Effect of heavy metal contaminated shooting range soils on mycorrhizal colonization of roots and metal uptake by leek.

We grew leek (Allium porrum) in soils of two shooting ranges heavily contaminated with heavy metals in the towns of Zuchwil and Oberuzwil in Switzerland as a bioassay to test the activity of arbuscular mycorrhizal (AM) fungi in these soils. Soil samples were taken from (1) front of the shooting house (HOUSE), (2) the area between house and target (FIELD) and (3) the berm (BACKSTOP). Samples of Ribwort plantain (Plantago lanceolata) growing naturally within the shooting ranges were also collected and the colonization of its roots by mycorrhizal fungi was measured. The number of AM spores in the soils was significantly reduced concomitant with the increase in the degree of soil contamination with metals. In Zuchwil, mycorrhizal fungi equally colonized roots of Ribwort plantain sampled from BACKSTOP and HOUSE. In Oberuzwil, however, plants from BACKSTOP had lower colonization when compared with those sampled from HOUSE. Colonization of leek was strongly reduced in the BACKSTOP soil of Zuchwil and slightly reduced in the BACKSTOP soil of Oberuzwil when compared with plants grown in respective HOUSE soil. Concentrations of Cd, Cr, Cu, Ni, Pb and Zn in the leaves of leek grown in the BACKSTOP soil was within the range considered toxic for human consumption. This points to the high degree of bioavailability of these metal in these soils. Significant decrease in the number of mycorrhizal spores in the BACKSTOP soils in Zuchwil and the low colonization of leek roots grown in these soils point to possible changes in the species diversity of mycorrhizal fungi in these soils.

Evidence for a four-strand exchange catalyzed by the RecA protein.

Strand exchange between two duplexes is usually initiated as a three-strand event that requires the presence of a single-stranded overhang or gap in one of the two molecules. Here we show that the RecA protein can catalyze a four-strand exchange. Specifically, it can recombine short hairpin substrates with homologous stems provided that one of the hairpins possesses a chimeric DNA/RNA backbone. This four-strand exchange reaction goes to completion in the presence of ATPgammaS and releases a stable heteroduplex upon removal of the RecA protein. Under identical conditions, strand exchange between two DNA hairpins is incomplete and generates a nascent heteroduplex that rapidly dissociates when the RecA protein is denatured. Since presynaptic filament formation does not appear to melt either type of hairpin, we propose that exchange occurs between homologously aligned duplexes that are extended and unwound within a RecA filament. The first reaction provides a mechanism for gene targeting by chimeric double-hairpin oligonucleotides while the second reaction explains the ability of the RecA protein to transiently align double-stranded DNA molecules.

The DNA strand of chimeric RNA/DNA oligonucleotides can direct gene repair/conversion activity in mammalian and plant cell-free extracts.

Chimeric oligonucleotides (chimeras), consisting of RNA and DNA bases folded by complementarity into a double hairpin conformation, have been shown to alter or repair single bases in plant and animal genomes. An uninterrupted stretch of DNA bases within the chimera is known to be active in the sequence alteration while RNA residues aid in complex stability. In this study, the two strands were separated in the hope of defining the role each plays in conversion. Using a series of single-stranded oligonucleotides, comprised of all RNA or DNA residues and various mixtures, several new structures have emerged as viable molecules in nucleotide conversion. When extracts from mammalian and plant cells and a genetic readout assay in bacteria are used, single-stranded oligonucleotides, containing a defined number of thioate backbone modifications, were found to be more active than the original chimera structure in the process of gene repair. Single-stranded oligonucleotides containing fully modified backbones were found to have low repair activity and in fact induce mutation. Molecules containing various lengths of modified RNA bases (2'-O-methyl) were also found to possess low activity. Taken together, these results confirm the directionality of nucleotide conversion by the DNA strand of the chimera and further present a novel, modified single-stranded DNA molecule that directs conversion in plant and animal cell-free extracts.

A plausible mechanism for gene correction by chimeric oligonucleotides.

