Chemistry: molecular biology and microbiology – Measuring or testing process involving enzymes or... – Involving nucleic acid
Reexamination Certificate
1997-07-22
2003-09-02
Houtteman, Scott W. (Department: 1637)
Chemistry: molecular biology and microbiology
Measuring or testing process involving enzymes or...
Involving nucleic acid
Reexamination Certificate
active
06613508
ABSTRACT:
TECHNICAL FIELD
The present invention relates generally to methods and compositions for analyzing nucleic acid molecules, and more specifically to tags which may be utilized in a wide variety of nucleic acid reactions, wherein separation of nucleic acid molecules based on size is required.
BACKGROUND OF THE INVENTION
Detection and analysis of nucleic acid molecules are among the most important techniques in biology. Such techniques are at the heart of molecular biology and play a rapidly expanding role in the rest of biology.
Generally, one type of analysis of nucleic acid reactions involves separation of nucleic acid molecules based on length. For example, one widely used technique, polymerase chain reaction (PCR) (see, U.S. Pat. Nos. 4,683,195, 4,683,202, and 4,800,159) has become a widely utilized technique to both identify sequences present in a sample and to synthesize DNA molecules for further manipulation.
Briefly, in PCR, DNA sequences are amplified by enzymatic reaction that synthesizes new DNA strands in either a geometric or linear fashion. Following amplification, the DNA sequences must be detected and identified. Because of non-specific amplifications, which would otherwise confuse analysis, or the need for purity, the PCR reaction products are generally subjected to separation prior to detection. Separation based on the size (i.e., length) of the products yields the most useful information. The method giving the highest resolution of nucleic acid molecules is electrophoretic separation. In this method, each individual PCR reaction is applied to an appropriate gel and subjected to a voltage potential. The number of samples that can be processed is limited by the number of wells in the gel. On most gel apparatus, from approximately 10 to 64 samples can be separated in a single gel. Thus, processing large numbers of samples is both labor and material intensive.
Electrophoretic separation must be coupled with some detection system in order to obtain data. Detection systems of nucleic acids commonly, and almost exclusively, utilize an intercalating dye or radioactive label, and less frequently, a nonradioactive label. Intercalating dyes, such as ethidium bromide, are simple to use. The dye is included in the gel matrix during electrophoresis or, following electrophoresis, the gel is soaked in a dye-containing solution. The dye can be directly visualized in some cases, but more often, and for ethidium bromide in particular, is excited by light (e.g., UV) to fluoresce. In spite of this apparent ease of use, such dyes have some notable disadvantages. First, the dyes are insensitive and there must be a large mass amount of nucleic acid molecules in order to visualize the products. Second, the dyes are typically mutagenic or carcinogenic.
A more sensitive detection technique than dyes uses a radioactive (or nonradioactive) label. Typically, either a radiolabeled nucleotide or a radiolabeled primer is included in the PCR reaction. Following separation, the radiolabel is “visualized” by autoradiography. Although more sensitive, the detection suffers from film limitations, such as reciprocity failure and non-linearity. These limitations can be overcome by detecting the label by phosphor image analysis. However, radiolabels have safety requirements, increasing resource utilization and necessitating specialized equipment and personnel training. For such reasons, the use of nonradioactive labels has been increasing in popularity. In such systems, nucleotides contain a label, such as a fluorophore, biotin or digoxin, which can be detected by an antibody or other molecule (e.g., other member of a ligand pair) that is labeled with an enzyme reactive with a chromogenic substrate. These systems do not have the safety concerns as described above, but use components that are often labile and may yield nonspecific reactions, resulting in high background (i.e., low signal-to-noise ratio).
The present invention provides novel compositions and methods which may be utilized in a wide variety of nucleic acid reactions, and further provides other related advantages.
SUMMARY OF THE INVENTION
Briefly stated, the present invention provides compositions and methods which may be utilized in a wide variety of ligand pair reactions wherein separation of molecules of interest, such as nucleic acid molecules, based on size is required. Representative examples of methods which may be enhanced given the disclosure provided herein include PCR, differential display, RNA fingerprinting, PCR-SSCP, oligo litations assays, nuclease digestion methods (e.g., exo- and endo-nuclease based assays), and dideoxy fingerprinting. The methods described herein may be utilized in a wide array of fields, including, for example, in the development of clinical or research-based diagnostics, the determination of polymorphisms, and the development of genetic maps.
Within one aspect of the present invention, methods are provided for determining the identity of a nucleic acid molecule, comprising the steps of (a) generating tagged nucleic acid molecules from one or more selected target nucleic acid molecules, wherein a tag is correlative with a particular nucleic acid fragment and detectable by non-fluorescent spectrometry or potentiometry, (b) separating the tagged fragments by size, (c) cleaving the tags from the tagged fragments, and (d) detecting tags by non-fluorescent spectrometry or potentiometry, and therefrom determining the identity of the nucleic acid molecules.
Within a related aspect of the invention, methods are provided for detecting a selected nucleic acid molecule, comprising the steps of (a) combining tagged nucleic acid probes with target nucleic acid molecules under conditions and for a time sufficient to permit hybridization of a tagged nucleic acid probe to a complementary selected target nucleic acid sequence, wherein a tagged nucleic acid probe is detectable by non-fluorescent spectrometry or potentiometry, (b) altering the size of hybridized tagged probes, unhybridized probes or target molecules, or the probe:target hybrids, (c) separating the tagged probes by size, (d) cleaving tags from the tagged probes, and (e) detecting the tags by non-fluorescent spectrometry or potentiometry, and therefrom detecting the selected nucleic acid molecule.
Within further aspects methods are provided for genotyping a selected organism, comprising the steps of (a) generating tagged nucleic acid molecules from a selected target molecule, wherein a tag is correlative with a particular fragment and may be detected by non-fluorescent spectrometry or potentiometry, (b) separating the tagged molecules by sequential length, (c) cleaving the tag from the tagged molecule, and (d) detecting the tag by non-fluorescent spectrometry or potentiometry, and therefrom determining the genotype of the organism.
Within another aspect, methods are provided for genotyping a selected organism, comprising the steps of (a) combining a tagged nucleic acid molecule with a selected target molecule under conditions and for a time sufficient to permit hybridization of the tagged molecule to the target molecule, wherein a tag is correlative with a particular fragment and may be detected by non-fluorescent spectrometry or potentiometry, (b) separating the tagged fragments by sequential length, (c) cleaving the tag from the tagged fragment, and (d) detecting the tag by non-fluorescent spectrometry or potentiometry, and therefrom determining the genotype of the organism.
Within the context of the present invention it should be understood that “biological samples” include not only samples obtained from living organisms (e.g., mammals, fish, bacteria, parasites, viruses, fungi and the like) or from the environment (e.g., air, water or solid samples), but biological materials which may be artificially or synthetically produced (e.g., phage libraries, organic molecule libraries, pools of genomic clones, cDNA clones, RNA clones, or the like). Representative examples of biological samples include biological fluids (e.g., blood, semen, cerebral spinal fluid,
Howbert J. Jeffry
Mulligan John T.
Ness Jeffrey Van
Tabone John C.
Houtteman Scott W.
Qiagen Genomics, Inc.
SEED Intellectual Property Law Group PLLC
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