Locked nucleic acid inhibits amplification of contaminating DNA in real-time PCR

Lone Hummelshoj; Lars P Ryder; Hans O Madsen; Lars K. Poulsen

Locked nucleic acid inhibits amplification of contaminating DNA in real-time PCR

Lone Hummelshoj, Lars P Ryder, Hans O Madsen, Lars K. Poulsen

22 Citations (Scopus)

Abstract

Locked nucleic acid (LNA) is a modified DNA with increased binding affinityfor complementary DNA sequences. Our strategy was to use this property of LNA to inhibit undesired PCR amplification (e.g.,from contaminating genomic DNA) in a cDNA-based assay. By placing a short complementary LNA sequence in intronic DNA, the aim was to inhibit the amplification of genomic DNA without affecting the amplification of reverse-transcribed spliced mRNA. LNA was designed to bind within intron 5 in the x-box binding protein 1 (XBP1) gene. An irrelevant LNA oligonucleotide served as a negative control. In both PCR and real-time PCR, the addition of LNA showed blocking of the amplification of genomic XBP1 but not cDNA XBP1. To test the effect of melting temperature (Tm) on the LNA, we investigated the number of LNA nucleotides that could be replaced with DNA nucleotides and still retain the blocking activity. More than three DNA nucleotides reduced the LNA inhibition ability. The sequence specificity of the LNA was tested by investigating the number of LNA nucleotide mismatches permitted. The introduction of one mismatch maintained the inhibition of genomic amplification whereas two mismatches reduced the amplification. Our results show that LNA may be used to enhance the specificity of PCR by eliminating unwanted PCR products.

Original language	English
Journal	BioTechniques
Volume	38
Issue number	4
Pages (from-to)	605-10
Number of pages	6
ISSN	0736-6205
Publication status	Published - 2005

Keywords

Base Pair Mismatch
Base Sequence
DNA
DNA-Binding Proteins
Gene Amplification
Introns
Models, Biological
Nuclear Proteins
Nucleic Acids
Polymerase Chain Reaction
Sensitivity and Specificity
Sequence Analysis, DNA
Temperature
Transcription Factors

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title = "Locked nucleic acid inhibits amplification of contaminating DNA in real-time PCR",

abstract = "Locked nucleic acid (LNA) is a modified DNA with increased binding affinityfor complementary DNA sequences. Our strategy was to use this property of LNA to inhibit undesired PCR amplification (e.g.,from contaminating genomic DNA) in a cDNA-based assay. By placing a short complementary LNA sequence in intronic DNA, the aim was to inhibit the amplification of genomic DNA without affecting the amplification of reverse-transcribed spliced mRNA. LNA was designed to bind within intron 5 in the x-box binding protein 1 (XBP1) gene. An irrelevant LNA oligonucleotide served as a negative control. In both PCR and real-time PCR, the addition of LNA showed blocking of the amplification of genomic XBP1 but not cDNA XBP1. To test the effect of melting temperature (Tm) on the LNA, we investigated the number of LNA nucleotides that could be replaced with DNA nucleotides and still retain the blocking activity. More than three DNA nucleotides reduced the LNA inhibition ability. The sequence specificity of the LNA was tested by investigating the number of LNA nucleotide mismatches permitted. The introduction of one mismatch maintained the inhibition of genomic amplification whereas two mismatches reduced the amplification. Our results show that LNA may be used to enhance the specificity of PCR by eliminating unwanted PCR products.",

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author = "Lone Hummelshoj and Ryder, {Lars P} and Madsen, {Hans O} and Poulsen, {Lars K.}",

year = "2005",

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journal = "BioTechniques",

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T1 - Locked nucleic acid inhibits amplification of contaminating DNA in real-time PCR

AU - Hummelshoj, Lone

AU - Ryder, Lars P

AU - Madsen, Hans O

AU - Poulsen, Lars K.

PY - 2005

Y1 - 2005

N2 - Locked nucleic acid (LNA) is a modified DNA with increased binding affinityfor complementary DNA sequences. Our strategy was to use this property of LNA to inhibit undesired PCR amplification (e.g.,from contaminating genomic DNA) in a cDNA-based assay. By placing a short complementary LNA sequence in intronic DNA, the aim was to inhibit the amplification of genomic DNA without affecting the amplification of reverse-transcribed spliced mRNA. LNA was designed to bind within intron 5 in the x-box binding protein 1 (XBP1) gene. An irrelevant LNA oligonucleotide served as a negative control. In both PCR and real-time PCR, the addition of LNA showed blocking of the amplification of genomic XBP1 but not cDNA XBP1. To test the effect of melting temperature (Tm) on the LNA, we investigated the number of LNA nucleotides that could be replaced with DNA nucleotides and still retain the blocking activity. More than three DNA nucleotides reduced the LNA inhibition ability. The sequence specificity of the LNA was tested by investigating the number of LNA nucleotide mismatches permitted. The introduction of one mismatch maintained the inhibition of genomic amplification whereas two mismatches reduced the amplification. Our results show that LNA may be used to enhance the specificity of PCR by eliminating unwanted PCR products.

AB - Locked nucleic acid (LNA) is a modified DNA with increased binding affinityfor complementary DNA sequences. Our strategy was to use this property of LNA to inhibit undesired PCR amplification (e.g.,from contaminating genomic DNA) in a cDNA-based assay. By placing a short complementary LNA sequence in intronic DNA, the aim was to inhibit the amplification of genomic DNA without affecting the amplification of reverse-transcribed spliced mRNA. LNA was designed to bind within intron 5 in the x-box binding protein 1 (XBP1) gene. An irrelevant LNA oligonucleotide served as a negative control. In both PCR and real-time PCR, the addition of LNA showed blocking of the amplification of genomic XBP1 but not cDNA XBP1. To test the effect of melting temperature (Tm) on the LNA, we investigated the number of LNA nucleotides that could be replaced with DNA nucleotides and still retain the blocking activity. More than three DNA nucleotides reduced the LNA inhibition ability. The sequence specificity of the LNA was tested by investigating the number of LNA nucleotide mismatches permitted. The introduction of one mismatch maintained the inhibition of genomic amplification whereas two mismatches reduced the amplification. Our results show that LNA may be used to enhance the specificity of PCR by eliminating unwanted PCR products.

KW - Base Pair Mismatch

KW - Base Sequence

KW - DNA

KW - DNA-Binding Proteins

KW - Gene Amplification

KW - Introns

KW - Models, Biological

KW - Nuclear Proteins

KW - Nucleic Acids

KW - Polymerase Chain Reaction

KW - Sensitivity and Specificity

KW - Sequence Analysis, DNA

KW - Temperature

KW - Transcription Factors

M3 - Journal article

C2 - 15884678

SN - 0736-6205

VL - 38

SP - 605

EP - 610

JO - BioTechniques

JF - BioTechniques

IS - 4

ER -

Locked nucleic acid inhibits amplification of contaminating DNA in real-time PCR

Abstract

Keywords

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