Functionalization of covalent DNA-streptavidin conjugates by means of biotinylated modulator components.

Covalent DNA-streptavidin conjugates are versatile biomolecular coupling reagents, since they have binding capacity for both a complementary nucleic acid and four molecules of biotin. The DNA-streptavidin hybrid molecules have been investigated for their capabilities to bind two different types of biotinylated components. Thus, (i) a functional biomolecule, e.g., a single-stranded DNA fragment or an enzyme and (ii) low-molecular weight biotin derivatives ("modulators") were coupled stepwise with the hybrid molecules. Modulators were D-biotin, aminobiotin, and biotin-fluorescein conjugate as well as a lysine-rich 10mer peptide, containing a biotin and a fluorescein substituent. These modulators were chosen to affected the hybridization properties of the DNA-streptavidin conjugates. As investigated by surface-plasmon resonance and microplate solid-phase hybridization measurements, D-biotin, biotin-fluorescein, and aminobiotin decreased the efficiency of hybridization with complementary, surface-bound oligonucleotides to a varying extent. The basic peptide increased the conjugate's hybridization efficiency. Moreover, it was demonstrated in two examples how modulators can be utilized as additional functional domains of streptavidin-based conjugates. First, fluorescein-containing modulators were used as hapten groups, allowing a sensitive detection by means of specific antibodies directed against the modulator. Second, the biotinylated peptide was used as a carrier molecule to attach multiple fluorogenic lanthanide-chelate groups to the streptavidin conjugate, enabling its sensitive detection by time-resolved fluorometry. The applicability of this kind of bioconjugation strategy to generate sensor-probes for gene detection assays was demonstrated.     

An oligodeoxynucleotide affinity column for the isolation of sequence specific DNA binding proteins.

A nucleic acid affinity matrix containing a short oligodeoxynucleotide ligand has been prepared as an example of a material which can be used for the rapid and effective isolation of sequence specific DNA binding proteins. Two complementary oligodeoxynucleotides have been employed, one of which contains a small 5'-spacer arm with a terminal thiol group. Using this terminal thiol group, the ligand can be covalently coupled to Tresyl-activated Sepharose 4B or Epoxy-activated Sepharose 6B via a thioether linkage. This approach allows the specific attachment of the nucleic acid ligand via its 5'-terminus to the insoluble matrix. The double stranded affinity material was obtained by annealing of the complementary DNA fragment. As an example, we have used an eicosomer affinity column containing the sequence d(GAATTC) for the isolation of the Eco RI restriction endonuclease. Using a single column, the enzyme could be isolated by eluting the column with a single step or multistep gradient of increasing salt concentration. The enzyme was purified to 75%-85% homogeneity with yields of 0.1 mg to 0.2 mg from 0.5 g of cell paste.     

Electron microscopy mapping of oligopurine tracts in duplex DNA by peptide nucleic acid targeting.

Biotinylated homopyrimidine decamer peptide nucleic acids (PNAs) are shown to form sequence-specific and stable complexes with complementary oligopurine targets in linear double-stranded DNA. The noncovalent complexes are visualized by electron microscopy (EM) without chemical fixation using streptavidin as an EM marker. The triplex stoichiometry of the PNA-DNA complexes (two PNA molecules presumably binding by Watson-Crick and Hoogsteen pairing with one of the strands of the duplex DNA) is indicated by the appearance of two streptavidin 'beads' per target site in some micrographs, and is also supported by the formation of two retardation bands in a gel shift assay. Quantitative analysis of the positions of the streptavidin 'beads' revealed that under optimized conditions PNA-DNA complexes are preferably formed with the fully complementary target. An increase in either the PNA concentration or the incubation time leads to binding at sites containing one or two mismatches. Our results demonstrate that biotinylated PNAs can be used for EM mapping of short targets in duplex DNA.     

DNA chip replication for a personalized DNA chip

We report the replication technology of DNA chip using by sequence specific localization of nucleic acids via hybridization and electric transfer of the nucleic acids onto a new substrate without losing their array information. The denatured DNA fragments are first spotted and UV-cross-linked on a nylon membrane. The membrane is then immersed and hybridized in a DNA mixture solution that contains all complementary sequences of the nucleic acids to be hybridized with the DNA fragments on the membrane. The hybridized DNA fragments are transferred to another membrane at the denatured condition. After separating two membranes, the transferred membrane contains a complementary array of DNA fragments. This method can be used for the replication of the same copy of DNA chip repeatedly and moreover could be applied for a personalized DNA chip fabrication, where specific information of each spot of DNA chip is originated from the genetic information of a personal sample.     

