Express FRET Labeling and Analysis of Phagocytic Clearance.

Lysosomal DNase II in phagocytic digestion produces DNA ends with 3'PO4/5'OH, which differ from those created in apoptotic DNA fragmentation, and can be used to label phagocytic clearance of cell death. Here, we describe the use of these specific DNA ends as selective markers of phagocytic reaction in cell suspensions. The approach does not require cell fixation. It selectively labels blunt-ended DNA breaks with terminal 5'OH. The detection is performed by ultra-fast FRET probes in a single step, closed-tube procedure. It takes 3 min and is signaled by fluorescence. The full step-by-step protocol is presented as well as instructions on analysis and representation of the results.The described DNA-end-based phagocytosis marker and the new rapid FRET assay can be useful in studies of phagocytosis, apoptosis and in immune system assessments.

Quick Detection of DNase II-Type Breaks in Formalin-Fixed Tissue Sections.

Blunt-ended DNase II-type breaks with 5' hydroxyls are generated in phagocytic cells of any lineage during digestion of the engulfed DNA. These breaks indicate the ongoing active phagocytic reaction. They are produced by the acid deoxyribonuclease-DNase II which is the primary endonuclease responsible for DNA degradation after its engulfment.Here, we present an express approach that detects blunt-ended 5' OH DNA breaks in fixed tissue sections. The technique is simple to perform and takes only 60 min to complete. It can be useful in studies of the clearance of dying cells in oncological, inflammatory, and autoimmune disorders.

Zebra Tail Amplification: Accelerated Detection of Apoptotic Blunt-Ended DNA Breaks by In Situ Ligation.

In situ ligation (ISL) is a simple and specific technique for apoptosis labeling in tissue sections. In its most economical version ISL uses ordinary PCR-labeled DNA fragments as probes. In tissue sections these makeshift probes are ligated to apoptotic DNA breaks by T4 DNA ligase. The approach can selectively label 5'PO4 DNA breaks with blunt ends, and is the histological equivalent of electrophoretic apoptotic ladder detection. The main drawback of this technique is its low speed, as it requires 18 h-incubation for efficient labeling. Here, we describe an easy modification of ISL which reduces the incubation time to 1 h and converts ISL into a rapid detection method taking ~3 h overall. Signal enhancement is achieved by a new type of isothermal amplification reaction which generates "zebra tails"- long and labeled extensions of the probes attached to DNA breaks.

Apoptotic Bodies: Selective Detection in Extracellular Vesicles.

Normal and dying cells release various types of membrane-bound vesicles including microvesicles, exosomes, and apoptotic bodies. These vesicles play important roles in intercellular communication and signal transduction. However, their diverse forms and subtypes fluctuate in size and other properties. In result current purification approaches do not fully discriminate between different categories of extracellular vesicles. Here, we present a fluorescence technique that specifically identifies apoptotic bodies in preparations of microvesicles, exosomes, and other extracellular vesicles.The approach exclusively labels the vesicles that contain DNA with 5'PO4 blunt-ended DNA breaks, such as those produced by the apoptotic CAD nuclease during apoptotic DNA degradation. The technique can be useful in studies of apoptosis involving microvesicles and exosomes.

Dual Detection of Nucleolytic and Proteolytic Markers of Lysosomal Cell Death: DNase II-Type Breaks and Cathepsin D.

Lysosomes contain hydrolytic enzymes that can degrade proteins and DNA. Leakage of these reactive compounds through a compromised lysosomal membrane causes lysosomal cell death, which can have apoptotic, necrotic, or mixed morphology. Lysosomal cathepsin proteases, such as cathepsin D, and the lysosomal endonuclease, DNase II, have both been implicated in lysosome-related cell death. Here, we present a fluorescence dual-labeling technique for simultaneous visualization of these two markers of lysosomal activity linked to cell death. The approach labels the intracellular distribution of cathepsin D and the sites with DNase II-type breaks in fixed tissue sections. It determines the lysosomal or extra-lysosomal localization of the markers and can be useful in studying pathways and signals of lysosomal cell death.

Nanoblinker: Brownian motion powered bio-nanomachine for FRET detection of phagocytic phase of apoptosis.

