Improved PCR method for amplification of GC-rich DNA sequences

A quantitative sequencing method using synthetic internal standards including functional and phylogenetic marker genes

The method of spiking synthetic internal standard genes (ISGs) to samples for amplicon sequencing, generating sequences and converting absolute gene numbers from read counts has been used only for phylogenetic markers and has not been applied to functional markers. In this study, we developed ISGs, including gene sequences of the 16S rRNA, pmoA, encoding a subunit of particulate methane monooxygenase and amoA, encoding a subunit of ammonia monooxygenase. We added ISGs to the samples, amplified the target genes and performed amplicon sequencing. For the mock community, the copy numbers converted from read counts using ISGs were equivalent to those obtained by the quantitative real-time polymerase chain reaction (4.0 × 104 versus 4.1 × 104 and 3.0 × 103 versus 4.0 × 103 copies μL-DNA-1 for 16S rRNA and pmoA genes, respectively), but we also identified underestimation, possibly due to primer coverage (7.8 × 102 versus 3.7 × 103  μL-DNA-1 for amoA gene). We then applied this method to environmental samples and analysed phylogeny, functional diversity and absolute quantities. One Methylocystis population was most abundant in the sludge samples [16S rRNA gene (3.8 × 109 copies g-1 ) and the pmoA gene (2.3 × 109 copies g-1 )] and were potentially interrelated. This study demonstrates that ISG spiking is useful for evaluating sequencing data processing and quantifying functional markers.

Dual role of enhancer of zeste homolog 2 in the regulation of ultraviolet radiation-induced matrix metalloproteinase-1 and type I procollagen expression in human dermal fibroblasts

Abnormalities in the extracellular matrix (ECM) caused by ultraviolet (UV) radiation are mediated by epigenetic mechanisms. Enhancer of zeste homolog 2 (EZH2) is a histone methyltransferase that is implicated in inflammation, immune regulation, and senescence. However, its role in controlling UV-induced ECM alterations in the skin remains elusive. Here, we investigated the role of EZH2 in UV-induced expression of matrix metalloproteinase (MMP)-1 and type I procollagen. We found that UV induced EZH2 expression in human skin in vivo and in human dermal fibroblasts (HDFs). EZH2 knockdown reduced the expression and promoter activity of MMP-1 and increased those of type I procollagen, whereas EZH2 overexpression had the opposite effects. Mechanistically, EZH2 increased NF-κB activity, and p65 and p50 expression and promoter activity. Intriguingly, chromatin immunoprecipitation assays revealed that the EZH2/p65/p50 complex was recruited and bound to the MMP-1 promoter after UV irradiation, independent of its histone methyltransferase activity. In contrast, EZH2-induced DNA methyltransferase 1 (DNMT1) formed a complex with EZH2 and enhanced the enrichment of H3K27me3 on the COL1A2 promoter following UV irradiation. These findings indicate that EZH2 plays a dual role in regulating MMP-1 and type I procollagen expression and improve our understanding of how this epigenetic mechanism contributes to UV-induced skin responses and photoaging. This study shows that inhibiting EZH2 is a potential anti-aging strategy for preventing UV-induced skin aging by reducing MMP-1 expression and inducing type I procollagen expression.

Nucleotide amplification and sequencing of the GC-rich region between matrix and fusion protein genes of peste des petits ruminants virus

Peste des petits ruminants virus (PPRV) causes a highly devastating disease of sheep and goats, that threatens the conservation of small wild ruminants. The development of PPRV vaccines, diagnostics and therapeutics, greatly depends on in-depth genomic data. Yet, high guanine-cytosine (GC) content between matrix (M) and fusion (F) genes of PPRV poses difficulty for both primer design and nucleotide amplification. In turn, this has led into absence or low nucleotide sequence coverage in this region. This poses a risk of missing important part of the genome that could help to infer viral evolution. Here, an overlapping long-read primer-based amplification strategy was developed to amplify the GC-rich fragments between M-F gene junction using nexus gradient polymerase chain reaction (PCR). The resulting amplicons were sequenced by dideoxynucleotide cycle sequencing and compared with other PPRV nucleotide sequences available at GenBank. Our findings indicate clear PCR amplification products with expected size of the GC-rich fragments on agarose gel electrophoresis. The sequencing results of these fragments indicate 99.5 % nucleotide identity with PPRV strain KY628761. An extremely difficult PCR target of 67.4 % GC contents was successfully amplified and sequenced using this long-read primer approach. The long-read primer set may be used in tiling multiplex PCR for complete genome sequencing of PPRV.

Knockout of a highly GC-rich gene in Burkholderia pyrrocinia by recombineering with freeze-thawing transformation

Genetic transformation is a valuable and essential method that provides powerful insights into the gene function of microorganisms and contributes to the construction of engineered bacteria. Here, we developed a novel genetic transformation system to easily knock out a highly GC-rich gene (74.71% GC) from Burkholderia pyrrocinia JK-SH007, a biocontrol strain of poplar canker disease. This system revealed a reliable selectable marker (trimethoprim resistance gene, Tmp) and a simplified, efficient transformation method (6,363.64 CFU/μg, pHKT2) that was developed via freeze-thawing. The knockout recombineering of B. pyrrocinia JK-SH007 was achieved through a suicide plasmid with a three-fragment mutagenesis construct. The three-fragment cassette for mutagenesis was generated by overlap extension and touchdown PCRs and composed of Tmp flanked by GC-rich upstream and downstream fragments from B. pyrrocinia JK-SH007. The mutant strain (ΔBpEG), which was verified by PCR, lost 93.3% of its ability to degrade carboxymethyl cellulose over 40 days. Overall, this system may contribute to future research on B. pyrrocinia traits.

