Gene expression analysis in epileptic hippocampi reveals a promoter haplotype conferring reduced aldehyde dehydrogenase 5a1 expression and responsiveness.

Increasing evidence indicates the pathogenetic relevance of regulatory genomic motifs for variability in the manifestation of brain disorders. In this context, cis-regulatory effects of single nucleotide polymorphisms (SNPs) on gene expression can contribute to changing transcript levels of excitability-relevant molecules and episodic seizure manifestation in epilepsy. Biopsy specimens of patients undergoing epilepsy surgery for seizure relief provide unique insights into the impact of promoter SNPs on corresponding mRNA expression. Here, we have scrutinized whether two linked regulatory SNPs (rs2744575; 4779C > G and rs4646830; 4854C > G) located in the aldehyde dehydrogenase 5a1 (succinic semialdehyde dehydrogenase; ALDH5A1) gene promoter are associated with expression of corresponding mRNAs in epileptic hippocampi (n = 43). The minor ALDH5A1-GG haplotype associates with significantly lower ALDH5A1 transcript abundance. Complementary in vitro analyses in neural cell cultures confirm this difference and further reveal a significantly constricted range for the minor ALDH5A1 haplotype of promoter activity regulation through the key epileptogenesis transcription factor Egr1 (early growth response 1). The present data suggest systematic analyses in human hippocampal tissue as a useful approach to unravel the impact of epilepsy candidate SNPs on associated gene expression. Aberrant ALDH5A1 promoter regulation in functional terms can contribute to impaired γ-aminobutyric acid homeostasis and thereby network excitability and seizure propensity.

Structure and evolution of RIM-BP genes: identification of a novel family member.

RIM-binding proteins (RIM-BPs) were identified as binding partners of the presynaptic active zone proteins RIMs as well as for voltage-gated Ca(2+)-channels. They were suggested to form a functional link between the synaptic-vesicle fusion apparatus and Ca(2+)-channels. Here we show that the RIM-BP gene family diversified in different stages during evolution, but retained their unique domain structure. While invertebrate genomes contain one, and vertebrates include at least two RIM-BPs, we identified an additional gene, RIM-BP3, which is exclusively expressed in mammals. RIM-BP3 is encoded by a single exon of which three copies are present in the human genome. All RIM-BP genes encode proteins with three SH3-domains and two to three fibronectin III repeats. The flanking regions diverge in size and sequence and are alternatively spliced in RIM-BP1 and -2. Quantitative real-time RT-PCR and in situ hybridization analyses revealed overlapping but distinct expression patterns throughout the brain for RIM-BP1 and -2, while RIM-BP3 was detected at high levels outside the nervous system. The modular domain structure of RIM-BPs, their expression pattern and the conservative expansion during evolution shown here support their potential role as important molecular adaptors.