The document describes RT2 Profiler PCR Arrays, which allow for pathway-focused gene expression profiling using real-time PCR. The PCR Arrays contain primer sets for 84 relevant genes, plus controls. They have been shown to have high sensitivity, specificity, and reproducibility. The complete system includes optimized primer assays, master mixes, and a first strand synthesis kit. Researchers can use pre-designed arrays focused on biological pathways or diseases, or customize arrays as needed.
The document describes RT2 Profiler PCR Arrays, which allow for pathway-focused gene expression profiling using real-time PCR. The system combines the quantitative performance of real-time PCR with the multiple-gene profiling capability of microarrays. Each array profiles the expression of 84 genes relevant to a specific pathway or disease state, along with controls. The arrays have high sensitivity, reproducibility and specificity for accurate comparison of gene expression levels. They provide a reliable tool for scientists to efficiently analyze gene expression of a focused panel of genes related to their research.
RT2 Profiler PCR Arrays: Pathway-focused Gene Expression Profiling with qRT-P...QIAGEN
This paper evaluates the performance of the newest technique for monitoring the expression of a panel of pathway- or disease-specific genes: the RT2 Profiler PCR Array System. The RT2 Profiler PCR Array System combines the quantitative performance of SYBR® Green real-time PCR with the multiple-gene profiling capabilities of a microarray.
The RT2 Profiler PCR Array is a 96- or 384-well plate containing RT2 qPCR Primer Assays for a set of 84 related genes, plus 5 housekeeping genes and 3 controls. The complete system includes an instrument-specific master mix and an optimized first strand synthesis kit. This paper presents experimental data showing that RT2 Profiler PCR Arrays have the sensitivity, reproducibility, and specificity expected from real-time PCR techniques. As a result, this technology brings focused gene expression profiling to any biological laboratory setting with a real-time PCR instrument.
Multicopy reference assay (MRef) — a superior normalizer of sample input in D...QIAGEN
Copy number variations (CNVs) and alterations (CNAs) are a source of genetic diversity in humans and are often pathogenic. Numerous CNVs and CNAs are being identified with various genome analysis platforms, including array comparative genomic hybridization (aCGH), single nucleotide polymorphism (SNP) genotyping platforms, and next-generation sequencing. Independent verification of copy number changes is a critical step. Quantitative real-time PCR (qPCR) is a classic method to verify microarray copy number findings. Traditional copy number assays that use qPCR typically rely on a putative single-copy gene reference assay (e.g., RNase P or TERT) to normalize the DNA input for downstream ΔΔCT-based copy number calculation for comparison to a reference genome. When applied to cancer samples, these single-copy reference assays may no longer be a reliable indicator of DNA input due to the presence of complex chromosome composition (both in chromosome number and structure). To meet the need for an accurate DNA input normalizer, especially for heterogeneous tumor samples, QIAGEN developed a multicopy reference (MRef) assay for real-time PCR copy number analysis. This assay, in conjunction with QIAGEN’s greater than 10 million genomewide copy number assays and pathway- and disease-focused copy number PCR arrays (Figure 1), provides a successful solution for copy number analysis. This article will address the assay design considerations, development, and performance of this multicopy reference (MRef) assay.
RT2 qPCR Primer Assays are specifically designed gene expression analysis tools that use SYBR Green-based quantitative real-time PCR, with each assay being experimentally verified to ensure amplification of a single correct-sized product with uniform high PCR efficiency (>90%) for accurate comparisons of gene expression levels. The assays have a wide linear dynamic range, high performance equivalent to TaqMan assays, and coverage of every human, mouse and rat gene for easy multiple gene expression profiling. RT2 qPCR Primer Assays deliver reliable results and convenience when used with optimized RT2 qPCR Master Mixes for various real-time PCR instruments.
The document provides an overview of PCR array technology for gene expression analysis from QIAGEN. It describes how RT2 Profiler PCR arrays work to simultaneously analyze the expression of multiple pathway-focused genes. Popular array types are listed, including inflammatory cytokines and receptors, oxidative stress, and stem cell arrays. The document highlights the simplicity, performance, and relevance of PCR arrays for expression profiling. It also provides examples of array applications in angiogenesis, cancer biomarker discovery, immune response, and determining drug toxicity.
A field-deployable RT-PCR system performs equivalently to real-time RT-PCR in...Simon Chung - genereach
A field-deployable RT-PCR system was found to perform equivalently to real-time RT-PCR in detecting type 2 porcine reproductive and respiratory syndrome virus (PRRSV). The field-deployable system provided results within 2 hours compared to 2.5 days for laboratory RT-PCR. Testing 50 vaccinated and 50 unvaccinated piglets over 11 weeks showed 96.25% agreement between the two methods. The field-deployable PCR system has potential for timely PRRSV detection and biosecurity management at points of need.
10 Tips to maximize your Real Time PCR Success - Download the Technical NoteQIAGEN
This document provides 10 tips for maximizing success with real-time PCR. The tips include using high-quality nucleic acid templates, determining template concentration and purity, checking storage conditions, using the optimal template amount, determining reaction efficiency for each primer pair, properly storing primers and probes, preventing contamination, thoroughly mixing reaction components, performing necessary control reactions, and double checking cycler settings.
Real-time quantitative PCR (qPCR) is a preferred platform for high throughput gene expression profiling, where large numbers of samples are characterized for hundreds of expression markers. Technically, the qPCR measurements are performed in the same way as when classical qPCR is used to analyze only a few targets per sample, but the higher throughput introduces additional sources of potential confounding variation that must be controlled for. In this presentation, Dr Kubista describes how high throughput qPCR profiling studies are designed. He covers assay optimization and validation, sample quality testing, and how to merge multi-plate measurements into a common analysis. Dr Kubista also discusses how to cost-effectively measure and compensate for background due to genomic DNA.
The document describes RT2 Profiler PCR Arrays, which allow for pathway-focused gene expression profiling using real-time PCR. The system combines the quantitative performance of real-time PCR with the multiple-gene profiling capability of microarrays. Each array profiles the expression of 84 genes relevant to a specific pathway or disease state, along with controls. The arrays have high sensitivity, reproducibility and specificity for accurate comparison of gene expression levels. They provide a reliable tool for scientists to efficiently analyze gene expression of a focused panel of genes related to their research.
RT2 Profiler PCR Arrays: Pathway-focused Gene Expression Profiling with qRT-P...QIAGEN
This paper evaluates the performance of the newest technique for monitoring the expression of a panel of pathway- or disease-specific genes: the RT2 Profiler PCR Array System. The RT2 Profiler PCR Array System combines the quantitative performance of SYBR® Green real-time PCR with the multiple-gene profiling capabilities of a microarray.
The RT2 Profiler PCR Array is a 96- or 384-well plate containing RT2 qPCR Primer Assays for a set of 84 related genes, plus 5 housekeeping genes and 3 controls. The complete system includes an instrument-specific master mix and an optimized first strand synthesis kit. This paper presents experimental data showing that RT2 Profiler PCR Arrays have the sensitivity, reproducibility, and specificity expected from real-time PCR techniques. As a result, this technology brings focused gene expression profiling to any biological laboratory setting with a real-time PCR instrument.
Multicopy reference assay (MRef) — a superior normalizer of sample input in D...QIAGEN
Copy number variations (CNVs) and alterations (CNAs) are a source of genetic diversity in humans and are often pathogenic. Numerous CNVs and CNAs are being identified with various genome analysis platforms, including array comparative genomic hybridization (aCGH), single nucleotide polymorphism (SNP) genotyping platforms, and next-generation sequencing. Independent verification of copy number changes is a critical step. Quantitative real-time PCR (qPCR) is a classic method to verify microarray copy number findings. Traditional copy number assays that use qPCR typically rely on a putative single-copy gene reference assay (e.g., RNase P or TERT) to normalize the DNA input for downstream ΔΔCT-based copy number calculation for comparison to a reference genome. When applied to cancer samples, these single-copy reference assays may no longer be a reliable indicator of DNA input due to the presence of complex chromosome composition (both in chromosome number and structure). To meet the need for an accurate DNA input normalizer, especially for heterogeneous tumor samples, QIAGEN developed a multicopy reference (MRef) assay for real-time PCR copy number analysis. This assay, in conjunction with QIAGEN’s greater than 10 million genomewide copy number assays and pathway- and disease-focused copy number PCR arrays (Figure 1), provides a successful solution for copy number analysis. This article will address the assay design considerations, development, and performance of this multicopy reference (MRef) assay.
RT2 qPCR Primer Assays are specifically designed gene expression analysis tools that use SYBR Green-based quantitative real-time PCR, with each assay being experimentally verified to ensure amplification of a single correct-sized product with uniform high PCR efficiency (>90%) for accurate comparisons of gene expression levels. The assays have a wide linear dynamic range, high performance equivalent to TaqMan assays, and coverage of every human, mouse and rat gene for easy multiple gene expression profiling. RT2 qPCR Primer Assays deliver reliable results and convenience when used with optimized RT2 qPCR Master Mixes for various real-time PCR instruments.
The document provides an overview of PCR array technology for gene expression analysis from QIAGEN. It describes how RT2 Profiler PCR arrays work to simultaneously analyze the expression of multiple pathway-focused genes. Popular array types are listed, including inflammatory cytokines and receptors, oxidative stress, and stem cell arrays. The document highlights the simplicity, performance, and relevance of PCR arrays for expression profiling. It also provides examples of array applications in angiogenesis, cancer biomarker discovery, immune response, and determining drug toxicity.
A field-deployable RT-PCR system performs equivalently to real-time RT-PCR in...Simon Chung - genereach
A field-deployable RT-PCR system was found to perform equivalently to real-time RT-PCR in detecting type 2 porcine reproductive and respiratory syndrome virus (PRRSV). The field-deployable system provided results within 2 hours compared to 2.5 days for laboratory RT-PCR. Testing 50 vaccinated and 50 unvaccinated piglets over 11 weeks showed 96.25% agreement between the two methods. The field-deployable PCR system has potential for timely PRRSV detection and biosecurity management at points of need.
10 Tips to maximize your Real Time PCR Success - Download the Technical NoteQIAGEN
This document provides 10 tips for maximizing success with real-time PCR. The tips include using high-quality nucleic acid templates, determining template concentration and purity, checking storage conditions, using the optimal template amount, determining reaction efficiency for each primer pair, properly storing primers and probes, preventing contamination, thoroughly mixing reaction components, performing necessary control reactions, and double checking cycler settings.
Real-time quantitative PCR (qPCR) is a preferred platform for high throughput gene expression profiling, where large numbers of samples are characterized for hundreds of expression markers. Technically, the qPCR measurements are performed in the same way as when classical qPCR is used to analyze only a few targets per sample, but the higher throughput introduces additional sources of potential confounding variation that must be controlled for. In this presentation, Dr Kubista describes how high throughput qPCR profiling studies are designed. He covers assay optimization and validation, sample quality testing, and how to merge multi-plate measurements into a common analysis. Dr Kubista also discusses how to cost-effectively measure and compensate for background due to genomic DNA.
This document provides guidance on designing quantitative PCR (qPCR) assays for specific applications, including species-specific, strain-specific, and copy number variation (CNV) assays. It outlines general design strategies and considerations, including using sequence alignments to identify unique target regions and primers that avoid nonspecific amplification. Examples are provided for designing assays to distinguish similar genes in Arabidopsis thaliana and related viral strains. Design of CNV assays is also discussed, highlighting the importance of a single-copy reference gene.
qPCR assays using intercalating dyes, such as SYBR® Green dye, are an economical and effective tool for measuring gene expression. To interpret intercalating dye assays, users need to know how to analyze melt curves, and understand the benefits and limitations of melt curve analysis. In this presentation, Nick Downey, PhD, covers melt curve basics and shares examples of multiple peaks due to suboptimal sample prep, primer dimers, and asymmetric GC content of amplicons. He demonstrates troubleshooting strategies. Experienced and novice users will benefit from an overview of uMeltSM software, developed by the Wittwer lab at the University of Utah, that can predict the melt profile of your assay before you run your experiment.
