A rapid method for the determination of human CEA/mouse anti-CEA immune complexes in patients undergoing immunoscintigraphy.

We report here on a new and quick procedure to isolate human (hu) CEA mouse anti CEA immune complexes of sera from patients admitted for immunoscintigraphy with radiolabeled monoclonal anti CEA antibody. This method employs rabbit anti mouse IgG immune affinity chromatography together with a commercial CEA-IRMA kit for the specific isolation of immune complexes. By applying this procedure we were able to show that immune complex formation increased in parallel to CEA serum concentration.

Proliferation-associated expression of DNA methyltransferase in human embryonic lung cells.

The cell cycle-dependent and proliferation-associated expression of the enzyme DNA methyltransferase has been evaluated immunocytochemically in synchronized L-132 human embryonic lung cells, using the anti-DNA methyltransferase monoclonal antibody M1F6D7/5C10. DNA methyltransferase-reactivity was firstly seen in mid-G1 cells. An intense and granular reaction in the cell nuclei with a sparing of the nucleoli was observed in addition to a homogenous and faint cytoplasmic staining.

Polypeptide composition and an immunological analysis of DNA methyltransferases from different species.

The cross-reactivity of the monoclonal anti-human placental DNA methyltransferase antibody M2B10 with DNA methyltransferases isolated from other species was investigated. This antibody immunoprecipitates DNA methyltransferases from mammalian cells, i.e.

Isolation and characterization of proteins that stimulate the activity of mammalian DNA methyltransferase.

Previously, the purification of DNA methyltransferase from murine P815 mastocytoma cells by immunoaffinity chromatography was described (Pfeifer, G.P., Grünwald, S.

Reduced methyl group acceptance of 1-beta-D-arabinofuranosylcytosine-containing DNA polymers.

Previous studies have shown that 1-beta-D-arabinofuranosylcytosine (ara-C) can induce differentiation of various malignant cells and that DNA methylation patterns become altered under ara-C treatment of those cells. The aim of this study was to investigate whether this influence on DNA methylation is caused by a direct effect of DNA-incorporated ara-C molecules on nuclear DNA methylase. For this reason, we constructed various ara-C-substituted DNA polymers and used them as substrates for highly purified eukaryotic DNA methylase isolated from murine P815 mastocytoma cells.