3'-minor groove binder-DNA probes increase sequence specificity at PCR extension temperatures.

DNA probes with conjugated minor groove binder (MGB) groups form extremely stable duplexes with single-stranded DNA targets, allowing shorter probes to be used for hybridization based assays. In this paper, sequence specificity of 3'-MGB probes was explored. In comparison with unmodified DNA, MGB probes had higher melting temperature (T(m)) and increased specificity, especially when a mismatch was in the MGB region of the duplex. To exploit these properties, fluorogenic MGB probes were prepared and investigated in the 5'-nuclease PCR assay (real-time PCR assay, TaqMan assay). A 12mer MGB probe had the same T(m)(65 degrees C) as a no-MGB 27mer probe. The fluorogenic MGB probes were more specific for single base mismatches and fluorescence quenching was more efficient, giving increased sensitivity. A/T rich duplexes were stabilized more than G/C rich duplexes, thereby leveling probe T(m)and simplifying design. In summary, MGB probes were more sequence specific than standard DNA probes, especially for single base mismatches at elevated hybridization temperatures.

Linkers designed to intercalate the double helix greatly facilitate DNA alkylation by triplex-forming oligonucleotides carrying a cyclopropapyrroloindole reactive moiety.

Triplex-forming oligonucleotides (TFOs) bind sequence-specifically in the major groove of double-stranded DNA. Cyclopropapyrroloindole (CPI), the electrophilic moiety that comprises the reactive subunit of the antibiotic CC-1065, gives hybridization-triggered alkylation at the N-3 position of adenines when bound in the minor groove of double-stranded DNA. In order to attain TFO-directed targeting of CPI, we designed and tested linkers to 'thread' DNA from the major groove-bound TFO to the minor groove binding site of CPI. Placement of an aromatic ring in the linker significantly enhanced the site-directed reaction, possibly due to a 'threading' mechanism where the aromatic ring is intercalated. All of the linkers containing aromatic rings provided efficient alkylation of the duplex target. The linker containing an acridine ring system, the strongest intercalator in the series, gave a small but clearly detectable amount of non-TFO-specific alkylation. An equivalent-length linker without an aromatic ring was very inefficient in DNA target alkylation.

Fidelity of binding of the guanidinium nucleic acid (DNG) d(Tg)4-T-azido with short strand DNA oligomers (A5G3A5, GA4G3A4G, G2A3G3A3G2, G2A2G5A2G2). A kinetic and thermodynamic study.

Short strand DNA oligomers (A5G3A5, GA4G3A4G, G2A3G3A3G2, and G2A2G5A2G2) and the guanidinium (g) linked thymidyl nucleoside d(Tg)4-T-azido associate as triplexes. The melting temperatures, Tm, the association and dissociation kinetic and thermodynamic parameters and activation energies for the triplexes were determined by UV thermal analysis. The hypochromic shift and Tm for triplex formation increases with increase in concentration and decreases with the number of mismatches. The melting temperatures are between 35 and 55 degrees C in the range of ionic strength of 0.06-0.24 and decrease with increase in ionic strength at 100 deg/(ionic strength unit). The melting and cooling curves exhibit hysteresis behavior in the temperature range 5-95 degrees C at 0.2 deg/min thermal rate. From these curves, the rate constants and the energies of activation for association (k(on), E(on)) and dissociation (k(off), E(off)) processes were obtained. The second-order rate constants, k(on), for the triplex formation at 288 K are between 10 and 500 M(-2) s(-1). Values of k(on) increase with the decrease in the ionic strength. The first order rate constants for the dissociation, k(off), at 288 K are between 10(-6) and 40 x 10(-6) s(-1) and increase with increase in ionic strength. The energies of activation for the association and dissociation processes are in the range -22 to -9 kcal/mol and 8 to 29 kcal/mol, respectively. At 6.3 x 10(-5) M/base and at the physiological ionic strength (0.15-0.30) and below, the triplex structures formed with d(Tg)4-T-azido and A5G3A5 and GA4G3A4G have well-defined Tm values. The melting curves with G2A3G3A3G2 and G2A2G5A2G2 are very shallow with small hypochromic shifts denoting negligible binding at physiological ionic strength. Therefore, with the increase in the G content (mismatched base pairs) at a certain concentration (e.g., 6.3 x 10(-5) M/base), discrimination (change in fidelity) occurs in the formation and strength of binding of d(Tg)4-T-azido to d(pAn pGm) oligomers. The standard molar enthalpies for triplex formation have in general larger negative values at low ionic strength than at high ionic strength, indicating that at lower mu values the formation of triplexes of d(Tg)4-T-azido with d(pAn pGm) are more favorable. The values of deltaH(standard)(288) calculated from the activation parameters are between -17 and -49 kcal/mol, and the values of deltaG(standard)(288) are between -7.5 and -11.8 kcal/mol for A5G3A5, GA4G3A4G, G2A3G3A3G2, and G2A2G5A2G2, respectively. There is a linear relationship in the enthalpy-entropy compensation for the triplex melting thermodynamics.

