Tetraalkylammonium derivatives as real-time PCR enhancers and stabilizers of the qPCR mixtures containing SYBR Green I

Gouse M. Shaik, Lubica Dráberová, Peter Dráber, Michael Boubelík and Petr Dráber^*

Department of Signal Transduction, Institute of Molecular Genetics, Academy of Sciences of the Czech Republic, Víde $n$ ská 1083, 14220 Prague 4, Czech Republic

*To whom correspondence should be addressed. Tel: +420 241062468; Fax: +420 241062214; Email: draberpe{at}img.cas.cz

Received May 1, 2008. Revised June 14, 2008. Accepted June 18, 2008.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Tetraalkylammonium (TAA) derivatives have been reported to serveas stabilizers of asymmetrical cyanine dyes in aqueous solutionsand to increase the yield and efficiency of polymerase chainreaction (PCR) detected by end-point analysis. In this study,we compared the ability of various TAA derivatives (with alkylchain ranging from 1 to 5 carbons) and some other compoundsto serve as enhancers of real-time PCR based on fluorescencedetection from intercalating dye SYBR Green I (SGI). Our dataindicate that TAA chlorides and some other TAA derivatives serveas potent enhancers of SGI-monitored real-time PCR. Optimalresults were obtained with 10–16 mM tetrapropylammoniumchloride. The effect of TAA compounds was dependent on the natureof counter ions present and composition of the reaction mixturesused. Based on measurements of SGI-generated fluorescence signalin the presence of PCR-amplified DNA fragments, oligonucleotideprimers and/or various additives, we propose that TAA-derivativesreduce the binding of SGI to oligonucleotide primers and thusenhance primer–template interactions during annealingphase. Furthermore, these compounds serve as stabilizers ofSGI-containing PCR mixtures. The combined data indicate thatTAA derivatives might be a new class of additives contributingto robustness of real-time PCR monitored by asymmetrical cyaninedye SGI.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Quantitative real-time PCR is rapidly becoming an importantresearch tool for a variety of analytical and diagnostic applications(1). Sequence-specific fluorescent probes and double-stranded(ds) DNA binding dyes have been used to continuously monitorPCR product formation. Sequence-specific probes allow highlysensitive detection of specific amplification products, butare relatively expensive. On the other hand, dsDNA-binding dyes,such as SYBR Green I (SGI), are inexpensive but also less specific,because they bind to all dsDNA present in PCR mixtures, includingnonspecific products and primer-dimers. Although some nonspecificproducts and primer-dimers could be detected by analysis ofmelting curves, their presence reduces the sensitivity of real-timePCR monitored by intercalating dyes. To enhance the productionof specific PCR products, optimization procedures are oftenemployed (2). These include optimization of concentration ofcomponents in PCR mixtures, namely concentration of Mg²⁺, orDNA polymerase, and design of improved primer sets. However,in some cases nonspecific products are formed even when allPCR parameters are seemingly optimized. A variety of additivesand enhancing agents have been tested to increase the specificity,yield and consistency of PCR amplification. These include dimethylsulfoxide(DMSO) (3–5 ), tetramethylene (TM) sulfone (6), TM sulfoxide(7), N,N,N-trimethylglycine monohydrate (betaine) (8,9), formamide(10–12 ), tetramethylammonium (TMA) chloride (13,14), TMAoxalate (15), ammonium sulfate (16), acetamide (12), nonionicdetergents (17,18), glycerol (19) and trehalose (20,21). Mostof these additives have been described to have beneficial effecton PCR amplifications as evaluated by end-point analysis. Theefficiency of these agents in real-time PCR based on fluorescencedetection from intercalating dyes is mostly unknown. It hasbeen reported that inhibitory effect of SGI on PCR performancecould be partially reversed by increased concentration of Mg²⁺(22) or inclusion of DMSO (5). Other studies showed that quaternarycompounds, such as tetrapentylammonium (TPA) hydroxide, TPA-bromideand tetrabutylammonium (TBA) hydroxide, stabilized fluorescencenucleic acid stains in aqueous solutions (23). Interestingly,tetraalkylammonium (TAA) derivatives also enhanced the stabilityof SGI in agarose gels used for electrophoresis (23,24). However,current knowledge does not make it possible to predict whetheror not these agents would serve as enhancers and/or stabilizersof real-time PCR based on fluorescence detection from intercalatingdye SGI.