We describe a new type of bio-nanomachine which runs on thermal noise. The machine is solely powered by the random motion of water molecules in its environment and does not ever require re-fuelling. The construct, which is made of DNA and vaccinia virus topoisomerase protein, can detect DNA damage by employing fluorescence. It uses Brownian motion as a cyclic motor to continually separate and bring together two types of fluorescent hairpins participating in FRET. This bio-molecular oscillator is a fast and specific sensor of 5'OH double-strand DNA breaks present in phagocytic phase of apoptosis. The detection takes 30 s in solution and 3 min in cell suspensions. The phagocytic phase is critical for the effective execution of apoptosis as it ensures complete degradation of the dying cells' DNA, preventing release of pathological, viral and tumor DNA and self-immunization. The construct can be used as a smart FRET probe in studies of cell death and phagocytosis.

Assessing phagocytic clearance of cell death in experimental stroke by ligatable fluorescent probes.

We describe a new histochemical approach for visualization of phagocytic clearance in focal brain ischemia. The approach permits the study of elimination of dead cells in stroke by waste-management phagocytes of any cellular lineage. Although numerous cells of different origins that are capable of phagocytosis are present in ischemic brain, only part of them actively engulf and digest cell corpses. The selective visualization, quantification and analysis of such active phagocytic waste-management are helpful in assessing brain response to ischemia. Efficient cell death clearance is important for brain recovery from ischemic injury, as it opens the way for the subsequent regenerative processes. The failure to clean the corpses would result in a toxic reaction caused by non-degraded DNA and proteins. The described procedure uses fluorescent probes selectively ligated by a viral topoisomerase to characteristic DNA breaks produced in all phagocytes during engulfment and digestion of cells irreversibly damaged by ischemia. The method is a new tool for the investigation of brain reaction to ischemic injury.

Selective detection of phagocytic phase of apoptosis in fixed tissue sections.

Degradation of apoptotic cells is finalized during the phagocytic waste-management phase of apoptosis. This eliminates genetic material present in dying cells which often contain pathological, viral, or cancerous DNA. In the waste-management phase, chromatin of apoptotic cells is engulfed and digested by professional phagocytes or surrounding tissue cells. This process is critical for the efficient completion of apoptosis and its detection is necessary in research on cancer and autoimmune diseases where clearance of dying cells plays the central role. Here we present a rapid and simple fluorescence technique for visualization of phagocytic cells participating in waste management. The detailed step-by-step protocol is provided. The approach works in fixed tissue sections and labels all types of active phagocytic cells which engulf and digest apoptotic chromatin.

Selective transport of cationized fluorescent topoisomerase into nuclei of live cells for DNA damage studies.

The targeted delivery of fluorescently labeled, DNA-modifying proteins into cellular nuclei permits investigation of DNA damage and chromatin function in living cells. Commercially available protein delivery vectors cannot provide selective intranuclear transportation and primarily unload their cargo in the cytoplasm. Here we describe a simple approach for specific intranuclear transportation of vaccinia topoisomerase protein based on its cationization. The delivered protein can be observed and monitored by fluorescence microscopy. The technique is cost-efficient and time-saving. It can be useful in live cell studies.

In vitro assembly of semi-artificial molecular machine and its use for detection of DNA damage.

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.

Fluorescent probes detecting the phagocytic phase of apoptosis: enzyme-substrate complexes of topoisomerase and DNA.

In apoptosis, the initial self-driven suicide phase generates cellular corpses which are digested in the phagolysosomes of professional and amateur phagocytes during the subsequent waste-management phase. This ensures the complete elimination of the genetic material which often contains pathological, viral or cancerous DNA sequences. Although the phagocytic phase is critical for the efficient execution of apoptosis, there are currently few methods specifically adapted for its detailed visualization in the fixed tissue section format. To resolve this we developed new fluorescent probes for in situ research. The probes selectively visualize active phagocytic cells of any lineage (professional, amateur phagocytes or surrounding tissue cells) which engulf and digest apoptotic cell DNA. These fluorescent probes are the covalently-bound enzyme-DNA intermediates produced in a topoisomerase reaction with specific "starting" oligonucleotides. They detect a specific marker of DNase II cleavage activity, which occurs exclusively in phagolysosomes of the cells that engulfed apoptotic nuclei. The probes provide snap-shot images of the digestion process occurring in cellular organelles responsible for the actual execution of phagocytic degradation of apoptotic cell corpses. We applied the probes for visualization of the phagocytic reaction in tissue sections of normal thymus and in several human lymphomas. We also discuss the nature, stability and properties of DNase II-type breaks as a marker of phagocytic activity. This development provides a useful fluorescent tool for studies of pathologies where clearance of dying cells is essential, such as cancers, inflammation, infection and auto-immune disorders.

