Literature DB >> 34890687

Observations on improving COVID-19 vaccination responses in kidney transplant recipients: heterologous vaccination and immunosuppression modulation.

Christophe Masset1, Simon Ville2, Claire Garandeau3, Florent Le Borgne4, Thibaut Letellier3, Diego Cantarovich3, Aurélie Meurette3, Cécile Guillot-Gueguen3, Maxime Bentoumi-Loaec2, Magali Giral2, Jacques Dantal2, Gilles Blancho2.   

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Year:  2021        PMID: 34890687      PMCID: PMC8651481          DOI: 10.1016/j.kint.2021.11.024

Source DB:  PubMed          Journal:  Kidney Int        ISSN: 0085-2538            Impact factor:   10.612


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To the editor: Solid organ transplant recipients have a weaker humoral response to coronavirus disease 2019 (COVID-19) vaccination because of several factors, including lymphopenia associated with immunosuppressive therapies (particularly belatacept, antiproliferative drugs, and steroids). Because of the high probability of severe COVID-19 symptoms in this at-risk population, a third vaccine dose has been proposed for immunocompromised patients by the French National Authority for Health to improve humoral responses and vaccine efficiency. Despite this improved vaccination schedule, >30% of kidney transplant recipients (KTRs) do not develop a humoral response and remain at risk of severe COVID-19 infection. ChAdOx1-nCov vaccine (i.e., AstraZeneca) has been sparingly used by transplant centers, because of the low representation of patients with vulnerability in the initial trial but also its rare but serious thrombotic complications. Recently, emerging data reported that heterologous vaccination using an mRNA booster after ChAdOx1-nCov primed vaccination induced a good—and in some cases an even better—humoral response than exclusive mRNA vaccination. There are currently no data that assess the benefit of heterologous vaccination in solid organ transplant recipients, or whether this can improve the humoral response. A total of 373 KTRs from our institution had a serologic assessment 1 month after the third vaccine injection (screening and binding antibody unit [BAU]/ml quantification of anti-spike IgG by ECLIA Roche, Architect Abbott, or Diasorin). Among them, 28 had a heterologous vaccination schedule (ChAdOx1-nCov priming, 1 or 2 injections, followed by 1 or 2 mRNA injections), and 345 received 3 mRNA injections. On the basis of established risk factors of nonhumoral response after mRNA vaccination, we identified a matched 2:1 control cohort having received 3 mRNA vaccines (mRNA exclusive) based on age (±5 years), lymphopenia (<1500/mm3), and use of antiproliferative drugs and steroids. Conditional logistic regression was used to compare heterologous and mRNA exclusive cohorts. The average age of both cohorts was 59 years, 71% received antiproliferative drugs, 39% received steroids, and the mean lymphocyte count was 1700/mm3. There was a trend of lower allograft function (assessed by the Modification of Diet in Renal Disease) in the heterologous cohort (44.6 vs. 51.5 ml/min; P = 0.06; Table 1 ). No difference in serious adverse events was observed among patients from the 2 groups. Median times of serologic screening in the heterologous group and the mRNA exclusive group were 33 and 34 days, respectively. Seroconversion (i.e., anti-spike IgG superior to laboratory threshold) was observed in 75% of patients with heterologous vaccination and 67.8% of patients with mRNA exclusive vaccination (odds ratio, 1.72; 95% confidence interval, 0.59–4.99; P = 0.32). Mean anti-spike IgG titers were 159 BAU/ml in the heterologous group and 125 BAU/ml in the mRNA exclusive group (P = 0.36; Figure 1 ). Recent data by Behrens et al. demonstrated a higher immune response induced by a heterologous schedule, including neutralization of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) delta variant. To our knowledge, we report the first study assessing humoral responses to a heterologous vaccination schedule in immunocompromised KTRs. Seroconversion rates and antibody titers induced by heterologous vaccination were at least equal to mRNA-exclusive vaccination in immunocompromised transplant recipients; although they trended higher in the heterologous group, this did not reach statistical significance because of the small cohort size. Moreover, the lower allograft function in the heterologous cohort may have weakened the observed humoral response. Overall, heterologous vaccination appears to induce a robust humoral response in KTRs and may be considered to improve vaccine response in this immunocompromised population.
Table 1