In this study, we compared various TAA derivatives and someother compounds as to their ability to enhance the performanceof SGI-monitored real-time PCR. Our data indicate that TAA derivativescould serve as a new class of additives contributing to robustnessof real-time PCR monitored by asymmetrical cyanine dye SGI andserving as stabilizers of SGI-containing PCR reaction mixtures.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials
TMA-Cl, TMA-OH, tetraethylammonium chloride (TEA-Cl), tetrapropylammoniumchloride (TPrA-Cl), TPrA-OH, TBA-Cl, TBA-OH, TPA-Cl, TPA-OH,TM sulfoxide, DMSO, formamide, D-(+)-trehalose dihydrate, betainemonohydrate, and glycerol were obtained from Fluka Chemie GmbH(Buchs, Switzerland) or Sigma-Aldrich (Steinheim, Germany).TPA-Cl, TAA-oxalates or TAA-acetates were prepared by neutralizingthe corresponding hydroxides with HCl, oxalic acid or aceticacid, respectively. The pH of all reagents used as additiveswas adjusted to 7.8–8.0. SGI was obtained from Invitrogen(Carlsbad, CA, USA). All other chemicals were from Sigma–Aldrich.

Real-time PCR conditions
Experiments were conducted in Mastercycler ep realplex (EppendorfAG, Hamburg, Germany) according to the manufacturer's instructions.All reactions were performed in 10 µl reaction volumesin 96-well plates for PCR heat-sealed with heat sealing film(Eppendorf). A standard 1x real-time SGI-supplemented (SSG)PCR mixture contained 10 mM Tris–HCl, pH 8.0 (25°C),50 mM KCl, 0.1% Triton X-100, 1.5 mM MgCl₂, 200 µM eachof dATP, dCTP, dGTP and dTTP (dNTPs), 5% DMSO, 25 U/ml of TaqDNA polymerase, protease inhibitors, 0.98 µM SGI (1:20000 diluted stock of 19.6 mM; molar absorption coefficient ofSGI at the absorption maximum (494 nm) is $~$ 73 000 M^–1cm^–1(25)), 0.5 µM primers and cDNA or plasmid DNA. The alternative1x real-time SGI-supplemented (ASG) PCR mixture contained 75mM Tris–HCl, pH 8.0 (25°C), 20 mM (NH₄)₂SO₄, 0.01%Tween 20, 2.5 mM MgCl₂, 200 µM dNTPs, 6% DMSO, 25 U/mlTaq DNA polymerase, protease inhibitors, 0.98 µM SGI,0.5 µM primers and cDNA or plasmid DNA. Also used was1x iQ^TM SYBR Green Supermix (Bio-Rad Laboratories, Hercules,CA, USA) containing 20 mM Tris–HCl, pH 8.4, 50 mM KCl,3 mM MgCl₂, 200 µM dNTPs, 25 U/ml iTaq DNA polymerase,unspecified amount of SGI, 20 nM fluorescein and unspecifiedstabilizers and 1x QuantiTect SYBR Green PCR kit (QIAGEN GmbH,Hilden, Germany) containing unspecified amount of HotStartTaqDNA polymerase, Tris–HCl, pH 8.7 (20^°C), KCl, (NH₄)₂SO₄,2.5 mM MgCl₂, dNTPs including dUTP, SYBR Green I and Rox passivereference dye.

For real-time PCR amplification of genomic DNA fragments weused PCR mixture, denoted GSB, containing at a final 1x concentration20 mM Tris–HCl, pH 8.8 (25°C), 10 mM (NH₄)₂SO₄, 10mM KCl, 2 mM MgSO₄, 200 µM dNTPs, 25 U/ml Taq DNA polymerase,protease inhibitors, 0.65 µM SGI, 0.5 µM primers,genomic DNA and 22 nM anti-Taq DNA polymerase monoclonal antibody.Hybridoma cell line producing anti-Taq DNA polymerase antibody(clone 4/C7) was prepared after immunization of BALB/c micewith Thermus aquaticus DNA polymerase, fusion of spleen cellsfrom immunized mice with SP2 myeloma cells as described (26),and selection and cloning of hybridoma cell line producing antibodyspecific for Taq DNA polymerase as determined by ELISA (27).The anti-Taq/4/C7 antibody, which is of the IgG₁ subclass, inhibitedthe enzymatic activity of Taq DNA polymerase by >95%, asdetermined by DNA polymerase assay using activated salmon testesDNA as a substrate (27). A 200 bp fragment of human CD4 clonedin plasmid vector (Seegene, Seoul, Korea) was amplified withforward primer 5'-GTCTACCAGGCATTCGCTTCAT-3' and reverse primer5'-CTGTGAATGCTGCGACTACGAT-3'. In some experiments, a segmentof 171 bps of rat actin cDNA was amplified using forward primer5'-ACTCTTCCAGCCTTCCTTC-3' and reverse primer 5'-ATCTCCTTCTGCATCCTGTC-3'.For amplification of 864 bp genomic DNA fragment of mouse Thy-1gene, a Thy-1 primer set was used, forward primer, 5'-ATGAACCCAGCCATCAGCG-3'and reverse primer 5'-GGGTAAGGACCTTGATATAGG-3'. Thermal cyclingconsisted of an initial denaturation at 95°C for 2 min followedby 40 cycles of denaturation at 94°C for 15 s, annealingat various temperatures for 15 s, and extension at 72°Cfor 60 s (for genomic DNA) or 20 s for other amplifications.Commercial real-time PCR master mixes were used according torecommended conditions, including initial DNA polymerase activationstep of 15 min at 95°C for QuantiTect SYBR Green PCR kit.Melting curve analysis was carried out from 70°C to 95°Cwith 0.2°C increments. In some experiments DNA ampliconswere visualized on agarose gels stained with ethidium bromide(0.5 µg/ml). Threshold cycle (Ct) values were determinedby automated threshold analysis. PCR efficiencies (E), weredetermined from dilutions of DNA and calculated from the slopesof the standard curves according to the equation, E = 10^–1/^a–1,where a is the slope of the corresponding standard curve. Thespecificity of PCR products was checked by agarose gel electrophoresis.