Solvent engineering studies on recombinase polymerase amplification

Recombinase polymerase amplification (RPA) is a technique that is used to specifically amplify a target nucleic acid sequence. Unlike the polymerase chain reaction (PCR), RPA is performed at a constant temperature between 37 and 42°C. Therefore, it can be potentially used for the onsite detection of various pathogens when combined with DNA extraction and amplicon detection techniques. In this study, we prepared recombinant recombinase and single-stranded DNA-binding protein from T4 phage and used them to examine the effects of reaction conditions and additives on the efficiency of RPA. The results revealed that the optimal pH was 7.5-8.0, optimal potassium acetate concentration was 40-80 mM, and optimal reaction temperature was 37-45°C although dimethyl sulfoxide at 5% v/v and formamide at 5% v/v inhibited the reaction. Our results suggest that RPA could be conducted using a wider range of optimal reaction conditions than those required for PCR and that RPA is highly suitable for point-of-care use.

Impact Of TP53 Gene Promoter Methylation On Chronic Lymphocytic Leukemia Pathogenesis And Progression

Background

Chronic lymphocytic leukemia (CLL) is a malignant lymphoid disorder that results from the overgrowth of mature-looking lymphoid cells in the blood and lymphatic tissue. Various clinical presentations have been attributed to the disease as a result of the different underlying genetic and epigenetic alterations. The current study has been initiated to study the role of an epigenetic alteration affecting the promoter of the TP53gene on CLL pathogenesis and progression.

Methods

The current study involved 54 newly diagnosed patients presenting with CLL as well as 30 normal individuals as controls. After obtaining verbal consent, data collection was done and the blood collected from all enrolled individuals for hematological investigations as well as for molecular categorization of TP53 methylation status. Methylation-specific polymerase chain reaction (MS-PCR) technique was used to define the methylation status of the TP53 gene promoter that encompasses DNA extraction, bisulfite conversion, conventional PCR amplification, running on agarose gel and documentation. Finally, statistical analysis was done to assess any correlation of the TP53 epigenetic alteration to the disease etiology and the progression.

Results

In the current study, all controls and 42 of 54 patients show unmethylated TP53 gene promoter; on the other hand, the methylated promoter was detected among 12 patients with a p-value of 0.001. TP53 gene promoter methylation significantly linked to reduced platelet count (p-value of 0.047) and advanced stage at presentation (p-value of 0.076). No significant differences were seen among both methylated and unmethylated TP53 promoters in relation to the age of the affected individuals, total white blood cell counts and hemoglobin level of the affected individuals.

Conclusion

The current study revealed a significant correlation of TP53 gene promoter methylation to chronic lymphocytic leukemia pathogenesis and lower platelet counts.

Polymerase Chain Reaction (PCR) Amplification of GC-Rich Templates

The efficiency of polymerase chain reaction (PCR) amplification is influenced by the nucleotide composition and sequence of the template DNA. Problematic templates include those with long homopolymeric runs, inverted repeats, or GC-rich tracts-such as those containing >60% G + C residues-that are found in the regulatory regions of many mammalian genes. Localized regions of templates rich in GC residues tend to fold into complex secondary structures that might not melt during the annealing phase of the PCR cycle. Also, the primers used to amplify GC-rich regions often have a high capacity to form self- and cross-dimers and a strong tendency to fold into stem-loop structures that can impede the progress of the DNA polymerase along the template molecule. Predictably, amplification of full-length template DNA is inefficient, and the products of the reaction contain a high proportion of shorter molecules that result from blockage of the DNA polymerase. Altering the design of the primers and using a combination of hot start and touchdown PCR can sometimes improve the efficiency of amplification. More often, a multipronged approach is required, such as the use of enhancers in the amplification reaction, adjustment of the cycling protocol, and, if necessary, designing new sets of primers. This protocol uses a mixture of four additives-betaine, dithiothreitol (DTT), dimethyl sulfoxide (DMSO), and bovine serum albumin (BSA)-for use with Taq DNA polymerase.

Efficient method for site-directed mutagenesis in large plasmids without subcloning

Commonly used methods for site-directed DNA mutagenesis require copying the entire target plasmid. These methods allow relatively easy modification of DNA sequences in small plasmids but become less efficient and faithful for large plasmids, necessitating full sequence verification. Introduction of mutations in larger plasmids requires subcloning, a slow and labor-intensive process, especially for multiple mutations. We have developed an efficient DNA mutagenesis technique, UnRestricted Mutagenesis and Cloning (URMAC) that replaces subcloning steps with quick biochemical reactions. URMAC does not suffer from plasmid size constraints and allows simultaneous introduction of multiple mutations. URMAC involves manipulation of only the mutagenesis target site(s), not the entire plasmid being mutagenized, therefore only partial sequence verification is required. Basic URMAC requires two PCR reactions, each followed by a ligation reaction to circularize the product, with an optional third enrichment PCR step followed by a traditional cloning step that requires two restriction sites. Here, we demonstrate URMAC’s speed, accuracy, and efficiency through several examples, creating insertions, deletions or substitutions in plasmids ranging from 2.6 kb to 17 kb without subcloning.

Enhanced detection of RNA by MMLV reverse transcriptase coupled with thermostable DNA polymerase and DNA/RNA helicase

Detection of mRNA is a valuable method for monitoring the specific gene expression. In this study, we devised a novel cDNA synthesis method using three enzymes, the genetically engineered thermostable variant of reverse transcriptase (RT), MM4 (E286R/E302K/L435R/D524A) from Moloney murine leukemia virus (MMLV), the genetically engineered variant of family A DNA polymerase with RT activity, K4pol_L329A from thermophilic Thermotoga petrophila K4, and the DNA/RNA helicase Tk-EshA from a hyperthermophilic archaeon Thermococcus kodakarensis. By optimizing assay conditions for three enzymes using Taguchi's method, 100 to 1000-fold higher sensitivity was achieved for cDNA synthesis than conventional assay condition using only RT. Our results suggest that DNA polymerase with RT activity and DNA/RNA helicase are useful to increase the sensitivity of cDNA synthesis.

