Comparison of different melting temperature calculation methods for short DNA sequences

doi:10.1093/bioinformatics/bti066

Bioinformatics Advance Access originally published online on October 22, 2004
Bioinformatics 2005 21(6):711-722; doi:10.1093/bioinformatics/bti066

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Comparison of different melting temperature calculation methods for short DNA sequences

Alejandro Panjkovich and Francisco Melo ^*

Departamento de Genética Molecular y Microbiología, Facultad de Ciencias Biológicas, Pontificia Universidad Católica de Chile Alameda 340, Santiago, Chile

^*To whom correspondence should be addressed.

Motivation: The overall performance of several molecular biologytechniques involving DNA/DNA hybridization depends on the accurateprediction of the experimental value of a critical parameter:the melting temperature T_m. Till date, many computer softwareprograms based on different methods and/or parameterizationsare available for the theoretical estimation of the experimentalT_m value of any given short oligonucleotide sequence. However,in most cases, large and significant differences in the estimationsof T_m were obtained while using different methods. Thus, itis difficult to decide which T_m value is the accurate one. Inaddition, it seems that most people who use these methods areunaware about the limitations, which are well described in theliterature but not stated properly or restricted the inputsof most of the web servers and standalone software programsthat implement them.

Results: A quantitative comparison on the similarities and differencesamong some of the published DNA/DNA T_m calculation methods isreported. The comparison was carried out for a large set ofshort oligonucleotide sequences ranging from 16 to 30 nt long,which span the whole range of CG-content. The results showedthat significant differences were observed in all the methods,which in some cases depend on the oligonucleotide length andCG-content in a non-trivial manner. Based on these results,the regions of consensus and disagreement for the methods inthe oligonucleotide feature space were reported. Owing to thelack of sufficient experimental data, a fair and complete assessmentof accuracy for the different methods is not yet possible. Inspiteof this limitation, a consensus T_m with minimal error probabilitywas calculated by averaging the values obtained from two ormore methods that exhibit similar behavior to each particularcombination of oligonucleotide length and CG-content class.Using a total of 348 DNA sequences in the size range between16mer and 30mer, for which the experimental T_m data are available,we demonstrated that the consensus T_m is a robust and accuratemeasure. It is expected that the results of this work wouldbe constituted as a useful set of guidelines to be followedfor the successful experimental implementation of various molecularbiology techniques, such as quantitative PCR, multiplex PCRand the design of optimal DNA microarrays.

Availability: A binary software distribution to calculate theconsensus T_m described in this work for thousands of oligonucleotidessimultaneously for the LINUX operating system is freely availableupon request to the authors or from our website http://protein.bio.puc.cl/melting-temperatures.html

Contact: fmelo{at}bio.puc.cl

Supplementary information: The large set of oligonucleotides,the detailed results of the comparative and accuracy benchmarks,and hundreds of comparative graphs generated during this workare available at our website http://protein.bio.puc.cl/melting-temperatures.html

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