RNA extraction and cDNA synthesis
RNA was extracted from 2H3 clone of rat basophilic leukemia(RBL-2H3) cells cultured under standard conditions (28) usingTri reagent (Sigma–Aldrich). The amount of RNA was determinedby spectrophotometer ND-1000 (NanoDrop Technologies, Inc., Wilmington,DE, USA). Single-stranded cDNA was synthesized by means of mousemoloney leukemia virus reverse transcriptase (Invitrogen) accordingto manufacturer's instructions using 10 µg of isolatedRNA and 50 ng of random hexamers per reaction.

Isolation of PCR-generated DNA fragments
A 200 bp fragment of human CD4 was amplified by PCR as describedabove and isolated through its binding to diatomaceous earthparticles in the presence of chaotropic agent guanidine thiocyanate(29). DNA was eluted from the particles with DNAse-free water.Concentration of PCR product was determined by spectrophotometerND-100.

Genomic DNA
Genomic DNA was isolated from C57BL/6 mouse tails as described(30). The mass of the haploid mouse genome (C-value) is $~$ 3.3pg (http://www.genomesize.com) and therefore 1 ng of mouse genomicDNA contains $~$ 330 copies of a single-copy gene. This number wasused for generation of standard curve of Ct values from amplificationplots versus log copy number (logQ).

SGI fluorescence measurements
Two-times concentrated SGI solution, containing 20 mM Tris–HCl,pH 8.0, 100 mM KCl, 0.2% Triton X-100 and 1.96 µM SGI,was supplemented with isolated PCR amplicons (final concentration5 µg/ml), oligonucleotide primers (0.4 µM), DMSO(5%), H₂O and/or TAA-derivatives (16 mM) to get 1x concentratedSGI solution. Ten microliter aliquots were transferred to 96-wellPCR plates, heat-sealed, and fluorescence reading was carriedout on Mastercycler ep realplex at 68°C or 55°C. Alternatively,fluorescence reading was carried out from 35°C to 80°C,recording fluorescence each 0.2°C increment. Fluorescenceof SGI was tested with the primers described above, and severalother primers including primer for mouse glyceraldehyde-3-phosphatedehydrogenase (GAPDH1), 5'-ATGACATCAAGAAGGTGGTG-3', linker ofactivated T cells (LAT), 5'-CTGGGGAGCAGCCTTGAGTAG-3', mouse/ratinterleukin-6 (IL6), 5'-AAATAGTCCTTCCTACCCCAA-3', mouse/human/ratactin 5'-ACTCTTCCAGCCTTCCTTC-3', poly(A)₂₀, poly(T)₂₀. All primerswere checked for hairpin and dimer formation by means of NetPrimerprogram (http://www.premierbiosoft.com). The primers were usedat concentration 0.2 µM.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In initial experiments we used SGI-containing PCR mixture withoutDMSO (SSG-) and analyzed the effect of three previously describedadditives, DMSO (5), TM-sulfoxide (7) and glycerol (19), onreal-time PCR amplification of CD4 DNA fragment. Ct values atvarious concentrations of the additives were determined andnormalized to the lowest Ct value obtained in a given experiment.In the absence of any additive, PCR mixture based on SSG- failedto give any specific amplification signal indicating that 0.98µM SGI inhibited the PCR. This conclusion was corroboratedby agarose gel electrophoresis where the expected DNA ampliconwas observed only in reactions without SGI (not shown). Theobserved inhibitory effect was not reversed by enhanced MgCl₂concentration up to 5 mM. As expected (5), addition of DMSOenhanced the PCR performance, as inferred from decreased Ctvalues in a broad range of concentrations (0.2–1.6 M)with the peak at $~$ 0.8 M (Figure 1). TM sulfoxide raised the PCRperformance only slightly less than DMSO but within a much narrowerrange of concentrations (0.3–0.8 M) peaking at $~$ 0.4 M.Some improvement was also observed in PCR mixtures supplementedwith a broad range of concentrations of glycerol (0.5–1.8M) with maximum at $~$ 1 M.]