PCR amplification of GC-rich DNA regions using the nucleotide analog N4-methyl-2'-deoxycytidine 5'-triphosphate

GC-rich DNA regions were PCR-amplified with Taq DNA polymerase using either the canonical set of deoxynucleoside triphosphates or mixtures in which the dCTP had been partially or completely replaced by its N4-methylated analog, N4-methyl-2'-deoxycytidine 5'-triphosphate (N4me-dCTP). In the case of a particularly GC-rich region (78.9% GC), the PCR mixtures containing N4me-dCTP produced the expected amplicon in high yield, while mixtures containing the canonical set of nucleotides produced numerous alternative amplicons. For another GC-rich DNA region (80.6% GC), the target amplicon was only generated by re-amplifying a gel-purified sample of the original amplicon with N4me-dCTP-containing PCR mixtures. In a direct PCR comparison on a highly GC-rich template, mixtures containing N4me-dCTP clearly performed better than did solutions containing the canonical set of nucleotides mixed with various organic additives (DMSO, betaine, or ethylene glycol) that have been reported to resolve or alleviate problems caused by secondary structures in the DNA. This nucleotide analog was also tested in PCR amplification of DNA regions with intermediate GC content, producing the expected amplicon in each case with a melting temperature (Tm) clearly below the Tm of the same amplicon synthesized exclusively with the canonical bases.

Development of a highly resolutive method, using a double quadruplex tetra-primer-ARMS-PCR coupled with capillary electrophoresis to study CD40LG polymorphisms

Polymorphisms in the CD40 ligand gene (CD40LG) are associated with various immunological disorders such as tumors, autoimmune and infectious diseases. The aim of this study was to develop a highly optimized double quadruplex tetra-primer amplification refractory mutation system PCR (double quadruplex T-ARMS-PCR) coupled with capillary electrophoresis to allow genotyping of eight relevant candidate CD40LG SNPs and to establish haplotypes. After conducting the double quadruplex T-ARMS-PCR, the genotypes obtained through agarose electrophoresis were compared with those obtained through capillary electrophoresis. This strategy was applied to analyze the genetic patterns of CD40LG in two distinct cohorts of blood donors (211 French and 274 Tunisian). The T-ARMS-PCR method was rapid, inexpensive, reproducible and reliable for SNP determination. Regarding the separation technique, capillary electrophoresis allows traceable and semi-automated analysis while agarose electrophoresis remains a cost-effective technique that does not require specialized or costly equipment. Using these methods, we identified significantly different genetic heterogeneity between the two investigated populations (p ≤ 0.0001) and we also extensively characterized their haplotypes. The obtained genotype distribution and the optimized quadruplex T-ARMS-PCR technique coupled with capillary electrophoresis provides valuable information for studying pathologic inflammation leading to various diseases in which CD40LG might be a candidate gene.

Guidelines for the tetra-primer ARMS-PCR technique development

The tetra-primer amplification refractory mutation system-polymerase chain (ARMS-PCR) reaction is a simple and economical method to genotype single-nucleotide polymorphisms (SNPs). It uses four primers in a single PCR and is followed just by gel electrophoresis. However, the optimization step can be very hardworking and time-consuming. Hence, we propose to demonstrate and discuss critical steps for its development, in a way to provide useful information. Two SNPs that provided different amplification conditions were selected. DNA extraction methods, annealing temperatures, PCR cycles protocols, reagents, and primers concentration were also analyzed. The use of tetra-primer ARMS-PCR could be impaired for SNPs in DNA regions rich in cytosine and guanine and for samples with DNA not purified. The melting temperature was considered the factor of greater interference. However, small changes in the reagents concentration significantly affect the PCR, especially MgCl2. Balancing the inner primers band is also a key step. So, in order to balance the inner primers band, intensity is important to observe which one has the weakest band and promote its band by increasing its concentration. The use of tetra-primer ARMS-PCR attends the expectations of modern genomic research and allows the study of SNPs in a fast, reliable, and low-cost way.

Bias in Whole Genome Amplification: Causes and Considerations

Whole genome amplification (WGA) is a widely used molecular technique that is becoming increasingly necessary in genetic research on a range of sample types including individual cells, fossilized remains and entire ecosystems. Multiple methods of WGA have been developed, each with specific strengths and weaknesses, but with a common defect in that each method distorts the initial template DNA during the course of amplification. The type, extent, and circumstance of the bias vary with the WGA method and particulars of the template DNA. In this review, we endeavor to discuss the types of bias introduced, the susceptibility of common WGA techniques to these bias types, and the interdependence between bias and characteristics of the template DNA. Finally, we attempt to illustrate some of the criteria specific to the analytical platform and research application that should be considered to enable combination of the appropriate WGA method, template DNA, sequencing platform, and intended use for optimal results.