Design and synthesis of ribonucleic guanidine: a polycationic analog of RNA.

Replacement of the phosphodiester linkages of the polyanion RNA with guanidinium linkers (represented by g) provides the polycation ribonucleic guanidine (RNG). An anticipated structure for the triple-helical hybrid [r(Up)9U.r(Ag)9A.r(Up)9U] is presented. A basic strategy for the synthesis of RNG oligomers is described. Synthetic procedures are provided for tetrameric adenosyl RNG [r(Ag)3A].

Binding studies of cationic thymidyl deoxyribonucleic guanidine to RNA homopolynucleotides.

Deoxyribonucleic guanidine is a potential antisense agent that is generated via the replacement of the negative phosphodiester linkages of DNA [--O--(PO2-)--O--] with positively-charged guanidinium (g) linkages [--NH--C(==NH2+)--NH--]. A pentameric thymidyl deoxyribonucleic guanidine molecule [d(Tg)4T-azido] has been shown to base pair specifically to poly(rA) with an unprecedented affinity. Both double and triple strands consisting of one and two equivalents of d(Tg)4T-azido paired with one equivalent of poly(rA) are indicated by thermal denaturation experiments. At an ionic strength of 0.22, the five bases of d(Tg)4T-azido are estimated to dissociate from a double helix with poly(rA) at > 100 degrees C! The effect of ionic strength on thermal denaturation is very pronounced, with stability greatest at low ionic strengths. The method of continuous variation indicates that there is an equilibrium complex with a molar ratio of d(Tg) to r(Ap) or d(Ap) of 2:1. Based on this evidence, models of the structures of d(Tg)9T-azido bound to r(Ap)9A are proposed.

Synthesis of a thymidyl pentamer of deoxyribonucleic guanidine and binding studies with DNA homopolynucleotides.

Replacement of the phosphodiester linkages of the polyanion DNA with guanidine linkers provides the polycation deoxynucleic guanidine (DNG). The synthesis of pentameric thymidyl DNA is provided. This polycationic DNG species binds with unprecedented affinity and with base-pair specificity to negatively charged poly(dA) to provide both double and triple helices. The dramatic stability of these hybrid structures is shown by their denaturation temperatures (Tm). For example, the double helix of the pentameric thymidyl DNG and poly(dA) does not dissociate in boiling water (ionic strength = 0.12), whereas the Tm for pentameric thymidyl DNA associated with poly(dA) is approximately 13 degrees C (ionic strength = 0.12). The effect of ionic strength on Tm for DNG complexes with DNA shows an opposite correlation compared with double-stranded DNA and is much more dramatic than for double-stranded DNA.

Design and synthesis of deoxynucleic guanidine: a polycation analogue of DNA.

The basic strategy is described for the connection of nucleosides by guanidinium (g) linkers to provide the positively charged deoxynucleic guanidine putative antigene agents. The synthetic procedures are provided for d(gT)n. Molecular modeling of double-stranded [d(gT)10.d(Ap)10] and the triple-helical hybrids [d(Tp)10.d(Ap)10.d(gT)10] and [d(gT)10.d(Ap)10.d(gT)10] suggest modes of interaction and anticipated structural features.

Kinetic studies of 2-(2'-Haloethyl) and 2-ethenyl substituted quinazolinone alkylating agents. Acid-catalyzed dehydrohalogenation and alkylation involving a quinazolinone prototropic tautomer.

The mechanism of halide elimination from 2-haloethyl-5,8-dihydroxyquinazolin-4(3H)-ones was studied in aqueous buffer by means of a pH-rate profile, buffer dilution studies, isotopic labeling, and kinetic isotope effects. From the results of these studies, it is apparent that a quinazolinone tautomer, arising from a prototropic shift of the C(l') proton to the N(1) position, is formed in the rate determining step of elimination. Monobasic phosphate acts as a bifunctional catalyst for the tautomerism. The halide then eliminates from the tautomer to afford the alkene derivative. Conversely, hydroxyethyl mercaptide adds to the alkene to afford the tautomer. The significance of these studies lies in the discovery of a prototropic tautomer of quinazolinone, which is reversibly formed in aqueous buffer under mild conditions, and in the discovery of alkylation chemistry useful in the design of quinazolinone-based enzyme inhibitors.

