5'-Fluorescein phosphoramidite contains no 4,4'-dimethoxytrityl (DMT) group and can be added only once at the 5'-terminus, thereby terminating synthesis. This product is prepared using the 6-carboxyfluorescein derivative. The tetrachloro (TET)-, hexachloro (HEX) - and dichloro-dimethoxy (JOE)- fluorescein phosphoramidites are designed to take advantage of the multicolor detection capability of modern DNA sequencers and genetic analyzers. Fluorescein phosphoramidite is designed to produce the same fluorescein-type structure as had been previously prepared using fluorescein isothiocyanate (FITC). Our fluorescein phosphoramidite also contains a DMT group to allow quantification of coupling. The analogous structure, 6-Fluorescein Phosphoramidite, prepared using 6-FAM, is also available, along with 6-Fluorescein Serinol Phosphoramidite. Fluorescein-dT can be inserted into the desired sequence as a replacement for a dT residue.
We offer five fluorescein supports. Fluorescein CPG has traditionally been used to add the fluorescein label at the 3'-terminus. The analogous structure, 3'-(6-Fluorescein) CPG, prepared using 6-FAM, is now also available, along with 6-Fluorescein Serinol CPG. We also offer 3'-(6-FAM) CPG and Fluorescein-dT CPG, both derivatives of 6-carboxyfluorescein (6-FAM). Both are single isomers and use an amide linkage which is stable during cleavage and deprotection and does not allow isomer formation. 3'-(6-FAM) CPG allows effective blockage of the 3'-terminus from polymerase extension as well as exonuclease digestion. Fluorescein-dT CPG allows both of these enzymatic activities to proceed. Normal cleavage and deprotection with ammonium hydroxide readily generates the fluorescein labelled oligos.
The spectral characteristics of these dyes are detailed on the following page.
Details
Usage
Coupling: 10 minute coupling time recommended.
Deprotection: Use ammonium hydroxide and deprotect as required by nucleobases. When using AMA, a small amount of a non-fluorescent impurity will be formed. To eliminate this impurity, first deprotect with ammonium hydroxide for 30 minutes at room temperature, add an equal volume of 40% methylamine and then complete the deprotection as required by the nucleobases - e.g. 10 minutes at 65°C or 2 hours at room temperature for standard bases.
Specifications
Diluent
Anhydrous Acetonitrile
Storage
Refrigerated storage, maximum of 2-8°C, dry
Stability
24 hours
Dilution/Coupling Data
The table below show pack size data and, for solutions, dilution and approximate coupling based on normal priming procedures.
Response: While AMA (Ammonium hydroxide/40% Methylamine 1:1 v/v) is considered compatible with fluorescein, the use of methylamine when deprotecting a Fluorescein-labeled oligo does lead to a small amount of degradation, which is characterized by a the appearance of a late-eluting peak by RP HPLC that shows no visible fluorescein absorbance. With standard deprotection conditions (AMA 10 minutes at 65 C) the amount of degradation is approximately 5%|||
It's an artifact of the MALDI analysis. The lasers used to ablate the MALDI matrix are generally between 308 and 355 nm, with the most frequently used laser line at 337 nm. When a laser hits a strong absorbance band of a molecule, often photochemistry starts to occur - which often leads to cleavage reactions. The Fluorescein-dT has strong UV absorbance in this region which appears to lead to a 135 m/z fragment is being blown off the molecule in a rather consistent manner. For instance, your oligos D1 and D2, which have 5 and 3 Flu-dTs respectively, the observed mass difference is -676 Da and -406 Da, which nicely fits the loss of a 135 mw fragment: 5 x 135 (675) and 3 x 135 (405). We haven't seen any papers that identify this 135 m/z fragment - but it's clear to me that that is what's occurring. Changing matrix matrix used may help. The matrix 2,4,6-trihydroxyacetophenone has been used successfully to analyze a fluorescein-labeled oligos[1], though the safest bet is to use Electrospray MS rather than MALDI for mass spec analysis.||REFERENCE(S):1 Pieles et al., Nucleic Acids Res., Vol 21 (14) 3191-3196 (1993)||