PCR - From Setup to Cleanup: A Beginner`s Guide with Useful Tips and Tricks -...QIAGEN
This End-Point PCR Beginner´s Guide will not only give you a comprehensive overview of tools and techniques to help you to get the most out of your samples, but also give you information on dedicated solutions and complete workflows on multiplex PCR and PCR fragment analysis.
This document summarizes a presentation about RNase H2 PCR (rhPCR), a new molecular technology that uses an RNA residue in PCR primers and a thermostable RNase H2 enzyme. It describes how rhPCR works, the advantages it provides over traditional PCR including reduced primer-dimer formation and improved specificity for rare allele detection. Two generations of cleavable primer designs - GEN1 and GEN2 - are discussed, along with their different applications. Examples are provided that demonstrate how rhPCR can improve assays for SNP genotyping, multiplex PCR, and detection in complex backgrounds.
PCR Array Data Analysis Tutorial: qPCR Technology Webinar Series Part 3QIAGEN
This webinar presentation provides an overview and tutorial on analyzing data from RT2 Profiler PCR Array experiments. It discusses organizing raw Ct value data, performing ΔCt and ΔΔCt calculations to analyze gene expression changes between sample groups, and using the GeneGlobe Data Analysis Center web portal to analyze the data. The webinar highlights new features of the Data Analysis Center including improved data visualization and an upgraded sample manager. It emphasizes following the standard protocol for setting baselines and thresholds when analyzing PCR array data.
1) The document presents a statistical error model for analyzing sources of variance in real-time PCR based RNAi validation. It finds that greater than 80% transfection efficiency is needed for reliable results.
2) The model shows that both biological and technical replicates are essential to account for variance from transfection and PCR. It recommends a minimum of three replicates for each RNAi experiment.
3) Applying the model to a case study of 119 shRNA sequences targeting 32 genes, the measured knockdowns matched well with the theoretical variance estimates, validating the error model.
1073958 wp guide-develop-pcr_primers_1012Elsa von Licy
methods analyze the exponential phase of individual amplification
1. The document outlines guidelines for developing high-quality real-time PCR primers based on lessons from designing assays for over 14,000 genes.
plots. Regardless of the method, efficiencies between 90-110
2. Key factors in primer design include thermodynamic properties, specificity testing to ensure a single amplicon, and verification of high amplification efficiency and reproducibility.
percent are generally acceptable for accurate analysis by the
3. Wet-bench testing of primers is crucial to validate specificity with single peak melt curves and correct sized products on gels, as well as high efficiency.
∆∆CT method.
This document summarizes a presentation given by Dr. Jo Vandesompele on state-of-the-art normalization of RT-qPCR data. It discusses the importance of normalization to remove experimental variation and introduces the geNorm algorithm for determining the optimal number and combination of reference genes for normalization. GeNorm has become the standard method for reference gene validation and normalization and has improved qPCR data analysis. The document also proposes a novel global mean normalization strategy for large-scale gene expression studies.
Critical Factors for Successful Real-Time PCR: Multiplex PCRQIAGEN
Multiplex end-point PCR is a powerful tool for genotyping and many other applications. QIAGEN’s multiplex PCR chemistry is optimized for reliable amplification of many different templates with high variability in copy numbers. Thus it enables very quick establishment of a new lab routine and instant success for your multiplex PCR strategy.
There is a set of critical factors which we recommend to be regarded for planning and performing this kind of PCR. These will be discussed in detail in the webinar. Additionally, our multiplex PCR chemistry has recently been gaining increasing popularity among scientists who are utilizing it for their next-generation sequencing workflows.
Learn about the power of LNA (Locked Nucleic Acid) technology and QIAGEN's LNA enhanced product portfolio for RNA and DNA research. Download the slide deck!
Cancer therapies that target specific pathways can be more effective than established, nonspecific chemotherapy and radiation treatments, and may prevent side effects on healthy tissues. Such targeted therapies can only be applied after underlying gene mutations have been identified. However, detecting low frequency variants from clinically relevant samples poses significant challenges. Specimens are routinely formalin-fixed and paraffin-embedded (FFPE) for histology, which can decrease the efficiency of NGS library preparation. In this presentation, we discuss approaches for extraction of DNA from FFPE samples, and recommend quality control assays to guide parameter selection for library construction and sequencing depth.
Reproducibility, Quality Control and Importance of AutomationQIAGEN
In this webinar, we will introduce you to the key sample quality parameters, discuss their respective impact on downstream applications and how to monitor them, and present the advantages of automating quality control along complex workflows.
The document discusses BioChain's products for PCR and sample preparation, including PCR enzymes, reverse transcriptases, master mixes, dNTPs, and supporting reagents. It provides details on BioChain's Taq DNA polymerase and Hot Start Taq DNA polymerase, which are produced under strict quality control. It also describes BioChain's UltraScript reverse transcriptase, which is ideal for cDNA synthesis of templates with secondary structure or high GC content. Furthermore, it mentions BioChain's pre-mixed master mixes for standard and quantitative PCR, which offer convenience and reproducibility.
Struggling with low editing efficiency or delivery problems? IDT has developed a simple and affordable CRISPR-Cas9 solution that outperforms other methods. In this presentation we present the advantages of using a Cas9:tracrRNA:crRNA ribonucleoprotein (RNP) complex in genome editing experiments, and explain why it is the most efficient driver for genome editing compared to alternative methods, such as expression plasmids or the use of sgRNAs. We also review RNP delivery using cationic lipids and electroporation, and provide tips for optimized transfection in your system.
This document describes how real-time PCR can be used to validate microarray data. Real-time PCR provides a quantitative and sensitive method for confirming changes in gene expression observed in microarray experiments. The document outlines a protocol for designing and running a real-time PCR experiment to validate a specific result from a microarray experiment showing increased expression of the TNFAIP3 gene in response to TNFα treatment. Key steps in the protocol include performing reverse transcription of RNA to generate cDNA, setting up a standard curve and controls, and analyzing the real-time PCR data to calculate fold-changes in gene expression.
Extending miRQC’s dynamic range: amplifying the view of Limiting RNA samples ...QIAGEN
The original microRNA quality control (miRQC) study provided an in-depth analysis of commercially available microRNA (miRNA) quantification platforms. Specifically, twelve different
microarray, real-time PCR and small RNA sequencing platforms were assessed for reproducibility, sensitivity, accuracy, specificity and concordance of differential expression using a variety of sample types. Overall, each platform exhibited specific strengths and weaknesses, leading to the
final suggestion that a platform should be chosen on the basis of the experimental setting and the specific research questions. With this suggestion in mind, and the fact that liquid miRNA biopsies are an area of intense interest, we sought to expand the original miRQC study. For our “miRQC extension,” we benchmarked the QIAGEN miScript® PCR System with and without preamplification, and included a specific focus on routinely used biofluids. Concurrently, we benchmarked the miScript PCR System against another SYBR® Green miRNA detection platform. Overall, QIAGEN miScript demonstrated strong reproducibility and accuracy as well as superior detection rate and sensitivity in biofluids. Collectively, QIAGEN miScript provides the leading solution for novel miRNA discoveries.
Real-Time quantitative PCR (qPCR) is a mainstream method that is used in research and diagnostic applications for quantification of gene expression. IDT has developed a robust and affordable qPCR master mix for use with probe-based qPCR in single and multiplex assays. In this presentation, we explore a variety of applications of PrimeTime® Gene Expression Master Mix. We cover the use of PrimeTime master mix with probe based assays from IDT. We also look at the use of PrimeTime master mix in multiplex applications without the loss of sensitivity that is commonly observed. Finally, we demonstrate the unmatched stability of PrimeTime master mix under ambient temperatures, saving your research money and minimizing on shipping delays.
RT2 Profiler PCR Arrays are a real-time PCR technology that allows researchers to study gene expression patterns across biological pathways and processes. The arrays contain pre-designed primer assays for 84 relevant genes as well as controls on a single plate in a 96-well format. The gene content of the arrays is selected based on biological relevance and published associations with relevant pathways. The primer assays on the arrays undergo extensive validation for sensitivity, specificity, reproducibility, and amplification efficiency. The PCR Array system also includes optimized components for RNA isolation, cDNA synthesis, and real-time PCR to provide a complete validated workflow for gene expression analysis from sample to results.
The document discusses using NCBI databases to design quantitative PCR (qPCR) assays. It describes several NCBI tools that can be used:
1) The NCBI Nucleotide and Gene databases to obtain sequence information for the gene of interest.
2) NCBI BLAST to perform sequence searches and check primer specificity against relevant databases.
3) NCBI dbSNP to search for single nucleotide polymorphisms (SNPs) in the primer binding sites that could affect assay performance.
The document provides guidance on how to use these NCBI tools at various steps of the qPCR assay design process.
Technical Guide to Qiagen PCR Arrays - Download the GuideQIAGEN
Total RNA discovery with RT2 and miScript PCR Arrays : Explore the RNA universe - Whatever your destination within the RNA universe, QIAGEN will help you get there. The miRNeasy kits deliver pure, high-quality total RNA from a broad range of samples. The RT2 and miScript PCR arrays are a complete solution both for focused analysis of gene and microRNA expression and for validation of microarray and RNA sequencing experiments. Together with the powerful analytics tools of GeneGlobe® and QIAGEN Ingenuity® Pathway Analysis, these products give you a smooth path from your sample to high-quality results.
RT2 qPCR Primer Assays are specifically designed gene expression analysis tools that use SYBR Green-based quantitative real-time PCR, with each assay being experimentally verified to ensure amplification of a single correct-sized product with uniform high PCR efficiency (>90%) for accurate comparisons of gene expression levels. The assays have a wide linear dynamic range, high performance equivalent to TaqMan assays, and coverage of every human, mouse and rat gene for easy multiple gene expression profiling. RT2 qPCR Primer Assays deliver reliable results and convenience when used with optimized RT2 qPCR Master Mixes for various real-time PCR instruments.
This document provides guidance on designing quantitative PCR (qPCR) assays for specific applications, including species-specific, strain-specific, and copy number variation (CNV) assays. It outlines general design strategies and considerations, including using sequence alignments to identify unique target regions and primers that avoid nonspecific amplification. Examples are provided for designing assays to distinguish similar genes in Arabidopsis thaliana and related viral strains. Design of CNV assays is also discussed, highlighting the importance of a single-copy reference gene.
qPCR assays using intercalating dyes, such as SYBR® Green dye, are an economical and effective tool for measuring gene expression. To interpret intercalating dye assays, users need to know how to analyze melt curves, and understand the benefits and limitations of melt curve analysis. In this presentation, Nick Downey, PhD, covers melt curve basics and shares examples of multiple peaks due to suboptimal sample prep, primer dimers, and asymmetric GC content of amplicons. He demonstrates troubleshooting strategies. Experienced and novice users will benefit from an overview of uMeltSM software, developed by the Wittwer lab at the University of Utah, that can predict the melt profile of your assay before you run your experiment.
PCR - From Setup to Cleanup: A Beginner`s Guide with Useful Tips and Tricks -...QIAGEN
This End-Point PCR Beginner´s Guide will not only give you a comprehensive overview of tools and techniques to help you to get the most out of your samples, but also give you information on dedicated solutions and complete workflows on multiplex PCR and PCR fragment analysis.
This document summarizes a presentation about RNase H2 PCR (rhPCR), a new molecular technology that uses an RNA residue in PCR primers and a thermostable RNase H2 enzyme. It describes how rhPCR works, the advantages it provides over traditional PCR including reduced primer-dimer formation and improved specificity for rare allele detection. Two generations of cleavable primer designs - GEN1 and GEN2 - are discussed, along with their different applications. Examples are provided that demonstrate how rhPCR can improve assays for SNP genotyping, multiplex PCR, and detection in complex backgrounds.