High-level expression in Escherichia coli and rapid purification of enzymatically active honey bee venom phospholipase A2.

Bee venom phospholipase A2 (BV-PLA2) is a hydrolytic enzyme that specifically cleaves the sn-2 acyl bond of phospholipids at the lipid/water interface. The same enzyme is also believed to be responsible for some systemic anaphylactic reactions in bee venom sensitized individuals. To study the structure/function relationships of this enzyme and to define the molecular determinants responsible for its allergenic potential, a synthetic gene encoding the mature form of BV-PLA2 was expressed in Escherichia coli. This enzyme was produced as a fusion protein with a 6xHis-tag on its amino-terminus yielding 40-50 mg of fusion protein per 1 of culture after metal ion affinity chromatography. A kallikrein protease recognition site was engineered between the 6xHis-tag and the amino-terminus of the enzyme allowing isolation of the protein with its correct N-terminus. Recombinant affinity purified BV-PLA2 was refolded, purified to homogeneity, and cleaved with kallikrein, resulting in a final yield of 8-9 mg of active enzyme per 1 of culture. The enzymatic and immunological properties of the recombinant BV-PLA2 are identical to enzyme isolated from bee venom indicating a native-like folding of the protein.

Rational design of quinazoline-based irreversible inhibitors of human erythrocyte purine nucleoside phosphorylase.

Described herein is the rational design of irreversible inhibitors of human erythrocyte purine nucleoside phosphorylase (PNPase). Inhibitor design started with the observation that the amino group of 8-aminoquinazolin-4(3H)-one interacts with enzyme-bound phosphate. This observation correctly predicted that the 5,8-dione (quinone) and 5,8-dihydroxy (hydroquinone) derivatives of quinazolin-4(3H)-ones would enter the active site. The amine-phosphate interaction also served to confirm that a quinazolin-4(3H)-one binds in the PNPase active sites like a purine substrate. From models of the PNPase active site it was possible to design quinazoline-based quinones that undergo a reductive-addition reaction with an active-site glutamate residue. The best inhibitor studied, 2-(chloromethyl)quinazoline-4,5,8(3H)-trione, rapidly inactivates PNPase by a first-order process with an inhibitor to enzyme stoichiometry of 150. The active-site hydroquinone adduct of this inhibitor eliminates a leaving group to afford a quinone methide species positioned to alkylate another active-site glutamate residue. Thus, this inhibitor is designed to cross-link the PNPase active site by reductive addition followed by the generation of an alkylating quinone methide species.

Interactions of tubulin with potent natural and synthetic analogs of the antimitotic agent combretastatin: a structure-activity study.

Combretastatin, an antineoplastic and antimitotic agent, was isolated from the bark of Combretum caffrum [Can. J. Chem. 60: 1374-1376 (1982); Biochem. Pharmacol. 32:3864-3867 (1983)]. Structurally, combretastatin consists of two substituted benzene rings linked by a saturated, hydroxy-substituted two-carbon bridge. A large number of combretastatin analogs have now been synthesized or obtained from C. caffrum. These vary in substituents on the phenyl rings or bridge carbons, bridge length, unsaturation of the bridge (i.e., stilbene derivatives, with the two phenyl rings oriented either cis or trans), and in precise ring structure (two major variants, with the bridge incorporated into a third six-member ring to form a phenanthrene structure or a methyl group eliminated from vicinal methoxy substituents to form a benzodioxole ring). Available analogs (17 natural products and 22 synthetic agents) were examined for antimitotic and cytotoxic activity and for effects on tubulin polymerization and colchicine binding. Nineteen compounds inhibited cell growth by 50% or more at concentrations of 1 microM or less, and 14 inhibited tubulin polymerization by at least 50% at stoichiometric drug concentrations. The most potent cytotoxic agents generally strongly inhibited both tubulin polymerization and the binding of colchicine to tubulin. The most promising compound is the (cis)-stilbene derivative (cis)-1-(3,4,5-trimethoxyphenyl)-2-(3'-hydroxy-4'-methoxyphenyl)ethene, which has been named combretastatin A-4. This compound inhibited cell growth by 50% at 7 nM, inhibited tubulin polymerization by 50% at 2.5 microM (1/4 molar equivalent), and competitively inhibited colchicine binding with an apparent Ki of 0.14 microM.