Chromosomal localization of SLC12A5/Slc12a5, the human and mouse genes for the neuron-specific K(+)-Cl(-) cotransporter (KCC2) defines a new region of conserved homology.

K(+)-Cl(-) cotransporters (KCCs) constitute a branch of the cation-chloride cotransporter (CCC) family. To date, four KCC isoforms (KCC1-KCC4) have been identified and they all mediate obligatorily coupled, electroneutral transmembrane movement of K(+) and Cl(-) ions. KCC2 (gene symbol SLC12A5) is expressed exclusively in neurons within the central nervous system and abnormalities in its expression have been proposed to play a role in pathological conditions such as epilepsy and neuronal trauma. Here we have determined chromosome location of both the human and the mouse genes encoding KCC2, which may assist in future efforts to determine the contribution of KCC2 to inherited human disorders. We assigned human SLC12A5 to 20q12-->q13.1 and its murine homolog, Slc12a5, to 5G2-G3 by fluorescence in situ hybridization (FISH). These mapping data are contradictory to the previously reported human-mouse conserved synteny relationships disrupting an exceptionally well-conserved homology segment between human Chr 20 and mouse Chr 2. We hence suggest the first region of conserved homology between human Chr 20 and mouse Chr 5.

Construction of gene-targeting vectors: a rapid Mu in vitro DNA transposition-based strategy generating null, potentially hypomorphic, and conditional alleles.

Gene targeting into mammalian genomes by means of homologous recombination is a powerful technique for analyzing gene function through generation of transgenic animals. Hundreds of mouse strains carrying targeted alleles have already been created and recent modifications of the technology, in particular generation of conditional alleles, have extended the usefulness of the methodology for a variety of special purposes. Even though the standard protocols, including the construction of gene-targeting vector plasmids, are relatively straightforward, they typically involve time-consuming and laborious gene mapping and/or sequencing steps. To produce various types of gene-targeting constructions rapidly and with minimum effort, we developed a strategy, that utilizes a highly efficient in vitro transposition reaction of phage Mu, and tested it in a targeting of the mouse Kcc2 gene locus. A vast number and different types of targeting constructions can be generated simultaneously with little or no prior sequence knowledge of the gene locus of interest. This quick and efficient general strategy will facilitate easy generation of null, potentially hypomorphic, and conditional alleles. Especially useful it will be in the cases when effects of several exons within a given gene are to be studied, a task that necessarily will involve generation of multiple constructions. The strategy extends the use of diverse recombination reactions for advanced genome engineering and complements existing recombination-based approaches for generation of gene-targeting constructions.