First of all, I would include an introductory paragraph outlining what TNP-ATP is and general uses. My main suggestion though would be to include headings and subheadings. You have a lot of information and it's easy to get lost in it. I would also suggest "dumbing down" some of the more technical parts if you can. If you made the technical parts their own section and introduced them in a more simplified way, I think you could keep it. That being said, I would consider not including the preparation example. It's just a bit much for a wiki article. Other than that, you have a great deal of good information. My only other thing to mention would perhaps be to flesh out a bit more the uses of TNP-ATP or perhaps include them closer to the beginning. Other than that, great job. I can tell you did a lot of good work. ~~~~ Travis
TNP-ATP is a fluorescent molecule that is able to determine whether or not a protein binds to ATP. It is primarily used in fluorescence spectroscopy, but is also very useful as an acceptor molecule in FRET, and as a fluorescent probe in fluorescence microscopy.
Constituent Parts
editTNP refers to the chemical compound 2,4,6-trinitrophenol, also known as Picric acid.[1] It is a primary constituent of many unexploded landmines, and is a cousin to TNT, but less stable.[1] It is recognized as an environmental contaminant and is toxic to many organisms.[1] It is still commonly used in the manufacture of fireworks, explosives, and rocket fuels, as well as in leather, pharmaceutical, and dye industries.[1]
ATP is an essential mediator of life.[2] It is used to overcome unfavorable energy barriers to initiate and fuel chemical reactions.[2] It is also used to drive biological machinery and regulate a number of processes via protein-phosphorylation.[2] However, the proteins that bind ATP for both regulation and enzymatic reactions are very diverse—many yet undiscovered—and for many proteins their relationship to ATP in terms of number of binding sites, binding constants, and dissociation constants remain unclear. [2]
TNP-ATP
editConjugating TNP to ATP renders this nucleotide triphosphate fluorescent and colored whilst allowing it to retain its biological activity.[2] TNP-ATP is thus a fluorescent analog of ATP.[3] This conjugation is very useful in providing information about interactions between ATP and an ATP-binding protein because TNP-ATP interacts with proteins and enzymes as a substitute for its parent nucleotide, and has a strong binding affinity for most systems that require ATP.[2]
TNP is excited at a wavelength of 408 and 470 nm, and fluoresces in the 530-560 nm range.[2][4][1][5] This is a very useful range of excitation because it is far from where proteins or nucleotides absorb.[2] When TNP-ATP is in water or other aqueous solutions, this emission is very weak[6][2]. However, once TNP-ATP binds to a protein, there is a dramatic increase in fluorescent intensity.[2][3][5][6] This property enables researchers to study various proteins’ binding interaction with ATP. Thus, with enhanced fluorescence, it can be seen whether or not a protein binds to ATP.[2]
When TNP-ATP in water is excited at 410 nm, TNP-ATP shows a single fluorescence maximum at 561 nm.[6] This maximum shifts as the fluid’s viscosity changes. For example, in N,N-dimethylformamide, instead of having its maxima at 561 nm as in water, the maxima is instead at 533 nm.[6]
Binding to a protein will also change the wavelength of maximal emission, as well as a change in fluorescent intensity.[6] For example, binding to the chemotaxis protein CheA indicates a severalfold enhancement of fluorescence intensity and a blue-shift in wavelength of the maximal emission.[6]
Using this TNP nucleotide analog has been shown in many instances to be superior to traditional radionucleotide-labelling based techniques.[2] The health concerns and the cost associated with the use of radioactive isotopes makes TNP-ATP an attractive alternative.[2]