A molecular beacon, bead-based assay for the detection of nucleic acids by flow cytometry

Molecular beacons are dual-labelled probes that are typically used in real-time PCR assays, but have also been conjugated with solid matrices for use in microarrays or biosensors. We have developed a fluid array system using microsphere-conjugated molecular beacons and the flow cytometer for the specific, multiplexed detection of unlabelled nucleic acids in solution. For this array system, molecular beacons were conjugated with microspheres using a biotin-streptavidin linkage. A bridged conjugation method using streptavidin increased the signal-to-noise ratio, allowing for further discrimination of target quantitation. Using beads of different sizes and molecular beacons in two fluorophore colours, synthetic nucleic acid control sequences were specifically detected for three respiratory pathogens, including the SARS coronavirus in proof-of-concept experiments. Considering that routine flow cytometers are able to detect up to four fluorescent channels, this novel assay may allow for the specific multiplex detection of a nucleic acid panel in a single tube.     

Allosteric aptamers: targeted reversibly attenuated probes

Aptamers are unique nucleic acids with regulatory potentials that differ markedly from those of proteins. A significant feature of aptamers not possessed by proteins is their ability to participate in at least two different types of three-dimensional structure: a single-stranded folded structure that makes multiple contacts with the aptamer target and a double-helical structure with a complementary nucleic acid sequence. We have made use of this structural flexibility to develop an aptamer-based biosensor (a targeted reversibly attenuated probe, TRAP) in which hybridization of a cis-complementary regulatory nucleic acid (attenuator) controls the ability of the aptamer to bind to its target molecule. The central portion of the TRAP, between the aptamer and the attenuator, is complementary to a target nucleic acid, such as an mRNA, which is referred to as a regulatory nucleic acid (regNA) because it regulates the activity of the aptamer in the TRAP by hybridization with the central (intervening) sequence. The studies reported here of the ATP-DNA TRAP suggest that, as well as inhibiting the aptamer, the attenuator also acts as a structural guide, much like a chaperone, to promote proper folding of the TRAP such that it can be fully activated by the regDNA. We also show that activation of the aptamer in the TRAP by the complementary nucleic acid at physiological temperatures is sensitive to single-base mismatches. Aptamers that can be regulated by a specific nucleic sequence such as in an mRNA have potential for many in vivo applications including regulating a particular enzyme or signal transduction pathway or imaging gene expression in vivo.     

Thermoprecipitation of streptavidin via oligonucleotide-mediated self-assembly with poly(N-isopropylacrylamide).

A versatile strategy has been developed for selectively and sequentially isolating targets in a liquid-phase affinity separation environment. The strategy uses a recently developed approach for joining together molecules in linkages that are defined by the complementary pairing of oligonucleotides conjugated to the different molecules [Niemeyer, C. M., Sano, T., Smith, C. L., and Cantor, C. R. (1994) Nucleic Acids Res. 22, 5530-9]. In the work presented here, streptavidin was noncovalently coupled with the temperature-responsive poly(N-isopropylacrylamide) [poly(NIPAAM)] through the sequence-specific hybridization of oligonucleotides conjugated to the protein and polymer. A 20-mer oligonucleotide was covalently linked through a heterobifunctional linker to a genetically engineered streptavidin variant that contained a unique cysteine residue at the solvent-accessible site Glu 116. The complementary DNA sequence was conjugated to the end of a linear ester-activated poly(NIPAAM). The two conjugates were allowed to self-assemble in solution via hybridization of their complementary DNA sequences. The streptavidin-poly(NIPAAM) complex could be used to affinity-precipitate radiolabeled biotin or biotinylated alkaline phosphatase above 32 degrees C through the thermally induced phase separation activity of the poly(NIPAAM). The streptavidin-oligo species could then be reversibly separated from the precipitated polymer-oligo conjugate and recycled by lowering the salt concentration, which results in denaturation of the short double-stranded DNA connection. The use of oligonucleotides to couple polymer to streptavidin allows for selective precipitation of different polymers and streptavidin complexes based on the sequence-specific hybridization of their oligonucleotide appendages.     

The design of single-stranded nucleic acid knots

A general strategy is described for the synthesis of single-stranded nucleic acid knots. Control of nucleic acid sequence is used to direct the formation of secondary structures that produce the target topology. The key feature of the strategy is the equation of a half-turn of double helical DNA or RNA with a node in a knot. By forming nodes from complementary DNA sequences, it appears possible to direct the assembly of any simple knot. Stabilization of individual nodes may be achieved by constructing them from long regions containing both B-DNA and Z-DNA. Control over the braiding of DNA that acts as a link between node-forming domains can be realized by condensing the nodes into well-defined DNA structures, such as extended domains of linear duplex, branched junctions, antijunctions or mesojunctions. Further topological control may be derived from the pairing of linker regions to complementary single-stranded molecules, thereby preventing them from braiding in an undesirable fashion.     