PCR Array Data Analysis Tutorial: qPCR Technology Webinar Series Part 3QIAGEN
This webinar presentation provides an overview and tutorial on analyzing data from RT2 Profiler PCR Array experiments. It discusses organizing raw Ct value data, performing ΔCt and ΔΔCt calculations to analyze gene expression changes between sample groups, and using the GeneGlobe Data Analysis Center web portal to analyze the data. The webinar highlights new features of the Data Analysis Center including improved data visualization and an upgraded sample manager. It emphasizes following the standard protocol for setting baselines and thresholds when analyzing PCR array data.
1) The document presents a statistical error model for analyzing sources of variance in real-time PCR based RNAi validation. It finds that greater than 80% transfection efficiency is needed for reliable results.
2) The model shows that both biological and technical replicates are essential to account for variance from transfection and PCR. It recommends a minimum of three replicates for each RNAi experiment.
3) Applying the model to a case study of 119 shRNA sequences targeting 32 genes, the measured knockdowns matched well with the theoretical variance estimates, validating the error model.
1073958 wp guide-develop-pcr_primers_1012Elsa von Licy
methods analyze the exponential phase of individual amplification
1. The document outlines guidelines for developing high-quality real-time PCR primers based on lessons from designing assays for over 14,000 genes.
plots. Regardless of the method, efficiencies between 90-110
2. Key factors in primer design include thermodynamic properties, specificity testing to ensure a single amplicon, and verification of high amplification efficiency and reproducibility.
percent are generally acceptable for accurate analysis by the
3. Wet-bench testing of primers is crucial to validate specificity with single peak melt curves and correct sized products on gels, as well as high efficiency.
∆∆CT method.
This document summarizes a presentation given by Dr. Jo Vandesompele on state-of-the-art normalization of RT-qPCR data. It discusses the importance of normalization to remove experimental variation and introduces the geNorm algorithm for determining the optimal number and combination of reference genes for normalization. GeNorm has become the standard method for reference gene validation and normalization and has improved qPCR data analysis. The document also proposes a novel global mean normalization strategy for large-scale gene expression studies.
Critical Factors for Successful Real-Time PCR: Multiplex PCRQIAGEN
Multiplex end-point PCR is a powerful tool for genotyping and many other applications. QIAGEN’s multiplex PCR chemistry is optimized for reliable amplification of many different templates with high variability in copy numbers. Thus it enables very quick establishment of a new lab routine and instant success for your multiplex PCR strategy.
There is a set of critical factors which we recommend to be regarded for planning and performing this kind of PCR. These will be discussed in detail in the webinar. Additionally, our multiplex PCR chemistry has recently been gaining increasing popularity among scientists who are utilizing it for their next-generation sequencing workflows.
Learn about the power of LNA (Locked Nucleic Acid) technology and QIAGEN's LNA enhanced product portfolio for RNA and DNA research. Download the slide deck!
Cancer therapies that target specific pathways can be more effective than established, nonspecific chemotherapy and radiation treatments, and may prevent side effects on healthy tissues. Such targeted therapies can only be applied after underlying gene mutations have been identified. However, detecting low frequency variants from clinically relevant samples poses significant challenges. Specimens are routinely formalin-fixed and paraffin-embedded (FFPE) for histology, which can decrease the efficiency of NGS library preparation. In this presentation, we discuss approaches for extraction of DNA from FFPE samples, and recommend quality control assays to guide parameter selection for library construction and sequencing depth.
Reproducibility, Quality Control and Importance of AutomationQIAGEN
In this webinar, we will introduce you to the key sample quality parameters, discuss their respective impact on downstream applications and how to monitor them, and present the advantages of automating quality control along complex workflows.
The document discusses BioChain's products for PCR and sample preparation, including PCR enzymes, reverse transcriptases, master mixes, dNTPs, and supporting reagents. It provides details on BioChain's Taq DNA polymerase and Hot Start Taq DNA polymerase, which are produced under strict quality control. It also describes BioChain's UltraScript reverse transcriptase, which is ideal for cDNA synthesis of templates with secondary structure or high GC content. Furthermore, it mentions BioChain's pre-mixed master mixes for standard and quantitative PCR, which offer convenience and reproducibility.
Struggling with low editing efficiency or delivery problems? IDT has developed a simple and affordable CRISPR-Cas9 solution that outperforms other methods. In this presentation we present the advantages of using a Cas9:tracrRNA:crRNA ribonucleoprotein (RNP) complex in genome editing experiments, and explain why it is the most efficient driver for genome editing compared to alternative methods, such as expression plasmids or the use of sgRNAs. We also review RNP delivery using cationic lipids and electroporation, and provide tips for optimized transfection in your system.
This document describes how real-time PCR can be used to validate microarray data. Real-time PCR provides a quantitative and sensitive method for confirming changes in gene expression observed in microarray experiments. The document outlines a protocol for designing and running a real-time PCR experiment to validate a specific result from a microarray experiment showing increased expression of the TNFAIP3 gene in response to TNFα treatment. Key steps in the protocol include performing reverse transcription of RNA to generate cDNA, setting up a standard curve and controls, and analyzing the real-time PCR data to calculate fold-changes in gene expression.
Extending miRQC’s dynamic range: amplifying the view of Limiting RNA samples ...QIAGEN
The original microRNA quality control (miRQC) study provided an in-depth analysis of commercially available microRNA (miRNA) quantification platforms. Specifically, twelve different
microarray, real-time PCR and small RNA sequencing platforms were assessed for reproducibility, sensitivity, accuracy, specificity and concordance of differential expression using a variety of sample types. Overall, each platform exhibited specific strengths and weaknesses, leading to the
final suggestion that a platform should be chosen on the basis of the experimental setting and the specific research questions. With this suggestion in mind, and the fact that liquid miRNA biopsies are an area of intense interest, we sought to expand the original miRQC study. For our “miRQC extension,” we benchmarked the QIAGEN miScript® PCR System with and without preamplification, and included a specific focus on routinely used biofluids. Concurrently, we benchmarked the miScript PCR System against another SYBR® Green miRNA detection platform. Overall, QIAGEN miScript demonstrated strong reproducibility and accuracy as well as superior detection rate and sensitivity in biofluids. Collectively, QIAGEN miScript provides the leading solution for novel miRNA discoveries.
Real-Time quantitative PCR (qPCR) is a mainstream method that is used in research and diagnostic applications for quantification of gene expression. IDT has developed a robust and affordable qPCR master mix for use with probe-based qPCR in single and multiplex assays. In this presentation, we explore a variety of applications of PrimeTime® Gene Expression Master Mix. We cover the use of PrimeTime master mix with probe based assays from IDT. We also look at the use of PrimeTime master mix in multiplex applications without the loss of sensitivity that is commonly observed. Finally, we demonstrate the unmatched stability of PrimeTime master mix under ambient temperatures, saving your research money and minimizing on shipping delays.
RT2 Profiler PCR Arrays are a real-time PCR technology that allows researchers to study gene expression patterns across biological pathways and processes. The arrays contain pre-designed primer assays for 84 relevant genes as well as controls on a single plate in a 96-well format. The gene content of the arrays is selected based on biological relevance and published associations with relevant pathways. The primer assays on the arrays undergo extensive validation for sensitivity, specificity, reproducibility, and amplification efficiency. The PCR Array system also includes optimized components for RNA isolation, cDNA synthesis, and real-time PCR to provide a complete validated workflow for gene expression analysis from sample to results.
The document discusses using NCBI databases to design quantitative PCR (qPCR) assays. It describes several NCBI tools that can be used:
1) The NCBI Nucleotide and Gene databases to obtain sequence information for the gene of interest.
2) NCBI BLAST to perform sequence searches and check primer specificity against relevant databases.
3) NCBI dbSNP to search for single nucleotide polymorphisms (SNPs) in the primer binding sites that could affect assay performance.
The document provides guidance on how to use these NCBI tools at various steps of the qPCR assay design process.
Technical Guide to Qiagen PCR Arrays - Download the GuideQIAGEN
Total RNA discovery with RT2 and miScript PCR Arrays : Explore the RNA universe - Whatever your destination within the RNA universe, QIAGEN will help you get there. The miRNeasy kits deliver pure, high-quality total RNA from a broad range of samples. The RT2 and miScript PCR arrays are a complete solution both for focused analysis of gene and microRNA expression and for validation of microarray and RNA sequencing experiments. Together with the powerful analytics tools of GeneGlobe® and QIAGEN Ingenuity® Pathway Analysis, these products give you a smooth path from your sample to high-quality results.
RT2 qPCR Primer Assays are specifically designed gene expression analysis tools that use SYBR Green-based quantitative real-time PCR, with each assay being experimentally verified to ensure amplification of a single correct-sized product with uniform high PCR efficiency (>90%) for accurate comparisons of gene expression levels. The assays have a wide linear dynamic range, high performance equivalent to TaqMan assays, and coverage of every human, mouse and rat gene for easy multiple gene expression profiling. RT2 qPCR Primer Assays deliver reliable results and convenience when used with optimized RT2 qPCR Master Mixes for various real-time PCR instruments.
RT2 Profiler PCR Arrays allow researchers to analyze gene expression profiles for focused panels of genes involved in biological pathways or disease states. The arrays provide laboratory-verified gene assays, integrated controls, and free data analysis software to generate a gene expression profile from a sample in less than 3 hours. Popular arrays analyze pathways such as extracellular matrix and adhesion molecules, WNT signaling, and cancer-related genes. The complete workflow begins with sample preparation and ends with data interpretation and publication of results.
This slidedeck presents a simple and accurate real-time PCR system for relevant biological pathway- and disease-focused mRNA and long noncoding RNA (lncRNA) expression profiling. Learn about the stringent performance built into the technology to ensure its sensitivity, specificity, reproducibility and reliability. Application examples are also presented.
This document provides an overview of real-time PCR, including commonly used formats, the basic steps involved in real-time PCR, and an overview of key reaction components. Real-time PCR allows for quantification of DNA or RNA sequences by measuring fluorescent signals during each PCR cycle. It discusses single-tube assays, multi-well plates, and array cards as common formats. The basic steps of real-time PCR involve denaturation, annealing of primers, and extension by DNA polymerase in each cycle. Key components that can affect results are the DNA polymerase, reverse transcriptase, dNTPs, magnesium concentration, and template quality and quantity.
The RT2Profiler PCR Array allows for the simultaneous analysis of 84 genes related to specific pathways using real-time PCR. It provides consistent and reproducible results that correlate well with other gene expression platforms such as microarrays and TaqMan assays. The document demonstrates the array's wide dynamic range, high amplification efficiency, and ability to accurately identify differentially expressed genes between normal and tumor tissue samples.
This document summarizes a study comparing gene expression results from a SYBR Green-based real-time PCR array to other technologies using two reference RNA samples. The PCR array showed high reproducibility and accuracy when compared to quantitative PCR methods like TaqMan and microarray platforms. There was a high degree of overlap between differentially expressed gene lists from the PCR array and other technologies. The PCR array provides a convenient, cost-effective way to simultaneously analyze expression of multiple genes related to the same pathway using validated primers.
PCR (polymerase chain reaction) is a technique that allows millions of copies of a specific DNA fragment to be produced. It involves repeated cycles of heating and cooling of the DNA sample in the presence of primers and a DNA polymerase. This allows for the targeted amplification of the DNA region between the primers. Real-time PCR (qPCR) allows for quantitative analysis of the amount of DNA present in samples and is commonly used for gene expression analysis and detection of pathogens.
This document provides an overview of RT2 Profiler PCR Arrays from SABiosciences, which allow for gene expression analysis from small samples and FFPE samples. The document discusses how PCR Arrays work using SABiosciences' PreAMP technology to increase sensitivity for samples containing as little as 1-100ng of RNA. It also reviews the performance data demonstrating the ability of PreAMP to detect more genes and shift genes with high Ct values into the detectable range. Finally, it highlights the complete PCR Array system from SABiosciences which provides optimized kits, controls, and software for reliable gene expression analysis from sample to results in about 3 hours.
