Multiple missense mutations in the diazepam binding inhibitor (DBI) gene identified in schizophrenia but lack of disease association.

The diazepam binding inhibitor (DBI), alternatively known as the acyl-CoA binding protein (ACBP), is involved in multiple biological actions. The polypeptide binds to the peripheral, or mitochondrial, benzodiazepine receptor and facilitates transport of cholesterol to the inner membrane to stimulate steroid synthesis. Through this action, DBI indirectly modulates gamma-aminobutyric acid (GABA)-mediated inhibitory neurotransmission. DBI can be postulated as a candidate gene for psychiatric phenotypes including anxiety, mood, and psychotic disorders. In an examination of the DBI gene among 112 individuals with schizophrenia, our laboratory has identified 18 novel single nucleotide polymorphisms (SNPs), including three missense changes in conserved amino acids, a coding region microdeletion, and multiple SNPs in the putative promoter region. Case-control association analyses were performed for the missense changes, but none was found to be significantly associated with disease.

Systematic screening for mutations in the glycine receptor alpha2 subunit gene (GLRA2) in patients with schizophrenia and other psychiatric diseases.

The glycine receptor, which is a member of the ligand-gated ion channel superfamily, mediates synaptic inhibition in the spinal cord and other brain regions. This superfamily has been implicated in the pathogenesis of schizophrenia and other psychiatric diseases. The complete coding sequence and splice junctions of the GLRA2 gene were scanned by DOVAM-S, a form of SSCP analysis with sufficient redundancy to detect virtually all mutations. Those analyses were performed in 113 patients with schizophrenia, and in pilot studies of patients with bipolar illness, alcoholism, puerperal psychosis, autism, and attention-deficit hyperactivity disorder (533 kb total scanned sequences). We detected three sequence changes in the coding region, all resulting in silent mutations: C894T in exon 5, C1134T in exon 7, and C1476T in exon 9. These do not alter the structure or the expression of the protein. It is unlikely that mutations in the coding region and splice junction of GLRA2 gene are associated with schizophrenia and other psychiatric diseases.

Scanning of estrogen receptor alpha (ERalpha) and thyroid hormone receptor alpha (TRalpha) genes in patients with psychiatric diseases: four missense mutations identified in ERalpha gene.

Estrogen and thyroid hormones exert effects on growth, development, and differentiation of the nervous system. Hormone administration can lead to changes in behavior, suggesting that genetic variants of the estrogen receptor alpha (ERalpha) and the thyroid hormone receptor alpha (TRalpha) genes may predispose to psychiatric diseases. To investigate this possibility, regions of likely functional significance (all coding exons and flanking splice junctions) of the ERalpha and TRalpha genes were scanned in patients with schizophrenia (113), along with pilot studies in patients with bipolar illness (BPI), puerperal psychosis, autism, attention-deficit hyperactivity disorder (ADHD), and alcoholism. A total of 1.18 megabases of the ERalpha gene and 1.16 megabases of the TRalpha gene were scanned with Detection of Virtually All Mutations-SSCP (DOVAM-S), a method that detects virtually all mutations. Four missense mutations, seven silent mutations and one deletion were identified in the ERalpha gene, while only four silent mutations were present in the TRalpha gene. Two of the missense mutations in ERalpha are conserved in the six available mammalian and bird species (H6Y, K299R) and a third sequence variant (P146Q) is conserved in mammals, birds, and Xenopus laevis, hinting that these sequence changes will be of functional significance. These changes were found in one patient each with BPI, puerperal psychosis, and alcoholism, respectively. Analysis of the ERalpha and TRalpha genes in 240 subjects reveals that missense changes and splice site variants are uncommon (1.7% and 0%, respectively). Further analyses are necessary to determine if the missense mutations identified in this study are associated with predisposition or outcome for either psychiatric or nonpsychiatric diseases.

An in-frame deletion in the alpha(2C) adrenergic receptor is common in African--Americans.

