Suppression of Ewing's sarcoma tumor growth, tumor vessel formation, and vasculogenesis following anti vascular endothelial growth factor receptor-2 therapy.

PURPOSE: We previously showed that bone marrow cells participate in new tumor vessel formation in Ewing's sarcoma, and that vascular endothelial growth factor 165 (VEGF(165)) is critical to this process. The purpose of this study was to determine whether blocking VEGF receptor 2 (VEGFR-2) with DC101 antibody suppresses tumor growth, reduces tumor vessel formation, and inhibits the migration of bone marrow cells into the tumor. EXPERIMENTAL DESIGN: An H-2 MHC-mismatched bone marrow transplant Ewing's sarcoma mouse model was used. Bone marrow cells from CB6F1 (MHC H-2(b/d)) mice were injected into irradiated BALB/cAnN mice (MHC H-2(d)). TC71 Ewing's sarcoma cells were s.c. injected 4 weeks after the bone marrow transplantation. Mice were then treated i.p. with DC101 antibody or immunoglobulin G (control) twice a week for 3 weeks starting 3 days after tumor cell injection. RESULTS: DC101 antibody therapy significantly reduced tumor growth and tumor mean vessel density (P < 0.05) and increased tumor cell apoptosis. Decreased bone marrow cell migration into the tumor was also shown after DC101 therapy as assessed by the colocalization of H-2K(b) and CD31 using immunohistochemistry. DC101 inhibited the migration of both human and mouse vessel endothelial cells in vitro. CONCLUSION: These results indicated that blocking VEGFR-2 with DC101 antibodies may be a useful therapeutic approach for treating patients with Ewing's sarcoma.     

A small interfering RNA targeting vascular endothelial growth factor inhibits Ewing's sarcoma growth in a xenograft mouse model.

Angiogenesis plays an essential role in tumor growth and metastasis and is a promising therapeutic target for cancer. Vascular endothelial growth factor (VEGF) is a key regulator in vasculogenesis as well as in angiogenesis. TC71 human Ewing's sarcoma cells overexpress VEGF, with a shift in isoform production from membrane-bound VEGF189 to the more soluble VEGF165. Transfection of TC71 cells with a vector-based VEGF targeted small interfering RNA expression system (VEGFsi) inhibited VEGF165 expression by 80% and VEGF165 protein production by 98%, with no alteration in VEGF189 expression. Human microvascular endothelial cell proliferation and migration induced by conditioned medium from VEGFsi-transfected TC71 cells was significantly less than that induced by conditioned medium from TC71 cells and control vector-transfected TC71 cells. Furthermore, after s.c. injection into athymic nu/nu mice, the tumor growth of VEGFsi-expressing TC71 cells was significantly less than that of parental or control vector-transfected cells. Vessel density as assessed by CD31 immunohistochemical analysis and VEGF165 expression as assessed by Northern blotting were also decreased. Intratumor gene therapy with polyethylenimine/VEGFsi also resulted in tumor growth suppression. When inoculated into the tibias of nude mice, VEGFsi-expressing TC71 cells induced osteolytic bone lesions that were less severe than those induced by control groups. These data suggest that targeting VEGF165 may provide a therapeutic option for Ewing's sarcoma.     

Stromal cell-derived factor-1 stimulates vasculogenesis and enhances Ewing's sarcoma tumor growth in the absence of vascular endothelial growth factor

Stromal cell-derived Factor-1alpha (SDF-1alpha) stimulates the migration of bone marrow (BM) cells, similar to vascular endothelial growth factor (VEGF). We previously demonstrated that inhibition of VEGF(165) by small interfering RNA inhibited Ewing's sarcoma tumor growth, tumor vessel formation and recruitment of BM cells to the tumor. To determine the importance of BM cells in tumor vessel development, we investigated the effects of SDF-1alpha on VEGF-inhibited TC/siVEGF(7-1) Ewing's tumor neovasculature formation and growth. The effect of SDF-1alpha on CD34(+) progenitor cell chemotaxis was determined in vivo. Using a BM transplantation model with GFP(+) transgenic mice as BM donors and nude mice as recipients, we evaluated the effect of SDF-1alpha on the recruitment of BM-derived cells to VEGF(165)-inhibited TC/siVEGF(7-1) tumors, as well as its effect on neovasculature development, vessel morphology and tumor growth. SDF-1alpha stimulated the migration of CD34(+) progenitor cells to Matrigel plugs in vivo and promoted the retainment of BM-derived pericytes in close association with perfused, functional tumor vessels. Intratumor inoculation of Ad-SDF-1alpha into TC/siVEGF(7-1) tumors resulted in increased SDF-1 and PDGF-BB expression, augmented tumor growth, an increase in the number of large, lumen-bearing vascular structures, and enhanced vessel pericyte coverage, with no change in VEGF(165). SDF-1alpha stimulates BM cell chemotaxis and the association of these cells with functional tumor vessels. Furthermore, SDF-1alpha enhances tumor neovascularization and growth with no alteration in VEGF(165). Our work suggests that SDF-1-mediated vasculogenesis may represent an alternate pathway that could potentially be utilized by tumors to sustain growth and neovasculature expansion after anti-VEGF therapy.     

