Complex Study of Drosophila Mutants in the agnostic Locus: A Model for Coupling Chromosomal Architecture and Cognitive Functions

After the devastation of genetics in our country, Academician Leon A. Orbeli has provided an opportunity for the studies on evolutionary conservatism of genes controlling the main properties of the higher nervous activity and conditioning. For the last few years, determination and bioinformatic analysis of genome sequences in the plant, worm, Drosophila, and human genome have revealed, indeed, a high interspecies homology of genes. Studies on Drosophila mutants have shown that components of intracellular signalization systems regulating neuronal functions and gene expression are organized in supramolecular complexes. It has become evident that the chromosomal architecture predetermines the appearance of deletions, duplications, insertions, and translocations and, therefore, plays an important role not only in evolution but also in generating human pathological syndromes with multiple manifestations, including cognitive dysfunctions. There appeared a new approach, comparative genomics, that allows revealing functions of human disease genes on the basis of their sequence homology to the known Drosophila gene with various well-studied mutant phenotypes. For this reason, the Drosophila genes should be saturated with mutant phenotypes, and these are to be studied in comparison with the chromosomal architecture. Our complex behavioral and molecular-genetic study of spontaneous, induced, and P-insertional mutations in the Drosophila agnostic locus and the bioinformatic analyses of genomic sequences has allowed us to assign the locus to the Drosophila genomic scaffold AE003489 from the 11AB X-chromosomal region that contains the CG1848 gene coding for LIM-kinase 1. Mutations, insertions, and deletions in the agnostic locus lead to an increased activity of Ca²⁺/calmodulin-dependent PDE1, resistance to ether, an inactivator of synaptic transmission, impairments of the brain structures, learning and memory defects in conditioned courtship suppression paradigm, alterations in sound production and in structural-functional chromosomal organization. Therefore, the agnostic locus represents a model to study the human Williams syndrome with multiple dysfunctions due to a contiguous deletion in the 7q11.23 spanning 17 genes, among them the gene for LIM-kinase 1 presumed to be responsible for cognitive defects. The Williams syndrome is considered to be a most efficient model to study human cognition, human genome organization, and evolution.     

Architecture of the X Chromosome,Expression of LIM Kinase 1, and Recombination in the agnostic Mutants of Drosophila: A Model for Human Williams Syndrome

As the Human Genome and Drosophila Genome Projects were completed, it became clear that functions of human disease-associated genes may be elucidated by studying the phenotypic expression of mutations affecting their structural or functional homologs in Drosophila.Genomic diseases were identified as a new class of human disorders. Their cause is recombination, which takes place at gene-flanking duplicons to generate chromosome aberrations such as deletions, duplications, inversions, and translocations. The resulting imbalance of the dosage of developmentally important genes arises at a frequency of 10^-3 (higher than the mutation rate of individual genes) and leads to syndromes with multiple manifestations, including cognitive defects. Genomic DNA fragments were cloned from the Drosophila melanogaster agnostic locus, whose mutations impair learning ability and memory. As a result, the locus was exactly localized in X-chromosome region 11AB containing the LIM kinase 1 (LIMK1) gene (CG1848), which is conserved among many species. Hemizygosity for the LIMK1 gene, which is caused by recombination at neighboring extended repeats, underlies cognitive disorders in human Williams syndrome. LIMK1 is a component of the integrin signaling cascade, which regulates the functions of the actin cytoskeleton, synaptogenesis, and morphogenesis in the developing brain. Immunofluorescence analysis revealed LIMK1 in all subdomains of the central complex and the visual system of Drosophila melanogaster.Like in the human genome, theD. melanogaster region is flanked by numerous repeats, which were detected by molecular genetic methods and analysis of ectopic chromosome pairing. The repeats determined a higher rate of spontaneous and induced recombination, including unequal crossing over, in theagnostic gene region. Hence, the agnostic locus was considered as the first D. melanogaster model suitable for studying the genetic defect associated with Williams syndrome in human.