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. 1993 May 11;21(9):2031–2038. doi: 10.1093/nar/21.9.2031

Deprotection of methylphosphonate oligonucleotides using a novel one-pot procedure.

R I Hogrefe 1, M M Vaghefi 1, M A Reynolds 1, K M Young 1, L J Arnold Jr 1
PMCID: PMC309461  PMID: 8502543

Abstract

Deprotection of methylphosphonate oligonucleotides with ethylenediamine was evaluated in a model system. Methylphosphonate sequences of the form 5'-TTTNNTTT, where N was either N4-bz-dC, N4-ibu-dC, N2-ibu-O6-DPC-dG, N2-ibu-dG, N6-bz-dA, or T, were used to determine the extent of modifications that occur during deprotection. Up to 15% of N4-bz-dC was found to transaminate at the C4 position when treated with ethylenediamine. A similar displacement reaction with ethylenediamine was observed at the O6 position of N2-ibu-O6-DPC-dG, and to a much lesser extent of N2-ibu-dG. Side reactions were not observed when oligonucleotides containing N4-ibu-dC, N6-bz-dA, or T were treated with ethylenediamine. A novel method of deprotecting methylphosphonate oligonucleotides was developed from these studies. The method incorporates a brief treatment with dilute ammonia for 30 minutes followed by addition of ethylenediamine for 6 hours at room temperature to complete deprotection in a one-pot format. The solution is then diluted and neutralized to stop the reaction and prepare the crude product for chromatographic purification. This method was used to successfully deprotect a series of oligonucleotides at the 1, 100, and 150 mumole scales. These deprotection results were compared to a commonly used two-step method and found to be superior in yield of product by as much as 250%.

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Selected References

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