S. Gorham

Circulating cell-free DNA as a biomarker of tissue injury: Assessment in a cardiac xenotransplantation model

BACKGROUND Observational studies suggest that cell-free DNA (cfDNA) is a biomarker of tissue injury in a range of conditions including organ transplantation. However, the lack of model systems to study cfDNA and its relevance to tissue injury has limited the advancements in this field. We hypothesized that the predictable course of acute humoral xenograft rejection (AHXR) in organ transplants from genetically engineered donors provides an ideal system for assessing circulating cfDNA as a marker of tissue injury. METHODS Genetically modified pig donor hearts were heterotopically transplanted into baboons (n = 7). Cell-free DNA was extracted from pre-transplant and post-transplant baboon plasma samples for shotgun sequencing. After alignment of sequence reads to pig and baboon reference sequences, we computed the percentage of xenograft-derived cfDNA (xdcfDNA) relative to recipient by counting uniquely aligned pig and baboon sequence reads. RESULTS The xdcfDNA percentage was high early post-transplantation and decayed exponentially to low stable levels (baseline); the decay half-life was 3.0 days. Post-transplantation baseline xdcfDNA levels were higher for transplant recipients that subsequently developed graft loss than in the 1 animal that did not reject the graft (3.2% vs 0.5%). Elevations in xdcfDNA percentage coincided with increased troponin and clinical evidence of rejection. Importantly, elevations in xdcfDNA percentage preceded clinical signs of rejection or increases in troponin levels. CONCLUSION Cross-species xdcfDNA kinetics in relation to acute rejection are similar to the patterns in human allografts. These observations in a xenotransplantation model support the body of evidence suggesting that circulating cfDNA is a marker of tissue injury.

Late manifestation of alloantibody-associated injury and clinical pulmonary antibody-mediated rejection: Evidence from cell-free DNA analysis

BACKGROUND Antibody-mediated rejection (AMR) often progresses to poor health outcomes in lung transplant recipients (LTRs). This, combined with the relatively insensitive clinical tools used for its diagnosis (spirometry, histopathology) led us to determine whether clinical AMR is diagnosed significantly later than its pathologic onset. In this study, we leveraged the high sensitivity of donor-derived cell-free DNA (ddcfDNA), a novel genomic tool, to detect early graft injury after lung transplantation. METHODS We adjudicated AMR and acute cellular rejection (ACR) in 157 LTRs using the consensus criteria of the International Society for Heart and Lung Transplantation (ISHLT). We assessed the kinetics of allograft injury in relation to ACR or AMR using both clinical criteria (decline in spirometry from baseline) and molecular criteria (ddcfDNA); percent ddcfDNA was quantitated via shotgun sequencing. We used a mixed-linear model to assess the relationship between and ddcfDNA levels and donor-specific antibodies (DSA) in AMR+ LTRs. RESULTS Compared with ACR, AMR episodes (n = 42) were associated with significantly greater allograft injury when assessed by both spirometric (0.1 liter vs -0.6 liter, p < 0.01) and molecular (ddcfDNA) analysis (1.1% vs 5.4%, p < 0.001). Allograft injury detected by ddcfDNA preceded clinical AMR diagnosis by a median of 2.8 months. Within the same interval, spirometry or histopathology did not reveal findings of allograft injury or dysfunction. Elevated levels of ddcfDNA before clinical diagnosis of AMR were associated with a concurrent rise in DSA levels. CONCLUSION Diagnosis of clinical AMR in LTRs lags behind DSA-associated molecular allograft injury as assessed by ddcfDNA.