This invention relates to determining the presence and/or abundance of mutant (Mutant) nucleic acids in a sample of interest.
Mitochondria are cytoplasmic organelles distributed in animal cells whose principal function is to generate energy-rich ATP molecules necessary for driving cellular biochemical processes. Mitochondria contain their own DNA that is separate and distinct from chromosomal DNA. Mitochondrial DNA (“mt-DNA”) encodes exclusively for a number of critical protein subunits of the electron transport chain and the structural rRNAs and tRNAs necessary for the expression of these proteins. Unlike chromosomal DNA, each cell can contain 100,000 copies or more of mt-DNA. Cells can harbor mixtures of wild-type and mutant mt-DNA (heteroplasmy). Mitochondrial genes are dynamic and the mt-DNA genotype can drift towards increased mt-DNA mutational burden in heteroplasmic cellular populations. The metabolic phenotype can deteriorate with time under these conditions, and can result in disease manifestation once the mutational burden exceeds a critical threshold in affected tissue, leading to bioenergetic failure and eventually cell death.
Mitochondrial disorders are particularly problematic in organs such as the heart and the brain, the two organs with the highest metabolic requirements for energy and the highest abundance of mitochondria (mt). ATP synthesis requires oxygen (“oxidative phosphorylation”); hence, acute hypoxia can be especially damaging to these tissues. Periods of hypoxia followed by resupply of oxygen can cause the release of oxygen-derived free radicals; these radicals can damage DNA (perfusion/reperfusion injury). Such radicals are generated in abundance by the mitochondrial cytochromes, located in close proximity to the mitochondrial genome. Moreover, since mitochondria are derived from primitive bacteria they lack the more advanced repair mechanisms found in the mammalian nucleus. For both reasons mitochondrial DNA undergoes higher mutation rates than the nuclear genome.
The activities of enzymes associated with oxidative phosphorylation (OXPHOS) have been shown to decline with age in human and primate muscle, liver, and brain. This is paralleled by an age-related increase in heart and skeletal muscle fiber focal cytochrome oxidase (COX) deficiency, with the COX-negative regions containing clonal expansions of individual mt-DNA rearrangements. It is also correlated with the accumulation of a variety of somatic mt-DNA mutations, including various deletions and base substitutions. The extent of mt-DNA damage that accumulates in various tissue is correlated with those tissues most prone to age-related dysfunction. Thus the basal ganglia accumulates the highest levels of mt-DNA damage, followed by the various cortical regions. Yet the cerebellum remains relatively free of mt-DNA damage throughout life. This suggests that the accumulation of somatic mt-DNA mutations may be an important factor in the age-related decline of somatic tissues.
As somatic mutations accumulate they could exacerbate inherited OXPHOS defects until the combined defect is sufficient to result in energetic failure of the tissues. Three late-onset progressive diseases associated with an increased frequency of somatic mt DNA mutations are: i) late-onset (>69 years) mitochondrial myopathy involving insidious proximal muscle (limb-girdle) weakness with fatigability; ii) inclusion body myositis involving late-onset chronic inflammatory muscle disease resulting in muscle weakness; and, iii) polymyalgia rheumatica associated with inflammatory stiffness and pain in the scapular and pelvic girdles. OXPHOS defects have also been reported in Huntington's Disease (HD), dystonia, and Alzheimer's Disease (AD). Somatic mt-DNA mutations have been reported to be elevated in sun-exposed skin, certain types of cardiomyopathy, livers of alcoholics, ovaries of post-menopausal women, and reduced mobility sperm.
Many mutations to mt-DNA are well known and characterized. Recently, large (kb long) mt-DNA genomic deletions have been found in cases involving certain ischemic heart diseases, cardiomyopathies, and myoclonic epilepsy. So-called “long” PCR has been the method of choice for unveiling such mutations. In this technique, the entire mitochondrial genome of damaged or affected tissue is amplified. This full-length mt-DNA is then sequenced and compared with the known sequence of intact human mt-genome to identify the missing nucleotide sequences.
While useful as a research tool, long PCR is not an efficient clinical method in this context. Moreover, a clinically useful method must minimize amplification or signaling attributable to nuclear pseudogenes. These are nucleic acid sequences similar to mt-DNA sequences that have been incorporated into the DNA of the nucleus. Additionally, long-PCR is tedious requiring highly specialized laboratory skills. If not carefully practiced, long-PCR can readily produce false negative results.
