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Macrophage Colony-Stimulating Factor (M-CSF), As Well As Granulocyte Colony-Stimulating Factor (G-CSF), Accelerates Neovascularization

^a First Department of Pathology,
^b Department of Ophthalmology,
^c Regeneration Research Center for Intractable Diseases,
^d Department of Anatomical Pathology,
^e Second Department of Internal Medicine, and
^f Department of Neurology, Kansai Medical University, Moriguchi, Osaka, Japan

Key Words. Bone marrow cell • G-CSF • M-CSF • Neovascularization

Correspondence: Susumu Ikehara, M.D., Ph.D., First Department of Pathology, Kansai Medical University, Moriguchi, Osaka, 570-8507, Japan. Telephone: 81-066-992-1001(ex. 2470); FAX 81-066-992-1219; e-mail: ikehara{at}takii.kmu.ac.jp

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
It has been reported that bone marrow cells (BMCs) differentiate into endothelial cells of blood vessels, and that granulocyte colony-stimulating factor (G-CSF) mobilizes progenitors in the BMCs to the peripheral blood, while macrophage colony-stimulating factor (M-CSF) augments the production of monocytes. We examined whether M-CSF augments the differentiation of BMCs into endothelial cells of blood vessels using a hindlimb-ischemic model. Either G-CSF or M-CSF, or both, was administered to the hindlimb-ischemic mice for 3 days. Both M-CSF and G-CSF augmented the differentiation of BMCs into endothelial cells of blood vessels through vascular endothelial cell growth factor (VEGF), resulting in early recovery of blood flow in the ischemic limbs.

	INTRODUCTION

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It has been reported that endothelial progenitor cells (EPCs) exist in the peripheral blood, and that they can differentiate into the endothelial cells of blood vessels [1]. Bone marrow cells (BMCs) have also been reported to differentiate into the endothelial cells of blood vessels [2].

Several cytokines, such as granulocyte colony-stimulating factor (G-CSF), macrophage colony-stimulating factor (M-CSF), and granulocyte macrophage colony-stimulating factor (GM-CSF) are known to augment the numbers and functions of granulocyte-monocyte lineage cells [3, 4, 5, 6]. G-CSF and GM-CSF have been reported to mobilize peripheral blood stem cells (PBSCs) [3, 7] and EPCs [8, 9]. However, it remains unclear whether M-CSF contributes to neovascularization and mobilizes EPCs from the bone marrow. Here, we report that M-CSF mobilizes EPCs from the bone marrow and that both M-CSF as well as G-CSF augment neovascularization of ischemic limbs.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Mice
C57BL/6 (B6, H-2^b) and C3H HeN (C3H, H-2^k) mice were purchased from SLC (Shizuoka, Japan; http://133.1.15.131/SLC/SLC.htm). Enhanced green fluorescent protein (EGFP)–transgenic mice (green mice), which were based on B6 mice, were kindly donated by Dr. H. Okabe (Osaka University, Osaka, Japan) [10].

Preparation of Hindlimb Ischemia
On day 0, unilateral hindlimb ischemia was induced by resecting the right femoral artery and vein of B6 mice or bone marrow–transplanted B6 mice. Three days after surgery, the skeletal muscles (bilateral gastrocnemius muscles) were isolated, embedded in optimal cutting temperature (OCT) compound (Sakura, Elkhart, IN), and snap-frozen in liquid nitrogen.

Administration of G-CSF and M-CSF
Hindlimb ischemia was induced in mice on day 0. Either recombinant human G-CSF (250 µg/kg) or recombinant human M-CSF (250 µg/kg), or both—kindly donated by Chugai Pharmaceutical Co. (Tokyo, Japan; http://www.chugai-pharm.co.jp/english/) and Kyowa Hakko Kogyo (Tokyo, Japan; http://www.kyowa.co.jp/en/), respectively—was administered to the mice i.p. for 3 days (day 0, day 1, and day 2) [5, 7]. The dosages of the cytokines were determined according to the method described in our previous paper [7]. On day 3, the mice were sacrificed to study neovascularization. Bilateral gastrocnemius muscles were isolated and snap-frozen in liquid nitrogen.