Herceptin down-regulates HER-2/neu and vascular endothelial growth factor expression and enhances taxol-induced cytotoxicity of human Ewing's sarcoma cells in vitro and in vivo.

We have previously shown that high levels of HER-2/neu protein were overexpressed in human Ewing's sarcoma cells (TC71, SK-ES1) relative to normal human osteoblasts. The purpose of this study was to determine whether herceptin alone or in combination with chemotherapeutic agents could inhibit the growth of Ewing's sarcoma in vitro and in vivo. Western blot analysis showed that the protein levels of HER-2/neu were decreased following herceptin treatment. Cell growth was also inhibited by herceptin in a dose-dependent manner with an IC(50) of 4 mg/mL in TC71 and SK-ES1 cell line, whereas human immunoglobin had no effect. Northern blot and ELISA showed the RNA expression and protein levels of vascular endothelial growth factor were also inhibited by herceptin treatment with no alteration in HIF-1alpha protein and topoisomerase IIalpha expression. Furthermore, Ewing's sarcoma tumor growth was significantly delayed by 100 mg/kg herceptin treatment in our Ewing's sarcoma xenograft mouse model. Combining taxol with herceptin resulted in additive cytotoxicity, whereas herceptin-etoposide, doxorubicin, and 9-nitrocamptothecin combinations did not. Taxol-herceptin enhanced growth inhibition in TC71 cells in vitro compared with either agent alone. Ewing's sarcoma growth was also delayed in vivo and mean tumor size was significantly lower in mice treated with herceptin plus taxol than in those receiving taxol or herceptin alone. These data suggest that herceptin in combination with taxol may be a therapeutic option in the treatment of Ewing's sarcoma.     

Tumor skewing of CD34+ progenitor cell differentiation into endothelial cells

Tumor production of granulocyte-macrophage colony-stimulating factor (GM-CSF) results in the mobilization of CD34(+) progenitor cells into the peripheral blood and tumor tissue. Using the Lewis lung carcinoma (LLC) model, in vitro studies showed that LLC cells could chemoattract CD34(+) cells predominantly through tumor production of VEGF. Addition of LLC-conditioned medium to CD34(+) cells that were cultured under conditions that support myeloid lineage cells skewed the differentiation of these precursor cells toward endothelial cells expressing CD31 and CD144. This differentiation of CD34(+) cells toward endothelial cells was attributed predominantly to angiopoietin-1 in the tumor-conditioned medium. The CD34(+) cells expressed the angiopoietin receptor Tie-2 and their differentiation into endothelial cells was blocked with neutralizing angiopoietin-1 antibodies. In vivo studies showed that infusion of lacZ(+) CD34(+) cells from the bone marrow of transgenic mice into wild-type mice bearing LLC tumors resulted in the accumulation of lacZ(+) cells within the tumor mass, particularly at the tumor's periphery. That these infused CD34(+) progenitor cells could develop into endothelial cells of the tumor vasculature was supported by their acquisition of the endothelial cell markers CD31 or CD144 within the tumor tissue. These studies demonstrate the capacity of tumor to attract CD34(+) cells to the tumor site and to direct the differentiation of these CD34(+) cells into endothelial cells that can become a component of the tumor vasculature.     

