A new hybridocytochemical method based on mercurated nucleic acid probes and sulfhydryl-hapten ligands. II. Effects of variations in ligand structure on the in situ detection of mercurated probes

In the preceding paper, a method to detect specific DNA sequences with mercurated nucleic acid probes and sulfhydryl-hapten ligands has been described. Due to the instability of the bond between mercury and a negatively charged sulfhydryl-hapten ligand (trinitrophenyl-glutathione), the in situ formed hybrid could not be detected. On basis of model system experiments it was suggested that this mercury-sulfhydryl bond could be stabilized by an extra polar interaction between ligand and nucleic acid. This was achieved by reversing the net charge of the ligand. Such ligands were synthesized by reacting aliphatic diamines to the carboxyl groups of Tnp-glutathione using a water soluble carbodiimide. Gel chromatographic analysis of mercurated polynucleotide-ligand complexes showed that the stability of the mercury-sulfhydryl bond is increased by the reversal of the net charge of the ligand. In situ hybridized mercurated mouse satellite DNA to mouse liver nuclei and mercurated kinetoplast cRNA hybridized to Crithidia fasciculata were immunocytochemically detected after the introduction of these positively charged ligands. The described method is applicable for RNA and DNA probes. It has a sensitivity comparable to other non-autoradiographic methods, is relatively simple to perform and can be carried out with ordinary laboratory chemicals.     

A new hybridocytochemical method based on mercurated nucleic acid probes and sulfhydryl-hapten ligands. I. Stability of the mercury-sulfhydryl bond and influence of the ligand structure on immunochemical detection of the hapten

The mechanisms underlying a new hybridocytochemical method, which is based on mercurated nucleic acid probes and their binding to sulfhydryl-hapten ligands, have been studied. Furthermore we developed a simple procedure for the preparation of mercurated probes at a microgram scale. Nucleic acids immobilized on Sephadex beads have been immunochemically detected after hybridization with mercurated probes and binding of the sulfhydryl-hapten ligand trinitrophenyl-glutathione. In this system, the method proved to be specific and sensitive. However, the same procedure, when applied in situ, failed to give a positive result. ELISA experiments showed that these results cannot be attributed to a suboptimal immunochemical detection of the ligand. Chromatographic analysis of mercurated polynucleotide-ligand complexes revealed, however, an unexpected lability of the mercury-sulfhydryl bond. Under non-equilibrium conditions, as present during a cytochemical washing procedure, the mercury-sulfhydryl b ond was found to dissociate rapidly. On basis of these results the hypothesis was forwarded that the bond between mercurated nucleic acids immobilized on Sephadex and the ligand was stabilized by the positive charge of the Sephadex matrix. This charge was introduced during the cyanogen bromide activation and inactivation necessary for the covalent coupling of nucleic acids to Sephadex. In situ, however, no such positive charges are present. By reversing the charge of the ligand we expected to stabilize the mercury-sulfhydryl bond. In a subsequent paper data are presented that confirm this hypothesis.     

A non-radioactive in situ hybridization method based on mercurated nucleic acid probes and sulfhydryl-hapten ligands.

Mercurated nucleic acid probes can be used for non-radioactive in situ hybridization. The principle of the method is based on the reaction of the mercurated pyrimidine residues of the in situ hybridized probe with the sulfhydryl group of a ligand which contains a hapten. Next, the hapten is immunocytochemically detected. Previous experiments showed that stable coupling of the sulfhydryl ligands could only be obtained when positively charged amino groups are present in the ligand. On basis of this finding, ligands were synthesized containing a sulfhydryl group, two lysyl residues and hapten groups such as trinitrophenyl, fluorescyl and biotinyl. The ligands, free or bound to mercurated nucleic acids, were immunochemically characterized in ELISAs. The method was shown to be specific and sensitive in the detection of target DNA in situ on microscopic preparations and in dot-blot hybridization reactions on nitrocellulose.     

Mercurated nucleic acid probes, a new principle for non-radioactive in situ hybridization

This report describes the localization of specific nucleic acid sequences in interphase nuclei and metaphase chromosomes by a new hybridocytochemical method based on the use of mercurated nucleic acid probes. After the hybridization a sulfhydryl-hapten compound is reacted with the hybrids formed. A number of such ligands were synthesized and tested. A fluorescyl ligand could be used for the direct visualization of highly repetitive sequences. For indirect immunocytochemical visualization trinitrophenyl ligands were found to be more sensitive than biotinyl analogues. These ligands were applied for the detection of target sequences in metaphase chromosomes and interphase nuclei of somatic cell hybrids, human lymphoid cell lines and blood cell cultures. The sequences were in the range of high to low copy numbers. The lower limit of sensitivity is indicated by the visualization of two human unique DNA fragments (40 and 15.6 kb) in human metaphases. The method is rapid, gives consistent results and can be used for both RNA and DNA probes. Other potentials of the new principle are discussed.     