To study the regeneration of blood vessels from BMCs, we performed two experiments. One was chimeric mice from B6-based transgenic mice expressing EGFP [10] into B6 mice. The other was chimeric mice from C3H into B6 mice. For bone marrow transplantation (BMT), we transplanted donor BMCs (2 x 10⁷) into the bone marrow cavity of lethally irradiated recipients, as previously described [11]. One month after BMT, we confirmed that more than 90% of the peripheral blood in the mice showed donor-type major histocompatability complex (MHC) (H-2^k) molecules. On day 0, hindlimb ischemia was induced, and either G-CSF or M-CSF, or both, was administered to the mice for a continuous 3 days (day 0–2). On day 3, the mice were sacrificed, and the gastrocnemius muscles were collected for microscopical observation.

Histological Analyses
Histological analyses were performed as previously described [12]. Briefly, 2-µm sections of frozen muscles were stained with fluorescein isothiocyanate (FITC)–labeled anti-CD31 Ab (Caltag Laboratories, Burlingame, CA; http://www.caltag.com/) to detect blood vessels. To detect donor-derived blood vessels, the sections obtained from the chimeric mice (EGFPB6) were stained with phycoerythrin (PE)–labeled anti-CD31 Ab (Caltag Laboratories). To examine whether or not newly developed vessels are due to fusion, the sections obtained from chimeric mice (C3HB6) were stained with PE-labeled anti-CD31 Ab, FITC-labeled anti-H-2K^b Ab, and biotin-labeled anti-H-2K^k Ab, followed by Alexa-labeled avidin. They were then observed using a confocal laser microscope (Olympus, Tokyo, Japan; http://www.olympus.co.jp/en/).

Laser Doppler Perfusion Image
The hind limbs of mice were shaved using a razor. The mice were anesthetized with 160 mg/kg pentobarbital, then fixed supine on the cork plate. We next measured the blood flow of limbs using a laser Doppler perfusion image (LPDI) analyzer (Moor Instruments, Millwey, Devon, England; http://www.moor.co.uk/), as described previously [13]. The LPDI index was expressed as the ratio of the ischemic (right) to normal (left) limb blood flow.

Thermography
The skin temperature of the lower part of the femur was measured with a thermograph (INFRA-EYE 1200A, Fujitsu, Tokyo, Japan; http://www.fujitsu.com) at a room temperature of 18°–20°C. The difference of the skin temperature between control legs and ischemina-induced legs was calculated (skin temperature of the control leg minus skin temperature of the ischemia-induced leg).

Estimation of Endothelial Progenitor Cells in Peripheral Blood
Three days after injecting the mice with either G-CSF or M-CSF, or both (each at 250 µg/kg per day), the cell numbers in the peripheral blood were counted using an SF-3000 auto-analyzer for the peripheral blood (Sysmex Corporation, Kobe, Japan; http://www.sysmex.com/). To stain surface markers of white blood cells (WBCs) in the peripheral blood, the red blood cells (RBCs) in the peripheral blood were then lysed with PharM Lyse (BD Biosciences-Pharningen, San Diego, CA; http://www.bdbiosciences.com/pharmingen/). Since Sca-1⁺ cells [9], Flk-1⁺/CD45^– cells, and Sca-1⁺/c-kit⁺/CD45^– cells have been reported to be an EPC-enriched fraction [14], peripheral blood cells (PBCs) were stained with PE-labeled anti-Sca-1 Ab (BD Biosciences-Pharmingen) + TC-labeled CD3 Ab (Caltag Laboratories) + TC-labeled CD19 Ab (Caltag Laboratories); TC-labeled anti-CD45 Ab (Caltag Laboratories) + PE-labeled anti-Sca-1 Ab (Caltag Laboratories) + FITC-labeled anti-c-kit Ab (Caltag Laboratories); or TC-labeled anti-CD45 Ab + PE-labeled anti-Flk-1 (VEGF-R2) Ab (BD Biosciences-Pharmingen). The stained cells were analyzed using a FACScan (BD Biosciences-Pharmingen). The numbers of positive cells for the indicated markers were calculated with the percentage of the cells in WBCs and the number of WBCs in the peripheral blood.

