Phosphate groups reaction with carbodiimides

DNA or RNA also may be modified with cystamine at the 5 -phosphate group using a carbodiimide reaction. See Chapter 27, Section 2.2 for a complete discussion of the labeling protocol. 

The second chemical-tagging approach, which in addition is also applicable to phosphotyrosine-containing peptides, uses a more complex chemistry to tag phosphopeptides [33], It involves the attachment of l-amine-2-thioethane to the phosphate group via a carbodiimide condensation reaction. The modified phosphopeptides are captured by an iodoacetyl resin and subsequently released with an acidic solution. 

Molecules containing phosphate groups, such as the 5 phosphate of oligonucleotides, also may be conjugated to amine-containing molecules by using a carbodiimide-mediated reaction (Chapter 27, Section 2.1). The carbodiimide activates the phosphate to an intermediate phosphate ester similar to its reaction with carboxylates (Chapter 3, Section 1). In the presence of an amine, the ester reacts to form a stable phosphoramidate bond (Reaction 13). 

Phosphate-containing carbohydrates that are stable, such as the 5 -phosphate of the ribose derivatives of oligonucleotides, may be targeted for modification using a carbodiimide-facilitated reaction (Section 4.3). The water-soluble carbodiimide EDC can react with the phosphate groups to form highly reactive phospho-ester intermediates. These intermediates can react with amine- or hydrazide-containing molecules to form stable phosphoramidate bonds. 

The carbodiimide of choice used to couple cystamine to carboxylate- or phosphate-containing molecules is most often the water-soluble carbodiimide, EDC hydrochloride Chapter 3, Section 1.1). This reagent rapidly reacts with carboxylates or phosphates to form an active ester intermediate, which is highly reactive toward primary amines. The reaction is efficient from pH 4.7 to 7.5, and a variety of buffers may be used, providing they don t contain competing groups. 

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