Bi-color detection of two target DNAs by non-radioactive in situ hybridization

Summary A non-radioactive in situ hybridization technique is described which allows the simultaneous detection of different DNA sequences. To demonstrate the feasibility of the proccdure, metaphases and interphase nuclei of a human-mouse somatic cell hybrid were simultaneously hybridized with mercurated total human DNA and a biotinylated mouse satellite DNA probe. After the hybridization, the probes were detected immunocytochemically using two different and independent affinity systems. By this approach we visualized the two DNA target sequences in metaphase chromosomes and in interphase nuclei with FITC and TRITC fluorescence, or blue (alkaline phosphatase) and brown (peroxidase) precipitated enzyme products. This method not only allows detection of intact chromosomes but also the visualization of rearrangements between parts of human and mouse chromosomes. Furthermore, the technique demonstrates the high topological resolution of nonradioactive in situ hybridizations.This investigation was supported in part by FUNGO, Foundation of Medical Scientific Research in The Netherlands (grant nr 13-54-21)     

How are hydrogen bonds modified by metal binding?

We have used density functional theory calculations to investigate how the hydrogen-bond strength is modified when a ligand is bound to a metal using over 60 model systems involving six metals and eight ligands frequently encountered in metalloproteins. We study how the hydrogen-bond geometry and energy vary with the nature of metal, the oxidation state, the coordination number, the ligand involved in the hydrogen bond, other first-sphere ligands, and different hydrogen-bond probe molecules. The results show that, in general, the hydrogen-bond strength is increased for neutral ligands and decreased for negatively charged ligands. The size of the effect is mainly determined by the net charge of the metal complex, and all effects are typically decreased when the model is solvated. In water solution, the hydrogen-bond strength can increase by up to 37 kJ/mol for neutral ligands, and that of negatively charged ligands can increase (for complexes with a negative net charge) or decrease (for positively charged complexes). If the net charge of the complex does not change, there is normally little difference between different metals or different types of complexes. The only exception is observed for sulphur-containing ligands (Met and Cys) and if the ligand is redox-active (e.g. high-valence Fe–O complexes).     

Isolation of Rhizobium loti Strain-Specific DNA Sequences by Subtraction Hybridization

Mixed-phase (heterogeneous) and single-phase (homogeneous) DNA subtraction-hybridization methods were used to isolate specific DNA probes for closely related Rhizobium loti strains. In the heterogeneous method, DNA from the prospective probe strain was repeatedly hybridized to a mixture of DNA from cross-hybridizing strains (subtracter DNA) which was immobilized on an epoxy-activated cellulose matrix. Probe strain sequences which shared homology with the matrix-bound subtracter DNA hybridized to it, leaving unique probe strain sequences in the mobile phase. In the homogeneous method, probe strain sequences were hybridized in solution to biotinylated, mercurated subtracter DNA. Biotinylated, mercurated subtracer DNA and probe strain sequences hybridized to it were removed by two-step affinity chromatography on streptavidin-agarose and thiol-Sepharose. The specificity of the sequences remaining after subtraction hybridization by both methods was assessed and compared by colony hybridization with R. loti strains. Both methods allowed the rapid isolation of strain-specific DNA fragments which were suitable for use as probes.     

In situ hybridization with fluoresceinated DNA.

We have used fluorescein-11-dUTP in a nick-translation format to produce fluoresceinated human nucleic acid probes. After in situ hybridization of fluoresceinated DNAs to human metaphase chromosomes, the detection sensitivity was found to be 50-100 kb. The feasibility and the increase in detection sensitivity of microscopic imaging of in situ hybridized, fluoresceinated DNA with an integrating solid state camera for rapid cosmid mapping is illustrated. Combination of fluoresceinated DNA with biotinated and digoxigeninated DNAs allowed easy performance of triple fluorescence in situ hybridization. The potential of these techniques for DNA mapping, cytogenetics and biological dosimetry is briefly discussed.     