Characteristics of the kidney transplant cohorts depending on their vaccination schedule (heterologous schedule: ChAdOx1-S primed vaccination, then mRNA booster; mRNA exclusive: mRNA vaccine alone)

CharacteristicsHeterologous (n = 28)
mRNA exclusive (n = 56)
P value
N/ANo.%N/ANo.%
Positive serology after 3 doses02875.005667.80.32
Male recipient02071.403969.60.99
Transplant rank ≥2a02175.004682.10.56
Calcineurin inhibitor treatment02485.704478.50.56
mTOR inhibitor treatment0612.4058.90.16
Antimetabolite treatment02071.404071.41
Steroid treatment01139.302239.31

BAU, binding antibody unit; MDRD, Modification of Diet in Renal Disease; N/A, nonavailable data.

Transplant rank ≥2: patient having received a second or more transplant kidney.

Figure 1

(a) Seroconversion rate after 3 injections (i.e., anti-spike IgG superior to laboratory threshold) in patients having received a heterologous schedule (ChAdOx1-S primed vaccination and mRNA booster) and a standard schedule (mRNA vaccine alone). (b) Anti-spike IgGs, expressed in binding antibody unit (BAU)/ml, and their respective mean titer 1 month after the last vaccine injection in both groups.

Characteristics of the kidney transplant cohorts depending on their vaccination schedule (heterologous schedule: ChAdOx1-S primed vaccination, then mRNA booster; mRNA exclusive: mRNA vaccine alone) BAU, binding antibody unit; MDRD, Modification of Diet in Renal Disease; N/A, nonavailable data. Transplant rank ≥2: patient having received a second or more transplant kidney. (a) Seroconversion rate after 3 injections (i.e., anti-spike IgG superior to laboratory threshold) in patients having received a heterologous schedule (ChAdOx1-S primed vaccination and mRNA booster) and a standard schedule (mRNA vaccine alone). (b) Anti-spike IgGs, expressed in binding antibody unit (BAU)/ml, and their respective mean titer 1 month after the last vaccine injection in both groups. Otherwise, there are important concerns for KTRs treated with belatacept, the only costimulation blocker that has received approval for clinical use. Although poor humoral responses following 2 mRNA vaccine injections in KTRs treated with belatacept has been well demonstrated,9, 10, 11 whether a third dose could overcome these issues, as in patients receiving conventional therapy, remains controversial. Indeed, published rates of seroconversion vary dramatically from 6.4% (4 of 62) in the study of Chavarot et al. to 41% (5 of 12) in the report by Kamar et al. These discrepancies could result from differences in confounding variables, especially the association with antiproliferative drugs, usually combined with belatacept and recognized as a risk factor for poor response to mRNA vaccines. To avoid this pitfall, we analyzed in our institutional cohort the seroconversion rate in KTRs treated with belatacept having received 3 mRNA doses and matched them with 2 KTRs not receiving belatacept, on age (±5 years), total lymphocyte count (<1500/mm3), and use of antiproliferative and steroid drugs. Characteristics of the 27 belatacept-treated patients and 56 control patients are presented in Table 2 ; none of them had a history of COVID-19 infection. Seroconversion after the second injection was observed in 13.3% of belatacept-treated patients and 25.8% of control patients (P = 0.45). After the third mRNA injection, seroconversion was observed in 22.2% of patients exposed to belatacept and 59.7% of the matched control patients (Figure 2 a), with mean anti-spike IgG titers at 24 and 106 BAU/ml, respectively (P < 0.001; Figure 2b). The corresponding odds ratio estimated from a conditional logistic regression was 4.97 (95% confidence interval, 1.40–17.67; P = 0.01). Hence, our results confirm that belatacept severely inhibits the humoral response to a third dose of mRNA SARS-CoV-2 vaccine in an independent way.
Table 2

