Lung Transplant Recipients with Severe Primary Graft Dysfunction Developed Decreased Transplant Arteriosclerosis in Humanized Mice Models

A.-K. Knofel; T. Siemeni; N. Madrahimov; W. Sommer; M. Avsar; F. Ius; K. Jansson; L. Ahrens; J. Salman; C. Kühn; I. Tudorache; A. Haverich; C. Falk; G. Warnecke

doi:10.1055/s-0039-1678982

The Thoracic and Cardiovascular Surgeon, Table of Contents

Thorac Cardiovasc Surg 2019; 67(S 01): S1-S100
DOI: 10.1055/s-0039-1678982

Short Presentations

Monday, February 18, 2019

DGTHG: Auf den Punkt gebracht - Grundlagenforschung

Georg Thieme Verlag KG Stuttgart · New York

Lung Transplant Recipients with Severe Primary Graft Dysfunction Developed Decreased Transplant Arteriosclerosis in Humanized Mice Models

Authors

A.-K. Knofel

¹Medical School Hannover, HTTG, Hannover, Germany
T. Siemeni

¹Medical School Hannover, HTTG, Hannover, Germany
N. Madrahimov

¹Medical School Hannover, HTTG, Hannover, Germany
W. Sommer

¹Medical School Hannover, HTTG, Hannover, Germany
M. Avsar

¹Medical School Hannover, HTTG, Hannover, Germany
F. Ius

¹Medical School Hannover, HTTG, Hannover, Germany
K. Jansson

¹Medical School Hannover, HTTG, Hannover, Germany
L. Ahrens

¹Medical School Hannover, HTTG, Hannover, Germany
J. Salman

¹Medical School Hannover, HTTG, Hannover, Germany
C. Kühn

¹Medical School Hannover, HTTG, Hannover, Germany
I. Tudorache

¹Medical School Hannover, HTTG, Hannover, Germany
A. Haverich

¹Medical School Hannover, HTTG, Hannover, Germany
C. Falk

²Medical School Hannover, Institut für Transplantationsimmunologie, Hannover, Germany
G. Warnecke

¹Medical School Hannover, HTTG, Hannover, Germany

Abstract

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Introduction: Primary graft dysfunction (PGD) is the main cause of early mortality after lung transplantation (LTx). Multiple mechanisms have been described, but the link between PGD, T cell priming and immune answer has not been defined. In humanized mice, we studied leukocytes from human lung recipients undergoing PGD with different kinetics and their impact on rejection of artery grafts.

Methods: Segments of the pericardiophrenic arteries were procured from surplus donor lung tissue and implanted into the abdominal aorta of immunodeficient mice. Development of transplant arteriosclerosis after reconstitution with PBMC was determined at day 28. Experiments were retrospectively divided; six patients developed transient PGD grade ≥2 at T0. Five patients developed PGD grade ≥2 at T24 and/or T48.

Mice from groups A–C were reconstituted with PBMC from PGD+ T0 patients. Group A mice were reconstituted with PBMC from the respective allogeneic human recipient. Group B mice additionally received CD4⁺CD25^high Treg cells with their PBMC. In Group C, administered PBMC were depleted of CD4⁺CD25^high Treg cells. Mice from groups D-F were reconstituted with PBMC from PGD+ T24/T48 patients, with group D receiving unmodified PBMC, group E receiving Treg enriched PBMC and group F receiving PBMC depleted of Tregs.

Results: Luminal occlusion of aortic vessels was higher in group D mice compared to group A. The addition of CD4⁺CD25^high Treg cells in group B & E mice had a suppressive effect on luminal occlusion.

Conclusions: We conclude that leukocytes from lung transplantation recipients undergoing PGD 2 or 3 transfer enhanced alloreactivity to humanized mice already immediately perioperatively. Therein, PGD 2 or 3 at T24 and/or T48 hours after lung transplantation translates to more severe rejection in humanized mice than transient PGD 2 or 3 at T0 only. This inflammatory response is suppressed by CD4⁺CD25^high Treg cells. This could be a potential target for future interventions in lung transplantation.