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Figure 1. The effect of additives on SGI-based qPCR performance. Standard SSG PCR mixtures, without DMSO, were supplemented with various concentrations of glycerol, TM-sulfoxide or DMSO and qPCRs were performed using cloned CD4 as a template. The lowest Ct value, obtained at a concentration of DMSO (0.8 M), was subtracted from Ct values of qPCR with additives at various concentrations ( ${Delta}$ Ct). Means ± SD from three experiments are shown.

When the SSG- reaction mixtures were supplemented with variousconcentrations of TMA-Cl or TPrA-Cl, no amplification of DNAfragments was detected by enhanced fluorescence of SGI or agarosegel electrophoresis (not shown). However, if TMA-Cl was addedto SSG mixture containing DMSO, a distinct decrease in Ct valueswas observed (Figure 2). With the size of alkyl chain increasingfrom 1 to 3 carbons, the range of concentrations of TAA-chloridesenhancing PCR performance rose. Best results were obtained withTPrA-Cl, which was found to enhance PCR performance within alarge range of concentrations (0.5–40 mM) with a peakat $~$ 20 mM (Figure 2).

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Figure 2. Enhanced performance of SGI-based qPCR by TMA-Cl, TEA-Cl, TPrA-Cl or TBA-Cl. Five percent DMSO-containing SSG PCR mixtures were supplemented with various concentrations of the additives and qPCRs were performed using cloned CD4 as a template. The Ct values obtained in PCR mixtures without TAA-Cl additives were subtracted from the Ct values obtained in the presence of additives ( ${Delta}$ Ct). Means ± SD from two experiments are shown.

Previously we have found that oxalate anion can enhance thespecificity and efficiency of TMA enhancer as detected by PCRend-point analysis (15). In further work we therefore analyzedthe real-time PCR performance of SSG mixtures supplemented withTAA derivatives with various anions and CD4 as a template. Datasummarized in Table 1 indicate that all TAA-chlorides raisedthe real-time PCR efficiency. Comparable results were obtainedwith optimal concentrations of the TAA-Cls with 1–4 carbonsin alkyl chain; however, with TPA-Cl, the performance decreased.In contrast, none TAA-oxalates were capable of decreasing Ctvalues. Acetate anions showed some improvement of PCR but onlyin TAA derivatives with 3 or 4 alkyl chains and were less potentthan chloride anions. Inclusion of betaine also lowered theCt values, but formamide and D-(+)-trehalose had no enhancingeffect. Inclusion of additives at concentrations giving thelowest Ct values also reduced the melting temperature. The observeddecrease was dependent on the number of alkyl chains; the lowestand highest decrease was seen with TMA-Cl and TPrA-acetate.However, there was no correlation between the drop in meltingtemperature and decline in Ct values. The reagents also differedin their ability to inhibit real-time PCR. As shown in Table 1,TPA-Cl inhibited PCR at relatively low concentrations (1.6 ±0.6 mM), whereas TPrA-Cl was inhibitory at 50.4 ± 5.2mM.

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Table 1. Effect of tested additives on efficiency and inhibition of real-time PCR

Using temperature gradient function of Mastercycler ep realplex,we also studied the changes in optimal annealing temperaturesin SSG PCR mixtures with various additives (Figure 3). WhenDNA fragment of CD4 was amplified, optimal annealing temperaturewas found to be 62°C. Inclusion of 16 mM TMA-Cl or TPrA-Clcaused not only a decrease in Ct values but also a broader rangeof optimal annealing temperatures.

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Figure 3. The effect of additives on optimal annealing temperature. Standard SSG PCR mixtures without TAA-additives (filled circle; Control) or supplemented with 16 mM TMA-Cl (open square) or 16 mM TPrA-Cl (open triangle) were run using cloned CD4 as a template and qPCR temperature gradient function from 54°C to 68°C. Means ± SD from three experiments are shown.

Next we analyzed the changes in PCR efficiencies under differentconditions. For these experiments the CD4 template was seriallydiluted and added to master mixes differing in composition.As shown in Figure 4A, SSG PCR mixtures supplemented with 16mM TMA-Cl or TPrA-Cl exhibited enhanced efficiencies, respectively,E = 0.85 and E = 0.90, compared to controls supplemented withvehicle (water) alone (E = 0.65). Data from four such experimentsshowed that TMA-Cl-mediated increase in PCR efficiency was significant(Figure 4B, SSG, dsDNA). Similar increase was also observedwith ASG master mixes or with iQ SYBR Green Supermixes fromBio-Rad Laboratories. When actin cDNA was amplified using SSGPCR mixture or iQ^TM SYBR Green Supermix, both supplemented with16 mM TMA-Cl, a significant increase in PCR efficiency was alsofound (Figure 4B, cDNA). These data indicate that addition ofcDNA mixture in reverse transcriptase reaction buffer does notinterfere with TMA-Cl performance; in fact, actin cDNA was amplifiedin general with higher efficiency, indicating better optimizedconditions for amplification of this template.

