A promoter polymorphism in the monoamine oxidase A gene and its relationships to monoamine metabolite concentrations in CSF of healthy volunteers

Journal of Psychiatric Research 34 (2000) 239±244

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A promoter polymorphism in the monoamine oxidase A gene and its relationships to monoamine metabolite concentrations in p CSF of healthy volunteers Erik G. JoÈnsson a,*, Nadine Norton b, J. Petter Gustavsson c, Lars Oreland d, Michael J. Owen b, GoÈran C. Sedvall a a

Department of Clinical Neuroscience, Psychiatry Section, Karolinska Institute, SE-171 76 Stockholm, Sweden b Department of Psychological Medicine, University of Wales College of Medicine, Heath Park, Cardi€, UK c Department of Health Sciences, University of SkoÈvde, SkoÈvde, Sweden d Department of Neuroscience, Section of Pharmacology, University of Uppsala, Uppsala, Sweden Received 4 November 1999; received in revised form 15 February 2000; accepted 23 March 2000

Abstract Concentrations of monoamine metabolites (MM) in lumbar cerebrospinal ¯uid (CSF) have been used extensively as indirect estimates of monoamine turnover in the brain. We investigated possible relationships between a putative functional promoter polymorphism in the monoamine oxidase A (MAOA) gene and CSF concentrations of homovanillic acid (HVA), 5hydroxyindoleacetic acid (5-HIAA), and 3-methoxy-4-hydroxyphenylglycol (MHPG) in healthy volunteers (n = 88). Among women (n = 37), those carrying at least one copy of the alleles associated with more ecient transcription displayed higher concentrations of HVA ( p = 0.01) and 5-HIAA ( p = 0.01). In men (n = 51), however, there was a tendency in the opposite direction. The results suggest that MAOA genotypes may participate di€erentially in the regulation of dopamine and serotonin turnover rates under presumed steady state in the central nervous system. The results should be interpreted with caution until replicated because of the limited sample size. 7 2000 Elsevier Science Ltd. All rights reserved. Keywords: Monoamine oxidase A gene; Monoamine metabolites (HVA; 5-HIAA; MHPG); Cerebrospinal ¯uid

1. Introduction Concentrations of the major monoamine metabolites (MM) 5-hydroxyindoleacetic acid (5-HIAA), homovanillic acid (HVA), and 3-methoxy-4-hydroxyphenylglycol (MHPG) in lumbar cerebrospinal ¯uid (CSF) have been used extensively as indirect measures of monoamine metabolism and turnover in the brain of humans. Studies of human twins indicate that CSF 5Part of this investigation has been presented at the 7th World Congress on Psychiatric Genetics, Monterrey, California, October 14±18, 1999. * Corresponding author. Tel.: +46-8-51772626; fax: +46-8346563. E-mail address: [email protected] (E.G. JoÈnsson). p

HIAA and HVA levels are under familial in¯uence of both genetic and environmental origin, while MHPG is under major genetic in¯uence (Oxenstierna et al., 1986). In rhesus monkeys signi®cant portions of CSF 5-HIAA, the major serotonin metabolite, HVA, the major dopamine metabolite, and MHPG, the major norepinephrine metabolite in the central nervous system, have been shown to be determined by genetic mechanisms (Higley et al., 1993). Monoamine oxidase (E.C. 1.4.3.4) is a mitochondrial enzyme involved in the degradation of biogenic amines including dopamine, serotonin, and norepinephrine. In humans two isozymes exist: monoamine oxidase A (MAOA), which preferentially deaminates serotonin and norepinephrine, and monoamine oxidase B (MAOB) catalyzing degradation of phenylethylamines and benzylamine