The first fluorescent ribose-modified ATP is 2’,3’-O-(2,4,7-trinitrocyclohexadienylidene) adenosine 5’triphosphate (TNP-ATP), and was introduced in 1973 by Hiratsuka and Uchida.[2][4] TNP-ATP was originally synthesized to investigate the ATP binding site of myosin ATPase.[2][3] Reports of TNP-ATP’s success in the investigation of this motor protein extended TNP-ATP’s use to other proteins and enzymes.[2] TNP-ATP has now been used as a spectroscopic probe for numerous proteins suspected to have ATP interactions.[2] These include several protein kinases, ATPases, myosin, and other nucleotide binding proteins.[2] Over the past twenty years, there have been hundreds of papers describing TNP-ATP’s use and applications.[2] Many applications involving this fluorescently labeled nucleotide have helped to clarify structure-function relationships of many ATP-requiring proteins and enzymes.[2][6][4][5][3] There have also been a growing number of papers that display TNP-ATP use as a means of assessing the ATP-binding capacity of various mutant proteins.[2][6]
Preparation
editPreparing TNP-ATP is a one-step synthesis that is relatively safe and easy.[2] Adenosine’s ribose moiety can be trinitrophenylated by 2,4,6-trinitrobenzene-1-sulfonate (TNBS).[4] The resulting compound assumes a bright orange color and has visible absorption characteristics, as is characteristic of a Meiseinheimer spiro complex compound linking.[2][4]
The following is an example of how to prepare TNP-ATP as written by TNP-ATP’s creators, T. Hiratsuka and K. Uchida:
“ATP (1.0 g, disodium salt, 1.65 mmoles) was dissolved in 10 ml of water and the pH was adjusted to 9.5 with 4 M LiOH. To this solution with continuous stirring TNBS (1.7 g, 5.4 mmoles) in 10 ml of water was added dropwise over 3 h at 30 °C. The pH was immediately adjusted to and maintained at 9.5 by titration with 0.4 M LiOH. The stirring was further continued for 4 days to ensure the reaction at room temperature in the dark. The reaction mixture was then evaporated to dryness at 30 °C. The residues obtained were suspended in 40 ml of acetone-methanol (3:1, v/v), and then filtered. The residues on a sintered glass were repeatedly washed with acetone. The reddish orange residues were dissolved in 10 ml of water and purified on a Sephadex LH-20 column packed in water.”[4]
To revert TNP-ATP back to its constituent parts, or in other words to hydrolyze TNP-ATP to give equilmolar amounts of picric acid (TNP) and ATP, TNP-ATP should be treated with 1 M HCl at 100 degrees Celsius for 1.5 hours.[4] This is because if TNP-ATP is acidified under mild conditions, it results in the opening of the dioxolane ring attached to the 2’-oxygen, leaving a 3’O-TNP derivative as the only product.[2]
Storage
editTNP-ATP should be stored at -20 degrees Celsius, in the dark, and used under minimal lighting conditions.[6] When in solution, TNP-ATP has a shelf-life of about 30 days.
pKa and Isosbestic Point
editWhen absorption was measured against wavelength at various pH values, the changes at wavelength 408 nm and 470 nm yielded a sigmoidal line with a midpoint at 5.1.[4] This indicated that the absorbance at these two wavelengths depends upon the ionization of the chromophoric portion of TNP-ATP and is unaffected by ionization of ATP.[4] Although this ionization constant of 5.1 is not in physiological range, it has been shown that the absorbance of TNP-ATP is sensitive enough to detect changes due to slight shifts in neutral pH.[4] Spectroscopic superposition indicated TNP-ATP’s isosbestic point to be 339 nm.[4]
Constants and Calculations
editAt low concentrations of TNP-ATP (<=1uM), fluorescent intensity is proportional to the concentration of TNP added.[6] However, at concentrations exceeding 1 uM, inner filter effects cause this relationship to no longer be linear.[6] To correct this, researchers must determine the ratio of the predicted theoretical fluorescence intensity (assuming linearity) to the observed fluorescence intensity and then apply this correction factor.[6] However, in most cases, researchers will try to keep the concentration of TNP to lower than 1 uM.[1][2][6][5][3]
To determine binding affinities, TNP-ATP is added to a solution and then titrated with protein.[5][6] This produces a saturation curve from which the binding affinity can be determined.[6][5] The number of binding sites may also be determined through this saturation curve by looking to see if there are sudden changes in slope.[5] One can also titrate a fixed amount of protein with increasing additions of TNP-ATP to obtain a saturation curve.[6] To do so, however, may get complicated due to the inner filter effects that will need to be corrected for.[6]
