Effect of the Anti‐C1s Humanized Antibody TNT009 and Its Parental Mouse Variant TNT003 on HLA Antibody–Induced Complement Activation—A Preclinical In Vitro Study

The classic pathway (CP) of complement is believed to significantly contribute to alloantibody‐mediated transplant injury, and targeted complement inhibition is currently considered to be a promising approach for preventing rejection. Here, we investigated the mode of action and efficacy of the humanized anti‐C1s monoclonal antibody TNT009 and its parental mouse variant, TNT003, in preclinical in vitro models of HLA antibody–triggered CP activation. In flow cytometric assays, we measured the attachment of C1 subcomponents and C4/C3 split products (C4b/d, C3b/d) to HLA antigen–coated flow beads or HLA‐mismatched aortic endothelial cells and splenic lymphocytes. Anti‐C1s antibodies profoundly inhibited C3 activation at concentrations >20 μg/mL, in both solid phase and cellular assays. While C4 activation was also prevented, this was not the case for C1 subcomponent attachment. Analysis of serum samples obtained from 68 sensitized transplant candidates revealed that the potency of inhibition was related to the extent of baseline CP activation. This study demonstrates that anti‐C1s antibodies TNT009 and TNT003 are highly effective in blocking HLA antibody–triggered complement activation downstream of C1. Our results provide the foundation for clinical studies designed to investigate the potential of TNT009 in the treatment or prevention of complement‐mediated tissue injury in sensitized transplant recipients.     

Complement inhibition as potential new therapy for antibody‐mediated rejection

Antibody‐mediated rejection (ABMR) is a leading cause of kidney allograft failure. While the exact mechanisms contributing to donor‐specific antibody (DSA)‐triggered tissue injury are still incompletely understood, complement activation via the classical pathway is believed to be one of the key players. There is now growing interest in complement blockade as an antirejection treatment. One attractive strategy may be inhibition of terminal complex formation using anti‐C5 antibody eculizumab. Anecdotal reports, case series, and a unique cohort of flow crossmatch‐positive live donor kidney transplant recipients subjected to eculizumab‐based desensitization have demonstrated successful prevention and reversal of acute clinical ABMR. Nevertheless, maybe due to complement activation steps proximal of C5 or even complement‐independent mechanisms, subclinical rejection processes that might culminate in chronic injury were found to escape inhibition. Larger studies designed to clarify the actual clinical value of terminal complement inhibition as an antirejection treatment are currently underway. In addition, alternative concepts, such as therapies that target key component C1, are currently under development, and we will see in the near future whether new strategies in the pipeline will have the potential to beneficially impact clinical practice.     

Histological picture of antibody‐mediated rejection without donor‐specific anti‐HLA antibodies: Clinical presentation and implications for outcome

In this cohort study (n = 935 transplantations), we investigated the phenotype and risk of graft failure in patients with histological criteria for antibody‐mediated rejection (ABMR) in the absence of circulating donor‐specific anti‐human leukocyte antigen (HLA) antibodies (DSA), and compared this to patients with definite ABMR and HLA‐DSA‐positivity. The histological picture did not differ between HLA‐DSA‐positive (n = 85) and HLA‐DSA‐negative (n = 123) cases of ABMR histology, apart from increased complement split product 4d (C4d) deposition in the peritubular capillaries in HLA‐DSA‐positive cases. Histology of ABMR without HLA‐DSA was more transient than DSA‐positive ABMR, and patients with ABMR histology without HLA‐DSA had graft survival superior to that of HLA‐DSA‐positive patients, independent of concomitant T cell–mediated rejection (38.2%) or borderline changes (17.9%). Multivariate analysis showed that the risk of graft failure was not higher in patients with histological picture of ABMR (ABMR_h) in the absence of HLA‐DSA, compared to patients without ABMR_h. Despite an association between C4d deposition and HLA‐DSA‐positivity, using C4d deposition as alternative for the DSA criterion in the diagnosis of ABMR, as proposed in Banff 2017, did not contribute to the prognosis of graft function and graft failure. We concluded that biopsies with ABMR_h but without detectable HLA‐DSA represent a distinct, often transient phenotype with superior allograft survival.     