Self-complementary chimeric oligonucleotides that consist of DNA and 2'-O-methyl RNA nucleotides arranged in a double-hairpin configuration can elicit a point mutation when targeted to a gene sequence. We have used a series of structurally diverse chimeric oligonucleotides to correct a mutant neomycin phosphotransferase gene in a human cell-free extract. Analysis of structure-activity relationships demonstrates that the DNA strand of the chimeric oligonucleotide acts as a template for high-fidelity gene correction when one of its bases is mismatched to the targeted gene. By contrast, the chimeric strand of the oligonucleotide does not function as a template for gene repair. Instead, it appears to augment the frequency of gene correction by facilitating complex formation with the target. In the presence of RecA protein, each strand of a chimeric oligonucleotide can hybridize with double-stranded DNA to form a complement-stabilized D-loop. This reaction, which may take place by reciprocal four-strand exchange, is not observed with oligonucleotides that lack 2'-O-methyl RNA segments. Preliminary sequencing data suggest that complement-stabilized D-loops may be weakly mutagenic. If so, a low level of random mutagenesis in the vicinity of the chimera binding site may accompany gene repair.

Targeted mutagenesis of DNA with alkylating RecA assisted oligonucleotides.

Site-specific mutation was demonstrated in a shuttle vector system using nitrogen mustard-conjugated oligodeoxyribonucleotides (ODNs). Plasmid DNA was modified in vitro by ODNs containing all four DNA bases in the presence of Escherichia coli RecA protein. Up to 50% of plasmid molecules were alkylated in the targeted region of the supF gene and mutations resulted upon replication in mammalian cells. ODNs conjugated with either two chlorambucil moieties or a novel tetrafunctional mustard caused interstrand crosslinks in the target DNA and were more mutagenic than ODNs that caused only monoadducts.

Antisense oligonucleotides containing modified bases inhibit in vitro translation of Leishmania amazonensis mRNAs by invading the mini-exon hairpin.

Complementary oligodeoxynucleotides (ODNs) that contain 2-aminoadenine and 2-thiothymine interact weakly with each other but form stable hybrids with unmodified complements. These selectively binding complementary (SBC) agents can invade duplex DNA and hybridize to each strand (Kutyavin, I. V., Rhinehart, R. L., Lukhtanov, E. A., Gorn, V. V., Meyer, R. B., and Gamper, H. B. (1996) Biochemistry 35, 11170-11176). Antisense ODNs with similar properties should be less encumbered by RNA secondary structure. Here we show that SBC ODNs strand invade a hairpin in the mini-exon RNA of Leishmania amazonensis and that the resulting heteroduplexes are substrates for Escherichia coli RNase H. SBC ODNs either with phosphodiester or phosphorothioate backbones form more stable hybrids with RNA than normal base (NB) ODNs. Optimal binding was observed when the entire hairpin sequence was targeted. Translation of L. amazonensis mRNA in a cell-free extract was more efficiently inhibited by SBC ODNs complementary to the mini-exon hairpin than by the corresponding NB ODNs. Nonspecific protein binding in the cell-free extract by phosphorothioate SBC ODNs rendered them ineffective as antisense agents in vitro. SBC phosphorothioate ODNs displayed a modest but significant improvement of leishmanicidal properties compared with NB phosphorothioate ODNs.

Targeted gene repair directed by the chimeric RNA/DNA oligonucleotide in a mammalian cell-free extract.

Chimeric oligonucleotides consisting of RNA and DNA residues have been shown to catalyze site-directed genetic alteration in mammalian cells both in vitro and in vivo. Since the frequency of these events appears to be logs higher than the rates of gene targeting, a process involving homologous recombination, we developed a system to study the mechanisms of chimera-directed gene conversion. Using a mammalian cell-free extract and a genetic readout in Escherichia coli, we find that point mutations and single base deletions can be corrected at frequencies of approximately 0.1% and 0.005%, respectively. The reaction depends on an accurately designed chimera and the presence of functional hMSH2 protein. The results of genetic and biochemical studies reported herein suggest that the process of mismatch repair functions in site-directed gene correction.

Inhibition of transcription elongation in the HER-2/neu coding sequence by triplex-directed covalent modification of the template strand.

