Acridine orange

Last updated
Acridine orange
Acridine Orange.svg
Acridine-orange-3D-balls.png
Names
Preferred IUPAC name
N,N,N′,N′-Tetramethylacridine-3,6-diamine
Systematic IUPAC name
3-N,3-N,6-N,6-N-Tetramethylacridine-3,6-diamine
Other names
3,6-Acridinediamine

Acridine Orange Base
Acridine Orange NO
Basic Orange 14
Euchrysine
Rhoduline Orange
Rhoduline Orange N
Rhoduline Orange NO
Solvent Orange 15

Waxoline Orange A

Contents

Identifiers
3D model (JSmol)
ChEBI
ChEMBL
ChemSpider
ECHA InfoCard 100.122.153 OOjs UI icon edit-ltr-progressive.svg
EC Number
  • 200-614-0
KEGG
MeSH Acridine+orange
PubChem CID
RTECS number
  • AR7601000
UNII
  • InChI=1S/C17H19N3/c1-19(2)14-7-5-12-9-13-6-8-15(20(3)4)11-17(13)18-16(12)10-14/h5-11H,1-4H3 Yes check.svgY
    Key: DPKHZNPWBDQZCN-UHFFFAOYSA-N Yes check.svgY
  • InChI=1/C17H19N3/c1-19(2)14-7-5-12-9-13-6-8-15(20(3)4)11-17(13)18-16(12)10-14/h5-11H,1-4H3
    Key: DPKHZNPWBDQZCN-UHFFFAOYAJ
  • n1c3c(cc2c1cc(N(C)C)cc2)ccc(c3)N(C)C
Properties
C17H19N3
Molar mass 265.360 g·mol−1
AppearanceOrange powder
Hazards
GHS labelling:
GHS-pictogram-skull.svg GHS-pictogram-exclam.svg
Warning
H302, H312, H341
P281, P304+P340
NFPA 704 (fire diamond)
NFPA 704.svgHealth 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 0: Will not burn. E.g. waterInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
0
0
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
X mark.svgN  verify  (what is  Yes check.svgYX mark.svgN ?)

Acridine orange is an organic compound that serves as a nucleic acid-selective fluorescent dye with cationic properties useful for cell cycle determination. Acridine orange is cell-permeable, which allows the dye to interact with DNA by intercalation, or RNA via electrostatic attractions. When bound to DNA, acridine orange is very similar spectrally to an organic compound known as fluorescein. Acridine orange and fluorescein have a maximum excitation at 502nm and 525 nm (green). When acridine orange associates with RNA, the fluorescent dye experiences a maximum excitation shift from 525 nm (green) to 460 nm (blue). The shift in maximum excitation also produces a maximum emission of 650 nm (red). Acridine orange is able to withstand low pH environments, allowing the fluorescent dye to penetrate acidic organelles such as lysosomes and phagolysosomes that are membrane-bound organelles essential for acid hydrolysis or for producing products of phagocytosis of apoptotic cells. Acridine orange is used in epifluorescence microscopy and flow cytometry. The ability to penetrate the cell membranes of acidic organelles and cationic properties of acridine orange allows the dye to differentiate between various types of cells (i.e., bacterial cells and white blood cells). The shift in maximum excitation and emission wavelengths provides a foundation to predict the wavelength at which the cells will stain. [1]

Optical properties

When the pH of the environment is 3.5, acridine orange becomes excited by blue light (460 nm). When acridine orange is excited by blue light, the fluorescent dye can differentially stain human cells green and prokaryotic cells orange (600 nm), allowing for rapid detection with a fluorescent microscope. The differential staining capability of acridine orange provides quick scanning of specimen smears at lower magnifications of 400x compared to Gram stains that operate at 1000x magnification. The differentiation of cells is aided by a dark background that allows colored organisms to be easily detected. The sharp contrast provides a mechanism for counting the number of organisms present in a sample. When acridine orange binds to DNA, the dye exhibits a maximum excitation at 502 nm producing a maximum emission of 525 nm. When bound to RNA, acridine orange displays a maximum emission value of 650 nm and a maximum excitation value of 460 nm. The maximum excitation and emission value that occur when acridine orange is bound to RNA are the result of electrostatic interactions and the intercalation between the acridine molecule and nucleic acid-base pairs present within RNA and DNA. [2]

Preparation

Acridine dyes are prepared via the condensation of 1,3-diaminobenzene with suitable benzaldehydes. Acridine orange is derived from dimethylaminobenzaldehyde and N,N-dimethyl-1,3-diaminobenzene. [3] It may also be prepared by the Eschweiler–Clarke reaction of 3,6-Acridinediamine.