alpha(2) adrenergic receptors are activated by adrenaline and noradrenaline, and three subtypes (ie, A, B, C) have differential affinities for antagonists and medications. The alpha(2c) adrenergic receptor (ADRA2C), located on chromosome 4p16.3, is a candidate gene for schizophrenia because it binds clozapine, an atypical neuroleptic useful for treatment-resistant schizophrenia. In addition, ADRA2C binds clonidine which is prescribed for three psychiatric diseases. This report communicates the findings of the genetic scanning of this gene of very tough GC content. The complete coding sequences and splice junctions were scanned with [DOVAM]-S in 104 schizophrenics, and pilot probes of patients with alcoholism (41 patients), cocaine abuse (25 patients), puerperal psychosis (30 patients), attention deficient/hyperactivity disorder (25 patients) and autism (25 patients). Six sequence variants were found, including five silent polymorphisms (allele frequencies 0.6--25%) and an in-frame deletion of a homologous repeat at nucleotides 967--978 (ie, TIDRU(1)). Genotyping of the normal two repeat unit of the Third Intracytoplasmic Domain Repeat Unit (TIDRU(2)) and the deleted variant (TIDRU(1)) revealed that TIDRU(1) had allelic frequencies of 39% (11/28) and 3.5% (6/172) in African-American and Caucasian schizophrenics, respectively, and it occurred with equal frequency in controls (44%, 31/70 and 3.0%, 6/198). TIDRU(1) occurs at a location similar to the third intracytoplasmic 48-nucleotide repeat unit in the DRD4 that is associated with ADHD. Although these data do not suggest an association of TIDRU(1) with schizophrenia, additional studies are needed to see whether TIDRU(1) confers a clinical phenotype.

Identification of single nucleotide polymorphisms (SNPs) and other sequence changes and estimation of nucleotide diversity in coding and flanking regions of the NMDAR1 receptor gene in schizophrenic patients.

Glutamatergic dysregulation has been hypothesized to play a role in schizophrenia. The N-methyl-D-aspartate (NMDA) type of glutamate receptor especially is of interest because, in addition to binding sites for glutamate and glycine, a necessary co-agonist, this receptor also contains noncompetitive binding sites for the psychotomimetics phencyclidine (PCP), MK-801, and ketamine. PCP-induced psychosis has been a useful disease model in that both the positive as well as the negative symptomatologies seen in schizophrenia are observed. Recently, a mouse deficient in expression of the NR1 subunit gene (NMDAR1) of the heteromeric receptor has been developed and shown to display aberrant behaviors, with reduced social and sexual interactions as well as increased stereotypic motor activity. In an extensive examination of the NMDAR1 gene in our laboratory in approximately 100 chronic schizophrenic patients, 28 unique sequence changes were identified, including eight single nucleotide polymorphisms (SNPs) in the 5' untranslated region (5'UTR), six SNPs in coding regions (cSNPs), eleven intronic SNPs, two intronic deletions of 7 and 30 bp, and an intronic microinsertion/deletion. With the exception of one previously reported cSNP, all of the identified changes were novel. The frequency of polymorphisms differed significantly by ethnicity and several appeared to be in linkage disequilibrium. None of the changes appeared likely to be of functional significance, thus suggesting that changes in the genomic NMDAR1 are unlikely to contribute to the etiology of schizophrenia. Estimates of nucleotide diversity are comparable to those observed in studies of other genes.

Five missense variants in the amino-terminal domain of the glucocorticoid receptor: no association with puerperal psychosis or schizophrenia.

Steroid hormone administration causes behavior changes in many and psychosis in a few. The clinical features suggest that genetic variants of the glucocorticoid receptor or cofactors could produce susceptible subpopulations who react adversely to hormonal cascades. To investigate this possibility, coding and splice site sequences of the glucocorticoid receptor were scanned for single nucleotide polymorphisms in genomic DNA samples from 100 schizophrenics (86 Caucasians and 14 African-Americans) and 40 Caucasians with puerperal psychosis. Five amino acid substitutions were found in the amino-terminal domain at frequencies of 0.6 to 3.8% in Caucasians: R23K, F29L, L112F, D233N, and N363S. In addition, four silent nucleotide changes were found: E22E, K293K, D677D, and N766N; a transversion in intron 4 occurred beyond the splice junction. None of these variants can be linked to these disorders at present. However, the N363S variant contributes a new potential phosphorylation site and has been associated with increased body mass and reduced bone mineral density [Huizenga et al., 1998], so it is possible that the other missense variants confer traits that currently are unrecognized. Comparisons to natural glucocorticoid receptor mutants in the familial glucocorticoid resistance syndrome and steroid resistant leukemias suggest that amino acid substitutions at highly conserved residues may cause severe functional defects and serious illness, while changes at less conserved sites produce lesser alterations and milder disease.

Variants in the alpha2A AR adrenergic receptor gene in psychiatric patients.