Triplex formation may be of potential utility to inhibit the expression of individual genes. We describe the formation of a triple helix in the coding sequence of the HER-2/neu gene. In vitro transcription analysis in the presence and absence of triplex formation demonstrates that an unmodified DNA triplex-forming oligonucleotide is incapable of inhibiting RNA polymerase elongation. Triplex formation by an oligonucleotide-psoralen conjugate was used to form a covalent photoadduct with a thymine on the nontemplate strand of the HER-2/neu gene. In the native HER-2/neu gene, covalent attachment of the triplex-forming oligonucleotide to the nontemplate strand did not prevent RNA polymerase elongation. Using HER-2/neu point mutants that would place the target thymine on the template strand, we demonstrated that covalent modification of the template strand was necessary to inhibit RNA polymerase elongation. Based on these data, we synthesized oligonucleotide-alkylator conjugates that would react with a specific guanine residue on the template strand of the HER-2/neu coding sequence. The oligonucleotide-alkylator conjugates inhibited transcription elongation by T7 RNA polymerase and eukaryotic RNA polymerase II from a HeLa nuclear extract. These studies demonstrate the successful application of triplex-forming oligonucleotide-alkylator conjugates to inhibit transcription elongation in the HER-2/neu gene, and show that covalent modification of the DNA strand used as the transcription template is necessary to prevent RNA polymerase elongation.

Triplex targeting of a native gene in permeabilized intact cells: covalent modification of the gene for the chemokine receptor CCR5.

A 12 nucleotide oligodeoxyribopurine tract in the gene for the chemokine receptor CCR5 has been targeted and covalently modified in intact cells by a 12mer triplex forming oligonucleotide (TFO) bearing a reactive group. A nitrogen mustard placed on the 5'-end of the purine motif TFO modified a guanine on the DNA target with high efficiency and selectivity. A new use of a guanine analog in these TFOs significantly enhanced triplex formation and efficiency of modification, as did the use of the triplex-stabilizing intercalator coralyne. This site-directed modification of a native chromosomal gene in intact human cells under conditions where many limitations of triplex formation have been partially addressed underscores the potential of this approach for gene control via site-directed mutagenesis.

Solution structure of a highly stable DNA duplex conjugated to a minor groove binder.

The tripeptide 1,2-dihydro-(3 H )-pyrrolo[3,2- e ]indole-7-carboxylate (CDPI3) binds to the minor groove of DNA with high affinity. When this minor groove binder is conjugated to the 5'-end of short oligonucleotides the conjugates form unusually stable hybrids with complementary DNA and thus may have useful diagnostic and/or therapeutic applications. In order to gain an understanding of the structural interactions between the CDPI3minor groove binding moiety and the DNA, we have determined and compared the solution structure of a duplex consisting of oligodeoxyribonucleotide 5'-TGATTATCTG-3' conjugated at the 5'-end to CDPI3 and its complementary strand to an unmodified control duplex of the same sequence using nuclear magnetic resonance techniques. Thermal denaturation studies indicated that the hybrid of this conjugate with its complementary strand had a melting temperature that was 30 degrees C higher compared with the unmodified control duplex. Following restrained molecular dynamics and relaxation matrix refinement, the solution structure of the CDPI3-conjugated DNA duplex demonstrated that the overall shape of the duplex was that of a straight B-type helix and that the CDPI3moiety was bound snugly in the minor groove, where it was stabilized by extensive van der Waal's interactions.

Modulation of Cm/T, G/A, and G/T triplex stability by conjugate groups in the presence and absence of KCl.

Apparent equilibrium association constants were determined by gel mobility shift analysis for triple strand formation between a duplex target containing a 21 base long A-rich homopurine run and several end-modified C(m)/T (pyrimidine motif; C(m) = 5-methylcytosine), G/A (purine motif), and G/T (purine-pyrimidine motif) triplex-forming oligonucleotides (TFOs). Incubations were carried out for 24 h at 37 degrees C in 20 mM HEPES, pH 7.2, 10 mM MgCl2, and 1 mM spermine. The purine motif triplex was the most stable (Ka = 6.2 x 10(8) M-1) even though the TFO self-associated as a linear duplex. Conjugation of a terminal hexanol or cholesterol group to the G/A-containing TFO reduced triplex stability by 1.6- or 13-fold, whereas an aminohexyl group or intercalating agent (acridine or psoralen) increased triplex stability by 1.3- or 13-fold. These end groups produced similar effects in C(m)/T and G/T triplexes, although the magnitude of the effect sometimes differed. Addition of 140 mM KCl to mimic physiological conditions decreased stability of the G/A triplex by 1900-fold, making it less stable than the C(m)/T triplex. The inhibitory effect of KCl on G/A triplex formation could be partially compensated for by conjugating the TFO to an intercalating agent (30-350-fold stabilization) or by adding the triplex selective intercalator coralyne (1000-fold stabilization). Although the G/T triplex responded similarly to these agents, the stability of the C(m)/T triplex was unaffected by the presence of coralyne and was only enhanced 1.4-2.8-fold when the TFO was linked to an intercalating agent. In physiological buffer supplemented with 40 microM coralyne, the G/A triplex (Ka = 3.0 x 10(8) M-1) was more stable than the C(m)/T and G/T triplexes by factors of 300 and 12, respectively.