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(Bach et al., 1988; Cawthon et al., 1981; Donnelly and Murphy, 1977). With regard to dopamine, at least in man, both isoenzymes participate with some preponderance of MAOB (StenstroÈm et al., 1987). This makes both the MAO genes, located on chromosome Xp11.23±Xp11.4 (Kochersperger et al., 1986; Lan et al., 1989; Levy et al., 1989; Ozelius et al., 1988; Pintar et al., 1981), of interest in studies of mechanisms for regulation of monoamine turnover and metabolism. Recently a MAOA promoter variable number tandem repeat (VNTR) polymorphism has been reported (Deckert et al., 1999; Sabol et al., 1998). This VNTR consists of exact repeats of a 30-bp sequence. Two to ®ve exact repeats have been reported. Also, the four complete repeats are followed by a half repeat consisting of the ®rst 15 bp of the repeated motif, giving the following repeat nr: 2, 3, 3.5, 4, and 5. In transfection experiments both Deckert et al.(1999) and Sabol et al.(1998) have shown that alleles with 3.5 and 4 copies are transcribed more eciently than those with 3 copies. In the present study we have examined this MAOA VNTR polymorphism for possible relationships to concentrations of 5-HIAA, HVA, and MHPG in lumbar CSF from healthy Swedish volunteers. 2. Methods 2.1. Healthy human volunteers The investigation was carried out in accordance with the Declaration of Helsinki. The study was approved by the Ethics Committee of the Karolinska Hospital, Stockholm. Informed consent of the subjects was obtained after the nature of the procedures had been fully explained. The characteristics and assessment of the majority of subjects (n = 66) participating in the present study have previously been described (JoÈnsson et al., 1996). In this study another 22 Caucasian individuals were added. Of these subjects 16 were initially drawn from a population register from Stockholm county council to take part in a study regarding CSF circulation including lumbar puncture (Oxenstierna et al., 1996). Otherwise these subjects were assessed in a similar way as the original 66 individuals, who were recruited predominantly among students or hospital sta€. Lumbar puncture (LP) was performed in all subjects. Height was also recorded. Back length, de®ned as the distance between the external occipital protuberance and the insertion point of the lumbar needle with the subject in the lying position, was measured in 63 subjects. Eight to 19 years later a structured interview was performed by a psychiatrist (EJ) to assess psychiatric morbidity (DSM-III-R; American Psychiatric Association, 1987), somatic illness and presence of mental and nervous

system disorders among relatives. Subjects completed a questionnaire regarding smoking habits. Hospital records were obtained and examined for diagnosis. Genealogical data for antecedents up to the third degree were obtained from parish registers to assess the origin of the individuals. Subjects who reported any life time psychiatric disorder were excluded. Of the subjects 51 were men and 37 women. The age range at the time of the present study was 29±56 years, with a mean of 41 years. The mean age at LP was 27 years, age range 19±43. Thirty six were university graduates. Twenty one subjects had a family history of major mental illness de®ned as at least one ®rst or second degree relative with schizophrenia, schizoa€ective disorder, bipolar disorder, recurrent unipolar disorder, other non-organic psychosis, or who had committed suicide. Of the subjects 53 were or had been regular tobacco users, 18 were non smokers or had only used tobacco once or a few times in their life, while data were missing for 11 individuals. Of the women, 15 used oral contraceptives at LP, 20 did not, while data were missing for two individuals. Except for oral contraceptives all participants were drug free at LP. Genealogical data implicated that 89 and 5% of the genes originated in ancestors born in Sweden and Finland, respectively, and the remaining 6% were distributed over eight European countries. 2.2. CSF MM concentrations All subjects had at least 8 h of bed rest in the hospital, abstaining from food and smoking. CSF samples were obtained by LP between 8 and 9 a.m.with the subjects in the sitting (n = 41) or recumbent (n = 47) position. Samples of 12.5 ml CSF were drawn according to a standardized sampling procedure (Sedvall et al., 1980). Samples were stored at below ÿ208C and analyzed within 2 months. HVA, 5-HIAA, and MHPG concentrations were measured by mass fragmentography with deuterium labelled internal standards (Swahn et al., 1976). 2.3. Genotype analyses Venous blood was taken from all individuals into EDTA-containing tubes. DNA was isolated as previously described (Geijer et al., 1994). The 186±276 bp fragments containing the MAOA VNTR were ampli®ed using the following primers: forward ¯uorescently labelled 5'-GCC CAG GCT GCT CCA GAA A-3 ' and reverse 5 '-GAA CGG ACG CTC CAT TCG GA-3'. The PCR conditions were as follows: 200 mM dNTPs, 1  Taq Gold PCR bu€er II (Perkin Elmer), 2.5 mM Mg, 1 unit Taq Gold (Perkin Elmer), and 48 ng DNA, with an initial denaturating