Other methods for characterizing particular aspects of DNA molecules are known as well. For example, U.S. Pat. No. 5,436,142 to Wigler proposes a method for producing probes for distinguishing different DNA molecules of similar origin. In this method, DNA molecules from two different but related sources are cleaved with restriction enzymes. The restriction fragments are amplified. Both sets of amplicons are then mixed together, melted, annealed and amplified. This is done with an excess of the amplicons originating from the DNA missing a particular sequence (the “target”). The product of this process is an enriched DNA molecule containing the target. These molecules can then be used to prepare probes for polymorphism sequences that are complementary to the target.
U.S. Pat. No. 5,919,623 to Taylor proposes the intentional construction of a heteroduplex DNA using restriction fragments of different DNAs, one of which is suspected of having a sequence of interest. The heteroduplex so obtained contains a mismatch. This mismatch can then be identified using a mismatch repair protein that binds to the mismatch site. Similarly, U.S. Pat. No. 6,110,684 to Kember employs a resolvase to detect mismatches. U.S. Pat. No. 5,391,480 to Davis also identifies the presence of a sequence of interest through the creation of a mismatch. In this case an exonuclease is used to cleave a label at the site of the mismatch if a mismatch is found. U.S. Pat. No. 5,958,692 to Cotton is yet another patent directed to the detection of heteroduplex mismatches. The method employs a resolvase system that cleaves cruciform DNA molecules. Experimental results in the patent indicated that the method was unable to detect three out of the four mutations that were deletion sequence mutations. It does not correlate amplification with the lack of a sequence. U.S. Pat. No. 5,876,941 to Landegren is similar to the Cotton patent in many respects.
U.S. Pat. No. 6,001,567 to Brow proposes the use of a modified DNA polymerase to identify target DNA sequences. The polymerase is modified so that it retains 5′ exonuclease activity but no longer has any synthetic ability. Nucleic acid segments are crafted so that they contain sequences that will flank the target sequence. One such segment contains a 5′ arm that is subject to attack and cleavage by the modified polymerase when a specific portion of the remainder of the DNA molecule to which it is attached binds to the target sequence. Cleavage of the 5′ arm initiates a signaling process indicting the presence of the target sequence. In this case, the agent responsible for locating the target sequence is the nucleic acid that is subject to cleavage. The modified DNA polymerase has no direct role in locating the target sequence.
U.S. Pat. No. 6,017,701 to Sorge proposes a method for preferentially amplifying nucleic acids having certain discrete sequences. In this method, nucleic acids are modified with adapters that also serve as primers for amplification. The adapters that bind to nucleic acids that do not have the sequences that are to be enriched also have sequences that are subject to attack by restriction enzymes. Thus, nucleic acids that lack the sequences of interest cannot be amplified while those that have such sequences are amplified. The patent does not propose the amplification of nucleic acids that are mutant such that they lack certain sequences. Further, distinguishing nucleic acids based on whether or not a given sequence is present does not occur until priming has already occurred.
WO 9632500 to Todd proposes a method of detecting a genetic polymorphism in an individual. This is done by PCR amplifying the sample using primers selected so that they introduce into the wild type amplicon a site cleaved by a restriction enzyme, so that this wild type DNA is not amplified. This Restriction Endonuclease Mediated PCR permits the selective enrichment of the mutant DNA present in a large excess of wild type DNA.
Most of the techniques previously described apply primarily to the detection of point or short mutations. Detecting deletions is particularly arduous in that they are sequences that are missing in the mutant molecule. Essentially, one is trying to detect a small fraction of DNA that is missing a sequence in the presence of a large excess of wild type DNA that contains that sequence. Yet diagnostics are necessary where a low level of the deletions may be clinically relevant. Thus, commercially available diagnostics for identifying such mutations should be sensitive, specific, robust and quantitative. Although sequencing has been used by others to establish the clinical relevance of these deletions, sequencing per se is too complex for commercial diagnostics.
The invention is a method for determining the presence of mutations in nucleic acids. More particularly, the mutations are deletions. In this method, a sample having nucleic acid present is contacted with mutant PCR primers under short PCR conditions. The nucleic acid that has been contacted with this material is then amplified and identified. Nucleic acids having long sequences between the sequences that hybridize to the mutant PCR primers (such as wild type DNA) are not amplified. Thus, the presence of amplicons indicates the presence of nucleic acid sequences having sequences deleted from the wildtype nucleic acid.
In another aspect of the invention, a sample having nucleic acid present is contacted with a cleavage reagent. The nucleic acid that has been contacted with this material is then amplified and identified. Nucleic acids that do not have the sequence that the material attacks are not cleaved and are therefore amplified under the correct amplifying conditions. Wild type nucleic acids having the sequence that the material attacks, are cleaved, and are not amplified by the mutant primers that flank the cleavage point.