IL‐17 Expression by Tubular Epithelial Cells in Renal Transplant Recipients with Acute Antibody‐Mediated Rejection

Acute rejection is still a common complication of kidney transplantation. IL‐17 is known to be associated with allograft rejection but the cellular source and the role of this cytokine remains unclear. We investigated IL‐17 graft expression in renal transplant recipients with acute antibody‐mediated rejection (ABMR), acute T‐cell‐mediated rejection (TCMR), interstitial fibrosis and tubular atrophy (IFTA) and acute tubular damage due to calcineurin‐inhibitor toxicity (CNI). In acute ABMR, tubular IL‐17 protein expression was significantly increased compared to TCMR, where most of the IL‐17⁺cells were CD4⁺graft infiltrating lymphocytes, IFTA and CNI control groups. The tubular expression of IL‐17 in acute ABMR colocalized with JAK2 phosphorylation and peritubular capillaries C4d deposition. In addition, IL‐17 tubular expression was directly and significantly correlated with the extension of C4d deposits. In cultured proximal tubular cells, C3a induced IL‐17 gene and protein expression along with an increased in JAK2 phosphorylation. The inhibition of JAK2 abolished C3a‐induced IL‐17 expression. The use of steroids and monoclonal antibodies reduced IL‐17 expression, JAK2 phosphorylation and C4d deposition in acute ABMR patients. Our data suggest that tubular cells represent a significant source of IL‐17 in ABMR and this event might be mediated by the complement system activation featuring this condition.     

Evaluation of C1q Status and Titer of De Novo Donor‐Specific Antibodies as Predictors of Allograft Survival

De novo donor‐specific antibodies (dnDSAs) that develop after renal transplantation are independent predictors of allograft loss. However, it is unknown if dnDSA C1q status or titer at the time of first detection can independently predict allograft loss. In a consecutive cohort of 508 renal transplant recipients, 70 developed dnDSAs. Histologic and clinical outcomes were correlated with the C1q assay or dnDSA titer. C1q positivity correlated with dnDSA titer (p < 0.01) and mean fluorescence intensity (p < 0.01) and was more common in class II versus class I dnDSAs (p < 0.01). C1q status correlated with tubulitis (p = 0.02) and C4d status (p = 0.03) in biopsies at the time of dnDSA development, but not T cell–mediated rejection (TCMR) or antibody‐mediated rejection (ABMR). De novo DSA titer correlated with Banff g, i, t, ptc, C4d scores, TCMR (p < 0.01) and ABMR (p < 0.01). Post‐dnDSA graft loss was observed more frequently in recipients with C1q‐positve dnDSA (p < 0.01) or dnDSA titer ≥ 1:1024 (p ≤ 0.01). However, after adjustment for clinical phenotype and nonadherence in multivariate models, neither C1q status nor dnDSA titer were independently associated with allograft loss, questioning the utility of these assays at the time of dnDSA development.     

A Probabilistic Approach to Histologic Diagnosis of Antibody‐Mediated Rejection in Kidney Transplant Biopsies

