Amplification of the murine mdr2 gene and a reconsideration of the structure of the murine mdr gene locus

Chromosomal organization of candidate genes involved in cholesterol gallstone formation: a murine gallstone map

Epidemiologic and family studies indicate that cholesterol gallstone formation is in part genetically determined. The major contribution to our current understanding of gallstone genes derives from animal studies, particularly cross-breeding experiments in inbred mouse strains that differ in genetic susceptibility to cholesterol gallstone formation (quantitative trait loci mapping). In this review we summarize how the combined use of genomic strategies and phenotypic studies in inbred mice has proven to be a powerful means of dissecting the complex pathophysiology of this common disease. We present a "gallstone map" for the mouse, consisting of all genetic loci that have been identified to confer gallstone susceptibility as well as putative candidate genes. Translation of the genetic loci and genes between mouse and human predicts chromosomal regions in the human genome that are likely to harbor gallstone genes. Both the number and the precise understanding of gallstone genes are expected to further increase with rapid progress of the genome projects, and multiple new targets for early diagnosis and prevention of gallstone disease should become possible.

Maintenance of hypomethylation status and preferential expression of exogenous human MDR1/PGY1 gene in mouse L cells by YAC mediated transfer

Selection of cells for resistance to vincristine or doxorubicin often induces overexpression of the multidrug resistance (MDR) genes, which encode the cell surface P-glycoproteins, as a result of gene amplification, transcriptional activation, or mRNA stabilization. The LMD1 and LMD4 cell lines were established after the transfer into mouse L cells of two independent yeast artificial chromosome clones containing 300 and 850 kb, respectively, of the human MDR locus. The human MDR1/PGY1 gene, but not the endogenous mouse mdr1a and mdr1b genes, was overexpressed as a result of gene amplification and transcriptional activation in various sublines of LMD1 and LMD4 cells selected for resistance to vincristine. Then we asked why human MDR1/PGY1 gene, but not mouse relevant gene, was expressed. Determination of the methylation status of cytosine residues at Msp I/Hap II cleavage sites (CCGG) in the promoter regions of human MDR1/PGY1 and mouse mdr1a revealed hypomethylation and hypermethylation of the human and mouse genes, respectively in LMD1, LMD4, and their vincristine-resistant derivatives. Various vincristine-resistant sublines were also established after exposure of LMD1 cells for 48 h to 5-aza-2'-deoxycytidine, an inhibitor of DNA methyltransferase. These sublines exhibited overexpression of mouse mdr1a and mdr1b, but not of human MDR1/PGY1, as well as hypomethylation of the mouse mdr1a promoter region. Thus, the selective expression of human or mouse MDR genes in this cell system appears to be related to the methylation status of the respective gene promoter regions.

De novo generation of simple sequence during gene amplification

Mammalian cells that have undergone gene amplification and/or gene rearrangement have been used as resources to gain insight into the questions of chromosome structure and dynamics. The multidrug resistant murine cell line J7.V2-1 has been shown previously to contain two distinct forms of the highly amplified mdr2 gene, a member of the mouse gene family responsible for the multidrug resistant (MDR) phenotype [Kirschner, L. S. (1995) DNA Cell Biol. 14, 47-59]. Characterization of both forms of the gene revealed that one form corresponded to the wild-type structure of the gene, whereas the other represented a rearrangement. Investigation of this altered gene demonstrated a deletion of 1.6 kb of the wild-type sequence, and replacement of this region with a poly(AT) tract that appears to have been generated de novo. Analysis of the native sequence in this region demonstrated the absence of repetitive elements, but was notable for the presence of two long stretches of polypurine: polypyrimidine strand asymmetry. Analysis of mdr2 transcripts in this cell line revealed that nearly all of the mRNA is transcribed from the rearranged form of the gene. This message is unable to code for a functional mdr2 gene product, owing to a deletion of the fourth exon during this event. Mechanisms of the rearrangement, as well as the significance of this curious effect on transcription, are discussed.