Method for isolating nucleic acids

Information

  • Patent Application
  • 20060078923
  • Publication Number
    20060078923
  • Date Filed
    September 20, 2005
    19 years ago
  • Date Published
    April 13, 2006
    18 years ago
Abstract
Described herein is a method in which genomic nucleic acid of a cell can be separated from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid (e.g., plasmid DNA) of the cell directly from a cell growth culture. Also described herein, a method in which genomic nucleic acid can be separated from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in a cell lysate without the need to prepare a cleared lysate. The present invention is also directed to a method of isolating genomic nucleic acid (e.g., RNA, DNA) of a cell or an organism.
Description
BACKGROUND OF THE INVENTION

Many molecular biology applications, such as capillary electrophoresis, nucleotide sequencing, reverse transcription cloning and gene therapy protocols, which contemplate the transfection, transduction or microinjection of mammalian cells, require the isolation of high quality nucleic acid preparations.


The advent of demanding molecular biology applications has increased the need for high-throughput, and preferably readily automatable, purification protocols capable of producing high quality nucleic acid preparations. Although recent technological advancements and the advent of robotics have facilitated the automation of sequencing reactions and gel reading steps, throughput is still limited by the availability of readily automatable methods of nucleic acid purification.


SUMMARY OF THE INVENTION

As described herein, Applicants provide a method in which genomic nucleic acid of a cell or organism can be separated from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid (e.g., plasmid DNA) of the cell or organism, directly from a cell or organism growth culture. In addition, Applicants provide a method in which genomic nucleic acid can be separated from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in a cell or organism lysate, without the need to prepare a cleared lysate.


Traditional alkaline lysis requires the following steps: concentrating or pelleting cells diluted in growth media; centrifuging or vortexing; lysing cells with alkaline detergent; shaking and/or agitating lysate; adding neutralization buffer; filtering and/or manipulating sample to remove the flocculent mass; adding a solid phase carrier; and adding binding buffer. Additional purification steps are generally required to remove the detergents and salts as follows: addition of solid phase carriers and addition of a binding buffer.


An advantage of the invention is that it allows for a simplified procedure for separating genomic nucleic acid of a cell or organism from nucleic acids having a molecular weight lower than the molecular weight of the genomic nucleic acid of the cell or organism. By providing solid phase carriers and a reagent that causes lysis of cells or organisms and precipitation of the nucleic acid of the cells or organism onto the solid phase carriers (a nucleic acid precipitation agent), one or more steps can be removed from the standard purification process of nucleic acid from intact or whole cells or organisms. Furthermore, by providing solid phase carriers and a reagent that causes precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, one or more steps can be removed from the standard purification process of nucleic acid from cell or organism lysates. The order in which the solid phase carriers and the reagent are combined with a cell, organism, cell lysate, or organism lysate is not critical. The solid phase carriers and the reagent that causes precipitation of the nucleic acid of the cell or organism onto the solid phase carriers and/or lysis of the cells or organisms, can be combined with a cell, organism, cell lysate or organism lysate sequentially (e.g., as separate components; in two steps) or simultaneously (e.g., as a single component; in one step). When the solid phase carriers and the reagent are combined into a single component, the methods described herein allow for the addition of a single reagent to a cell or organism, or culture of cells or organisms, followed by an incubation, a separation of a (one or more) solid phase carrier and a selective elution to achieve separation of a cell's or organism's genomic nucleic acid from the cell's or organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the genomic nucleic acid. No pH adjustments are required by the methods of the invention. The reduced number of steps provided by the reagents and methods described herein simplifies the automation of the nucleic acid purification process of cells, organisms, cell lysates or organism lysates.


Accordingly, the present invention relates to a method of separating genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism (e.g., plasmid DNA, episomal DNA, mitochondrial DNA, organelle DNA, viral DNA) comprising combining i) solid phase carriers (e.g., magnetic microparticles) whose surfaces have bound thereto a functional group (e.g., carboxyl group, amine group) which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent, wherein the reagent causes lysis of the cell or organism and precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell or organism bound thereto. The solid phase carriers are separated from the combination and contacted with an elution buffer (e.g., water) that causes elution (selective elution) of the nucleic acid having a lower molecular weight than the genomic nucleic acid from the solid phase carriers. The genomic nucleic acid remains bound to the solid phase carrier, thereby resulting in the separation of genomic nucleic acid of the cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism.


The present invention also relates to a method of separating genomic nucleic acid of a cell or organism from plasmid nucleic acid of the cell comprising combining i) magnetic microparticles whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent (e.g., alcohol such as ethanol, isopropanol, polyalkylene glycol), wherein the reagent causes lysis of the cell or organism and precipitation of nucleic acid of the cell or organism onto the magnetic microparticles, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the nucleic acid of the cell or organism binds reversibly to the magnetic microparticles, thereby producing magnetic microparticles having nucleic acid of the cell or organism bound thereto. The magnetic microparticles having nucleic acid of the cell or organism bound thereto are separated from the combination and contacted with an elution buffer that causes elution of the plasmid nucleic acid from the magnetic microparticles. The genomic nucleic acid remains bound to the solid phase carrier, thereby resulting in the separation of genomic nucleic acid of the cell or organism from plasmid nucleic acid of the cell or organism.


The present invention also relates to a method of separating genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism (e.g., plasmid nucleic acid) comprising combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism lysate and iii) a reagent, wherein the reagent causes precipitation of the nucleic acid of the cell or organism lysate onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which the nucleic acid of the cell or organism lysate binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell bound thereto. The solid phase carriers are separated from the combination and contacted with an elution buffer that causes elution of the nucleic acid having a lower molecular weight than the genomic nucleic acid from the solid phase carriers. The genomic nucleic acid remains bound to the solid phase carrier, thereby separating genomic nucleic acid of the cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism.


In the methods of the present invention, the solid phase carriers to which the genomic nucleic acid is bound can be separated from the eluate comprising the nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid using any suitable means (e.g., magnetic means, centrifugation). The solid phase carriers can then be contacted with a suitable elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


The present invention is also directed to a method of isolating genomic nucleic acid (e.g., RNA, DNA) of a cell (e.g., a prokaryotic cell, a eukaryotic cell such as a mammalian cell) or organism (e.g., a pathogen such as a virus, bacteria, parasite, fungus) comprising combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent, wherein the reagent causes lysis of the cell or organism and precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the genomic nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having genomic nucleic acid of the cell or organism bound thereto. The solid phase carriers are then separated from the combination, thereby isolating genomic nucleic acid of the cell or organism. The solid phase carriers can be contacted with an elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


In a particular embodiment, the present invention is directed to a method of isolating genomic nucleic acid of a cell or organism comprising combining the cell or organism and a reagent which causes lysis of the cell or organism, thereby producing a first combination; and maintaining the first combination under conditions in which the cell or organism is lysed, thereby producing a lysate. The lysate is combined with a binding buffer comprising solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid and a reagent which causes precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, thereby producing a second combination. The second combination is maintained under conditions in which genomic nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having genomic nucleic acid of the cell or organism bound thereto. The solid phase carriers are then separated from the second combination, thereby isolating genomic nucleic acid of the cell or organism. The method can further comprising contacting the solid phase carriers with an elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


The present invention is also directed to kits for use in the methods described herein. In one embodiment, the kit comprises a lysis buffer, a binding buffer, an agent that removes impurities and a wash buffer. The lysis buffer can comprise sodium dodecyl sulfate, Triton X-100, EDTA and Tris-HCl. The binding buffer can comprise magnetic microparticles, polyethylene glycol and sodium iodide. The agent that removes impurities can comprise an agent that digests protein, such as proteinase K, an agent that digests DNA (e.g., DNase) and/or an agent that digests RNA (e.g., RNase). The wash buffer can comprise polyethylene glycol and urea. In a particular embodiment, the kit comprises i) a lysis buffer comprising sodium dodecyl sulfate, Triton X-100, EDTA and Tris; ii) a binding buffer comprising magnetic microparticles, polyethylene glycol and sodium iodide; iii) proteinase K; and iv) a wash buffer comprising polyethylene glycol and urea.




BRIEF DESCRIPTION OF THE DRAWINGS

The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.



FIG. 1 is an illustration of the protocol for separation of genomic nucleic acid of a cell from nucleic acid having a lower molecular weight than the genomic nucleic acid in the cell.



FIG. 2 is a 96-well agarose gel which shows separation of E. coli genomic nucleic acid of a cell from a plasmid in the cell.



FIG. 3 is a histogram of the Phred 20 (red) and Phred 30 (black) bases generated by the reads; the Y axis is number of reads, the X axis if Phred 20 binds in 50 bp increments.



FIG. 4 shows GDNA duplicates prepared from 50 ul horse blood.



FIG. 5 shows the PicoGreen Analysis of 8 samples prepared gDNA from horse blood.



FIG. 6 shows a gradient PCR of prepared gDNA from horse blood (using Y3B19 markers with an expected amplicon size of 225 bp).



FIG. 7 is an agarose e-gel of genomic DNA isolated from whole equine blood.



FIG. 8 is an agarose e-gel of genomic DNA isolated from whole porcine blood.



FIG. 9 is an agarose e-gel of genomic DNA isolated from whole human blood using a method in which lysis and binding occurred in two steps.



FIG. 10 is an agarose e-gel of total RNA isolated from cultured mammalian cells.



FIG. 11 show the capillary electrophoresis results of RNA isolated from solid tissue.



FIG. 12 show the capillary electrophoresis results and an agarose e-gel of a sample of RNA isolated from whole blood.



FIG. 13 show an agarose e-gel and PCR results of genomic DNA isolated from Buccal cells using mouthwash collection.



FIG. 14 show an agarose e-gel and PCR results of genomic DNA isolated from Buccal cells using swab collection.



FIG. 15 show the PCR results of isolation and detection of hepatitis B virus (HBV) genomic DNA in plamsa samples.



FIG. 16 show an agarose e-gel and PCR results of genomic DNA isolated from paraffin embedded samples.




DETAILED DESCRIPTION OF THE INVENTION

As described herein, the present invention provides methods in which a cell's and/or organism's genomic nucleic acid can be separated from the cell's or organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the genomic nucleic acid (e.g., plasmid DNA) using a minimal number of steps. The separation can be performed on a cell or organism culture directly without the need to pellet the cells or organisms. In addition, the methods described herein can be performed directly on a cell or organism lysate without the need to clear the lysate of genomic nucleic acid using traditional methods (e.g., centrifugation, chemical treatment). In particular embodiments in which the nucleic acid of a cell is primarily endogenous nucleic acid (e.g., DNA, RNA) the present invention provides methods in which a cell's or organism's endogenous nucleic acid (e.g., genomic nucleic acid (e.g., DNA, RNA), mitochondrial nucleic acid, mitochondrial RNA, transfer RNA, micro RNA, messenger RNA) is isolated from the cell or organism. The method can also be used to separate the various species of endogenous nucleic acid (e.g., separate endogenous DNA from endogenous RNA) of a cell or organsim from one another.