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Figure 4. Enhanced efficiencies of SSG PCR mixtures supplemented with TMA-Cl or TPrA-Cl. (A) Tenfold serial dilutions of the CD4 DNA template were amplified with the corresponding primers in triplicates in standard SSG mixtures without additives (filled circle; Control) or supplemented with 16 mM TMA-Cl (open circle) or 16 mM TPrA-Cl (inverted filled triangle). Standard curves were obtained for control (E = 0.65; R² = 0.997), TMA-Cl-supplemented (E = 0.85; R² = 0.995) and TPrA-Cl-supplemented (E = 0.90; R² = 0.997) PCR mixtures. Typical experiments from 4 (Control and TMA-Cl) or 2 (TPrA-Cl) performed are shown. (B) Tenfold serial dilutions of the CD4 plasmid template (dsDNA) or cDNA from RBL-2H3 cells (cDNA) were amplified with primers for CD4 or actin, respectively, in triplicates in SSG, ASG or iQ SYBR Green Supermix from Bio-Rad (BR) Laboratories PCR mixtures, supplemented (grey column) or not (black column) with 16 mM TMA-Cl. Efficiencies were calculated from standard curves. Means ± SD were calculated from at least three independent experiments. Statistical significance of the differences between controls and TMA-Cl-supplemented samples is also shown; *P $≤$ 0.05; **P $≤$ 0.01.

In an attempt to explain the enhancing effect of TAA-derivativeson SGI-monitored real-time PCR, we evaluated SGI fluorescenceunder various conditions. In initial experiments we measuredfluorescence at annealing temperature (55°C) in SGI solutionssupplemented with forward CD4 primer or isolated 200 bp CD4dsDNA amplicon. Data presented in Figure 5A show that additionof oligonucleotide primer significantly increased SGI fluorescence.When DMSO (5% final concentration) or TMA-Cl (16 mM final concentration)were added, fluorescence was significantly inhibited. Oligonucleotideprimer-induced SGI fluorescence was completely inhibited whenboth TMA-Cl and DMSO were added together. Addition of CD4 dsDNAamplicons to SGI solution resulted in a dramatically enhancedfluorescence, which could be weakly but reproducibly inhibitedby DMSO. In contrast to oligonucleotide primers, however, SGIfluorescence was enhanced by TMA-Cl, and DMSO reduced this enhancedfluorescence to levels observed in samples without additives.The effect of TAA-Cls and DMSO on fluorescence of SGI-dsDNAand SGI-oligonucleotide primer complexes was further analyzedin experiments in which all TAA-Cls employed in this study weresuccessively used. Data presented in Figure 5B show that TAA-Clswith 1–3 carbons enhanced fluorescence of SGI-dsDNA, whereasTBA-Cl was without effect. Interestingly, TPA-Cl enhanced fluorescenceof SGI-dsDNA substantially more than did other TAA-Cls. In allcases, DMSO partially inhibited the fluorescence. In contrast,TAA-Cls had different effect on fluorescence of SGI-oligonucleotideprimers; fluorescence was inhibited by TAA-Cl with 1–4carbons and this inhibition was potentiated by DMSO, whereasTPA-Cl alone or in combination with DMSO had no inhibitory effect(Figure 5C). Inhibitory effect of TMA-Cl and DMSO was observedwith several other primers tested, including a primer for GAPDHand reverse primer for CD4 (not shown).

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Figure 5. Interaction of SYBR with single-stranded oligonucleotide primers or dsDNA fragments. (A) SYBR-containing solutions were supplemented with water alone (Cw), CD4 forward primer (Primer) or PCR amplified CD4 fragment (dsDNA), DMSO (+, filled columns, final concentration 5%) and/or TMA-Cl (+, final concentration 16 mM). Fluorescence of the samples was determined in Mastercycler ep realplex at 55°C. (B) SYBR-containing solutions were supplemented with water (Cw), or dsDNA-amplified CD4 fragment, DMSO (+, filled columns, final concentration 5%) and the indicated TAA-Cls at final concentration 16 mM. Fluorescence was determined at 68°C and normalized to samples without additives (Control). (C) SYBR-containing solutions were supplemented and analyzed as in (B) except that Thy-1.2 primer was used and fluorescence was determined at 55°C. Means ± SD were calculated from at least three independent experiments performed in triplicates or quadruplicates. Statistical significance of the differences between samples is also shown; *P $≤$ 0.05, **P $≤$ 0.01. Asterisks over columns indicate statistical significance of differences between samples with and without DMSO. (D) Fragment of Thy-1 genomic DNA was amplified in standard real-time PCR mixture with different concentrations of Thy-1 primers (20, 40 or 60 nM) in the absence (–) or presence (+) of 0.98 µM SYBR. After 30 cycles, PCR amplicons were analyzed by agarose gel electrophoresis. Position of DNA markers in the middle of the gel is also indicated. Arrows indicate position of 864 bps Thy-1 amplicon. Relative amounts of Thy-1 fragments generated during PCR were determined by densitometry and normalized to the amount of Thy-1 amplicons produced in PCR with 20 nM primers but without SYBR (Fold). A typical experiment of two performed is shown.

