核苷酸、聚核苷酸和核酸猝灭Tb3+-钛铁试剂络合物荧光的机理研究

研究了核苷酸、聚核苷酸和核酸对Tb³⁺－钛铁试剂(TR)络合物的荧光碎灭机理,认为荧光猝灭过程是核苷酸、聚核苷酸和核酸分子中的磷酸基组分与TR竞争Tb³⁺离子,生成实验条件下无荧光的二元络合物的静态猝灭过程;用Tb³⁺－TR络合物荧光探针研究DNA嵌入剂和金属离子与DNA相互作用的实验结果说明这一机理是合理的.     

Behaviour of nucleotides and oligonucleotides in potentiometric HPLC detection

Potentiometric HPLC detection was studied of mononucleotides (UMP, AMP, UDP, ADP, CTP, UTP, GTP, ATP) and oligonucleotides (a synthetic mixture d(T)_12–18 5′OH, a mixed 21-mer, 33-mer, and 60-mer). Coated-wire electrodes were used. The coatings were of the liquid membrane type containing PVC, DOS and synthetic macrocyclic amine- and podand ureum receptors. Electrodes based on these receptors gave very sensitive responses to triphosphate nucleotides and to oligonucleotides. The molar response of the oligonucleotides was related to their molar mass. The HPLC system consisted of a reversed phase column eluted with a phosphate buffer, triethylammoniumacetate (TEAA), and an acetonitrile gradient. The sensitive potentiometric response of these highly charged ions is discussed.     

Nucleotides. Part LXXVI

A series of new fluorescing 8‐(6‐hydroxyhexyl)isoalloxazine (=8‐(6‐hydroxyhexyl)benzo[g]pteridine‐2,4(1H,3H)‐dione) derivatives 4 – 13 were synthesized from 6‐[(6‐hydroxyhexyl)amino]uracil ( 2 ) with 1‐chloro‐4‐nitrosobenzene via 8‐chloro‐10‐(6‐hydroxyhexyl)isoalloxazine ( 3 ) and subsequent substitution of the Cl‐atom of 3 by various amines (Scheme). Analogously, 8‐substituted 10‐{3‐[(2,2‐dimethyl‐1,3‐dioxolan‐4‐yl)methoxy]propyl}isoalloxazines 19, 20 , and 23 – 25 were prepared which yielded on deprotection the corresponding 10‐[3‐(2,3‐dihydroxypropoxy)propyl]alloxazines 21, 22 , and 26 – 28 . Their conversion into the 3″‐O‐(4,4′‐dimethoxytrityl) derivatives 29 – 33 and subsequent transformation into the corresponding 2″‐(2‐cyanoethyl N,N‐diisopropylphosphoramidites) 34 – 38 led to new building blocks for oligonucleotide synthesis. A series of 21‐mer oligodeoxyribonucleotides carrying the fluorescing isoalloxazine 37 in various positions of the chain were assembled in a DNA synthesizer. Combination with the complementary sequence yielded the stable duplexes 40 – 54 showing by the melting temperatures T_m that the fluorophor ( F ) does not harm the stability of the unmodified duplex 39 (Table).     

New phosphorylating reagents for deoxyribonucleosides and oligonucleotides

New phosphorylating reagents 1 and 2 were prepared in three steps from 4-hydroxybenzaldehyde. They showed good efficiency in the solid phase synthesis of 5′-phosphate monoester nucleosides. End-phosphate DNA sequence synthesis demonstrated the efficiency of the new reagents (1 and 2) according to the general procedure of automated DNA synthesis. The oxidation of P(III) to P(V) and the removal of benzyl protecting groups were achieved in a single step by treatment with a 0.02 M I₂/pyridine/H₂O solution. Due to this one-pot treatment, it is possible to use the phosphorylating reagents (1 and 2) for the synthesis of base-sensitive ODNs. The reagents 1 and 2 are unique among phosphorylating reagents.     

Chemical synthesis of polynucleotides

Current methodology for the chemical synthesis of short chains (up to about twenty nucleotide units) of deoxyribopolynucleotides is reviewed.     

Synthesis and Hybridization Properties of Oligodeoxynucleotides with Long‐Chain Linkers

New oligonucleotides with a long‐chain linker (6,9‐dioxa‐3,12‐diazatetradecane‐1,14‐diyl) in their backbone were synthesized, and their hybridization properties were studied by measurement of their T_m curves and fluorescence spectra. The T_m analyses revealed that these oligonucleotides could bind to their complementary strands despite the presence of the long‐chain linker. We also demonstrated interesting fluorescence properties of oligodeoxynucleotides with an anthracen‐9‐ylmethyl group on one of the two N‐atoms in the long‐chain linker. The fluorescence intensity of these oligonucleotides increased upon their hybridization to the complementary strands and was sensitive to the presence of the mismatch base pairs at a specific position.     