E.G. JoÈnsson et al. / Journal of Psychiatric Research 34 (2000) 239±244

period at 958C for 10 min, followed by 35 cycles of 95 (45 sec), 62 (45 sec), and 628C (10 min). The PCR products were electrophoresed on 10% denaturing polyacrylamide gels on an ABI 373 DNA sequencer, and analysed using the ABI GENESCAN and GENOTYPER software. 2.4. Data analysis Subjects were grouped into those with or without 3.5/4 alleles, respectively, because the MAOA alleles containing 3.5 and 4 alleles have been shown to induce a more e€ective transcription than other alleles (Sabol et al., 1998). In a previous study, of the majority of the present sample, back length was found to be a signi®cant confounding variable for MM concentrations in CSF (JoÈnsson et al., 1996). To make it possible to correct MM for back length, back length values, based on the relationship between back length and height (r = 0.73, p < 0.0001), were constructed for those where only height had been measured (n = 26). Analysis of covariance (ANCOVA) was used to adjust for di€erences in CSF levels due to back length. Because correcting MM concentrations for back length is still controversial (JoÈnsson et al., 1997), analyses were also performed with MM data uncorrected for back length. Analysis of variance (ANOVA) was used. Signi®cance level was de®ned as a p-value less than 0.05. Because of the exploratory nature of the investigation, no corrections were made for multiple comparisons. However, the reader is reminded of the increased potential for type I errors due to the large number of analyses performed (Grove and Andreasen, 1982). 3. Results The results shown in Table 1 demonstrate the stat-

241

istical data analysis performed on MM residuals corrected and uncorrected for back length. MM means and standard deviations (SD) are presented as uncorrected values. Four di€erent alleles were detected in the present sample. In one women an allele with only two repeats was found. The allele frequencies were 0.01 (2 repeats), 0.31 (3 repeats), 0.02 (3.5 repeats), and 0.66 (4 repeats), respectively. Among men the allele frequencies were 0.22 (3 repeats), 0.02 (3.5 repeats), and 0.77 (4 repeats), respectively. In women the allele frequencies were 0.01 (2 repeats), 0.38 (3 repeats), 0.03 (3.5 repeats), and 0.58 (4 repeats), respectively, distributed on the following genotypes: 2/3 (3%), 3/3 (11%), 3/3.5 (3%), 3/4 (49%), 3.5/4 (3%), and 4/4 (32%). As the MAOA gene is located on the X chromosome, each gender was analysed separately. In women a relationship was indicated between the MAOA polymorphism and HVA-levels (F = 5.22, d.f.=1, p = 0.029 and F = 6.65, p = 0.015 uncorrected and corrected for back length, respectively). Women with genotypes including the 3.5 or 4 repeat alleles had higher HVA concentrations than women without these alleles. A similar relationship was obtained when the female subjects were analyzed for MAOA genotypes with regard to 5-HIAA levels. Women with genotypes including 3.5 or 4 repeat alleles displayed higher 5HIAA levels than those without these alleles (F = 7.47, d.f.=1, p = 0.010 and F = 7.31, p = 0.011 uncorrected and corrected for back length, respectively). However, no relationship was found in women between the MAOA polymorphism and MHPG levels. Women were also grouped into subjects only carrying alleles suggested to give rise to high transcription (genotypes 3.5/4 and 4/4), low transcription (2/3, 3/3), or subjects carrying both these types of alleles (3/3.5, 3/ 4). When compared vs CSF MMs the following results

Table 1 Comparisons (ANOVA) between monoamine oxidase A (MAOA) genotypes and homovanillic acid (HVA), 5-hydroxyindoleacetic acid (5HIAA), and 3-methoxy-4-hydroxyphenylglycol (MHPG) concentrations in lumbar cerebrospinal ¯uid of healthy volunteers HVA

5-HIAA

MHPG

Sex

Allele

n

Mean2SD (nmol/L)