Vascular endothelial growth factor overexpression by soft tissue sarcoma cells: implications for tumor growth, metastasis, and chemoresistance

To better elucidate the role of vascular endothelial growth factor (VEGF)(165) in soft tissue sarcoma (STS) growth, metastasis, and chemoresistance, we generated stably transfected human STS cell lines with VEGF(165) to study the effect of VEGF(165) on STS cells in vitro and the effect of culture medium from these cells on human umbilical vascular endothelial cells. Severe combined immunodeficient mice bearing xenografts of transfected cell lines were used to assess the effect of VEGF overexpression and the effect of VEGF receptor (VEGFR) 2 inhibition on STS growth, metastasis, and response to doxorubicin. VEGF(165)-transfected xenografts formed highly vascular tumors with shorter latency, accelerated growth, enhanced chemoresistance, and increased incidence of pulmonary metastases. Blockade of VEGFR2 signaling using DC101 anti-VEGFR2 monoclonal antibody enhanced doxorubicin chemoresponse; this combined biochemotherapy inhibited tumor growth and decreased pulmonary metastases without overt toxicity. Combined therapy reduced microvessel counts while increasing vessel maturation index. VEGF overexpression did not affect on the sarcoma cells per se; however, conditioned medium from VEGF transfectants caused increased endothelial cell proliferation, migration, and chemoresistance. Addition of DC101 induced endothelial cell sensitivity to doxorubicin and suppressed the activity of matrix metalloproteinases secreted by endothelial cells. We therefore conclude that VEGF is a critical determinant of STS growth and metastasis and that STS chemoresistance, in our model, is a process induced by the interplay between STS cells and tumor-associated endothelial cells. STS growth and metastasis can be interrupted by combined low-dose doxorubicin and anti-VEGFR2, a strategy that attacks STS-associated endothelial cells. In the future, such therapeutic approaches may be useful in treating STS before the development of clinically apparent metastases.     

A midkine promoter-based conditionally replicative adenovirus for treatment of pediatric solid tumors and bone marrow tumor purging.

The treatment of advanced neuroblastoma (NB) or Ewing's sarcoma (ES) is one of the major challenges in pediatric oncology. Both malignancies are refractory to conventional therapies and have an extremely poor prognosis. High-dose myeloablative radiochemotherapy with autologous bone marrow or peripheral blood stem cell rescue is one of the most aggressive treatments attempted for these diseases but is often undermined by residual tumor cells contaminating the graft. Thus, in this approach, purging of tumor cells from the graft is key to the prevention of relapse after transplantation. We investigated a novel approach to eliminate tumor cells from the bone marrow or peripheral blood stem cell graft without causing stem cell damage through the use of a conditionally replicative adenovirus (Ad). ES and NB are sensitive to Ad infection, and advanced NBs express a high level of the growth/differentiation factor midkine (MK). We confirmed in this study that ES cell lines (SK-ES-1 and RD-ES) are also sensitive to Ad infection and express high levels of MK. In contrast, CD34+ stem cells are refractory to Ad infection and express very little MK. A conditionally replicative Ad in which the expression of E1 is controlled by the MK promoter achieved good levels of viral replication in NB or ES and induced remarkable tumor cell killing. On the other hand, this virus caused no damage to CD34+ cells even after 3 h of infection at a dose of 1000 multiplicity of infection. We concluded that application of this replication-competent Ad to hematopoietic grafts could be a simple but effective procedure to achieve complete tumor cell purging.     

The endogenous anti-angiogenic VEGF isoform, VEGF165b inhibits human tumour growth in mice

Vascular endothelial growth factor-A is widely regarded as the principal stimulator of angiogenesis required for tumour growth. VEGF is generated as multiple isoforms of two families, the pro-angiogenic family generated by proximal splice site selection in the terminal exon, termed VEGFxxx, and the anti-angiogenic family formed by distal splice site selection in the terminal exon, termed VEGFxxxb, where xxx is the amino acid number. The most studied isoforms, VEGF165 and VEGF165b have been shown to be present in tumour and normal tissues respectively. VEGF165b has been shown to inhibit VEGF- and hypoxia-induced angiogenesis, and VEGF-induced cell migration and proliferation in vitro. Here we show that overexpression of VEGF165b by tumour cells inhibits the growth of prostate carcinoma, Ewing's sarcoma and renal cell carcinoma in xenografted mouse tumour models. Moreover, VEGF165b overexpression inhibited tumour cell-mediated migration and proliferation of endothelial cells. These data show that overexpression of VEGF165b can inhibit growth of multiple tumour types in vivo indicating that VEGF165b has potential as an anti-angiogenic, anti-tumour strategy in a number of different tumour types, either by control of VEGF165b expression by regulation of splicing, overexpression of VEGF165b, or therapeutic delivery of VEGF165b to tumours.     