This document describes a real-time PCR array for simultaneously evaluating the expression of multiple cytokine mRNAs. The RT2Profiler PCR Array allows detection of 84 cytokine-related genes with high reproducibility, specificity, efficiency and sensitivity. The array was used to identify cytokines upregulated or downregulated in peripheral blood mononuclear cells stimulated with PMA and ionomycin compared to unstimulated cells. Twenty-nine genes showed at least a 5-fold change in expression, and protein level changes measured by ELISA were consistent with mRNA changes detected by the array. The PCR array provides a reliable tool for profiling cytokine gene expression.
This document describes a real-time PCR array for simultaneously evaluating the expression of multiple cytokine mRNAs. The RT2Profiler PCR Array demonstrated high reproducibility, specificity, efficiency, sensitivity, and linear dynamic range. Using this array, 29 genes were found to have at least a 5-fold change in expression between resting and stimulated peripheral blood mononuclear cells after 6 hours of stimulation. The array provides a reliable tool for profiling cytokine pathway gene expression.
This document provides an introduction to real-time quantitative PCR (qPCR). It discusses what qPCR is, how it works, its applications and workflow. Specifically, it explains that qPCR allows for monitoring of PCR reactions during early and exponential phases to quantify initial amounts of target templates. It also outlines common applications like gene expression analysis, discusses important considerations for assay design and optimization, and provides an overview of the basic qPCR workflow from sample preparation to data analysis.
Gene Expression Assay Performance Guaranteed With the TaqMan® Assays QPCR Gua...Thermo Fisher Scientific
Real-time or quantitative PCR (qPCR) is one of the most powerful and sensitive techniques available for gene expression analysis. It is used for a broad range of applications, including quantification of gene expression, measuring RNA interference, biomarker discovery, pathogen detection, and drug target validation. When studying gene expression with qPCR, scientists usually investigate changes—increases or decreases—in the quantity of particular gene products or a set of gene products. Investigations typically evaluate gene response to biological conditions such as disease states, exposure to pathogens or chemical compounds, the organ or tissue location, or cell cycle or differentiation status.
Real-time PCR for the quantification of gene expression using the 5’ nuclease assay with TaqMan® probes has become a standard method in basic and clinical research.
http://owl.li/dgR59
The ArrayGradeTM FFPE RNA isolation kit provides a more effective method for isolating RNA from formalin-fixed paraffin-embedded (FFPE) tissue samples. It yields RNA of higher quantity and quality compared to other commercial kits. The RNA isolated has greater compatibility with microarray and real-time PCR applications, providing more positive results and sensitivity. This allows researchers to reliably perform gene expression profiling on archived FFPE samples to gain insights into cancer progression and other disease studies.
Real-time PCR is a technique that monitors DNA amplification during the PCR process in real-time using fluorescence detection. It allows for both quantification of DNA present and detection of DNA amplification as it occurs. Real-time PCR has advantages over traditional PCR such as higher sensitivity, specificity, and ability to provide quantitative results. It uses sequence-specific DNA probes labeled with fluorescent dyes and quenchers to detect amplification of target DNA sequences. Data analysis can provide both absolute and relative quantification of DNA targets. Real-time PCR has many applications including gene expression analysis, disease diagnosis, and food and environmental testing.
Introduction to real-Time Quantitative PCR (qPCR) - Download the slidesQIAGEN
This slidedeck introduces the concepts of real-time PCR and how to conduct a real-time PCR assay. The topics that are covered include an overview of real-time PCR chemistries, protocols, quantification methods, real-time PCR applications and factors for success.
qBiomarker Somatic Mutation PCR Arrays are panels of real-time PCR assays that allow for sensitive detection of mutations in 85-370 genes from fresh or FFPE samples. They provide detection of cancer-associated mutations with superior sensitivity compared to other methods using a simple real-time PCR protocol. The document describes the workflow which involves extracting DNA from samples, mixing with mastermix, distributing across the PCR array plate, running on a real-time PCR instrument, and analyzing data to make mutation calls. Examples of available arrays are provided that focus on different cancer types and pathways.
This document describes pathway-powered PCR arrays for gene expression analysis. It discusses:
- PCR arrays that analyze the expression of genes involved in biological pathways, covering sample prep through data analysis.
- Over 140 pathway-focused PCR arrays are available covering cancer, inflammation, neuroscience, and other areas.
- The PCR arrays allow analysis of mRNA expression from various sample types in a high-sensitivity and reproducible manner using real-time PCR instrumentation.
The document summarizes qBiomarker Somatic Mutation PCR Arrays, which are PCR-based assays that can rapidly and accurately detect somatic mutations in cancer samples. The arrays can detect mutations present at as little as 0.01% of DNA in a sample. They have been validated to work reliably with different sample types, including archived samples. The arrays cover a wide range of clinically relevant cancer mutations and allow screening of many mutations simultaneously in a single PCR run. The assays and content were selected based on published data on mutation frequencies and functional significance. The arrays provide a simple method for sensitive somatic mutation profiling to aid cancer research.
Styles of Scientific Reasoning, Scientific Practices and Argument in Science ...Elsa von Licy
The document discusses various topics related to scientific reasoning, practices, and argumentation including different styles of scientific thinking, features of scientific knowledge, and teaching and learning science. It provides examples of "crazy ideas" in science that are now accepted, examines the role of argument in science, and outlines the scientific practices and central questions of science. It also discusses developing models, planning investigations, analyzing data, and constructing explanations as key scientific practices.
Anti-philosophy rejects traditional philosophy and logic, instead embracing creativity, spirituality, and personality. It considers philosophy to be dead, kept alive artificially by analytic philosophers. The document criticizes how philosophy is currently taught and argues it has become unproductive, replacing original aims with nonsense. Anti-philosophy's goal is not to destroy philosophy but to transform its current state and avoid fundamentalism in philosophy and science.
There is no_such_thing_as_a_social_science_introElsa von Licy
This document provides an introduction and overview of the arguments made in the book "There is No Such Thing as Social Science". It begins by stating the provocative title and questioning whether the authors will take it back or qualify their position.
It then outlines three ways the term "social science" could be used - referring to a scientific spirit of inquiry, a shared scientific method, or reducibility to natural sciences. The authors argue against the latter two, methodological and substantive reductionism.
The introduction discusses how opponents may accuse the authors of being a priori or anti-reductionist, but argues that those defending social science are actually being dogmatic by insisting it must follow a scientific model. It frames the debate as being
1. TECHNICAL ARTICLE
RT2 Profiler™ PCR Arrays:
Pathway-Focused Gene Expression Profiling with qRT-PCR
Emi Arikawa, George Quellhorst, Ying Han, Hongguang Pan, and Jingping Yang
SABioscience 6951 Executive Way, Frederick, MD 21703 USA
Phone: +1 (301) 682-9200 Fax: +1 (301) 682-7300 Web: www.SABiosciences.com
Email: support@SABiosciences.com
Abstract: This paper evaluates the performance of the newest technique for monitoring the expression of a panel of
pathway- or disease-specific genes: the RT2 Profiler PCR Array System from SA Biosciences. The PCR Array
System combines the quantitative performance of SYBR® Green-based real-time PCR with the multiple gene profiling
capabilities of a microarray. The PCR Array is a 96- or 384-well plate containing RT2 qPCR Primer Assays for a set
of 84 related genes, plus five housekeeping genes, and three controls. A complete system includes an instrumentspecific master mix and an optimized first strand synthesis kit. This paper presents scientific data showing that PCR
Arrays have the sensitivity, reproducibility, and specificity expected from real-time PCR techniques. As a result,
this technology brings focused gene expression profiling to any biological laboratory setting with a real-time PCR
instrument.
Introduction
The RT2 Profiler PCR Array System is the most reliable and accurate
tool for analyzing the expression of a focused panel of genes using
SYBR Green-based real-time PCR. It brings together the quantitative
performance of real-time PCR and the multiple gene profiling
capability of microarrays. Each PCR Array profiles the expression of
84 genes relevant to a specific pathway or disease state. Expression
levels are measured by gene-specific RT2 qPCR Primer Assays
optimized for simultaneous use in the PCR Array System.
RT2 qPCR Primer Assays are key components in the PCR Array
System. Each qPCR assay on the array is uniquely designed for use
in SYBR Green real-time PCR analysis. The assay design criteria
ensure that each qPCR reaction will generate single, gene-specific
amplicons and prevent the co-amplification of non-specific products.
The qPCR Assays used in PCR Arrays are optimized to work under
standard conditions enabling a large number of genes to be assayed
simultaneously. Their specificity is guaranteed by SABiosciences when
RT2 SYBR Green qPCR Master Mixes are used as part of the complete
PCR Array System protocol.
The RT² Profiler PCR Array System is specifically designed to meet
the unique challenges of profiling pathway-focused sets of genes
using real-time PCR. Simultaneous gene expression analyses require
similar qPCR efficiencies for accurate comparison among genes. RT²
qPCR Primer Assays are designed with an amplicon size ranging
from 100 to 250 bp and with PCR efficiencies uniformly greater than
90%. Overall, more than 10 thermodynamic criteria are included in
the design of each RT² qPCR Primer Assay to ensure the most reliable
and accurate results for pathway-based gene expression analysis in
the PCR Array System.
Contents
Introduction........................................................................................
Experimental Protocol .....................................................................
PCR Array Design and Gene Content ...........................................
Pathway-Focused PCR Arrays ..........................................................
Customized PCR Arrays .....................................................................
The Complete PCR Array System ......................................................
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2
2
3
3
3
Why the PCR Array System Works:
Component 1: RT2 PCR Primer Sets........................................ 3
Component 2: RT2 qPCR Master Mixes.................................. 4
Component 3: RT2 First Strand Kit .......................................... 4
PCR Array Performance:
Sensitivity ................................................................................... 4
Specificity .................................................................................. 5
Reproducibility .......................................................................... 5
PCR Array Application Examples
I: Identifying and Monitoring Oncogenic Pathways .................. 6
II: Monitoring Cytokine Expression Levels .................................. 8
Summary ............................................................................................ 10
PCR Array Buyer’s Guide................................................................. 11
2. RT2 Profiler PCR Arrays
2
Experimental Protocol
PCR Array Design and Gene Content
Figure 1 depicts an overview of the PCR Array procedure. The protocol
takes only two hours to perform (per sample) from start to finish. Start by
converting the experimental RNA samples into PCR template with the
RT2 First Strand Kit. Then, combine the template with an instrumentspecific and ready-to-use RT2 SYBR Green qPCR Master Mix. Add
equal aliquots of this mixture (25 μl for 96-well or 10 μl for 384-well
plates) to each well of the same PCR Array plate containing the predispensed gene-specific primer sets, and perform PCR. Use your
instrument’s software to calculate the threshold cycle (Ct) values for
Each RT2 Profiler PCR Array contains gene-specific qPCR assays
for a thoroughly researched set of 84 genes relevant to a pathway
or disease state and three RNA quality control elements (See Figure
2 for the layout of a typical PCR Array). Researchers are able to
focus on genes related to their biological pathway or disease state
with our pre-designed pathway- or application-specific gene panels.
By limiting the range to less than one hundred genes (instead of
thousands at one time), analysis can be achieved much faster and
with greater precision due to the highly specific, yet smaller amount
of data to analyze. As a result, more meaningful data can be obtained
in less time. This process also streamlines the preparation stages of
the experiment because the relevant genes are already grouped into
one ready-to-use assay.
all the genes on each PCR Array. Finally, calculate fold-changes in
gene expression for pair-wise comparison using the ∆∆Ct method. A
simple examination of Ct value consistency for the housekeeping genes
quickly indicates the proper normalization method. A similarly quick
evaluation of the built-in RNA quality controls elements provides
the relative levels of genomic DNA contamination and inhibitors of
either the reverse transcription or the PCR itself.
