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First published online 27 April 2005
doi: 10.1242/dev.01846

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Perivascular cells expressing annexin A5 define a novel mesenchymal stem cell-like population with the capacity to differentiate into multiple mesenchymal lineages

¹ Department of Cell and Matrix Biology, MCRI, 3052 Parkville Victoria, Australia
² Department of Experimental Medicine I, University Erlangen-Nürnberg, 91054 Erlangen, Germany
³ Department of Ophthalmology, University Erlangen-Nürnberg, 91054 Erlangen, Germany
⁴ Max-Planck-Institute of Psychiatry, 80804 München, Germany
⁵ Department of Experimental Pathology, Lund University, 22363 Lund, Sweden
⁶ Department of Genetics, University Erlangen-Nürnberg, 91054 Erlangen, Germany

View larger version (109K): [in a new window]   Fig. 1. Expression of Anxa5 in early embryonic development is restricted to the primary capillary plexus, dorsal aorta and extra-embryonic tissues. Whole-mount embryos heterozygous for Anxa5-lacZ fusion gene were stained for ß-galactosidase activity at E7.0 (A), E7.5 (B), E8.5 (C,D) and E9.0 (F). Sections of E8.5 (E) and E9.0 (G-I) embryos were counterstained with Eosin after X-gal staining. Strong expression is detected in the ectoplacental cone (A,B, arrowheads). Expression of Anxa5-lacZ reporter in lining angioblasts of the visceral yolk sac mesoderm (D; E, arrows), dorsal aorta (B,C,H arrows) and in intersegmental vessels (I, arrows) is marked. Scale bar: 50 µm in E,H,I; 200 µm in A-D,F,G.

View larger version (67K): [in a new window]   Fig. 2. Anxa5-lacZ reporter is specifically expressed in the vasculature of E10.5 embryos. Sagittal sections (A-D,F-I) of heterozygous embryos were stained for ß-galactosidase activity (A,F) followed by immunodetection of SMA (B,G), PECAM (C,H) and nuclear staining by DAPI (D,I). In the overlays (E,J), X-gal deposits are indicated by white spots. Anxa5-lacZ+ cells are restricted to SMA+/PECAM+ dorsal aorta and PECAM+ capillaries (E). At higher magnification, only a subset of PECAM-associated cells was positive for lacZ, as shown by DAPI staining (J, arrows). (K-N) Anxa5-lacZ+ cells are located in regions positive for the pericyte-specific marker NG2-proteoglycan in embryonic brain at E13.5. Transverse sections of capillaries were stained for ß-galactosidase activity (K, arrows). Positive areas appear black because of the monochrome character of the camera system. In parallel, PECAM (L) and NG2-proteoglycan (M) were detected by immunostaining. After merging, colocalization of PECAM and NG2 appears orange (N). X-gal deposits are shown as white spots (N, arrows). Scale bar: 50 µm.

View larger version (135K): [in a new window]   Fig. 3. Anxa5-lacZ+ cells are found associated with, but are not identical to, the endothelium in capillaries of E10.5 embryos and adult vasculature. (A) Sagittal sections of heterozygous embryos at E10.5 were stained for lacZ activity and immunostained for PECAM. After merging, Anxa5-lacZ+ regions appear red (arrows). Anxa5-lacZ+ cells are located parallel to the lining endothelial cells. (B) Ultrastuctural localization of Anxa5-lacZ+ expression in heterozygous embryos at E10.5 by electron microscopy. An electrondense deposit of X-gal product is detected (arrow) exclusively in PVCs. (C,D) Sections from adult kidney tested for lacZ activity (C) and SMA expression (D) showed colocalization in the vascular walls of large blood vessels. The relative intensity of fluorescence was reduced by X-gal staining. (E) Expression of the Anxa5-lacZ reporter in brain of adult mice is found in the pial vasculature. (F) X-gal staining (arrow) is restricted to cytoplasmic vesicles in pericytes, characterized by the common basement membrane (arrowhead) with endothelial cells. Capillaries (C), endothelial cells (EC) and pericytes (P) are marked (B,F). Scale bars: 50 µm (A,C); 1 mm (E).