Zn2+ dependent DNA binders based on terminally modified peptide nucleic acids

Two ligand-intercalator-peptide nucleic acid conjugates (L-NADI-PNAs) have been synthesized. Affinity of these conjugates to their complementary DNAs was found to be affected by Zn(2+). The magnitude of this effect could be controlled by a variation of the ligand. Upon binding Zn(2+) the L-NADI-PNAs form positively charged ZnL complexes, which interact with the negatively charged DNA backbone. This electrostatic interaction stabilizes PNA/DNA duplexes. It has been found that Zn(2+) dependent stabilization takes place only if the ZnL complex has a higher total positive charge than the ligand. Linear correlation has been observed between Zn(2+) induced stabilization of PNA/DNA duplexes and difference of charges of the ZnL complex and the ligand.     

Snap-to-it probes: chelate-constrained nucleobase oligomers with enhanced binding specificity

We describe snap-to-it probes, a novel probe technology to enhance the hybridization specificity of natural and unnatural nucleic acid oligomers using a simple and readily introduced structural motif. Snap-to-it probes were prepared from peptide nucleic acid (PNA) oligomers by modifying each terminus with a coordinating ligand. The two coordinating ligands constrain the probe into a macrocyclic configuration through formation of an intramolecular chelate with a divalent transition metal ion. On hybridization with a DNA target, the intramolecular chelate in the snap-to-it probe dissociates, resulting in the probe ‘snapping-to’ and binding the target nucleic acid. Thermal transition analysis of snap-to-it probes with complementary and single-mismatch DNA targets revealed that the transition between free and target-bound probe conformations was a reversible equilibrium, and the intramolecular chelate provided a thermodynamic barrier to target binding that resulted in a significant increase in mismatch discrimination. A 4–6°C increase in specificity (ΔT_m) was observed from snap-to-it probes bearing either terminal iminodiacetic acid ligands coordinated with Ni²⁺, or terminal dihistidine and nitrilotriacetic acid ligands coordinated with Cu²⁺. The difference in specificity of the PNA oligomer relative to DNA was more than doubled in snap-to-it probes. Snap-to-it probes labeled with a fluorophore-quencher pair exhibited target-dependent fluorescence enhancement upon binding with target DNA.     

Single base discrimination of CENP-B repeats on mouse and human Chromosomes with PNA-FISH

The satellite repeat structure of the mammalian centromere contains the CENP-B protein binding site. Using the peptide nucleic acid-fluorescence in situ hybridization (PNA-FISH), we show by direct PNA-DNA binding that all detectable CENP-B sites in a mammalian genome might have the same sequence. Two species-specific PNA 17-mers, pMm and pMc, were identified from CENP-B binding sites of Mus musculus and M. caroli, respectively. Fluorescence in situ hybridization confirmed that pMc hybridized to M. caroli centromeres only; however, pMm cross-hybridized to M. musculus and human centromeres. By using a series of CENP-B PNA 17-mers containing 1, 2, 3, 5, and 7 base-pair mismatches to their DNA counterparts, we further demonstrate that PNA-FISH can discriminate between two CENP-B DNA sequences that differ by a single base-pair in mouse and human centromeres, suggesting the degree of conservation of CENP-B sequences throughout the genome. In comparison with DNA oligonucleotides, PNA oligomers demonstrate the higher sequence specificity, improved stability, reproducibility, and lower background. Therefore, PNA oligomers have significant advantages over DNA oligonucleotide probes in analyzing microsatellites in a genome. Received: 16 June 1998 / Accepted: 3 September 1998     

The murine homolog of the human breast and ovarian cancer susceptibility geneBrca1 maps to mouse chromosome 11D

The recently cloned human breast and ovarian cancer suseptibility gene,BRCA1, is located on human chromosome 17q21. We have isolated murine genomic clones containingBrca1 as a first step in generating a mouse model for the loss ofBRCA1 function. A mouse genomic library was screened using probes corresponding to exon 11 of the humanBRCA1 gene. Two overlapping mouse clones were identified that hybridized to humanBRCA1 exons 9–12. Sequence analysis of 1.4 kb of the region of these clones corresponding to part of human exon 11 revealed 72% nucleic acid identity but only 50% amino acid identity with the human gene. The longest of the mouseBrca1 genomic clones maps to chromosome 11D, as determined by two-color fluorescence in situ hybridization. The synteny to human chromosome 17 was confirmed by cohybridization with the mouse probe for the NF1-gene. This comparative study confirms that the relative location of theBRCA1 gene has been conserved between mice and humans.     

DNA complexing with polyamidoamine dendrimers: implications for transfection.