Characteristics of the cohort of patients undergoing belatacept therapy and matched controls

CharacteristicsBelatacept (n = 27)
Matched controls (n = 54)
P value
N/ANo.%N/ANo.%
Positive serology after 2 doses12213.324825.80.45
Positive serology after 3 doses0622.203259.70.01
Male recipient01659.203870.30.33
Transplant rank ≥2a0414.801538.40.26
Calcineurin inhibitor treatment0725.903768.5<0.001
mTOR inhibitor treatment00001222.20.006
Antimetabolite treatment01866.703666.71
Steroid treatment01970.303870.31

BAU, binding antibody unit; MDRD, Modification of Diet in Renal Disease; N/A, nonavailable data.

Transplant rank ≥2: patient having received a second or more transplant kidney.

Figure 2

Serologic assessment was performed by ECLIA Roche, Architect Abbott, or Diasorin technologies, and anti-spike IgG titers were expressed in binding antibody unit (BAU)/ml. Positivity was set as anti-spike IgG superior to laboratory threshold. Median times of serologic screening in the belatacept group and the matched control group were 42 and 36 days, respectively, after the third injection. (a) Seroconversion rate after 2 and 3 mRNA injections (i.e., anti-spike IgG level superior to laboratory threshold) in patients receiving belatacept and matched controls. (b) Anti-spike IgGs, expressed in BAU/ml, and their respective mean titer 1 month after the last vaccine injection in belatacept recipients and matched controls. Anti-spike IgGs, expressed in BAU/ml, and their respective mean titer 1 month after the last vaccine injection in belatacept recipients and patients who underwent belatacept withdrawal. ∗P < 0.05, ∗∗P < 0.01, and ∗∗∗P < 0.001. NS, nonsignificant difference.

Characteristics of the cohort of patients undergoing belatacept therapy and matched controls BAU, binding antibody unit; MDRD, Modification of Diet in Renal Disease; N/A, nonavailable data. Transplant rank ≥2: patient having received a second or more transplant kidney. Serologic assessment was performed by ECLIA Roche, Architect Abbott, or Diasorin technologies, and anti-spike IgG titers were expressed in binding antibody unit (BAU)/ml. Positivity was set as anti-spike IgG superior to laboratory threshold. Median times of serologic screening in the belatacept group and the matched control group were 42 and 36 days, respectively, after the third injection. (a) Seroconversion rate after 2 and 3 mRNA injections (i.e., anti-spike IgG level superior to laboratory threshold) in patients receiving belatacept and matched controls. (b) Anti-spike IgGs, expressed in BAU/ml, and their respective mean titer 1 month after the last vaccine injection in belatacept recipients and matched controls. Anti-spike IgGs, expressed in BAU/ml, and their respective mean titer 1 month after the last vaccine injection in belatacept recipients and patients who underwent belatacept withdrawal. ∗P < 0.05, ∗∗P < 0.01, and ∗∗∗P < 0.001. NS, nonsignificant difference. Given the crucial importance for KTRs to be vaccinated, it has been suggested that belatacept could be replaced with conventional maintenance therapy to improve vaccine effectiveness. However, whether this strategy is worthwhile deserves further investigation for several reasons: (i) recent data have shown that vaccine effectiveness is deeply impacted by preexisting cross-reactive CD4+ T cells specific for endemic human cold coronavirus , and (ii) costimulation blockade promotes specific T-cell hyporesponsiveness and anergy. Consequently, vaccine responses could be impacted a long time after discontinuation of a costimulation blockade. To address these issues, we assessed the response to the mRNA SARS-CoV-2 vaccine in the KTRs of our whole cohort who had been previously exposed to belatacept for at least 1 year. In the 9 patients identified, belatacept had been intentionally withdrawn and replaced with conventional immunosuppressive drugs, mainly a mycophenolate derivative combined with a calcineurin inhibitor (see Supplementary Table S1 for details), and none had presented a rejection episode in the follow-up. The mean time between belatacept discontinuation and vaccination was 32 months. One month after the third vaccine dose, 8 of 9 patients (87.5%) had a positive serology with a mean anti-spike IgG titer at 105 BAU/ml (Figure 2b). These results are extremely encouraging with respect to withdrawing a costimulation blockade to improve vaccine effectiveness. This obviously needs to be confirmed in KTRs having stopped belatacept more recently. In conclusion, several strategies can be considered to improve humoral responses following COVID-19 vaccination in KTRs. Heterologous vaccination, using an mRNA booster after ChAdOx1-nCov priming, induced at least as good a humoral response, if not a better response, to exclusive mRNA vaccination. Otherwise, immunosuppression modulation, notably temporary belatacept withdrawal, seems promising to improve the poor humoral response in these patients.
  16 in total