Hybridisation of N4-methylcytosine-containing amplicons on DNA microarrays

5'-Cy5-labelled PCR amplicons containing the analogue base, N(4)-methylcytosine, instead of cytosines were compared in microarray hybridisation experiments with the corresponding amplicons containing the canonical set of bases, with respect to the intensity of the fluorescence signal obtained, and cross hybridisation to non-corresponding probes. In general, higher hybridisation temperatures resulted in reduced signal intensities, particularly in the case of the N(4)-methylcytosine containing amplicons. At the lower hybridisation temperatures tested (40 °C, 30 °C), these modified amplicons gave about equal or stronger fluorescence signal than the corresponding regular amplicons. With the two GC-richest amplicons tested, in one instance the N(4)-methylated target gave a dramatically higher signal intensity than the unmodified amplicon, interpreted as reflecting the reduced formation of hairpin structures in the target sequence, due to the lower thermodynamic stability of the G:N(4)-methylC base pair, making the target more accessible, while in the other case no hybridisation was observed with either version of the amplicon, probably due to interference from a G-tetrad structure. Both for the regular and the N(4)-methylated amplicons, no significant cross hybridisation was seen in these experiments.

Utility of amplification enhancers in low copy number DNA analysis

One parameter that impacts the robustness and reliability of forensic DNA analyses is the amount of template DNA used in the polymerase chain reaction (PCR). With short tandem repeat (STR) typing, low copy number (LCN) DNA samples can present exaggerated stochastic effects during the PCR that result in heterozygote peak height imbalance, allele drop out, and increased stutter. Despite these effects, there has been little progress toward decreasing the formation of stutter products and heterozygote peak imbalance effects during PCR. In an attempt to develop a more robust system that is less refractory to stochastic effects, the PCR additives, betaine, DMSO, PEG, and PCRboost®, were investigated on low-quantity DNA samples. The effects of the additives were assessed by evaluating STR typing results. Of the four additives, the only positive effects were observed with betaine treatment. Betaine, at a final concentration of 1.25 mol/L, was found to improve the robustness of the amplification, specifically by decreasing stutter in a dual locus system. In contrast, the addition of 1.25 mol/L betaine to commercial STR amplification kits did not affect stutter ratios. However, the addition of betaine did lead to increased yield of PCR products in all commercial kits tested. The results support that betaine can improve amplification efficiency of LCN DNA samples.

Enhancement of PCR amplification of moderate GC-containing and highly GC-rich DNA sequences

PCR is a commonly used and highly efficient technique in biomolecular laboratories for specific amplification of DNA. However, successful DNA amplification can be very time consuming and troublesome because many factors influence PCR efficiency. Especially GC-rich DNA complicates amplification because of generation of secondary structures that hinder denaturation and primer annealing. We investigated the impact of previously recommended additives such as dimethylsulfoxide (DMSO), magnesium chloride (MgCl2), bovine serum albumin (BSA), or formamide. Furthermore, we tested company-specific substances as Q-Solution, High GC Enhancer, and Hi-Spec; various actively promoted polymerases as well as different PCR conditions for their positive effects on DNA amplification of templates with moderate and extremely high CG-content. We found considerable differences of specificity and quantity of product between different terms. In this article, we introduce conditions for optimized PCR to help resolve problems amplifying moderate to high GC-rich templates.

Optimization of PCR conditions for amplification of GC-Rich EGFR promoter sequence

BACKGROUND

Polymerase chain reaction (PCR) is an extremely sensitive method that often demands optimization, especially when difficult templates need to be amplified. The aim of the present study was to optimize the PCR conditions for amplification of the epidermal growth factor receptor (EGFR) promoter sequence featuring an extremely high guanine-cytosine (GC) content in order to detect single nucleotide polymorphisms -216G>T and -191C>A.

METHODS

Genomic DNA used for amplification was extracted from formalin-fixed paraffin-embedded lung tumor tissue and PCR products were detected by agarose gel electrophoresis.

RESULTS

Results showed that addition of 5% dimethyl sulfoxide (DMSO), as well as DNA concentration in PCR reaction of at least 2 μg/ml, were necessary for successful amplification. Due to high GC content, optimal annealing temperature was 7°C higher than calculated, while adequate MgCl2 concentration ranged from 1.5 to 2.0 mM.

CONCLUSION

In conclusion, EGFR promoter region is a difficult PCR target, but it could be amplified after optimization of MgCl2 concentration and annealing temperature in the presence of DMSO and the DNA template of acceptable concentration.

Polymerase chain reaction optimization for amplification of Guanine-Cytosine rich templates using buccal cell DNA

CONTEXT

Amplification of Guanine-Cytosine (GC) -rich sequences becomes important in screening and diagnosis of certain genetic diseases such as diseases arising due to expansion of GC-rich trinucleotide repeat regions. However, GC-rich sequences in the genome are refractory to standard polymerase chain reaction (PCR) amplification and require a special reaction conditions and/or modified PCR cycle parameters.

AIM

Optimize a cost effective PCR assay to amplify the GC-rich DNA templates.

SETTINGS AND DESIGN

Fragile X mental retardation gene (FMR 1) is an ideal candidate for PCR optimization as its GC content is more than 80%. Primers designed to amplify the GC rich 5' untranslated region of the FMR 1 gene, was selected for the optimization of amplification using DNA extracted from buccal mucosal cells.

MATERIALS AND METHODS

A simple and rapid protocol was used to extract DNA from buccal cells. PCR optimization was carried out using three methods, (a) substituting a substrate analog 7-deaza-dGTP to dGTP (b) in the presence of a single PCR additive and (c) using a combination of PCR additives. All PCR amplifications were carried out using a low-cost thermostable polymerase.

RESULTS

Optimum PCR conditions were achieved when a combination of 1M betaine and 5% dimethyl sulfoxide (DMSO) was used.

CONCLUSIONS

It was possible to amplify the GC rich region of FMR 1 gene with reproducibility in the presence of betaine and DMSO as additives without the use of commercially available kits for DNA extraction and the expensive thermostable polymerases.