内皮祖细胞作为干扰素基因载体的体外抑瘤实验

目的 研究用人骨髓诱导培养内皮祖细胞（EPCs）并以其作为免疫性基因载体治疗肿瘤的可行性。方法 采用梯度离心法从人骨髓中分离单个核细胞,加入人血管内皮生长因子(VEGF165）诱导培养,用流式细胞仪测定细胞表面标志CD133、KDR和CD34的表达情况。以增强型绿色荧光蛋白基因（EGFP）作为报告基因,用流式细胞仪检测携带EGFP基因的腺病毒载体（Ad-EGFP）对EPCs的感染效率。携带人干扰素γ（hγIFN）基因的腺病毒载体（Ad-hγIFN）感染EPCs（EPCs-hγIFN）,ELISA法检测细胞EPCs-hγIFN分泌 hγIFN的情况。将EPCs-hγIFN与肺癌细胞株H460、胃癌细胞株SGC7901、大肠癌细胞株LoVo混合培养,观察EPCs-hγIFN对肿瘤细胞的作用。结果 经过诱导培养2周后,贴壁的单核细胞开始表达CD133、KDR和CD34。Ad-EGFP的感染复数（MOI）为150pfu／EPCs时,感染率达90％以上。EPCs-hγIFN培养上清可以测得浓度稳定且高水平的hγIFN,第1天上清液中的hγIFN浓度为1305.28pg／ml,第14天为1419.10pg／ml。EPCs-hγIFN与H460、SGC7901、LoVo细胞株混合培养4天,肿瘤细胞的生长受到明显的抑制,肿瘤细胞存活率分别为（77.87 ± 6.50）％、（79.36 ± 4.35）％和（69.52 ± 3.78）％, 均显著低于对照组（P＜0.05）。结论携带hγIFN目的基因的腺病毒转染EPCs后基因表达情况良好,体外实验中表现为抑制肿瘤细胞的生长,可作为免疫性基因载体开展进一步的研究。     

骨髓来源内皮前体细胞促进肿瘤新生血管生成

Objective:Neovascularization of tumor is a complex process.In this study,we aimed to reveal whether the bone marrow-originated endothelial progenitor calls (EPCs) contributed to neovasculature in tumor and the angiogenesis-associated factors,VEGF and B-FGF,enhanced this process.Methods:We had established a mouse model,which were deprived of bone marrow by radiation and transplanted with bone marrow of syngenetic GFP (Green Fluorescence Protein)-transgened mice,then implanted Lewis calls.Immunohistochemical and immunoflourensenca proved the EPCs location in tumors by indentifying colocalization of GFP expression in cells staining with endothelial progenitor cell markers,CD 133,ICAM-1,CD31.The growth statue and MVD of tumor was observed after injection of VEGF or B-FGF.ICAM-1 and VE-cadherin in tumor were detected by Western blot.Results:By immunohistochemical and immunoflourensence,we proved part of bone marrow precursors located in area of tumor angiogenesis and VEGF or B-FGF increased the MVD of tumor.In Western blot,it was found and VEGF or B-FGF up-regulate the expression of ICAM-1,VE-Cadherin.Conclusion:Bone marrow-derived endothelial progenitor cell seem to be recruited in neovasculature induced by tumor.VEGF and B-FGF are key regulators of this process.     

VEGF expression by mesenchymal stem cells contributes to angiogenesis in pancreatic carcinoma

Little is known about the factors that enable the mobilisation of human mesenchymal stem cells (MSC) from the bone marrow into the blood stream and their recruitment to and retention in the tumour. We found specific migration of MSC towards growth factors present in pancreatic tumours, such as PDGF, EGF, VEGF and specific inhibitors Glivec, Erbitux and Avastin interfered with migration. Within a few hours, MSC migrated into spheroids consisting of pancreatic cancer cells, fibroblasts and endothelial cells as measured by time-lapse microscopy. Supernatant from subconfluent MSC increased sprouting of HUVEC due to VEGF production by MSC itself as demonstrated by RT-PCR and ELISA. Only few MSCs were differentiated into endothelial cells in vitro, whereas in vivo differentiation was not observed. Lentiviral GFP-marked MSCs, injected in nude mice xenografted with orthotopic pancreatic tumours, preferentially migrated into the tumours as observed by FACS analysis of green fluorescent cells. By immunofluorescence and intravital microscopic studies, we found the interaction of MSC with the endothelium of blood vessels. Mesenchymal stem cells supported tumour angiogenesis in vivo, that is CD31(+) vessel density was increased after the transfer of MSC compared with siVEGF-MSC. Our data demonstrate the migration of MSC toward tumour vessels and suggest a supportive role in angiogenesis.     