Factors influencing the extent and selectivity of alkylation within triplexes by reactive G/A motif oligonucleotides.

G/A motif triplex-forming oligonucleotides (TFOs) complementary to a 21 base pair homopurine/homopyrimidine run were conjugated at one or both ends to chlorambucil. These TFOs were incubated with several synthetic duplexes containing the targeted homopurine run flanked by different sequences. The extent of mono and interstrand cross-linking was compared with the level of binding at equilibrium. Covalent modification took place within a triple-stranded complex and usually occurred at guanine residues in the flanking double-stranded DNA. The efficiency of alkylation was dependent upon the sequence of the flanking duplex, the solution conditions, and the rate of triplex formation relative to the rate of chlorambucil reaction. Self-association of the TFOs as parallel duplexes was demonstrated and this did not interfere with triple strand formation. With an optimal target, cross-linking of the triplex was very efficient when incubation was carried in a physiological buffer supplemented with the triplex selective intercalator coralyne.

Sequence-specific targeting and covalent modification of human genomic DNA.

We compare two techniques which enable selective, nucleotide-specific covalent modification of human genomic DNA, as assayed by quantitative ligation- mediated PCR. In the first, a purine motif triplex-forming oligonucleotide with a terminally appended chlorambucil was shown to label a target guanine residue adjacent to its binding site in 80% efficiency at 0.5 microM. Efficiency was higher in the presence of the triplex-stabilizing intercalator coralyne. In the second method, an oligonucleotide targeting a site containing all four bases and bearing chlorambucil on an interior base was shown to efficiently react with a specific nucleotide in the target sequence. The targeted sequence in these cases was in the DQbeta1*0302 allele of the MHC II locus.

Oligonucleotides with conjugated dihydropyrroloindole tripeptides: base composition and backbone effects on hybridization.

The ability of conjugated minor groove binding (MGB) residues to stabilize nucleic acid duplexes was investigated by synthesis of oligonucleotides bearing a tethered dihydropyrroloindole tripeptide (CDPI3). Duplexes bearing one or more of these conjugated MGBs were varied by base composition (AT- or GC-rich oligonucleotides), backbone modifications (phosphodiester DNA, 2'-O-methyl phosphodiester RNA or phosphorothioate DNA) and site of attachment of the MGB moiety (5'- or 3'-end of either duplex strand). Melting temperatures of the duplexes were determined. The conjugated CDPI3 residue enhanced the stability of virtually all duplexes studied. The extent of stabilization was backbone and sequence dependent and reached a maximum value of 40-49 degrees C for d(pT)8. d(pA)8. Duplexes with a phosphorothioate DNA backbone responded similarly on CDPI3 conjugation, although they were less stable than analogous phosphodiesters. Modest stabilization was obtained for duplexes with a 2'-O-methyl RNA backbone. The conjugated CDPI3 residue stabilized GC-rich DNA duplexes, albeit to a lesser extent than for AT-rich duplexes of the same length.

Efficient priming of PCR with short oligonucleotides conjugated to a minor groove binder.

The tripeptide 1,2-dihydro-(3H)-pyrrolo[3,2-e]indole-7-carboxylate (CDPI3) binds to the minor groove of DNA with high affinity. When this minor groove binder (MGB) is conjugated to the 5'-end of short oligodeoxynucleotides (ODNs), the conjugates form unusually stable hybrids with complementary DNA in which the tethered CDPI3group resides in the minor groove. We show that these conjugates can be used as PCR primers. Due to their unusually high binding affinity, conjugates as short as 8-10mers can be used to amplify DNA with good specificity and efficiency. The reduced length primers described here might be appropriate for the PCR amplification of viral sequences which possess a high degree of variability (e.g., HPV, HIV) or for recent techniques such as gene hunting and differential display which amplify multiple sequences using short primer pairs.