Nucleotides. Part LXXVIII

Several N(‐hydroxyalkyl)‐2,4‐dinitroanilines were transformed into their phosphoramidites (see 5 and 6 in Scheme 1) in view of their use as fluorescence quenchers, and modified 2‐aminobenzamides (see 9, 10, 18 , and 19 in Scheme 1) were applied in model reactions as fluorophors to determine the relative fluorescence quantum yields of the 3′‐Aba and 5′‐Dnp‐3′‐Aba conjugates (Aba=aminobenzamide, Dnp=dinitroaniline). Thymidine was alkylated with N‐(2‐chloroethyl)‐2,4‐dinitroaniline ( 24 ) to give 25 which was further modified to the building blocks 27 and 28 (Scheme 3). The 2‐amino group in 29 was transformed by diazotation into the 2‐fluoroinosine derivative 30 used as starting material for several reactions at the pyrimidine nucleus (→ 31, 33 , and 35 ; Scheme 4). The 3′,5′‐di‐O‐acetyl‐2′‐deoxy‐N²‐[(dimethylamino)methylene]guanosine ( 37 ) was alkylated with methyl and ethyl iodide preferentially at N(1) to 43 and 44 , and similarly reacted N‐(2‐chloroethyl)‐2,4‐dinitroaniline ( 24 ) to 38 and the N‐(2‐iodoethyl)‐N‐methyl analog 50 to 53 (Scheme 5). The 2′‐deoxyguanosine derivative 53 was transformed into 3′,5′‐di‐O‐acetyl‐2‐fluoro‐1‐{2‐[(2,4‐dinitrophenyl)methylamino]ethyl}inosine ( 54 ; Scheme 5) which reacted with 2,2′‐[ethane‐1,2‐diylbis(oxy)]bis[ethanamine] to modify the 2‐position with an amino spacer resulting in 56 (Scheme 6). Attachment of the fluorescein moiety 55 at 56 via a urea linkage led to the doubly labeled 2′‐deoxyguanosine derivative 57 (Scheme 6). Dimethoxytritylation to 58 and further reaction to the 3′‐succinate 59 and 3′‐phosphoramidite 60 afforded the common building blocks for the oligonucleotide synthesis (Scheme 6). Similarly, 30 reacted with N‐(2‐aminoethyl)‐2,4‐dinitroaniline ( 61 ) thus attaching the quencher at the 2‐position to yield 62 (Scheme 7). The amino spacer was again attached at the same site via a urea bridge to form 64 . The labeling of 64 with the fluorescein derivative 55 was straigthforward giving 65 . and dimethoxytritylation to 66 and further phosphitylation to 67 followed known procedures (Scheme 7). Several oligo‐2′‐deoxynucleotides containing the doubly labeled 2′‐deoxyguanosines at various positions of the chain were formed in a DNA synthesizer, and their fluorescence properties and the T_ms in comparison to their parent duplexes were measured (Tables 1–5).     

Nucleotides. Part LXXV

The reactivity of the 2′‐deoxy‐N⁴‐(phenoxycarbonyl)cytidine derivatives 3 and 4 with aromatic amines was studied to form new types of urea derivatives (see 5 – 10 ). On the same basis, labeling of 3 and 4 with 5‐aminofluorescein ( 14 ) was achieved to give the conjugates 15 and 17 , respectively (Scheme 1). Treatment of 17 with 2‐(4‐nitrophenyl)ethanol in a Mitsunobu reaction led to double protection of the fluorescein moiety (→ 18 ) and desilylation yielded 19 . Dimethoxytritylation (→ 20 ) and subsequent phosphitylations afforded the new building blocks 21 and 22 . Synthesis of the fully protected trimer 28 was achieved by condensation of 21 with 23 to 26 which after detritylation (→ 27 ) was coupled with 25 to give 28 (Scheme 2). Deprotection of all blocking groups was performed with 1,8‐diazabicyclo[5.4.0]undec‐7‐ene (DBU) in one step to give 29 . The synthesis of the decamer 5′‐d(C^FluCCG GCC CGC)‐3′ ( 33 ) started from 30 which was attached to the solid support and then elongated with 31, 32 , and 22 at the 5′‐terminal end (C^Flu=deprotected phosphate derivative of 22 ). Hybridization with the complementary oligomer 5′‐d(G GGC CGG GCG)‐3′ ( 34 ) showed the influence of the fluorescein label on the stability of the duplex.     

Systematic Enzymatic Synthesis of dTDP-Activated Sugar Nucleotides

Deoxythymidine diphosphate (dTDP)-activated sugar nucleotides are the most diverse sugar nucleotides in nature. They serve as the glycosylation donors of glycosyltransferases to produce various carbohydrate structures in living organisms. However, most of the dTDP-sugars are difficult to obtain due to synthetic difficulties. The limited availability of dTDP-sugars has hindered progress in investigating the biosynthesis of carbohydrates and exploring new glycosyltransferases in nature. In this study, based on the de novo and salvage biosynthetic pathways, a variety of dTDP-activated sugar nucleotides were successfully prepared in high yields and on a large scale from readily available starting materials. The produced sugar nucleotides could provide effective tools for fundamental research in glycoscience.     