The present invention provides methods and reagents for isolating nucleic acids. The reagents described herein can be used to separate genomic nucleic acid of a (one or more) cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid of the cell or organism, by combining the cell or organism with solid phase carriers and a reagent which causes lysis of the cell or organism, and precipitation of nucleic acid of the cell or organism onto the solid phase carriers. Alternatively, the reagents described herein can be used to separate genomic nucleic acid of a cell or organism lysate from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid of the cell or organism lysate, by combining the cell or organism lysate with solid phase carriers and a reagent which causes precipitation of nucleic acid of the cell or organism lysate onto the solid phase carriers. The nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid of the cell or organism is then selectively eluted from the solid phase carriers. In yet another embodiment, the reagents described herein can be used to isolate genomic nucleic acid of a cell or organism (one or more), by combining the cell or organism with solid phase carriers and a reagent which causes lysis of the cell or organism and precipitation of the genomic nucleic acid of the cell or organism onto the solid phase carriers.


As described herein, the method comprises binding the nucleic acid of a cell, organism, cell lysate or organism lysate nonspecifically and reversibly to solid phase carriers (e.g., magnetic microparticles) having a functional group coated surface (e.g., carboxyl coated surface). The microparticles are then separated from the supernatant, for example, by applying a magnetic field to draw down the magnetic microparticles. The remaining solution, (e.g., supernatant) can then be removed, leaving the microparticles with the bound nucleic acid. Once separated from the supernatant, the microparticles can be contacted with an elution buffer that selectively elutes the nucleic acid having a molecular weight that is lower than the molecular weight of genomic nucleic acid of the cell or organism. As a result, an elution buffer containing unbound nucleic acid (the cell's or organism's nucleic acid which has a lower molecular weight than the molecular weight of the cell's or organism's genomic nucleic acid) and magnetic microparticles to which genomic nucleic acid of the cell or organism is still bound are produced. The elution buffer used to elute the nucleic acid having a molecular weight that is lower than the molecular weight of genomic nucleic acid of the cell or organism is a solution in which the concentration of a nucleic acid precipitating reagent is below the range required for binding of nucleic acid having a molecular weight that is lower than the molecular weight of genomic nucleic acid onto magnetic microparticles. In the embodiments in which essentially all the nucleic acid in the cell or organism is genomic nucleic acid, then the microparticles are contacted with an elution buffer that elutes the genomic nucleic acid from the microparticles. In one embodiment, the eluent is water. In addition, sucrose (20%) and formamide (100%) solutions can be used to elute the nucleic acid. Elution of the nucleic acid from the microparticles occurs in thirty seconds or less when an elution buffer of low ionic strength, for example, water, is used. Once the bound nucleic acid has been eluted, the magnetic microparticles are separated from the elution buffer that contains the eluted nucleic acid. Preferably, the magnetic microparticles are separated from the elution buffer by magnetic means. Other methods known to those skilled in the art can be used to separate the magnetic microparticles from the supernatant. For example, filtration or centrifugation can be used.


In one embodiment, once removed from the elution buffer containing unbound nucleic acid (e.g., the cell's or organism's nucleic acid which has a lower molecular weight than the molecular weight of the cell's or organism's genomic nucleic acid), the magnetic microparticles to which genomic nucleic acid of the cell or organism is still bound can also be contacted with a suitable elution buffer to elute the genomic nucleic acid of the cell or organism from the magnetic microparticles. The removed genomic nucleic acid can be used, for example, in agarose gel analysis, PCR amplification, restriction enzyme digestion, diagnostic and/or therapeutic analysis, human identity testing, membrane hybridizations (e.g., Southern and dot/slot blots) and AFLP, RFLP, RAPD, microsatellite and SNP analyses (e.g., for genotyping, fingerprinting etc.).


The isolation of high quality nucleic acid preparations from starting solutions of diverse composition and complexity is a fundamental technique in molecular biology. As a result of the reagents and methods described herein, rapid and readily automatable methods of separating genomic nucleic acid from nucleic acid having a lower molecular weight than genomic nucleic acid are now available. Nucleic acids isolated by the disclosed methods can be used for molecular biology applications requiring high quality nucleic acids, such as the preparation of DNA sequencing templates, microinjection, transfection or transformation of mammalian cells, in vitro synthesis of RNAi hairpins, reverse transcription cloning, cDNA library construction, PCR amplification, and gene therapy research, as well as for other applications with less stringent quality requirements including, but not limited to, transformation, restriction endonuclease or microarray analysis, selective RNA precipitations, in vitro transposition, separation of multiplex PCR amplification products, preparation of DNA probes and primers and detemplating protocols.


The reagents and methods described herein can be used together with a variety of nucleic acid purification techniques, including those described in U.S. Pat. Nos. 5,705,628; 5,898,071; 6,534,262; U.S. Application No. 2002/0106686 and WO 99/58664, the contents of which are herein incorporated by reference.


In one embodiment, the present invention relates to a method of separating genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid (e.g., plasmid DNA) in the cell or organism, comprising combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent, wherein the reagent causes lysis of the cell or organism and precipitation of the nucleic acid of the cell onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell or organism bound thereto. The solid phase carriers are separated from the combination and contacted with an elution buffer that causes elution of the nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid from the solid phase carriers, but does not cause elution of the genomic nucleic acid from the solid phase carriers, thereby separating genomic nucleic acid of the cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism.


In another embodiment, the present invention relates to a method of separating genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism, comprising combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism lysate and iii) a reagent, wherein the reagent causes precipitation of the nucleic acid of the cell or organism lysate onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which the nucleic acid of the cell or organism lysate binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell or organism bound thereto. The solid phase carriers are removed from the combination and contacted with an elution buffer that causes elution of the nucleic acid having a molecular weight that is lower than the genomic nucleic acid, but does not cause elution of the genomic nucleic acid from the solid phase carriers, from the solid phase carriers, thereby separating genomic nucleic acid of the cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism.


The present invention further relates to a method of separating genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism, wherein the nucleic acid having a lower molecular weight is suitable for use in either manual or a high-throughput automated sequencing methods.


The present invention is also directed to a method of isolating endogenous nucleic acid (e.g., RNA, DNA) of a cell (e.g., a prokaryotic cell, a eukaryotic cell such as a mammalian cell) or organism (e.g., a pathogen such as a virus, bacteria, mycobacteria, parasite, fungus). As used herein “endogenous nucleic acid of a cell or organism” refers to nucleic acid normally found in a cell or organism (the nucleic acid found in a cell or organism as the cell or organism occurs in nature).


In one embodiment, the present invention is directed to a method of isolating genomic nucleic acid of a cell or organism comprising combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent, wherein the reagent causes lysis of the cell or organism and precipitation of the nucleic acid of the cell onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the genomic nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having genomic nucleic acid of the cell or organism bound thereto. The solid phase carriers are then separated from the combination, thereby isolating genomic nucleic acid of the cell or organism. The solid phase carriers can be contacted with an elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


In one embodiment, the present invention is directed to a method of isolating genomic nucleic acid of a cell or organism comprising combining the cell and a reagent which causes lysis of the cell or organism, thereby producing a first combination; and maintaining the first combination under conditions in which the cell or organism is lysed, thereby producing a lysate. The lysate is combined with a binding buffer comprising solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid and a reagent which causes precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, thereby producing a second combination. The second combination is maintained under conditions in which genomic nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having genomic nucleic acid of the cell or organism bound thereto. The solid phase carriers are then separated from the second combination, thereby isolating genomic nucleic acid of the cell or organism. The method can further comprising contacting the solid phase carriers with an elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


In another embodiment, the methods of isolating genomic nucleic acid described herein can be used, for example, to isolate genomic nucleic acid of a virus. In this embodiment, the method comprises combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a virus and iii) a reagent, wherein the reagent causes lysis of the virus and precipitation of the nucleic acid of the virus onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the virus occurs and the genomic nucleic acid of the virus binds reversibly to the solid phase carriers, thereby producing solid phase carriers having genomic nucleic acid of the virus bound thereto. The solid phase carriers are then separated from the combination, thereby isolating genomic nucleic acid of the virus. The solid phase carriers can be contacted with an elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers. Alternatively, the virus can first be contacted with an agent that causes lysis of the virus and then contacted with solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid and a reagent which causes precipitation of the nucleic acid of the virus onto the solid phase carriers.


In the methods of isolating genomic nucleic acid the method can further comprise the addition of agents that facilitate removal of nucleic acid that is non-genomic (e.g., RNase when the genomic nucleic acid is DNA; DNase when the genomic nucleic acid is RNA; a proteinase (e.g., proteinase K) to remove protein).


The method described herein can also be used to isolate RNA (e.g., endogenous RNA) from a cell or organism. In one embodiment, the method comprises combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell or organism and iii) a reagent, wherein the reagent causes lysis of the cell or organism and precipitation of the nucleic acid of the cell onto the solid phase carriers, thereby producing a combination. The combination is maintained under conditions in which lysis of the cell or organism occurs and the endogenous nucleic acid of the cell or organism binds reversibly to the solid phase carriers, thereby producing solid phase carriers having endogenous nucleic acid of the cell or organism bound thereto. In a particular embodiment, the solid phase carriers are then contacted with an agent that removes or digests DNA, and maintained under conditions in which the DNA is removed or digested and the RNA remains intact (the RNA is not removed or digested). When the agent that removes DNA is in a solution (e.g., aqueous) that elutes nucleic acid (e.g., DNA, RNA) from the solid phase carriers, the solid phase carriers are then contacted with a reagent that causes precipitation of the RNA onto the solid phase carriers. The solid phase carriers are then separated from the combination, thereby isolating RNA of the cell or organism. The solid phase carriers can be contacted with an elution buffer that causes elution of the RNA from the solid phase carriers.


In another embodiment of isolating RNA, the method comprises combining the cell and a reagent which causes lysis of the cell or organism, thereby producing a first combination; and maintaining the first combination under conditions in which the cell or organism is lysed, thereby producing a lysate. The lysate is combined with a binding buffer comprising solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid and a reagent which causes precipitation of the nucleic acid of the cell or organism onto the solid phase carriers, thereby producing a second combination. In a particular embodiment, the solid phase carriers are then contacted with an agent that removes or digests DNA, and maintained under conditions in which the DNA is removed or digested and the RNA remains intact (the RNA is not removed or digested). When the agent that removes DNA is in a solution (e.g., aqueous) that elutes nucleic acid (e.g., DNA, RNA) from the solid phase carriers, the solid phase carriers are then contacted with a reagent that causes precipitation of the RNA onto the solid phase carriers. The solid phase carriers are then separated from the combination, thereby isolating RNA of the cell or organism. The solid phase carriers can be contacted with an elution buffer that causes elution of the RNA from the solid phase carriers.


The methods described herein are readily automatable method of isolating a plasmid DNA template for nucleotide sequencing. The use of the reagents described herein affords an alternative, and readily automatable, means of nucleic acid separation.


As used herein the terms “separating” or “isolating” is intended to mean that the material in question exists in a physical milieu distinct from that in which it occurs in nature and/or has been completely, substantially or partially separated, isolated or purified from other nucleic acid molecules or cellular components (e.g., cell membrane, cell organelle).


As used herein the terms “nucleic acid” and “nucleic acid molecule” are used synonymously with the term polynucleotides and they are meant to encompass DNA (e.g., single-stranded, double-stranded, covalently closed, and relaxed circular forms), RNA (e.g., single-stranded and double-stranded), RNA/DNA hybrids and polyamide nucleic acids (PNAs).