DNA and polyamidamine (PAMAM) dendrimers form complexes on the basis of the electrostatic interactions between negatively charged phosphate groups of the nucleic acid and protonated (positively charged) amino groups of the polymers. Charge neutralization of both components and subsequent increases of the net positive charge of the complex result in changes in the physicochemistry and biological properties of the complexes. The formation of soluble, low-density and insoluble, high-density complexes was analyzed using UV light absorption and measurements of radioactive labeled DNA. Formation of high molecular weight and high-density complexes depended mainly on the DNA concentration and was enhanced by increasing the dendrimer-DNA charge ratio. Electrostatic charge related effects (attraction or repulsion of charged particles) appeared to be modulated by the generation of dendrimer (size of the polymer). With the progressive increases in the dendrimer-DNA charge ratio (above 20), an increase in the amount of low-density, soluble complexes was observed. Functional analysis revealed that the great majority (>90%) of transfection is carried by low-density, soluble, complexes which only represent approximately 10-20% of total complexed DNA. The ability of the dendrimer to complex and form aggregates with DNA is crucial for efficient transfection and the function of the complexed DNA.     

In Situ Hybridization of Cytospin Preparations: A Rapid Nonisotopic Screening Method for Isolated Cells

A simple and rapid method for light microscopic in situ hybridization on cytospin preparations is described and demonstrated for detection of viral nucleic acid in a virus-infected cell line. Cells were fixed by acetone followed by chloroform, denatured by heat, hybridized at 37 C, and hybridized sites detected with a multiple step procedure (primary anti-biotin antibody, biotinylated second antibody, streptavidin-peroxidase). This method can be used for screening studies at the light microscope level, and offers a useful and simple way to determine optimum hybridization conditions for subsequent electron microscopic investigations.     

Probing the energetic and structural role of amino acid/nucleobase cation-pi interactions in protein-ligand complexes

X-ray structures of proteins bound to ligand molecules containing a nucleic acid base were systematically searched for cation-pi interactions between the base and a positively charged or partially charged side chain group located above it, using geometric criteria. Such interactions were found in 38% of the complexes and are thus even more frequent than pi-pi stacking interactions. They are moreover well conserved in families of related proteins. The overwhelming majority of cation-pi contacts involve Ade bases, as these constitute by far the most frequent ligand building block; Arg-Ade is the most frequent cation-pi pair. Ab initio energy calculations at MP2 level were performed on all recorded pairs. Though cation-pi interactions involving the net positive charge carried by Arg or Lys side chains are the most favorable energetically, those involving the partial positive charge of Asn and Gln side chain amino groups (sometimes referred to as amino-pi interactions) are favorable too, owing to the electron correlation energy contribution. Chains of cation-pi interactions with a nucleobase bound simultaneously to two charged groups or a charged group sandwiched between two aromatic moieties are found in several complexes. The systematic association of these motifs with specific ligand molecules in unrelated protein sequences raises the question of their role in protein-ligand structure, stability, and recognition.     

Detection of a 17 kb unique sequence (T-DNA) in plant chromosomes by in situ hybridization

An approach is described for the detection of a unique sequence, the T-DNA region of the Agrobacterium rhizogenes root-inducing (Ri) plasmid, in plant chromosomes by in situ hybridization. This sequence was introduced into the Crepis capillaris genome (2n=6) by infecting Crepis stem segments with A. rhizogenes. Roots growing from the infection site contain T-DNA and synthesize mannopine, which can be used as a convenient biochemical marker for T-DNA transformation. Southern analysis of DNA isolated from one transformed Crepis root line verified the presence of a single copy of T-DNA (approximate size 17 kb) per diploid Crepis genome. To localize T-DNA, both DNA and RNA probes, labelled with either tritium or biotin, were hybridized to Crepis chromosomes prepared from transformed root tips by a novel spreading method. Biotinylated probes were visualized using reflection-contrast microscopy. In the hybridization experiments described, T-DNA was detected in one homologue of chromosome 3, where it could be assigned to a paracentromeric position in the neighbourhood of the nucleolar organizing region. These results demonstrate that it is possible to localize unique sequences in plant chromosomes by in situ hybridization.     

Use of bioluminescence in nucleic acid hybridization reactions

Luminescence reactions can be used to detect specific nucleic acid sequences hybridized with a nucleic probe. Different labels such as cytidine sulphone, fluorescein, and biotin can be incorporated into DNA or oligonucleotide molecules and detected by antibody or avidin conjugates coupled to glucose-6P dehydrogenase. On supports such as nitrocellulose filters, sensitivity is not greatly increased using luminescence, but detection is rapid and easy to perform using polaroid film. Moreover, hybridization can be performed with different labelled probes on the same sample. In solution, luminescence can be used to monitor sandwich reactions. The method is less sensitive than detection on filters but can easily be automated. The performance of these assays can be increased considerably by enzymatic amplification of the target catalysed by a thermostable polymerase.