Synthesis of oligonucleotides containing an O-G-alkyl-O-G interstrand cross-link

A methodology to synthesize oligonucleotides containing an alkyl interstrand cross-link between the two O6 atoms of deoxyguanosine has been developed. This cross-link is designed to serve as a stable structural mimic of the lesion formed in duplex DNA with the bifunctional alkylating agent hepsulfam. The O6-alkyl coupling is performed via a Mitsunobu reaction between a nucleoside and mono-protected 1,7-heptanediol. Solid-phase oligonucleotide synthesis using a nucleoside bis-phosphoramidite allows for the assembly of the cross-linked duplex. Sufficient quantities of this cross-linked duplex were obtained for various structural and biological investigations.     

Synthesis of reactive cytidine derivatives as building blocks for cross-linking oligonucleotides

6-Vinylcytidine derivative (1) possessing good Michael acceptor properties has been synthesized through C-6 formylation and subsequent Wittig reaction. In view of introducing the reactive nucleoside into the oligonucleotide sequence, protection of the vinyl group as ethylthio derivative was proved to be effective for the masking and subsequent regeneration of the reactive vinyl moiety.     

Structure and Function of Nucleosides and Nucleotides

The nucleosides participating in biological processes consist of a sugar and a heterocyclic nucleobase; the nucleotides, which occur as monomers and as building units of polymeric nucleic acids, contain an additional phosphoester group. The complexity of the molecules leads to a complex stereochemistry with which the present progress report is concerned. Particular attention will be devoted to conformational considerations at the sugar groups, the syn-anti conformation, the position of the C(5′)? O(5′) bond relative to the sugar group, and the conformation of the phosphoester bonds. The article touches upon base pairing and base stacking, as well as forces stabilizing the syn conformation, and also deals with the reaction mechanism of the enzyme pancreatic ribonuclease as established from the stereochemistry of nucleotides and the mechanisms of action of the antileukemia drug 6-azauridine and the antibiotic actinomycin D. Views on the effects of the unusual structures of the “rare” nucleosides 4-thiouridine, isopentenyladenosine, and dihydrouridine on the structure of transfer ribonucleic acid are also presented.     

A Monte Carlo simulation study of the aqueous hydration of d(CGCGCG) in Z form

Summary Monte Carlo computer simulation is described for the hexamer d(CGCGCG) in the Z form together with 910 water molecules at an environmental density of 1 gm/cc in a cubic cell under periodic boundary conditions. Water-water interactions were treated using the TIP4P potential and the solute water interactions by TIP4P spliced with the non-bonded interactions from the AMBER 3.0 force field. The simulation was subjected to proximity analysis to obtain solute coordination numbers and pair interaction energies for each solute atom. Hydration density distributions partitioned into contributions from the major groove, the minor groove, and the sugar-phosphate backbone were examined, and the probabilities of occurrence for one- and two-water bridges in the simulation were enumerated. The results are compared with observations of crystallographic ordered water sites from the X-ray diffraction studies.     

Synthesis of Thymidine Dimer Containing Novel (N‐Acetyl)imino Linkage

By starting with 3′‐keto‐5′‐O‐protected thymidine, 3′‐O‐amino‐5′‐t‐butyl‐diphenylsilyl thymidine ( 9 ) was prepared and coupled with 3′‐O‐t‐butyl‐diphenylsilyl‐5′‐formyl thymidine to form a nucleoside dimer ( 11 ) containing oxime linkage. The back bone of this dimer, then, under went reduction followed by acetylation to give an (N‐acetyl)imino linkage, and a novel dinucleotide ( 13 ) was obtained.     

Synthesis and properties of cross-linkable DNA duplex using 4-amino-2-oxo-6-vinyl-1,3,5-triazine

We synthesized the DNA oligonucleotide containing a new cross-linkable 4-amino-2-oxo-6-vinyltriazine (AOVT) nucleobase analogue (Et-AOVT) and evaluated these properties. Our results of the cross-link assay and thermal denaturing assay of duplexes containing AOVT demonstrated that the additional aza of AOVT has an impact on the duplex stability and crosslink properties. Our data suggests that the additional 5-aza of AOVT is involved in the hydrogen bonding with the complementary guanine, and this hydrogen bonding system successfully flipped the reactive vinyl group out to the major groove of the duplex demonstrating a new paradigm of a “cross-linkable duplex”.     

Synthesis of 1,3-{Di-[N-bis(dimethylamino)methane]}- benzyl-diamide and its Molecular Recognition of Nucleotides in Aqueous Solution

1,3-Di-{N-[bis(dimethylamino)methane]}benzyl-diamide 1 was synthesized by the reaction of isophthaloyl dichloride with 1,1,3,3-tetramethylguanidine (TMG). Its structure was confirmed by IR, ¹H NMR, EI-MS and elemental analysis. ¹H NMR results of the interaction of 1 with phosphate-containing biomolecules showed it has the ability of selective molecular recognition for nucleotides.