[Selective stabilization of AT-rich DNA duplexes by oligodeoxyribonucleotide conjugates with distamycin analogues]. / Selektivnaya stabilizatsiya AT-bogatykh DNK-dupleksov kon''iugatami oligodezoksiribonuleotidov i analogov distamitsina.

Oligodeoxyribonucleotide conjugates with distamycin analogues containing up to five pyrrolecarboxamide moieties were synthesized. The stability of duplexes formed by these conjugates was shown to depend directly upon the number of pyrrolecarboxamide moieties in the ligand molecule. For the duplexes formed by octaadenylate and octathymidilate conjugates with the distamycin pentapyrrole analogue, stability was demonstrated to be achieved by either one or two ligand molecules; however, duplexes containing two ligand molecules are more stable.

Inhibition of tRNA aminoacylation by 2'-O-methyl oligonucleotides.

A 2'-O-methyl oligonucleotide complementary to 18 nucleotides in the dihydrouridine stemloop of Escherichia coli tRNA(Cys) has been shown to stably bind to the tRNA. The binding inhibits aminoacylation of the tRNA by cysteine tRNA synthetase. The same oligonucleotide sequence but with the DNA deoxy backbone does not bind to the tRNA. This provides the basis for the design and test of a series of 2'-O-methyl oligonucleotides for their ability to bind to E. coli tRNA(Cys) and inhibit aminoacylation. We show here that different regions of the tRNA have different sensitivities to oligonucleotides. A 10-mer that targets G15 forms a stable complex with the tRNA. The Kd of the complex is several orders of magnitude lower than that of the tRNA-synthetase complex. Measurements of dissociation rate constants indicate that the stronger affinity of the 10-mer to tRNA(Cys) is due to a significantly slower rate of dissociation (by a factor of 10(6)) than that of the synthetase from the tRNA. Only a stoichiometric amount of the 10-mer is necessary to completely inhibit aminoacylation. Because tRNA aminoacylation is fundamental to cell growth, these results provide the rationale for the 10-mer and its derivatives as pharmaceutical agents that target specific cell growth.

Oligonucleotides containing 2-aminoadenine and 2-thiothymine act as selectively binding complementary agents.

A pair of complementary oligodeoxynucleotides (ODNs) uniformly substituted with 2-amino-adenine (A') in place of adenine and 2-thiothymine (T') in place of thymine did not hybridize to each other but did form very stable hybrids with unmodified complementary ODNs. These unusual properties were a consequence of the hydrogen-bonding properties of the two base analogs. Thermal denaturation studies of short duplexes which contained these bases demonstrated that the A'-T and A-T' doublets formed stable base pairs whereas the A'-T' doublet acted like a mismatch. Complementary ODNs substituted with these base analogs are referred to as SBC or selectively binding complementary ODNs. When used as a pair, these single-stranded ODNs invaded the ends of homologous duplexes and formed stable three-arm junctions under conditions where unmodified ODNs failed to give a product. SBC ODNs have a fundamental thermodynamic advantage in hybridizing to short segments of double-stranded nucleic acid and represent a new approach for the design of oligomeric probes and antisense agents. Many secondary structure features present in long single-stranded nucleic acids should be accessible to these reagents.

G/C-modified oligodeoxynucleotides with selective complementarity: synthesis and hybridization properties.

Modified oligodeoxyribonucleotides (ODNs) that have unique hybridization properties were designed and synthesized for the first time. These ODNs, called selective binding complementary ODNs (SBC ODNs), are unable to form stable hybrids with each other, yet are able to form stable, sequence specific hybrids with complementary unmodified strands of nucleic acid. To make SBC ODNs, deoxyguanosine (dG) and deoxycytidine (dC) were substituted with deoxyinosine (dI) and 3-(2'-deoxy-beta-D-ribofuranosyl)pyrrolo-[2,3-d]-pyrimidine-2-(3H)-one (dP), respectively. The hybridization properties of several otherwise identical complementary ODNs containing one or both of these nucleoside analogs were studied by both UV monitored thermal denaturation and non-denaturing PAGE. The data showed that while dI and dP did form base pairs with dC and dG, respectively, dI did not form a stable base pair with dP. A self-complementary ODN uniformly substituted with dI and dP acquired single-stranded character and was able to strand invade the end of a duplex DNA better than an unsubstituted ODN. This observation implies that SBC ODNs should effectively hybridize to hairpins present in single-stranded DNA or RNA.