Histologic diagnosis of antibody‐mediated rejection (ABMR) in kidney transplant biopsies uses lesion score cutoffs such as 0 versus >0 rather than actual scores and requires donor‐specific antibody (DSA); however, cutoffs lose information, and DSA is not always reliable. Using microarray‐derived molecular ABMR scores as a histology‐independent estimate of ABMR in 703 biopsies, we reassessed criteria for ABMR to determine relative importance of various lesions, the utility of equations using actual scores rather than cutoffs, and the potential for diagnosing ABMR when DSA is unknown or negative. We confirmed that the important features for ABMR diagnosis were peritubular capillaritis (ptc), glomerulitis (g), glomerular double contours, DSA and C4d staining, but we questioned some features: arterial fibrosis, vasculitis, acute tubular injury, and sum of ptc+g scores. Regression equations using lesion scores predicted molecular ABMR more accurately than score cutoffs (area under the curve 0.85–0.86 vs. 0.75). DSA positivity improved accuracy, but regression equations predicted ABMR with moderate accuracy when DSA was unknown. Some biopsies without detectable DSA had high probability of ABMR by regression, although most had HLA antibody. We concluded that regression equations using lesion scores plus DSA maximized diagnostic accuracy and can estimate probable ABMR when DSA is unknown or undetectable.     

Early clinical experience using donor‐derived cell‐free DNA to detect rejection in kidney transplant recipients

Donor‐derived cell‐free DNA (dd‐cfDNA) became Medicare reimbursable in the United States in October 2017 for the detection of rejection in kidney transplant recipients based on results from its pivotal validation trial, but it has not yet been externally validated. We assessed 63 adult kidney transplant recipients with suspicion of rejection with dd‐cfDNA and allograft biopsy. Of these, 27 (43%) patients had donor–specific antibodies and 34 (54%) were found to have rejection by biopsy. The percentage of dd‐cfDNA was higher among patients with antibody–mediated rejection (ABMR; median 1.35%; interquartile range [IQR]: 1.10%‐1.90%) compared to those with no rejection (median 0.38%, IQR: 0.26%‐1.10%; P < .001) and cell–mediated rejection (CMR; median: 0.27%, IQR: 0.19%‐1.30%; P = .01). The dd‐cfDNA test did not discriminate patients with CMR from those without rejection. The area under the ROC curve (AUC) for CMR was 0.42 (95% CI: 0.17‐0.66). For ABMR, the AUC was 0.82 (95% CI: 0.71‐0.93) and a dd‐cfDNA ≥0.74% yielded a sensitivity of 100%, specificity 71.8%, PPV 68.6%, and NPV 100%. The dd‐cfDNA test did not discriminate CMR from no rejection among kidney transplant recipients, although performance characteristics were stronger for the discrimination of ABMR.     

Complement Independent Antibody‐Mediated Endarteritis and Transplant Arteriopathy in Mice

Complement fixation, as evidenced by C4d in the microvasculature, is a widely accepted criterion of antibody‐mediated rejection. Complement fixation has been shown to be essential in acute antibody‐mediated rejection, but its role in chronic rejection has not been addressed. Previous studies showed that passive transfer of complement fixing monoclonal IgG2a anti‐H‐2K^k into B6.RAG1^?/? KO recipients of B10.BR hearts led to progressive chronic transplant arteriopathy (CTA) over 14–28 days, accompanied by C4d deposition. The present studies were designed to test whether complement was required for these lesions. We report that a noncomplement fixing donor‐specific alloantibody (DSA, monoclonal IgG1 anti‐H‐2K^k) injected into B6.RAG1^‐/‐ KO recipients of B10.BR hearts also promotes CTA, without C4d deposition. Furthermore, a passive transfer of DSA (monoclonal IgG2a anti‐H‐2K^k) initiated endarteritis followed by CTA in B6.RAG1^?/‐ mice genetically deficient in the third component of complement (RAG1^?/?C3^?/?). These studies indicate that antibody to class I MHC antigens can trigger chronic arterial lesions in vivo without complement participation, in contrast to acute antibody‐mediated rejection. This pathway may be relevant to C4d‐negative chronic rejection sometimes observed in patients with DSA, and argues that lack of C4d deposition does not exclude antibody‐mediated chronic rejection.     