Effects of GC bias in next-generation-sequencing data on de novo genome assembly

Next-generation-sequencing (NGS) has revolutionized the field of genome assembly because of its much higher data throughput and much lower cost compared with traditional Sanger sequencing. However, NGS poses new computational challenges to de novo genome assembly. Among the challenges, GC bias in NGS data is known to aggravate genome assembly. However, it is not clear to what extent GC bias affects genome assembly in general. In this work, we conduct a systematic analysis on the effects of GC bias on genome assembly. Our analyses reveal that GC bias only lowers assembly completeness when the degree of GC bias is above a threshold. At a strong GC bias, the assembly fragmentation due to GC bias can be explained by the low coverage of reads in the GC-poor or GC-rich regions of a genome. This effect is observed for all the assemblers under study. Increasing the total amount of NGS data thus rescues the assembly fragmentation because of GC bias. However, the amount of data needed for a full rescue depends on the distribution of GC contents. Both low and high coverage depths due to GC bias lower the accuracy of assembly. These pieces of information provide guidance toward a better de novo genome assembly in the presence of GC bias.

Capacity of N4-methyl-2'-deoxycytidine 5'-triphosphate to sustain the polymerase chain reaction using various thermostable DNA polymerases

The dCTP analog N4-methyl-2'-deoxycytidine 5'-triphosphate (N4medCTP) was evaluated for its performance in the polymerase chain reaction (PCR). Using the HotStart Taq DNA polymerase with a standard thermal protocol, test segments 85 or 200 bp long were amplified equally well using dCTP or N4medCTP:dCTP mixtures ranging in molar ratio from 3:1 to 10:1, while complete replacement of dCTP by N4medCTP gave clearly lower amplicon yields and higher Cq values. Comparable yields with N4medCTP or dCTP were achieved only by using a slowdown protocol. Post-PCR melting analyses showed decreasing Tm values for amplicons obtained with increasing N4medCTP:dCTP input ratios; for the 200-bp amplicon, complete replacement of dCTP by N4medCTP in the reaction reduced the Tm by 11 °C; for the 85-bp amplicon the Tm reduction was 7 °C. In experiments aiming at the 200-bp amplicon, Pfu exo(-) DNA polymerase did not sustain PCR when dCTP was fully replaced by N4medCTP, even with the slowdown protocol, except at elevated N4medCTP concentrations, and, compared to PCR conducted exclusively with dCTP, the use of N4medCTP:dCTP mixtures gave reduced yields and distinctly higher Cq values, regardless of the thermal program employed. PCR experiments with 9°N DNA polymerase using N4medCTP in the conventional thermal protocol failed to produce the 200-bp amplicon.

The RIPK2 gene: a positional candidate for tick burden supported by genetic associations in cattle and immunological response of knockout mouse

Ticks and tick-borne diseases have a detrimental impact on livestock production causing estimated losses of around $200 million per year in Australia alone. Host resistance to ticks is heritable, within-breed heritability estimates being around 0.35, and with large differences between breeds. Previously a QTL for tick burden was detected on BTA14 at ~72 Mb distal to the centromere, near the gene receptor-interacting serine-threonine kinase 2 (RIPK2). To identify polymorphisms in this region, we sequenced all exons of the RIPK2 gene, identifying 46 single nucleotide polymorphism (SNP). Using SNP from RIPK2 as well as SNP from the bovine genome sequence, we genotyped two samples, one of 1,122 taurine dairy cattle and one of 761 zebu and zebu composite beef cattle. We confirmed that SNP and haplotypes from this region, including from RIPK2, were associated with tick burden in both dairy and beef cattle. To determine whether RIPK2 influences response to tick salivary gland extract (SGE), an immunisation experiment with tick SGE in a RIPK2 knockout (RIPK2 −/−) mouse strain was conducted. There was a significant (P < 0.05) reduction in IgG production in the RIPK2 −/− mouse in response to the SGE compared to its background strain C57BL/ 6 as well as the outbred CD1 mouse strain. In addition, antibodies generated by RIPK2 −/− mice recognised a different set of antigens within SGE when compared to parental-derived antibodies. In summary, the SNP association with tick burden at BTA14 was confirmed and quantitative and qualitative differences in antibody production were observed between RIPK2 −/− and wild-type mice.

Multiple heat pulses during PCR extension enabling amplification of GC-rich sequences and reducing amplification bias

PCR amplification over GC-rich and/or long repetitive sequences is challenging because of thermo-stable structures resulting from incomplete denaturation, reannealing, and self-annealing of target sequences. These structures block the DNA polymerase during the extension step, leading to formation of incomplete extension products and favoring amplification of nonspecific products rather than specific ones. We have introduced multiple heat pulses in the extension step of a PCR cycling protocol to temporarily destabilize such blocking structures, in order to enhance DNA polymerase extension over GC-rich sequences. With this novel type of protocol, we were able to amplify all expansions of CGG repeats in five Fragile X cell lines, as well as extremely GC-rich nonrepetitive segments of the GNAQ and GP1BB genes. The longest Fragile X expansion contained 940 CGG repeats, corresponding to about 2.8 kilo bases of 100% GC content. For the GNAQ and GP1BB genes, different length PCR products in the range of 700 bases to 2 kilobases could be amplified without addition of cosolvents. As this technique improves the balance of amplification efficiencies between GC-rich target sequences of different length, we were able to amplify all of the allelic expansions even in the presence of the unexpanded allele.

1,2-propanediol-trehalose mixture as a potent quantitative real-time PCR enhancer

Background

Quantitative real-time PCR (qPCR) is becoming increasingly important for DNA genotyping and gene expression analysis. For continuous monitoring of the production of PCR amplicons DNA-intercalating dyes are widely used. Recently, we have introduced a new qPCR mix which showed improved amplification of medium-size genomic DNA fragments in the presence of DNA dye SYBR green I (SGI). In this study we tested whether the new PCR mix is also suitable for other DNA dyes used for qPCR and whether it can be applied for amplification of DNA fragments which are difficult to amplify.

