We report a novel approach for the attachment of DNA fragments to the surface of live cells. By using fluorescence microscopy and flow cytometry we demonstrated that our synthetic conjugates of fatty acid with oligonucleotides can be incorporated in plasma membrane and then hybridized with complementary sequences at the cell surface. Method permits to control amount of immobilized DNA on the cell surface. All procedures can be completed within minutes and do not alter cell viability. Using this approach we tethered floating myeloid HL-60 cells to adherent A431 epitheliocytes in a sequence specific fashion. Thus, this method allows rapid and simple DNA multicoding of the cell surface and, therefore, opens new opportunities in manipulating with cell–cell interactions.
In order to create effective therapeutically significant oligonucleotide structures, a series of analogs of thrombin-binding aptamer d(GGTTGGTGTGGTTGG) containing thiophosphoryl substitutions were synthesized. The anticoagulation effects of the resultant thrombin-binding aptamer analogs were evaluated and the effects of local thiomodifications on their structure and function were studied, including the effects on stability in blood plasma and resistance to DNA nucleases. A promising modified oligonucleotide (LL11) was found with the structure modified only in TT loops. It retains antithrombin properties of thrombin-binding aptamer, but is more resistant to biodegradation.
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