To decide whether SGI-mediated inhibition of PCR is dependenton primers concentration, we analyzed by agarose gel electrophoresisproduction of PCR amplicons in reaction mixtures with or withoutSGI and various concentrations of primers. Data shown in Figure 5Dindicate that, at low concentration of primers (20 nM), specificPCR amplicons were formed in the absence of SGI, but were completelyinhibited in its presence. Increasing concentrations of primersto 40 and 60 nM resulted in enhanced production of PCR amplicons,which remained lower in SGI-supplemented reaction mixtures;thus SGI could interfere with annealing of primers and initiationof PCR.

The observed enhanced fluorescence of SGI in the presence ofoligonucleotide primers was surprising and could be explainedby suboptimal design of primers forming hairpins and/or dimers.In further experiments we therefore evaluated that SGI fluorescencein the presence of such individual primers exhibit no secondarystructures and/or dimers as determined by NetPrimer analysis.Data presented in Figure 6A show that rising temperature causeda slight decrease of SGI fluorescence. If SGI-containing solutionswere supplemented with LAT primer (Figure 6A), reverse CD4 primer(Figure 6B) or GAPDH1, IL-6 or actin primer (not shown), enhancedfluorescence of SGI was observed at 35°C. Rising temperaturecaused a gradual decrease in SGI fluorescence; at 65°C andabove the primers contributed only very little to enhanced SGIfluorescence. Surprisingly, poly(A)₂₀ oligonucleotide (Figure 6A)and poly(T)₂₀ oligonucleotide (Figure 6B) also enhanced SGIfluorescence, indicating that SGI could directly interact withssDNA. When poly(A)₂₀ oligonucleotide was mixed with 16 mM TPrA-Cl,a clear decrease in SGI fluorescence was observed (Figure 6C).As expected, mixing poly(A)₂₀ with poly(T)₂₀ induced a dramaticincrease in SGI fluorescence, and TPrA-Cl at temperature range35–65°C decreased it (Figure 6D). The combined dataindicate that even homopolymeric oligonucleotides could interactwith SGI, and thus strengthen the concept that SGI could interactwith ssDNA oligonucleotide primers.

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Figure 6. The effect of temperature on SGI fluorescence in the presence of single- or double-stranded oligonucleotides and additives. SGI-containing solutions were supplemented or not with various oligonucleotides and additives, and temperature-dependent changes in SGI fluorescence were determined. (A) poly(A)₂₀ [p(A)] or oligonucleotide primer LAT was used. (B) poly(T)₂₀ [p(T)] or reverse oligonucleotide primer (rCD4) was used. (C) Poly(A)₂₀ was used alone or mixed with TPrA-Cl (TPr; 16 mM final concentration]. (D) Poly(A)₂₀ and Poly(T)₂₀ [p(A+T)] were mixed and analyzed alone or after addition of TPrA-Cl. In A and B temperature-dependent changes in fluorescence of SGI alone are also shown. Means ± SD from 2 to 4 experiments performed in triplicates or quadruplicates are shown.

TAA-Cls at concentrations enhancing RT–PCR performancewere also tested for their contribution to stability of SSGPCR master mixes. Two-times concentrated master mixes were supplementedor not with 32 mM TMA-Cl, TEA-Cl, TPrA-Cl or TBA-Cl and storedat –20 or 37°C in the dark. After 2 weeks they weresupplemented with CD4 template DNA, primers and water and usedfor real-time PCR. Freshly prepared SSG PCR mixes with or withoutadditives were prepared and also used for PCR as controls. Datapresented in Figure 7 indicate that all master mixes supplementedwith TAA-Cls showed significantly lower Ct values than thosewithout additives. Interestingly, storage of SSG master mixesat –20°C or even at 37°C for two weeks had nonegative effect on their PCR performance.

