Francis J. McMahon

Linkage of bipolar affective disorder to chromosome 18 markers in a new pedigree series.

Several groups have reported evidence suggesting linkage of bipolar affective disorder (BPAD) to chromosome 18. We have reported data from 28 pedigrees that showed linkage to marker loci on 18p and to loci 40 cM distant on 18q. Most of the linkage evidence derived from families with affected phenotypes in only the paternal lineage and from marker alleles transmitted on the paternal chromosome. We now report results from a series of 30 new pedigrees (259 individuals) genotyped for 13 polymorphic markers spanning chromosome 18. Subjects were interviewed by a psychiatrist and were diagnosed by highly reliable methods. Genotypes were generated with automated technology and were scored blind to phenotype. Affected sib pairs showed excess allele sharing at the 18q markers D18S541 and D18S38. A parent-of-origin effect was observed, but it was not consistently paternal. No robust evidence of linkage was detected for markers elsewhere on chromosome 18. Multipoint nonparametric linkage analysis in the new sample combined with the original sample of families supports linkage on chromosome 18q, but the susceptibility gene is not well localized.

Increased levels of a mitochondrial DNA deletion in the brain of patients with bipolar disorder.

Mutations in mitochondrial DNA (mtDNA) have been implicated in the pathophysiology of affective disorders. To examine possible pathophysiological significance of mtDNA deletions in bipolar disorder, the concentration of the 4977-base-pair deletion in mtDNA in the autopsied brains of 7 patients with bipolar disorder, 9 suicide victims, and 9 controls was examined using a quantitative polymerase chain reaction method. The ratio of deleted to wild-type mtDNA in cerebral cortex was significantly higher in patients with bipolar disorder [0.23 +/- 0.18 (mean +/- SD)%] compared with that in age-matched controls (0.06 +/- 0.07%, p < 0.05). This result supports a hypothesis that mtDNA deletions may play a role in the pathophysiology of bipolar disorder.

Full-Genome Scan for Linkage in 50 Families Segregating the Bipolar Affective Disease Phenotype

A genome scan of approximately 12-cM initial resolution was done on 50 of a set of 51 carefully ascertained unilineal multiplex families segregating the bipolar affective disorder phenotype. In addition to standard multipoint linkage analysis methods, a simultaneous-search algorithm was applied in an attempt to surmount the problem of genetic heterogeneity. The results revealed no linkage across the genome. The results exclude monogenic models and make it unlikely that two genes account for the disease in this sample. These results support the conclusion that at least several hundred kindreds will be required in order to establish linkage of susceptibility loci to bipolar disorder in heterogeneous populations.

Linkage Disequilibrium Analysis of G-olfα (GNAL) in Bipolar Affective Disorder

This study examines G-olf{sub {alpha}} as a possible candidate gene for susceptibility to bipolar affective disorder (BPAD) using the Transmission Disequilibrium Test (TDT). G-olf{sub {alpha}}, which encodes a subunit of a G-protein involved in intracellular signaling, maps within a region of chromosome 18 that has been implicated by two different linkage studies as a potential site of BPAD susceptibility loci. The expression pattern of G-olf{sub {alpha}} in the brain, its coupling to dopamine receptors, and the effects of lithium salts on G-proteins all support G-olf{sub {alpha}} as a candidate gene for BPAD. Our study population consisted of 106 probands and sibs with bipolar I disorder, with a median age-at-onset of 21.5 years ascertained from the United States. There was no evidence of linkage disequilibrium between BPAD and any of the observed G-olf{sub {alpha}} alleles in our sample. Division of families based on sex of the transmitting parent did not significantly change the results. This sample had good power (78%) to detect linkage disequilibrium with alleles conferring a relative risk equal to that estimated for the putative 18p locus (2.58). Our results do not support a major role for G-olf{sub {alpha}} as a susceptibility locus for BPAD in a substantial portionmorexa0» of our sample. Other genes lying near G-olf{sub {alpha}} within the linked region on chromosome 18 cannot be excluded by our data. This study illustrates the use of the TDT in evaluating candidate genes within linked chromosome regions. 24 refs., 1 tab.«xa0less

Anticipation in schizophrenia: A review and reconsideration

There have been several reports on anticipation and schizophrenia, and the purpose of the present article is to review the literature and present data from an ongoing family study of schizophrenia. The published data find on average a 10-year difference in the age of onset between the parental and offspring generation in family sets that have been ascertained for a genetic linkage study. The biases inherent in such studies include the biases of ascertainment that were described by Penrose [1948]. Several investigators have searched for evidence of enlarged triplet repeats, and some find evidence consistent with expanded triplet repeats, whereas others do not. In any event the phenomenon of anticipation in schizophrenia appears to be consistently found and an explanation is needed. Data are presented from pairwise analyses using intergenerational pairs from 61 pedigrees with schizophrenia showing evidence of anticipation as well as the fertility bias. Anticipation was found in aunt:niece/nephew pairs (14.5 years) but not in uncle:niece/nephew pairs (0.5 years). The sex difference in age of onset was accentuated in uncles versus aunts (8.5 years), present in parents (4.5 years), but absent in the proband generation. Therefore, there appears to be an interaction within families between age of onset and sex that deserves further investigation. Am. J. Med. Genet. (Neuropsychiatr. Genet.) 88:686-693, 1999.

