mCherry is a member of the mFruits family of monomeric red fluorescent proteins (mRFPs). As an RFP, mCherry was derived from DsRed of Discosoma sea anemones, unlike green fluorescent proteins (GFPs) which are often derived from Aequorea victoria jellyfish. [1] Fluorescent proteins are used to tag components in cells so that they can be studied using fluorescence spectroscopy and fluorescence microscopy. mCherry absorbs light between 540 and 590 nm and emits light in the range of 550-650 nm. [2] mCherry belongs to the group of fluorescent protein chromophores used as instruments to visualize genes and analyze their functions in experiments. Genome editing has been improved greatly through the precise insertion of these fluorescent protein tags into the genetic material of many diverse organisms. Most comparisons between the brightness and photostability of different fluorescent proteins have been made in vitro , removed from biological variables that affect protein performance in cells or organisms. [3] It is hard to perfectly simulate cellular environments in vitro, and the difference in environment could have an effect on the brightness and photostability.
mRFPs—like mCherry—are useful because they have a lower molecular weight and fold faster than tetramers, which results in reduced disturbance of the target system.
DsRed is isolated from Discosoma sea anemones, and is a tetrameric protein. [1] Most red fluorescent proteins come from DsRed. DsRed has low photostability (resistance to change under the influence of light) and a slow maturation rate (time until half the protein is folded). mRFP1 is derived from DsRed and is a monomer so it is smaller, but its quantum yield and photostability are less than that of DsRed. [1] mCherry and other mFruits have improved brightness and photostability over both DsRed and mRFP1. mCherry was developed through directed evolution from mRFP1 by the group of Roger Tsien at UCSD. [1] The mFruits in general were developed because, while different colored proteins could be found from other anthozoans, the proteins would mostly be tetramers, which would most likely have the same issues as DsRed. These tetramers would require derivations like those done to DsRed to be done in order to make them useful fusion partners. [1] As a result, the mFruits were derived from mRFP1 by adjusting key amino acids in order to adjust the excitation and emission wavelengths. Different colors allow for the tracking of different cell types, transcriptional activity, and fusion in proteins. mCherry, out of all of the true monomers developed, has the longest wavelengths, highest photostability, fastest maturation, excellent pH resistance, and is closest to mRFP1 in its excitation and emission maxima. [1] However, mCherry has a lower quantum yield than mRFP1. [1]
The gene for mCherry is 711bp long, [4] and the protein is made up of 236 residues with a mass of 26.722 kDa. [5] The crystal structure of mCherry was determined in 2006. [6] It contains 3 alpha helices and 13 beta sheets which make up the beta barrel. The chromophore in mCherry is made up of three amino acids, methionine, tyrosine, and glycine, which are post-translationally modified into an imidazolinone. [1] The number of these residues in sequence are 71, 72, and 73 respectively. The extended pi-electron conjugation gives mCherry its red-shifted absorbance and emission. [7] The chromophore forms from a central helix which is shielded from solvent in an 11-stranded beta barrel. [7] This structure is almost identical to the tertiary structure of DsRed which also has an 11-stranded beta barrel, and is similar to GFPs tertiary structure. [8] This makes the environment around the chromophore in mCherry more hydrophobic than the environment around the chromophore of DsRed. [9] The end termini on mCherry are GFP-like, which allows it to be incorporated in to systems where GFP can be used and mRFP1 could not have been used. [1]
mCherry is used in fluorescence microscopy as an intracellular probe. [10] However, when a protein is tagged by fusion to a fluorescent protein, interactions between them can undesirably disturb targeting or function. [11]
mCherry is valued where constitutive gene expression is desired, and other experimental approaches require the coordinated control of multiple genes. While multiple venues have been developed for use in E. coli and other models, the utility and functionality of such techniques does not always translate to other species. For example, for the Gram-negative pathogen Legionella pneumophila , a vector for Legionnaires’ Disease, the Ptac system represents the only well-established expression control system. In order to enhance the tools available to study bacterial gene expression in L. pneumophila, mCherry was developed, which confers constitutive gene expression from a mutagenized LacI binding site. mCherry neither interferes with other plasmids harboring an intact LacI-Ptac expression system nor alters the growth of Legionella species during intracellular growth. The broad-host-range plasmid backbone of mCherry allowed constitutive gene expression in a wide variety of Gram-negative bacterial species, making mCherry a useful tool for the greater research community. [12]
It can be used to label bacteria to visualize them without antibiotic pressure [13] and also be used as a long-wavelength hetero-FRET (fluorescence resonant energy transfer) acceptor and probe for homo-FRET experiments. [14] FRET is a type of fluorescence energy transfer where there is no intermediate photon and the energy is transferred from the donor to the acceptor.
