Available evidence suggests that cortexin 3 is involved in brain ontogeny, particularly in the development of GABAergic neurotransmission and metabolism of APP which could, in turn, impact on neuronal maturation, migration and synaptogenesis. Taking into account the developmental hypothesis of schizophrenia, we conjecture that any genetic variations in the CTXN3 gene affecting expression and/or characteristic of cortexin 3 protein would have a potential to contribute to the aetiology of complex mental diseases.
Duff BJ, Macritchie KA, Moorhead TW, Lawrie SM, Blackwood DH. Human brain imaging studies of DISC1 in schizophrenia, bipolar disorder and depression: a systematic review. Schizophr Res. 2013;147:1–13.
Lipina TV, Roder JC. Disrupted-in-schizophrenia (DISC1) interactome and mental disorders: impact of mouse models. Neurosci Biobehavior Rev. 2014;45:271–94.
Hikida T, Gamo NJ, Sawa A. DISC1 as a therapeutic target for mental ilnesses. Expert Opin Ther Targets. 2012;16:1151–60.
Young-Pearse TL, Suth S, Luth ES, Sawa A, Selkoe DJ. Biochemical and functional interaction of DISC1 and APP regulates neuronal migration during mammalian cortical development. J Neurosci. 2010;30:10431–40.
Wang HT, Chang JW, Guo Z, Li BG. In silico-initiated cloning and molecular characterization of cortexin 3, a novel human gene specifically expressed in the kidney and brain, and well conserved in vertebrates. Int J Mol Med. 2007;20:501–10.
Panichareon B, Nakayama K, Iwamoto S, Thurakitwannakarn W, Sukhumsirichart W. Association of CTNX-SLC12A2 polymorphisms and schizophrenia in a Thai population. Behav Brain Functions. 2012;8:27.
Potkin SG, Turner JA, Guffanti G, Lakatos A, Fallon JH, Nguyen DD, et al. A genome-wide association study of schizophrenia using brain activation as a quantitative phenotype. Schizophr Bull. 2009;35:96–108.
Potkin SG, Macciardi F, Guffanti G, Wang Q, Turner JA, Lakatos A, et al. Identifying gene regulatory networks in schizophrenia. Neuroimage. 2009;53:839847.
Straub RE, MacLean CJ, O‘Neill FA, Walsh D, Kendler KS. Support for a possible schizophrenia vulnerability locus in region 5q22-31 in Irish families. Mol Psychiatry. 1997;2:148–55.
Lewis CM, Levinson DL, Wise LH, DeLisi LE, Strau RE, Hovatta I, et al. Genome scan meta-analysis of schizophrenia and bipolar disorder, Part II: Schizophrenia. Am J Hum Genet. 2003;73:34–48.
Gladwin TE, Derks EM, Genetic Risk and Outcome of Psychosis (GROUP), Rietschel M, Mattheisen M, Breuer R, et al. Segment-wise genome-wide association analysis identifies a candidate region associated with schizophrenia in three independent samples. PLoS ONE 2. 2012;7:e38828.
Kim JY, Liu CY, Zhang F, Duan X, Wen Z, Song J, et al. Interplay between DISC1 and GABA signalling regulates neurogenesis in mice and risk for schizophrenia. Cell. 2012;148:1051–64.
Callicott JH, Feighery EL, Mattay VS, White MG, Che Q, Baranger DAA, et al. DISC1 and SLC12A2 interaction affects human hippocampal function and connectivity. J Clin Invest. 2013;123:2961–4.
Lochman J, Balcar VJ, Šťastný F, Šerý O. Preliminary evidence for association between schizophrenia and polymorphisms in the regulatory Regions of the ADRA2A, DRD3 and SNAP-25 Genes. Psychiatry Res. 2013;205:7–12.
Lochman J, Plesník J, Janout V, Povová J, Míšek I, Dvořáková D, et al. Interactive effect of MTHFR and ADRA2A gene polymorphisms on pathogenesis of schizophrenia. Neuroendocrinol Lett. 2013;34:792–7.