In various studies of psychiatric patients, alterations in adrenergic receptor (AR) expression or function have been suggested. Herein, the alpha2A AR gene was screened in 206 patients with schizophrenia, attention deficit hyperactivity disorder (ADHD), autism, alcohol dependence, or cocaine dependence. The entire coding region was examined for single base pair changes, using restriction endonuclease fingerprinting (REF), a screening method that can detect virtually 100% of mutations in 2-kb DNA segments. In the approximately 600 kb of screened sequence, six novel nucleotide changes were identified. The changes resulted in four missense changes (A25G, N251K, R368L, and K370N), and a sequence in the 3' untranslated region. In addition, a silent change (G363G) was found at high frequency in Asians and Native Americans. Of the four missense changes, two found in patients with alcohol/drug dependence occur in highly conserved amino acids, suggesting that these are of likely functional significance. As the alpha2A ARs are widely distributed both pre- and postsynaptically, and as many pharmacological agents with multiple effects target these receptors, the novel missense changes described herein may be candidates for involvement in alcohol/drug dependence, in other clinical disorders or traits, or in differential response to pharmacotherapy.

Scanning of the dopamine D1 and D5 receptor genes by REF in neuropsychiatric patients reveals a novel missense change at a highly conserved amino acid.

In previous analyses of schizophrenic patients, multiple missense changes and one nonsense change were identified in the D5 dopamine receptor (DRD5) gene, but no sequence changes of likely functional significance were identified in the D1 dopamine receptor (DRD1) gene. In the present study, we examined these genes in patients with certain other neuropsychiatric disorders that may be related to dopaminergic dysregulation. The coding regions of the DRD1 and DRD5 genes were examined in 25 and 25 autistic patients, 25 and 28 attention deficit hyperactivity disorder patients, and 51 and 43 alcoholic patients, respectively. In addition, the DRD5 gene was examined in 75 schizophrenic patients to search for additional variants affecting protein structure or expression (VAPSEs). These patients were analyzed with REF (restriction endonuclease fingerprinting), a hybrid between SSCP and restriction endonuclease digestion, which allows the entire coding sequence to be screened in one lane of a gel. Approximately 800 kb of genomic sequence were examined. No sequence changes were identified in the DRD1 gene among the 101 patient samples analyzed. Two sequence changes were identified in the DRD5 gene among the 171 patient samples. These included one previously identified silent polymorphism at base pair 978 (P326P). The change was identified in patients from all disease categories and from different ethnic backgrounds. One novel missense change, L88F, occurred in transmembrane domain II at a highly conserved amino acid in all dopamine receptors as well as in alpha1- and beta-adrenergic receptors. The mutation was identified in a Caucasian male patient with autism. Further analysis is necessary to determine if this missense change is associated with a particular neuropsychiatric phenotype.

Screening the monoamine oxidase B gene in 100 male patients with schizophrenia: a cluster of polymorphisms in African-Americans but lack of functionally significant sequence changes.

The monoamine oxidase B (MAO-B) gene was examined in 100 alleles derived from 80 Caucasian, 10 African-American, 5 Asian, and 5 Native American male patients with schizophrenia to identify sequence changes that might be associated with the disease. Approximately 235 kb of genomic sequence, primarily in coding regions, were screened by dideoxy fingerprinting, a modification of single-strand conformational polymorphism (SSCP) analysis that detects virtually 100% of sequence changes [Sarkar et al. (1992): Genomics 13:441-443; Liu and Sommer (1994): PCR Methods Appl 4:97-108]. No sequence changes of likely functional significance were identified, suggesting that mutations affecting the structure of the MAO-B protein are uncommon in the general population and are unlikely to contribute significantly to the genetic predisposition to schizophrenia. Eight polymorphisms were identified in African-Americans and Native Americans, but none were identified among Caucasians. Of the eight observed polymorphisms, a set of five transitions and one microdeletion was identified within approximately 17 kb of genomic sequence in the same 3 African-American individuals, while the remaining 7 African-Americans had a sequence identical to that in Caucasians. The presence of two such haplotypes, without intermediates, is compatible with the hypothesis that germline mutations can occur in clusters, as also suggested by other recent findings.

Gender difference in apolipoprotein E-associated risk for familial Alzheimer disease: a possible clue to the higher incidence of Alzheimer disease in women.

