Liquid purification or separation – Processes – Liquid/liquid solvent or colloidal extraction or diffusing...
Reexamination Certificate
2000-02-10
2002-04-16
Therkorn, Ernest G. (Department: 1723)
Liquid purification or separation
Processes
Liquid/liquid solvent or colloidal extraction or diffusing...
C210S656000, C210S198200, C435S006120, C536S025400
Reexamination Certificate
active
06372142
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to DNA separation systems and methods suitable for effecting a size-based (base pair length) separation of DNA. The invention concerns an improved separation column for increasing the range of base pair length of the DNA fragments that can be separated by Matched Ion Polynucleotide Chromatography (MIPC) and for improving the separation of heteroduplex and homoduplex DNA using MIPC under partially denaturing conditions.
BACKGROUND OF THE INVENTION
Separations of polynucleotides such as DNA have been traditionally performed using slab gel electrophoresis or capillary electrophoresis. However, liquid chromatographic separations of polynucleotides are becoming more important because of the ability to automate the analysis and to collect fractions after they have been separated. Therefore, columns for polynucleotide separation by liquid chromatography (LC) are becoming more important.
DNA molecules are polymers comprising sub-units called deoxynucleotides. The four deoxynucleotides found in DNA comprise a common cyclic sugar, deoxyribose, which is covalently bonded to any of the four bases, adenine (a purine), guanine (a purine), cytosine (a pyrimidine), and thymine (a pyrimidine), referred to herein as A, G, C, and T respectively. A phosphate group links a 3′-hydroxyl of one deoxynucleotide with the 5′-hydroxyl of another deoxynucleotide to form a polymeric chain. In double stranded DNA, two strands are held together in a helical structure by hydrogen bonds between what are called complimentary bases. The complimentarity of bases is determined by their chemical structures. In double stranded DNA, each A pairs with a T and each G pairs with a C, i.e., a purine pairs with a pyrimidine. Ideally, DNA is replicated in exact copies by DNA polymerases during cell division in the human body or in other living organisms. DNA strands can also be replicated in vitro by means of the Polymerase Chain Reaction (PCR). Sometimes, exact replication fails and an incorrect base pairing occurs. Further replication of the new strand produces double stranded DNA offspring containing a heritable difference in the base sequence from that of the parent. Such heritable changes in base pair sequence are called mutations.
As used herein, double stranded DNA is referred to as a duplex. When a base sequence of one strand is entirely complimentary to a base sequence of the other strand, the duplex is called a homoduplex. When a duplex contains at least one base pair which is not complimentary, the duplex is called a heteroduplex. A heteroduplex is formed during DNA replication when an error is made by a DNA polymerase enzyme and a non-complimentary base is added to a polynucleotide chain being replicated. Further replications of a heteroduplex will, ideally, produce homoduplexes which are heterozygous, i.e., these homoduplexes will have an altered sequence compared to the original parent DNA strand. When the parent DNA has a sequence which predominates in a naturally occurring population, the sequence is generally referred to as a “wild type”.
Many different types of DNA mutations are known. Examples of DNA mutations include, but are not limited to, “point mutation” or “single base pair mutations” in which an incorrect base pairing occurs. The most common point mutations comprise “transitions” in which one purine or pyrimidine base is replaced for another and “transversions” wherein a purine is substituted for a pyrimidine (and visa versa). Point mutations also comprise mutations in which a base is added or deleted from a DNA chain. Such “insertions” or “deletions” are also known as “frameshift mutations”. Although they occur with less frequency than point mutations, larger mutations affecting multiple base pairs can also occur and may be important. A more detailed discussion of mutations can be found in U.S. Pat. No. 5,459,039 to Modrich (1995), and U.S. Pat. No. 5,698,400 to Cotton (1997).
The sequence of base pairs in DNA is a code for the production of proteins. In particular, a DNA sequence in the exon portion of a DNA chain codes for a corresponding amino acid sequence in a protein. Therefore, a mutation in a DNA sequence may result in an alteration in the amino acid sequence of a protein. Such an alteration in the amino acid sequence may be completely benign or may inactivate a protein or alter its function to be life threatening or fatal. On the other hand, mutations in an intron portion of a DNA chain would not be expected to have a biological effect since an intron section does not contain code for protein production. Nevertheless, mutation detection in an intron section may be important, for example, in a forensic investigation.
Detection of mutations is therefore of great importance in diagnosing diseases, understanding the origins of disease, and the development of potential treatments. Detection of mutations and identification of similarities or differences in DNA samples is also of critical importance in increasing the world food supply by developing diseases resistant and/or higher yielding crop strains, in forensic science, in the study of evolution and populations, and in scientific research in general (Guyer, et al.,
Proc. Natl. Acad. Sci. USA
92:10841 (1995); Cotton, TIG 13:43 (1997)).
Alterations in a DNA sequence which are benign or have no negative consequences are sometimes called “polymorphisms”. For the purposes of this application, all alterations in the DNA sequence, whether they have negative consequences or not, are defined herein as “mutations”. For the sake of simplicity, the term “mutation” is used herein to mean an alteration in the base sequence of a DNA strand compared to a reference strand (generally, but not necessarily, a wild type). As used herein, the term “mutation” includes the term “polymorphism” or any other similar or equivalent term of art.
Separation of double-stranded deoxyribonucleic acids (dsDNA) fragments and detection of DNA mutations is of great importance in medicine, in the physical and social sciences, and in forensic investigations. The Human Genome Project is providing an enormous amount of genetic information and yielding new information for evaluating the links between mutations and human disorders (Guyer, et al.,
Proc. Natl. Acad. Sci. USA
92:10841 (1995)). For example, the ultimate source of disease is described by genetic code that differs from the wild type (Cotton, TIG 13:43 (1997)). Understanding the genetic basis of disease can be the starting point for a cure. Similarly, determination of differences in genetic code can provide powerful and perhaps definitive insights into the study of evolution and populations (Cooper, et. al.,
Human Genetics
vol. 69:201 (1985)). Understanding these and other issues related to genetic coding requires the ability to identify anomalies, i.e., mutations, in a DNA fragment relative to the wild type.
Traditional chromatography is a separation process based on partitioning of mixture components between a “stationary phase” and a “mobile phase”. The stationary phase is provided by the surface of solid materials which can comprise many different materials in the form of particles or passageway surfaces of cellulose, silica gel, coated silica gel, polymer beads, polysaccharides, and the like. These materials can be supported on solid surfaces such as on glass plates or packed in a column. The mobile phase can be a liquid or a gas in gas chromatography. This invention relates to liquid mobile phases.
The separation principles are generally the same regardless of the materials used, the form of the materials, or the apparatus used. The different components of a mixture have different respective degrees of solubility in the stationary phase and in the mobile phase. Therefore, as the mobile phase flows over the stationary phase, there is an equilibrium in which the sample components are partitioned between the stationary phase and the mobile phase. As the mobile phase passes through the column, the equilibrium is constantly shifted in favor of the mobile phas
Gjerde Douglas T.
Haefele Robert M.
Hecker Karl H.
Roque Raquel R.
Therkorn Ernest G.
Transgenomic Inc.
Walker William B.
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