Šerý O, Přikryl R, Častulík L, Št‘astný F. A118G polymorphism of OPRM1 gene is associated with schizophrenia. J Mol Neurosci. 2010;41:219–22.
Schumacher J, Laje G, Abou Jamra R, Becker T, Mühleisen TW, Vasilescu C, et al. The DISC locus and schizophrenia: evidence from an association study in a central European sample and from a meta-analysis across different European populations. Hum Mol Genet. 2009;18:2719–27.
Schosser A, Gaysina D, Cohen-Woods S, Chow PC, Martucci L, Craddock N, et al. Association of DISC1 and TSNAX genes and affective disorders in the depression case-control (DeCC) and bipolar affective case-control (BACCS) studies. Mol Psychiatry. 2010;15:844–9.
Carless MA, Glahn DC, Johnson MP, Curran JE, Bozaoglu K, Dyer TD, et al. Impact of DISC1 variation on neuroanatomical and neurocognitive phenotypes. Mol Psychiatry. 2011;16:1096–104.
Palo OM, Antila M, Silander K, Hennah W, Kilpinen H, Soronen P, et al. Association of distinct allelic haplotypes of DISC1 with psychotic and bipolar spectrum disorders and with underlying cognitive impairments. Hum Mol Genet. 2007;16:2517–28.
Saetre P, Agartz I, De Franciscis A, Lundmark P, Djurovic S, Kähler A, et al. Association between a disrupted-in-schizophrenia 1 (DISC1) single nucleotide polymorphism and schizophrenia in a combined Scandinavian case-control sample. Schizophr Res. 2008;106:237–41.
Hoenicka J, Garrido E, Ponce G, Rodríguez-Jiménez R, Martínez I, Rubio G, et al. Sexually dimorphic interaction between the DRD1 and COMT genes in schizophrenia. Am J Med Genet B Neuropsychiatr Genet. 2010;153B:948–54.
Lecrubier Y, Sheehan DV, Weiller E, Amorim P, Bonora I, Sheehan K, et al. The Mini International Neuropsychiatric Interview (MINI). A short diagnostic structured interview: Reliability and validity according to the CIDI. Eur Psychiatry. 1997;12:224–31.
Jánošíková B, Zavadáková P, Kožich V. Single-nucleotide polymorphisms in genes relating to homocysteine metabolism: how applicable are public SNP databases to a typical European population? Eur J Hum Genet. 2005;13:86–95.
Coulter PM, Bautista EA, Margulies JE, Watson JB. Identification of cortexin: a novel neuron-specific 82-residue membrane protein enriched in rodent cerebral cortex. J Neurochem. 1993;61:756–9.
Chakraborty S, Khan GA, Karmohapatra SK, Bhattacharaya R, Bhattacharaya G, Kumar Sinha A. Purification and mechanism of action of “cortexin“, a novel antihypertensive protein hormone from kidney and its role in essential hypertension in men. J Amer Soc Hypertens. 2009;3:119–32.
Ghosh R, Bhattacharyya M, Khan G, Chakraborty S, Bhattacharya R, Maji UK, et al. Diagnosis of essential hypertension in humans by the determination of plasma renal cortexin using enzyme-linked immunosorbent assay. Clin Lab. 2013;59:475–81.
Chalisova NI, Khavinson VK. Studies of cytokines in nerve tissue cultures. Neurosci Behav Physiol. 2000;30:261–5.
Evzel‘man MA, Aleksandrova NA. Cognitive disorders and their correction in patients with ischemic stroke. Zh Nevrol Psikhiatr Im S S Korsakova. 2013;113:36–9.
Almasy L, Gur RC, Haack K, Cole SA, Calkins ME, Peralta JM, et al. A genome screen for quantitative trait loci influencing schizophrenia and neurocognitive phenotypes. Am J Psychiatry. 2008;165:1185–92.
Balcar VJ, Dammasch I, Wolff JR. Is there a non-synaptic component in the K+-stimulated release of GABA in the developing rat cortex? Brain Res. 1983;312:309–11.
