Synthesis of well-defined phosphate-methylated DNA fragments: the application of potassium carbonate in methanol as deprotecting reagent.

A new deprotection procedure in the synthesis of (partially) phosphate-methylated oligodeoxynucleotides has been developed, involving treatment of fully protected DNA fragments with methanolic potassium carbonate. It is shown that base deprotection can be accomplished in potassium carbonate/methanol without affecting the methyl phosphotriesters. This methodology enables us to synthesize, both in solution and on a solid support, DNA fragments which are phosphate-methylated at defined positions. The solid phase synthesis, however, turns out to be accompanied by considerable demethylation of the phosphotriesters. It is demonstrated that this demethylation does not occur during the deprotection or work-up procedure. Furthermore, it was found that the latter side-reaction is suppressed when the standard capping procedure with acetic anhydride is included.     

Rapid deprotection procedures for synthetic oligonucleotides.

Two new rapid procedures for the full deprotection of synthetic oligonucleotides has been developed. We have successfully used the mixture of ethanolamine and ethanol (1:1) or pure ethanolamine for deprotection of oligonucleotides, prepared by different methods. In the case of oligonucleotides prepared by commonly used beta-cyanoethyl phosphoramidite and H-phosphonates method deprotection takes half an hour at 70 degrees C. We have found also that mixture of hydrazine, ethanolamine and methanol (1:3:3, v/v/v) can serve as a very efficient reagent for deprotection of oligonucleotides, prepared by beta-cyanoethyl phosphoramidite method with isopropoxyacetyl protecting group for cytosine residues. In this case deprotection time is 12-17 min at room temperature.     

A synthesis of N6,N6,N6-trimethyl-L-lysine dioxalate in gram amounts

A procedure is described for the synthesis of crystalline N6,N6,N6-trimethyl-L-lysine dioxalate in gram amounts starting from the commercially available N2-tert-butoxycarbonyl-N6-benzyloxycarbonyl-L-lysine, which is reacted with methyl iodide in methanol in the presence of potassium hydrogen carbonate after deprotection of the side-chain amino group by catalytic hydrogenation. The work-up involves only filtrations and evaporations.     

Synthesis and biological activity of some unsaturated 6-azauracil acyclonucleosides

A useful route is described for obtaining Z and E unsaturated alkylating agents 3 and 4. Coupling 6-azauracils 5 and 6 with unsaturated alkylating agent followed by the deprotection with H+ resin gave acyclonucleosides 11-14 in good overall yields. Unsaturated acyclonucleosides phosphonates 19 and 20 were prepared using potassium carbonate as base and 4-bromobut-2-enyl diethyl phosphonate 16 as the alkylating agent. The introduction of a propargyl group at the N-3 position of acyclonucleosides 7, 8 17, 18, 19, and 20 was achieved using potassium carbonate in DMF.     

On the rapid deprotection of synthetic oligonucleotides and analogs.

The efficiency of oligodeoxynucleotide deprotection is greatly enhanced using a combination of: (a) ethanolamine, and especially a mixture of hydrazine, ethanolamine and methanol, in place of the usual aqueous ammonia; (b) tert-butylphenoxyacetyl amino protecting groups, and (c) oxalyl link between the first nucleotide and the polymeric support. The extent of base modification, particularly of C, is shown to be extremely low, and the quality of deprotected oligonucleotides is as high as in the case of ammonia deprotection. This method is also shown to be applicable to the preparation of phosphorothioate and methylphosphonate oligodeoxynucleotides and oligoribonucleotides.     

Studies on deprotection of cysteine and selenocysteine side-chain protecting groups.

We present here a simple method for deprotecting p-methoxybenzyl groups and acetamidomethyl groups from the side-chains of cysteine and selenocysteine. This method uses the highly elecrophilic, aromatic disulfides 2,2'-dithiobis(5-nitropyridine) (DTNP) and 2,2'-dithiodipyridine (DTP) dissolved in TFA to effect removal of these heretofore difficult-to-remove protecting groups. The dissolution of these reagents in TFA, in fact, serves to 'activate' them for the deprotection reaction because protonation of the nitrogen atom of the pyridine ring makes the disulfide bond more electrophilic. Thus, these reagents can be added to any standard cleavage cocktail used in peptide synthesis.The p-methoxybenzyl group of selenocysteine is easily removed by DTNP. Only sub-stoichiometric amounts of DTNP are required to cause full removal of the p-methoxybenzyl group, with as little as 0.2 equivalents necessary to effect 70% removal of the protecting group. In order to remove the p-methoxybenzyl group from cysteine, 2 equivalents of DTNP and the addition of thioanisole was required to effect removal. Thioanisole was absolutely required for the reaction in the case of the sulfur-containing amino acids, while it was not required for selenocysteine. The results were consistent with thioanisole acting as a catalyst. The acetamidomethyl group of cysteine could also be removed using DTNP, but required the addition of > 15 equivalents to be effective. DTP was less robust as a deprotection reagent. We also demonstrate that this chemistry can be used in a simultaneous cyclization/deprotection reaction between selenocysteine and cysteine residues protected by p-methoxybenzyl groups to form a selenylsulfide bond, demonstrating future high utility of the deprotection method.     