1.  A phase III study of belatacept versus cyclosporine in kidney transplants from extended criteria donors (BENEFIT-EXT study).

Authors:  A Durrbach; J M Pestana; T Pearson; F Vincenti; V D Garcia; J Campistol; M del Carmen Rial; S Florman; A Block; G Di Russo; J Xing; P Garg; J Grinyó
Journal:  Am J Transplant       Date:  2010-03       Impact factor: 8.086

2.  Weak antibody response to three doses of mRNA vaccine in kidney transplant recipients treated with belatacept.

Authors:  Nathalie Chavarot; Antoine Morel; Marianne Leruez-Ville; Estelle Vilain; Gillian Divard; Carole Burger; Alexandra Serris; Rebecca Sberro-Soussan; Frank Martinez; Lucile Amrouche; Lynda Bererhi; Fanny Lanternier; Christophe Legendre; Julien Zuber; Dany Anglicheau; Anne Scemla
Journal:  Am J Transplant       Date:  2021-09-12       Impact factor: 8.086

3.  Cross-reactive CD4+ T cells enhance SARS-CoV-2 immune responses upon infection and vaccination.

Authors:  Julian Braun; Larissa Henze; Beate Kruse; Manuela Dingeldey; Ulf Reimer; Florian Kern; Tatjana Schwarz; Lucie Loyal; Maike Mangold; Clara Unger; Friederike Dörfler; Shirin Kadler; Jennifer Rosowski; Kübrah Gürcan; Zehra Uyar-Aydin; Marco Frentsch; Florian Kurth; Karsten Schnatbaum; Maren Eckey; Stefan Hippenstiel; Andreas Hocke; Marcel A Müller; Birgit Sawitzki; Stefan Miltenyi; Friedemann Paul; Marcus A Mall; Holger Wenschuh; Sebastian Voigt; Christian Drosten; Roland Lauster; Nils Lachman; Leif-Erik Sander; Victor M Corman; Jobst Röhmel; Lil Meyer-Arndt; Andreas Thiel; Claudia Giesecke-Thiel
Journal:  Science       Date:  2021-10-08       Impact factor: 47.728

4.  Immune Response Post-SARS-CoV-2 mRNA Vaccination in Kidney Transplant Recipients Receiving Belatacept.

Authors:  Johan Noble; Antoine Langello; William Bouchut; Julien Lupo; Dorothee Lombardo; Lionel Rostaing
Journal:  Transplantation       Date:  2021-11-01       Impact factor: 5.385

5.  Low-dose mRNA-1273 COVID-19 vaccine generates durable memory enhanced by cross-reactive T cells.

Authors:  Jennifer M Dan; Zeli Zhang; Jose Mateus; Carolyn Rydyznski Moderbacher; Marshall Lammers; Benjamin Goodwin; Alessandro Sette; Shane Crotty; Daniela Weiskopf
Journal:  Science       Date:  2021-10-22       Impact factor: 47.728

6.  A third injection of the BNT162b2 mRNA COVID-19 vaccine in kidney transplant recipients improves the humoral immune response.