The cleavage reagents include, for example, a restriction enzyme specific for the deletion sequence, a DNAzyme, Ribozyme or other material with requisite specificity.
In one embodiment of the invention the nucleic acid subjected to this method is mitochondrial DNA (mt-DNA).
In another embodiment of this invention, the method includes the step of preparing multiple aliquots of sample. One aliquot is amplified to detect the presence of nucleic acid having deletions and the other is amplified to detect the presence of wild type nucleic acid. The amplicons from this process are useful as a positive control. In a further embodiment of the invention, the method is quantitated by comparing the quantity of the mutant nucleic acid with the quantity of the nonmutant nucleic acid.
In another embodiment of the invention, molecules useful as primers and probes for conducting the methods described above are provided.
In yet another embodiment of the invention, a kit is provided that includes amplification reagents. Kits are also provided that contain cleavage reagents.
The inventions described in this specification are useful in commercial clinical diagnostic applications.
Definitions:
“Wildtype (wt) nucleic acid sequence” is the nucleic acid sequence that is considered the standard for the organism with respect to genotype and phenotype. It is the sequence that is most prevalent for a given gene or coding segment for the organism as it is seen in the wild. In the context of this specification, the term refers to a segment of nucleic acid that is not mutated with deletions of long sequences of bases.
“Mutant nucleic acid sequence” is a nucleic acid sequence that deviates from the wildtype sequence. Deletion sequences are thus mutants according to this view since they deviate from the wildtype sequence.
“Nucleic acid deletion sequence” is a nucleotide sequence or segment that is present in a wildtype nucleic acid sequence for an organism and whose absence in a nucleic acid segment of interest for a given individual or group constitutes a mutation. That is, the absence of the sequence makes the nucleic acid segment a mutant nucleic acid sequence. Generally, such mutations can be manifested within an individual in a clinically significant way such as with an illness or a predisposition to illness.
“Cleavage reagents” are materials that when contacted with nucleic acids cut them at a particular site or sites. Restriction enzymes are the most preferred cleavage reagents but DNAzymes and other reagents that degrade or attack the nucleic acid at a particular site can also be used (provided they do not also degrade the mutant DNA or otherwise render it incapable of amplification). In the kits and methods of this invention, the cleavage reagents shear, degrade, and/or attack a nucleic acid having a known nucleic acid deletion sequence. For example, an assay for the detection of a Mutant mt-DNA missing a certain 5 kb deletion sequence would include cleavage reagents that cleave wt mt-DNA at one or more points within the deletion sequence or as a result of having the deletion sequence so as to prevent amplification of the wild type sequence when mutant primers are used in the amplification.
“Cleave” and “cleavage” as the terms are used in relation to the use of cleavage reagents refers to a process by which a nucleic acid is rendered incapable of amplification when the cleavage point is flanked by a forward and a reverse priming site, as is the case here for the primers used for detecting deletion sequences.
“Short PCR” or “sPCR” means amplification via the polymerase chain reaction (PCR) wherein the sequences that are amplified are less than about 1 kb, preferably 500 bases or less, and most preferably 300 bases or shorter. Short PCR can be ensured by the practice of PCR under certain conditions described in detail below.
“Long PCR” means amplification via the polymerase chain reaction (PCR) wherein the sequences that are amplified are greater than about 5 kb. Long PCR involves the practice of PCR under certain conditions described in detail below.
“Primer”, as the term is used throughout this specification has its ordinary meaning within the context of PCR technology.
“mutant PCR Primers” means primers made to hybridize to primer sites on complementary nucleic acid sequences that are no less than 1 kb apart for the wild type DNA.
“wild type PCR Primers” means primers made to hybridize to primer sites on complementary nucleic acid sequences that are no greater than 1 kb apart for the wild type DNA.
Assay Targets
The targets of the assays of this invention are nucleic acids suspected of having mutations comprising deletions of no less than 4 kb. Preferably the targets are suspected of having deletions of about 4 kb to about 10 kb. Most preferably, the targets are suspected of having deletions of about 5 kb to about 7 kb.