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Figure 7. The effect of additives on performance of PCR mixtures stored under different conditions. Two-times concentrated SSG PCR mixes were supplemented or not with various TAA-Cls at 32 mM concentration and stored for two weeks at 37 or –20°C. As controls (C) freshly prepared SSG PCR mixes with or without additives were also analyzed. Real-time PCRs were performed using cloned CD4 DNA as a template and corresponding primers, and Ct values were determined. Means ± SD were calculated from three experiments performed in triplicates. Statistical significance of the differences between samples with no additives and samples supplemented with additives is also shown; *P $≤$ 0.05, **P $≤$ 0.01.

Finally, we checked whether TAA derivatives could improve SGI-monitoredamplification of difficult templates. For these experimentswe used mouse genomic DNA and amplified 864 bps fragment ofmouse Thy-1 gene. In pilot experiments we found that Thy-1 ampliconswere not detectable by SGI fluorescence measurement or agarosegel electrophoresis when SSG, ASG, iQ^TM SYBR Green Supermixor QuantiTect SYBR Green PCR kit under optimized conditionswere used. Removal of SGI from SSG or ASG master mixes resultedin production of the expected 864 bps amplicon, confirming theinhibitory effect of SGI in this system. Addition of TMA-Clor TPrA-Cl at concentrations 5–30 mM to various SGI-basedPCR mixtures did not enhance production of the 864 bp Thy-1amplicons as detected by agarose gel electrophoresis. To solvethis problem we performed a series of optimization experimentsand prepared a new DMSO-free PCR mixture, denoted GSB, the compositionof which is described in ‘Materials and Methods’section. When Thy-1 fragment was amplified in GSB-based mixture,PCR efficiency was 0.60 ± 0.12 (mean ± SD, n =3, Figure 8A). In the presence of TPrA-Cl at optimal concentration10 mM, efficiency was increased to 0.81 ± 0.08 (n = 4;Figure 8B). Agarose gel electrophoresis after real-time PCRconfirmed generation of the corresponding band and enhancedproduction of the Thy-1 amplicons in TPrA-Cl-supplemented PCRmixtures (Figure 8C). It should be noted that addition of TPrA-Clalso decreased nonspecific amplification as reflected by lower‘background’. Similar results were observed whengenomic fragments of Thy-1 and three other genes were amplifiedin the presence of 10 mM TPrA-Cl, TMA-Cl or TEA-Cl (not shown).The combined data indicate that addition of TAA-Cls improvesSGI-monitored real-time PCR performance even when difficultgenomic fragments are amplified. Key factor for amplificationof large genomic fragments in the presence of SGI is to useGSB PCR mixture.

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Figure 8. Effect of TPrA-Cl on PCR performance using genomic DNA as a template. (A and B) Genomic DNA was 3-fold diluted and used as a template for real-time PCR using GSB reaction mixes without (A) or with (B) 10 mM TPrA-Cl. Thy-1 fragment of 864 bps was amplified using the corresponding primer set. Ct values were obtained from amplification curves and plotted against calculated copy numbers (logQ). Typical experiments from 3 (A) or 4 (B) performed. (C) After 40 cycles of PCR amplification the samples were analyzed by agarose gel electrophoresis. Lines 1–5 and 6–10 correspond to samples run, respectively, in the absence or presence of TPrA-Cl. Lines 1 + 6, 2 + 7, 3 + 8 and 4 + 9 correspond to samples containing template DNA at concentrations, respectively, 0.3, 0.9, 2.7 and 8.1 ng/µl. Lines 5 + 10 did not contain template DNA.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Data presented in this study indicate that TAA derivatives couldserve as potent enhancers of SGI-monitored real-time PCR. Theeffect of TAA derivatives depended on the nature of ions present.The strongest effect was observed with TAA-cations with 1–4carbons in alkyl chain combined with chloride as anion. TPA-Clwith 5 carbons in alkyl chain was less potent. As concerns TAAderivatives with acetate as anion, the enhancing effect wasconfined only to TPrA-acetate and TBA-acetate (Table 1). Incontrast to previous results showing that TMA-oxalate enhancesthe specificity and yield of PCRs evaluated by end-point analysis(15), all TAA-oxalates failed to act as SGI-monitored real-timePCR enhancers. Although melting temperature slightly decreasedwith increasing size of alkyl chain (up to 3 carbons), optimalannealing temperature was not dramatically changed, thus corroboratingprevious findings (13).