Fa pa

Fb pb

Mean2SD (nmol/L)

Fa pa

Fb pb

Mean2SD (nmol/L)

Fa pa

Fb pb

Men

3.5/4 Other Genotype 3.5/4c Other 3.5/4+4/4 3/3.5+3/4 2/3+3/3

40 11

154261 208290

F = 3.43 p = 0.070

F = 5.33 p = 0.025

89235 108240

F = 1.04 p = 0.313

F = 2.47 p = 0.122

4227 4629

F = 0.85 p = 0.361

F = 1.54 p = 0.221

32 5 13 19 5

209272 133245 192253 221282 133245

F = 6.65 p = 0.015 F = 3.75 p = 0.034

F = 5.22 p = 0.029 F = 3.32 p = 0.048

113235 68215 106233 117237 68215

F = 7.31 p = 0.011 F = 4.14 p = 0.025

F = 7.47 p = 0.010 F = 4.21 p = 0.023

4226 3722 4126 4226 3722

F = 2.57 p = 0.118 F = 1.42 p = 0.256

F = 2.58 p = 0.117 F = 1.46 p = 0.246

Women Women

a

Statistical comparisons corrected for back length. Statistical comparisons uncorrected for back length. c Genotypes containing alleles 3.5 and/or 4.

b

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emerged: CSF HVA (F = 3.32, d.f.=2, p = 0.048 and F = 3.75, p = 0.034 uncorrected and corrected for backlength, respectively), CSF 5-HIAA (F = 4.21, d.f.=2, p = 0.023 and F = 4.14, p = 0.025 uncorrected and corrected for backlength, respectively), and MHPG (F = 1.46, d.f.=2, p = 0.246 and F = 1.42, p=0.256 uncorrected and corrected for backlength, respectively). Without correction for back length there was a relationship in men (F = 5.33, d.f.=1, p = 0.025) with lower CSF HVA-levels in subjects with the 3.5 or 4 repeat alleles as compared to those lacking these alleles. However, after correction for back length this relationship was reduced to a trend (F = 3.43, p = 0.070). No relationships was found in men between the MAOA polymorphism and CSF 5-HIAA and MHPG concentrations, respectively. 4. Discussion To our knowledge the present publication is the ®rst comparing MAOA genotypes and lumbar CSF MM in healthy human subjects. In women, relationships were found between MAOA genotypes and CSF concentrations of HVA and 5-HIAA. Women with genotypes containing alleles with 3.5 and/or 4 repeats, reported to induce a more e€ective monoamine oxidase transcription (Deckert et al., 1999; Sabol et al., 1998), were found to have higher levels of HVA and 5-HIAA. A similar tendency was also found with regard to MHPG in women, although this di€erence was not signi®cant. It would seem reasonable that a higher amount of a converting enzyme may contribute to higher levels of a resulting degradation product and, furthermore, treatment with an MAOA inhibitor results in a decrease in CSF levels of monoamine transmitter metabolites (Major et al., 1979). The experiments by Sabol et al. (1998) showed that the MAOA activities di€ered considerably when the di€erent MAOA gene promoter VNTR alleles were transfected to cell lines. Post mortem studies on human brain tissues, on the other hand, indicate that variation in MAOA activity is remarkably low (Fowler et al., 1980). Thus, it remains to be shown that the present MAOA gene polymorphism is associated with variation in enzyme activity in vivo. In men no signi®cant relationships emerged, although a trend in the opposite direction as compared to women was found between MAOA alleles and HVA levels. This may indicate that there are marked di€erences between men and women with regard to the strength of these relationships. There have been reports of gender di€erences with regard to CSF monoamine metabolites (Blennow et al., 1993; Constantino and Murphy, 1996; Nordin et al., 1995). If there is a real di€erence between men and