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PCR Arrays are designed for use with the RT2 First Strand Kit.
Test
Sample
cDNA
Control
Sample
cDNA
30 minutes
How It Works
Control Sample
PCR Mix
minutes
Test Sample
PCR Mix
HK3
HK4
HK5
GDC
RTC
RTC
RTC
PPC
PPC
Wells A1 through G12 contain individual qPCR assays for 84 genes relevant to a biological pathway
or disease state. Wells H1 through H5 contain a panel of housekeeping genes (HK1-HK5) used for
normalizing the PCR Array data. Well H6 contains a Genomic DNA Control (GDC) primer set that
specifically detects non-transcribed, repetitive genomic DNA with a high level of sensitivity. Wells
H7 through H9 contain replicate Reverse Transcription Controls (RTC). These elements verify the
efficiency of the RT reaction with a qPCR assay that specifically detects template synthesized from the
first strand synthesis kit’s built-in external RNA control. The replicate Positive PCR Controls (PPC) in
wells H10 through H12 report on the efficiency of the polymerase chain reaction itself. These elements
use a pre-dispensed artificial DNA sequence and the primer set that detects it. The two sets of
replicate control wells (RTC and PPC) also test for inter-well and intra-plate consistency.
Test Sample
PCR Array
Control Sample
PCR Array
minutes
Aliquot the Mixture Across Your PCR Arrays.
Each PCR Array profiles the expression of 84 pathway-specific
genes plus controls.
Analyze Fold Changes in Expression.
Simply cut-and-paste the Ct values collected by your realtime PCR instrument into the PCR Array analysis spreadsheet.
2.0 - 2.5 hours
Control Sample
Simple and Accurate: Easy-to-use qRT-PCR
based procedure provides high performance
levels
minutes
Test Sample
PCR Array Benefits
Pathway-Focused: Efficiently profiles the
expression of a large panel of genes relevant to
a pathway or disease state
Perform Thermal Cycling
Collect real-time amplification data (Ct values) using your
instrument’s software.
Easy Access:
Brings the power of expression profiling to any
lab with real-time PCR capabilities
Figure 1: The Complete PCR Array Procedure is Easy-to-use and Requires
Minimal Hands-on Time.
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301-682-9200
PPC
Figure 2: Layout of the Cataloged PCR Arrays
2
Add cDNA to RT qPCR Master Mix.
RT2 SYBR Green qPCR Master Mixes add
guaranteed performance.
HK2
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301-682-7300
3. SABiosciences
3
Pathway-Focused PCR Arrays
The Complete PCR Array System
The 96- or 384-well format of the RT2 Profiler PCR Arrays is uniquely
suited to SABiosciences' pathway-focused design concept. This
product line combines the current understanding of important
biological pathways with real-time PCR technology to generate
application-specific research tools. To compile each product’s
comprehensive list of genes and to continually expand the breadth
of available products, a systematic process comprised of literature
surveys, database searches, expert review, and user feedback is
utilized. SABiosciences now has the largest collection of pathway and
application specific human, mouse, and rat PCR Arrays available
on the market. (For examples, see Table 1.) This knowledge-based
design merges the benefits of hypothesis-driven and discovery-based
research, allowing researchers to answer highly specific questions in
a systematic fashion. These pre-designed application-specific PCR
Arrays accelerate, simplify, and improve life science research by
saving time, effort, and resources. Currently, PCR Arrays are available
for many pathways including apoptosis, inflammation, signal
transduction, cancer and other diseases. Visit the SABiosciences web site
(www.SABiosciences.com) for a complete list.
The complete PCR Array System includes the RT2 Profiler PCR
Arrays, the RT2 SYBR Green qPCR Master Mixes and the RT2 First
Strand Kit. These system components are optimized for SYBR Green
real-time PCR detection. The primer design and the optimized master
mix formulation work together to insure the specificity of each assay
in the array. The instrument-specific PCR Array plate formats and the
master mixes containing the appropriate reference dyes also provide
the PCR Arrays with the flexibility to match most real-time PCR
platforms. The RT2 First Strand Kit provides superior sensitivity and
an External RNA Control detected by the PCR Array that helps test
the quality of the input RNA material.
Table 1: Examples of Cataloged Pathway-Focused PCR Arrays
Research
Application
Biological
Process
Functionally or
Structurally
Related Genes
Signal
Transduction
Pathways
Disease
PCR Array Example
Gene Content Selected
for the PCR Array Example
Human Apoptosis
TNF Ligands and their Receptors
BCL2 Family Members
Caspases
Death and Effector Domains
ATM and p53 Pathways
Mouse Common Cytokines
Interferons and Interleukins
Bone Morphogenetic Proteins
Tumor Necrosis Factors
Other Various Growth Factors
Human NF B
Signaling Pathway
Human Cancer
PathwayFinder™
Extracellular Ligands and Receptors
NF B and I B Family Members
Kinases
Transcription Factors
Responsive Genes
Cell Cycle Control and DNA Damage
Repair
Apoptosis and Cell Senescence
Cell Adhesion
Angiogenesis
Invasion and Tumor Metastasis
Customized PCR Arrays
For researchers who have special gene expression profiling needs,
SABiosciences offers a streamlined custom design and array production
service. SABiosciences' Custom PCR Arrays provide researchers the
flexibility to 1) validate a focused panel of genes identified by a highdensity, genome-wide microarray, 2) modify the gene content of an
existing PCR Array to better fit their research project, or 3) characterize
a pathway or otherwise focused gene panel not covered by one of
the cataloged PCR Arrays. The content of a PCR Array may also be
subdivided into multiple sets of a smaller number of gene targets.
This format allows for the characterization of multiple biological or
technical replicates on the same array and during the same run. Like
the cataloged products, Custom PCR Arrays are also available in
either 96- or 384-well plate formats.
Email support@SABiosciences.com
Why the PCR Array System Works:
Component 1: RT2 qPCR Primer Assays
The greatest challenge for the PCR Array system is the amplification
of every relevant, pathway- or disease-focused gene during the same
run. The same uniform PCR conditions must be used while still
achieving the high level of sensitivity, specificity, and reproducibility
expected of real-time PCR. SABiosciences has designed the best possible
qPCR assays and optimized the PCR master mix formulation for
SYBR Green detection by experimentally testing thousands of qPCR
assays under many reaction conditions.
RT2 qPCR Primer Assays: Key Primer Design Criteria
Three of the most important primer design criteria in our
experimentally verified computer algorithm:
1. Specificity: Using BLAST and other algorithms, the specificity
of each primer set is measured against the entire human, mouse,
or rat genome to prevent the amplification of sequence-related,
non-specific secondary products. The primer specificity is also
checked against the E. coli genome to assure that the primers
do not amplify bacterial genomic DNA, a common but minor
contaminant of many Taq DNA polymerases.
2. Uniformity: To use the same annealing temperature for
every well in each PCR Array, only primer pairs with similar GC
contents, melting temperature (Tm), and other chemical and
physical properties are used.
3. Efficiency: Short amplicons (~ 100 to 200 bp) have been
chosen for our primer pairs so that the enzyme replicates the
entire sequence in the time allotted by the cycling program.
Several filters are also used to strengthen the 3-prime anchoring
of the primers, eliminating the amplification of dimers and other
non-specific annealing events.
Web www.SABiosciences.com
4. RT2 Profiler PCR Arrays
4
PCR master mix quality also plays an important role in the performance
of SYBR Green-based real-time PCR. A tightly controlled hot-start Taq
DNA polymerase is a critical component for success. The RT2 qPCR
Master Mixes from SABiosciences utilize a unique and proprietary
chemically-modified HotStart Taq polymerase which only gains
full activity after its heat activation step. Under these conditions,
non-specific priming events occurring at low temperatures are not
extended. Other master mixes often amplify the resulting templates
into non-specific products which can cause false positive results. In
addition, the RT2 qPCR Master Mixes include proprietary chemical
components that further minimize primer dimer formation and
ensure high amplification efficiencies for even the most difficult to
amplify genes. The combination of the RT2 qPCR Primer Assay design
and the high performance of the RT2 SYBR Green qPCR Master Mix
formulation is the foundation for the guaranteed specificity of the
assays on the PCR Array.
Why the PCR Array System Works:
Component 3: RT2 First Strand Kit
The RT² First Strand Kit contains all of the reagents needed not only
to convert RNA into first strand cDNA, but also for the removal of
genomic DNA from the RNA in the same simple two-step 30-minute
reaction. A proprietary genomic DNA elimination buffer completely
removes any residual genomic DNA from your RNA sample. Then,
the optimized formulation also allows you to directly use the RNA
preparation for reverse transcription and finally real-time PCR
without affecting reaction performance. By eliminating genomic DNA
contamination, real-time PCR signal intensities accurately reflect the
relative level of gene-specific mRNA transcript.
The kit also includes a built-in External RNA Control, an in vitro
transcript with an artificial sequence designed to help test for
inhibitors of reverse transcription. The Reverse Transcription Control
(RTC) in the PCR Array specifically detects cDNA template generated
by the kit from the external RNA control. A reproducible threshold
cycle value from this control indicates a consistent and high level of
RNA quality and transcription efficiency. Such a result provides a
greater degree of confidence in the final results.
The RT² First Strand Kit is optimized for use with the RT² SYBR
Green qPCR Master Mixes and subsequent gene expression analysis
with the RT2 Profiler PCR Arrays as part of the complete PCR Array
System. Random hexamers and oligo-dT prime reverse transcription
in an unbiased manner and capture more difficult-to-detect genes.
The reverse transcriptase, optimized magnesium concentration, and
other buffer components maximize cDNA product yield and length.
The RT² First Strand Kit contains a complete set of reagents for the
conversion of RNA into PCR template and provides greater control
over RNA quality than other available kits or enzyme sources. Table
2 summarizes the features of the RT2 Profiler PCR Array System.
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301-682-9200
Table 2: Features of Complete RT2 Profiler PCR Array System
84 pathway-focused genes
5 housekeeping genes
Array Design
1 Genomic DNA control
3 Reverse Transcription Controls (RTC)
3 Positive PCR controls (PPC)
Specificity: Sequence alignment filter
Primer Design
Uniformity: Consistent melting and annealing temperatures
Efficiency: Short amplicon sequence
Instrument-specific SYBR Green formulations
Supports all ABI, Bio-Rad, MJ Research, and Stratagene platforms
Master Mix
Hot Start Enzyme:
No extension of non-specific priming events
No amplification of secondary products like primer dimers
First Strand Synthesis
Optimized gDNA elimination buffer prevents false positive signals
Built-in External RNA Control to test for inhibitors of RT
PCR Array Performance: Sensitivity
Researchers continually attempt to detect genes at ever lower levels
of expression and in ever smaller amounts of total RNA. To meet
these needs, the PCR Array System must pass a very stringent
test of sensitivity. A wide variety of universal RNA amounts were
characterized with the PCR Array System and an array representing
inflammatory cytokine and receptor genes that are known to be
expressed at very low levels. Figure 3 plots the percent positive call
(the percentage of genes with Ct < 35) versus the amount of input
RNA. The results indicate that the PCR Array System achieves greater
than 80 percent positive calls with input total RNA amounts as low as
25.0 ng and as high as 1.0 μg (or even 5.0 μg) per array plate. For other
pathways or gene panels expressed at higher levels, the sensitivity
of the system may be further improved, potentially yielding high
positive call rates with even lower amounts of input total RNA.
However, the recommended amount of input RNA for first-time
users is 0.5 to 1.0 μg to assure a maximum number of positive calls.
The minimum recommended RNA amount is 25.0 ng, because the
percent positive call drops significantly with less material.