Chromosomes 8 and 10 workshop

The chromosomes 8 and 10 workshop took place at the Sixth World Congress on Psychiatric Genetics from October 6th-10th, 1998 in Bonn, Germany. Aim of the workshop was to discuss and summarize reports on potential susceptibility genes for psychiatric disorders. Linkage-findings on chromosome 8 concentrate on 8p22-p21 and include mainly schizophrenic disorders. Two areas on chromosome 10 were reported to contain potential susceptibility genes for schizophrenic as well as for affective disorders. The strongest findings were reported for 10p14-p11, while other groups communicated also linkage data for the telomeric part of the long arm to the workshop.

Hyperactivity following posterior cortical injury in lateralized, sensitive to lesion size and independent of the nigrostriatal dopamine system

In a previous study, we reported that a specific size cortical suction lesion of the right posterior cortex in rats produced hyperactivity and increased concentrations of dopamine in the nigrostriatal pathway. The present study extended those findings by addressing whether this phenomenon is lateralized to the right posterior cortex and whether the increases in nigrostriatal dopamine are necessary for the behavioral changes produced by the lesion. Right posterior cortical lesions of 1.8 mm diameter produced spontaneous hyperactivity over a 30-day postoperative period while identically placed 1.3 mm or 2.4 mm diameter lesions did not. Left hemisphere lesions of 1.3 mm, 1.8 mm or 2.4 mm diameter also failed to produce hyperactivity. The hyperactivity response to 1.8 mm diameter lesions of the right posterior cortex was not blocked by 70% depletions in nigrostriatal dopamine produced by bilateral nigral injections of 6-hydroxydopamine two weeks prior to cortical lesions. These findings suggest that hyperactivity following right posterior cortical lesions is lateralized and is not dependent upon changes in the nigrostriatal dopaminergic pathway.

Integrating clinical and laboratory data in genetic studies of complex phenotypes: a network-based data management system.

The identification of genes underlying a complex phenotype can be a massive undertaking, and may require a much larger sample size than thought previously. The integration of such large volumes of clinical and laboratory data has become a major challenge. In this paper we describe a network-based data management system designed to address this challenge. Our system offers several advantages. Since the system uses commercial software, it obviates the acquisition, installation, and debugging of privately-available software, and is fully compatible with Windows and other commercial software. The system uses relational database architecture, which offers exceptional flexibility, facilitates complex data queries, and expedites extensive data quality control. The system is particularly designed to integrate clinical and laboratory data efficiently, producing summary reports, pedigrees, and exported files containing both phenotype and genotype data in a virtually unlimited range of formats. We describe a comprehensive system that manages clinical, DNA, cell line, and genotype data, but since the system is modular, researchers can set up only those elements which they need immediately, expanding later as needed.

Circadian genes and lithium response in bipolar disorders: associations with PPARGC1A (PGC-1α) and RORA.

Preliminary studies suggest that lithium (Li) response might be associated with some circadian gene polymorphisms, we therefore performed a pharmacogenetic study on the core clock genes in two independent samples suffering from bipolar disorder (BD) and thoroughly characterized for their Li response. Two independent Caucasian samples (165 and 58 bipolar patients) treated with Li were selected from samples recruited in a French multicenter study and assessed for their Li response using the Alda scale. The two samples were genotyped using the Human660 (H660) and OmniExpress (OE) BeadChips and gene‐based association analyses of 22 core clock genes were conducted. In the first sample (H660 chip), the RAR‐related orphan receptor‐a gene (RORA) and the Peroxisome Proliferator‐Activated Receptor Gamma, Coactivator 1 Alpha gene (PPARGC1A or PGC‐1α) were significantly associated with the Li response (empirical P‐value = 0.0015 and 0.04, respectively), and remained significant only for RORA after Bonferroni correction. In the second sample (OE chip), PPARGC1A was significantly associated with the Li response (empirical P‐value = 0.04), and did not remain significant after Bonferroni correction. PPARGC1A is a master regulator of mitochondrial function and a key component of the endogenous clock that stimulates the expression of Bmal1 and Rev‐erb‐alpha through coactivation of RORA. Although the observed associations deserve further replication and investigation, our results suggest genetic associations between Li response and these two close biological partners: PPARGC1A and RORA involved in circadian rhythms and bioenergetics processes in Li response.