women with regard to the relationships between MAOA genotypes and monoamine metabolite levels this may indicate certain confounding factors which di€er between the sexes. In¯uence of steroids has been discussed as one such potential confounder (Best et al., 1992; JoÈnsson et al., 1997). Interstingly, in the present sample female users of contraceptives had signi®cantly lower CSF-levels of 5-HIAA (t = 2.40, d.f.=33, p = 0.023) and MHPG (t = 2.25, d.f.=33, p = 0.031) than non-users. These di€erences were not signi®cantly in¯uenced by back length (data not shown). Similar di€erences with regard to CSF MHPG, but not 5HIAA levels have previously been reported (Eklundh et al., 1994; TraÈskman-Bendz, 1980). However, we did not ®nd any MAOA genotype di€erence between users and non-users of contraceptives (Fisher's exact test p = 0.141) indicating that the relationships between MAOA genotypes and monoamine metabolite levels are not signi®cantly in¯uenced by the use of contraceptives. Tobacco use has been suggested to signi®cantly in¯uence CSF HVA (Geracioti Jr et al., 1999) and also to considerably inhibit the activity of monoamine oxidase (Fowler et al., 1996a,b). In the present sample, however, no signi®cant di€erences were found when use or non-use of tobacco were compared vs MAOA allele/genotype constalletions or levels of HVA, 5HIAA, or MHPG in each sex separately or with the two sexes combined, respectively (data not shown). This result, together with the previously reported small variation in enzyme activity in post mortem brain tissue (Fowler et al., 1980), may indicate that the associations found are not the result of a direct cause relationship. An alternative explanation would be that the in¯uence of the di€erent MAOA alleles on the expression of enzyme activity during prenatal development will induce life-long e€ects on brain monoamine systems, similar to those induced in rats by prenatal MAOA inhibition (Whitaker-Azmitia et al., 1994). The signi®cant CSF HVA and 5-HIAA di€erences with regard to MAOA genotypes in the present study may be chance ®ndings. The sample size is limited. Also considering the many variables tested, type I errors can be expected to emerge. There were six primarily independent investigations performed (genotypes of one polymorphism vs concentrations of three monoamine metabolites in two sexes) in the total sample. This gives a p-value of less than 0.008 to be considered signi®cant using Bonferroni's correction. Thus, applying this correction in the total sample no relationship would remain signi®cant. This means that until the present results are replicated in independent investigations, they must be regarded as preliminary and should be interpreted with caution. Dopamine, serotonin and norepinephrine transmission have been implicated in a€ective disorder and

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schizophrenia (Potter and Manji, 1994; van Kammen and Antelman, 1984; van Rossum, 1967; Woolley and Shaw, 1954). The present tentative ®ndings indicate that MAOA genotypes participate di€erentially in the regulation of dopaminergic and serotonergic transmission in the central nervous system. Therefore, the variables recorded can be regarded as valid parameters to examine for changes in these psychiatric disorders. The present results do not favour a di€erential in¯uence of MAOA gene activities on MHPG concentrations in lumbar CSF. Acknowledgements This study was supported by grants from the Swedish Medical Research Council (03560), the National Institute of Mental Health (44814), the Medical Research Council (UK), and the SoÈderstroÈm-KoÈnigska Foundation. We thank Kjerstin Lind and Alexandra Tylec, Department of Clinical Neuroscience, Karolinska Hospital for technical assistance. References American Psychiatric Association. Diagnostic and statistical manual of mental disorders. 3rd ed. Washington DC: American Psychiatric Association, 1987 revised. Bach AW, Lan NC, Johnson DL, Abell CW, Bembenek ME, Kwan SW, Seeburg PH, Shih JC. cDNA cloning of human liver monoamine oxidase A and B: molecular basis of di€erences in enzymatic properties. Proceedings of the National Academy of Sciences of the United States of America 1988;85:4934±8. Best NR, Rees MP, Barlow DH, Cowen PJ. E€ect of estradiol implant on noradrenergic function and mood in menopausal subjects. Psychoneuroendocrinology 1992;17:87±93. Blennow K, Wallin A, Gottfries CG, Karlsson I, MaÊnsson JE, Skoog I, WikkelsoÈ C, Svennerholm L. Cerebrospinal ¯uid monoamine metabolites in 114 healthy individuals. Eur Neuropsychopharmacology 1993;3:55±61. Cawthon RM, Printar JE, Haseltine FP, Breake®eld XO. Di€erences in the structure of A and B forms of human monoamine oxidase. Journal of Neurochemistry 1981;37:363±72. Constantino JN, Murphy DL. Monoamine metabolites in `leftover' newborn human cerebrospinal ¯uid. A potential resource for biobehavioral research. Psychiatry Research 1996;65:129±42. Deckert J, Catalano M, Syagailo YV, Bosi M, Okladnova O, Di Bella D, NoÈthen MM, Ma€ei P, Franke P, Fritze J, Maier W, Propping P, Beckmann H, Bellodi L, Lesch KP. Excess of high activity monoamine oxidase A gene promoter alleles in female patients with panic disorder. Human Molecular Genetics 1999;8:621±4. Donnelly CH, Murphy DL. Substrate and inhibitor-related characteristics of human platelet monoamine oxidase. Biochemical Pharmacology 1977;26:853±8. Eklundh T, FernstroÈm V, Nordin C. In¯uence of tapping time and atmospheric pressure on concentrations of monoamine metabolites in the cerebrospinal ¯uid: a prospective study in female volunteers. Journal of Psychiatric Research 1994;28:511±7. Fowler CJ, Wiberg AÊ, Oreland L, Marcusson J, Winblad B. The e€ect of age on the activity and molecular properties of human