C1 Inhibitor in Acute Antibody‐Mediated Rejection Nonresponsive to Conventional Therapy in Kidney Transplant Recipients: A Pilot Study

Complement inhibitors have not been thoroughly evaluated in the treatment of acute antibody‐mediated rejection (ABMR). We performed a prospective, single‐arm pilot study to investigate the potential effects and safety of C1 inhibitor (C1‐INH) Berinert added to high‐dose intravenous immunoglobulin (IVIG) for the treatment of acute ABMR that is nonresponsive to conventional therapy. Kidney recipients with nonresponsive active ABMR and acute allograft dysfunction were enrolled between April 2013 and July 2014 and received C1‐INH and IVIG for 6 months (six patients). The primary end point was the change in eGFR at 6 months after inclusion (M+6). Secondary end points included the changes in histology and DSA characteristics and adverse events as evaluated at M+6. All patients showed an improvement in eGFR between inclusion and M+6: from 38.7 ± 17.9 to 45.2 ± 21.3 mL/min/1.73 m² (p = 0.0277). There was no change in histological features, except a decrease in the C4d deposition rate from 5/6 to 1/6 (p = 0.0455). There was a change in DSA C1q status from 6/6 to 1/6 positive (p = 0.0253). One deep venous thrombosis was observed. In a secondary analysis, C1‐INH patients were compared with a similar historical control group (21 patients). C1‐INH added to IVIG is safe and may improve allograft function in kidney recipients with nonresponsive acute ABMR.     

Clinical utility of C3d binding donor‐specific anti‐human leukocyte antigen antibody detection by single antigen beads after kidney transplantation—a retrospective study

Development of donor‐specific antibodies (DSA) after renal transplantation is known to be associated with worse graft survival, yet determining which specificities in which recipients are the most deleterious remains under investigation. This study evaluated the relationship of the complement binding capacity of post‐transplant de novo anti‐human leukocyte antigen (HLA) antibodies with subsequent clinical outcome. Stored sera from 265 recipients previously identified as having de novo DSA were retested for DSA and their C3d binding capacity using Luminex‐based solid‐phase assays. Most recipients had anti‐HLA class II‐reactive DSA (class I = 12.5%, class II = 68.7%, class I and class II = 18.9%). The recipients that had C3d binding DSA (67.5%) had a significantly higher incidence of antibody‐mediated rejection and any rejection. They also had significantly lower kidney survival, with the lowest survival in those that had both anti‐HLA class I and class II C3d binding DSA. Concurrent biopsy comparison revealed a 96.2% positive predictive value and 47.4% negative predictive value for C4d peritubular capillary (Ptc) deposition. Anti‐HLA class I and class II C3d binding DSA carried a twofold and 1.5‐fold increased risk of kidney loss, respectively, in multivariate analysis.     

Markers of graft microvascular endothelial injury may identify harmful donor‐specific anti‐HLA antibodies and predict kidney allograft loss

Graft microvasculature is a major target of donor‐specific antibodies (DSA) and endothelial damage is direct evidence of antibody‐mediated rejection (ABMR). Using immunohistochemistry, we analyzed the expression of three microvascular endothelial activation markers (fascin, vimentin, and hsp47), suggestive of endothelial‐to‐mesenchymal transition (EndMT) in 351 graft biopsies from 248 kidney recipients, with concomitant screening of circulating antihuman leukocyte antigen (HLA) DSA at the time of the biopsy. The factors associated with EndMT marker expression were DSA and the presence of microvascular inflammation (MI). EndMT expressing grafts had significantly more allograft loss compared to EndMT negative grafts (P < .0001). The expression of EndMT markers positively correlated with anti‐HLA DSA class II mean fluorescence intensity (MFI) levels and especially identified DQ and DR antibodies as being more closely associated with microvascular injury. Moreover, only DSA linked to positive EndMT score affected allograft survival, regardless of DSA MFI levels or presence of C4d deposition. Thus, EndMT markers could represent a clinically relevant tool for early identification of ongoing endothelial injury, harmful DSA, and patients at high risk for allograft failure.     

