Chemistry: molecular biology and microbiology – Measuring or testing process involving enzymes or... – Involving nucleic acid
Reexamination Certificate
1998-05-22
2001-07-03
Myers, Carla J. (Department: 1656)
Chemistry: molecular biology and microbiology
Measuring or testing process involving enzymes or...
Involving nucleic acid
C435S006120, C435S287100, C435S091100, C536S024300, C204S450000, C204S456000, C216S039000, C424S256100, C424S282100, C424S193100, C424S192100, C424S185100, C423S324000
Reexamination Certificate
active
06255050
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to nucleic acid hybridization and detection, and more particularly to methods and means for hybridizing complementary nucleic acid molecules at an accelerated rate.
BACKGROUND OF THE INVENTION
The use of nucleic acid probes to detect particular target nucleic acid sequences in samples containing at least one nucleic acid is of vast utility to research, medicine and forensics. Because nucleic acid probes are highly specific for their target sequences, they can be used as diagnostic reagents to detect the presence of a particular nucleic acid, as well as features within that nucleic acid. Commercial nucleic acid probe assays are being developed for the detection of infectious microorganisms, viruses, mutations in the human genome, as well as for fingerprinting human and other species' genomes. Research applications of nucleic acid probes are many, having been extensively utilized in recombinant DNA work for over 10 years.
Nucleic acid probe hybridization involves the detection of a target nucleic acid (e.g., RNA or DNA), either bound to a solid support or free in solution, using a labeled complementary probe nucleic acid or analog thereof (e.g., peptide nucleic acids (PNAs), methylene methyl amino oligonucleotides, and other polymers having Watson-Crick bases). Nucleic acid probe assays fall into two general categories, i.e., free-solution (or homogeneous) assays and solid support (or heterogeneous) assays.
In homogeneous assays, the target and probe nucleic acids are dissolved in solution. Target nucleic acid is first extracted from the sample, typically denatured to convert it to single-stranded form, and dissolved in hybridization buffer. Extraction of target nucleic acid from the sample and denaturation thereof can be accomplished by the procedure disclosed by Maniatis et al. in “Molecular Cloning: A Laboratory Manual”, Cold Spring Harbor Laboratory (1982), pages 191 to 198. A labeled probe complementary to the target nucleic acid is added to this solution and allowed to hybridize with the target sequence. When the hybridization reaction is complete, a suspension of hydroxyapatite (calcium hydroxide) is added. The hydroxyapatite selectively binds double-stranded probe/target nucleic acid duplexes as well as other double-stranded molecules, but does not bind unannealed single-stranded molecules. The insoluble hydroxyapatite with probe/target sequence duplex bound thereto is separated from the hybridization medium by centrifugation and washed to remove traces of unreacted probe molecules. If the probe has an isotopic label, the amount of probe bound to the hydroxyapatite is quantitated by scintillation counting. Other conventional means can be used to detect and quantitate nonisotopically labeled probe bound to the hydroxyapatite.
Heterogeneous assays can be performed in many ways. A particularly common method comprises binding a single-stranded target nucleic acid to a nitrocellulose or nylon filter in an irreversible manner. This can be accomplished by applying the target nucleic acid to the filter, and then baking them at temperatures of 70° C. to 80° C. for about one to about two hours under reduced pressure, i.e., at a pressure of less than 1 psi. The filter with sample nucleic acid bound thereto is subsequently prehybridized by immersion in an aqueous solution containing salts, protein, nonreactive DNA or RNA, sodium dodecyl sulfate detergent, buffer, EDTA, and formamide to block nonspecific binding sites on its surface. See, e.g., Grunstein et al, “Colony Hybridization: A Method for the Isolation of Cloned DNAs that Contain a Specific Gene,” Proc. Nat'l Acad. Sci., 72(10):3961-3965, 1975.
When the prehybridization step is complete, labeled probe is dissolved in an aqueous solvent and is added to the solution containing the prehybridized filter to which the sample nucleic acid is bound. The probe is allowed to hybridize with the filter-bound sample nucleic acid until formation of sample/probe duplexes has gone to completion. The filter is then removed from the hybridization solution and washed with a buffered salt solution at a controlled temperature to remove nonspecifically bound labeled probe sequences. After the washing step, only labeled probe molecules which are specifically annealed to matching sample target sequences remain on the filter. The washed filter can be autoradiographed, or other appropriate conventional means can be used to detect the label and determine the amount and location of the bound probe, and thereby the location of the complementary sample sequences originally applied. See, e.g., Meinkoth et al., “Hybridization of Nucleic Acids Immobilized on Solid Supports,” Analytical Biochemistry, 138:267, 1984; and Thomas, “Hybridization of Denatured RNA and Small DNA Fragments Transferred to Nitrocellulose,” Proc. Nat'l Acad. Sci., 77(9):5201-5205, 1980.
All nucleic acid probe assays require a step in which a labeled probe nucleic acid is hybridized to a target nucleic acid sequence. The time required for such hybridization is often a critically limiting factor in nucleic acid probe assays. The rate of hybridization is affected by several factors, such as ionic strength, temperature, concentration of the reactant molecules, and the presence of denaturing solvent. Concentration of the reactant molecules is perhaps the most important of these factors, because it limits the rate at which the random collisions between the complementary nucleic acid probe and target sequences occur as required to bring about hybridization. Once two complementary nucleic acid molecules have appropriately collided, they rapidly hybridize to form a thermodynamically stable duplex that does not spontaneously dissociate into its single-stranded components.
It has been found that the rate of DNA or RNA hybridizaton in homogeneous assays can be accelerated by the addition to the hybridization medium of water soluble polymers, such as dextran sulfate, polyvinyl pyrrolidone, or tetraethyl ammonium chloride. See, e.g., Wetnur, Biopolymers, 14:2517-2524, 1975; Chang et al., Biopolymers, 13:1847-1858, 1975; and Kohne, ACPR:20-29, November 1986. The mechanism by which these polymers enhance the rate of hybridization of DNA or RNA molecules is believed to involve a reduction in the effective solvent volume available to the nucleic acids in solution. The negatively charged polymers complex with available solvent molecules from around the nucleic acid molecules, resulting in an effective increase in concentration of DNA or RNA molecules relative to each other. Such concentration is believed to be effective to increase the number of collisions between complementary sequences, and to thereby produce faster hybridization rates.
Such rate-enhancing compounds have been found to increase nucleic acid probe hybridization rates by 10 to 200 fold in homogeneous assays, thereby making possible hybridization times of 1 to 2 hours, rather than overnight. In the case of short synthetic nucleic acid probes, hybridization reactions can be completed in less than 15 minutes if high concentrations of oligomeric probe, for example 1 milligram per milliliter, are used along with rate-enhancing compounds. In general, however, the hybridization reaction for nucleic acid probe assays requires 1 to 2 hours when probes of 100 or more nucleotides in length are used in homogeneous hybridization assays. Moreover, rate-enhancing compounds have not been found to significantly enhance the hybridization rate for heterogeneous assays.
In order to supply the frequent need of researchers and others to collect a dense amount of nucleic acid molecules, for example on a carrier membrane, instruments are available commercially which can separate nucleic acid from a gel or can isolate or concentrate nucleic acid molecules from a solution thereof. The operation of such electroelution or electrophoretic concentration devices takes advantage of the fact that, due to the presence of phosphate groups on the nucleic acid backbone, DNA and RNA in aqueous solution are highly ne
Nie Eileen Xiao-Feng
Wu Yuan Min
Caesar Rivise Bernstein Cohen & Pokotilow Ltd.
Lorne Park Research, Inc.
Myers Carla J.
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