100
Percentage of Positive Calls
Why the PCR Array System Works:
Component 2: RT2 qPCR Master Mixes
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Figure 3: High Positive Call Rates with as little as 25 ng of Total RNA
The RT2 Profiler PCR Array System yields high positive call rates with as little as 25 ng of total RNA.
Different amounts of XpressRef™ Human Universal RNA (25, 50, 100, 500, and 1000 ng) were characterized
with the Human Inflammatory Cytokines and Receptors PCR Array, the RT2 First Strand kit and the RT2
SYBR Green/Fluorescein qPCR Master Mix on the Bio-Rad iCycler instrument. The percent positive call
rate (the percentage of genes with Ct < 35) is plotted versus the input amount of total RNA.
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5. SABiosciences
5
PCR Array Performance: Specificity
A. User-to-User Reproducibility
The PCR Array System has been designed and optimized for the
SYBR Green based detection method used by most real-time systems,
making the PCR Array System very flexible and widely applicable.
Concerns have been raised over the specificity of SYBR Green-based
detection and its ability to amplify only one gene-specific amplicon
product, because it detects double-stranded DNA non-specifically.
SABiosciences' experimentally verified primer design algorithm, used
for the PCR Arrays, guarantees the generation of single, gene-specific
amplicons without the co-amplification of primer dimers or other
non-specific secondary products.
For an example of a stringent test of PCR Array specificity, we characterized the real-time PCR dissociation curves of each gene on a
PCR Array representing highly homologous members of the TGFβ
and Bone Morphogenetic Protein (BMP) gene families. Products were
also characterized by agarose gel electrophoresis. Figure 4 displays the
representative dissociation curves and the agarose gel results for the
BMP gene family. Each dissociation curve contains only one peak,
and each agarose gel lane contains only one band of the predicted
size. The results indicate that the PCR Array amplifies gene-specific
products despite the expression of highly homologous members of
the same gene family in the same RNA sample. The optimized PCR
Array System now brings a level of specificity to SYBR Green-based
detection that most thought could be achieved only by more expensive probe-based methods.
A
BMP1
BMP2
BMP3
BMP4
BMP5
BMP6
BMP7
BMP15
BMP2
BMP3
BMP4
BMP5
BMP6
BMP7
A1
A2
A3
A4
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Figure 5: High User-to-User Reproducibility
The PCR Array System demonstrates a high degree of user-to-user reproducibility. Two different endusers characterized template cDNA prepared from Human XpressRef Universal Total RNA (5.0 μg) in
technical quadruplicates using the Human Drug Metabolism PCR Array and the
RT2 SYBR Green / Fluorescein qPCR Master Mix on the Bio-Rad iCycler. Panel A compares the
raw threshold cycle values of the array’s gene panel as determined by each of the first end-user’s
replicates versus each of the second end-user’s replicates. Panel B lists the correlation coefficient of
the linear curve fit for each scatter plot comparison.
To directly demonstrate that the results from the PCR Array System
are indeed reproducible, the fold-differences in the expression of
drug metabolism genes between two different RNA samples were
compared across three different real-time PCR instrument platforms.
In each gene expression profile comparison shown in Figure 6, the
curve fit to a straight line with a slope of one (1) has a correlation
coefficient of 0.97 or higher. Assuming good RNA sample
preparation and proper execution of the PCR Array protocol, any
differences observed in gene expression levels are attributable to the
biological conditions under study and not experimental variation
associated with this level of reproducibility in the technology itself.
Table 3 summarizes the typical performance of the RT2 Profiler PCR
Array.
B
BMP1
B. Correlation Coefficients (R values)
BMP15
Table 3: Typical Performance of the RT2 Profiler PCR Array
Sensitivity
Figure 4: High Specificity with the PCR Array System
PCR Array Performance: Reproducibility
The quantitative nature of real-time PCR should impart a high degree of reproducibility onto the PCR Array System. To test this notion, two different end-users characterized, in technical replicates (n
= 4), the same universal total RNA sample, each with two separate
manufacturing lots of a cataloged PCR Array on two separate days.
The raw threshold cycle values for the entire array’s gene panel
were then compared between each user’s replicates and all four of
the other user’s replicates. Figure 5 displays the resulting scatter plots
and correlation coefficients. Each comparison yields the predicted
ideals of straight lines with slopes of 1.0 and correlation coefficients of 0.99 or greater. The results demonstrate the high degree of
plate-to-plate, run-to-run, and replicate-to-replicate reproducibility
inherent in the PCR Array System technology, even at the level of
raw data.
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At least five (5) orders of magnitude
Specificity
The RT2 Profiler PCR Arrays demonstrate a high degree of specificity for their target genes. XpressRef
Human Universal Total RNA (5 μg) was characterized on the Human TGFβ / BMP Signaling Pathway
PCR Array using the RT2 SYBR Green/Fluorescein qPCR Master Mix on the Bio-Rad iCycler instrument.
After a standard melting curve program, dissociation curves were obtained (Panel A), and the products
were characterized by agarose gel electrophoresis (Panel B).
80 % Positive Call with as little as 25 ng
Dynamic Range
Primers amplify single, target-specific PCR products
Reproducibility
Correlation coefficients (R) 0.99 for intra-lab raw Ct values
Correlation coefficients (R) 0.97 for inter-lab fold-change values
Average standard deviation of 0.25 threshold cycles
A. Instrument-to-Instrument Reproducibility
ABI 7500
FAST
Stratagene
MX3000P
Bio-Rad
iCycler
B. Correlation Coefficients (R values)
7500 FAST
Mx3000p
7500 FAST
Mx3000p
0.980
1
iCycler
0.981
0.973
iCycler
1
1
Figure 6: High Instrument-to-Instrument Reproducibility
PCR Arrays demonstrate a high degree of instrument-to-instrument reproducibility. Two different
MAQC RNA samples were characterized using the Human Drug Metabolism PCR Array and either the
RT2 SYBR Green / Fluorescein qPCR Master Mix on the Bio-Rad iCycler or the RT2 SYBR Green / ROX
qPCR Master Mix on either the Stratagene Mx3000p or the ABI 7500 FAST instrumentation. The folddifference in the expression of the entire array’s gene panel between the two RNA samples determined
by each instrument was calculated and compared with both of the other two instruments in scatter plots
(Panel A) and the correlation coefficients of the linear curve fits (Panel B).
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6. RT2 Profiler PCR Arrays
6
PCR Array Application Example I:
Identifying and Monitoring Oncogenic Pathways
10-1
Normal Breast
Materials and Methods: Template cDNAs prepared from normal
human breast and human breast tumor #1 total RNA (BioChain
Institute, Inc., 5.0 μg) were characterized in technical triplicates
using the Human Cancer PathwayFinder PCR Array and the RT2
SYBR Green/Fluorescein qPCR Master Mix on the iCycler PCR
System.
1.0
CCNE1
-2
CDKN2A
FGFR2
10
ITGB3
10-4
10
1.0
10-1
10-2
10-3
10-4
10-5
Breast Tumor
Figure 7: Relative expression comparison for 84 cancer-related genes
between normal human breast and human breast tumor #1.
-ΔCt
The figure depicts a log transformation plot of the relative expression level of each gene (2 ) between
breast tumor (x-axis) and normal breast (y-axis). The gray lines indicate a four-fold change in gene
expression threshold.
Results: Gene expression profiling is important for discovering and
validating tumor biomarkers and therapeutic targets. Using the
Cancer PathwayFinder PCR Array and the Human Extracellular
Matrix and Adhesion Molecules PCR Array, we examined the
gene expression profiles exhibited by two different human breast
tumors relative to normal tissues. The study compared the relative
expression of both tumorigenesis- and adhesion-related genes
between each tumor sample and a normal breast tissue sample.
This study provides an example of the identification of a pathway
affected by the transformation of a particular tumor type.
Total RNA samples from normal breast tissue and the first of
two unmatched breast tumor were analyzed using the Cancer
PathwayFinder PCR Array. This PCR Array includes representative
genes from the following biological pathways involved in
tumorigenesis: adhesion, angiogenesis, apoptosis, cell cycle control,
cell senescence, DNA damage repair, invasion, metastasis, signal
transduction molecules, and transcription factors.
Figure 7 displays a scatter plot report of the results from the Cancer
PathwayFinder PCR Array experiment, indicating the positions of
several noteworthy genes based on their large fold-differences in
expression between the normal breast and the breast tumor samples.
Of the 84 cancer pathway-focused genes in this array, 24 genes
demonstrated at least a 3-fold difference in gene expression between
normal breast tissue and the breast tumor. Up-regulation was
observed in 17 genes, while 7 genes appeared to be down-regulated
in the tumor samples, for a total of 24 differentially regulated genes
(Table 4).
A subset of six of the 24 genes (ITGA2, ITGA4, ITGB3, MCAM,
MMP9, and TIMP3) represents adhesion and extracellular matrix
molecules. ITGB3 was down-regulated, while the other five genes were
up-regulated. The results suggest that changes in the expression of
genes involved in cellular interactions played an important role in the
transformation of this and perhaps other breast tumors. To further test
this hypothesis and to analyze the expression of other adhesion-related
genes, a second breast tumor sample was characterized using a cellular
adhesion-focused PCR Array.
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ITGB4 TIMP3
10-6
the iCycler® PCR System.
10-6
MMP9
ITGA2
MCAM
-5
Triplicate total RNA samples prepared from normal human breast
and human breast tumor #2 total RNA (BioChain Institute, Inc., 1.0
μg) were converted into template cDNA and then characterized
using the Human Extracellular Matrix and Adhesion Molecules PCR
Array and the RT2 SYBR Green/Fluorescein qPCR Master Mix on
TGFB1
10-3
301-682-9200
Table 4: Changes in expression for cancer-related genes between normal
human breast and human breast tumor #1.
Genes from the experiment in Figure 7 that exhibit a three-fold or greater change in expression
between normal and tumor breast tissue are listed.
Gene
MMP9
TIMP3
TNF
ITGA4
TGFB1
BCL2
FOS
GZMA
TEK
JUN
APAF1
ATM
ITGA2
PIK3R1
SYK
PLAUR
MCAM
PLAU
ETS2
ANGPT1
FAS
TERT
NFKB1
NME4
ERBB2
ITGA3
UCC1
MYC
SNCG
CCNE1
ITGB3
CDKN2A
FGFR2
Fold change
Average Raw Ct
Tumor/Normal
t-Test
p value
Tumor
Normal
542.45
39.85
35.51
27.54
15.10
12.27
9.74
9.30
6.88
6.88
5.34
5.34
5.34
5.34
4.65
4.44
4.14
3.61
3.44
3.36
3.36
3.29
3.07
3.07
-3.29
-3.78
-4.65
-5.34
-7.73
-8.48
-9.08
-26.91
-41.74
0.0000
0.0000
0.0000
0.0001
0.0000
0.0012
0.0003
0.0003
0.0003
0.0008
0.0018
0.0001
0.0042
0.0001
0.0003
0.0007
0.0000
0.0132
0.0015
0.0028
0.0031
0.0314
0.0068
0.0019
0.0000
0.0000
0.0003
0.0004
0.0000
0.0000
0.0026
0.0000
0.0007
21.8
30.5
25.2
31.1
21.1
24.6
20.1
25.5
27.7
22.3
23.8
19.9
26.8
21.3
22.5
26.4
28.2
27.8
23.5
31.3
24.7
34.1
22.9
24.1
25.9
23.9
26.6
25.7
26.0
27.6
33.3
29.4
31.5
30.0
35.0
29.5
35.0
24.1
27.4
22.5
27.9
29.7
24.2
25.4
21.5
28.4
22.9
23.9
27.7
29.4
28.8
24.4
32.2
25.6
35.0
23.6
24.9
23.3
21.1
23.5
22.4
22.2
23.7
29.3
23.8
25.2
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301-682-7300
7. SABiosciences
7
Total RNA samples from normal breast tissue and the second of the two
unmatched breast tumors were characterized on the Extracellular Matrix
and Adhesion Molecules PCR Array. Genes that displayed at least a
3-fold difference in expression between the samples are listed in Table 5.