“Genomic nucleic acid” refers to the genomic or chromosomal nucleic acid present in a cell or organism. Typically, the molecular weight of genomic or chromosomal nucleic acid is from about 500 kilobases (kb) (e.g., mycoplasma) to about 500 gigabases (Gb). In particular embodiments, the molecular weight of genomic or chromosomal nucleic acid ranges from about 1000 kb to about 250 Gb (e.g., onion); from about 10,000 kb to about 5 Gb; from about 100,000 kb to about 1 Gb; and from about 500,000 kb to 1,000,000 kb. The genomic nucleic acid can be DNA or RNA.


“Nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism” refers to nucleic acid other than genomic or chromosomal nucleic acid that is present in a cell or organism and can be endogenous or exogenous nucleic acid. Nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism typically has a molecular weight between about 1 kb to about 250,000 kb (e.g., BAC). In particular embodiments, nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism ranges from about 5 kb to about 100,000 kb; from about 100 kb to about 10,000 kb; and from about 1000 kb to about 5000 kb. As used herein “endogenous nucleic acid” (host cell nucleic acid) refer to nucleic acid that are present in the cell or organism as the cell or organism is obtained. “Exogenous nucleic acid” (foreign nucleic acid; recombinant nucleic acid) refer to nucleic acid that is not present in the cell or organism as obtained (e.g., transfected cell or organism, transduced cell or organism). Exogenous nucleic acid may be present in a cell or organism as a result of being introduced into the cell or organism, or being introduced into an ancestor of the cell or organism. The exogenous nucleic acid may be introduced directly or indirectly into the cell or organism, or an ancestor thereof by means known to one of ordinary skill in the art (e.g., transformation or transfection). Examples of exogenous nucleic acid introduced into a cell or organism include bacterial artificial chromosome (BAC), yeast artificial chromosomes (YAC), plasmids, cosmids, P1 vector and nucleic acid introduced due to an amplification process (e.g., polymerase chain reaction (PCR)). As used herein the term “plasmid” refers to double stranded circular DNA species which originate from an exogenous source (e.g., are introduced into a host cell) and which are capable of self-replication independent of host chromosomal DNA. Thus, the term encompasses cloned DNA produced from the replication of any of the above-mentioned vectors. Examples of vectors used to introduce nucleic acid into a cell include pUC, pOT, pBluescript, pGEM, pTZ, pBR322, pSC101, pACYC, SuperCos and pWE15. Alternatively, the exogenous nucleic acid may be introduced into the cell or organism from a phage into which the nucleic acid has been packaged (e.g., cosmid, P1). Additional examples of “nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell or organism” include, but are not limited to, episomal nucleic acid, mitochondrial nucleic acid, organelle nucleic acid, RNA, siRNA, plastids, microchromosomes, organelle nucleic acid, primers, viral nucleic acid, bacterial nucleic acid and nucleic acid from other pathogens.


A “solid phase carrier” is an entity that is essentially insoluble under conditions upon which a nucleic acid can be precipitated. Suitable solid phase carriers for use in the methods of the present invention have sufficient surface area to permit efficient binding and are further characterized by having surfaces which are capable of reversibly binding nucleic acids. Suitable solid phase carriers include, but are not limited to, microparticles, fibers, beads and supports which have an affinity for nucleic acid and which can embody a variety of shapes, that are either regular or irregular in form, provided that the shape maximizes the surface area of the solid phase, and embodies a carrier which is amenable to microscale manipulations. In one embodiment, the solid phase carrier is paramagnetic, e.g., a paramagnetic microparticle (magnetically responsive). In another embodiment, the solid phase carrier includes a functional group coated surface. For example, the solid phase carrier can be an amine-coated paramagnetic microparticle, a carboxyl-coated paramagnetic microparticle, or an encapsulated carboxyl group-coated paramagnetic microparticle.


As used herein, “paramagnetic microparticles” refers to microparticles which respond to an external magnetic field (e.g., a plastic tube or a microtiter plate holder with an embedded rare earth (e.g., neodymium) magnet) but which demagnetize when the field is removed. Thus, the paramagnetic microparticles are efficiently separated from a solution using a magnet, but can be easily resuspended without magnetically induced aggregation occurring. Preferred paramagnetic microparticles comprise a magnetite rich core encapsulated by a pure polymer shell. Suitable paramagnetic microparticles comprise about 20-35% magnetite/encapsulation ratio. For example, magnetic particles comprising a magnetite/encapsidation ration of about 23%, 25%, 28% 30% 32% or 34% are suitable for use in the present invention. Magnetic particles comprising less than about a 20% ratio are only weakly attracted to the magnets used to accomplish magnetic separations. Depending on the nature of the host cell, the viscosity of the cell growth and the nature of the vector (e.g. high or low copy) paramagnetic microparticles comprising a higher percentage of magnite should be considered. The use of encapsulated paramagnetic microparticles, having no exposed iron, or Fe304 on their surfaces, eliminates the possibility of iron interfering with polymerase function in certain downstream manipulations of the isolated DNA. However the larger the magnetite core the higher the chance of encapsulation leakage (e.g., release of iron oxides). Suitable paramagnetic microparticles for use in the instant invention can be obtained for example from Bangs Laboratories Inc., Fishers, Ind. (e.g., estapor® carboxylate-modified encapsulated magnetic microspheres), Agencourt Biosciences and Seradyn.


Suitable paramagnetic microparticles should be of a size that their separation from solution, for example by magnetic means or by filtration, is not difficult. In addition, preferred paramagnetic microparticles should not be so large that their surface area is minimized or that they are not suitable for microscale manipulation. Suitable sizes range from about 0.1 mean diameter to about 100 mean diameter. A preferred size is about 1.0 mean diameter. Suitable magnetic microparticles are commercially available from PerSeptive Diagnostics and are referred to as BioMag COOH.


As used herein, the term “functional group-coated surface” refers to a surface which is coated with moieties which reversibly bind nucleic acid (e.g., DNA, RNA or polyamide nucleic acids (PNA)). One example is a surface which is coated with moieties which each have a free functional group which is bound to the amino group of the amino silane or the microparticle; as a result, the surfaces of the microparticles are coated with the functional group containing moieties. The functional group acts as a bioaffinity adsorbent for precipitated nucleic acid (e.g., polyalkylene glycol precipitated DNA). In one embodiment, the functional group is a carboxylic acid. A suitable moiety with a free carboxylic acid functional group is a succinic acid moiety in which one of the carboxylic acid groups is bonded to the amine of amino silanes through an amide bond and the second carboxylic acid is unbonded, resulting in a free carboxylic acid group attached or tethered to the surface of the paramagnetic microparticle. Carboxylic acid-coated magnetic particles are commercially available from PerSeptive Diagnostics (BioMag COOH). Suitable solid phase carriers having a functional group coated surface that reversibly binds nucleic acid molecules are for example, magnetically responsive solid phase carriers having a functional group-coated surface, such as, but not limited to, amino-coated, carboxyl-coated and encapsulated carboxyl group-coated paramagnetic microparticles.


Appropriate starting material include organisms, cells (intact or whole cells), tissue (e.g., solid tissue, paraffin embedded tissue), cell lysates (cells in growth or culture media) and lysates prepared from such cells or organisms. In one embodiment, the starting material is fresh or frozen blood (e.g., whole blood) and serum which can contain citrate, EDTA or heparin coagulants. In another embodiment, the starting material is buccal cells. Appropriate starting material include cells obtained from either mammalian (i.e., human, primate (chimpanzee), equine, canine, feline, bovine, porcine, murine) tissue or body fluids and lysates prepared from such cells. Thus, any type of cell or organism having nucleic acid (e.g., genomic nucleic acid; nucleic acid having a molecular weight lower than the molecular weight of the genomic nucleic acid) can be used. Examples of cells for use in the methods of the present invention include, but are not limited to, mammalian cells (e.g., blood cells, such as whole blood cells), bacterial cells (e.g., E. Coli such as DH5, DH10B, DH12S, C600 or XL-1 Blue), yeast cells, plant cells, tissue cells (cells from, for example, C. elegans, mouse tails, human biopsies) and host cells containing exogenous nucleic acid (e.g., recombinant DNA, bacterial DNA or replicative form DNA) which is targeted for isolation from host cell chromosomal DNA and other host cell biomolecules. Examples of organisms include a virus (e.g., hepatitis virus, human immunodeficiency virus, herpes virus, influenza virus), a bacteria, a mycobacteria (M. bovis BCG, M. leprae, M. tuberculosis), a fungus (e.g., yeast such as C. cerevisiae, C. albicans), and a parasite (e.g., Leishmania). Alternatively, the starting material can be lysates prepared from such cells.


As used herein a “host cell” or “host organism” is any cell into which exogenous nucleic acid can be introduced, thereby producing a host cell or organism which contains exogenous nucleic acid, in addition to host cell or organism nucleic acid. As used herein the terms “host cell or organism nucleic acid” and “endogenous nucleic acid” refer to nucleic acid species (e.g., genomic or chromosomal nucleic acid) that are present in a host cell or organism as the cell or organism is obtained. As used herein, the term “exogenous” refers to nucleic acid other than host cell or organism nucleic acid (e.g., plasmid); exogenous nucleic acid can be present into a host cell or organism as a result of being introduced in the host cell or organism, or being introduced into an ancestor of the host cell or organism. Thus, for example, a nucleic acid species which is exogenous to a particular host cell or organism is a nucleic acid species which is non-endogenous (not present in the host cell or organism as it was obtained or an ancestor of the host cell or organism). Appropriate host cells include, but are not limited to, bacterial cells, yeast cells, plant cells and mammalian cells.


As described herein, an advantage of the present invention is that a cell's or organism's genomic nucleic acid can be separated from the cell's or organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the genomic nucleic acid using a minimal number of steps. As described herein, the separation can be performed on a cell or organism culture directly without the need to pellet the cells or organism. In addition, the method can be performed on a cell or organism lysate, wherein the methods of the present invention make it unnecessary to clear the lysate in order to separate genomic nucleic acid of a cell or organism from nucleic acid having a molecular weight that is lower than the molecular weight of the endogenous nucleic acid. In the embodiments in which essentially all the nucleic acid in the cell or organism is endogenous nucleic acid (e.g., DNA, RNA) the methods described herein can be used to isolate a particular species of the endogenous nucleic acid (e.g., genomic nucleic acid; total RNA) from the cell or organism.


As used herein, a “lysate” is a solution containing components of cells or organisms which contain genomic nucleic acid and nucleic acid having a lower molecular weight than genomic nucleic acid and whose cell membranes have been disrupted by any means with the result that the contents of the cell or organism, including the nucleic acid therein, are in solution. A “cleared lysate” is a lysate in which the chromosomal or genomic nucleic acid, proteins and membranes of the cell or organism have been removed such as by chemical treatment or centrifugation of the lysate. Cells or organism are lysed using known methods, thereby preparing a mixture suitable for use with the method of the instant invention. For example, cells or organisms can be lysed using chemical means (e.g., alkali or alkali and anionic detergent treatment), isotonic shock, or physical disruption (e.g., homogenization).