While the nucleic acids that are assayed according to this invention may be of any origin, mt-DNA is particularly amenable to the methods of this invention given its high mutation rate, the number and type of known prominent deletions, and the clinical significance of the quantitation of mt-DNA. Moreover, the length of the mt-DNA genome and the nature of the distribution of deletions in mutant mt-DNA make it an excellent analyte for the assays of this invention. The mt-DNA of the preferred embodiments can come from any source of human mt-DNA including whole blood and tissues (such as placental sample).
mt-DNA suspected of having the following deletions are preferred analytes (c.f. www.gen.emory.edu/mitomap; the Emory University website on mt-DNA):
Note: terminology adopted in Table 1 is the same as that adopted in MITOMAP (see below):
MITOMAP: Mitochondrial DNA Function Locations
“D-Loop” in this database refers to the non-coding region between Proline and Phenylalanine (np16024-576)
Locus names are the official designations delineated by the given nucleotide numbers. The map positions correspond to the nucleotide pair (np) numbers determined from the DNA sequence. The map symbols are used to indicate the position of the locus on the map.
Notes further define each locus: TAS=termination associated sequence, CSB=conserved sequence block, mtTF1=mitochondrial transcription factor, Y=either pyrimidine, N=any base. H-strand replication origin positions have been identified at np 110, 147, 169, 191, 219, 310, 441. L-strand promoter positions have been identified at np 407, 392-435. H-strand promoter positions have been identified at np 559 1, 561. L-strand replication origin positions have been identified at np 5721-5781, 5761, 5799.
Sample Preparation
Well known methods for obtaining nucleic acids from a variety of sources (preferably human mt-DNA) can be used to obtain and isolate nucleic acids for use in the methods of this invention. For example, the DNA from a blood sample may be obtained by cell lysis following alkali treatment. Total nucleic acid can be obtained by lysis of white blood cells resuspended in water by incubation of cells in a boiling water bath for about 10 minutes. After cooling, cellular debris is removed, such as by centrifugation at about 14,000 g for about two minutes. The clear supernatant, which contains the DNA, may be stored frozen, e.g., at about −80.degree. C.
Where the target is mt-DNA, the conventional proteinase K/phenol-chloroform methods of isolating DNA are not preferred nor are other conventional methods of DNA isolation. Instead, the boiling method described above is preferred. This is described more fully in U.S. Pat. No. 6,027,883 to Herrnstadt and incorporated herein by reference. The contamination of samples by nuclear DNA can be eliminated by purifying the isolated mt-DNA on a CsCl gradient prior to PCR amplification. This is particularly preferred where the nuclear DNA is believed to contain pseudogenes (nucleic acid segments incorporated within nuclear DNA that appear to be the same as or very similar to sequences of mt-DNA). This will help ensure that nuclear DNA is not inadvertently amplified or otherwise acted upon in a way that would interfere with reactions involving the target mt-DNA. It is also worth noting that any procedure for decreasing nuclear DNA contamination of mt-DNA samples intended for PCR amplification can be compromised if the primers selected favor the nuclear sequence. Thus, the judicious use of primers is also important in this regard and is discussed more fully below.
Commercially available kits for extracting and purifying mt-DNA are available and can also be used to good effect in the practice of this invention. For example, the alkaline lysis miniprep procedure is a simpler technique for the purification of mt-DNA. This technique is used through the application of the “WIZARD MINIPREPS DNA PURIFICATION SYSTEM” (commercially available from Promega Corp.). Numerous other mt-DNA extraction kits are readily available from companies such as Qiagen Corporation of Germany (preferred for blood samples) and Waco Corportion of Japan (preferred for tissue).
Amplification and Reagents
The methods of this invention all employ PCR. The preferred methods of this invention employ short PCR protocols (“short PCR”). So-called “Long PCR” is not used. This ensures that wild type sequences of the size and type described herein are not amplified and hence falsely reported.
Hybridizing conditions should enable the binding of primers to the single nucleic acid target strand. As is known in the art, the primers are selected so that their relative positions along a duplex sequence are such that an extension product synthesized from one primer, when the extension product is separated from its template (complement) serves as a template for the extension of the other primer to yield a replicate chain of defined length.
With this in mind, the reagents employed in the methods and kits of this invention include the following components.
Methods of the Invention
Practicing the methods of the invention requires the isolation of a nucleic acid from a sample of interest, preferably mt-DNA. Each strand of the DNA molecule can be characterized as having an upstream zone, a downstream zone and a sequence between the upstream zone and the downstream zone (which sequence is deleted in mutant DNA). In wild type DNA, the deletion sequence can be cleaved in the presence of a cleavage reagent. Mutant DNA can be characterized as having an upstream zone and a downstream zone but, as noted above, lacks the deletion sequence found in wild type DNA. Thus, the presence of the cleavage reagent directed to such a deletion sequence found only in the wild type DNA has no cleaving effect on mutant DNA.
