Project description:Recombinant human erythropoietin administration studies involving transcriptomic approaches have demonstrated a gene-expression signature that could aid detection of blood doping. However, current anti-doping testing does not involve blood collection into tubes with RNA preservative. This study investigated if whole blood in long-term storage and whole blood leftover from standard haematological testing in short-term storage could be used for transcriptomic analysis despite lacking RNA preservative. Whole blood samples were collected from thirteen and fourteen healthy males, for long-term and short-term storage experiments. Long-term storage: whole blood collected into Tempus™ tubes and K2EDTA tubes and subjected to long-term (i.e., −80°C) storage and RNA extracted. After storage, K2EDTA tubes were thawed and extracted using GeneJET RNA Purification Kit (Thermo Fisher Scientific, Vilnius, Lithuania) or Tempus™ Spin RNA Isolation Kit (Life Technologies, Carlsbad, CA, USA). RNA quality and purity was sufficient for gene expression analysis. Principle Component Analysis of microarray and RNA-seq gene expression data for long-term storage: When comparing gene expression between blood tubes with and without RNA preservation, 6% (4058 transcripts) were differentially expressed. RNA quantity, purity and integrity was not significantly compromised from long-term storage in blood storage tubes lacking RNA preservative, indicating that transcriptomic analysis could be conducted using anti-doping samples collected or biobanked without RNA preservation.

Project description:Purpose: Recombinant human erythropoietin administration studies involving “omics” approaches have demonstrated a gene-expression signature that could aid detection of blood doping. However, current anti-doping testing does not involve blood collection into tubes with RNA preservative. This study investigated if whole blood in short-term storage could be used for transcriptomic analysis despite lacking RNA preservation. Methods: Whole blood samples were collected from fourteen male healthy individuals. Short-term storage: whole blood collected into K2EDTA tubes and subjected to short-term (i.e., at 4°C) storage for 6 hours, 12 hours, 24 hours and 48 hours. After storage, blood from K2EDTA tubes were transferred into Tempus™ Blood tubes, and then extracted using Tempus™ Spin RNA Isolation Kit (Life Technologies, Carlsbad, CA, USA). Samples from four subjects of each time point that presented higher RIN value (≥7) were selected for RNA_Seq analysis. Results: The experiment provided RNA quality and purity for gene expression analysis. Considering 6-hours storage as a reference group, the number of differentially expressed genes were 19, 45 and 70 in comparison to 12, 24 and 48-hours, respectively (which means 0.37, 0.88 and 1.37% of mapped genes). Of the 19 differentially expressed genes in the comparison 6 vs. 12-hours, 9 overlapped with the 45 in the comparison 12 vs. 24-hours. Furthermore, 40 of those 45 overlapped with the 70 differentially expressed in the comparison 6 vs. 48-hours. None of the transcripts described in previous studies (Durussel et al. 2016; Wang, Durussel, et al. 2017) were differently expressed. Conclusion: RNA quantity, purity and integrity was not significantly compromised from short-term storage in blood storage tubes lacking RNA stabilisation, indicating that transcriptomic/omics analysis could be conducted using anti-doping samples collected without RNA preservation.

Project description:Integrating whole blood transcriptomic collection procedures into the current anti-doping testing system, including long-term storage and re-testing of anti-doping samples [Long-term]

Project description:Integrating whole blood transcriptomic collection procedures into the current anti-doping testing system, including long-term storage and re-testing of anti-doping samples [Short-term]

Project description:Integrating whole blood transcriptomic collection procedures into the current anti-doping testing system, including long-term storage and re-testing of anti-doping samples

Project description:Integrating whole blood transcriptomic collection procedures into the current anti-doping testing system, including long-term storage and re-testing of anti-doping samples

Project description:We conducted an animal experiment and used total RNA sequencing (RNA-Seq) to identify novel RNA markers to detect autologous blood transfusion (ABT) doping within red blood cells (RBCs) as a pilot study before human trials. The total RNA-Seq and bioinformatics were performed using rat RBCs that were stored 10- and 20-day periods with citrate–phosphate–dextrose solution with adenine (CPDA) at 4°C In the results, we identified three significant genes whose expression levels were drastically decreased according to the storage period. Our novel insights may allow future studies to develop a test method for ABT doping.

Project description:To compare gene expression in whole blood samples collected in PAXgene RNA or Tempus collection tubes, and processed using the PAXgene Blood RNA Kit or Tempus Spin RNA isolation Kit, respectively.

Project description:Analysis of long-term freezing on the stability of transcriptome profiles in PAXgene stabilized whole blood samples. In the present study it was tested if long-term freezing of PAXgene RNA tubes (up to one year) has an influence on the transcriptome profile of peripheral whole blood samples. Results indicated that gene expression profiles of whole blood samples stabilized with PAXgene RNA tubes remain stable for at least 1 year. Total RNA was obtained from peripheral whole blood samples collected in PAXgene RNA tubes of healthy human subjects. RNA was either isolated after 24h storage at room temperature or after freezing of PAXgene RNA tubes for up to 1 year (6 weeks, 6 months and 12 months).

Project description:Gene doping model by hEPO (human erythropoietin) and adenoviral vector was established in the study. This study revealed that the gene expression profile in whole blood on the gene doping model significantly altered, which may be a new marker of hEPO-gene doping