Mutation identification DNA analysis system (MIDAS) for detection of known mutations.

We introduce a novel experimental strategy for DNA mutation detection named the Mismatch Identification DNA Analysis System (MIDAS) [1, 2], which has an associated isothermal probe amplification step to increase target DNA detection sensitivity to attomole levels. MIDAS exploits DNA glycosylases to remove the sugar moiety on one strand (the probe strand) at a DNA base pair mismatch. The resulting apyrimidinic/ apurinic (AP) site is cleaved by AP endonucleases/lyases either associated with the DNA glycosylase or externally added to the reaction mixture.

The use of dynamic size-sieving capillary electrophoresis and mismatch repair enzymes for mutant DNA analysis.

The detection of base pair mismatches in limiting amounts of DNA is important in the early diagnosis of cancer and other genetic diseases. The specific type and exact location of a bp mismatch in certain genes can yield information on the likelihood of a patient developing a genetic disease, as well as the severity of the disease. We demonstrate two methods of specific DNA point mutation detection and identification that involve the integration of mismatch repair cleavage enzyme analyses with dynamic size-sieving capillary electrophoresis.

GATA-6 stimulates a cell line-specific activation element in the human lactase promoter.

Lactase-phlorizin hydrolase (LPH) synthesis is restricted to differentiated small intestinal enterocytes and is highly regulated during development. Analysis of expression of LPH promoter segments fused with luciferase transfected in Caco-2 cells, a line that uniquely expresses LPH mRNA, mapped an 18-base pair (bp) segment 100 bp upstream of the transcription start site that is required for transactivation. Remarkably, the LPH upstream element (LUE) has no stimulatory activity in both human intestinal and nonintestinal lines in which LPH mRNA is absent.

A transactivator of c-myc is coordinately regulated with the proto-oncogene during cellular growth.

A recently cloned nuclear protein, which binds a far upstream element (FUSE) of the human c-myc proto-oncogene, stimulates promoter driven expression in undifferentiated cells. In concert with a loss of c-myc expression, both FUSE binding protein (FBP) mRNA and protein levels disappeared in HL60 cells after PMA-induced differentiation, due to a drop in the rate of transcription that was measured by nuclear runoff. During the differentiation of these cells, the brief half-lives of FBP mRNA (3 h) and protein (1.

Targeted melting and binding of a DNA regulatory element by a transactivator of c-myc.

A far upstream element (FUSE) of c-myc stimulates promoter activity when bound by a newly identified trans-acting protein, which is expressed in cycling cells. Since FUSE binding protein (FBP) binds only the noncoding strand (NCS) of its regulatory element in a sequence-specific manner, and not double-stranded (ds) DNA, formation of the protein DNA complex in vivo first requires unwinding of the DNA helix. In this report, we show evidence that FBP forces strand separation of short stretches of linear dsDNA.