DNA plays an import hole in biological activities and its survey bit by bit grew during the old ages. Knowledge of DNA chemical science provided the footing for the development of synthesis methods of nucleic acids in the research lab.1This accomplishment is possibly the most of import in the country for understanding the maps of DNA,1and about every molecular biological science technique in usage today employs chemically synthesized DNA’s and RNA’s for usage in DNA sequencing, site directed mutagenesis, ringer and express cistrons, etc.?

    For most applications, really little measures are required ; ? nevertheless, a fast method with high output and quality of merchandise is necessary. However, several old ages ago the synthesis was really arduous and clip devouring. As an illustration, a 21 base paired DNA semidetached house could last the equivalent of four old ages of extremely skilled and intense attempt.4In the 1950s to 1960s the solution technique for DNA synthesis developed by Khorana was used. It was known as phosphodiester method and it refers to the byproducts: diester phosphate salts. The purification of merchandises were highly clip devouring because of these salts, as the output were non high and the merchandise needed word picture in each measure of the synthesis.?

    With the increasing of applications for DNA oligonucleotides, several research labs focused on developing synthesis methodological analysiss. The first betterment was the triester production alternatively of diester phosphate salts, which increased the outputs and turned the purification easier.? The following progress was the displacement from solution methods to solid support methods, which improved the purification measure, virtually eliminated mechanical losingss and allowed the usage of big surplus of reactants to drive the reaction to products.?

    By 1980’s, a discovery was achieved and a less than a twenty-four hours synthesis method of oligonucleotides was established.4It is known as phosphoramidite method of DNA synthesis. A phosphoramidite monomer is really different synthesis unit compared with the old 1s. It is a normal base but with protection groups added to the reactive aminoalkane, hydroxyl and phosphate groups. ( Figure 1 ) . Besides, the nexus to the support is made through the 3’ C, so the synthesis returns from 3’ to 5’ C, ? instead than to 5’ – 3’ way of DNA biogenesis ( reproduction ) . This synthesis method made it possible to do longer oligonucleotides, increasing the quality and output and diminishing cost, ? so this work will concentrate in the description of this chemical synthesis method of DNA.

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    Figure 1:Nucleoside phosphoramidite monomer for chemical synthesis of DNA.?

      1. Solid supports

    Solid-phase synthesis is truly of import and widely used in synthesis of peptides, oligonucleotides and oligosaccharides. The advantages are multiple, but the most of import are: drive of reactions to completion by big usage of reagents ; cancellation of purification of merchandises after each measure due the lavation of drosss and extra reagents before each reaction ; and mechanization on computer-controlled solid-phase synthesizers.?

    The solid-phase synthesis is carried out on a solid support held between filters in columns that enable all reagents and dissolvers to go through through freely. The solid support, besides known as rosins, are indissoluble atoms, can be of different composings and typically 50-200 ?min diameter. In the DNA synthesis, the oligonucleotide is bounded during the synthesis.? Two types of solid supports have proved to be the most utile for the phosphoramidite DNA synthesis method, the controlled pore glass ( CPG ) and polystyrene ( PS ) .

    1. Synthesis of nucleoside phosphoramidite monomers

    The A, G, C and T phosphoramidites monomers used in the Deoxyribonucleic acid synthesis are prepared on big graduated table from the free nucleosides, which are obtained from natural beginnings. The synthesis consists in the protection of the aminoalkanes ( except T, which does non necessitate protection ) , followed by a tritylation of the 5’ C with the 4,4’-dimetroxytrityl chloride in pyridine at room temperature ( protection of the 5’-hydroxyl group ) and eventually, after purification of the merchandise, a phosphitylation at the 3’ C utilizing 2-cyanoethyl diisopropylaminophosphorochloriditein the presence of the non-nucleophilic base diisopropylethylamine ( DIPEA ) . After intervention in a silicon oxide gel column chromatography, precipitation into hexane and filtration through microfilter, the phosphoramidite monomers are ready to utilize in DNA synthesis. ?