Late-onset Alzheimer disease (AD) is associated with the apolipoprotein E (APOE)-epsilon4 allele. In late-onset familial AD, women have a significantly higher risk of developing the disease than do men. The aim of this study was to determine whether the gender difference in familial AD is a function of APOE genotype. We studied 58 late-onset familial AD kindreds. Kaplan-Meier survival analysis was used to assess genotype-specific distributions of age at onset. Odds ratios were estimated by logistic regression with adjustment for age and by conditional logistic regression with stratification on families. All methods detected a significant gender difference for the epsilon4 heterozygous genotype. In women, epsilon4 heterozygotes had higher risk than those without epsilon4; there was no significant difference between epsilon4 heterozygotes and epsilon4 homozygotes. In men, epsilon4 heterozygotes had lower risk than epsilon4 homozygotes; there was not significant difference between epsilon4 heterozygotes and those without epsilon4. A direct comparison of epsilon4 heterozygous men and women revealed a significant twofold increased risk in women. We confirmed these results in 15 autopsy-confirmed AD kindreds from the National Cell Repository at Indiana University Alzheimer Disease Center. These observations are consistent with the increased incidence of familial AD in women and may be a critical clue to the role of gender in the pathogenesis of AD.

Genotype-to-phenotype analysis: search for clinical characteristics of a missense change in the GABAA-beta 1 receptor gene.

Genotype-to-phenotype analysis reverses the classical approach to genetic disease in which an unknown genotype is sought for a known phenotype. This paper provides an example of genotype-to-phenotype analysis for the possible psychiatric effects of a missense mutation (H396Q) at a highly conserved residue of the beta 1 subunit gene of the gamma aminobutyric acid type A receptor. DNA samples from 1,507 Caucasians of Western European descent were screened, and 10 heterozygotes for H396Q were identified. These individuals were matched to homozygous normal individuals by age, gender, and length of available medical records. The complete medical records of these 20 individuals were reviewed blindly by two psychiatrists (D.C.S., L.L.H.) to assess psychiatric symptomatology, with an emphasis on anxiety and related disorders. However, no association was found between this missense change at a conserved amino acid and a dominant neuropsychiatric disease phenotype. Thus, this missense change may be neutral or only mildly deleterious, may only cause recessive disease in rare individuals, or may interact epistatically with some other gene(s).

The D5 dopamine receptor gene in schizophrenia: identification of a nonsense change and multiple missense changes but lack of association with disease.

To determine whether mutations in the D5 dopamine receptor gene (DRD5) are associated with schizophrenia, the gene was examined in 78 unrelated schizophrenic individuals (156 DRD5 alleles). After amplification by the polymerase chain reaction, products were examined by dideoxy fingerprinting (ddF), a screening method related to single strand conformational polymorphism analysis that detects essentially 100% of mutations. All samples with abnormal ddF patterns were sequenced. Nine different sequence changes were identified. Five of these were sequence changes that would result in protein alterations; of these, one was a nonsense change (C335X), one was a missense change in an amino acid conserved in all dopamine receptors (N351D), two were missense changes in amino acids that are identical in only some dopamine receptors and in only some species (A269V; S453C), and one was a missense change in a non-conserved amino acid (P330Q). To investigate whether the nonsense change (C335X), predicted to prematurely truncate the receptor protein and result in a 50% diminution of functional protein, was associated with schizophrenia, other neuropsychiatric diseases, or specific neuropsychological, psychophysiological, or personality traits, both case-control and family analyses were performed. No statistically-significant associations were detected with schizophrenia or other neuropsychiatric disease. There also were no significant associations between any one measure of neuropsychological function. However, a post-hoc analysis of combined measures of frontal lobe function hinted that heterozygotes for C335X may have a vulnerability to mild impairment, but these findings must be interpreted with caution.(ABSTRACT TRUNCATED AT 250 WORDS)

Screening the dopamine D1 receptor gene in 131 schizophrenics and eight alcoholics: identification of polymorphisms but lack of functionally significant sequence changes.

To determine whether mutations in the D1 dopamine receptor (D1 DR) gene are associated with schizophrenia, the coding sequence was examined in 106 Caucasian, 11 African-American, 8 Asian, and 6 Native American patients. Approximately 350 kb of genomic sequence was screened by dideoxy fingerprinting, a method related to single strand conformational polymorphism (SSCP) analysis that detects virtually 100% of sequence changes [Sarkar et al., 1992: Genomics 13:441-443; Liu and Sommer, 1994: PCR Methods and Applications 4:97-108]. One polymorphism was identified in Asians and one in Caucasians, but neither altered the amino acid sequence (Leu66, and Ser421, respectively). In addition, a previously reported polymorphism in the 5' untranslated region of exon 2 at bp -48 was found to be common, with an allele frequency of approximately 40% in Caucasians of Western European descent. Based on the fact that no sequence changes of likely functional significance were identified, these data suggest that mutations affecting the structure of the D1 dopamine receptor protein are uncommon and are unlikely to contribute significantly to the genetic predisposition to schizophrenia. The D1 DR gene also was examined in eight alcoholics, including 3 African-Americans and 1 Native American, but no sequence changes were identified.