In situ ligation: a decade and a half of experience.

The in situ ligation (ISL) methodology detects apoptotic cells by the presence of characteristic DNA double-strand breaks. A labeled double-stranded probe is ligated to the double-strand breaks in situ on tissue sections. Like the popular TUNEL assay, ISL detects cells in apoptosis based on the ongoing destruction of DNA by apoptotic nucleases. In comparison to TUNEL, it is more specific for apoptosis versus other causes of DNA damage, both repairable damage and necrosis. In the decade and a half since its introduction, ISL has been used in several hundred publications. Here we review the development of the method, its current status, and its uses and limitations.

In situ ligation simplified: using PCR fragments for detection of double-strand DNA breaks in tissue sections.

The simplified in situ ligation procedure is described. All reagents for the assay can be easily obtained in any molecular or cell biology laboratory. The technique uses ligation of double-stranded, PCR-derived DNA fragments labeled with digoxigenin or fluorophores for highly selective detection of apoptotic cells in paraffin-embedded tissue sections. Two types of DNA fragments prepared by PCR are employed. The fragment synthesized by Taq polymerase contains single-base 3' overhangs, whereas the Pfu polymerase-made fragment is blunt ended. Both fragments can be used as specific, sensitive and cost-effective DNA damage probes. After ligation to apoptotic nuclei in tissue sections, they indicate the presence of double-strand DNA breaks with single-base 3' overhangs as well as blunt ends.

In situ labeling of DNA breaks and apoptosis by T7 DNA polymerase.

The native T7 DNA polymerase is a fast and highly processive enzyme that can be used for in situ detection of apoptosis and various types of DNA breaks. The technique is quick and simple, and was shown to label earlier stages of apoptosis compared to the terminal transferase technique. The in situ labeling applications of T7 DNA polymerase are presented and summarized from the DNA damage detection standpoint. The detailed protocols are provided together with the discussion of their advantages and limitations.

5'OH DNA breaks in apoptosis and their labeling by topoisomerase-based approach.

Recently, the concept of apoptotic cell elimination was expanded and programed cell death is no longer viewed as an individual cellular event. The complete description of the apoptotic process now includes two phases: the self-driven cell disassembly and the externally-controlled elimination of apoptotic cell corpses by phagocytizing cells. The second, phagocytic phase is essential, highly conserved, and is even more important than the internal phase of cell disassembly. This is because it ensures the complete degradation of the dying cell's DNA, preventing the release of pathological, viral and tumor DNA, and self-immunization. In different cells and species from mammals to flies, a single conserved enzyme--DNase II is responsible for the elimination of cellular DNA in the second "mopping up" phase of apoptosis. Here, we present an assay for the selective detection of the phagocytic phase of apoptosis. The technology capitalizes on the fact that phagocytic DNase II produces identifiable signature DNA breaks, which can be labeled by vaccinia topoisomerase. The assay permits labeling of the previously underestimated phase of apoptotic execution and is a useful tool in the apoptosis detection arsenal.

Oscillating probe for dual detection of 5'PO4 and 5'OH DNA breaks in tissue sections.

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.

Horseradish peroxidase-driven fluorescent labeling of nanotubes with quantum dots.

We describe the first enzyme-driven technique for fluorescent labeling of single-walled carbon nanotubes (SWNTs). The labeling was performed via enzymatic biotinylation of nanotubes in the tyramide-horseradish peroxidase (HRP) reaction. Both direct and indirect fuorescent labeling of SWNTs was achieved using either biotinyl tyramide or fluorescently tagged tyramides. Biotinylated SWNTs later reacted with streptavidin-conjugated fluorophores. Linking semiconductor nanocrystals, quantum dots (Q-dots), to the surface of nanotubes resulted in their fluorescent visualization, whereas conventional fluorophores bound to SWNTs directly or through biotin-streptavidin linkage, were completely quenched. Enzymatic biotinylation permits fluorescent visualization of carbon nanotubes, which could be useful for a number of biomedical applications. In addition, other organic molecules such as proteins, antibodies, or DNA can be conjugated to biotinylated SWNTs using this approach.