    1. Protection of amides

    The amides can be protected by two methods, a common benzoylation followed by adding a strong base to retrieve the intoxicants groups ( Figure 2 ) or a transeunt protection of the intoxicant maps followed by benzoylation of the amino groups ( Figure 3 ) . The last has the advantage of being a one-pot synthesis, the isolation or purification of the intermediate silylated nucleoside is non necessary. ?

    Figure 2:Benzoyl protection of A ?

    Figure 3:Transient protection of A ?

    There is another method for the protection of deoxycytidine: its amino group is sufficiently reactive to be functionalised with active esters that do non respond with the hydroxyl maps. So, it can respond with pentafluorophenylbenzoate affording a one-step synthesis of the protected N ( 4 ) -benzoyl District of Columbia ( Figure 4 ) . ?

    Figure 4:Protection of C utilizing pentafluorophenyl benzoate ?

    The protection of G follow same mechanisms than the protection of A, but utilizing with an isobutyryl protecting group ( Figure 5 ) . Thymine, as said before, does non necessitate protection.

    Figure 5:Protected G ?

    1. Protection of 5’-hydroxyl group – Tritylation

    The protected district attorney, decigram, District of Columbia and unprotected T nucleosides are tritylated selectively utilizing 4,4’-dimethoxytrityl ( DMT ) at the 5’-hydroxyl group to protect it ( Figure 6 ) . ?

    Figure 6:DMT nucleoside protection ?

    1. Phosphitylation

    The DMT-nucleosides are now phosphitylated at the 3’-position utilizing 2-cyanoethyl diisopropylaminophosphorochloriditein the presence oof DIPEA to give the phosphoramidite monomers ( Figure 7 ) . ? The reagent used for the phosphitilation is made by handling P trichloride with 2-cyanoethanol so with N, N-diisopropylamine in the presence of DIPEA ( Figure 8 ) . ?

    Figure 7: Nucleoside phosphitylation ?

    Figure 8: Synthesis of the phosphitylation reagent ?

    1. Resin Functionalization

    After the synthesis of phosphoramidite monomers, it is necessary to handle the solid support to bring forth the functionalised rosin for the synthesis of oligonucleotides. The functionalization occurs by the intervention of 5’-DMT nucleosides with succinic anhydride at room temperature in the presence of pyridine. Alarge surplus of each nucleoside succinate is so added to a batch of the amino-functionalized rosin along with a diimide matching agent and an acidic intoxicant such as 4-nitrophenol which forms an active ester in which it acts as a good departure group. This is followed by a capping measure to barricade any unreacted amino groups which would otherwise cause jobs in oligonucleotide synthesis ( Figure 9 ) . ?

    Figure 9: Resin functionalization ?

    1. The phosphoramidite method for chemical solid-phase Deoxyribonucleic acid synthesis

    The phosphoramidite method for DNA synthesis returns in the 3’ to 5’ way and one base is added per synthesis rhythm. It besides consists of a series of stairss, which are traveling to be outline below.

    Figure 10:The phosphoramidite oligonucleotide synthesis rhythm ?

    1. Detritylation of the support-bond at 3’ C of the nucleoside.

    The first measure consists in the remotion of the protection group of the 5’ C. It is functionalised with DMT to forestall polymerisation during the rosin functionalization, but it is necessary to be removed so the synthesis can proceed.? The mechanism of the detritylation is showed above ( Figure 11 ) , it uses trichloroacetic acid as accelerator.

    Figure 11:Phosphoramidite nucleoside detritylation ?

    1. Activation and Matching

    After the detritylation, the support-bound nucleoside is ready to respond with the following base. It is added in the signifier of nucleoside phosphoramidite monomer in big surplus, assorted with an activator ( tetrazole ) , both dissolved in acetonitrile. The mechanism of the activation of the nucleoside phosphoramidite monomer and the yoke is showed in Figure 11: the activation occurs by a protonation of the phosphoramidite monomer by the activator, turning the amino group of the phosphoramidite bond into a good departure group, which is quickly displaced by onslaught of the 5’-hydroxyl group of the support-bound phosphite trimester. The unbound base and byproducts are washed out at the terminal of the reaction, and the tetrazole is reconstituted.? The usage of this activator addition matching efficiency to greater than 99 % .?