On this array, a larger number of genes exhibited differential expression
in the second tumor than was observed for the first tumor on the Cancer
PathwayFinder PCR Array. A total of 38 genes had a different level of
expression in the breast tumor than in the normal breast tissue, with 27
genes showing up-regulation and 11 genes showing down-regulation.
Table 5: Changes in relative expression for genes encoding ECM and adhesion
molecules between normal human breast and human breast tumor #2.
The table lists genes that exhibit at least a three-fold difference in expression in the breast tumor
sample when compared to the normal breast tissue. The raw threshold cycle (Ct) values seen in the
two samples are also listed for comparison.
Gene
CTNND2
TIMP3
SELE
MMP1
MMP3
KAL1
MMP13
MMP10
MMP16
FN1
CD44
TNC
MMP9
SELP
MMP11
COL7A1
CSPG2
COL4A2
TNA
COL11A1
THBS1
SELL
HAS1
CTNND1
ITGA4
ITGA7
THBS2
SPP1
ITGB5
CTNNB1
ITGAV
CNTN1
MMP7
ITGB3
ADAMTS1
LAMA3
NCAM1
ITGB4
Fold change
Tumor/Normal
t-Test
p value
229.39
104.57
43.46
36.97
34.50
31.45
21.73
16.47
16.09
11.92
11.92
10.87
10.62
9.46
7.51
7.00
6.39
5.56
5.43
5.31
4.84
4.21
3.93
3.84
3.34
3.34
3.19
-3.08
-3.31
-3.31
-4.57
-5.25
-5.37
-7.25
-9.35
-10.26
-23.02
-30.38
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0512
0.0046
0.0000
0.0001
0.0001
0.0000
0.0057
0.0000
0.0009
0.0001
0.0017
0.0185
0.0002
0.0010
0.0007
0.0000
0.0003
0.0058
0.0000
0.0000
0.0003
0.0072
0.0001
0.0000
0.0094
0.0003
0.0000
0.0000
0.0000
Average Raw Ct
Tumor
Normal
23.8
28.4
26.3
27.9
29.9
23.1
26.9
31.0
25.3
29.9
23.5
22.9
27.1
26.1
25.0
30.9
24.0
23.9
26.9
30.7
24.1
24.7
27.5
30.4
25.4
27.6
26.1
23.6
23.2
21.2
26.5
28.8
25.7
32.1
25.5
24.7
30.9
26.6
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31.6
35.0
31.7
33.0
35.0
28.0
31.2
35.0
29.2
33.4
27.0
26.2
30.4
29.2
27.9
33.7
26.6
26.3
29.3
33.0
26.3
26.7
29.4
32.2
27.1
29.3
27.7
21.9
21.4
19.4
24.2
26.3
23.2
29.2
22.2
21.2
26.3
21.6
The first and second breast tumor sample displayed concordant results
for four genes (MMP9, TIMP3, ITGA4, and ITGB3) that changed
expression in the same direction on the Cancer PathwayFinder PCR
Array and the Extracellular Matrix and Adhesion Molecules PCR
Array. These results not only further verify that cellular adhesion genes
changed their expression in these two particular breast cancer tumors,
but also suggest a more general role for these genes in breast tissue
transformation.
These types of studies provide a new and convenient way to
investigate the mechanisms underlying oncogenesis of specific
tumors on a pathway-focused basis. The data shown here is
consistent with known principles, that changes in the expression of
genes related to cellular adhesion play a role in the transformation
of breast tissue1-2. Alterations in the expression of these genes
enhance or inhibit metastasis of the tumor from its original location
and may aid tumor invasion into a new tissue or organ. A PCR
Array focusing on Human Tumor Metastasis is available and could
be used to continue this study.
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8. RT2 Profiler PCR Arrays
8
PCR Array Application Example II:
Monitoring Cytokine Expression Levels
To validate the results obtained from the PCR Array, the protein
level of eight selected cytokines secreted by the PBMC (IL-2, 4, 5,
10, 12, 13, and IFN-γ and TNF-α) was measured. Cell supernatants
were collected at different time points (0, 6, 24, and 48 hours) and
the cytokines were measured by enzyme-linked immunosorbent
assay (ELISA) using the Human Th1 / Th2 Cytokines Multi-Analyte
Profiler ELISArray™ Kit. Optical Density (OD) readings for each
protein analyte from the samples were compared to a standard
curve for quantification of the amount of protein in the original
samples.
Results: Cytokine quantification is an important element in studies
of inflammation and immune responses. Quantitative RT-PCR,
a rapid and sensitive assay, is the preferred method to quantify
cytokine mRNA levels because they are often expressed at low
levels. The PCR Array System offers a simple, reliable and sensitive
tool for multiple cytokine profiling. Using the Human Cytokine
PCR Array, we have monitored the mRNA levels of 84 different
cytokines in stimulated versus and untreated human peripheral
blood mononuclear cells (PBMC).
The gene expression results identify 23 up-regulated and 6 downregulated genes (with >5 fold-change and p < 0.005) upon 6 hours
of stimulation. At 24 hours, the effects of PMA-ionomycin on
genes such as BMP’s, CSF’s, IFNγ, IL1β, IL6, IL11, TGFβ and TNF
are continuously observed, while the effect on other genes such
as interleukin 2, 3, 5, 9, 10, 13, 17 and 22 diminishes twenty-four
hours after stimulation (Figure 8 and Table 6). To validate these
results, the protein levels of 8 selected cytokines secreted by the
PBMC was measured using a multiplex ELISA array (Figure 9). The
effects of these mRNA expression changes were observed in the
changes in cytokine production induced by PMA ionomycin at 6
hours after stimulation. The induction in cytokine production by
PMA-ionomycin was sustained up to 48 hours after stimulation,
despite the observation of the subdued mRNA expression for some
cytokines at 24 hours after stimulation.
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301-682-9200
TNF
TNFSF10 IL1B
p Value
10-6
LTA
10-5
TNFSF13B
FASLG
10-4
IFNA5
10-3
10
IL9
IL10
IL1A
10-7
IL1F7
CSF1
IFNG
IL11
CSF2
IL2
IL5
IL21 IL13 IL22
IL3
IL17
PDGFA
TGFB2
TNFSF11
TNFRSPSF11B
BMP6
TNFSF14
BMP3
-2
10-1
1.0
-7
-5
-3
-1
1
3
5
7
9
Fold Difference (Log2)
11
13
15
17
Figure 8: RNA isolated from resting PBMC or PBMC stimulated with PMA
ionomycin for 6 or 24 hours were characterized on the Human Common
Cytokine PCR Array.
Log2 fold-changes in gene expression between PBMC stimulated with PMA ionomycin and resting
PBMC are plotted against t-test p-values to produce a “volcano plot”. The higher the position, the more
significant the gene’s fold-change. Genes plotted farther from the central axis have larger changes
in gene expression. Thresholds for fold-change (vertical lines, 5-fold) and significant difference
(horizontal line, p < 0.005) were used in this display.
Using the Common Cytokine PCR Array, we identified 29 genes that
exhibited at least a five-fold change in gene expression between resting
and PMA ionomycin stimulated peripheral blood mononuclear cells
at 6 hours after stimulation. Our data show that changes in cytokine
mRNA levels detected by PCR Arrays accurately predict changes in
protein levels measured by ELISA. Hence, the PCR Array offers a
simple, reliable and sensitive tool for multiple cytokine profiling.
IL-13
mRNA Expression
(Fold Change vs.
Untreated Cells)
template.
10-8
TNF-a
IFN-g
1500
45
1000
40
500
35
4000
3000
2000
1000
0
IL-13
6 hour
3962
24 hour
145
30
0
IFN-g
Time
(Hours after Stimulation)
Secreted Cytokine
Protein Level
(pg / ml)
Materials and Methods: Peripheral Blood Mononuclear Cells
(PBMC) were treated with or without 50 ng/ml PMA + 1 μg/ml
ionomycin for 6 or 24 hours. After each incubation period, total
RNA was isolated from each preparation, and first strand cDNAs
were prepared from 500 ng total RNA of each sample using the RT2
First Strand Kit. Template cDNAs were characterized in technical
triplicates using the Human Common Cytokine PCR Array with
the RT² SYBR Green/ROX qPCR Master Mix on the 7500 FAST®
Real-Time PCR System (Applied Biosystems). Fold changes in gene
expression between the stimulated and resting PBMC RNA were
calculated using the ΔΔCt method in the PCR Array Data Analysis
10-9
6 hour
526
24 hour
1287
TNF-a
Time
(Hours after Stimulation)
6 hour
40
24 hour
35
Time
(Hours after Stimulation)
800
800
800
600
600
600
400
400
400
200
200
0
200
0
0 hour
IL-13 21.2
6 hour 24 hour 48 hour
229.5
707.9
753.1
Time
(Hours after Stimulation)
0
0 hour
IFN-g 0.5
6 hour 24 hour 48 hour
25300 224912 404176
Time
(Hours after Stimulation)
TNF-a
0 hour
38.3
6 hour 24 hour 48 hour
1819
8170
14475
Time
(Hours after Stimulation)
Figure 9. The effects of PMA-ionomyocin on the secretion of the eight
selected cytokines were assessed by multiplex cytokine ELISA.
As shown in the above graphs, in parallel with the PCR Array results (upper panel), a marked increase
in cytokine release (lower panel) was seen for IL-13, and IFN-g and TNF-a . The induction in cytokine
secretion by PMA-ionomycin were sustained up to 48 hours of stimulation, despite the observation
of the subdued mRNA expression for some cytokines such as IL-13 and TNF-a after 24 hours of
stimulation.
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301-682-7300
9. SABiosciences
9
Table 6. List of cytokines induced or down regulated in Phorbol Myristate Acetate Ionomycin-stimulated Peripheral Blood Mononuclear Cells (PBMC) versus
resting PBMC.
The significance of the change in gene expression between the two samples was evaluated by unpaired Student t-test for each gene. The level of statistical significance is set at <0.005. Genes that show at least
a five-fold difference in expression between the two samples are listed in the table. After six hours of stimulation, a total of 29 genes have at least a 5-fold change in expression between the stimulated and resting
PBMC, with 23 genes having increased expression and six genes having decreased expression in stimulated PBMC.
