Abstract
Reverse transcription quantitative polymerase chain reaction (RT-qPCR) is considered as the gold standard for accurate, sensitive, and fast measurement of gene expression. Prior to downstream statistical analysis, RT-qPCR fluorescence amplification curves are summarized into one single value, the quantification cycle (Cq). When RT-qPCR does not reach the limit of detection, the Cq is labeled as “undetermined”. Current state of the art qPCR data analysis pipelines acknowledge the importance of normalization for removing non-biological sample to sample variation in the Cq values. However, their strategies for handling undetermined Cq values are very ad hoc. We show that popular methods for handling undetermined values can have a severe impact on the downstream differential expression analysis. They introduce a considerable bias and suffer from a lower precision. We propose a novel method that unites preprocessing and differential expression analysis in a single statistical model that provides a rigorous way for handling undetermined Cq values. We compare our method with existing approaches in a simulation study and on published microRNA and mRNA gene expression datasets. We show that our method outperforms traditional RT-qPCR differential expression analysis pipelines in the presence of undetermined values, both in terms of accuracy and precision.
Highlights
High-throughput reverse transcription quantitative polymerase chain reaction (RT-qPCR) is a popular technology for gene expression profiling
From a statistical point of view, undetermined Cq-values (UV) can be considered as right censored, i.e. the data is incompletely observed, but UV are known to correspond with a Cq of at least LOD cycles (e.g. LOD = 40); we observe an undetermined value as the LOD
We proposed a unified censored normal regression (UCNR) model for analyzing differential expression in qPCR experiments
Summary
High-throughput reverse transcription quantitative polymerase chain reaction (RT-qPCR) is a popular technology for gene expression profiling. An important advantage of qPCR is the speed, specificity and sensitivity of the qPCR assays. QPCR is often referred to as the gold standard for gene expression profiling [e.g. It is commonly used within the context of diagnostic and prognostic testing as well as for biological validation of biomarkers discovered in large screening experiments with microarray or generation sequencing technologies. QPCR differential gene expression analysis the manuscript. The specific roles of these authors are articulated in the ‘author contributions’ section
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