Authors:  Christophe Masset; Clarisse Kerleau; Claire Garandeau; Simon Ville; Diego Cantarovich; Maryvonne Hourmant; Delphine Kervella; Aurélie Houzet; Cécile Guillot-Gueguen; Irène Guihard; Magali Giral; Jacques Dantal; Gilles Blancho
Journal:  Kidney Int       Date:  2021-08-30       Impact factor: 10.612

7.  Immunogenicity and reactogenicity of BNT162b2 booster in ChAdOx1-S-primed participants (CombiVacS): a multicentre, open-label, randomised, controlled, phase 2 trial.

Authors:  Alberto M Borobia; Antonio J Carcas; Mayte Pérez-Olmeda; Luis Castaño; María Jesús Bertran; Javier García-Pérez; Magdalena Campins; Antonio Portolés; María González-Pérez; María Teresa García Morales; Eunate Arana-Arri; Marta Aldea; Francisco Díez-Fuertes; Inmaculada Fuentes; Ana Ascaso; David Lora; Natale Imaz-Ayo; Lourdes E Barón-Mira; Antonia Agustí; Carla Pérez-Ingidua; Agustín Gómez de la Cámara; José Ramón Arribas; Jordi Ochando; José Alcamí; Cristóbal Belda-Iniesta; Jesús Frías
Journal:  Lancet       Date:  2021-06-25       Impact factor: 79.321

8.  Three Doses of an mRNA Covid-19 Vaccine in Solid-Organ Transplant Recipients.

Authors:  Nassim Kamar; Florence Abravanel; Olivier Marion; Chloé Couat; Jacques Izopet; Arnaud Del Bello
Journal:  N Engl J Med       Date:  2021-06-23       Impact factor: 91.245

9.  An initial report from the French SOT COVID Registry suggests high mortality due to COVID-19 in recipients of kidney transplants.

Authors:  Sophie Caillard; Dany Anglicheau; Marie Matignon; Antoine Durrbach; Clarisse Greze; Luc Frimat; Olivier Thaunat; Tristan Legris; Valerie Moal; Pierre Francois Westeel; Nassim Kamar; Philippe Gatault; Renaud Snanoudj; Antoine Sicard; Dominique Bertrand; Charlotte Colosio; Lionel Couzi; Jonathan M Chemouny; Christophe Masset; Gilles Blancho; Jamal Bamoulid; Agnes Duveau; Nicolas Bouvier; Nathalie Chavarot; Philippe Grimbert; Bruno Moulin; Yannick Le Meur; Marc Hazzan
Journal:  Kidney Int       Date:  2020-08-24       Impact factor: 10.612
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1.  Immunogenicity and Risk Factors Associated With Poor Humoral Immune Response of SARS-CoV-2 Vaccines in Recipients of Solid Organ Transplant: A Systematic Review and Meta-Analysis.

Authors:  Kasama Manothummetha; Nipat Chuleerarux; Anawin Sanguankeo; Olivia S Kates; Nattiya Hirankarn; Achitpol Thongkam; M Veronica Dioverti-Prono; Pattama Torvorapanit; Nattapong Langsiri; Navaporn Worasilchai; Chatphatai Moonla; Rongpong Plongla; William M Garneau; Ariya Chindamporn; Pitchaphon Nissaisorakarn; Tany Thaniyavarn; Saman Nematollahi; Nitipong Permpalung
Journal:  JAMA Netw Open       Date:  2022-04-01

2.  Neutralizing antibody response against the B.1.617.2 (delta) and the B.1.1.529 (omicron) variants after a third mRNA SARS-CoV-2 vaccine dose in kidney transplant recipients.