The term “lysed host cell suspension” or “lysed host organism suspension”, as used herein, refers to a suspension comprising host cells or organisms whose membranes have been disrupted by any means (e.g., chemical, such as alkali or alkali and anionic detergent treatment, isotonic shock, or physical disruption by homogenization); such a suspension is a mixture of host cell biomolecules, cellular components and disrupted membrane debris. In one embodiment, a lysed host cell or organism suspension suitable for use in the instant invention is prepared by contacting host cells or organisms with an alkali and anionic detergent (e.g., sodium dodecyl sulphate (SDS)) solution (e.g., 0.2 N NaOH, 1% SDS). Optionally, lysozyme could be included in the lysis buffer. The presence of an anionic detergent in the lysing solution functions to produce an anti-protein environment by neutralizing the effective charge of the proteins, thereby minimizing their attraction to the surfaces of the functional group-coated paramagnetic microparticles. In one embodiment, the lysed host cell or organism suspension is non-neutralized. Optionally, RNAse can be added to the host cell or organism lysate to degrade host cell RNA, thereby allowing DNA to bind to the magnetic microparticles free, or essentially free, from RNA.


According to the methods of the present invention, a cell or organism is combined with solid phase carriers and a reagent, wherein the reagent causes the nucleic acids of the cell or organism to bind non-specifically and reversibly to the solid phase carriers.


“Non-specific nucleic acid binding” refers to binding of different nucleic acid molecules with approximately the same affinity to magnetic microparticles, despite differences in the nucleic acid sequence or size of the different nucleic acid molecules. As used herein, “facilitated adsorption” refers to a process whereby a precipitating reagent, (e.g., a poly-alkyelene glycol) is used to promote the precipitation and subsequent adsorption of a species of DNA molecules, which were initially in mixture, onto the surface of a solid phase carrier. The resulting reversible interaction is distinct from, for example, an interaction between two binding partners (e.g., streptavidin/biotin, antibody/antigen or a sequence-specific interaction), which are conventionally utilized for the purpose of isolating particular biomolecules based on their composition or sequence.


A “nucleic acid precipitating reagent” or “nucleic acid precipitating agent” or “crowding reagent” is a composition that causes the nucleic acid of a cell or organism to go out of solution. Suitable precipitating agents include alcohols (e.g., short chain alcohols, such as ethanol or isopropanol) and a poly-OH compound (e.g., a polyalkylene glycol). The nucleic acid precipitating reagent can comprise one or more of these agents. The nucleic acid precipitating reagent is present in sufficient concentration to nonspecifically and reversibly bind the nucleic acid of the cell onto the solid phase carriers.


Appropriate alcohol (e.g., ethanol, isopropanol) concentrations (final concentrations) for use in the methods of the present invention are from about 40% to about 60%; from about 45% to about 55%; and from about 50% to about 54%.


Appropriate polyalkylene glycols include polyethylene glycol (PEG) and polypropylene glycol. Suitable PEG can be obtained from Sigma (Sigma Chemical Co., St. Louis Mo., Molecular weight 8000, Dnase and Rnase fee, Catalog number 25322-68-3). The molecular weight of the polyethylene glycol (PEG) can range from about 6000 to about 10,000, from about 6000 to about 8000, from about 7000 to about 9000, from about 8000 to about 10,000. In a particular embodiment PEG with a molecular weight of about 8000 is used. In general, the presence of PEG provides a hydrophobic solution which forces hydrophilic nucleic acid molecules out of solution. In one embodiment, the PEG concentration is from about 5% to about 20%. In other embodiments, the PEG concentration ranges from about 7% to about 18%; from about 9% to about 16%; and from about 10% to about 15%.


As described above, in the embodiment in which the starting material is a cell or organism the reagent is formulated to cause the lysis of the cell or organism. A variety of lysis components can be used to cause the disruption of a membrane (such as alkali, alkali and anionic detergent treatment, or isotonic shock). A reagent that causes lysis of a cell or organism can comprise, for example, sodium hydroxide (NaOH), sodium doedecyl sulfate (SDS), Triton, sodium lauryl sarcosine and/or guanidine isothiocyanate. In one embodiment, the lysis component of the reagent is an alkali (NaOH) and/or an anionic detergent (e.g., sodium dodecyl sulphate (SDS)) solution (e.g., final concentration of 0.2 N NaOH, 1% SDS when added to a cell). Optionally, lysozyme could be included in the lysis component of the first reagent. The presence of an anionic detergent in the lysis component functions to produce an anti-protein environment by neutralizing the effective charge of the proteins, thereby minimizing their attraction to the surfaces of the solid phase carrier (e.g., a functional group-coated paramagnetic microparticle). Optionally, RNAse (e.g., 1.75 ng/ul RNAse/ddH2O) can be added to the lysis component to degrade host cell RNA, thereby allowing DNA to bind to the solid phase carrier free, or essentially free, from RNA. The necessity of including a RNAse step will largely be determined by the size of the nucleic acid species that is targeted for isolation in the particular nucleic acid precipitation that is being performed. For example, if the conditions selected for isolation are appropriate for isolating nucleic acids comprising at least 4,000 base pairs, then it is unlikely that RNA species will be an appreciable contaminant.


The reagent used in the methods described above is useful for isolating a nucleic acid from a cell or an organism. This reagent contains a nucleic acid precipitating agent and a solid phase carrier, and can also be formulated to cause lysis of a cell(s) or an organism(s). The nucleic acid precipitating agent is of sufficient concentration to precipitate the nucleic acid of the cell or organism. The solid phase carrier in this reagent contains a surface that binds nucleic acid of the cell or organism. The components of the reagent can be contained in a single reagent or as separate components. The components can be combined simultaneously or sequentially with cells. The order in which the elements of the combination are combined is not critical. The nature and quantity of the components contained in the reagent are as described in the methods above. The reagent may formulated in a concentrated form, such that dilution is required to obtain the functions and or concentrations described in the methods herein.


Optionally, salt may be added to the reagent to cause precipitation of the nucleic acid of the cell onto the solid phase carriers. Suitable salts which are useful for facilitating the adsorption of nucleic acid molecules targeted for isolation to the magnetically responsive microparticles include sodium chloride (NaCl), lithium chloride (LiCl), barium chloride (BaCl2), potassium (KCl), calcium chloride (CaCl2), magnesium chloride (MgCl2) and cesium chloride (CsCl). In one embodiment, sodium chloride is used. In general, the presence of salt functions to minimize the negative charge repulsion of the nucleic acid molecules. The wide range of salts suitable for use in the method indicates that many other salts can also be used and suitable levels can be empirically determined by one of ordinary skill in the art. The salt concentration can be from about 0.1M to about 0.5M; from about 0.15M to about 0.4M; and from about 2M to about 4M.


At high salt concentrations (e.g., synonymous with high ionic strengths) suitable paramagnetic microparticles will adsorb DNA fragments of all sizes. The term “high salt concentration” refers to salt concentrations greater than about 0.5 M. At “low salt concentrations” (or low ionic strengths), which as used herein connotes concentrations less than about 0.2 M, essentially no DNA, of any size, will be precipitated even in the presence of a PEG concentration that is as high as 12% (weight/volume) (Lis, John T, Methods in Enzymology 65: 437-353 (1980). Additional components may be added to the reagent. In one embodiment, RNAse is added to the nucleic acid precipitating agent.


According to the methods of the invention, the isolation of the nucleic acid molecules of the cell or organism is accomplished by removing the nucleic acid-coated solid phase carrier from the combination. The solid phase carrier (e.g., a paramagnetic microparticle) can be recovered from the first combination, for example, by vacuum filtration, centrifugation, or by applying a magnetic field to draw down the solid phase carrier (e.g., a paramagnetic microparticle). Paramagnetic microparticles are preferably separated from solutions using magnetic means, such as applying a magnet field of at least 1000 Gauss. However, other methods known to those skilled in the art can be used to remove the magnetic microparticles from the supernatant (e.g., vacuum filtration or centrifugation). The remaining solution can then be removed, leaving solid phase carriers having the nucleic acid of the cell or organism adsorbed to their surface. Once separated from the mixture, the nucleic acid having a lower molecular than the molecular weight of the genomic nucleic acid of the cell or organism which is adsorbed to the solid phase carrier can be recovered by contacting the solid phase carrier with a suitable elution buffer. As a result, 1) a solution comprising the nucleic acid molecules having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the elution buffer and 2) solid phase carriers to which is bound genomic nucleic acid of the cell or organism, are produced.


In one embodiment, a suitable “elution buffer” for use in the methods of the present invention is a buffer that selectively elutes a cell's or organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the cell's or organism's genomic nucleic acid. In the embodiments in which essentially all the nucleic acid in the cell or organism is genomic nucleic acid (e.g., DNA, RNA), a suitable elution buffer is a buffer that elutes the genomic nucleic acid from the solid phase carrier. In one embodiment, a suitable elution buffer for use in the present invention can be water or any aqueous solution in which the nucleic acid precipitating agent (e.g., isopropanol and/or PEG) concentration is below the concentration required for binding of a cell's or an organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the cell's or organism's genomic nucleic acid to the solid phase carrier, as discussed above. For example, useful buffers include, but are not limited to, TRIS-HCl, Tris acetate, sucrose (20%) and formamide (100%) solutions. Elution of a cell's or an organism's nucleic acid which has a molecular weight that is lower than the molecular weight of the cell's or organism's genomic nucleic acid from the solid phase carrier can occur quickly (e.g., in thirty seconds or less) when a suitable low ionic strength elution buffer is used. Once the bound nucleic acid has been eluted, the solid phase carrier, to which is bound the cell's or organism's genomic nucleic acid, is separated from the elution buffer which comprises the nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid. The solid phase carriers can then be contacted with a suitable elution buffer that causes elution of the genomic nucleic acid from the solid phase carriers.


Optionally, impurities (e.g., host cell components, particular nucleic acids, proteins, metabolites, chemicals or cellular debris) can be removed by contacting the paramagnetic microparticles with nucleic acid bound thereto (e.g., by contacting the microparticles with a suitable wash buffer solution) with an agent that removes and/or dissolves impurities before separating the microparticle-bound nucleic acid from the solid phase carriers. An agent that removes and/or dissolves impurities can be an agent that dissolves particular nucleic acid, such as DNA (e.g., DNase), RNA (e.g., RNase) or protein (e.g., Proteinase K). Alternatively, an agent that dissolves impurities can be a “wash buffer” or included in a wash buffer, which is a composition that dissolves or removes impurities either bound directly to the microparticle, or associated with the adsorbed nucleic acid, but does not solubilize the nucleic acid absorbed onto the solid phase. The pH and solute composition and concentration of the wash buffer can be varied according to the types of impurities which are expected to be present. For example, ethanol (e.g., 70%) exemplifies a preferred wash buffer useful to remove excess PEG and salt. The magnetic microparticles with bound nucleic acid can also be washed with more than one wash buffer solution. The microparticles can be washed as often as required (e.g., three to five times) to remove the desired impurities. However, the number of washings is preferably limited to in order to minimize loss of yield of the bound nucleic acid. A suitable wash buffer solution has several characteristics. First, the wash buffer solution must have a sufficiently high salt concentration (a sufficiently high ionic strength) that the nucleic acid bound to the magnetic microparticles does not elute off of the microparticles, but remains bound to the microparticles. A suitable salt concentrations is greater than about 0.1 M and is preferably about 0.5M. Second, the buffer solution is chosen so that impurities that are bound to the nucleic acid or microparticles are dissolved. The pH and solute composition and concentration of the buffer solution can be varied according to the types of impurities which are expected to be present. Suitable wash solutions include the following: 0.5×5SSC; 100 mM ammonium sulfate, 400 mM Tris pH 9, 25 mM MgCl2 and 1% bovine serum albumin (BSA); and 0.5M NaCl. In one embodiment, the wash buffer solution comprises 25 mM Tris acetate (pH 7.8), 100 mM potassium acetate (KOAc), 10 mM magnesium acetate (Mg2OAc), and 1 mM dithiothreital (DTT). In another embodiment, the wash solution comprises 2% SDS, 10% Tween and/or 10% Triton.


