Integrin engagement regulates monocyte differentiation through the forkhead transcription factor Foxp1
Can Shi, … , Mukesh K. Jain, Daniel I. Simon
Can Shi, … , Mukesh K. Jain, Daniel I. Simon
Published August 1, 2004
Citation Information: J Clin Invest. 2004;114(3):408-418. https://doi.org/10.1172/JCI21100.
View: Text | PDF
Article Vascular biology

Integrin engagement regulates monocyte differentiation through the forkhead transcription factor Foxp1

Abstract

The precise signals responsible for differentiation of blood-borne monocytes into tissue macrophages are incompletely defined. “Outside-in” signaling by integrins has been implicated in modulation of gene expression that affects cellular differentiation. Herein, using differential display PCR, we have cloned an 85-kDa forkhead transcription factor (termed Mac-1–regulated forkhead [MFH] and found subsequently to be identical to Foxp1) that is downregulated in β2-integrin Mac-1–clustered compared with Mac-1–nonclustered monocytic THP-1 cells. MFH/Foxp1 is expressed in untreated HL60 cells, and its expression was markedly reduced during phorbol ester–induced monocyte differentiation, but not retinoic acid–induced granulocyte differentiation. Overexpression of MFH/Foxp1 markedly attenuated phorbol ester–induced expression of c-fms, which encodes the M-CSF receptor and is obligatory for macrophage differentiation. This was accompanied by decreased CD11b expression, cell adhesiveness, and phagocytosis. Using electromobility shift and reporter assays, we have established that MFH/Foxp1 binds to previously uncharacterized sites within the c-fms promoter and functions as a transcriptional repressor. Deficiency of Mac-1 is associated with altered regulation of MFH/Foxp1 and monocyte maturation in vivo. Taken together, these observations suggest that Mac-1 engagement orchestrates monocyte-differentiation signals by regulating the expression of the forkhead transcription repressor MFH/Foxp1. This represents a new pathway for integrin-dependent modulation of gene expression and control of cellular differentiation.

Authors

Can Shi, Xiaobin Zhang, Zhiping Chen, Karina Sulaiman, Mark W. Feinberg, Christie M. Ballantyne, Mukesh K. Jain, Daniel I. Simon

×

Figure 5

Options: View larger image (or click on image) Download as PowerPoint
MFH/Foxp1and c-fms expression. (A) Overexpression of MFH/Foxp1attenuates...
MFH/Foxp1and c-fms expression. (A) Overexpression of MFH/Foxp1attenuates expression of c-fms. HL60 cells transduced with control virus (MSCV.GFP) or MSCV.MFH/Foxp1.GFP were stimulated with PMA (10 nM), and the expression of c-fms and PU.1 over time was assessed by Northern analysis. (B) Clustering of Mac-1 enhances c-fms expression. Northern blots containing 1 μg/lane of mRNA isolated from Mac-1–clustered (+) and –nonclustered (–) THP-1 cells were probed with 32P-labeled c-fms and MFH/Foxp1 cDNA probes. (C) Regulation of MFH/Foxp1 and c-fms protein by Mac-1. MFH/Foxp1 and c-fms proteins were assessed after Mac-1 clustering. THP-1 cells were lysed 24 hours after clustering with SDS-PAGE reduced-sample buffer and then immunoblotted sequentially with anti–MFH/Foxp1, anti–c-fms (130 kDA and 150 kDa), and anti-tubulin antibodies. Signaling inhibitors included 250 nmol/l wortmannin, 5 μmol/l bortezomib, 100 nmol/l SB203580, and 1 μmol/l herbimycin A. (D) MFH/Foxp1 in human monocytes. Semiquantitative PCR of MFH/Foxp1 and c-fms from RNA isolated from Mac-1–clustered (+) and –nonclustered (–) peripheral blood human monocytes.