Original RFP: DsRed
First Generation RFP: mRFP1
Second Generation RFPs: mStrawberry, mOrange, dTomato
mFruits are second-generation monomeric red fluorescent proteins (mRFPs) that have improved brightness and photostability compared to the first-generation mRFP1. Their emission and excitation wavelengths are distributed over a range of about 550−650 and 540−590 nm, respectively. However, the variations in their spectra can be traced back to a few key amino acids. Spectroscopic and atomic resolution crystallographic analyses of three representatives, mOrange, mStrawberry, and mCherry, reveal that different mechanisms operate to establish the excitation and emission maxima. Undergoing a second oxidation step, each mFruit produces an acylimine linkage in the polypeptide backbone. In comparison to the progenitor DsRed, direct covalent modification to this linkage (mOrange) and indirect modification of the chromophore environment (mStrawberry and mCherry) produces strong blue- and red-shifted variants. The blue shift of mOrange is induced by a covalent modification of its protein backbone.
The electron-density map indicates the formation of a third heterocycle, 2-hydroxy-dihydrooxazole, upon the reaction of Thr 66 Oγ with the polypeptide backbone, which in turn reduces the conjugation of the carbonyl at position 65 with the rest of the chromophore. In mStrawberry and mCherry, the movement of charged Lys 70 and protonation of Glu 215 are proposed to modify the chromophore electron-density distribution, inducing their signature red shift. [2]
The green fluorescent protein (GFP) is a protein that exhibits green fluorescence when exposed to light in the blue to ultraviolet range. The label GFP traditionally refers to the protein first isolated from the jellyfish Aequorea victoria and is sometimes called avGFP. However, GFPs have been found in other organisms including corals, sea anemones, zoanithids, copepods and lancelets.
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.
In molecular biology, a reporter gene is a gene that researchers attach to a regulatory sequence of another gene of interest in bacteria, cell culture, animals or plants. Such genes are called reporters because the characteristics they confer on organisms expressing them are easily identified and measured, or because they are selectable markers. Reporter genes are often used as an indication of whether a certain gene has been taken up by or expressed in the cell or organism population.
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.
Förster resonance energy transfer (FRET), fluorescence resonance energy transfer, resonance energy transfer (RET) or electronic energy transfer (EET) is a mechanism describing energy transfer between two light-sensitive molecules (chromophores). A donor chromophore, initially in its electronic excited state, may transfer energy to an acceptor chromophore through nonradiative dipole–dipole coupling. The efficiency of this energy transfer is inversely proportional to the sixth power of the distance between donor and acceptor, making FRET extremely sensitive to small changes in distance.
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.
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.
Yellow fluorescent protein (YFP) is a genetic mutant of green fluorescent protein (GFP) originally derived from the jellyfish Aequorea victoria. Its excitation peak is 513 nm and its emission peak is 527 nm. Like the parent GFP, YFP is a useful tool in cell and molecular biology because the excitation and emission peaks of YFP are distinguishable from GFP which allows for the study of multiple processes/proteins within the same experiment.
Roger Yonchien Tsien was an American biochemist. He was a professor of chemistry and biochemistry at the University of California, San Diego and was awarded the Nobel Prize in Chemistry in 2008 for his discovery and development of the green fluorescent protein, in collaboration with organic chemist Osamu Shimomura and neurobiologist Martin Chalfie. Tsien was also a pioneer of calcium imaging.
Douglas C. Prasher is an American molecular biologist. He is known for his work to clone and sequence the genes for the photoprotein aequorin and green fluorescent protein (GFP) and for his proposal to use GFP as a tracer molecule. He communicated his pioneering work to Martin Chalfie and Roger Y. Tsien, but by 1991 he was unable to obtain further research funding, and left academia. Eventually, he had to abandon science. Chalfie and Tsien were awarded the 2008 Nobel Prize in Chemistry for work that they publicly acknowledged was substantially based on Prasher's work; through their efforts and those of others, he returned to scientific research in June 2010.