The isolation of high quality nucleic acid preparations from starting solutions of diverse composition and complexity is a fundamental technique in molecular biology. Thus, as a result of the work described herein, novel and readily automatable methods of separating nucleic acid molecules having a molecular weight that is lower than the molecular weight of genomic nucleic acid are now available. In one embodiment, the reagent is added to the cell or organism by a multisample transfer device. In another embodiment, the first reagent is added simultaneously to a plurality of samples, e.g., at least 6, 12, 24, 96, 384, or 1536 samples, each sample containing one or more cells or organisms. In another embodiment, the first reagent is sequentially delivered to a plurality of samples (e.g., at least 6, 12, 24, 96, 384, or 1536 samples) each sample containing one or more cells or organisms. The invention includes methods of analyzing a plurality of nucleic acid samples. The methods include providing a plurality of nucleic acid samples isolated by a method described herein and analyzing the samples, e.g., performing sequence analysis on the samples.


In another embodiment, the isolated nucleic acid of one or a plurality of samples is subjected to further analysis (e.g., sequence analysis). Nucleic acids isolated by the disclosed method can be used for molecular biology applications requiring high quality nucleic acids, for example, the preparation of DNA sequencing templates, the microinjection, transfection or transformation of mammalian cells, the in vitro synthesis of RNA probes, reverse transcription cloning, cDNA library construction, PCR amplification, or gene therapy research, as well as for other applications with less stringent quality requirements including, but not limited to, transformation, restriction endonuclease or microarray analysis, selective RNA precipitations, in vitro transposition, separation of multiplex PCR amplification products, in vitro siRNA, RNAi hairpins, preparation of DNA probes and primers and detemplating protocols.


Also encompassed by the present invention are kits comprising one or more reagents for use in the methods described herein. In one embodiment, the kit comprises a reagent that causes lysis of a cell or organism (e.g., a lysis buffer such as TRIS-HCL, detergent, sodium dodecyl sulfate, Triton X-100, EDTA) and a reagent that causes binding of nucleic acid to the solid phase carriers (e.g., a binding buffer). In a particular embodiment, the binding buffer comprises a nucleic acid precipitating reagent such as PEG, a salt such as NaI and/or solid phase carriers such as magnetic microparticles. The kit can further comprise and an agent that dissolves impurities. In one embodiment, the agent that dissolves impurities is an agent that digests protein (e.g., Proteinase K). The kit can further comprise additional buffers such as a (one or more) wash buffer (e.g., PEG, urea, NaCl, Tris-HCL) and/or an (one or more) elution buffer. In a particular embodiment, the kit comprises a lysis buffer (e.g., TRIS, detergent), a binding buffer (e.g., a nucleic acid precipitating reagent such as PEG and/or a salt such as NaI and magnetic microparticles), an agent that digests protein (e.g., Proteinase K) and a wash buffer (e.g., PEG, urea). The reagents of the kit can be present separately or one of more the reagents in the kit can be combined. Additional components that can be provided in the kit include a multisample vessel (e.g., a microtiter plate), a magnetic multisample holder (e.g., a microtiter plate holder) and a multisample transfer device (e.g., a multichannel pipette). The kit can further comprise instructions for use of the kit and its components.


EXEMPLIFICATION
Example 1
One Embodiment of a Protocol for Separation of Nucleic Acid Having a Lower Molecular Weight than Genomic Nucleic Acid in a Cell

The following protocol is illustrated in FIG. 1.


Growth of Bacterial Cultures




  • 1. Pipette 200 L of 2×YT bacterial growth media containing the appropriate antibiotic into each well of a 300 l Costar 96 well round bottom plate (Cat.# 3750).

  • 2. Innoculate each well with a single plasmid containing E. coli bacterial colony (DH10B, DH5alpha: Invitrogen). Growth cultures can be innoculated directly from agar lawns or from glyceral stocks.

  • 3. Cover the plate with a porous seal and shake vigorously (e.g., 300 rpm) at 37 C for 16 hours.


    Purification Procedure

  • 1. Add 60 L of paramagnetic lysis buffer (0.4N NaOH, 2% SDS, 0.0016% solids Agencourt COOH magnetic microparticles) solution to each well of the source plate and shake or tip mix.

  • 2. Add 60 L of Wash A solution (100% isopropanol) to the samples. Perform 15 tip mixes once the Wash A solution is added. Tip mixing conditions may vary depending on the tup orifice.

  • 3. Place source plate onto a magnetic SPRIplate96-R(TM) (cat.# Agencourt Biosciences) for 5 minutes to separate beads from solution.

  • 4. Aspirate and discard the cleared solution from the destination plate while it is situated on a SPRIplate96-R (TM) (RING Shaped magnets).

  • 5. Dispense 200 L of Wash B solution (70% ethanol) into each well of the Destination Plate as a wash solution.

  • 6. Remove ethanol wash solution and repeat step four times.

  • 7. Dry the destination plate at 37 C for 30 minutes.

  • 8. Add 40 L of elution buffer (ddH20+1.75 ng/1 RNAse A) to each well of the plate and shake. Reagent grade water is the recommended elution buffer, Vortex or shake the plate after adding elution buffer or wait 10 minutes for the elution to occur.


    Sequencing Procedure:

  • For 1/24th×BigDye reaction add:

  • 60 l of purified DNA

  • 1 l BigDye Cocktail


    BigDye Cocktail

  • 5 parts BigDye Terminator

  • 1 part 200 m M13-21 primer

  • 4 parts 15× BigDye Buffer


    Cycle Sequence

  • 95 C for 2 minutes

  • 50 cycles of (54 C for 15 seconds, 60 C for 2.5 minutes, 95 C for 5 seconds)

  • 4 C until cleanup


    Purify sequencing reactions using either standard EtOH precipitation of Agencourt CleanSeq kit (cat. # 000121 and 000222).


    Elute Precipitation of CleanSeq product in 30 l of ddH2O and place on an ABI 3700 or 3730 for sequencing detection.


    Over 11,000 reads sequences using POP5 polymer on the ABI 3700 produced 90% pass rates (passing read must average phred 20 from bp 100-300), and 625 Phred20 bases.



Example 2
Isolation of Exogenous Nucleic Acid Having a Lower Molecular Weight than Genomic Nucleic Acid in Bacterial Cells

Methods and Materials


Cloning and Purification:


Chimpanzee genomic DNA was sheared, end repaired with T4 polymerase and Klenow (NEB), and cloned in pOT bacterial vector. DH10B cells (Invitrogen) were electroporated and plated on 25 ug/ml chloramphenicol agar and grown overnight. Colonies were picked with a Gentix Qpix into 200 ul of 2×YT, 50 ug/ml Chloramphenicol broth and grown for 16 hours. The clones were purified in the growth plate on a Beckman FX robotic platform.


Purification Process


Comparing method described herein (OneStep Prep) to the method described in U.S. Pat. No. 6,534,262 (McPrep).


24 samples were purified using two different purification methods; McPrep and the single step purification method described herein. Controlled samples were loaded on an agarose gel to compare recovery (FIG. 2).


60 ul of paramagnetic lysis buffer (0.4N NaOH, 2% SDS, 160 mg/liter Seradyn COOH paramagnetic beads) in addition to 60 ul of 100% isopropanol (or 100 ul 40% PEG) was added to the cell culture and tip mixed 15 times. Samples were separated for 6 minutes on an Agencourt Magnet Plate (1000 gauss). Supernatant was removed and the separated beads were rinsed 5 times with 70% ethanol. After elution with 1.75 ng/ul RNAse A/ddH2O (Sigma), samples were run on a 96 E-Gel(Invitrogen) to estimate relative DNA recovery (FIG. 2). Pico Green Analysis (Molecular Probes) was also run on the samples and average DNA recovery was 20 ng/ul. Average conductivity of the samples were recorded to estimate any salt contamination from the growth broth by pooling all 40 ul of eluent from 10 wells. Conductivity was less than 20 us/cm.


Sequencing Reaction Setup:


Samples where eluted in 40 ul of 1.75 ng/ul RNAse/ddH2O and robotically agitated for 20 cycles of 0.5 cm at 2 Hz. 3 ul of DNA was aspirated and placed into 0.5 ul (⅓× BigDye) reagent plus 3 pmole of −21 primer. Reactions were overlayed with mineral oil and cycle sequenced in a 384 well plate. Samples were cycle sequenced according to the manufacturers recommendations. Sequencing reactions were purified with Agencourt's CleanSeq kit and eluted in 15 ul of ddH20 and heat sealed prior to loading on the ABI 3700.


Detection:


DNA sequencing Data generated using ABI3700 sequencing platform and 1/48th×BigDye V3.1 Sequencing Chemistry and POP5 polymer. Electrophoresis was performed at 5800V with a 30 second injection.


Results:


12672 sequencing reads were generated from 6336 purified samples (Table 1). The high Pass Rates, high Signal Intensity and high Average Phred 20 base pairs (Ewing et al., Genome Research, 8:175-185 (1998)) obtained are exceptional for 48 fold diluted BigDye sequencing chemistry. A histogram of the read performance is plotted in FIG. 3.



FIG. 2 shows a 96 well Agarose gel with 13 columns by 8 rows. The 13th column is 200 ng pGEM 3.2 kb vector (Promega). Positive electrode is at the bottom of the picture. Prep samples are eluted in 40 ul of various elution buffers and 10 ul loaded on the gel. One can see a 3-5 kb plasmid on the gels with no sign of E. coli genomic DNA remaining in the Agarose wells. RNA can be seen in wells that were not eluted in 1.75 ng/ul of RNAse (row F).


One can see more plasmid DNA is recovered using the single step method versus using the McPrep method (Row A vs Row B & Row C vs Row D). This is expected as the McPrep method requires E. coli genomic DNA to be bound to one set of beads and the plasmid enriched supernatant to be removed to another plate for binding to a second mixture. This supernatant removal step makes it difficult to aspirate 100% of the plasmid supernatant without disturbing the genomic DNA magnetic beads, so a loss of DNA is expected.