In one embodiment of this invention (preferably, where the target is mutant DNA with a 5 kb deletion), the nucleic acid sample that has been isolated is divided into a first aliquot and a second aliquot. The first aliquot is contacted with a cleavage reagent, thereby forming a mixture. The mixture contains cleaved wild type DNA that cannot be amplified if mutant primers flanking the cut are used. However, if mutant DNA having the deletion is present, uncleaved mutant DNA can be amplified. This mixture is contacted with a forward primer specific for a portion of the upstream zone common to both mutant DNA and wild type DNA. To this mixture is added a reverse primer complementary to the downstream zone of the mutant DNA and each of four different nucleoside triphosphates as well as a DNA polymerase, under conditions such that only the mutant DNA is amplified.
The second aliquot is also contacted with a forward primer specific for a portion of the upstream zone of both DNA molecules and a reverse primer specific for a portion of the deletion sequence of the wild type DNA molecule. It is also contacted with four different nucleoside triphosphates and a DNA polymerase. This is conducted under conditions such that the DNA is amplified. Since no cleavage reagent is added, and since the sequence separating the priming site is short, wild type DNA that can hybridize to the primers will be amplified irrespective of the presence of deletion sequences. But mutant DNA molecules lack a reverse priming site complementary to this reverse primer, its site being located within the deletion sequence. The mutant DNA thus remains un-amplified. Therefore, only the wild type DNA is amplified. Accordingly, the second aliquot can serve as a positive control for the wild type DNA.
The aliquots are amplified in the presence of an appropriate signal reagent directed to detecting amplified species. More than one signal reagent may be used to indicate the presence of both the wild type DNA in the control and the mutant DNA in the first aliquot. This is readily done, for example, using molecular beacons with different fluorophors bound to beacons that are complimentary to either the deletion sequence or, for example, the sequence at the interface of the mutant DNA segments that are spliced together where the deletion sequence would otherwise be.
In another embodiment of the invention, a sample is prepared that is suspected of comprising:
The sample is divided into two aliquots. One aliquot is contacted with a cleavage reagent, specific for the cleavage site(s) of the deletion sequence, thereby forming a mixture of cleaved and uncleaved DNA molecules. The cleaved DNA molecules should not amplify in subsequent steps when mutant primers are used. The mixture of cleaved and uncleaved DNA molecules is contacted with a forward primer specific for a portion of the upstream zone of both the wild type DNA and the mutant DNA molecules; and a reverse primer specific for the downstream zone of the mutant DNA molecule. To this mixture is added four different nucleoside triphosphates, and a DNA polymerase, under short PCR conditions such that only the mutant DNA is amplified. Most, if not all, of the wild type DNA molecules will have been cleaved by the cleavage reagents thereby rendering them incapable of amplification when the primers for the mutant sequence are used (in the event that any wild type DNA escaped cleavage, they would also be incapable of amplification due to the inability to bridge the distance between priming sites using short PCR techniques according to the process of this invention). A probe specific for a sequence within the amplified portion of the mutant DNA molecules is added. This probe is labeled or capable of being labeled.
The second aliquot (in the absence of a cleavage reagent) is contacted with a forward primer specific for a portion of the upstream zone of both the wild type DNA molecule and the upstream zone of mutant DNA molecule and a reverse primer directed to a site within the deletion sequence of the wild type DNA, four different nucleoside triphosphates and a DNA polymerase, under conditions such that the wild type DNA is amplified. A probe specific for a sequence of the deletion sequence of the sense or antisense wild type DNA molecules is added. This probe is labeled or is capable of being labeled, preferably in a different manner than that of the probe in the case of the first aliquot.
The labels of each probe are then detected as cycling proceeds as a measure of the presence or amount of each type of DNA.
The deletion sequence should be sufficiently long (preferably, greater than 1 kb) that it is not readily amplifiable using primers specific for the termini under the short PCR conditions employed in the process of this invention. The reverse primer for the mutant sequence is chosen to be sufficiently distant from the forward primer that even if some wt material survives restriction the wt sequence will not be amplified.
The drawings further illustrate the practice of this invention. In
In
As a check on the presence of amplifiable DNA and as a control to ensure that amplification can occur, primers and probes appropriate for a conserved DNA sequence can be added to the contents of either or both the wild type and mutant aliquots. Thus amplification can involve co-amplification of this conserved region with either the wild type sequence (in the case of the wild type aliquot), or the mutant sequence (in the case of the mutant aliquot).