Enzyme-Linked Immunoassay (ELISA) for Vascular Endothelial Growth Factor (VEGF)
Spleen cells and BMCs from B6 mice were adjusted to 2 x10⁶/ml and cultured with or without either G-CSF or M-CSF, or both (each at 10 ng/ml) for 1 day or 3 days. Supernatants were collected after culture for the indicated days, and ELISA for VEGF was performed using the Quantikine: Mouse VEGF Immunoassay Kit (R&D Systems, Minneapolis, MN; http://www.rndsystems.com/).

Statistical Analyses
Statistical analyses were performed using Student’s t-test.

	RESULTS

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Neovascularization Induced by G-CSF with or without M-CSF in Ischemic Limbs
We first examined whether either G-CSF or M-CSF, or both, is involved in the formation of new blood vessels. Either G-CSF or M-CSF, or both, was administered to mice in which the right hindlimbs were induced with ischemia, as described in Materials and Methods. On day 3, the skeletal muscles of the lower limbs were collected. The specimens were stained with anit-CD31 Ab, and blood vessels were detected by CD31⁺ cells and their shape (morphology).

As shown in Figure 1, nontreated limbs showed similar numbers of blood vessels in all groups. However, the ischemic hindlimbs of mice treated with either G-CSF or M-CSF, or both, showed a significant increase in the number of blood vessels in the skeletal muscles. We also obtained similar results using anti-CD146 Ab, which is also a specific marker for endothelial cells (data not shown).

View larger version (58K): [in this window] [in a new window]   Figure 1. Augmentation of neovascularization in ischemic hindlimbs by either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both. (A): Hindlimb-ischemic mice were prepared, and either G-SCF or M-CSF, or both, (each at 250 µg/kg) was administered to the mice for 3 consecutive days. One day after the last injection, the skeletal muscles of the ischemic hindlimbs and the nontreated hindlimbs were collected and snap-frozen in liquid nitrogen. The blood vessels in the muscles were visualized by staining with fluorescein isothiocyanate (FITC)–anti-CD31 Ab, which is expressed on the endothelial cells of blood vessels, and samples were observed by confocal laser microscopy (original magnification: x40, bars = 50 µm). (B): The number of blood vessels (per field) in which endothelial cells express CD31 molecules was calculated, and the mean ± SD is shown (n = 4). *p < .005. Abbreviation: FITC, fluorescein isothiocyanate.

Differentiation from BMCs into Blood Vessels
It has been reported that the EPCs in the peripheral blood and BMCs differentiate into endothelial cells of blood vessels [1, 2]. We therefore examined whether BMCs could differentiate into endothelial cells of blood vessels. One month after the BMCs of EGFP-transgenic mice were transplanted into the lethally irradiated B6 mice, unilateral hindlimb ischemia was induced. Either G-CSF or M-CSF, or both, was then injected i.p. for 3 days (day 0 to day 2). On day 3, the mice were sacrificed, and frozen sections of the gastrocnemius muscles were prepared to examine vascularization using a confocal microscopy. In the ischemic limbs of either G-CSF or M-CSF, or both, treated mice, we found cells expressing both EGFP and CD31 (Fig. 2). The numbers of blood vessels in each group were similar to those in the experiment using B6 mice (Fig. 1 and Fig. 2B), suggesting that BMT had no effect on the neovascularization by either G-CSF or M-CSF, or both.