243

brain monoamine oxidase. Journal of Neural Transmission 1980;49:1±20. Fowler JS, Volkow ND, Wang GJ, Pappas N, Logan J, MacGregor R, Alexo€ D, Shea C, Schlyer D, Wolf AP, Warner D, Zezulkova I, Cilento R. Inhibition of monoamine oxidase B in the brains of smokers. Nature 1996a;379:733±6. Fowler JS, Volkow ND, Wang GJ, Pappas N, Logan J, Shea C, Alexo€ D, MacGregor RR, Schlyer DJ, Zezulkova I, Wolf AP. Brain monoamine oxidase A inhibition in cigarette smokers. Proceedings of the National Academy of Sciences of the United States of America 1996b;93:14065±9. Geijer T, Neiman J, Rydberg U, Gyllander A, JoÈnsson E, Sedvall G, Valverius P, Terenius L. Dopamine D2 receptor gene polymorphisms in Scandinavian chronic alcoholics. European Archives of Psychiatry and Clinical Neuroscience 1994;244:26±32. Geracioti Jr TD, West SA, Baker DG, Hill KK, Ekhator NN, Wortman MD, Keck PE, Norman AB. Low CSF concentration of a dopamine metabolite in tobacco smokers. American Journal of Psychiatry 1999;156:130±2. Grove WM, Andreasen N. Simultaneous tests of many hypotheses in exploratory research. Journal of Nervous and Mental Disease 1982;170:3±8. Higley JD, Thompson WW, Champoux M, Goldman D, Hasert MF, Kraemer GW, Scanlan JM, Suomi SJ, Linnoila M. Paternal and maternal genetic and environmental contributions to cerebrospinal ¯uid monoamine metabolites in rhesus monkeys (Macaca mulatta ). Archives of General Psychiatry 1993;50:615± 23. JoÈnsson E, Sedvall G, Brene S, Gustavsson JP, Geijer T, Terenius L, Crocq M-A, Lannfelt L, Tylec A, Sokolo€ P, Schwartz JC, Wiesel F-A. Dopamine-related genes and their relationships to monoamine metabolites in CSF. Biological Psychiatry 1996;40:1032±43. JoÈnsson EG, Goldman D, Spurlock G, Gustavsson JP, Nielsen DA, Linnoila M, Owen MJ, Sedvall GC. Tryptophan hydroxylase and catechol-O-methyltransferase gene polymorphisms. Relationships to monoamine metabolite concentrations in CSF of healthy volunteers. European Archives of Psychiatry and Clinical Neuroscience 1997;247:297±302. Kochersperger LM, Parker EL, Siciliano M, Darlington GJ, Denney RM. Assignment of genes for human monoamine oxidases A and B to the X chromosome. Journal of Neuroscience Research 1986;16:601±16. Lan NC, Heinzmann C, Gal A, Klisak I, Orth U, Lai E, Grimsby J, Sparkes RS, Mohandas T, Shih JC. Human monoamine oxidase A and B genes map to Xp11.23 and are deleted in a patient with Norrie disease. Genomics 1989;4:552±9. Levy ER, Powell JF, Buckle VJ, Hsu YP, Brake®eld XO, Craig IW. Localization of human monoamine oxidase A gene to Xp11.2311.4 by in situ hybridization: implications for Norrie disease. Genomics 1989;5:368±70. Major LF, Murphy DL, Lipper S, Gordon E. E€ects of clorgyline and pargyline on deaminated metabolites of norepinephrine, dopamine and serotonin in human cerebrospinal ¯uid. Journal of Neurochemistry 1979;32:229±31. Nordin C, Eklundh T, FernstroÈm V, Swedin A, Zachau AC. Gradients of CSF monoamine metabolites: a comparison between male and female volunteers. Journal of Psychiatric Research 1995;29:133±40. Oxenstierna G, Bergstrand G, Edman G, Flyckt L, NybaÈck H, Sedvall G. Increased frequency of abberant CSF circulation in schizophrenic patients compared to healthy volunteers. European Psychiatry 1996;11:16±20. Oxenstierna G, Edman G, Iselius L, Oreland L, Ross SB, Sedvall G. Concentrations of monoamine metabolites in the cerebrospinal ¯uid of twins and unrelated individuals Ð a genetic study. Journal of Psychiatric Research 1986;20:19±29.