In the most preferred embodiments of this invention, reaction conditions are further controlled to minimize mis-priming that can result in the production and amplification of side products. These conditions are described by way of example in Example 7 and Example 8. In one of the methods, illustrated in Example 8, the thermal profile can be modified to include very stringent conditions initially. They are followed by less stringent cycles during which beacons are monitored in real-time. Indeed, in Example 8 the thermal profile was modified to include 10 initial cycles of PCR conducted under very stringent conditions (i.e., the anneal-extend temperature was selected to be 72 C). These early stringent PCR cycles were followed by 20 cycles of PCR conducted under less stringent conditions (an anneal step of 51 C was used, during which fluorescence from the probe was monitored in real-time as cycling proceeded). In a second approach, a second beacon directed at an amplicon located near the opposite end of each deletion sequence can be introduced. This confirms the presence of the desired product, and not just some fragement thereof. This is illustrated in Example 7 in which molecular beacons were directed at the downstream region of the 5 kb deletion sequence and the upstream region of the 7 kb deletion sequence, respectively.
The following conditions and reagents were used throughout the examples (unless otherwise indicated).
Restriction enzymes ScaI and PleI were purchased from New England BioLabs. Specimens were initially digested in restriction-specific buffers supplied by the vendor using 1 u of enzyme/ug of DNA as measured spectrophotometrically (except for PleI, where 15 u/1 ug of DNA was used). Reaction mixtures were incubated at 37 degrees C. for 1 hour, then heat inactivated at 80 degrees C. for 20 minutes. In all cases, 2 ul of digest were used per PCR well.
DdeI was purchased from Gibco. Two ul of enzyme were used to restrict 4 ul of mt-DNA at a concentration of 0.24 u/ug, diluted into 4 ul of 10× buffer diluted with 30 ul of deionized water. Incubation was at 37 degrees C. for 3.5 hours.
Primers and probes were synthesized by Research Genetics and TriLink according to sequence specifications specified by the inventors.
PCR Thermal Profile:
mt-DNA extraction kits were purchased from Qiagen Corporation and mt-DNA was extracted as directed from the whole blood of volunteers, except for mt-DNA standards (described below), which were purchased from the National Institute of Standards and Technology, Washington, D.C.
A control sequence was prepared as a reference both to test for the presence of mt-DNA and a standard relative to which the 5 kb and 7 kb sequences were measured.
The oligonucleotide target had the following sequence (bases 271-377):
The forward primer used in this example was 24 nt in base length and had the sequence (bases 271-294):
The reverse primer used in this example was 25 nt in base length (bases 353-377) and had the sequence:
The probe having the sequence listed below was a molecular beacon, having a 6 nt long stem sequence (underlined). It probes bases 321-341.
The restriction enzyme used for this purpose was BamHI, which recognizes the following sequence:
It is one of many restriction enzymes that cleaved mt DNA outside of the control region.
The control sequence was amplified in the presence of the materials described above and a plot was made of the logarithm of the concentration of the control sequence, versus PCR cycle number at which fluorescence first became detectable over background (“Ct”). This was done for a dilution series of different copy levels ranging in number from 3×100 copies to 3×108 copies of mt-DNA. A similar plot was made using amplification products from unrestricted sequences. With restriction it was possible to obtain a regression line spanning approximately 7 decades in copy number, but without restriction, a linear regression line was obtained that spanned only 3 decades. This example shows the ability to use primers and probes as described for the amplification and detection of mtDNA. This was shown despite the fact that mtDNA is circular, covalently bonded at its ends, and well hybridized. This example also shows that improved amplification can be attained through the use of cleavage reagents.
The wild-type oligonucleotide target used this example has the following sequence (bases 8344-8670):
The forward primer used in this example was 27 nt in base length (bases 8344-8369) and had the sequence:
The reverse primer used in this example was 21 nt in base length (bases 8650-8670) and had the sequence:
The wild-type probe had the sequence listed below. It was a molecular beacon (bases 8490-8510), having a 6 nt long stem sequence (underlined):
The restriction enzyme used to cleave this deletion sequence was ScaI, which recognizes the following sequence:
ScaI does not cut the control region, which can be co-amplified with other sequences if desired.