Authors:  Louise Benning; Christian Morath; Marie Bartenschlager; Heeyoung Kim; Marvin Reineke; Jörg Beimler; Mirabel Buylaert; Christian Nusshag; Florian Kälble; Paula Reichel; Maximilian Töllner; Matthias Schaier; Katrin Klein; Vladimir Benes; Tobias Rausch; Susanne Rieger; Maximilian Stich; Burkhard Tönshoff; Niklas Weidner; Paul Schnitzler; Martin Zeier; Caner Süsal; Thuong Hien Tran; Ralf Bartenschlager; Claudius Speer
Journal:  Am J Transplant       Date:  2022-04-18       Impact factor: 9.369

Review 3.  Impact of the COVID-19 pandemic on the kidney community: lessons learned and future directions.

Authors:  Duvuru Geetha; Andreas Kronbichler; Megan Rutter; Divya Bajpai; Steven Menez; Annemarie Weissenbacher; Shuchi Anand; Eugene Lin; Nicholas Carlson; Stephen Sozio; Kevin Fowler; Ray Bignall; Kathryn Ducharlet; Elliot K Tannor; Eranga Wijewickrama; Muhammad I A Hafidz; Vladimir Tesar; Robert Hoover; Deidra Crews; Charles Varnell; Lara Danziger-Isakov; Vivekanand Jha; Sumit Mohan; Chirag Parikh; Valerie Luyckx
Journal:  Nat Rev Nephrol       Date:  2022-08-24       Impact factor: 42.439

4.  Humoral response to SARS-CoV-2 mRNA vaccination in previous non-responder kidney transplant recipients after short-term withdrawal of mycophenolic acid.

Authors:  Louise Benning; Christian Morath; Tessa Kühn; Marie Bartenschlager; Heeyoung Kim; Jörg Beimler; Mirabel Buylaert; Christian Nusshag; Florian Kälble; Marvin Reineke; Maximilian Töllner; Matthias Schaier; Katrin Klein; Antje Blank; Paul Schnitzler; Martin Zeier; Caner Süsal; Ralf Bartenschlager; Thuong Hien Tran; Claudius Speer
Journal:  Front Med (Lausanne)       Date:  2022-08-18

5.  Immunogenicity After a Heterologous BNT262b2 Versus Homologous Booster in Kidney Transplant Recipients Receiving 2 Doses of CoronaVac Vaccine: A Prospective Cohort Study.

Authors:  José Medina-Pestana; Laila Almeida Viana; Monica Rika Nakamura; Elizabeth França Lucena; Celso Francisco Hernandes Granato; Yasmim Cardoso Dreige; Laysla Verhalen Pouzo Amorim; Charles Yea Zen Chow; Renato Demarchi Foresto; Lucio Roberto Requião-Moura; Helio Tedesco-Silva; Marina Pontello Cristelli
Journal:  Transplantation       Date:  2022-08-05       Impact factor: 5.385

6.  Humoral and cellular response of COVID-19 vaccine among solid organ transplant recipients: A systematic review and meta-analysis.

Authors:  Hari Shankar Meshram; Vivek Kute; Hemant Rane; Ruchir Dave; Subho Banerjee; Vineet Mishra; Sanshriti Chauhan
Journal:  Transpl Infect Dis       Date:  2022-08-04

7.  SARS-CoV-2 vaccine booster in solid organ transplant recipients previously immunised with inactivated versus mRNA vaccines: A prospective cohort study.

Authors:  Martín Dib; Nicole Le Corre; Catalina Ortiz; Daniel García; Marcela Ferrés; Constanza Martinez-Valdebenito; Cinthya Ruiz-Tagle; María José Ojeda; Manuel A Espinoza; Aquiles Jara; Juan Pablo Arab; Ricardo Rabagliati; Cecilia Vizcaya; María Elena Ceballos; Mauricio Sarmiento; Sebastián Mondaca; Macarena Viñuela; Antonia Pastore; Vania Szwarcfiter; Elizabeth Galdames; Aldo Barrera; Pablo Castro; Nicolás Ms Gálvez; Jorge A Soto; Susan M Bueno; Alexis M Kalergis; Bruno Nervi; M Elvira Balcells
Journal:  Lancet Reg Health Am       Date:  2022-09-23
  7 in total

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