Hydroquinone-O,O'-diacetic acid ('Q-linker') as a replacement for succinyl and oxalyl linker arms in solid phase oligonucleotide synthesis.

When hydroquinone-O,Ooffiacetic acid is used as a linker arm in solid phase oligonucleotide synthesis, the time for NH4OH cleavage of oligodeoxy- or oligoribonucleotides is reduced to only 2 min. This allows increased productivity on automated DNA synthesizers without requiring any other modifications to existing reagents or synthesis and deprotection methods. The Q-linker may also be rapidly cleaved by milder reagents such as 5% NH4OH, potassium carbonate, anhydrous ammonia, t-butylamine or fluoride ion. However, the Q-linker is sufficiently stable for long-term storage at room temperature without degradation and no loss of material occurs during synthesis. The linker is also reasonably resistant to 20% piperidine/DMF, 0.5 M DBU/pyridine and 1:1 triethylamine/ethanol. The Q-linker can therefore serve as a general replacement for both succinyl and oxalyl linker arms.     

Microwave-assisted rapid deprotection of oligodeoxyribonucleotides.

A novel method for the deprotection of oligodeoxyribonucleotides under microwave irradiation has been developed. The oligodeoxynucleotides having base labile, phenoxyacetyl (pac), protection for exocyclic amino functions were fully deprotected in 0. 2 M sodium hydroxide (methanol:water : : 1:1, v/v) = A and 1 M sodium hydroxide (methanol:water : : 1:1, v/v) = B using microwaves in 4 and 2 min, respectively. The deprotection of oligodeoxyribonucleotides carrying conventional protecting groups, dAbz, dCbzand dGpac, for exocyclic amino functions was achieved in 4 min in B without any side product formation. The deprotected oligonucleotides were compared with the oligomers deprotected using standard deprotection conditions (29% aq. ammonia, 16 h, 55 degrees C) with respect to their retention time on HPLC and biological activity.     

Antisense pro-drugs: 5'-ester oligodeoxynucleotides.

Oligonucleotides bearing a terminal lipophilic group attached through a biodegradable ester bond should be useful as antisense pro-drugs with improved cellular uptake. The synthesis of 5'-ester oligonucleotides is, however, problematic due to lability of the ester bond during aqueous ammonia treatment that is commonly used for the deprotection of synthetic oligonucleotides. The synthesis of 5'-palmitoyl oligodeoxynucleotides was accomplished in good yield by the use of a combination of base-labile tert-butylphenoxyacetyl amino protecting groups (t-BPA), the oxalyl-CPG anchor group, and ethanolamine (EA) as a deprotecting reagent.     

8-Amino-2'-deoxyguanosine incorporation into oligomeric DNA

During the incorporation of 8-amino-dG into oligomeric DNA, the deprotection conditions previously recommended (28% ammonia at room temperature) do not effect complete removal of the dimethylaminomethylene protecting groups. At elevated temperatures oxidative degradation of the oligomer and exchange of ammonia with dimethylamine in the protecting group at C8 occurred. The resolution of these problems and a method to obtain a series of homogeneous oligomers in reasonable yield containing 8-amino-dG located site-specifically are described.     

A one-pot synthesis of 1-alpha- and 1-beta-D-arabinofuranosyl-2-nitroimidazoles: synthons to the markers of tumor hypoxia

1-alpha- and 1-beta-D-Arabinofuranosyl-2-nitroimidazole (alpha-AZA and beta-AZ A) are synthons for a number of potential markers of tissue hypoxia. A one pot synthesis in which 2-nitroimidazole is coupled with a mixture of alpha- and beta-1-O-acetyl-2,3,5-tri-O-benzoyl-D-arabinofuranose in the presence of stannic chloride, followed by deprotection using ammonia/methanol, is described Previously reported conditions for coupling 2-nitroimidazole to 1-alpha-bromoarabinofuranose protected by base-hydrolyzable groups afforded alpha-AZA almost exclusively.     