A PCR reaction using the materials described above was conducted. One set of samples was not contacted with cleavage reagents while another was so contacted. A plot of fluorescence versus cycle number for the 5 kb wt sequence in the presence and absence of target DNA indicated that the sample unrestricted with ScaI showed an increase in fluorescence beginning at cycle 16. This showed that the sample contained a sizable amount of 5 kb wt mt-DNA. A similar plot using the sample restricted with ScaI resulted in a shift in fluorescence vs. cycle number ˜6 cycles to the right, indicating that the number of wt molecules was reduced by restriction by a factor of ˜26=64 fold.
Master Mix:
The restriction enzyme Hind III was purchased from New England BioLabs. The suggested standard reaction conditions were used, except with approximately 5 U of enzyme per ug of DNA, instead of 1 U/ug.
In this example, the following PCR profile was used for a first round of amplification: 92 degrees/15 sec., 71 degrees/45 sec. for 40 cycles.
The above master mix, without the beacon present, was used for PCR with the following
100 ng of Hind III-digested DNA was also included.
The products from the above PCR were examined by agarose gel electrophoresis. There were no product gel bands observed in any lane.
For the next part of this experiment, 1 ul of target DNA was removed from each well in the above PCR reaction. This DNA was placed into a new well containing new master mix and the following primers:
The PCR profile used for this second amplification was: 92 degrees/15 sec., 69 degrees/45 sec for 40 cycles.
Agarose gel electrophoresis was performed on the samples obtained following two rounds of PCR as described above. Gel bands of size compatible with deletions of the 5 kb region (MW of approximately 174 bp) were seen in all samples examined. No primer-dimer bands were observed.
In the last part of this experiment, 1 ul of target DNA was removed from the PCR amplification that had been performed at an annealing-extension temperature of 71° C. (the first PCR round). This sample was added to a reaction tube containing new master mix, the following primers were used:
along with the following beacon: 5′ TET-ccgctcgaaa ggtattcctg ctaatgctag gctgccaatc gagcgg-Dabcyl 3′ Seq. ID No. 13
This tube was then subjected to the following PCR conditions:
A fluorescent signal from the probe was monitored at 57° C. in real-time in the ABI PRISM 7700 analyzer.
Fluorescence versus cycle number was plotted for the 5 kb mu sequence, in the presence and absence of target DNA. The increase in fluorescence, which crossed the threshold after PCR cycle ˜10, indicated a positive beacon signal for the 5 kb deletion. This fluorescent signal is consistent with the observation of the corresponding gel band described earlier.
The products of the reamplified PCR were then visualized by agarose gel electrophoresis. This figure demonstrated the presence of 5 kb mutant DNA in the samples, as seen by a major band of approximate MW 174 bp. Minor side products were also seen.
Forward wt primer used in this example was 22 nt in base length (bases 16033-16054) and had the sequence:
The reverse primer was 20 nt in base length (bases 16194-16213) and had the sequence:
The WT probe having the sequence listed below (bases 16065-16088) is a molecular beacon, having a 6 nt long stem sequence (underlined):
The restriction enzyme used to cleave this 7 kb deletion sequence was PleI, which recognizes the following sequence:
PleI does not cut the conserved region, which can be co-amplified.
A PCR reaction using the materials described above was conducted. One set of samples was not contacted with cleavage reagents while another was so contacted. A plot of fluorescence versus cycle number for the 7 kb WT sequence in the presence and absence of target DNA was made. This sample unrestricted with PleI showed an increase in fluorescence beginning at cycle number 17 indicating the presence of a sizable amount of 7 kb wild type mt-DNA in this specimen. A plot of fluorescence versus cycle number for the restricted sample showed a shift of ˜5 cycles to the right, indicating that the number of WT molecules was reduced by restriction by a factor of ˜25=32 fold.
Example 4 is repeated except that one aliquot of sample contains mtDNA with a 7 kb deletion.
The mutant (7 kb deletion) target sequence is:
The mutant probe is a molecular beacon (bases 16103-16127) having the sequence: 5′-gcg tcg ctg cca gcc acc atg aat att gta cga cgc dabcyl-3′ Seq. ID. No 19
The forward mutant primer used in this example is 33 nt in base length (bases 8581-8613) and has the sequence:
The muDNA amplifies and is detected by interrogation of the probe.
The mt-DNA reference standards obtained from NIST and referred to in the first example above were used as standards in duplicate calibration experiments performed separately. The control region was amplified and detected using Seq. ID No 4 (5′FAM-gcg agc tct ggc cac agc act taa acc c gct cgc dabcyl-3′) and associated primers. PCR was performed as described in Example 1; values of Ct were determined and plotted versus the logarithm of target copy number. The linear regression parameters obtained are as shown in Table 1, below. The intercept of the calibration curve is the number of cycles required to detect a single copy of target, as shown below.
