Focal and Segmental Glomerulosclerosis Induced in Mice Lacking Decay-accelerating Factor in T Cells

Overview

Journal J Clin Invest

Specialty General Medicine

Date 2009 Apr 8

PMID 19349693

Citations 27

Authors

Lihua Bao

Mark Haas

Jeffrey Pippin

Ying Wang

Takashi Miwa

Anthony Chang

Andrew W Minto

Miglena Petkova

Guilin Qiao

Wen-Chao Song

Charles E Alpers

Jian Zhang

Stuart J Shankland

Richard J Quigg

Affiliations

Soon will be listed here.

Abstract

Heritable and acquired diseases of podocytes can result in focal and segmental glomerulosclerosis (FSGS). We modeled FSGS by passively transferring mouse podocyte-specific sheep Abs into BALB/c mice. BALB/c mice deficient in the key complement regulator, decay-accelerating factor (DAF), but not WT or CD59-deficient BALB/c mice developed histological and ultrastructural features of FSGS, marked albuminuria, periglomerular monocytic and T cell inflammation, and enhanced T cell reactivity to sheep IgG. All of these findings, which are characteristic of FSGS, were substantially reduced by depleting CD4+ T cells from Daf(-/-) mice. Furthermore, WT kidneys transplanted into Daf(-/-) recipients and kidneys of DAF-sufficient but T cell-deficient Balb/(cnu/nu) mice reconstituted with Daf(-/-) T cells developed FSGS. In contrast, DAF-deficient kidneys in WT hosts and Balb/(cnu/nu) mice reconstituted with DAF-sufficient T cells did not develop FSGS. Thus, we have described what we believe to be a novel mouse model of FSGS attributable to DAF-deficient T cell immune responses. These findings add to growing evidence that complement-derived signals shape T cell responses, since T cells that recognize sheep Abs bound to podocytes can lead to cellular injury and development of FSGS.

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