End-joining long nucleic acid polymers

Many experiments involving nucleic acids require the hybridization and ligation of multiple DNA or RNA molecules to form a compound molecule. When one of the constituents is single stranded, however, the efficiency of ligation can be very low and requires significant individually tailored optimization. Also, when the molecules involved are very long (>10 kb), the reaction efficiency typically reduces dramatically. Here, we present a simple procedure to efficiently and specifically end-join two different nucleic acids using the well-known biotin–streptavidin linkage. We introduce a two-step approach, in which we initially bind only one molecule to streptavidin (STV). The second molecule is added only after complete removal of the unbound STV. This primarily forms heterodimers and nearly completely suppresses formation of unwanted homodimers. We demonstrate that the joining efficiency is 50 ± 25% and is insensitive to molecule length (up to at least 20 kb). Furthermore, our method eliminates the requirement for specific complementary overhangs and can therefore be applied to both DNA and RNA. Demonstrated examples of the method include the efficient end-joining of DNA to single-stranded and double-stranded RNA, and the joining of two double-stranded RNA molecules. End-joining of long nucleic acids using this procedure may find applications in bionanotechnology and in single-molecule experiments.     

The characterization of a mutant affecting DNA metabolism in the development of D. melanogaster

Using a "single-fly" nucleic acid hybridization method, we have surveyed a collection of D. melanogaster strains in search of variants which affect DNA complementary to the polypyrimidine sequence corresponding to one strand of the 1.705 satellite. Hybridization of labelled polypyrimidine probe to polypurine sequence in nucleic acid extracts of single flies, followed by thermal chromatography over hydroxyapatite led to the identification of one variant. The strain Cy/M(2)S2(10) produced excess hybrid, much of which had low thermal stability. A developmental analysis of the low-melt hybrid phenotype showed that certain tissues, in particular the ovaries, were affected. In addition to the biochemical phenotype, the break down of nurse cell nuclei in Cy/M(2)S2(10) ovaries during oocyte maturation was abnormal. A genetic analysis demonstrated that both the biochemical and cytological phenotypes were the consequences of a single recessive mutation in the DNase-1 gene on chromosome III. Studies with purified DNA demonstrated that the low-melt hybrid phenotype resulted from the accumulation of low molecular weight DNA complementary to the polypyrimidine probe.     

Supramolecular DNA-streptavidin nanocircles with a covalently attached oligonucleotide moiety

Covalent hybrid conjugates consisting of streptavidin (STV) and a 24-mer single-stranded DNA oligonucleotide have been used as a starting material for the synthesis of supramolecular nanocircles. For this, the covalent hybrid conjugates were oligomerized by cross-linking with 5 ,5 -bis-biotinylated double-stranded DNA (dsDNA) fragments of various length. Heat denaturation of the resulting oligomeric conjugates and subsequent rapid cooling led to the formation of the nanocircles, in which the oligonucleotide-containing STV molecule is coupled with both ends of the circular bis-biotinylated dsDNA fragment. The circular structure of the bioconjugates was established by electrophoretic studies including Ferguson plot analysis as well as by scanning force microscopy (SFM) inspection. The formation process and the stability against degradation by ligand exchange with free D-biotin was compared for the nanocircles obtained from covalent oligonucleotide-STV hybrids and native STV. The former nanocircles revealed a decreased stability with respect to ring opening than the circles obtained from native STV. This suggested that the affinity of the covalent oligonucleotide-STV hybrid for binding biotinylated DNA is significantly decreased. Nevertheless, the single-stranded oligonucleotide moiety of the hybrid nanocircles can be used as a molecular handle for further functionalization. For instance, it was used for the selective DNA-directed immobilization at a surface, previously functionalized with complementary capture oligonucleotides. Moreover, we demonstrate that a pair of nanocircles, containing complementary oligonucleotide moieties, can be hybridized to form specific dimers, thereby generating a novel type of supramolecular DNA-protein nanostructures.     