To determine dissociation constants, TNP-ATP can be competed off of a protein with ATP.[6][5] The value of the dissociation constant Kd for a single-site binding can then be obtained by applying the Langmuir equation for a curve fit:
RFUobs = RFUfree + [{(RFUbound – RFUfree) * [([protein]total + [TNP]total + Kd) – sqrt(([protein]total + [TNP]total + Kd)2 – (4*[protein]total * [TNP]))]} / (2[TNP]total)],
where RFU is relative fluorescent units, RFUobs is the fluorescence observed, RFUfree is the fluorescence of free TNP-ATP, and RFUbound is the fluorescence of TNP-ATP when completely bound to a protein.[5]
To measure an ATP competitor, one can add competitor to pre-incubated samples of protein:TNP-ATP. The fraction of TNP-ATP bound to the protein can be calculated via:
θ = (RFUobs – RFUfree) / (RFUmax – RFUfree),
where θ is that fraction, and RFUmax is the value of fluorescence intensity at saturation, meaning when 100% of TNP-ATP is bound.[5]
The dissociation constants for TNP and competitor can then be calculated through the equation:
θ = 0.5[TNP] * {KTNP+ (KTNP/KCompetitor)*[competitor]+[TNP]+[protein]-sqrt[[KTNP + (KTNP/Kcompetitor)*[competitor]+[TNP]+[protein])2 – 4*[TNP]*[protein]}.[5]
For reasons not yet fully understood, TNP-ATP typically binds the ATP binding sites of proteins and enzymes anywhere from one to three times tighter than regular ATP.[2][6] The dissociation constants are usually around 0.3-50 uM.[2]
Others Uses
editIn addition to using TNP-ATP to determine whether or not a protein binds ATP, its binding affinity and dissociation constants, and number of binding sites, TNP-ATP can also be used in ligand binding studies.[2] To do this, titrations of the protein are added to TNP-ATP. Then, ligand is added to displace the bound analog.[2] This is measured by decreases in fluorescence.[2] One can also do this by titrating protein with TNP-ATP in the presence and absence of varying concentrations of the ligand of interest.[2] Using either experiment will allow the binding affinity of the ligand to protein to be measured.
TNP-ATP is also valuable fluorescence acceptor.[1][2] This is because, as with any good acceptor, TNP-ATP absorbs over a wide wavelength range that corresponds to the range of emission of common FRET donors.[1] Thus, TNP-ATP can be used to look at the conformational changes that proteins undergo.[1]
In addition to fluorescent spectroscopy, TNP-ATP is very useful in fluorescent microscopy.[2] This is because it greatly increases the sensitivity of the observations when bound to proteins—the enhanced fluorescence greatly reduces the problem of background fluorescence.[2] This is especially true under epifluorescent illumation (illumination and light are both on the same side of the specimen).[2]
References
edit- ^ a b c d e f g h i Deng, Xiang, Xiaomei Huang, and Di Wu. "Förster Resonance-energy-transfer Detection of 2,4,6-trinitrophenol Using Copper Nanoclusters." Anal Bioanal Chem Analytical and Bioanalytical Chemistry 407.16 (2015): 4607-613. Web.
- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai Hiratsuka, Toshiaki (February 2003). "Fluorescent and colored trinitrophenylated analogs of ATP and GTP". European Journal of Biochemistry.
- ^ a b c d e Fujita, Suguru, Tomoko Nawata, and Kazuhiro Yamada. "Fluorescence Changes of a Label Attached near the Myosin Active Site on Nucleotide Binding in Rat Skeletal Muscle Fibres." The Journal of Physiology 515.3 (1999):869-80. Web.
- ^ a b c d e f g h i j k Hiratsuka, T., and K. Uchida. "Preparation and Properties of 2′(or 3′)-O-(2,4,6-trinitrophenyl) Adenosine 5′-triphosphate, an Analog of Adenosine Triphosphate." Biochimica Et Biophysica Acta (BBA) - General Subjects 320.3 (1973): 635-47. Web.
- ^ a b c d e f g h i j k Guarnieri, Michael T., Brian S. J. Blagg, and Rui Zhao. "A High-Throughput TNP-ATP Displacement Assay for Screening Inhibitors of ATP-Binding in Bacterial Histidine Kinases." ASSAY and Drug Development Technologies 9.2 (2011): 174-83. Web.
- ^ a b c d e f g h i j k l m n o p q r s Stewart, Richard C., Ricaele Vanbruggen, Dolph D. Ellefson, and Alan J. Wolfe. "TNP-ATP and TNP-ADP as Probes of the Nucleotide Binding Site of CheA, the Histidine Protein Kinase in the Chemotaxis Signal Transduction Pathway of Escherichia Coli †." Biochemistry 37.35 (1998): 12269-2279. Web.
Category:Biophysics Category:Biochemistry Category:Cell biology Category:Physiology Category:Nucleotides Category:Purines Category:Spectroscopy Category:Fluorescence