E-selectin ligand–1 regulates growth plate homeostasis in mice by inhibiting the intracellular processing and secretion of mature TGF-β
Tao Yang, … , Arthur L. Beaudet, Brendan Lee
Tao Yang, … , Arthur L. Beaudet, Brendan Lee
Published June 7, 2010
Citation Information: J Clin Invest. 2010;120(7):2474-2485. https://doi.org/10.1172/JCI42150.
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Research Article Bone biology

E-selectin ligand–1 regulates growth plate homeostasis in mice by inhibiting the intracellular processing and secretion of mature TGF-β

Abstract

The majority of human skeletal dysplasias are caused by dysregulation of growth plate homeostasis. As TGF-β signaling is a critical determinant of growth plate homeostasis, skeletal dysplasias are often associated with dysregulation of this pathway. The context-dependent action of TFG-β signaling is tightly controlled by numerous mechanisms at the extracellular level and downstream of ligand-receptor interactions. However, TGF-β is synthesized as an inactive precursor that is cleaved to become mature in the Golgi apparatus, and the regulation of this posttranslational intracellular processing and trafficking is much less defined. Here, we report that a cysteine-rich protein, E-selectin ligand–1 (ESL-1), acts as a negative regulator of TGF-β production by binding TGF-β precursors in the Golgi apparatus in a cell-autonomous fashion, inhibiting their maturation. Furthermore, ESL-1 inhibited the processing of proTGF-β by a furin-like protease, leading to reduced secretion of mature TGF-β by primary mouse chondrocytes and HEK293 cells. In vivo loss of Esl1 in mice led to increased TGF-β/SMAD signaling in the growth plate that was associated with reduced chondrocyte proliferation and delayed terminal differentiation. Gain-of-function and rescue studies of the Xenopus ESL-1 ortholog in the context of early embryogenesis showed that this regulation of TGF-β/Nodal signaling was evolutionarily conserved. This study identifies what we believe to be a novel intracellular mechanism for regulating TGF-β during skeletal development and homeostasis.

Authors

Tao Yang, Roberto Mendoza-Londono, Huifang Lu, Jianning Tao, Kaiyi Li, Bettina Keller, Ming Ming Jiang, Rina Shah, Yuqing Chen, Terry K. Bertin, Feyza Engin, Branka Dabovic, Daniel B. Rifkin, John Hicks, Milan Jamrich, Arthur L. Beaudet, Brendan Lee

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Figure 7

ESL-1 inhibits TGF-β proteolytic processing.

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ESL-1 inhibits TGF-β proteolytic processing. (A) ESL-1 inhibits the intr...
(A) ESL-1 inhibits the intracellular cleavage and maturation of proTGF-β2 in vivo as shown by the relative abundance of mature TGF-β2 and proTGF-β2 on Western blot analysis of Esl1–/– versus WT cartilage lysates. α-Tubulin is used as a loading control. The ratio of mature TGF-β2 to total TGF-β2 is shown at right. (B) ESL-1 inhibits the intracellular cleavage of proTGF-β1 in vitro. The scheme of transfections and chemical treatments of COS7 cells is shown at the top. Primary antibodies and molecular weights are denoted. Both proTGF-β1-V5 (50 kDa) and the mature TGF-β1-V5 (15 kDa) can be detected by V5 antibody. Note that the amount of 15-kDa TGF-β1 (*) was significantly reduced in the presence of ESL-1. Under nonreducing condition, the presence of ESL-1 remarkably increased proTGF-β1 dimer (100 kDa). LAP1 (37 kDa) was decreased in the presence of ESL-1. α-Tubulin, as an internal control, was similar in all samples. Expression of ESL-1 reduced the secretion of mature TGF-β1 ligand found in medium. Baf, bafilomycin; Chx, cycloheximide. (C) ESL-1 inhibits furin processing of proTGF-β1 by in vitro furin assay. Western blot analysis of the furin reaction samples with V5 antibody. Reaction time (Rxn time), plasmids for transfections, and identity of the bands are noted. Furin inhibitor II (hexa-d-arginine) was added in the last sample (180 min + FI) to confirm the specificity of the furin reaction. The ratios of cleaved to uncleaved TGF-β1 at all time points is shown. The proportion of mature TGF-β1 ligand is greatly increased after 30 minutes incubation in the absence of ESL-1.