Polycarbonates from the polyhydroxy natural product quinic acid

Strategies for the preparation of polycarbonates, derived from natural polyhydroxy monomeric repeat units, were developed for biosourced polycarbonates based on quinic acid. The design and synthesis of regioselectively tert-butyldimethylsilyloxy (TBS)-protected 1,4- and 1,5-diol monomers of quinic acid were followed by optimization of their copolymerizations with phosgene, generated in situ from trichloromethyl chloroformate, to yield protected poly(1,4-quinic acid carbonate) and poly(1,5-quinic acid carbonate). The molecular weights reached ca. 7.6 kDa, corresponding to degrees of polymerization of ca. 24, with polydispersities ranging from 2.0 to 3.5, as measured by SEC using tetrahydrofuran as the eluent and with polystyrene calibration standards. Partially because of the presence of the bicyclic backbone, each regioisomeric poly(quinic acid carbonate) exhibited relatively high glass-transition temperatures, 209 °C for poly(1,4-quinic acid carbonate) and 229 °C for poly(1,5-quinic acid carbonate). Removal of the TBS-protecting groups was studied under mild conditions to achieve control over potential competing reactions involving polymer degradation, which could include cleavage of lactones within the repeat units, carbonate linkages, or both between the repeat units. Full deprotection was not achieved without some degree of polymer degradation. The regiochemistry of the monomer showed significant impact on the reactivity during deprotection and also on the thermal properties, with the 1,5-regioisomeric polymer having lower reactivity and giving higher T(g) values, in comparison with the 1,4-regioisomer. Each regioisomer underwent a 10-20 °C increase in T(g) upon partial removal of the TBS-protecting groups. As the extent of deprotection increased, the solubility decreased. Ultimately, at long deprotection reaction times, the solubility increased and the T(g) decreased because of significant degradation of the polymers.     

Chromatography on Sephadex LH20 as an efficient purification step after removal of internucleotide 2,2,2-trichloroethyl protective groups from oligoribonucleotide phosphotriesters.

Chromatography on Sephadex LH20, in a linear gradient of methanol in 0.02M TEAB buffer pH 7.5, is proposed as a fast and efficient method for the isolation and purification of protected oligoribonucleotide phosphodiesters obtained by deprotection of internucleotide phosphotriesters, and for the monitoring of the deprotection step itself. Its utility is shown on the example of removal of 2,2,2-trichloroethyl groups from oligoribonucleotide phosphotriester I of sequence CCCAUAA by two methods: /1/ reductive elimination with zinc in the presence of acetylacetone modified as presented here, and /2/ hydrogenolytic dehalogenation over palladium in pyridine. This method of chromatography on Sephadex LH20 is used as a key purification step during the removal of 2,2,2-trichloroethyl groups from I by method /1/ and allows to raise the yield of III during fianl deprotection step from 5 to 65%.     

Cleavage of oligodeoxyribonucleotides from controlled-pore glass supports and their rapid deprotection by gaseous amines.

A novel method for the deprotection of oligodeoxyribonucleotides has been developed. Gaseous amines such as ammonia or methylamine were employed under pressure to achieve mild and rapid deprotection conditions. For example, oligodeoxyribonucleotides having a (tert-butyl)phenoxyacetyl group for the protection of the exocyclic amino function of cytosine, adenine and guanine were released from controlled-pore glass supports and fully deprotected by ammonia or methylamine under gas phase conditions, at room temperature, within 35 or 2 min respectively.     

Solid-phase synthesis of oligoribonucleotides

Selective deprotection of the 5'-O-dimethoxytrityl group of oligoribonucleotides required for 5'-deprotection reaction during synthesis of an oligoribonucleotide was achieved by the treatment with 1% dichloroacetic acid in dichloromethane at room temperature, without removal of the 2'-O-tetrahydropyranyl group. Phosphorylation of protected ribonucleosides and coupling reaction to the 5' end of oligoribonucleotides attached to polystyrene solid support were carried out by the use of bifunctional reagent 2-chlorophenyl-O-O-bis(1-benzotriazolyl) phosphate. In this way, trinucleotides; TpTpT, dUpdUpT, and UpUpT, were synthesized.     

Characteristics of anaerobic ammonia removal by a mixed culture of hydrogen producing photosynthetic bacteria

It is known that the presence of ammonia inhibits hydrogen production by photosynthetic bacteria. In order to avoid it, a two-step process containing ammonia removal and hydrogen production was investigated in this study. Firstly, the effects of carbonate presence on ammonia removal by photosynthetic bacteria were investigated by the vial tests because it is known that the uptake of volatile fatty acids (VFAs) sometimes requires carbonate. The results of them showed that the presence of carbonate promoted the uptake of VFAs and ammonia. Especially, the uptake of propionate and/or butyrate required the presence of carbonate. The results of the batch experiments of two-step hydrogen production showed that the depletion of ammonia triggered hydrogen evolution. Herein, the presence of albumin did not inhibit hydrogen evolution and preferably it increased the hydrogen production rate. And the VFA-C/NH4-N ratio in substrate fed into two-step hydrogen production process should be more than 6.0.     