Molecular Cloning of DNA Complementary to the RNA-Genome of Plum Pox Virus (PPV)

Genomic RNA of plum pox virus (PPV) was used as a template for the synthesis of complementary DNA (cDNA). The generated cDNA molecules were subsequently cloned into pBR 322. A physical map covering 9700 bases of the PPV genome was constructed from 8, clones by hybridization and restriction endonuclease digestion. Clone pPPV-NAT 309, starting at the 3′-end, with an 866 bp insert was used in Northern- and Dot-hybridizations for the detection of single-stranded viral RNA in total nucleic acid as well as in sap preparations of PPV infected Nicotiana clevelandii. The nucleotide sequence of this clone was determined, the amino acid sequence of the coat protein C-terminal part was deduced and compared with four other coat proteins of potyviruses.     

Protein displacement by an assembly of helicase molecules aligned along single-stranded DNA

Helicases are molecular motors that unwind double-stranded DNA or RNA. In addition to unwinding nucleic acids, an important function of these enzymes seems to be the disruption of protein-nucleic acid interactions. Bacteriophage T4 Dda helicase can displace proteins bound to DNA, including streptavidin bound to biotinylated oligonucleotides. We investigated the mechanism of streptavidin displacement by varying the length of the oligonucleotide substrate. We found that a monomeric form of Dda catalyzed streptavidin displacement; however, the activity increased when multiple helicase molecules bound to the biotinylated oligonucleotide. The activity does not result from cooperative binding of Dda to the oligonucleotide. Rather, the increase in activity is a consequence of the directional bias in translocation of individual helicase monomers. Such a bias leads to protein-protein interactions when the lead monomer stalls owing to the presence of the streptavidin block.     

Nucleic acid evolution and minimization by nonhomologous random recombination

We have developed a simple method for exploring nucleic acid sequence space by nonhomologous random recombination (NRR) that enables DNA fragments to randomly recombine in a length-controlled manner without the need for sequence homology. We compared the results of using NRR and error-prone PCR to evolve DNA aptamers that bind streptavidin. Starting with two parental sequences of modest avidin affinity, evolution using NRR resulted in aptamers with 15- to 20-fold higher affinity than the highest-affinity aptamers evolved using error-prone PCR, and 27- or 46-fold higher affinities than parental sequences derived using systematic evolution of ligands by exponential enrichment (SELEX). NRR also facilitates the identification of functional regions within evolved sequences. Inspection of a small number of NRR-evolved clones identified a 40-base DNA sequence, present in multiple copies in each clone, that binds streptavidin. Our findings suggest that NRR may enhance the effectiveness of nucleic acid evolution and the ease of identifying structure-activity relationships among evolved sequences.     

SSO1450 - A CAS1 protein from Sulfolobus solfataricus P2 with high affinity for RNA and DNA

Clustered regularly interspaced short palindromic repeats (CRISPR) and their associated protein genes (cas genes) are ubiquitous in archaea and eubacteria. It has been suggested that CRISPR and CAS proteins act as an immune system preventing the invasion of foreign genomic elements at the DNA level. The protein SSO1450 from Sulfolobus solfataricus (Sso) P2 belongs to the CAS1 cluster which is one of the core protein clusters most frequently associated with CRISPR sequences. In this study we show that SSO1450 is a high-affinity nucleic acid binding protein. It binds DNA, RNA and DNA-RNA hybrid apparently sequence non-specific in a multi-site binding mode. Furthermore, SSO1450 promotes the hybridization of complementary nucleic acid strands.     

The hepatitis C virus Core protein is a potent nucleic acid chaperone that directs dimerization of the viral (+) strand RNA in vitro

The hepatitis C virus (HCV) is an important human pathogen causing chronic hepatitis, liver cirrhosis and hepatocellular carcinoma. HCV is an enveloped virus with a positive-sense, single-stranded RNA genome encoding a single polyprotein that is processed to generate viral proteins. Several hundred molecules of the structural Core protein are thought to coat the genome in the viral particle, as do nucleocapsid (NC) protein molecules in Retroviruses, another class of enveloped viruses containing a positive-sense RNA genome. Retroviral NC proteins also possess nucleic acid chaperone properties that play critical roles in the structural remodelling of the genome during retrovirus replication. This analogy between HCV Core and retroviral NC proteins prompted us to investigate the putative nucleic acid chaperoning properties of the HCV Core protein. Here we report that Core protein chaperones the annealing of complementary DNA and RNA sequences and the formation of the most stable duplex by strand exchange. These results show that the HCV Core is a nucleic acid chaperone similar to retroviral NC proteins. We also find that the Core protein directs dimerization of HCV (+) RNA 3' untranslated region which is promoted by a conserved palindromic sequence possibly involved at several stages of virus replication.