PRELIMINARY STUDY OF RETROVIRAL MEDIATED TRANSFER OF THE HUMAN mdr-1 GENE INTO MURINE AND HUMAN HEMATOPOIETIC STEM/PROGENITOR CELLS

ＰＲＥＬＩＭＩＮＡＲＹＳＴＵＤＹＯＦＲＥＴＲＯＶＩＲＡＬＭＥＤＩＡＴＥＤＴＲＡＮＳＦＥＲＯＦＴＨＥＨＵＭＡＮｍｄｒ１ＧＥＮＥＩＮＴＯＭＵＲＩＮＥＡＮＤＨＵＭＡＮＨＥＭＡＴＯＰＯＩＥＴＩＣＳＴＥＭ／ＰＲＯＧＥＮＩＴＯＲＣＥＬＬＳＦｅｎｇＫａｉ冯凯Ｐｅ...     

Immune system augmentation via humanization using stem/progenitor cells and bioengineering in a breast cancer model study

Despite significant advances, most current in vivo models fail to fully recapitulate the biological processes that occur in humans. Here we aimed to develop an advanced humanized model with features of an organ bone by providing different bone tissue cellular compartments including preosteoblasts, mesenchymal stem/stromal (MSCs), endothelial and hematopoietic cells in an engineered microenvironment. The bone compartment was generated by culturing the human MSCs, umbilical vein endothelial cells with gelatin methacryloyl hydrogels in the center of a melt‐electrospun polycaprolactone tubular scaffolds, which were seeded with human preosteoblasts. The tissue engineered bone (TEB) was subcutaneously implanted into the NSG mice and formed a morphologically and functionally organ bone. Mice were further humanized through the tail vein injection of human cord blood derived CD34+ cells, which then populated in the mouse bone marrow, spleen and humanized TEB (hTEB). 11 weeks after CD34+ transplantation, metastatic breast cancer cells (MDA‐MB‐231BO) were orthotopically injected. Cancer cell injection resulted in the formation of a primary tumor and metastasis to the hTEB and mouse organs. Less frequent metastasis and lower tumor burden were observed in hematochimeric mice, suggesting an immune‐mediated response against the breast cancer cells. Overall, our results demonstrate the efficacy of tissue engineering approaches to study species‐specific cancer‐bone interactions. Further studies using genetically modified hematopoietic stem cells and bioengineered microenvironments will enable us to address the specific roles of signaling molecules regulating hematopoietic niches and cancer metastasis in vivo.     

Reduced bone marrow stem cell pool and progenitor mobilisation in multiple myeloma after melphalan treatment

The content of stem cells was analysed in bone marrow samples from 75 multiple myeloma patients. In unstimulated bone marrow the percentage of CD34+ cells was significantly reduced in 11 patients previously treated with melphalan-prednisolone (MP)(median= 0.15%) compared to median 0.87% in 31 untreated patients (P=0.0001). The bone marrow cellularity in the two groups did not differ. There was no correlation between the number of courses or total dose of melphalan and content of CD34+ cells in the bone marrow. The clonogenicity as well as the ability to expand the marrow stem cell pool during growth factor treatment were also reduced in MP treated patients compared to untreated patients. Analysis of different subsets of CD34+ cells revealed no influence on the pre B cell compartment in the bone marrow by MP treatment, but the committed stem cells (CD34+CD38+) were reduced more than the uncommitted stem cells (CD34+CD38-) in the MP treated group compared to the untreated patients. Mobilisation to and harvest of total number of CD34+ cells from peripheral blood was also reduced in the MP treated group. There was, however, no difference in the distribution between CD34+CD38+ and CD34+CD38- populations in the leukapheresis products in the untreated and the melphalan-treated group, suggesting selective mobilisation of CD34+CD38+ cells and/or differentiation of CD34+CD38-cells during growth factor stimulation. We conclude that melphalan decreased the number of stem cells in the bone marrow, the ability to expand the stem cell pool and mobilise stem cells to the pheripheral blood.     