Wonders CP, Anderson SA. The origin and specification of cortical interneurons. Nat Rev Neurosci. 2006;7:687–96.
Deidda G, Bozarth IF, Cancedda L. Modulation of GABAergic transmission and neurodevelopmental disorders: investigating physiology and pathology to gain therapeutic persepctives. Frontiers Cell Sci. 2012;8:1–23.
Jelitai M, Madarsz E. The role of GABA in the early neuronal development. In: Dirk M, Drossche A, editors. “GABA in Autism and Related Disorders“, vol. 71. 2005. p. 27–62. Ed., Int Review Neurobiol.
Nuñez JL, McCarthy MM. Evidence for an extended duration of GABA-mediated excitation in the developing male v. female hippocampus. Dev Neurobiol. 2007;67:1879–90.
Chouraki V, De Bruijn RF, Chapuis J, Bis JC, Reitz C, Schraen S, et al. A genome-wide association meta-analysis of plasma Aβ peptides concentrations in the elderly. Mol Psychiatry. 2014;19:1326–35.
Šerý O, Povová J, Míšek I, Pešák L, Janout V. Molecular mechanisms of neuropathological changes in Alzheimer’s disease: a review. Folia Neuropathol. 2013;5:1–9.
Armstrong RA. What causes Alzheimer’s disease? Folia Neuropathol. 2013;51:169–88.
Povová J, Ambrož P, Bar M, Pavuková V, Šerý O, Tomášková H, et al. Epidemiological of and risk factors for Alzheimer’s disease. Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub. 2012;156:108–14.
Nalivaeva NN, Turner AJ. The amyloid precursor protein: A biochemical enigma in brain development, function and disease. FEBS Lett. 2013;587:2046–54.
Priller C, Bauer T, Mittereger G, Krebs B, Kretzschamr HA, Herms J. Synapse formation and function is modulated by the amyloid precursor protein. J Neurosci. 2006;26:7217–21.
Arliker B, Müller U. The functions of mammalian amyloid precursor protein and related amyloid precursor-like proteins. Neurodegenerative Dis. 2006;3:239–46.
Young-Pearse TL, Bai J, Chang R, LoTurco JJ, Selkoe DJ. A critical function for beta-amyloid precursor protein in neuronal migration revealed by in utero RNA interference. J Neurosci. 2007;27:14459–69.
Cousins SL, Hoey SEA, Stephenson FA, Perkington MS. Amyloid precursor protein associates with assabled NR2A- and NR2B-containing NMDA receptors to result in the enhancement of their cell surface delivery. J Neurochem. 2009;111:1501–13.
Vrajová M, Štastný F, Horáček J, Lochman J, Šerý O, Peková S, et al. Expression of the hippocampal NMDA receptor GluN1 subunit and its splicing isoforms in schizophrenia: postmortem study. Neurochem Res. 2010;35:994–1002.
Hall J, Trent S, Thomas KL, O’Donovan MC, Owen MJ. Genetic risk for schizophrenia: Convergence on synaptic pathways involved in plasticity. Biol Psych 2014, In press
Šerý O, Povová J, Balcar VJ. Perspectives in genetic prediction of Alzheimer’s disease. Neuroendocrinol Lett. 2014;35:101–8.
We would like to acknowledge Dr. Radovan Přikryl and Dr. Dagmar Dvořáková for their assistance in screening and interviewing the subjects. This work has been supported by the Internal grant agency of the Ministry of Health of the Czech Republic (IGA MZCR) No. NT/14504-3.
The authors declare that they have no competing interests with respect to the authorship and/or publication of this article.
OS designed the study, interviewed controls subjects, supervised the genotyping, performed statistical evaluation of the data and drafted the manuscript; JL and JPlesník performed DNA isolation and analysis; JPovová and VJ initiated the study, helped with its design and supervised selection of participants; VJB contributed to the interpretation of data in the context of developmental and synaptic neurochemistry and helped to prepare the final draft of the manuscript. All authors read and approved the final manuscript.