Su Kah Goh1,2, Vijayaragavan Muralidharan2, Christopher Christophi2, Hongdo Do1,3,4, Alexander Dobrovic5,3,4. 1. Translational Genomics and Epigenomics Laboratory, Olivia Newton-John Cancer Research Institute, Heidelberg, Victoria, Australia. 2. Department of Surgery, University of Melbourne, Austin Health, Heidelberg, Victoria, Australia. 3. School of Cancer Medicine, La Trobe University, Bundoora, Victoria, Australia. 4. Department of Pathology, University of Melbourne, Parkville, Victoria, Australia. 5. Translational Genomics and Epigenomics Laboratory, Olivia Newton-John Cancer Research Institute, Heidelberg, Victoria, Australia; alex.dobrovic@onjcri.org.au.
Abstract
BACKGROUND: Donor-specific cell-free DNA (dscfDNA) is increasingly being considered as a noninvasive biomarker to monitor graft health and diagnose graft rejection after solid-organ transplantation. However, current approaches used to measure dscfDNA can be costly and/or laborious. A probe-free droplet digital PCR (ddPCR) methodology using small deletion/insertion polymorphisms (DIPs) was developed to circumvent these limitations without compromising the quantification of dscfDNA. This method was called PHABRE-PCR (Primer to Hybridize across an Allelic BREakpoint-PCR). The strategic placement of one primer to hybridize across an allelic breakpoint ensured highly specific PCR amplification, which then enabled the absolute quantification of donor-specific alleles by probe-free ddPCR. METHODS: dscfDNA was serially measured in 3 liver transplant recipients. Donor and recipient genomic DNA was first genotyped against a panel of DIPs to identify donor-specific alleles. Alleles that differentiated donor-specific from recipient-specific DNA were then selected to quantify dscfDNA in the recipient plasma. RESULTS: Lack of amplification of nontargeted alleles confirmed that PHABRE-PCR was highly specific. In recipients who underwent transplantation, dscfDNA was increased at day 3, but decreased and plateaued at a low concentration by 2 weeks in the 2 recipients who did not develop any complications. In the third transplant recipient, a marked increase of dscfDNA coincided with an episode of graft rejection. CONCLUSIONS: PHABRE-PCR was able to quantify dscfDNA with high analytical specificity and sensitivity. The implementation of a DIP-based approach permits surveillance of dscfDNA as a potential measure of graft health after solid-organ transplantation.
BACKGROUND:Donor-specific cell-free DNA (dscfDNA) is increasingly being considered as a noninvasive biomarker to monitor graft health and diagnose graft rejection after solid-organ transplantation. However, current approaches used to measure dscfDNA can be costly and/or laborious. A probe-free droplet digital PCR (ddPCR) methodology using small deletion/insertion polymorphisms (DIPs) was developed to circumvent these limitations without compromising the quantification of dscfDNA. This method was called PHABRE-PCR (Primer to Hybridize across an Allelic BREakpoint-PCR). The strategic placement of one primer to hybridize across an allelic breakpoint ensured highly specific PCR amplification, which then enabled the absolute quantification of donor-specific alleles by probe-free ddPCR. METHODS: dscfDNA was serially measured in 3 liver transplant recipients. Donor and recipient genomic DNA was first genotyped against a panel of DIPs to identify donor-specific alleles. Alleles that differentiated donor-specific from recipient-specific DNA were then selected to quantify dscfDNA in the recipient plasma. RESULTS: Lack of amplification of nontargeted alleles confirmed that PHABRE-PCR was highly specific. In recipients who underwent transplantation, dscfDNA was increased at day 3, but decreased and plateaued at a low concentration by 2 weeks in the 2 recipients who did not develop any complications. In the third transplant recipient, a marked increase of dscfDNA coincided with an episode of graft rejection. CONCLUSIONS: PHABRE-PCR was able to quantify dscfDNA with high analytical specificity and sensitivity. The implementation of a DIP-based approach permits surveillance of dscfDNA as a potential measure of graft health after solid-organ transplantation.
Authors: Michael Oellerich; Karen Sherwood; Paul Keown; Ekkehard Schütz; Julia Beck; Johannes Stegbauer; Lars Christian Rump; Philip D Walson Journal: Nat Rev Nephrol Date: 2021-05-24 Impact factor: 28.314
Authors: Su Kah Goh; Hongdo Do; Adam Testro; Julie Pavlovic; Angela Vago; Julie Lokan; Robert M Jones; Christopher Christophi; Alexander Dobrovic; Vijayaragavan Muralidharan Journal: Transplant Direct Date: 2019-06-21
Authors: Zimeng Ye; Zac Chatterton; Jahnvi Pflueger; John A Damiano; Lara McQuillan; Anthony Simon Harvey; Stephen Malone; Hongdo Do; Wirginia Maixner; Amy Schneider; Bernadette Nolan; Martin Wood; Wei Shern Lee; Greta Gillies; Kate Pope; Michael Wilson; Paul J Lockhart; Alexander Dobrovic; Ingrid E Scheffer; Melanie Bahlo; Richard J Leventer; Ryan Lister; Samuel F Berkovic; Michael S Hildebrand Journal: Brain Commun Date: 2021-01-21
Authors: Hajnalka Andrikovics; Zoltán Őrfi; Nóra Meggyesi; András Bors; Lívia Varga; Petra Kövy; Zsófia Vilimszky; Fanni Kolics; László Gopcsa; Péter Reményi; Attila Tordai Journal: Int J Mol Sci Date: 2019-09-10 Impact factor: 5.923
Authors: Eva-Maria Dauber; Dagmar Kollmann; Nicolas Kozakowski; Susanne Rasoul-Rockenschaub; Thomas Soliman; Gabriela A Berlakovich; Wolfgang R Mayr Journal: Transpl Int Date: 2019-12-13 Impact factor: 3.782