Results

We found that several DNA dyes (SGI, SYTO-9, SYTO-13, SYTO-82, EvaGreen, LCGreen or ResoLight) exhibited optimum qPCR performance in buffers of different salt composition. Fidelity assays demonstrated that the observed differences were not caused by changes in Taq DNA polymerase induced mutation frequencies in PCR mixes of different salt composition or containing different DNA dyes. In search for a PCR mix compatible with all the DNA dyes, and suitable for efficient amplification of difficult-to-amplify DNA templates, such as those in whole blood, of medium size and/or GC-rich, we found excellent performance of a PCR mix supplemented with 1 M 1,2-propanediol and 0.2 M trehalose (PT enhancer). These two additives together decreased DNA melting temperature and efficiently neutralized PCR inhibitors present in blood samples. They also made possible more efficient amplification of GC-rich templates than betaine and other previously described additives. Furthermore, amplification in the presence of PT enhancer increased the robustness and performance of routinely used qPCRs with short amplicons.

Conclusions

The combined data indicate that PCR mixes supplemented with PT enhancer are suitable for DNA amplification in the presence of various DNA dyes and for a variety of templates which otherwise can be amplified with difficulty.

A primer design strategy for PCR amplification of GC-rich DNA sequences

OBJECTIVES

To establish a primer design method for amplification of GC-rich DNA sequences.

DESIGN AND METHODS

A group of 15 pairs of primers with higher T(m) (>79.7°C) and lower level ΔT(m) (<1°C) were designed to amplify GC-rich sequences (66.0%-84.0%). The statistical analysis of primer parameters and GC content of PCR products was performed and compared with literatures. Other control experiments were conducted using shortened primers for GC-rich PCR amplifications in this study, and the statistical analysis of shortened primer parameters and GC content of PCR products was performed compared with primers not shortened. A group of 26 pairs of primers were designed to test the applicability of this primer designing strategy in amplifications of non-GC-rich sequences (35.2%-53.5%).

RESULTS

All the DNA sequences in this study were successfully amplified. Statistical analyses show that the T(m) and ΔT(m) were the main factors influencing amplifications.

CONCLUSIONS

This primer designing strategy offered a perfect tool for amplification of GC-rich sequences. It proves that the secondary structures cannot be formed at higher annealing temperature conditions (>65°C), and we can overcome this difficulty easily by designing primers and using higher annealing temperature.

Universal method facilitating the amplification of extremely GC-rich DNA fragments from genomic DNA

Polymerase chain reaction (PCR) is a basic technique with wide applications in molecular biology. Despite the development of different methods with various modifications, the amplification of GC-rich DNA fragments is frequently troublesome due to the formation of complex secondary structure and poor denaturation. Given the fact that GC-rich genes are closely related to transcriptional regulation, transcriptional silencing, and disease progression, we developed a PCR method combining a stepwise procedure and a mixture of additives in the present work. Our study demonstrated that the PCR method could successfully amplify targeted DNA fragments up to 1.2 Kb with GC content as high as 83.5% from different species. Compared to all currently available methods, our work showed satisfactory, adaptable, fast and efficient (SAFE) results on the amplification of GC-rich targets, which provides a versatile and valuable tool for the diagnosis of genetic disorders and for the study of functions and regulations of various genes.

Successful pyrosequencing of GC-rich DNA sequences by partial substitution of deoxyguanosine with deoxyinosine

We experienced significant problems while developing a PyrosequencingTM (Biotage, Uppsala, Sweden) assay to characterize the rifampin resistance-determining region of Mycobacteriumtuberculosis, a target with high guanosine-cytosine content. This paper describes the successful use of a modified pyrosequencing protocol through partial substitution of deoxyguanosine triphosphate with deoxyinosine triphosphate in the polymerase chain reaction.

Fast evolving 18S rRNA sequences from Solenogastres (Mollusca) resist standard PCR amplification and give new insights into mollusk substitution rate heterogeneity

BACKGROUND

The 18S rRNA gene is one of the most important molecular markers, used in diverse applications such as molecular phylogenetic analyses and biodiversity screening. The Mollusca is the second largest phylum within the animal kingdom and mollusks show an outstanding high diversity in body plans and ecological adaptations. Although an enormous amount of 18S data is available for higher mollusks, data on some early branching lineages are still limited. Despite of some partial success in obtaining these data from Solenogastres, by some regarded to be the most "basal" mollusks, this taxon still remained problematic due to contamination with food organisms and general amplification difficulties.

RESULTS

We report here the first authentic 18S genes of three Solenogastres species (Mollusca), each possessing a unique sequence composition with regions conspicuously rich in guanine and cytosine. For these GC-rich regions we calculated strong secondary structures. The observed high intra-molecular forces hamper standard amplification and appear to increase formation of chimerical sequences caused by contaminating foreign DNAs from potential prey organisms. In our analyses, contamination was avoided by using RNA as a template. Indication for contamination of previously published Solenogastres sequences is presented. Detailed phylogenetic analyses were conducted using RNA specific models that account for compensatory substitutions in stem regions.

CONCLUSIONS

The extreme morphological diversity of mollusks is mirrored in the molecular 18S data and shows elevated substitution rates mainly in three higher taxa: true limpets (Patellogastropoda), Cephalopoda and Solenogastres. Our phylogenetic tree based on 123 species, including representatives of all mollusk classes, shows limited resolution at the class level but illustrates the pitfalls of artificial groupings formed due to shared biased sequence composition.

