Transplanted endothelial cells repopulate the liver endothelium and correct the phenotype of hemophilia A mice
Antonia Follenzi, … , Sanj Raut, Sanjeev Gupta
Antonia Follenzi, … , Sanj Raut, Sanjeev Gupta
Published February 14, 2008
Citation Information: J Clin Invest. 2008;118(3):935-945. https://doi.org/10.1172/JCI32748.
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Research Article Hematology

Transplanted endothelial cells repopulate the liver endothelium and correct the phenotype of hemophilia A mice

Abstract

Transplantation of healthy cells to repair organ damage or replace deficient functions constitutes a major goal of cell therapy. However, the mechanisms by which transplanted cells engraft, proliferate, and function remain unknown. To investigate whether host liver sinusoidal endothelium could be replaced with transplanted liver sinusoidal endothelial cells, we developed an animal model of tissue replacement that utilized a genetic system to identify transplanted cells and induced host-cell perturbations to confer a proliferative advantage to transplanted cells. Under these experimental conditions, transplanted cells engrafted efficiently and proliferated to replace substantial portions of the liver endothelium. Tissue studies demonstrated that transplanted cells became integral to the liver structure and reacquired characteristic endothelial morphology. Characterization of transplanted endothelial cells by membrane markers and studies of cellular function, including synthesis and release of coagulation factor VIII, demonstrated that transplanted cells were functionally intact. Further analysis showed that repopulation of the livers of mice that model hemophilia A with healthy endothelial cells restored plasma factor VIII activity and corrected their bleeding phenotype. Our studies therefore suggest that transplantation of healthy endothelial cells should be considered for cell therapy of relevant disorders and that endothelial reconstitution with transplanted cells may offer an excellent paradigm for defining organ-specific pathophysiological mechanisms.

Authors

Antonia Follenzi, Daniel Benten, Phyllis Novikoff, Louisa Faulkner, Sanj Raut, Sanjeev Gupta

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Figure 8

Expression of coagulation factors in ECs.

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Expression of coagulation factors in ECs. (A) RT-PCR of total liver RNA ...
(A) RT-PCR of total liver RNA for FVIII, FIX, and vWF. Lane 1, liver from healthy FVB/N mouse; lane 2, liver from hemophilia A mouse; lane 3, LSECs from healthy FVB/N mouse; lane 4, hepatocytes from healthy FVB/N mouse; and lane 5, PCR mix alone. (B and C) Immunostaining of NOD/SCID hemophilia A mouse liver showing coexpression of CD31 endothelial marker (red) and vWF (green) in liver sinusoids; cells expressing both appear yellow. C shows enlargement of the boxed area in B. Nuclei were stained with DAPI (blue). In B, confocal microscopy demonstrates vWF expression in LSECs costained for CD31. Scale bar: 24 μm (B). Original magnification, ×630 (C). (D) RT-PCR of total liver RNA showing vWF mRNA expression. Lane 1, FVB/N donor LSECs; lane 2, hemophilia A mouse liver; lane 3, FVB/N mouse liver; lanes 4–7, liver of hemophilic mice after LSEC transplantation. (E) RT-PCR of total RNA for FVIII expression. Lanes 1–4, FVB/N mouse liver, bone marrow, spleen, and lung, respectively; lane 5, hemophilia A mouse liver; lane 6, FVB/N LSECs; lane 7, FVB/N ECs from spleen; and lane 8, mix alone. Expression of β-actin verified RNA integrity in A, D, and E.