CD14+CD34low Cells With Stem Cell Phenotypic and Functional Features Are the Major Source of Circulating Endothelial Progenitors

doi:10.1161/01.RES.0000177670.72216.9b

Circulation Research. 2005
Published online before print July 14, 2005, doi: 10.1161/01.RES.0000177670.72216.9b

A more recent version of this article appeared on August 19, 2005

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Submitted on April 28, 2005
Revised on July 5, 2005
Accepted on July 6, 2005

CD14+CD34^low Cells With Stem Cell Phenotypic and Functional Features Are the Major Source of Circulating Endothelial Progenitors

Paola Romagnani ; Francesco Annunziato ; Francesco Liotta ; Elena Lazzeri ; Benedetta Mazzinghi ; Francesca Frosali ; Lorenzo Cosmi ; Laura Maggi ; Laura Lasagni ; Alexander Scheffold ; Manuela Kruger ; Stefanie Dimmeler ; Fabio Marra ; Gianfranco Gensini ; Enrico Maggi ; and Sergio Romagnani ^*

From the Center for Research (P.R., F.A., F.L., E.L., B.M., F.F., L.C., L.M., L.L., S.D., F.M., G.G., E.M., S.R.), Transfer and High Education DENOVOthe, University of Florence, Italy; the Deutches Rheuma Forschungszentrum (A.S., M.K.), Berlin, Germany; and the Department of Molecular Cardiology (S.D.), University of Frankfurt, Germany.

^* To whom correspondence should be addressed. E-mail: s.romagnani{at}dmi.unifi.it.

Endothelial progenitor cells (EPCs) seem to be a promising toolfor cell therapy of acute myocardial infarction, but their natureis still unclear. We show here that EPCs obtainable from peripheralblood (PB) derive from the adhesion-related selection in cultureof a subset of CD14+ cells, which, when assessed by the highly-sensitiveantibody-conjugated magnetofluorescent liposomes (ACMFL) technique,were found to express CD34. These CD14+CD34^low cells representeda variable proportion at individual level of CD14+ cells, rangingfrom 0.6% to 8.5% of all peripheral-blood leukocytes, and constitutedthe dominant population among circulating KDR+ cells. By usingthe ACMFL technique, virtually all CD14+ cells present in thebone marrow were found to be CD14+CD34^low double-positive cells.EPCs, as well as purified circulating CD14+CD34^low cells, exhibitedhigh expression of embryonic stem cell (SC) markers Nanog andOct-4, which were downregulated in a STAT3-independent mannerwhen they differentiated into endothelial cells (ECs). Moreover,circulating CD14+CD34^low cells, but not CD14+CD34- cells, proliferatedin response to SC growth factors, and exhibited clonogenicityand multipotency, as shown by their ability to differentiatenot only into ECs, but also into osteoblasts, adipocytes, orneural cells. The results of this study may reconcile apparentlycontradictory data of the literature, showing the generationof PB-derived EPCs from either CD34+ or CD14+ cells. We suggestthat the use of this previously unrecognized population of circulatingCD14+CD34^low cells, which exhibit both phenotypic and functionalfeatures of SCs, may be useful in improving cell-based therapiesof vascular and tissue damage.

Key words: endothelial progenitor cells • monocytes • CD14+CD34^low cells • Nanog

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