Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.1.22.1 (
DNase II
)
429
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Several types of DNA cuts are used as markers of apoptosis for detection of apoptotic cells in situ. We recently introduced a ligase-based in situ assay that is specific for a single type of DNA damage--a double-strand break of DNase I-type, bearing 5'PO4. Here we describe a vaccinia
topoisomerase I
-based approach to label another type of DNA damage in situ--a double-strand break of
DNase II
-type, bearing 5'OH. The assay uses a new type of probe, a molecular oscillator. The probe self-assembles in solution out of a dual-hairpin oligonucleotide and vaccinia
topoisomerase I
. The enzyme continuously separates and religates two fluorescently labeled hairpins, which can participate in energy transfer. We describe the successful combination of topoisomerase-and ligase-based systems into an in situ assay. The assay uses an oscillating probe for simultaneous detection of two types of DNA cuts in tissue sections.
...
PMID:Oscillating probe for dual detection of 5'PO4 and 5'OH DNA breaks in tissue sections. 1678 20
Naturally occurring bio-molecular machines work in every living cell and display a variety of designs. Yet the development of artificial molecular machines centers on devices capable of directional motion, i.e. molecular motors, and on their scaled-down mechanical parts (wheels, axels, pendants etc). This imitates the macro-machines, even though the physical properties essential for these devices, such as inertia and momentum conservation, are not usable in the nanoworld environments. Alternative designs, which do not follow the mechanical macromachines schemes and use mechanisms developed in the evolution of biological molecules, can take advantage of the specific conditions of the nanoworld. Besides, adapting actual biological molecules for the purposes of nano-design reduces potential dangers the nanotechnology products may pose. Here we demonstrate the assembly and application of one such bio-enabled construct, a semi-artificial molecular device which combines a naturally-occurring molecular machine with artificial components. From the enzymology point of view, our construct is a designer fluorescent enzyme-substrate complex put together to perform a specific useful function. This assembly is by definition a molecular machine, as it contains one. Yet, its integration with the engineered part - fluorescent dual hairpin - re-directs it to a new task of labeling DNA damage. Our construct assembles out of a 32-mer DNA and an enzyme vaccinia
topoisomerase I
(VACC TOPO). The machine then uses its own material to fabricate two fluorescently labeled detector units (Figure 1). One of the units (green fluorescence) carries VACC TOPO covalently attached to its 3'end and another unit (red fluorescence) is a free hairpin with a terminal 3'OH. The units are short-lived and quickly reassemble back into the original construct, which subsequently recleaves. In the absence of DNA breaks these two units continuously separate and religate in a cyclic manner. In tissue sections with DNA damage, the topoisomerase-carrying detector unit selectively attaches to blunt-ended DNA breaks with 5'OH (
DNase II
-type breaks), fluorescently labeling them. The second, enzyme-free hairpin formed after oligonucleotide cleavage, will ligate to a 5'PO(4) blunt-ended break (DNase I-type breaks), if T4 DNA ligase is present in the solution. When T4 DNA ligase is added to a tissue section or a solution containing DNA with 5'PO(4) blunt-ended breaks, the ligase reacts with 5'PO(4) DNA ends, forming semi-stable enzyme-DNA complexes. The blunt ended hairpins will interact with these complexes releasing ligase and covalently linking hairpins to DNA, thus labeling 5'PO(4) blunt-ended DNA breaks. This development exemplifies a new practical approach to the design of molecular machines and provides a useful sensor for detection of apoptosis and DNA damage in fixed cells and tissues.
...
PMID:In vitro assembly of semi-artificial molecular machine and its use for detection of DNA damage. 2225 63