Screening the dystrophin gene suggests a high rate of polymorphism in general but no exonic deletions in schizophrenics.

The dystrophin gene, located at chromosome Xp21, was evaluated as a candidate gene in chronic schizophrenia in response to the report of a large family in which schizophrenia cosegregated with Becker muscular dystrophy [Zatz et al., 1991: Am J Hum Genet 49: A364; 1992: J Med Genet 30(2):131-134]. Genomic DNA from 94 men with chronic schizophrenia was evaluated by Southern blot analysis using cDNA probes that span exons 1-59. No exonic deletions were identified. An unexpectedly high rate of polymorphism was calculated in this study and two novel polymorphisms were found, demonstrating the usefulness of the candidate gene approach even when results of the original study are negative.

Dopamine D4 receptor variants in unrelated schizophrenic cases and controls.

The D4 dopamine receptor (D4DR) exists in multiple allelic forms (Van Tol et al.: Nature 358:149-152, 1992) which involve different numbers of a 48 basepair repeat sequence in the putative third cytoplasmic loop. Different binding properties have been reported for at least three of the alleles in cDNA binding assays with clozapine, an atypical neuroleptic, and spiperone (Van Tol et al., 1992). We have examined 115 unrelated schizophrenic cases defined by DSM-III-R criteria and 115 controls of similar ethnicity to determine the frequency of seven different D4 alleles in these groups. No statistically significant difference in the distribution of the alleles existed between cases and controls, although a trend towards a greater prevalence of homozygotes for the 4-repeat allele was observed in schizophrenics.

Novel association approach for determining the genetic predisposition to schizophrenia: case-control resource and testing of a candidate gene.

We have developed a two-tiered approach to elucidating the genetic predisposition to schizophrenia. The approach first involves the examination of candidate genes in a subset of schizophrenic individuals to identify DNA sequence variations of likely functional significance, i.e., that produce either structural alterations in the protein or affect the level of gene expression. Once identified, the prevalence of the aberrant allele is examined in a large group of unrelated schizophrenic cases and controls to assess whether a true disease association exists. Herein, we describe the establishment of a DNA bank on nearly 200 unrelated schizophrenic cases defined by DSM-III-R criteria and on over 300 unrelated, ethnically similar controls. Characteristics of the study sample are described. The study approach then is illustrated by testing known mutations in the phenylalanine hydroxylase gene, responsible for the autosomal recessive disease of phenylketonuria, in the case-control sample to determine if carriership of a mutant allele is associated with an increased risk of schizophrenia. Using PCR amplification of specific alleles (PASA), we screened 190 schizophrenic cases and 336 controls for two common point mutations in the phenylalanine hydroxylase gene. Two carriers were found among the controls, while none of the cases was shown to carry a mutant allele. Thus, carriership of either of two common mutations in the phenylalanine hydroxylase gene does not appear to be associated with an increased risk of schizophrenia. As additional candidate genes are tested in this case-control resource, adjustment for multiple comparisons will become crucial in order to reduce the chance of false positive findings.(ABSTRACT TRUNCATED AT 250 WORDS)

Early detection of Alzheimer's disease: a statistical approach using positron emission tomographic data.

Correlational analysis of regional cerebral glucose metabolism (rCMRglc) obtained by high-resolution positron emission tomography (PET) has demonstrated reduced neocortical rCMRglc interactions in mildly/moderately demented patients with probable Alzheimer's disease (AD). Thus, identification of individual differences in patterns of rCMRglc interactions may be important for the early detection of AD, particularly among individuals at greater risk for developing AD (e.g., those with a family history of AD). Recently, a statistical procedure, using multiple regression and discriminant analysis, was developed to assess individual differences in patterns of rCMRglc interdependencies. We applied this new statistical procedure to resting rCMRglc PET data from mildly/moderately demented patients with probable AD and age/sex-matched controls. The aims of the study were to identify a discriminant function that would (a) distinguish patients from controls and (b) identify an AD pattern in an individual at risk for AD with isolated memory impairment whose initial PET scan showed minor abnormalities, but whose second scan showed parietal hypometabolism, coincident with further cognitive decline. Two discriminant functions, reflecting interactions involving regions most involved in reduced correlations in probable AD, correctly classified 87% of the patients and controls, and successfully identified the first scan of the at-risk individual as AD (probability > 0.70). The results suggest that this statistical approach may be useful for the early detection of AD.