The calibration equation is:
Ct=Intercept+Slope×log [copy #]
Ct for a single copy is given by the intercept; hence the intercept indicates the number of PCR cycles required for single copy sensitivity.
This example shows the reproducibility of the procedure (the two intercepts differ by <1 cycle, while the intercepts differ by only 5%), and also indicates that the assay possesses single copy sensitivity at a level of 46 or 47 PCR cycles. Thus, the assay is reproducible and sensitive. Moreover, the establishment of a reliable calibration curve enables the quantitation of mutant DNA relative to wildtype DNA or relative to the control sequence. This can be particularly important in distinguishing between disease state or condition that is related to aging as opposed to disease state or condition related to other causes.
Two beacons were targeted to each of two mutant amplicons produced by 5 kb and 7 kb deletions, respectively. These probes were tested in PCR according to conditions listed below. Two new primers were synthesized and used to amplify a portion of the wild type mt-DNA genome containing a binding site complementary to the probes.
The sequences of these primers and probes were as follows.
The probe for the 5 kb deletion was: 5′ TET-ccg ctc ga aag gta ttc ctg cta atg cta ggc tgc caa tc gag cgg-Dabcyl Seq. ID No 21
The probe for the 7 kb deletion was 5′ TET-ccgctcg gccgcagtac tgatcattct atttccccct cta cgagcgg-Dabcyl 3′ probe Seq. ID No 22
The reverse primer used in conjunction with the probe for the 5 kb deletion had the sequence: tgt atg ata tgt ttg cgg ttt cga tga t Seq. ID No 23
The forward primer had the sequence:
This primer was synthesized to obtain amplification at a site to which the probe could bind.
The forward primer used in conjunction with the probe for the 7 kb deletion had the sequence:
The reverse primer had the sequence:
This primer was synthesized to obtain amplification at a site to which the probe could bind.
The thermal profile used on the ABI 7700 sequence detector was as follows:
The PCR mastermix consisted of:
Using a fluorescence threshold of 29 fluorescence units, target was first detected in real time at ˜7 PCR cycles using the beacon for the 5 kb deletion. Using a threshold of 39 cycles, target was first detected at ˜16 PCR cycles using the beacon for the 7 kb deletion.
The products of these PCR reactions were electrophoresed on a standard agarose gel and stained with ethidium bromide. Bands were observed corresponding to amplicons of the correct size (˜126 base pairs for the 5 kb and ˜236 base pairs for the 7 kb, respectively). A no-template control lane corresponding to the blank reactions for the 7 kb deletion were completely free of bands, although a small amount of what appeared to be primer-dimer side product was observed in the lane corresponding to the blank for the 5 kb deletion.
As in earlier examples, mt DNA was subjected to PCR real-time monitoring in the presence of mutant primer sets for both the 5 kb and 7 kb deletion sequences, except that two different thermal profiles were employed.
The first thermal profile was:
The primer/beacon sets were:
Following PCR, amplified products were electrophoresed on agarose gels under standard conditions, and stained with ethidium bromide to reveal the size distribution of the reaction products. The gel exhibited numerous bands indicative of non-specific priming.
The second PCR thermal profile commenced with 10 cycles using a high [stringent] annealing temperature, followed by 30 cycles of real-time monitoring under less stringent conditions; i.e., at a lower annealing temperature. The primers/beacons used were:
The thermal profile was:
Once again, amplified product was electrophoresed on a gel, stained with ethidium bromide, and the resulting bands compared to those of markers of known molecular weight.
In contrast with the results obtained under the previous thermal cycling conditions, no fluorescence above background was observed during real-time monitoring. Moreover, the gel results showed a complete absence of bands.
Although PleI and ScaI can be used for restricting wt DNA as described in earlier examples, it is convenient to use just one restriction enzyme capable of cleaving both the 7 kb and 5 kb wt mt-DNA within their respective deletion sequences. Hind III, which cuts the following sequence:
is used for this purpose. It does not cut the control region; hence, when it is desired to quantitate deletions relative to the control region, Hind III is especially preferred. It is incubated for 1 hour at 37 C with DNA at a level of ˜1 u/ug DNA, as described by the manufacturer (New England Nuclear).
The present application is a continuation application of U.S. application Ser. No. 09/877,748, filed Jun. 11, 2001.
Number | Date | Country | |
---|---|---|---|
Parent | 09877748 | Jun 2001 | US |
Child | 11253126 | Oct 2005 | US |