Kaede is a photoactivatable fluorescent protein naturally originated from a stony coral, Trachyphyllia geoffroyi. Its name means "maple" in Japanese. With the irradiation of ultraviolet light (350–400 nm), Kaede undergoes irreversible photoconversion from green fluorescence to red fluorescence.
EosFP is a photoactivatable green to red fluorescent protein. Its green fluorescence (516 nm) switches to red (581 nm) upon UV irradiation of ~390 nm due to a photo-induced modification resulting from a break in the peptide backbone near the chromophore. Eos was first discovered as a tetrameric protein in the stony coral Lobophyllia hemprichii. Like other fluorescent proteins, Eos allows for applications such as the tracking of fusion proteins, multicolour labelling and tracking of cell movement. Several variants of Eos have been engineered for use in specific study systems including mEos2, mEos4 and CaMPARI.
Fluorescence is used in the life sciences generally as a non-destructive way of tracking or analysing biological molecules. Some proteins or small molecules in cells are naturally fluorescent, which is called intrinsic fluorescence or autofluorescence. Alternatively, specific or general proteins, nucleic acids, lipids or small molecules can be "labelled" with an extrinsic fluorophore, a fluorescent dye which can be a small molecule, protein or quantum dot. Several techniques exist to exploit additional properties of fluorophores, such as fluorescence resonance energy transfer, where the energy is passed non-radiatively to a particular neighbouring dye, allowing proximity or protein activation to be detected; another is the change in properties, such as intensity, of certain dyes depending on their environment allowing their use in structural studies.
A chromoprotein is a conjugated protein that contains a pigmented prosthetic group. A common example is haemoglobin, which contains a heme cofactor, which is the iron-containing molecule that makes oxygenated blood appear red. Other examples of chromoproteins include other hemochromes, cytochromes, phytochromes and flavoproteins.
Calcium imaging is a microscopy technique to optically measure the calcium (Ca2+) status of an isolated cell, tissue or medium. Calcium imaging takes advantage of calcium indicators, fluorescent molecules that respond to the binding of Ca2+ ions by fluorescence properties. Two main classes of calcium indicators exist: chemical indicators and genetically encoded calcium indicators (GECI). This technique has allowed studies of calcium signalling in a wide variety of cell types. In neurons, action potential generation is always accompanied by rapid influx of Ca2+ ions. Thus, calcium imaging can be used to monitor the electrical activity in hundreds of neurons in cell culture or in living animals, which has made it possible to observe the activity of neuronal circuits during ongoing behavior.
A FMN-binding fluorescent protein (FbFP), also known as a LOV-based fluorescent protein, is a small, oxygen-independent fluorescent protein that binds flavin mononucleotide (FMN) as a chromophore.
Small ultra red fluorescent protein (smURFP) is a class of far-red fluorescent protein evolved from a cyanobacterial phycobiliprotein, α-allophycocyanin. Native α-allophycocyanin requires an exogenous protein, known as a lyase, to attach the chromophore, phycocyanobilin. Phycocyanobilin is not present in mammalian cells. smURFP was evolved to covalently attach phycocyanobilin without a lyase and fluoresce, covalently attach biliverdin and fluoresce, blue-shift fluorescence to match the organic fluorophore, Cy5, and not inhibit E. coli growth. smURFP was found after 12 rounds of random mutagenesis and manually screening 10,000,000 bacterial colonies.
Red fluorescent protein (RFP) is a protein which acts as a fluorophore, fluorescing red-orange when excited. The original variant occurs naturally in the coral genus Discosoma, and is named DsRed. Several new variants have been developed using directed mutagenesis which fluoresce orange, red, and far-red.
Fluorescence imaging is a type of non-invasive imaging technique that can help visualize biological processes taking place in a living organism. Images can be produced from a variety of methods including: microscopy, imaging probes, and spectroscopy.
Nathan Shaner is a researcher in the field of neuroscience and biotechnology, known for his contributions to the development of fluorescent proteins and optogenetic tools. Using directed evolution, he has created fluorescent proteins, including mNeonGreen, mCherry, and dTomato. Shaner discovers new, naturally occurring bioluminescent and fluorescent molecules, and engineers improved variants for biological research applications, such as imaging. He is part of the bioluminescence hub, a research group dedicated to applying bioluminescent probes to neuroscience and optogenetics.