Statistical modeling of sequencing errors in SAGE libraries

doi:10.1093/bioinformatics/bth924

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Statistical modeling of sequencing errors in SAGE libraries

Tim Beißbarth ¹^,*, Lavinia Hyde ¹, Gordon K. Smyth ¹, Chris Job ², Wee-Ming Boon ², Seong-Seng Tan ², Hamish S. Scott ¹ and Terence P. Speed ¹

¹ Walter and Eliza Hall Institute of Medical Research, Genetics and Bioinformatics, 1G Royal Parade, Parkville, Vic 3050, Australia and ² Howard Florey Institute, Brain Development Laboratory, University of Melbourne, Parkville, Vic 3010, Australia

Received on January 15, 2004; accepted on March 1, 2004

Motivation: Sequencing errors may bias the gene expression measurementsmade by Serial Analysis of Gene Expression (SAGE). They mayintroduce non-existent tags at low abundance and decrease thereal abundance of other tags. These effects are increased inthe longer tags generated in LongSAGE libraries. Current sequencingtechnology generates quite accurate estimates of sequencingerror rates. Here we make use of the sequence neighborhood ofSAGE tags and error estimates from the base-calling softwareto correct for such errors.

Results: We introduce a statistical model for the propagationof sequencing errors in SAGE and suggest an Expectation-Maximization(EM) algorithm to correct for them given observed sequencesin a library and base-calling error estimates. We tested ourmethod using simulated and experimental SAGE libraries. Whencomparing SAGE libraries, we found that sequencing errors canintroduce considerable bias. High abundance tags may be falselycalled as significantly differentially expressed, especiallywhen comparing libraries with different levels of sequencingerrors and/or of different size. Truly, differentially expressedtags have decreased significance as ‘true’-tag countsare generally underestimated. This may alter if tags near thethreshold of differential expression are called significant.Moreover, the number of different transcripts present in a libraryis overestimated as false tags are introduced at low abundance.Our correction method adjusts the tag counts to be closer tothe true counts and is able to partly correct for biases introducedby sequencing errors.

Availability: An implementation using R is distributed as anR package. An online version is available at http://tagcalling.mbgproject.org

Contact: beissbarth{at}wehi.edu.au

^* To whom correspondence should be addressed.

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