Defining Stable Reference Genes In Hiv Latency Reversal Experiments

Quantification of cell-associated HIV RNA (ca-RNA) is one of the most important and commonly used methods to evaluate the performance of latency-reversing agents (LRAs). Copies of HIV RNA measured by quantitative PCR (qPCR) are often normalized to the input RNA or cell number. However, these could be affected by biological variability and/or technical errors, which can be avoided by using an internal reference gene. To obtain reliable data, it is essential to select stable reference genes (RGs) of which the expression is not influenced by biological variability, the type of cells, or the LRAs used. However, to date, no study has carefully evaluated RG stability following LRA exposure. We analyzed the stability of six widely used RGs (GAPDH, TBP, YWHAZ, UBE2D2, HPRT1, and RPL27A) in human peripheral blood mononuclear cells (PBMCs) and CD4(+) T cells. LRA exposure significantly influenced the stability of these RGs. Overall, TBP, UBE2D2, and RPL27A were the most stable RGs under all tested conditions. TBP was generally the most stable RG, whereas GAPDH varied the most. Finally, we evaluated the impact of applying different RG normalizers to host genes and HIV ca-RNA data. Altered results were observed both in host and HIV gene expression when unstable RGs were used. Our data underline the importance of testing the stability of RGs utilized to evaluate LRA-induced HIV ca-RNA expression. To our knowledge, this is the first careful evaluation of the stability of RGs after LRA exposure and will significantly contribute to the quality of data analysis in regard to gene expression.IMPORTANCE Latency-reversing agents (LRAs) are ubiquitously used in the "shock-and-kill" HIV cure strategy, and their performance is often evaluated by ex vivo quantification of cell-associated HIV RNA. HIV RNA, measured by quantitative PCR (qPCR), is often normalized to internal reference genes, but the expression of these genes should not be influenced by the experimental settings. We found that treatment of human peripheral blood mononuclear cells (PBMCs) and CD4(+) T cells with LRAs significantly altered the expression of several commonly used reference genes, such as GAPDH. Finally, we evaluate the impact of different reference genes on the normalization of host genes and HIV cell-associated RNA expression and demonstrated that using unstable reference genes dramatically altered experimental outcome. Our data highlight the importance of using reference genes that are unaffected by LRAs under study to correctly evaluate host gene and cell-associated HIV RNA expression induced by latency-reversing agents.