Molecular mechanism of the enhancing effect of TAA-derivativeson real-time PCR is unknown. Several possibilities may be considered.First, TMA-Cl is known to increase thermal stability of AT basepair (31,32). The enhanced AT base-pair stability could thuscontribute to a more efficient binding of primers to the templateand to a more efficient amplification in the presence of TAA-Cls.Our finding that optimal annealing temperature was similar incontrol and TAA-Cls-supplemented PCR mixtures, however, suggeststhat contribution of the additives to the base-pairs stabilityis small. It should also be noted that the effect of TMA-Clon base-pairs stability was in previous studies observed atrelatively high concentrations of TMA-Cl (3 M), whereas theenhancing effect on real-time PCR was effected at much lowerconcentrations ( $~$ 16 mM); higher concentrations (>32 mM) wereinhibitory. Second, additives could interfere with the inhibitoryeffect of SGI on PCR. This possibility is supported by our findingthat in the absence of fluorescence dye the template amplification,evaluated by end-point analysis, was of comparable extent inboth control and TAA-Cl-supplemented samples. The structureof SGI and its positive charges (25) should allow its interactionwith negative electrostatic potential in the minor groove. Furthermore,van der Waals interactions within the boundaries of the minorgroove are likely to contribute to its high affinity for dsDNA.These interactions could be affected by TAA-containing solutions.The highest SGI-derived fluorescence signal was observed insolution supplemented with TPA-Cl (Figure 5B). However, TPA-Clhad only small effect on RT–PCR performance, a findingsuggesting that enhanced SGI binding rather inhibits than promotesPCR amplification. Interestingly, the enhanced fluorescenceobserved in samples with TAA derivatives was decreased in samplessupplemented with DMSO. Thus, DMSO could contribute to enhancedPCR performance by partially reducing the binding of SGI toDNA. Yet these effects were relatively small and do not explainthose dramatic changes induced by DMSO and TAA derivatives.Third, it is known that SGI binds with low efficiency to single-strandedDNA (25). In fact, addition of primers to SGI solution enhancedsignificantly fluorescence signal measured at annealing temperature.Interestingly, the signal was inhibited by TAA-derivatives,and DMSO further enhanced the inhibitory effect. Disparate effectsof TAA-derivatives and DMSO on SGI binding to primers and dsDNAsuggest different underlying binding mechanisms. When samplescontaining SGI and oligonucleotide primers were supplementedwith TPA-Cl and DMSO or vehicle (water), comparable fluorescencewas observed (Figure 5C); these data suggest that DMSO and TAA-derivativesdo not interfere with fluorescence signal detection, but ratherwith binding of SGI to primers and generation of fluorescencesignal. Unexpectedly, enhanced SGI fluorescence was also observedin samples with poly(A)₂₀ and poly(T)₂₀, which have no possibilityto form complementary secondary structures and/or duplexes,and again TPrA-Cl inhibited this fluorescence. In view of thesefindings we propose that SGI could inhibit amplification throughits binding to primers by a distinct mechanism, one which interfereswith their annealing and/or initiation of polymerase reaction.This conclusion was corroborated by other experimental dataindicating that production of electrophoretically detectableamplicons at limiting concentrations of primers was inhibitedin the presence of SGI. Obviously, it is still possible thatSGI could also affect PCR efficiency by some other mechanism(s).

In initial experiments we used SGI-supplemented home-made orcommercial real-time PCR master mixes, which performed wellwhen relatively short (100–400 bp) DNA or cDNA fragmentswere amplified. When TAA-Cls (up to four carbons) were added,PCR efficiency during amplification of such fragments was enhanced.However, with larger genomic fragments (>800 bps) in thepresence of SGI, amplification was inhibited in all tested SGI-supplementedmaster mixes regardless of the presence or absence of variousconcentrations of TAA-Cls. Evidently, SGI was the inhibitorbecause its withdrawal led to easily detectable products end-pointagarose gel electrophoresis. To solve this problem we formulatednew SGI-based PCR mixture, GSB, which allowed amplificationof longer genomic fragments in the presence of SGI. PCR performancein GSB-based mixtures was also enhanced by TAA-Cls, confirminggeneral suitability of these additives for SGI-based real-timePCR analysis. At the same time, addition of TAA-Cls decreasednonspecific amplicons often observed when genomic fragmentsare amplified even under seemingly optimal conditions. It hasbeen reported previously that SGI is not chemically stable for>3 weeks (33). Furthermore, Karsai and co-workers found thatSGI degradation products are potent inhibitors of PCR (34).Our data that TAA derivatives protect SGI-containing PCR mixesfrom aging, comply with and somewhat extend the previous findingsthat TAA derivatives stabilize SGI in agarose gels (23). Inclusionof TAA derivatives not only enhances the efficiency of SGI-containingPPP master mixes but also contributes to their increased stabilityeven at 37°C. This should facilitate their handling.

ACKNOWLEDGEMENTS

We thank Luká $s$ Kocanda and Hanka Mrázováfor skilled technical assistance. Funding was provided by theAcademy of Sciences of the Czech Republic (1QS500520551, KAN200520701,Institutional project AVOZ50520514). Funding to pay the OpenAccess publication charges for this article was provided bythe Academy of Sciences of the Czech Republic, project KAN200520701.

Conflict of interest statement. None declared.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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Tetraalkylammonium derivatives as real-time PCR enhancers and stabilizers of the qPCR mixtures containing SYBR Green I