What have we learned about how to prevent and treat antibody‐mediated rejection in kidney transplantation?

Antibody‐mediated rejection (ABMR) in kidney transplantation is a major cause of late graft loss, and despite all efforts to date the “standard of care” remains plasmapheresis, IVIg, and steroids, which itself is based on low quality evidence. This review focuses on the risk factors leading to memory and de novo donor‐specific antibody (DSA)‐associated ABMR, the optimal prevention strategies for ABMR, and advances in  adjunctive and emerging therapies for ABMR. Because new agents require regulatory approval via a Phase 3 randomized control trial (RCT), an overview of progress in innovative trial design for ABMR is provided. Finally, based on the insights gained in the biology of ABMR, current knowledge gaps are identified for future research that could significantly affect our understanding of how to optimally treat ABMR.     

Isolated v‐lesion in kidney transplant recipients: Characteristics,association with DSA,and histological follow‐up

Isolated v‐lesion (IvL) represents a rare and challenging situation in renal allograft biopsies because it is unknown whether IvL truly represents rejection, antibody‐ or T cell–mediated, or not. This multicentric retrospective study describes the clinicopathological features of IvL with an emphasis on the donor‐specific antibody (DSA) status, histological follow‐up, and graft survival. Inclusion criteria were the presence of v‐lesion with minimal interstitial (i ≤ 1) and microvascular inflammation (g + ptc≤1). C4d‐positive biopsies were excluded. We retrospectively found 33 IvL biopsies in 33 patients, mainly performed in the early posttransplantation period (median time 27 days) and clinically indicated in 66.7%. A minority of recipients (5/33, 15.2%) had DSA at the time of biopsy. IvL was treated by anti‐rejection therapy in 21 cases (63.6%), whereas 12 (36.4%) were untreated. Seventy percent of untreated patients and 66% of treated patients showed favorable histological evolution on subsequent biopsy. Kidney graft survival in IvL was significantly higher than in a matched cohort of antibody‐mediated rejection with arteritis. In conclusion, IvL is not primarily antibody‐mediated and may show a favorable evolution. The heterogeneity of IvL pathophysiology on early biopsies should prompt DSA testing as well as close clinical and histological follow‐up in all patients with IvL.     

Development and outcomes of de novo donor‐specific antibodies in low,moderate, and high immunological risk kidney transplant recipients

De novo donor‐specific antibodies (dnDSA) play an important role in antibody‐mediated rejection (ABMR) and graft failure, yet their development in kidney transplant recipients (KTx) of higher immunological risk has not been characterized. We prospectively determined the incidence of dnDSA at 3 and 12 months posttransplant and assessed their associations with outcomes in recipients stratified by low, moderate, and high immunological risk. Adult KTx were screened for DSA pretransplant, months 3 and 12 posttransplant, and when clinically indicated. Outcomes included incidence of dnDSA, death‐censored graft survival (DCGS), and ABMR. Of 371 recipients, 154 (42%) were transplanted across a pretransplant DSA that became undetectable by 12 months posttransplant in 78% of cases. dnDSA were detected in 16% (95% confidence interval [CI]: 12‐20%) by 3 months and 23% (95% CI: 18‐29%) by 12 months posttransplant. Incidence at 12 months was higher in the moderate (30%) and high‐risk groups (29%) compared to the low‐risk group (16%). dnDSA were associated with an increased risk of ABMR (hazard ratio [HR] 2.2; 95% CI: 1.1‐4.4; P = .04) but were not an independent risk factor for DCGS. In conclusion, dnDSA were more frequent in transplant recipients of higher immune risk and associated with an increased risk of ABMR.     