Genotyping the GGGCGG tandem repeat promoter polymorphism in the 5-lipoxygenase enzyme gene (ALOX5) by pyrosequencing assay

AIMS

Efficient genotyping methods for many biologically significant repeat genetic polymorphisms, particularly in GC-rich regions of the genome, are limited. In particular, a short tandem repeat polymorphism [GGCGGG] in the promoter region of ALOX5 has been implicated as an important marker for inflammatory diseases. We developed a pyrosequencing assay to genotype the ALOX5 short tandem repeat polymorphism using pyrosequencing technology that will make assessing this important genetic marker in large, diverse populations more accessible than using current methods.

MATERIALS AND METHODS

We used a nested polymerase chain reaction approach to amplify DNA for pyrosequencing. Population allele frequencies were assessed in two cohorts of previously collected human DNA samples with 188 and 1032 samples, respectively. Sixteen genetic samples with known genotypes were used to confirm the accuracy of the method.

RESULTS AND DISCUSSION

Genotypes were 100% concordant with samples of known genotype. Genotype frequencies in European American, Hispanic, and African American agreed with previously published results (wild-type homozygotes 66%, 64%, and 19%, respectively). The method presented here will facilitate both genetic association and pharmacogenomic research on this polymorphism in large samples that are ethnically and/or racially admixed.

Characterization of transcription from TATA-less promoters: identification of a new core promoter element XCPE2 and analysis of factor requirements

BACKGROUND

More than 80% of mammalian protein-coding genes are driven by TATA-less promoters which often show multiple transcriptional start sites (TSSs). However, little is known about the core promoter DNA sequences or mechanisms of transcriptional initiation for this class of promoters.

METHODOLOGY/PRINCIPAL FINDINGS

Here we identify a new core promoter element XCPE2 (X core promoter element 2) (consensus sequence: A/C/G-C-C/T-C-G/A-T-T-G/A-C-C/A(+1)-C/T) that can direct specific transcription from the second TSS of hepatitis B virus X gene mRNA. XCPE2 sequences can also be found in human promoter regions and typically appear to drive one of the start sites within multiple TSS-containing TATA-less promoters. To gain insight into mechanisms of transcriptional initiation from this class of promoters, we examined requirements of several general transcription factors by in vitro transcription experiments using immunodepleted nuclear extracts and purified factors. Our results show that XCPE2-driven transcription uses at least TFIIB, either TFIID or free TBP, RNA polymerase II (RNA pol II) and the MED26-containing mediator complex but not Gcn5. Therefore, XCPE2-driven transcription can be carried out by a mechanism which differs from previously described TAF-dependent mechanisms for initiator (Inr)- or downstream promoter element (DPE)-containing promoters, the TBP- and SAGA (Spt-Ada-Gcn5-acetyltransferase)-dependent mechanism for yeast TATA-containing promoters, or the TFTC (TBP-free-TAF-containing complex)-dependent mechanism for certain Inr-containing TATA-less promoters. EMSA assays using XCPE2 promoter and purified factors further suggest that XCPE2 promoter recognition requires a set of factors different from those for TATA box, Inr, or DPE promoter recognition.

CONCLUSIONS/SIGNIFICANCE

We identified a new core promoter element XCPE2 that are found in multiple TSS-containing TATA-less promoters. Mechanisms of promoter recognition and transcriptional initiation for XCPE2-driven promoters appear different from previously shown mechanisms for classical promoters that show single "focused" TSSs. Our studies provide insight into novel mechanisms of RNA Pol II transcription from multiple TSS-containing TATA-less promoters.

Qualitative analysis of Adenomatous Polyposis Coli promoter: hypermethylation, engagement and effects on survival of patients with esophageal cancer in a high risk region of the world, a potential molecular marker

Background

Squamous cell carcinoma of esophagus (SCCE) occurs at a high incidence rate in certain parts of the world. This feature necessitates that different aspects of the disease and in particular genetic characteristics be investigated in such regions. In addition, such investigations might lead to achievement of molecular markers helpful for early detection, successful treatment and follow up of the disease. Adenomatous Polyposis Coli (APC) promoter hypermethylation has been shown to be a suitable marker for both serum and solid tumors of adenocarcinoma of esophagus. We investigated the status of APC promoter hypermethylation in Iranian patients, compared the results with the former studies, and evaluated its applicability as a candidate molecular marker by examining association between survival of SCCE patients and APC promoter methylation.

Methods

For evaluating the status of APC promoter hypermethylation and its association with SCCE, a qualitative methylation specific PCR (MSP) was used. DNA was extracted and digested with an appropriate restriction enzyme, treated with sodium bisulfite in agarose beads and amplified in two-step PCR reaction by applying either methylated or unmethylated promoter specific primers. Universally methylated DNA and methylase treated blood DNA of healthy donors were used as positive controls as well. Survival of patients was followed up for two years after treatment and survival rate of patients with methylated APC promoter was compared with that of unmethylated patients.

Results

Assessment of APC promoter methylation revealed that normal tissues were unmethylated, while twenty out of forty five (44.4%) tumor tissues were hypermethylated either in one or both alleles of APC. Among the tissues in which methylation was detected, seven were hypermethylated in both alleles while the other thirteen were hypermethylated in one of the two alleles of APC. Analyzing two-year survival rate of patients with respect to promoter hypermethylation showed a lower rate of survival for patients with methylated APC promoter following their treatment. Further investigation into the association between promoter hypermethylation and tumor differentiation status indicated that patients with well differentiated tumors were more likely to develop promoter hypermethylation.