The effect of the acidity of rapeseed oil on its transesterification

The aim of this work is to study the transesterification of vegetable oil with a high acid number at unchanged reaction conditions. Rapeseed oil was used as the raw material and its acid number was changed by the addition of oleic acid (from 0.89 to 12.25 mg KOH/g). Methanol was used for transesterification (molar ratio of oil to methanol 1:6) and potassium hydroxide was used as a catalyst. After the reaction time, the residue of the catalyst was neutralised by gaseous carbon dioxide and the methanol excess was removed. After the separation of two phases, each of them was analyzed (in the ester phase: yield, content of methyl ester and acid number; in the glycerol phase: yield, density, viscosity, content of glycerol, soaps, methyl ester, potassium carbonate and hydrogen carbonate). The obtained data was compared with theoretical material balances and the effect on the saponification of oil was discussed. The results show that the yield of methyl ester (biodiesel) is significantly affected by a higher acid number, as well as enhanced soap formation. On the other hand, the conversion of the oil and acid number of the ester phase remain at constant values in studied borders.     

Evaluation of 3-ethoxy-1,2,4-dithiazoline-5-one (EDITH) as a new sulfurizing reagent in combination with labile exocyclic amino protecting groups for solid-phase oligonucleotide synthesis.

3-ethoxy-1,2,4-dithiazoline-5-one (EDITH) was recently introduced as an efficient sulfurizing reagent for solid-phase oligonucleotide synthesis. The successful syntheses were performed using standard base protecting groups (i.e. benzoyl for A and C, isobutyryl for G), which required deprotection in concentrated ammonium hydroxide at 55 degrees C for 15-18 h. We have explored the possibility of using EDITH in combination with fast deprotection chemistry(e.g. Expedite Chemistry using tert -butylphenoxy acetyl as a base protecting group). Surprisingly, poor synthesis performance was observed when syntheses were conducted with EDITH, Expedite Chemistry and standard synthesis cycle (i.e. Coupling-Thio-Cap). Potential G modification seemed to be the source of incompatibility since sequences containing no G or carrying isobutyryl- protected G residues could be synthesized with high efficiency. However, the deleterious G modification can be readily eliminated by inserting a capping step before the sulfurization reaction. Oligomers prepared with the Coupling-Cap-Thio-Cap cycle contained few phosphodiester contaminants as measured by31P-NMR, anion-exchange HPLC and MALDI-TOF mass spectrometry. In addition to reducing deprotection time, this new combination also provides a mild method for the preparation of certain phosphorothioate oligomers that may be sensitive to prolonged ammonia treatment (e.g. thioated RNAs).     

Functional inhibition of cytosolic and mitochondrial aspartate aminotransferase by l-2-amino-4-methoxy-trans-3-butenoic acid in isolated rat hepatocytes and mitochondria

The transaminase inhibitor l-2-amino-4-methoxy-trans-3-butenoic acid (AMB) decreased aspartate aminotransferase activity by approximately two-thirds in isolated rat liver mitohondria incubated with succinate, ammonia, and ornithine. Aspartate production by the mitochondria was unaffected over the 30-min incubation period, indicating that mitochondrial aspartate aminotransferase activity is normally far in excess of that required for maximal rates of aspartate production. In rat hepatocytes incubated with lactate, ammonia, and ornithine the inhibition of both the cytosolic and mitochondrial isozymes of aspartate aminotransferase by AMB was partially blocked by the presence of ammonia and ornithine. When pyruvate was substituted for lactate as a carbon source with isolated hepatocytes, the presence of ammonia and ornithine blocked the inhibition by AMB of the mitochondrial but not the cytosolic isozyme of aspartate aminotransferase. Urea formation by cells incubated with lactate, ammonia, and ornithine was unaffected by AMB unless the cells were preincubated with the inhibitor prior to the addition of substrates. However, urea formation by cells incubated in the presence of pyruvate, ammonia, and ornithine was inhibited strongly by AMB even without preincubation. The results suggest that the stimulation of ureogenesis from ammonia and ornithine by pyruvate involves the cytosolic isozyme of aspartate aminotransferase. In contrast, the stimulation of ureogenesis elicited by lactate primarily involved mitochondrial aspartate aminotransferase.     

A One-Pot Synthesis of 1-α- And 1-β-D-Arabinofuranosyl-2-Nitroimidazoles: Synthons to the Markers of Tumor Hypoxia

1-α-and 1-β-D-Arabinofuranosyl-2-nitroimidazole (α-AZA and β-AZA) are synthons for a number of potential markers of tissue hypoxia. A one pot synthesis in which 2-nitroimidazole is coupled with a mixture of α-and β-1-O-acetyl-2,3,5-tri-O-benzoyl-D-arabinofuranose in the presence of stannic chloride, followed by deprotection using ammonia/methanol, is described. Previously reported conditions for coupling 2-nitroimidazole to 1-α-bromoarabinofuranose protected by base-hydrolyzable groups afforded α-AZA almost exclusively.