Gene
IL2
IL3
IL22
IL17
IL13
IL9
IL21
CSF2
IFNG
IL5
IL11
IL10
TNF
PDGFA
CSF1
TNFRSF11B
LTA
TNFSF11
BMP6
BMP3
FASLG
TGFB2
TNFSF14
TNFSF8
TNFSF13
BMP4
IL6
GDF10
IL20
IL4
TNFSF12
IL12A
IL1F6
IL18
LTB
IL17C
IFNK
IL16
TNFSF4
IL1F9
IL15
IFNB1
BMP8B
IL12B
TGFA
IL1B
IL1F7
IFNA5
IL1A
TNFSF10
TNFSF13B
6 HOURS AFTER STIMULATION
Average Raw Ct Value
Stimulated / Resting
t-test
Stimulated
Resting
Fold Change
p-value
47820.23
14.64
29.99
0.0000
38218.94
19.53
34.56
0.0000
9823.35
0.0000
21.08
34.14
7601.14
0.0000
21.51
34.21
3961.96
21.05
32.80
0.0000
3339.31
23.49
35.00
0.0000
1522.26
19.76
30.13
0.0000
1494.38
0.0000
16.80
27.15
525.91
13.57
22.41
0.0000
208.71
21.89
29.40
0.0000
136.74
24.22
31.12
0.0000
62.77
21.43
27.21
0.0000
40.00
17.91
23.04
0.0000
29.22
0.0000
24.17
28.84
23.73
21.27
25.64
0.0000
16.63
30.39
34.25
0.0003
8.39
22.19
25.06
0.0000
6.40
0.0001
26.61
29.10
6.14
0.0003
26.37
28.79
5.50
31.45
33.71
0.0041
5.46
20.90
23.16
0.0000
5.43
28.98
31.23
0.0000
5.37
32.77
35.00
0.0009
0.0000
20.16
22.27
4.92
29.20
30.38
2.60
0.0000
32.11
33.29
2.58
0.0935
18.77
19.88
2.47
0.0002
33.11
34.08
2.23
0.1166
31.75
32.56
2.00
0.0117
32.00
32.31
1.42
0.3010
26.05
26.25
1.32
0.0057
27.19
27.19
1.14
0.0971
30.28
29.72
-1.29
0.2311
29.14
28.53
-1.33
0.0449
22.22
21.47
-1.48
0.0120
28.78
27.95
-1.55
0.0213
29.27
28.40
-1.60
0.0206
23.52
22.25
-2.11
0.0000
28.43
26.89
-2.54
0.0002
29.69
28.07
-2.68
0.6977
29.46
27.55
-3.28
0.0007
31.11
29.07
-3.58
0.0022
29.36
27.25
-3.76
0.0001
35.00
32.72
-4.25
0.0132
29.29
26.92
-4.49
0.0000
-7.12
0.0000
18.66
15.64
-11.19
34.52
30.84
0.0012
-12.89
33.53
29.65
0.0011
-16.62
0.0000
24.27
20.02
-19.22
26.16
21.70
0.0000
-26.62
29.68
24.75
0.0001
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24 HOURS AFTER STIMULATION
Average Raw Ct Value
Stimulated / Resting
t-test
Stimulated
Resting
Fold Change
p-value
11190.60
13.54
26.91
0.0000
4020.99
18.46
30.35
0.0000
87.02
24.26
30.62
0.0000
3365.64
20.63
32.26
0.0000
144.67
23.65
30.74
0.0000
516.75
22.22
31.15
0.0000
1152.06
20.00
30.09
0.0000
2714.87
15.53
26.86
0.0000
1287.18
13.94
24.19
0.0000
12.70
25.77
29.35
0.0000
542.45
25.35
34.35
0.0000
26.37
24.33
-3.87
0.0015
34.54
18.69
23.72
0.0000
29.11
23.27
28.05
0.0000
9.78
20.64
23.85
0.0000
30.63
32.16
3.06
0.0060
23.92
20.26
24.76
0.0000
5.30
27.28
29.61
0.0001
7.84
26.40
29.28
0.0000
35.00
34.71
-1.16
0.1996
6.48
21.54
24.16
0.0000
5.91
30.88
33.36
0.0029
33.51
35.00
2.98
0.0003
19.88
19.94
24.17
0.0000
-52.10
31.80
26.02
0.0000
12.38
28.99
32.54
0.0003
6.29
19.92
22.49
0.0000
-13.30
32.95
29.13
0.0006
7.03
32.27
35.00
0.0001
33.36
32.22
-2.08
0.0025
-41.16
29.28
23.84
0.0000
27.18
27.18
1.06
0.3060
-8.48
33.34
30.17
0.0046
-21.26
33.32
28.83
0.0000
-102.54
27.18
20.42
0.0000
-17.31
31.86
27.66
0.0001
-5.71
29.73
27.14
0.0011
-12.91
24.75
20.97
0.0000
-5.38
27.96
25.45
0.0000
-16.34
26.92
22.81
0.0000
-5.23
28.79
26.32
0.0000
-19.03
34.37
30.03
0.0015
-6.74
31.35
28.51
0.0018
31.24
29.86
-2.46
0.0049
-14.06
27.96
24.06
0.0000
-11.93
20.12
16.46
0.0000
-16.76
35.00
30.85
0.0000
31.19
29.13
-3.93
0.0002
25.48
23.24
-4.46
0.0000
-24.20
25.41
20.73
0.0000
-411.10
31.27
22.50
0.0001
Web www.SABiosciences.com
10. RT2 Profiler PCR Arrays
10
Summary:
The RT2 Profiler PCR Array System is the ideal tool for analyzing
the expression of a focused panel of genes. The flexibility, simplicity,
and convenience of standard SYBR Green PCR detection methodology make the PCR Array System accessible for routine use in any
research laboratory. The correct combination of instrument-specific
plate format and master mix matches the PCR Array System with
the most popular real-time instrument platforms. The arrays feature
a pathway-focused or a customizable gene content design, while
demonstrating the sensitivity, specificity, and reproducibility performance expected of real-time PCR. The focused design of this system
decreases the amount of time necessary to complete the experiment
and facilitates easier and more straightforward data analysis. Using this system, results can be generated with as little as 25 ng or
as much as 5 μg of total RNA starting material. The specificity of
the system guarantees the amplification of only one gene-specific
product in each reaction meaning that the expression level result
confidently reflects only the gene of interest. The reproducibility
of the system (with intra-lab and inter-lab correlations greater than
0.99 and 0.97, respectively) demonstrates that the same results are
obtainable by multiple end-users. As a result, the RT2 Profiler PCR
Array System is indeed ideally suited to allow every laboratory to
combine the performance of real-time PCR with the profiling capabilities of a microarray.
References:
1.
Ross JS, Linette GP, Stec J, Clark E, Ayers M, Leschly N,
Symmans WF, Hortobagyi GN, Pusztai L. Breast
cancer biomarkers and molecular medicine: part II. Expert
Rev Mol Diagn 2004; 4(2):169-88
2.
Perou CM, Jeffrey SS, van de Rijn M, Rees CA, Eisen MB, Ross
DT, Pergamenschikov A, Williams CF,
Zhu SX, Lee JC, Lashkari D, Shalon D, Brown PO, Botstein D.
Distinctive gene expression patterns in human
mammary epithelial cells and breast cancers. Proc Natl Acad
Sci U S A. 1999; 96(16):9212-7.
RT2Profiler ™ PCR Array, RT2 Real-Time™, PathwayFinder™, XpressRef™, and PCR Array™ are
trademarks of SABiosciences Corporation. SYBR® is a registered trademark of Molecular
Probes, Inc. ABI® and ROX® are a registered trademarks of Applera Corporation. Opticon®,
Chromo4®, iCycler® and MyiQ® are registered trademarks of Bio-Rad Laboratories. Mx3000P®,
MX3005P®, and Mx4000® are registered trademarks of Stratagene. TaqMan® is a registered
trademark of Roche Molecular Systems.
Tel 888-503-3187 (USA)
301-682-9200
Fax 888-465-9859 (USA)
301-682-7300
11. 11
PCR Array Buyer’s Guide
Step 1: Find your pathway in the list below. For complete
PCR Array gene lists, see our web site at:
www.SABiosciences.com/ArrayList.php
Real-Time PCR Systems
Determine the plate type and master mix that fits your real-time PCR system.
Step 2: Determine which PCR Array format fits the instrument
in your lab using the Real-Time PCR Systems table.
Instrument Make and Model
Step 3: Select your pack sizes and reagents. Place your
order by phone, fax, or e-mail:
Pathway / Topic Focus
PCR Array
Catalog Number
Angiogenesis
Angiogenic Growth Factors & Angiogenesis Inhibitors
Apoptosis
Atherosclerosis
Breast Cancer and Estrogen Receptor Signaling
cAMP and Calcium Signaling Pathway
Cancer Drug Resistance and Metabolism
Cancer PathwayFinder™
Cell Cycle
Chemokines and Receptors
Common Cytokines
Diabetes
DNA Damage Signaling Pathway
Drug Metabolism
Drug Metabolism: Phase I Enzymes
Drug Transporters
Endothelial Cell Biology
Extracellular Matrix and Adhesion Molecules
Growth Factors
Hypoxia Signaling Pathway
Inflammatory Cytokines and Receptors
Insulin Signaling Pathway
Interferons (IFN) and Receptors
JAK / STAT Signaling Pathway
MAP Kinase Signaling Pathway
Neuroscience Ion Channels and Transporters
Neurotransmitter Receptors and Regulators
Neurotrophins and Receptors
NF B Signaling Pathway
Nitric Oxide Signaling Pathway
Notch Signaling Pathway
Obesity
Osteogenesis
Oxidative Stress and Antioxidant Defense
p53 Signaling Pathway
Signal Transduction PathwayFinder™
Stem Cell
Stress and Toxicity PathwayFinder™
TGF / BMP Signaling Pathway
Th17 for Autoimmunity and Inflammation
Th1-Th2-Th3
Toll-Like Receptor Signaling Pathway
Tumor Metastasis
Tumor Necrosis Factor (TNF) Ligands and Receptors
Wnt Signaling Pathway
Housekeeping Genes
RT RNA QC PCR Array - quality control plates
Custom Options -
PAXX-024Y
PAXX-072Y
PAXX-012Y
PAXX-038Y
PAXX-005Y
PAXX-066Y
PAXX-004Y
PAXX-033Y
PAXX-020Y
PAXX-022Y
PAXX-021Y
PAXX-023Y
PAXX-029Y
PAXX-002Y
PAXX-068Y
PAXX-070Y
PAXX-015Y
PAXX-013Y
PAXX-041Y
PAXX-032Y
PAXX-011Y
PAXX-030Y
PAXX-064Y
PAXX-039Y
PAXX-061Y
PAXX-036Y
PAXX-060Y
PAXX-031Y
PAXX-025Y
PAXX-062Y
PAXX-059Y
PAXX-017Y
PAXX-026Y
PAXX-065Y
PAXX-027Y
PAXX-014Y
PAXX-405Y
PAXX-003Y
PAXX-035Y
PAXX-073Y
PAXX-034Y
PAXX-018Y
PAXX-028Y
PAXX-063Y
PAXX-043Y
PAXX-000Y
PAXX-999Y
Inquire
2
“XX“= HS, MM, RN (Human, Mouse, Rat) see web site for availability
y
A
ABI 7500 Standard Block
A
ABI 7500 FAST Block
C
ABI 7900HT Standard 96 Block
A
ABI 7900HT FAST 96 Block
C
ABI 7900HT 384-well Block
E
ABI 5700 (Perkin Elmer)
A
ABI 7700 (Perkin Elmer)
A
iCycler, iQ5
A
iQ5
A
MyiQ
A
Chromo 4 (MJ Research)
A
Opticon (2) (MJ Research)
Applied Biosystems
E-mail: order@SABiosciences.com
D
Mx3005p
A
Mx3000p
A
Mx4000
Required
Master Mix
A
ABI 7300
Bio-Rad
Fax: 888.465.9859
ABI 7000
Eppendorf Roche Stratagene
Phone: 888.503.3187
PCR Array
Plate Format
(Cat. No. Y = )
D
LightCycler 480 96 Block
PA-010
PA-012
G
Mastercycler ep realplex
PA-011
F
LightCycler 480 384 Block
PA-012
A
PA-010
Inquire
Pack Sizes and Required Reagents
Volume discounts are built into the PCR Array 12-pack and 24-pack sizes.
PCR Array Pack Sizes
Two (2) 96-well PCR Arrays
Twelve (12) 96-well PCR Arrays
Twenty-Four (24) 96-well PCR Arrays
Four (4) 384-well PCR Arrays (Format “E”)
RT2 SYBR Green qPCR Master Mixes are required for use with PCR Arrays.
Master Mix Pack Sizes
(Number of 96-well PCR Arrays Accommodated)
Catalog Number
Two-Pack (2)
PA-01#
Twelve-Pack (12)
PA-01#-12
Twenty-Four Pack (24)
PA-01#-24
The RT 2 First Strand Kit is required for use with PCR Arrays.
For best results, we also recommend the RT 2 qPCR-Grade RNA Isolation Kit.
RT First Strand Kit
(Cat. No. C-03, enough for 12 reactions)
2
RT qPCR-Grade RNA Isolation Kit
(Cat. No. PA-001, enough for 12 RNA isolations)
2