History

Acridine orange is derived from the organic molecule acridine, which was first discovered by Carl Grabe and Heinrich Caro, who isolated acridine by boiling coal in Germany during the late nineteenth century. Acridine has antimicrobial factors useful in drug-resistant bacteria and isolating bacteria in various environments. [4] Acridine orange in the mid-twentieth century was used to examine the microbial content found in soil and direct counts of aquatic bacteria. Additionally, the method of acridine orange direct count (AODC) proved useful in the enumeration of bacteria found within landfills. Direct epifluorescent filter technique (DEFT) using acridine orange is a method known for examining the microbial content within food and water. The use of acridine orange in clinical applications has become widely accepted, mainly focusing on highlighting bacteria in blood cultures. Past and present studies comparing acridine orange staining with blind subcultures for the detection of positive blood cultures showed that the acridine orange is a simple, inexpensive, rapid staining procedure that appears to be more sensitive than the Gram stain for detecting microorganisms in cerebrospinal fluid and other clinical and non-clinical materials. [3]

Applications

Acridine orange has been widely accepted and used in many different areas, such as epifluorescence microscopy, and the assessment of sperm chromatin quality. Acridine orange is useful in the rapid screening of ordinarily sterile specimens. When acridine orange is used with flow cytometry, the differential stain is used to measure DNA denaturation [5] and the cellular content of DNA versus RNA [6] in individual cells, or detect DNA damage in infertile sperm cells. [7] Acridine orange is recommended for the use of fluorescent microscopic detection of microorganisms in smears prepared from clinical and non-clinical materials. Acridine orange staining has to be performed at an acidic pH to obtain the differential staining, which allows bacterial cells to stain orange and tissue components to stain yellow or green. [8]

Acridine orange is recorded as being used as a curing agent to cure selectable marker in antibiotic resistant organisms present in a sample. When isolates are subjected to curing in the presence of acridine orange, a substantial number were recorded to have been cured of at least one resistant marker.[ citation needed ] Acridine orange is also used to stain acidic vacuoles (lysosomes, endosomes, and autophagosomes), RNA, and DNA in living cells. This method is a cheap and easy way to study lysosomal vacuolation, autophagy, and apoptosis. The emission color of acridine orange changes from yellow, to orange, to red as the pH drops in an acidic vacuole of the living cell. Under specific conditions of ionic strength and concentration, acridine orange emits red fluorescence when it binds to RNA by stacking interactions, and green fluorescence when it binds to DNA by intercalation. Depending on acridine orange concentration, nuclei may emit yellowish-green fluorescence in untreated cells, and green fluorescence when RNA synthesis is inhibited by compounds such as chloroquine. [9] Acridine orange can be used in conjunction with ethidium bromide or propidium iodide to differentiate between viable, apoptotic, and necrotic cells. Additionally, acridine orange may be used on blood samples causing bacterial DNA to fluoresce, aiding in the clinical diagnosis of bacterial infections, such as meningitis. [3]

Related Research Articles

<span class="mw-page-title-main">Reticulocyte</span> Immature red blood cell

In hematology, reticulocytes are immature red blood cells (RBCs). In the process of erythropoiesis, reticulocytes develop and mature in the bone marrow and then circulate for about a day in the blood stream before developing into mature red blood cells. Like mature red blood cells, in mammals, reticulocytes do not have a cell nucleus. They are called reticulocytes because of a reticular (mesh-like) network of ribosomal RNA that becomes visible under a microscope with certain stains such as new methylene blue and Romanowsky stain.

<span class="mw-page-title-main">Fluorescent tag</span>

In molecular biology and biotechnology, a fluorescent tag, also known as a fluorescent label or fluorescent probe, is a molecule that is attached chemically to aid in the detection of a biomolecule such as a protein, antibody, or amino acid. Generally, fluorescent tagging, or labeling, uses a reactive derivative of a fluorescent molecule known as a fluorophore. The fluorophore selectively binds to a specific region or functional group on the target molecule and can be attached chemically or biologically. Various labeling techniques such as enzymatic labeling, protein labeling, and genetic labeling are widely utilized. Ethidium bromide, fluorescein and green fluorescent protein are common tags. The most commonly labelled molecules are antibodies, proteins, amino acids and peptides which are then used as specific probes for detection of a particular target.