    Figure 11:Phosphoramidite activation and matching with support-bond nucleoside. ?

    1. Caping

    Even with a great yoke efficiency, the procedure still hold a failure rate. In this instance, the failure consists in the remain of unreacted support-bond nucleoside, it means, remain freely reactive and able to match in the following rhythm that would ensue in a missing base in the synthesis. Therefore, matching failures must be removed from farther engagement in the synthesis by presenting a cresting measure to barricade the unreacted 5’-hydroxyl groups. It uses acetic anhydride and N-methyllimidazole ( NMI ) dissolved in tetrahydrofuran and a little measure of pyridine ( Figure 12 ) .

    Figure 12:Phosphoramidite cresting ?

    1. Oxidation

    The oxidation measure is a procedure necessary to stabilise the phosphite-triester ( P ( III ) ) formed during the coupling measure, which is unstable in acid. The end is to change over it into stable ( P ( V ) ) species, and it is achieved by iodine oxidization in presence of H2O and pyridine ( Figure 13 ) . The attendant phosphotriester is efficaciously a Deoxyribonucleic acid anchor protected with a 2-cyanoethyl group that prevents unwanted reactions at phosphoric during subsequent rhythms.

    Figure 13:Phosphoramidite oxidization ?

    1. Detritylation

    After all these stairss, it is necessary a new detritylation to take the DMT protection group at the 5’-end of the resin-bound DNA concatenation so the hydroxyl can respond with the following nucleotide phosphoramidite in the following rhythm. It is the same procedure than the first measure, but now utilizing the support-bound DNA concatenation alternatively of the chiefly support-bound nucleoside.

    1. Cleavage from the solid support

    After the completion of all synthesis rhythms to organize the coveted oligonucleoside, it is necessary to cleavage the Deoxyribonucleic acid from the support. The linker used most often in DNA synthesis is the succinyl linker. It is stable in all reagents during the synthesis, but cleavable by intervention with concentrated ammonium hydrated oxide at room temperature for one hr ( Figure 14 ) .

    Figure 14:oligonucleotide rosin cleavage ?

    1. Oligonucleotide deprotection

    The oligonucleotide dissolved in concentrated aqueous ammonium hydroxide from the last measure now is heated to take the protection groups from the heterocyclic bases and phosphates ( Figure 15 ) .

    Figure 15:Oligonucleotide deprotection ?

    1. Purification

    The last measure of chemical synthesis of DNA is the purification of the merchandises obtained. It chiefly uses two methods for post-production purification: Polyacrylamide gel cataphoresis ( PAGE ) or High public presentation liquid chromatography ( HPLC ) . ? The quality control of the purified merchandise is besides necessary and can be made by mass spectroscopy ( MS ) or capillary cataphoresis ( CE ) . ?


    The first efforts of chemical DNA synthesis are from the same clip of the find of DNA, due the importance of cognizing this molecule. The method was developed, and the coming of phosphoramidite chemical science affecting tetrazole intermediates in the 1980’s make it possible to do longer oligonucleotides, faster, and with higher outputs and quality. Nowadays, this method is widely used for the chemical synthesis of DNA, and is really of import for the multiple applications of man-made DNA. This procedure besides permits multiple change in the composing of the DNA, leting different surveies.


    ? Garrett Larson, Bruce E.Kaplan, John J. Ross,The American Biology Teacher, 1984,46, 440-446.

    ? Chemical Synthesis and Purification of Oligonucleotides,Integrated DNA Technologies, hypertext transfer protocol: //eu.idtdna.com/Pages/docs/technical-reports/chemical-synthesis-of-oligonucleotides.pdf ( Accessed December 2014 ) .

    ? Solid-phase Oligonucleotide synthesis,atdbio, hypertext transfer protocol: //www.atdbio.com/content/17/Solid-phase-oligonucleotide-synthesis ( Accessed December 2014 ) .

    4Marvin H. Caruthers,Acc. Chem. Res. ,1991,24, 278-284.


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