Value of monitoring circulating donor‐reactive memory B cells to characterize antibody‐mediated rejection after kidney transplantation

Antibody‐mediated rejection (ABMR) is defined by specific histopathological lesions and evidence of circulating donor‐specific antibodies (DSA). Although DSA are not always detectable, monitoring donor‐reactive memory B cells (mBC) could identify patients at risk of developing ABMR. Peripheral donor‐reactive mBC using a novel HLA B cell ELISpot assay, serum DSA, and numbers of different B cell subsets were assessed in 175 consecutive kidney transplants undergoing either for‐cause or 6‐ and 24‐month surveillance biopsies for their association with main histological lesions of ABMR and impact on allograft outcome. In 85 incident for‐cause biopsies, high frequencies of donor‐reactive mBC were detected in all 16 (100%) acute ABMR/DSA+ and most chronic ABMR, with or without DSA (24/30[80%] and 21/29[72.4%], respectively). In a longitudinal cohort of 90 nonsensitized patients, a progressively higher expansion of donor‐reactive mBC than de novo DSA was observed at 6 and 24 months (8.8% vs 7.7% and 15.5% vs 11.1%, respectively) and accurately identified patients with ongoing subclinical ABMR (area under the curve = 0.917 and area under the curve = 0.809, respectively). An unsupervised hierarchical cluster analysis revealed a strong association between donor‐reactive mBC with main fundamental allograft lesions associated with ABMR and conferred a significant deleterious impact on graft outcome. Monitoring donor‐reactive mBC may be useful to further characterize humoral rejection after kidney transplantation.     

Solid phase detection of C4d‐fixing HLA antibodies to predict rejection in high immunological risk kidney transplant recipients

Protocols for recipient desensitization may allow for successful kidney transplantation across major immunological barriers. Desensitized recipients, however, still face a considerable risk of antibody‐mediated rejection (AMR), which underscores the need for risk stratification tools to individually tailor treatment. Here, we investigated whether solid phase detection of complement‐fixing donor‐specific antibodies (DSA) has the potential to improve AMR prediction in high‐risk transplants. The study included 68 sensitized recipients of deceased donor kidney allografts who underwent peritransplant immunoadsorption for alloantibody depletion (median cytotoxic panel reactivity: 73%; crossmatch conversion: n = 21). Pre and post‐transplant sera were subjected to detection of DSA‐triggered C4d deposition ([C4d]DSA) applying single‐antigen bead (SAB) technology. While standard crossmatch and [IgG]SAB testing failed to predict outcomes in our desensitized patients, detection of preformed [C4d]DSA (n = 44) was tightly associated with C4d‐positive AMR [36% vs. 8%, P = 0.01; binary logistic regression: odds ratio: 10.1 (95% confidence interval: 1.6–64.2), P = 0.01]. Moreover, long‐term death‐censored graft survival tended to be worse among [C4d]DSA‐positive recipients (P = 0.07). There were no associations with C4d‐negative AMR or cellular rejection. [C4d]DSA detected 6 months post‐transplantation were not related to clinical outcomes. Our data suggest that pretransplant SAB‐based detection of complement‐fixing DSA may be a valuable tool for risk stratification.     

Identifying Subphenotypes of Antibody‐Mediated Rejection in Kidney Transplants

The key lesions in antibody‐mediated kidney transplant rejection (ABMR) are microcirculation inflammation (peritubular capillaritis and/or glomerulitis lesions, abbreviated “pg”) and glomerular double contours (cg lesions). We used these features to explore subphenotypes in 164 indication biopsies with ABMR‐related diagnoses: 137 ABMR (109 pure and 28 mixed with T cell–mediated rejection [TCMR]) and 27 transplant glomerulopathy (TG), identified from prospective multicenter studies. The lesions indicated three ABMR subphenotypes: pgABMR, cgABMR, and pgcgABMR. Principal component analysis confirmed these subphenotypes and showed that TG can be reclassified as pgcgABMR (n = 17) or cgABMR (n = 10). ABMR‐related biopsies included 45 pgABMR, 90 pgcgABMR, and 25 cgABMR, with four unclassifiable. Dominating all time intervals was the subphenotype pgcgABMR. The pgABMR subphenotype presented earliest (median <2 years), frequently mixed with TCMR, and was most associated with nonadherence. The cgABMR subphenotype presented late (median 9 years). Subphenotypes differed in their molecular changes, with pgABMR having the most histologic–molecular discrepancies (i.e. potential errors). Donor‐specific antibody (DSA) was not identified in 29% of pgcgABMR and 46% of cgABMR, but failure rates and molecular findings were similar to cases where DSA was known to be positive. Thus, ABMR presents distinct subphenotypes, early pg‐dominant, late cg‐dominant, and combined pgcg phenotype, differing in time, molecular features, accompanying TCMR, HLA antibody, and probability of nonadherence.     

