A single nucleotide substitution in the promoter region of the apolipoprotein C-II gene identified in individuals with chylomicronemia.

Apolipoprotein (apo) C-II plays a major role as a cofactor for lipoprotein lipase, the enzyme involved in the hydrolysis of triglyceride-rich particles. We identified in two relatives of a family (mother and son) massive hypertriglyceridemia with chylomicronemia. In these individuals apoC-II was not measurable in plasma by radial immunodiffusion. On isoelectric focusing of very low density apolipoproteins, trace amounts of apoC-II became obvious in the regular position. By sequencing, no abnormalities in the exons or neighboring intron sequences were detected. However, three alterations in the DNA sequence were found upstream from the transcription initiation site. Two variations could be explained by differences in previously published DNA sequences. The third variation (A-->G; position -86; Das et al. 1987. J. Biol. Chem. 262: 4787-4793) was present only in the homozygous form in the two hypertriglyceridemic probands. In 46 hypertriglyceridemic individuals outside the family, this mutation was not found. In electrophoretic mobility shift experiments with nuclear extracts from HepG2 cells, the 31 bp DNA fragment carrying the A-->G substitution resulted in a markedly diminished protein binding compared with the wildtype DNA fragment. In promoter reporter gene assays, the activity of the basal promoter was reduced in the case of the A-->G substitution and the deletion of the bases -91 to -58. The pedigree analysis and the experimental results are evidence that this is the first mutation in the apolipoprotein C-II gene where a single nucleotide substitution diminishes the binding of a transcription factor to a positive cis-acting clement in the promoter resulting in a depletion of apolipoprotein C-II in plasma.

Structure of the human apolipoprotein C-II gene promoter.

To localize transcriptional active cis elements and to study the effect of a single base transition at -86 derived from a patient (PS) with an inherited severe form of hypertriglyceridemia a reporter gene transfection assay with apo C-II promoter fragments was performed. Sequences from -170 to -140, -140 to -59 and -59 to -39 were transcriptional active. The A to G transition at -86 reduced promoter activity to 25% (pC2PS-13). A nuclear protein bound sequence specific to a DNA fragment from -102 to -70, but disappeared when the point mutation at -86 was introduced. We found that one of these cis elements enhances promoter activity as a response of cAMP elevation. Apo CII mRNA level increases after incubation of HepG2 cells with 10 microM forskolin within 2 hours as measured by northern blot analyses. Incubation of transfected cells (pC2W) with forskolin [10 microM] or a cAMP analogue resulted in an 6-fold increase of luciferase activity within 6 hours and a subsequent decrease. The results suggest that several positive acting elements are located between -170 and -36 and that one of them may be responsible for promoter activation by cAMP. The reduction of promoter activity by the point mutation may be a consequence of impaired protein-DNA interaction.

[Partially automated antigen determination and antibody detection with microtiter plates]. / Teilautomatisierte Antigenbestimmung und Antikörpersuche auf Mikrotitrationsplatten.

In addition to several conventional methods for the detection of red cell antigens, the use of microplates has various advantages either as a solid-phase assay (enzyme immunoassay) or as native microplate. Microplates may also be used for the detection of red cell antibodies in 'pooled-cell solid-phase assays' of the second generation and for antibody screening. Blood donors and patients are the two main fields which are to be examined in immunohematology. There are various advantages in using the microplate in blood group serology: (i) if there is hardware already available, like sample processors and microplate readers, the use of microplates in blood group serology reduces the costs even if the equipment has to be purchased for this purpose only; (ii) low quantities of reagents are used in microplate assays; (iii) the application of bar codes on tubes and microplates guarantees the most security in sample identification; (iv) it is possible to investigate blood samples selectively depending on the available software if antibody detection is done as the sixth test beside anti-HIV, anti-HCV, HBsAG, lues antibodies and ALT, and (v) recording of data will be easy if electronic data processing is used.