View larger version (55K): [in this window] [in a new window]   Figure 2. Contribution of BMCs to neovascularization of ischemic limbs. BMCs of EGFP–transgenic mice were transplanted into lethally irradiated B6 mice. One month after bone marrow transplantation, hindlimb ischemia was induced in the mice. Either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both (each at 250 µg/kg) was administered to the mice for 3 consecutive days. One day after the last injection, the skeletal muscles of the ischemic hindlimbs and nontreated hindlimbs were collected and snap-frozen in liquid nitrogen. The blood vessels in the muscles were visualized by staining with PE–anti-CD31 Ab, followed by counting EGFP-positive or -negative intramuscular capillaries using a confocal microscopy. (A): Representative data of the staining. Arrows show EGFP+ blood vessels. (B): The number of blood vessels (per field) was calculated, and the mean ± SD is shown (n = 4). *p < .005. (C): The number of EGFP+ blood vessels (per field) was calculated, and the mean ± SD is shown (n = 4). *p <.005. Abbreviations: BMC, bone marrow cells; EGFP, enhanced green fluorescent protein; PE, phycoerythrin.

Since there are several reports suggesting that cell fusion instead of regeneration should be considered [15], we performed further experiments to assess whether some new blood vessels are truly derived from BMCs. BMT from C3H mice to B6 mice were performed, as described in Materials and Methods. One month after BMT, we confirmed that more than 90% of the peripheral blood showed donor-type MHC (H-2^k) molecules, suggesting that host BMCs (H-2^b) were replaced by donor BMCs (H-2^k). We induced unilateral hindlimb ischemia in the mice, followed by cytokine injection for 3 days, as described above. As shown in Figure 3, the endothelium cells, which wereH-2^k+/H-2^b–/CD31⁺, existed in the capillary walls of ischemia-induced muscle of cytokine-treated mice. Moreover, the numbers of H-2^k+/H-2^b–/CD31⁺ capillary were similar to those of EGFP⁺ capillaries (Fig. 2 and data not shown). These results suggest that the expression of donor MHC molecules by endothelial cells was not due to cell fusion but to real differentiation from donor BMCs.

View larger version (89K): [in this window] [in a new window]   Figure 3. Contribution of bone marrow–derived cells to neovascularization due to differentiation into endothelium, but not due to cell-to-cell fusion. To discriminate real differentiation from cell-to-cell fusion, we performed further BMT experiments. One month after BMT (from C3H mice into lethally irradiated B6 mice), hindlimb ischemia was induced in the mice. Either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both (each at 250 µg/kg), was administered to the mice for 3 consecutive days. One day after the last injection, the skeletal muscles of the ischemic hindlimbs and the nontreated hindlimbs were collected and snap-frozen in liquid nitrogen. The blood vessels in the muscles were visualized by staining with PE–anti-CD31 Ab (red), FITC–labeled anti-H-2b Ab (green), and biotin-labeled H-2k Ab (orange), followed by staining with Alexa-labeled avidin (blue). Representative data of H-2k+/H-2b– () or H-2b+/H-2k– () blood vessels are shown (original magnification: x60, bars = 5 µm). Abbreviations: BMT, bone marrow transplant; FITC, fluorescein isothiocyanate; PE, phycoerythrin.

View larger version (38K): [in this window] [in a new window]   Figure 4. Augmentation of EPCs in the peripheral blood of mice treated with either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both. G-CSF and M-CSF (each at 250 µg/kg) were injected i.p. to B6 mice for a continuous 3 days. One day after the last injection, white blood cells of the mice were collected and analyzed, followed by calculation of the number of Sca-1+/CD3–/CD19– cells, Flk-1+/CD45– cells, or Sca-1+/c-kit+/CD45– cells in the peripheral blood. *p < .005. Abbreviation: EPC, endothelial progenitor cells.