Row A:10 ul/40 ul McPrepRow B:10 ul/40 ul OneStep PrepRow C:10 ul/40 ul McPrepRow D:10 ul/40 ul OneStep PrepRow E & F:10 ul//40 ul OneStep with and without RNAseRow G:10 ul/40 ul McPrep without RNAse


3 ul eluted plasmid DNA was used for BigDye sequencing. Eletropherogram read quality was determined by running Phred (Ewing et al., Genome Research, 8:175-185 (1998)). Phred 30 bases have an error rate of 1 in 1000, Phred 40 bases have an error rate 1 in 10,000. Counting the number of phred 20 bases that each read produces is a standard sequencing quality metric (Table).


Pass Rate is Defined as the Number of Reads Meeting the PASS criteria/Total Reads




  • P30=Average Number of Phred 30 per 384 well plate

  • P20=Average Number of Phred 20 per 384 well plate

  • CP20=Average Number of Contiguous Phred 20 s per 384 well plate

  • P15=Average Number of Phred 15 per 384 well plate

  • Qual=Average Phred scores throughout the whole read: Averaged over 384 well plate


    PASS criteria—A read must average Phred20 quality in a 200 bp window from bp 100 to bp 300.

  • SigA=Average Relative Fluorescent Units in the A channel for the 96 reads.

  • SigG=Average Relative Fluorescent Units in the G channel for the 96 reads

  • SigC=Average Relative Fluorescent Units in the C channel for the 96 reads



SigT=Average Relative Fluorescent Units in the T channel for the 96 reads

SeqPassSigSigSigSigBarcodePassTotal%P30P20CP20P15QualLengthAGCT000048032741 (KF)35138491.4157666954070647763188134177187000028713241 (KN)36038493.7552862648267046743149118161158000028713341 (KP)34538489.845346254896634673651334650000028713641 (HK)34538489.8453862050966044744936485103000028714941 (GQ)35338491.9355263951567743741202151191208000028715041 (KF)33638487.5055565452069446754197125168186000048032841 (KF)35038491.1556865952769646754165114146162000028712941 (KN)35738492.9758868156071747778188156173197000028713041 (KH)36938496.095856705457054776894566382000028713141 (KJ)34138488.805386275216634772611379110148000028713441 (KP)34138488.80569665534703467601157598114000028713541 (KN)33938488.2852863248767746755268217295292000028713741 (GZ)34738490.3654963951567744741165117143146000028713941 (HK)34938490.8954863852267645740177121148177000028714141 (KN)35238491.674985984476434572710883113114000028714241 (KK)34738490.36548646516685467471208399127000028714441 (GY)35038491.155296215036604672713898124135000028714541 (GQ)34338489.3252562048366343738194118182184000028714641 (KF)31138480.995406384816784574714689119141000028714741 (XB)35138491.4148861237166138726170120128178000028714841 (KF)33338486.7256966652770647759205122161191000028715141 (HH)36338494.5353661850765246712191129157201000028715541 (GQ)35838493.235326195056604373111086102110000028715641 (KR)36238494.275306124956454671051456565000028712841 (HG)36138494.0153763450467544741360220335339000028714041 (KF)34938490.895426374996774574677496175000028715241 (GW)35938493.494975804626184369913267102117000028715441 (HH)34538489.84487570450610436961047081109000028715741 (KS)35438492.194645463935854567539293938000028713841 (HA)35838493.235346235076604672112696144167000028712741 (GR)32638484.904345204015614167476536473000028714341 (GR)32838485.424815704466134270499708496000028715341 (GR)33438486.9847856345560342698114698499114671267290.495316234926624573314399129145

FIG. 3 is a Histogram of the Phred 20 (red) ad Phred30 (black) bases generated by the reads. Y Axis is number of Reads, X axis is phred20 bins in 50 bp increments.


Example 3
Isolation of Nucleic Acid Having a Lower Molecular Weight than Genomic Nucleic Acid in Horse Whole Blood Cells

Materials and Methods


Source


Horse whole blood was obtained in 1:1 ratio with Alsevers anti-coagulant (2.05% dextrose, 0.5% sodium citrate, 0.055% citric acid, 0.42% sodium chloride).


Purification Process


60 ul paramagnetic lysis buffer (0.4NaOH, 2% SDS, 160 mg/liter Seradyn COOH paramagnetic beads) in addition to 80 ul of 100% isopropanol is added to the cell culture and tip mixed 15 times. Samples were separated for 15 minutes on an Agencourt Magnet Plate (1000 gauss). Supernatant was removed and the separated beads were rinsed 5 times with 70% ethanol. After elution with ddH2O (Sigma), samples were run on a 96 E-Gel (Invitrogen) to estimate relative DNA recovery (FIG. 4). Pico Green Analysis (Molecular Probes) was also run on the samples and average DNA recovery is 0.5 ng/ul (FIG. 5). DNA quality was verified in its applicability to the Polymerase Chain Reaction (PCR), a common downstream application (FIG. 6).



FIG. 4 shows GDNA duplicates prepped from 50 ul horse blood. FIG. 5 shows the PicoGreen Analysis of 8 samples prepped gDNA. FIG. 6 shows a gradient PCR of prepped GDNA above (using Y3B19 markers with an expected amplicon size of 225 bp).


Example 4
Isolation of Genomic DNA from Whole Equine Blood Using a One Step Lyse and Bind Method





    • 1. Placed 50 ul horse blood into a multi-well plate.

    • 2. Added 200 ul of Lysis Buffer (20% PEG1000, 1M NaCl, 0.5% SDS, 1% Triton X-100, 10 mM EDTA, 20 mM Tris HCl, 0.29% solids magnetic beads), mixed by pipetting 10 times. Incubated for 5 min.

    • 3. Placed on magnetic plate for about 5 min

    • 4. Removed supernatant, leaving beads behind.

    • 5. Re-suspended beads in 250 ul of Wash Buffer (6M urea/14% PEG1000, 1M NaCl). Waited for 5 minutes without magnetic stand.

    • 6. Put on magnetic stand for 5 minutes. Removed supernatant.

    • 7. Repeated steps 5 and 6.

    • 8. Re-suspended beads in 70% ethanol and magnetically separated beads three times.

    • 9. Air-dried for 5-10 minutes

    • 10. Added 50-200 ul of nuclease free water, preheated at 60-70° C. Mixed for 10 minutes.

    • 11. Placed plate on magnet plate to separate beads. Removed eluted DNA.


      Results





DNA was loaded onto a 0.8% agarose e-gel. OD 260 readings were used to determine concentration. OD 260/280 readings were used to indicate purity


Conclusions


As shown in FIG. 7, the methods described herein can be used to isolate high yield, high quality genomic DNA from whole blood.


Example 5
Isolation of Genomic DNA from Whole Porcine Blood Using a Two Step Lyse and Bind Method





    • 1. Aliquoted 200 μl fresh porcine blood into 1.2 ml 96-well plate.

    • 2. Added 2 volumes lysis buffer (0.5% SDS, 1% Triton-X-100, 10 mM EDTA, 20 mM Tris pH 7.4) and 12 μl 20 μg/μl proteinase K and gently tip mixed 5 times.

    • 3. Incubated at 37° C. for 10 minutes.

    • 4. Added 0.5 volume binding buffer (40% PEG1000, 1.5M NaCl, 0.29% solids magnetic beads) and gently tip mixed 10 times.

    • 5. Placed on magnet plate for 15 minutes.

    • 6. Removed the supernatant and discarded.

    • 7. Resuspended beads in 800 μl wash buffer (6M urea, 14% PEG 1000, 1 M NaCl) off magnet.

    • 8. Placed on magnet plate for 10 minutes.

    • 9. Discarded supernatant—repeated steps 7 and 8 for a second wash.

    • 10. On magnet, washed beads 3 times with 800 μl 70% ethanol each time, without disturbing the beads.

    • 11. After the last wash, removed all traces of ethanol. Dried beads on magnet plate for 5 minutes.

    • 12. Resuspended beads off magnet in 1 volume of nuclease free water and sat on bench for 2 minutes, then resuspended beads again.

    • 13. Placed on magnet plate for 10 minutes.

    • 14. Transferred DNA containing supernatant to clean wells for storage.


      Results





Loaded 10 uL of DNA from 9 wells on a 0.8% agarose e-gel. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity.


Conclusions


As shown in FIG. 8, the methods described herein can be used to isolate high yield, high quality genomic DNA from whole blood.


Example 6
Isolation of Genomic DNA from Whole Human Blood Using the Two Step Lyse and Bind Method





    • 1. Aliquoted 200 μl frozen human blood from three different healthy donors into 1.2 ml 96-well plate.

    • 2. Added 2 volumes lysis buffer (0.5% SDS, 1% Triton-X-100, 10 mM EDTA, 20 mM Tris pH 7.4) and 12 μl 20 μg/μl proteinase K and gently tip mixed 5 times.

    • 3. Incubated at 37° C. for 10 minutes.

    • 4. Added 0.5 volume binding buffer (40% PEG1000, 1.5M NaCl, 0.29% solids magnetic beads) and gently tip mixed 10 times.

    • 5. Placed on magnet plate for 15 minutes.

    • 6. Removed the supernatant and discarded.

    • 7. Resuspended beads in 800 μl wash buffer (6M urea, 14% PEG 1000, 1 M NaCl) off magnet.

    • 8. Placed on magnet plate for 10 minutes.

    • 9. Discarded supernatant—repeated steps 7 and 8 for a second wash.

    • 10. On magnet, washed beads 3 times with 800 μl 70% ethanol each time, without disturbing the beads.

    • 11. After the last wash, removed all traces of ethanol. Dried beads on magnet plate for 5 minutes.

    • 12. Resuspended beads off magnet in 1 volume of nuclease free water and sat on bench for 2 minutes, then resuspended beads again.

    • 13. Placed on magnet plate for 10 minutes.

    • 14. Transferred DNA containing supernatant to clean wells for storage.


      Results





Loaded 10 uL of DNA from each sample on a 0.8% agarose e-gel. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity.


Conclusions


As shown in FIG. 9, the methods described herein can be used to isolate high yield, high quality genomic DNA from whole human blood.


Example 7
Isolation of Total RNA from Cultured Cells (One Step Method)

Procedure:






    • 1. Completely removed all cell culture media from wells in a 96 well plate of cultured 293T cells (˜1×105 cells per well). Pipette Lysis Buffer (20 mM Sodium Citrate pH 7.5, 10 mM EDTA pH 8, 1 mM Aurin tricarboxylic acid, 1% triton-x-100, 2% sodium lauryl sarcosine, 1 M LiCl, 0.075% solids magnetic bead) directly on cells in each well. Mixed by pipeting repeatedly until it appears that most of the cells are off the plate and in suspension. Let sit a few minutes then pipetted a few more times to be sure all of the cells were off the plate.

    • 2. Transfered to a 1.7 ml RNase free eppendorf tube sitting in a magnet stand. Let sit for 5 minutes to separate beads from solution.

    • 3. Slowly aspirated the cleared solution from the tube and discarded.

    • 4. Washed beads one time with 1-1.5 mls 70% ethanol. Pipetted directly onto the magnetic beads and let sit 5 minutes or until supernatant appeared clear. Carefully aspirated ethanol without disturbing beads.

    • 5. Moved eppendorf off magnet and added 30 uL DNaseI solution (10 mM Tris pH 7.5, 2.5 mM MgCl2, 0.5 mM CaCl2, 0.4 U/uL DNase I).

    • 6. Pipetted until beads are back in suspension and let sit off magnet for 15 minutes to digest DNA.