Visualization of individual single-walled carbon nanotubes by fluorescent polymer wrapping.

Manipulating optical properties of single-walled nanotubes (SWNTs) is necessary for the development of nanoscale optical devices and probes for biomedical research. In life sciences it will make possible the direct observation of SWNTs inside living cells using optical microscopes. In the nanotechnology field it will enable the development of nanosensors with fluorescent reporting. However, the direct fluorescent labeling of SWNTs is obstructed by their strong light quenching qualities. Besides, chemical functionalization of SWNTs needed for the covalent attachment of fluorescent dyes could change favorable properties of nanotubes. Here we report that optical properties of SWNTs can be manipulated without their covalent modification by wrapping them with fluorescently labeled polymer poly(vinylpyrrolidone) (PVP-1300). Fluorescent PVP-1300 forms a monomolecular approximately 2.5 nm thick layer coiling around individual SWNTs and nanotube bundles. PVP casing is fluorescent although it is only several nanometers thick. This makes individual SWNTs observable by a fluorescent microscope. The spare polymer strands left over after wrapping around the relatively shorter nanotubes form junctions between SWNTs tying them together into new configurations, primarily Y- and psi-type junctions. The ability to use a single fluorescent polymer strand to fasten nanotubes together can be useful in assembly of nanotube-made devices. In PVP-covered SWNTs multiple fluorophores are attached to each single nanotube making them unique composite fluorophores attractive as parts of biological fluorescent probes and in the development of the new materials in photonics and nanotechnology.

Semi-artificial Fluorescent Molecular Machine for DNA Damage Detection.

The design of artificial molecular machines is complicated because the mechanics used in macromachines is not readily adaptable for nano environments. We constructed a semi-artificial molecular device, which contains a naturally occurring molecular machine-a vaccinia virus encoded protein-linked with an artificial part. The self-assembled construct makes two fluorescently labeled detector units. It is the first sensor capable of selectively detecting different types of DNA breaks, exemplifying a practical approach to the design of molecular devices.

Thimerosal induces DNA breaks, caspase-3 activation, membrane damage, and cell death in cultured human neurons and fibroblasts.

Thimerosal is an organic mercurial compound used as a preservative in biomedical preparations. Little is known about the reactions of human neuronal and skin cells to its micro- and nanomolar concentrations, which can occur after using thimerosal-containing products. A useful combination of fluorescent techniques for the assessment of thimerosal toxicity is introduced. Short-term thimerosal toxicity was investigated in cultured human cerebral cortical neurons and in normal human fibroblasts. Cells were incubated with 125-nM to 250-microM concentrations of thimerosal for 45 min to 24 h. A 4', 6-diamidino-2-phenylindole dihydrochloride (DAPI) dye exclusion test was used to identify nonviable cells and terminal transferase-based nick-end labeling (TUNEL) to label DNA damage. Detection of active caspase-3 was performed in live cell cultures using a cell-permeable fluorescent caspase inhibitor. The morphology of fluorescently labeled nuclei was analyzed. After 6 h of incubation, the thimerosal toxicity was observed at 2 microM based on the manual detection of the fluorescent attached cells and at a 1-microM level with the more sensitive GENios Plus Multi-Detection Microplate Reader with Enhanced Fluorescence. The lower limit did not change after 24 h of incubation. Cortical neurons demonstrated higher sensitivity to thimerosal compared to fibroblasts. The first sign of toxicity was an increase in membrane permeability to DAPI after 2 h of incubation with 250 microM thimerosal. A 6-h incubation resulted in failure to exclude DAPI, generation of DNA breaks, caspase-3 activation, and development of morphological signs of apoptosis. We demonstrate that thimerosal in micromolar concentrations rapidly induce membrane and DNA damage and initiate caspase-3-dependent apoptosis in human neurons and fibroblasts. We conclude that a proposed combination of fluorescent techniques can be useful in analyzing the toxicity of thimerosal.