View larger version (72K): [in this window] [in a new window]   Figure 5. Recovery of blood flow using laser Doppler perfusion image (LDPI). We measured the blood flow of the lower limbs, using an LDPI analyzer. Before ischemia induction, we confirmed that bilateral legs showed similar blood flow. After ischemia induction, blood flow of the legs was measured (day 0). We administered either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both (each at 250 µg/kg), to the mice for a continuous 3 days (day 0–2). At 3 and 7 days after surgery, we measured blood flow using an LPDI analyzer, followed by calculation of the ratio of the ischemic (right) to normal (left) limb blood flow. (A): Representative figures of LDPIs showing the time course of the ratio of the ischemic to normal limb blood flow (mean ± SD) (n = 4). *p < .005. Abbreviation: LDPI, Laser Doppler perfusion image.

View larger version (63K): [in this window] [in a new window]   Figure 6. Recovery of blood flow using a thermography. After either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both (each at 250 µg/kg) was administered to ischemic hindlimb mice for 3 days, the skin temperature was measured using a thermograph. Differences of skin thermographs of right (treated) and left (nontreated) legs are shown. (A): Representative data of thermography on day 3. (B): Mean ± SD of the differences of the skin temperatures on day 3 (n = 4). *p < .005.

Next, we cultured spleen cells and BMCs (2 x 10⁶/ml) with, or both G-CSF or M-CSF (each at 10 ng/ml), then we measured the VEGF using the ELISA kit. We did not detect VEGF in the supernatants of spleen cells even when cytokines had been added, but we did in the supernatants of BMCs (Fig. 7). The amount of VEGF in the supernatants of BMCs with either G-CSF or M-CSF, or both, increased. These results suggest that G-CSF and M-CSF stimulate BMCs, probably monocyte-lineage cells, to produce VEGF, followed by an increase in the number of EPCs and augmentation of their mobilization.

View larger version (34K): [in this window] [in a new window]   Figure 7. Augmentation of vascular endothelial cell growth factor (VEGF) production by bone marrow cells (BMCs) in the presence of either granulocyte colony-stimulating factor (G-CSF) or macrophage colony-stimulating factor (M-CSF), or both, in vitro. Spleen cells or BMCs (each at 2 x 106/ml) were cultured with or without G-CSF or M-CSF, or both, for 1 day or 3 days. The concentrations of VEGF in the supernatants were measured by enzyme-linked immunoassay (ELISA).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The existence of a common progenitor of both hematopoietic cells and endothelial cells of blood vessels has been reported [17]. It has also been reported that PBCs and BMCs have the capacity to differentiate into endothelial cells [1, 2]. These results suggest that EPCs exist in PBCs and BMCs, and that these EPCs can differentiate into endothelial cells of blood vessels and contribute to neovascularization. Recently, it has been reported that human CD34⁺ cells mobilized by G-CSF are involved in neovasculogenesis in infarcted hearts of rats [8]. It has also been reported that GM-CSF mobilizes EPCs from BMCs and contributes to neovascularization [9]. These newly formed blood vessels were found to work functionally; transplanted human EPCs prevented ischemic hindlimbs of nude mice from falling off [18], providing an experimental basis for the ongoing therapies using BMCs to treat arteriosclerosis obliterans [19].

These results suggest that G-CSF and GM-CSF mobilize not only hemopoietic progenitors but also EPCs and raise the possibility of therapy for ischemic diseases using cytokine-induced neovascularization. M-CSF is also well known as a cytokine for augmenting the proliferation and function of monocytes [20]. We have here demonstrated that M-CSF contributes to neovascularization and that a part of the effect can be attributed to mobilization of EPCs from the bone marrow, resulting in an early recovery of blood flow in the ischemic limb. Although Scholz et al. [21] stated that monocytes are related to angiogenesis, when arteries are occluded, and Eubank et al. [16] recently reported that M-CSF induces the differentiation of the monocytes that produce VEGF, we did not detect VEGF in the sera of mice injected with G-CSF or M-CSF for the continuous 3 days. Neither did we detect VEGF in the supernatants of the spleen cells cultured with G-CSF or M-CSF. However, we detected a high concentration of VEGF in supernatants of BMCs cultured with either G-CSF or M-CSF. These results suggest that G-CSF and M-CSF augment EPCs through VEGF production.

