File:3D-animation of the diatom Corethron sp.ogg|thumb|upright=1.7| (a) Green: [DiOC6(3) fluorescence] - stains cellular membranes indicating the core cell bodies(b) Cyan: [PLL-A546 fluorescence] - generic counterstain for visualising eukaryotic cell surfaces(c) Blue: [Hoechst fluorescence] - stains DNA, identifies nuclei(d) Red: [chlorophyll autofluorescence] - resolves chloroplasts
sperm stained with
SYBR green in a
cuvette illuminated by blue light in an epifluorescence microscope. The SYBR green in the sample binds to the herring sperm
DNA and, once bound, fluoresces giving off green light when illuminated by blue light. In order for a sample to be suitable for fluorescence microscopy it must be fluorescent. There are several methods of creating a fluorescent sample; the main techniques are labelling with fluorescent stains or, in the case of biological samples,
expression of a
fluorescent protein. Alternatively the intrinsic fluorescence of a sample (i.e.,
autofluorescence) can be used. A new peptide, known as the
Collagen Hybridizing Peptide, can also be conjugated with
fluorophores and used to stain
denatured collagen fibers. Staining of the plant
cell walls is performed using stains or dyes that bind
cellulose or
pectin. The quest for fluorescent probes with a high specificity that also allow live imaging of plant cells is ongoing. There are many fluorescent molecules called
fluorophores or
fluorochromes such as
fluorescein,
Alexa Fluors, or
DyLight 488, which can be chemically linked to a different molecule which binds the target of interest within the sample.
Immunofluorescence Immunofluorescence is a technique which uses the highly specific binding of an
antibody to its
antigen in order to label specific proteins or other molecules within the cell. A sample is treated with a primary antibody specific for the molecule of interest. A fluorophore can be directly conjugated to the primary antibody. Alternatively a
secondary antibody, conjugated to a fluorophore, which binds specifically to the first antibody can be used. For example, a primary antibody raised in a mouse which recognises
tubulin combined with a secondary anti-mouse antibody derivatised with a fluorophore could be used to label
microtubules in a cell.
Fluorescent proteins The modern understanding of
genetics and the techniques available for modifying DNA allow scientists to genetically modify proteins to also carry a fluorescent protein reporter. In biological samples this allows a scientist to directly make a protein of interest fluorescent. The protein location can then be directly tracked, including in live cells. ==Limitations==