A New Diagnostic Algorithm for Antibody‐Mediated Microcirculation Inflammation in Kidney Transplants

We studied the significance of microcirculation inflammation in kidney transplants, including 329 indication biopsies from 251 renal allograft recipients, who were mostly nonpresensitized (crossmatch negative). Glomerulitis (g) and peritubular capillaritis (ptc) were often associated with antibody‐mediated rejection (65% and 75%, respectively), but were also found in other diseases in the absence of donor‐specific antibody (DSA): T‐cell‐mediated rejection (ptc, g), glomerulonephritis (g) and acute tubular necrosis (ptc). To develop rules for reducing the nonspecificity of microcirculation inflammation and defining the best grading thresholds associated with DSA, we built and validated a decision tree to predict DSA. The decision tree revealed that g + ptc sum (addition of g‐score plus ptc‐score) was the best predictor of DSA, followed by time posttransplant, then C4d, which had a small role. Late biopsies with g + ptc > 0 showed higher frequency of DSA compared to early biopsies with g + ptc > 0 (79% vs. 27%). Microcirculation inflammation in early biopsies was often false positive (antibody‐independent). The decision tree predicted DSA with higher sensitivity and accuracy than C4d staining. Microcirculation inflammation sum score predicted graft failure independently of time, C4d and transplant glomerulopathy. Thus any degree of microcirculation inflammation in late kidney transplant biopsies strongly indicates presence of DSA and predicts progression to graft failure.     

Comparison of C4d Detection on Erythrocytes and PTC‐C4d to Histological Signs of Antibody‐Mediated Rejection in Kidney Transplantation

C4d on erythrocytes (EC4d), C4d peritubular capillary deposition (PTC‐C4d) staining and histology were compared in a cross‐sectional cohort of 146 renal allograft biopsies (132 patients). EC4d levels paralleled PTC‐C4d staining, but were more predictive of peritubular capillaritis (PTC). Donor‐specific antibodies (DSA), PTC‐C4d, EC4d and PTC were analyzed in an independent longitudinal follow‐up cohort (96 biopsies, 76 patients). Seventy‐six samples were PTC and EC4d concordant, 11 positive and 65 negative, 7 PTC‐EC4d+ and 13 PTC+EC4d?. EC4d levels were related to DSA occurrence. With ABMR defined by PTC and DSA, all apparently discordant patients, EC4d negative, were correctly reassigned comparing EC4d level curves with rejection kinetics, with positive EC4d samples predating biopsy or late biopsies compared with ABMR flare‐ups. All EC4d‐positive patients without PTC or DSA had permanent high EC4d levels unrelated to rejection. EC4d was more abundant in PTC‐positive (mean = 108.5%± 3.4; n = 50) than PTC‐negative samples (mean = 88.1%± 1.3; n= 96; p < 0.0001). Sensitivity, specificity, positive predictive value and negative predictive value of PTC‐C4d and EC4d for PTC were, respectively, 75%, 79%; 64%, 76% (p < 0.05); 28%, 46% (p < 0.05) and 93%, 94%. Values were similar for DSA. A noninvasive blood test, EC4d, and particularly longitudinally monitoring EC4d levels, may increase surrogate ABMR testing options.