Mobilized EPCs could participate in the development of collateral arteries. In our experiments, the cell numbers of EPC-enriched fractions in the peripheral blood mobilized by G-CSF plus M-CSF were significantly higher than those by each single factor. However, the number of blood vessels generated by G-CSF plus M-CSF is comparable with that by each single factor. These results suggest that the trapping of EPCs in the ischemic limbs might be limited even if many more EPCs exist in the peripheral blood.

We used 250 µg/kg of G-CSF or M-CSF in this experiment, as in our previous experiments [7]. Although the dosages of the cytokines (for example, 200–250 µg/kg) seem to be extremely high in comparison with human dosages, both our group and other groups have used these doses for experiments to mobilize hematopoietic progenitor cells [22, 23].

It is well known that inflammation is involved in the development and progression of atherosclerosis [24]. Indeed, several papers describe the possibility of enhancement of atherosclerosis by M-CSF and G-CSF [25, 26]. Therefore, in clinical settings, the short-term use of cytokines is thought to be better than extended use in order to limit the exacerbation of atherosclerosis. Bensinger et al. [27] have described that, in studies with humans, the absolute number of CD34⁺ cells per ml in the peripheral blood increases 10-fold over baseline and peaks on approximately day 5 of G-CSF. They have also shown that 3-day administration of G-CSF is sufficient to mobilize CD34⁺ cells. Therefore, we examined the effects of short-term administration of G-CSF or M-CSF on acute ischemia. Our results also showed that the 3-day administration of G-CSF or M-CSF is effective in augmenting blood vessels in acute ischemia.

Previous experiments also demonstrated that the peak of incorporation of human EPCs that had been administered into nude mice in which ischemic limbs had been induced was within 3–7 days and rescued the ischemic limbs [3]. Flk-1⁺ cells derived from embryonal stem cells expressed VE-cadherin, one of the markers of endothelial cells, after only 1 day of culture [28]. Therefore, we analyzed the number of capillaries in the ischemic muscles and the temperature of the skin on day 3. In the control limbs, in which no ischemia was induced, there was no difference in neovascularization between saline-injected mice and G-CSF- or M-CSF-treated mice. These results suggest that mobilized EPCs might home in on the sites of ischemia, which is where neovascularization is necessary; no unnecessary angiogenesis therefore occurs. This would be a valuable phenomenon in clinical applications.

The differences in LPDI index and skin temperature between the nontreated limbs and ischemic limbs of G-CSF-and M-CSF-treated mice were significantly less than in the saline-injected mice. These results reflect enhanced blood flow in the ischemic limbs.

It has been reported that M-CSF has no effect on the number of peripheral blood cells or monocytes in the peripheral blood [5], whereas G-CSF and GM-CSF cause an increase in the number of peripheral blood cells, especially granulocytes [2, 3]. Therefore, M-CSF would be readily applicable to the treatment of various diseases in humans, since it is well known that leukocytosis, particularly granulocytosis, accelerates tissue injury [29].

	ACKNOWLEDGMENTS

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We thank professor H. Okabe (Osaka University, Osaka, Japan) for the donation of EGFP-transgenic mice. We also thank Ms. Sachiko Miura, Ms. Mari Murakami-Shinkawa, and Ms. Yoko Tokuyama for their expert technical assistance, and also Mr. Hilary Eastwick-Field and Ms. Keiko Ando for the preparation of this manuscript. Keizo Minamino and Yasushi Adachi contributed equally to this work.

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Top Abstract Introduction Materials and Methods Results Discussion References

 

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