Conclusion

Observing similar level of APC promoter hypermethylation in patients with SCCE in this high risk region and comparing it with other parts of the world could support the hypothesis that a common molecular mechanism might be involved in tumorigenesis of SCCE. In addition, the higher rate of two-year survival for patients with unmethylated APC promoter as well as its relationship with tumor differentiation would suggest that this tumor suppressor could be an appropriate candidate molecular marker for evaluating tumor malignancy and predicting survival of patients subsequent to treatment.

PCR-amplification of GC-rich regions: 'slowdown PCR'

The polymerase chain reaction (PCR) technique has become an indispensable method in molecular research. However, PCR-amplification of GC-rich templates is often hampered by the formation of secondary structures like hairpins and higher melting temperatures. We present a novel method termed 'Slowdown PCR', which allows the successful PCR-amplification of extremely GC-rich (>83%) DNA targets. The protocol relies on the addition of 7-deaza-2'-deoxyguanosine, a dGTP analog to the PCR mixture and a novel standardized cycling protocol with varying temperatures. The latter consists of a generally lowered ramp rate of 2.5 degrees C s(-1) and a low cooling rate of 1.5 degrees C s(-1) for reaching an annealing temperature and is run for 48 cycles. We established this protocol as a versatile method not only for amplification of extremely GC-rich regions, but also for routine DNA diagnostics and pharmacogenetics for templates with different annealing temperatures. The protocol takes 5 h to complete.

A hCXCR1 transgenic mouse model containing a conditional color-switching system for imaging of hCXCL8/IL-8 functions in vivo

To address the functions of human CXCL8 (hCXCL8)/IL-8 through hCXCR1 in vivo, we have developed a humanized, transgenic mouse for hCXCR1. This mouse line is versatile and allows for a variety of functional analyses using bioimaging, including Cre/loxP-mediated, tissue-specific hCXCR1 expression in a spatiotemporal manner; a color-switching mechanism, which uses spectrum-complementary, genetically encoded green and red fluorescence markers to label the hCXCR1-expressing cells [enhanced GFP (eGFP)] against the background [monomeric red fluorescent protein (mRFP)]; a bioluminescent marker, which is present in the hCXCR1-expressing cells; and an exogenous cell surface marker (eGFP moiety) in the hCXCR1-expressing cells, which facilitates identification, isolation, and targeting of these cells. The established, transgenic founder line RCLG3A (TG(+)) expresses only mRFP and does so ubiquitously. When the RCLG3A mice are crossed with the tamoxifen-inducible, whole-tissue Cre mice (ROSA26-Cre/Esr(+/-)), administration of tamoxifen induces whole-body hCXCR1 expression and color-switching. When RCLG3A mice are crossed with thymocyte-specific Cre mice (Lck-Cre(+/+)), the hCXCR1 expression and color-switching are restricted in a lineage-specific manner. This mouse line can be used to understand the functions of hCXCL-8 in vivo. In addition, our approach and vectors can be used to establish other tissue-specific, transgenic mice in conjunction with multifunctional cell markers, which facilitate cell imaging, tracing, and manipulation in vivo.

Epigenetic modulation and cancer: effect of metabolic syndrome?

The importance of epigenetics in the etiology of disease, including cancer development and progression, is increasingly being recognized. However, the relevance of epigenetics to the metabolic syndrome, and how it may affect cancer, is only beginning to capture the interest of the scientific community. This review focuses on data supporting the hypothesis that, in addition to the "thrifty genotype" and "thrifty phenotype" hypotheses, diet-induced changes in "epigenetic programming" during fetal and postnatal development may precipitate the metabolic syndrome. Thus, epigenetics may bridge both the thrifty genotype and thrifty phenotype hypotheses and provide a link between genes and the environment concerning disease predisposition to metabolic syndrome and its associated diseases.

Amplification of GC-rich genes by following a combination strategy of primer design, enhancers and modified PCR cycle conditions

PCR amplification failure from cDNA libraries or RNA templates, under the optimal conditions is generally attributed to high GC content. Utilization of various additives without thorough analysis of secondary structures of the template as well as primers and subsequent PCR cycle conditions, generally leads to inadequate yields and/or truncated products. To address these concerns, we have examined two highly GC-rich human genes namely insulin receptor (IR) and cSRC kinase. In silico analysis of these genes revealed that their -5' and -3' sequences have > 80% GC content. Primers designed through these GC-rich regions had high self-dimer free energy values (DeltaG). Null mutations were introduced to bring down these DeltaG levels below -5.0 kcal/mol. Oligo(dT)18 primed cDNA was synthesized from HepG2 and HT29 total RNA to amplify IR and cSRC kinase ORFs, respectively. A multi-prong strategy including primer modifications, various DMSO-betaine combinations and high denaturing temperature conditions was pursued during cDNA synthesis to achieve optimal PCR amplification. The reported approach can be utilized to improve the amplification of templates with high GC content, which are otherwise relatively difficult to resolve.

An efficient and economic enhancer mix for PCR

Polymerase chain reaction (PCR) has become a fundamental technique in molecular biology. Nonetheless, further improvements of the existing protocols are required to broaden the applicability of PCR for routine diagnostic purposes, to enhance the specificity and the yield of PCRs as well as to reduce the costs for high-throughput applications. One known problem typically reported in PCR experiments is the poor amplification of GC-rich DNA sequences. Here we designed and tested a novel effective and low-cost PCR enhancer, a concentration-dependent combination of betaine, dithiothreitol, and dimethyl sulfoxide that broadly enhanced the quantitative and/or qualitative output of PCRs. Additionally, we showed that the performances of this enhancer mix are comparable to those of commercially available PCR additives and highly effective with different DNA polymerases. Thus, we propose the routine application of this PCR enhancer mix for low- and high-throughput experiments.