<span class="mw-page-title-main">Ethidium bromide</span> DNA gel stain and veterinary drug

Ethidium bromide is an intercalating agent commonly used as a fluorescent tag in molecular biology laboratories for techniques such as agarose gel electrophoresis. It is commonly abbreviated as EtBr, which is also an abbreviation for bromoethane. To avoid confusion, some laboratories have used the abbreviation EthBr for this salt. When exposed to ultraviolet light, it will fluoresce with an orange colour, intensifying almost 20-fold after binding to DNA. Under the name homidium, it has been commonly used since the 1950s in veterinary medicine to treat trypanosomiasis in cattle. The high incidence of antimicrobial resistance makes this treatment impractical in some areas, where the related isometamidium chloride is used instead. Despite its reputation as a mutagen, tests have shown it to have low mutagenicity without metabolic activation.

<span class="mw-page-title-main">Staining</span> Technique used to enhance visual contrast of specimens observed under a microscope

Staining is a technique used to enhance contrast in samples, generally at the microscopic level. Stains and dyes are frequently used in histology, in cytology, and in the medical fields of histopathology, hematology, and cytopathology that focus on the study and diagnoses of diseases at the microscopic level. Stains may be used to define biological tissues, cell populations, or organelles within individual cells.

<span class="mw-page-title-main">Flow cytometry</span> Lab technique in biology and chemistry

Flow cytometry (FC) is a technique used to detect and measure the physical and chemical characteristics of a population of cells or particles.

<span class="mw-page-title-main">Fluorophore</span> Agents that emit light after excitation by light

A fluorophore is a fluorescent chemical compound that can re-emit light upon light excitation. Fluorophores typically contain several combined aromatic groups, or planar or cyclic molecules with several π bonds.

<span class="mw-page-title-main">Fluorescence microscope</span> Optical microscope that uses fluorescence and phosphorescence

A fluorescence microscope is an optical microscope that uses fluorescence instead of, or in addition to, scattering, reflection, and attenuation or absorption, to study the properties of organic or inorganic substances. "Fluorescence microscope" refers to any microscope that uses fluorescence to generate an image, whether it is a simple set up like an epifluorescence microscope or a more complicated design such as a confocal microscope, which uses optical sectioning to get better resolution of the fluorescence image.

<span class="mw-page-title-main">DAPI</span> Fluorescent stain

DAPI, or 4′,6-diamidino-2-phenylindole, is a fluorescent stain that binds strongly to adenine–thymine-rich regions in DNA. It is used extensively in fluorescence microscopy. As DAPI can pass through an intact cell membrane, it can be used to stain both live and fixed cells, though it passes through the membrane less efficiently in live cells and therefore provides a marker for membrane viability.

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<span class="mw-page-title-main">Nile blue</span> Chemical compound

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Propidium iodide is a fluorescent intercalating agent that can be used to stain cells and nucleic acids. PI binds to DNA by intercalating between the bases with little or no sequence preference. When in an aqueous solution, PI has a fluorescent excitation maximum of 493 nm (blue-green), and an emission maximum of 636 nm (red). After binding DNA, the quantum yield of PI is enhanced 20-30 fold, and the excitation/emission maximum of PI is shifted to 535 nm (green) / 617 nm (orange-red). Propidium iodide is used as a DNA stain in flow cytometry to evaluate cell viability or DNA content in cell cycle analysis, or in microscopy to visualize the nucleus and other DNA-containing organelles. Propidium Iodide is not membrane-permeable, making it useful to differentiate necrotic, apoptotic and healthy cells based on membrane integrity. PI also binds to RNA, necessitating treatment with nucleases to distinguish between RNA and DNA staining. PI is widely used in fluorescence staining and visualization of the plant cell wall.

<span class="mw-page-title-main">Texas Red</span> Chemical compound

Texas Red or sulforhodamine 101 acid chloride is a red fluorescent dye, used in histology for staining cell specimens, for sorting cells with fluorescent-activated cell sorting machines, in fluorescence microscopy applications, and in immunohistochemistry. Texas Red fluoresces at about 615 nm, and the peak of its absorption spectrum is at 589 nm. The powder is dark purple. Solutions can be excited by a dye laser tuned to 595-605 nm, or less efficiently a krypton laser at 567 nm. The absorption extinction coefficient at 596 nm is about 85,000 M−1cm−1.

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References

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  8. "Review" (PDF). ki.se.
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