    • 7. Upon completion of DNase I incubation, added 150 uL Binding Buffer (20 mM Sodium Citrate pH 7.5, 10 mM EDTA pH 8, 1 mM Aurin tricarboxylic acid, 1% triton-x-100, 2% sodium lauryl sarcosine, 1 M LiCl, 30% isopropanol) to beads/DNase I mixture and pipetted five times until mixed well.

    • 8. Placed tube back on magnet stand and let sit 5 minutes.

    • 9. Carefully aspirated supernatant.

    • 10. Added 150 ul Wash Buffer (25 mM sodium citrate, 1M guanidine hydrochloride, 1% Triton-x-100) and resuspended beads off magnet. Placed immediately back on magnet stand and let sit 5 minutes or until supernatant appeared clear.

    • 11. Carefully aspirated supernatant.

    • 12. Repeated washing with an additional four washes in 70% ethanol. Pipetted 1 ml 70% ethanol into eppendorf tube while on magnet stand, let sit for 1 minute and removed.

    • 13. After aspirating final ethanol wash let the reaction tube air-dry on magnet stand 10 minutes.

    • 14. Eluted the purified product from the beads by completely resuspending beads in 40 ul RNase Free water

    • 15. Let sit off magnet 5 minutes then placed on magnet stand for 5 minutes.

    • 16. Transferred purified RNA to a new plate.

    • 17. Loaded 12 samples from each plate onto a 0.8% agarose e-gel. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity.


      Results





RNA from 8 wells from two rows of the 96 well plate was loaded onto 0.8% agarose e-gels. FIG. 8 shows high yield, intact ribosomal RNA bands indicting good quality RNA. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity.


Conclusions


As indicated in FIG. 10, the methods described herein can be used to isolate high yield, high quality total RNA from cultured mammalian cells.


Example 8
Isolation of Total RNA from Solid Tissue





    • 1. To each well of the 96 well lysis plate added 400 ul of lysis buffer (2M guanidine isothiocyanate, 200 mM sodium citrate, 1 mM DTT, 1% triton-x-100, 1.2 mg/ml Proteinase K), one metal bead, and up to 10 mg of various rat tissues. Sealed the plate with clear plate sealing tape and attached to vortexor. Set vortexor to high and vortex plate for 10 minutes to homogenize tissue.

    • 2. Removed plate from vortexor and placed in thermocycler for 15 minutes at 50° C.

    • 3. Allowed to cool at room temp for 5 minutes.

    • 4. Added 400 ul of binding buffer (80% isopropanol, 1% magnetic beads solids) to lysate and mixed by pipetting 5 times. Incubated at room temperature for 2 minutes.

    • 5. Transferred 400 ul of binding reaction to a fresh 1.2 ml plate and placed on magnet plate for 5 minutes.

    • 6. Removed supernatant and transferred remaining 400 ul of binding reaction to 1.2 ml plate on magnet plate for 5 minutes.

    • 7. Fully removed supernatant.

    • 8. Removed plate from magnet plate and washed by adding 600 ul of 70% EtOH per well and mixed by pipetting 5 times.

    • 9. Returned plate to magnet plate for 5 minutes.

    • 10. Removed ethanol wash completely and took the plate off the magnet plate.

    • 11. Added 100 ul of DNase solution (10 mM Tris pH 7.5, 2.5 mM MgCl2, 0.5 mM CaCl2, 0.4 U/uL DNase I) mixed by pipetting 5 times and incubated at 37° C. for 15 minutes.

    • 12. Added 550 ul of re-binding buffer (1M guanidine isothiocyanate, 100 mM sodium citrate, 0.5 mM DTT, 0.5% triton-x-100, 40% isopropanol) mixed by pipetting 5 times and incubated at room temperature for 2 minutes.

    • 13. Placed plate onto magnet plate and incubated for 15 minutes.

    • 14. Removed supernatant and wash by adding 600 ul 70% EtOH and mixed by pipetting 5 times (plate on magnet).

    • 15. Repeated step 13 four more times for a total of 4 washes.

    • 16. Removed final ethanol wash completely and allow beads to dry for 10 minutes air room temperature.

    • 17. Removed plate from magnet plate and eluted RNA by adding a minimum of 40 ul of nuclease free water and mixing 10 times by pipetting. Incubated at room temperature for 2 minutes.

    • 18. Returned plate to magnet plate for 1 minute and carefully remove eluted RNA.


      Results





Analyzed 1 uL of each RNA sample by capillary electrophoresis on a Bioanalyzer 2100. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity.


Conclusion



FIG. 11 shows that the methods described herein can be used to isolate high quality total RNA from solid tissue.


Example 9
Isolation of Total RNA from Whole Blood





    • 1. In a 3-50-mL centrifuge tube, mixed 3 separate 10 mL Paxgene tube collected blood samples with 3.3 mL Lysis Buffer (4M GITC, 400 mM NaCltrate, 2% TX-100), 13.2 uL 0.5M DTT and 660 uL Proteinase K (20 mg/mL).

    • 2. Incubated for 30 min at 55° C.

    • 3. Added 6.2 mL isopropanol and 100 uL 5% solids magnetic beads to the sample. Mixed well. Incubated for 10 min at room temperature.

    • 4. Placed the tube on a magnetic stand for 30 min to magnetically separate the beads from the solution. Carefully removed the supernatant.

    • 5. Washed the beads twice with 30 mL Wash Solution (30% isopropanol, 2M GITC, 200 mM NaCltrate, 1% TX-100, 1 mM DTT).

    • 6. Washed the beads twice with 30 mL 70% ethanol.

    • 7. Air-dried the beads for 10 min.

    • 8. Resuspended the beads in 640 uL nuclease free water. Transfered to a 2-mL centrifuge tube. Incubated for 5 min at room temperature.

    • 9. Magnetically separated the beads from the supernatant on a magnetic stand. Transferred the supernatant to a 2-mL tube.

    • 10. Added to the sample 160 uL DNase I Buffer (10 mM Tris pH 7.5, 2.5 mM MgCl2, 0.5 mM CaCl2, 0.4 U/uL DNase I). Mixed by pipetting up and down.

    • 11. Incubated for 15 min at room temperature.

    • 12. Added 540 uL isopropanol, 350 uL Lysis Buffer and 10 uL fresh beads. Mixed well and incubated for 5 min at room temperature.

    • 13. Magnetically separated the beads from the supernatant. Discarded the supernatant.

    • 14. Washed the beads 3 times with 1.6 mL 70% ethanol.

    • 15. Air-dried the beads for 10 min.

    • 16. Resuspended the beads in 50 uL nuclease free water. Incubated for 5 minutes at room temperature.

    • 17. Collected the RNA and stored at −80° C.


      Results





Analyzed 1 uL of each RNA sample by capillary electrophoresis on a Bioanalyzer 2100. OD 260 readings were used to determine concentration and yield. OD 260/280 readings were used to indicate purity. Also shown is one sample analyzed on a 0.8% agarose e-gel.


Conclusion



FIG. 12 shows that the methods described herein can be used to isolate high quality total RNA from whole blood.


Example 10
Isolation of Genomic DNA from Buccal Cells Using Mouthwash Collection





    • 1. Swished mouth with 10 mls of mouthwash and collected in 50 mls conical tube.

    • 2. Centrifuged at 3000×g for 10 minutes to pellet cells.

    • 3. Discarded supernatant and resuspend cells in 400 uL resuspension buffer (10 mM Tris pH 8, 1 mM EDTA, pH 8, 1.75 ng/uL RNase A).

    • 4. Added 600 uL of lysis buffer (10 mM Trsi pH 8, 4M guanidine hydrochloride, 10% Tween-20, 1% n-lauryl sarcosine) and mixed gently.

    • 5. Incubated for 30 minutes at room temperature.

    • 6. Transfered 150 uL lysate to a new tube and combined with 150 uL binding buffer (18% PEG 8000, 2.2 M NaCl, 0.115% solids magnetic beads), tipmixed 10 times and placed on magnet to separate beads.

    • 7. Discarded supernatant and washed three times with 200 uL 70% ethanol.

    • 8. Dried beads for 5 minutes.

    • 9. Added 40 uL water, tipmixed 10 times and placed on magnet to separate.

    • 10. Removed DNA containing supernatant.


      Results





Isolated genomic DNA was analyzed by agarose gel electrophoresis on a 0.8% e-gel. The average yield was 1.8 ug per prep, but varied significantly from subject to subject. One 1 uL of each sample was used in PCR with human ADP ribosylation factor 1 primers yielding a 543 bp product.


Conclusion



FIG. 13 shows that the methods described herein can be used to isolate high quality, high yield GDNA from Buccal cells using a mouthwash collection protocol. The gDNA is functional in downstream PCR analysis.


Example 11
Isolation of Genomic DNA from Buccal Cells Using Swab Collection





    • 1. Swabbed inside cheek 20 times with a sterile swab.

    • 2. Placed swab in 200 uL of resuspension buffer (10 mM Tris pH 8, 1 mM EDTA, pH 8, 1.75 ng/uL RNase A) and rotated 10 times to release cells.

    • 3. Added 300 uL of lysis buffer (10 mM Trsi pH 8, 4M guanidine hydrochloride, 10% Tween-20, 1% n-lauryl sarcosine) and rotated swab 10 times to mix. Pressed swab against top of tube to release any liquid from the fibers.

    • 4. Incubated 15 minutes at room temperature.

    • 5. Transfered 150 uL lysate to a new tube and combined with 150 uL binding buffer (18% PEG 8000, 2.2 M NaCl, 0.115% solids magnetic beads), tipmixed 10 times and placed on magnet to separate beads.

    • 6. Discarded supernatant and washed three times with 200 uL 70% ethanol.

    • 7. Dried beads for 5 minutes.

    • 8. Added 40 uL water, tipmixed10 times and placed on magnet to separate.

    • 9. Removed DNA containing supernatant.


      Results





Isolated genomic DNA was analyzed by agarose gel electrophoresis on a 0.8% e-gel. The average yield was 1.8 ug per prep, but varied significantly from subject to subject. One 1 uL of each sample was used in PCR with human cytoskeletal β-actin primers yielding a 370 bp product.


Conclusions



FIG. 14 shows that the methods described herein can be used to isolate high quality, high yield GDNA from Buccal cells using a swab collection protocol. The GDNA is functional in downstream PCR analysis.


Example 12
Isolation and Detection of Viral Genomic DNA





    • 1. Added 147 uL Lysis Buffer (4M GITC, 400 mM NaCltrate, 2% TX-100), 0.5 uL PolyA RNA (10 ug/uL) and 40 uL Proteinase K (20 mg/mL) to 400 uL human plasma containing HBV at 50 copies/mL. Mixed by pipetting up and down at least 15 times.

    • 2. Incubated the samples at 56° C. for 30 min.

    • 3. Let plate cool to room temperature. Added 260 uL 100% isopropanol and 10 ul 5% solids magnetic beads. Mix by pipetting up and down at least 15 times.

    • 4. Transferred half of the sample (˜430 uL) to a new well. Let the plate sit on the bench for 5 min.

    • 5. Placed the plate on a plate magnet for at least 7 min to separate.

    • 6. Aspirated off the supernatant.