244

E.G. JoÈnsson et al. / Journal of Psychiatric Research 34 (2000) 239±244

Ozelius L, Hsu YP, Bruns G, Powell JF, Chen S, Weyler W, Utterback M, Zucker D, Haines J, Trofatter JA, et al. Human monoamine oxidase gene (MAOA): chromosome position (Xp21± Xp11) and DNA polymorphism. Genomics 1988;3:53±8. Pintar JE, Barbosa J, Francke U, Castligione CM, Hawkins Jr M, Breake®eld XO. Gene for monoamine oxidase type A assigned to the human X chromosome. Journal of Neuroscience 1981;1:166± 75. Potter WZ, Manji HK. Catecholamines in depression: an update. Clinical Chemistry 1994;40:279±87. Sabol SZ, Hu S, Hamer D. A functional polymorphism in the monoamine oxidase A gene promoter. Human Genetics 1998;103:273± 9. Sedvall G, FyroÈ B, Gullberg B, NybaÈck H, Wiesel F-A, WodeHelgodt B. Relationships in healthy volunteers between concentrations of monoamine metabolites in cerebrospinal ¯uid and family history of psychiatric morbidity. British Journal of Psychiatry 1980;136:366±74. StenstroÈm A, Hardy J, Oreland L. Intra- and extra-dopamine-synaptosomal localization of monoamine oxidase in striatal homogenates from four species. Biochemical Pharmacology 1987;36:2931±5.

Swahn C-G, SandgaÈrde B, Wiesel F-A, Sedvall G. Simultaneous determination of the three major monoamine metabolites in brain tissue and body ¯uids by a mass fragmentographic method. Psychopharmacology 1976;48:147±52. TraÈskman-Bendz L. Depression and suicidal behavior. Thesis. Stockholm: Karolinska Institute, 1980. van Kammen DP, Antelman S. Impaired noradrenergic transmission in schizophrenia? Life Sciences 1984;34:1403±13. van Rossum JM. The signi®cance of dopamine-receptor blockade for the action of neuroleptic drugs. In: Brill H, Cole JO, Deniker P, Hippius H, Bradley PB, editors. Proceedings of the ®fth Collegium Internationale Neuropsychopharmacologicum. Amsterdam: Excerpta Medica, 1967. p. 321±9. Whitaker-Azmitia PM, Zhang X, Clarke C. E€ects of gestational exposure to monoamine oxidase inhibitors in rats: preliminary behavioral and neurochemical studies. Neuropsychopharmacology 1994;11:125±32. Woolley DW, Shaw E. A biochemical and pharmacological suggestion about certain mental disorders. Proceedings of the National Academy of Sciences of the United States of America 1954;40:228±31.