Cis- and trans- loci influence expression of the schizophrenia susceptibility gene DTNBP1.

Susceptibility to complex disease appears to be partly mediated by heritable differences in gene expression. Where cis-acting effects on a gene's expression influence disease susceptibility, other genes containing polymorphism with a trans-acting effect on expression of that gene may also be expected to modulate risk. Use of the expression of an identified disease gene as an endophenotype for quantitative linkage analysis may therefore provide a powerful method for mapping loci that modulate disease susceptibility. We performed genome-wide linkage analysis on expression of dystrobrevin binding protein 1 (DTNBP1), a well-supported susceptibility gene for schizophrenia, in large CEPH pedigrees. We observed genome-wide significant evidence for linkage at the DTNBP1 locus on chromosome 6p22, and demonstrated that this reflects variable cis-acting effects on DTNBP1 expression. In addition, we observed genome-wide suggestive evidence for linkage of DTNBP1 expression to chromosome 8p, suggesting a locus that exerts a trans-acting effect on DTNBP1 expression. The region of linkage to DTNBP1 expression on chromosome 8 is contiguous with linkage findings based upon the clinical schizophrenia phenotype, and contains another well-supported schizophrenia susceptibility gene, neuregulin-1 (NRG1). Our data provide complementary evidence for chromosome 8p as a susceptibility locus for schizophrenia, and suggest that genetic variation within this region may influence risk, at least in part, through effects on DTNBP1 expression.

Huntingtin Exists as Multiple Splice Forms in Human Brain.

BACKGROUND: A CAG repeat expansion in HTT has been known to cause Huntington's disease for over 20 years. The genomic sequence of the 67 exon HTT is clear but few reports have detailed alternative splicing or alternative transcripts. Most eukaryotic genes with multiple exons show alternative splicing that increases the diversity of the transcriptome and proteome: it would be surprising if a gene with 67 known exons in its two major transcripts did not present some alternative transcripts. OBJECTIVE: To investigate the presence of alternative transcripts directly in human HTT. METHODS: An overlapping RT-PCR based approach was used to determine novel HTT splice variants in human brain from HD patients and controls and 3D protein homology modelling employed to investigate their significance on the function of the HTT protein. RESULTS: Here we show multiple previously unreported novel transcripts of HTT. Of the 22 splice variants found, eight were in-frame with the potential to encode novel HTT protein isoforms. Two splice variants were selected for further study; HTT Δex4,5,6 which results in the skipping of exons 4, 5 and 6 and HTTex41b which includes a novel exon created via partial retention of intron 41. 3D protein homology modelling showed that both splice variants are of potential functional significance leading to the loss of a karyopherin nuclear localisation signal and alterations to sites of posttranslational modification. CONCLUSIONS: The identification of novel HTT transcripts has implications for HTT protein isoform expression and function. Understanding the functional significance of HTT alternative splicing would be critical to guide the design of potential therapeutics in HD that aim to reduce the toxic HTT transcript or protein product including RNA silencing and correction of mis-splicing in disease.

Identification of novel alternative splicing events in the huntingtin gene and assessment of the functional consequences using structural protein homology modelling.

Huntington's disease (HD) is an inherited progressive neurodegenerative disorder caused by a pathological CAG trinucleotide repeat expansion in the large multi-exon gene, huntingtin (HTT). Although multiple pathogenic mechanisms have been proposed for HD, there is increasing interest in the RNA processing of the HTT gene. In mammals, most multi-exon genes are alternatively spliced; however, few alternative transcripts have been described for HTT. Given the numerous protein bands detected in mouse and human brain tissue by Western blotting using anti-huntingtin antibodies, we examined whether alternative splicing of HTT may account for some of these fragments. Using RT-PCR in mouse brain, we detected two novel splice variants of Htt that lacked the 111-bp exon 29 (Htt∆ex29) or retained a 57-bp portion of intron 28 (Htt(+57)in28) via use of a cryptic splice site. The alternative transcripts were present in wild-type and homozygous Hdh(Q150/Q150) mouse brain at all ages and in all brain regions and peripheral tissues studied. Differential splicing of Htt∆ex29 was found in the cerebellum of Hdh(Q150/Q150) mice with a significant reduction in transcript levels in mutant animals. In human brain, we detected similar splice variants lacking exons 28 and 29. The ability of alternatively spliced transcripts to encode different protein isoforms with individual functions in the cell, combined with the known role of splicing in disease, renders these novel transcripts of interest in the context of HD pathogenesis.

Longitudinal analysis of gene expression and behaviour in the HdhQ150 mouse model of Huntington's disease.

Substantial transcriptional changes are seen in Huntington's disease (HD) brain and parallel early changes in gene expression are observed in mouse models of HD. Analysis of behaviour in such models also shows substantial deficits in motor, learning and memory tasks. We examined the changes in the transcriptional profile in the HdhQ150 mouse model of HD at 6, 12 and 18 months and correlated these changes with the behavioural tasks the animals had undertaken. Changes in gene expression over time showed a significant enrichment of RNAs altered in abundance that related to cognition in both HdhQ150 and wild-type animals. The most significantly down-regulated mRNA between genotypes over the whole time-course was Htt itself. Other changes between genotypes identified at 6 months related to chromatin organization and structure, whilst at 18 months changes related mainly to intracellular signalling. Correlation of the changes in gene product abundance with phenotypic changes revealed that weight and detection of the opposite position of the platform in the water maze seemed to correlate with the chromatin alterations whereas changes in the rotarod performance related mainly to intracellular signalling and homeostasis. These results implicate alterations in specific molecular pathways that may underpin changes in different behavioural tasks.

Regional and cellular gene expression changes in human Huntington's disease brain.

Huntington's disease (HD) pathology is well understood at a histological level but a comprehensive molecular analysis of the effect of the disease in the human brain has not previously been available. To elucidate the molecular phenotype of HD on a genome-wide scale, we compared mRNA profiles from 44 human HD brains with those from 36 unaffected controls using microarray analysis. Four brain regions were analyzed: caudate nucleus, cerebellum, prefrontal association cortex [Brodmann's area 9 (BA9)] and motor cortex [Brodmann's area 4 (BA4)]. The greatest number and magnitude of differentially expressed mRNAs were detected in the caudate nucleus, followed by motor cortex, then cerebellum. Thus, the molecular phenotype of HD generally parallels established neuropathology. Surprisingly, no mRNA changes were detected in prefrontal association cortex, thereby revealing subtleties of pathology not previously disclosed by histological methods. To establish that the observed changes were not simply the result of cell loss, we examined mRNA levels in laser-capture microdissected neurons from Grade 1 HD caudate compared to control. These analyses confirmed changes in expression seen in tissue homogenates; we thus conclude that mRNA changes are not attributable to cell loss alone. These data from bona fide HD brains comprise an important reference for hypotheses related to HD and other neurodegenerative diseases.