    • 7. Removed the plate from the magnet. Added 500 uL Wash Buffer (30% isopropanol, 2M GITC, 200 mM NaCltrate, 1% TX-100, 1 mM DTT) and pipette mixed 10 times.

    • 8. Let the plate sit on the bench for 5 min. Placed the plate back on the magnet for 7 min. Aspirated off the supernatant.

    • 9. Repeated wash steps 7-8 two more times.

    • 10. Removed the plate from the magnet. Added 500 uL 70% ethanol and resuspended the beads by pipette mixing.

    • 11. Placed the plate back on the magnet for 7 min. Aspirated off the supernatant.

    • 12. Repeated ethanol wash steps 10-11 two more times. Removed as much of the ethanol as possible after the third wash.

    • 13. Let the plate sit on the magnet for 20 min to dry the beads.

    • 14. Took the plate off the magnet. Added 20 uL nuclease free water, pipette mixed and incubated for 5 min.

    • 15. Placed the plate back on the magnet. Transferred the supernatant to a clean tube.


      Results





Used 10 ul of each sample in a 50-ul PCR reaction with HBV specific primers. Mock extraction sof plasma containing no HBV were negative, while all 16 samples containing HBV were positive.


Conclusion



FIG. 15 shows that the methods described herein can be used to isolate and detect genomic DNA from a virus at a very low copy number.


Example 13
Isolation of Genomic DNA from Paraffin Embedded Samples

Tissue Digestion:






    • 1. From 2-20 mg paraffin embedded tissue blocks, cut tissue into thin (10 um) sections and placed in a 1.5 ml tube. Closed the cap and tapped the tube on the bench until the tissue samples dropped to the bottom of the tube.

    • 2. Added 100 ul of de-cross-linking buffer (50 mM HEPES buffer, pH7.9, 1% Ammonium hydroxide) and incubated at 70° C. for 1 hour.

    • 3. Added 100 ul of lysis buffer (50 mM HEPES, pH7.9, 1% SDS, 1 mM EDTA) with 20 ul of 20 mg/ml of protease K.

    • 4. Digested the tissue at 55 C for 1 hour


      DNA Extraction:

    • 1. To a tube containing 200 ul of digested tissue, added binding buffer (200 ul 4M GITC, 400 mM NaCltrate (pH 7.0), 2% Triton X-100; 6 ul 5% solids magnetic beads; 200 ul isopropanol).

    • 2. Mixed and incubated at room temperature for 1 minute.

    • 3. Placed the tube on a magnet stand for 1 minute.

    • 4. Discarded the supernatant.

    • 5. Resuspended the beads in 300 ul of Wash Buffer (2 M GITC, 200 mM Na Citrate, 1% TX-100 and 30% isopropanol), incubated at room temperature for 1 minute.

    • 6. Placed on magnet stand for 1 minute. Discarded the supernatant.

    • 7. Repeated step 6 and step 7.

    • 8. Resuspended beads in 200 ul of 70% ethanol. Incubated at room temperature for 1 minute.

    • 9. Discarded supernatant.

    • 10. Repeated step 9 and step 10 twice.

    • 11. Air dried the beads for 10-15 minutes.

    • 12. Resuspended the beads in 50 ul of water, left at room temperature for 1 minute.

    • 13. Placed tube on magnet stand for 1 minute.

    • 14. Transfered DNA elute into a fresh tube.


      Results





Loaded 20 ul of the DNA on a 0.8% agarose gel. The DNA yield was 1.5-3 ug from 20 mg of tissue. (Upper Gel) Lane 1 and 2 show a typical pattern of DNA which has been isolated from tissue fixed in paraffin. (Lower gel) Gene specific PCR amplification from the two extracted samples (lanes 1 and 2), no template control (lane 3) and positive control DNA (lane 4).


Conclusion


As shown in FIG. 16 the methods described herein can be used to isolate genomic DNA from paraffin embedded tissue sections of sufficient quality to function in downstream PCR amplification.


While this invention has been particularly shown and described with references to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.

Claims
  • 1. A method of separating genomic nucleic acid of a cell from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell comprising: a) combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell and iii) a reagent, wherein the reagent causes lysis of the cell and precipitation of the nucleic acid of the cell onto the solid phase carriers;  thereby producing a combination; b) maintaining the combination under conditions in which lysis of the cell occurs and the nucleic acid of the cell binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell bound thereto; c) separating the solid phase carriers from the combination; d) contacting the solid phase carriers with an elution buffer that causes elution of the nucleic acid having a lower molecular weight than the genomic nucleic acid from the solid phase carriers, thereby separating genomic nucleic acid of the cell from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell.
  • 2. The method of claim 1 wherein the nucleic acid having a lower molecular weight is selected from the group consisting of: plasmid DNA, episomal DNA, mitochondrial DNA, organelle DNA, and viral DNA.
  • 3. The method of claim 1 wherein the solid phase carriers magnetic microparticles.
  • 4. The method of claim 3 wherein the magnetic microparticles have a coated surface wherein the coated surface is selected from the group consisting of: a carboxyl group coated surface and amine group coated surface.
  • 5. The method of claim 1 wherein the reagent comprises an alcohol.
  • 6. The method of claim 5 wherein the alcohol is selected from the group consisting of: ethanol, isopropanol and polyalkylene glycol.
  • 7. The method of claim 5 wherein the reagent further comprises a salt.
  • 8. The method of claim 7 wherein the salt is selected from the group consisting of: NaCl, LiCl and MgCl2.
  • 9. The method of claim 1 wherein elution buffer comprises water.
  • 10. The method of claim 9 wherein the elution buffer further comprises RNAse.
  • 11. The method of claim 1 wherein the solid phase carriers are separated from the combination using a method selected from the group consisting of: applying a magnetic field, applying vacuum filtration and applying centrifugation.
  • 12. A method of separating genomic nucleic acid of a cell from plasmid nucleic acid of the cell comprising: a) combining i) magnetic microparticles whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell and iii) a reagent, wherein the reagent causes lysis of the cell and precipitation of nucleic acid of the cell onto the magnetic microparticles;  thereby producing a combination; b) maintaining the combination under conditions in which lysis of the cell occurs and the nucleic acid of the cell binds reversibly to the magnetic microparticles, thereby producing magnetic microparticles having nucleic acid of the cell bound thereto; c) separating the magnetic microparticles having nucleic acid of the cell bound thereto from the combination; d) contacting the magnetic microparticles with an elution buffer that causes elution of the plasmid nucleic acid from the magnetic microparticles, thereby separating genomic nucleic acid of the cell from nucleic acid having a lower molecular weight in the cell.
  • 13. The method of claim 12 wherein the magnetic microparticles have a coated surface wherein the coated surface is selected from the group consisting of: a carboxyl group coated surface and amine group coated surface.
  • 14. The method of claim 12 wherein the reagent comprises an alcohol.
  • 15. The method of claim 14 wherein the alcohol is selected from the group consisting of: ethanol, isopropanol and polyalkylene glycol.
  • 16. The method of claim 14 wherein the reagent further comprises a salt.
  • 17. The method of claim 16 wherein the salt is selected from the group consisting of: NaCl, LiCl and MgCl2.
  • 18. The method of claim 12 wherein the elution buffer comprises water.
  • 19. The method of claim 18 wherein the elution buffer further comprises RNAse.
  • 20. The method of claim 12 wherein the magnetic microparticles are separated from the combination using a method selected from the group consisting of: applying a magnetic field, applying vacuum filtration and applying centrifugation.
  • 21. A method of separating genomic nucleic acid of a cell from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell comprising: a) combining i) solid phase carriers whose surfaces have bound thereto a functional group which reversibly binds nucleic acid, ii) a cell lysate and iii) a reagent, wherein the reagent causes precipitation of the nucleic acid of the cell lysate onto the solid phase carriers;  thereby producing a combination; b) maintaining the combination under conditions in which the nucleic acid of the cell lysate binds reversibly to the solid phase carriers, thereby producing solid phase carriers having nucleic acid of the cell bound thereto; c) separating the solid phase carriers from the combination; d) contacting the solid phase carriers with an elution buffer that causes elution of the nucleic acid having a lower molecular weight than the genomic nucleic acid from the solid phase carriers, thereby separating genomic nucleic acid of the cell from nucleic acid having a molecular weight that is lower than the molecular weight of the genomic nucleic acid in the cell.
  • 22. The method of claim 21 wherein the nucleic acid having a lower molecular weight is selected from the group consisting of: plasmid DNA, episomal DNA, mitochondrial DNA, organelle DNA and viral DNA.
  • 23. The method of claim 21 wherein the solid phase carriers are magnetic microparticle.
  • 24. The method of claim 23 wherein the magnetic microparticles have a coated surface wherein the coated surface is selected from the group consisting of: a carboxyl group coated surface and amine group coated surface.
  • 25. The method of claim 21 wherein the reagent comprises an alcohol.
  • 26. The method of claim 25 wherein the alcohol is selected from the group consisting of: ethanol, isopropanol and polyalkylene glycol.
  • 27. The method of claim 25 wherein the reagent further comprises a salt.
  • 28. The method of claim 27 wherein the salt is selected from the group consisting of: NaCl, LiCl and MgCl2.
  • 29. The method of claim 21 wherein elution buffer comprises water.
  • 30. The method of claim 29 wherein the elution buffer further comprises RNAse.
  • 31. The method of claim 21 wherein the solid phase carriers are separated from the combination using a method selected from the group consisting of: applying a magnetic field, applying vacuum filtration and applying centrifugation.
  • 32. The method of claim 21 wherein the cell is selected from the group consisting of: a bacterial cell, a viral cell and a mammalian cell.
  • 33. The method of claim 21 wherein the mammalian cell is a whole blood cell.
  • 34. A kit comprising a lysis buffer, a binding buffer, an agent that removes impurities and a wash buffer.
  • 35. The kit of claim 34 wherein the lysis buffer comprises sodium dodecyl sulfate, Triton X-100, EDTA and Tris-HCl.
  • 36. The kit of claim 34 wherein the binding buffer comprises magnetic microparticles, polyethylene glycol and sodium iodide.
  • 37. The kit of claim 34 wherein the agent that removes impurities is an agent that digests protein
  • 38. The kit of claim 37 wherein the agent that digests protein is proteinase K.
  • 39. The kit of claim 34 wherein the wash buffer comprises polyethylene glycol and urea.
  • 40. A kit comprising: a) a lysis buffer comprising sodium dodecyl sulfate, Triton X-100, EDTA and Tris; b) a binding buffer comprising magnetic microparticles, polyethylene glycol and sodium iodide; c) proteinase K; and d) a wash buffer comprising polyethylene glycol and urea.
RELATED APPLICATIONS

This application is a continuation-in-part of U.S. application Ser. No. 10/406,141, filed Apr. 2, 2003 and is a continuation-in-part of International Application No. PCT/US2004/009960, which designated the United States, was filed Apr. 1, 2004, and was published in English. The entire teachings of the above application(s) are incorporated herein by reference.

Continuation in Parts (2)
Number Date Country
Parent 10406141 Apr 2003 US
Child 11231363 Sep 2005 US
Parent PCT/US04/09960 Apr 2004 US
Child 11231363 Sep 2005 US