View larger version (42K): [in a new window]   Fig. 4. Detection and purification of lacZ+ cells by fluorescence-activated cell sorting. Single cell suspensions of heterozygous embryos at E12.5 were stained with the fluorescent lacZ substrate FDG and cell death was detected by adding propidium iodide (PI). In FACS analysis, only vital cells in gate R1 (FSC/SSC) were considered for data analysis (A). Cells from wild-type embryos were used as control and almost no events were detected in gate R2 (B). About 3% of the heterozygous cells analyzed, represent vital Anxa5-lacZ+ cells (C). Similar amounts of Anxa5-lacZ+ cells were detected in embryos at E8.5 (D) and E10.5 (E) as well as in adult brain meninges (F). The percentages of cells within the gate are depicted, genotypes (wild type, wt; heterozygous, +/–) are indicated.

View larger version (56K): [in a new window]   Fig. 5. Expression profiles of isolated Anxa5-lacZ+ cells. Cells were sorted from heterozygous embryos at E10.5 (A), dissected brains from E16.5 embryos (B), adult brain meninges (C) and RNA was isolated. RNA isolated from total embryos at E10.5 represented the positive control (D). RT-PCR was used to detect the mRNA of specific markers for stem cells (Flk1, Kit, Sca1, CD45, CD34, VE-cadherin), myogenic cells (Myod1) as well as myogenic satellite cells (Pax7) and pericytes (PDGFRß, NG2). Anxa5 was tested as a positive control and reactions without mRNA (E) were used as negative controls. GAPDH was used for standardization.

View larger version (90K): [in a new window]   Fig. 6. Anxa5-lacZ+ cells differentiate into early chondrogenic, osteogenic and adipocyte lineages in vitro. Aggregate cultures of PVCs were cultivated in chondrogenic medium (A-F,M-O). By day 14 (B,C,E,F,M-O) or 21 (A,D), cryosections were performed and strong staining was seen for collagen VI (Col6; C) and collagen IX (Col9; B), whereas collagen II was barely detectable (Col2; A). Aggregate sections were stained for neutral fat deposits using oil Red O staining (red droplets) and Hematoxylin (M) as well as for PPAR2 (N). Additionally, isolated PVCs were cultivated in osteogenic medium for 21 days (G-L). Ca2+ deposits in cryosections of these aggregates were detected by Alizarin Red (H) as well as van Kossa staining (I). Collagen I was detected by immunostaining (G). Aggregates of PVCs were cultivated in proliferating medium as negative control for the staining of Ca2+ deposits (K,L). Secondary antibodies were used as negative control for the immunostaining (D-F,J,O). Scale bars: 50 µm.

View larger version (92K): [in a new window]   Fig. 7. Purified PVCs participate in muscle regeneration in vivo. Isolated Anxa5-lacZ+ PVCs of adult brain meninges were injected into regenerating areas of crushed tibialis anterior (TA) muscle of immunodeficient NOD/SCID mice. By day 13, consecutive muscle sections were analyzed for ß-galactosidase activity by X-gal staining and expression of desmin (B,E), PECAM (C) as well as CD34 (F) by immunohistochemistry. Injected Anxa5-lacZ+ cells were detected at day 13 in the zone of regeneration (arrows, A,D) in columnar structures associated with intact desmin-positive muscle fibers (B,E). No staining was seen in intact fibers. lacZ-expressing cells were found in areas positive for CD34+ (D,F) but not in areas positive for PECAM (A,C). Scale bars: 50 µm.

View larger version (23K): [in a new window]   Fig. 8. Purified Anxa5-lacZ+ PVCs do not have hematopoietic capacity in vivo. Purified Anxa5-lacZ+ PVCs from adult brain meninges (Ly5.2+, 1 x105 cells) were mixed with bone marrow cells (Ly5.1+, 9 x105) and injected intravenously into recipient mice (Ly5.1+) after lethal irradiation. After 28 days, peripheral blood of recipients was analyzed by flow cytometry for the presence of Ly5-markers. (A) No Ly5.2+ cells were detectable in blood of the negative control mice, represented by non irradiated wild-type Ly5.1+ mice without transplantation. (B) In the positive control, 18% of the blood cells derived from the injected Ly5.2+ BMCs. (C) No Ly5.2+ cells could be detected after administration of Anxa5-lacZ+/Ly5.2+ donor PVCs.