Bone and bone-marrow interactions: haematological activity of osteoblastic growth peptide (OGP)-derived carboxy-terminal pentapeptide. Mobilizing properties on white blood cells and peripheral blood stem cells in mice.

Osteogenic growth peptide (OGP) increases blood and bone marrow cellularity in mice, and enhances engraftment of bone marrow transplant. Carboxy-terminal pentapeptide (OGP10-14) holds several properties of full-length polypeptide. We evaluated whether synthetic OGP-derived pentapeptide (sOGP10-14) has some activity on peripheral blood cell recovery after cyclophosphamide-induced aplasia, and on stem cell mobilization. Peripheral blood stem cell (PBSC) mobilization was evaluated by administering granulocyte-colony stimulating factor (G-CSF) or sOGP10-14 after cyclophosphamide (CTX) injection. Haematological parameters and CD34/Sca-1 positive cells were sequentially evaluated. Colony-forming tests were performed in bone marrow cells from CTX-, G-CSF- and sOGP10-14-treated mice. sOGP10-14 was able to enhance band cells and monocyte recovery after cyclophosphamide administration. White blood cell (WBC) counts reached the maximum peak by day +10 but, on day +7, a significant recovery was already detected in sOGP10-14 treated mice. On day +10 the WBC increase in sOGP10-14-treated mice was comparable to that found in G-CSF treated ones. Moreover, CD34/Sca-1 positive early precursors were significantly mobilized by sOGP10-14 compared to the control group. In sOGP10-14-treated mice, the colony-forming unit-granulocyte-macrophage-megakaryocyte (GEMM-CFU) and burst-forming unit-erythroid (BFU-E) were significantly increased in bone marrow cells in comparison to mice treated with CTX only. These results suggest a central role of sOGP10-14 in bone and bone marrow interaction, and a possible role of sOGP10-14 as a mobilizing agent.     

Transplantation of human acute myeloid leukemia (AML) cells in immunodeficient mice reveals altered cell surface phenotypes and expression of human endothelial markers

To better characterize acute myeloid leukemia (AML) development in non-obese diabetic (NOD)/severe combined immunodeficiency (SCID) mice, we transplanted samples from patients with AML or KG-1 and EOL-1 cell lines. We found 9/12 primary AML samples and both cell lines to engraft within 2-8 weeks, with 5-80% human cells in bone marrow. Compared with freshly isolated AML cells, percentages of human CD33+, CD38+, CD31+ CD13+ or CD15+ subpopulations increased after transplantation, whereas percentages of CD34+ cells decreased. Engrafted mice frequently showed expression of human endothelial cell markers. Thus, transplantation of human AML into NOD/SCID mice reveals expression of hematopoietic and endothelial differentiation markers.     

Lymphatic and vascular origin of Kaposi's sarcoma spindle cells during tumor development

The histogenesis of Kaposi's sarcoma (KS) tumor spindle cells (SC) remains controversial but several immunohistochemical studies favor a lymphatic origin. Twenty KS surgical biopsies were analyzed for the coexpression of LANA, CD34, LYVE-1, D2-40, VEGFR-2, VEGFR3 by using double or triple immunostaining. Most of the SC in both early and late KS expressed the lymphatic markers LYVE-1, D2-40 and VEGFR-3 and the blood vascular endothelial/endothelial precursor cell markers CD34 and endothelial stem cell marker VEGFR-2. All the LANA+ SC in early and late KS were LYVE-1+, but only 75% of these LANA+ cells were CD34(+). The CD34(+)/LANA+ cells increased from early- (68.8%) to late-stage KS (82.2%). However, approximately 18% of the LANA+ SC in early KS were CD34(-) but were LYVE-1+, suggesting that resident lymphatic endothelial cells (LEC) are targeted for primary infection by human herpesvirus-8. This LANA+/LYVE-1+/CD34(-) (resident LEC) cell population clearly decreased during the development of KS from early (18.7%) to late KS (2.9%). Thus, in late stages of KS, most SC were LANA+/CD34(+)/LYVE-1+. However, in both early- and late-stage KS, approximately 18% of the SC were CD34(+)/LANA-/LYVE-1 -- and could represent newly recruited endothelial precursor cells, which become infected in the lesion and eventually undergo a phenotype switch expressing LEC markers. Our study apparently indicates that KS represents a unique variant of tumor growth with continues recruitment of tumor precursor cells as well as proliferation and decreased apoptosis of SC.     

Inhibition of accelerated tumor growth by blocking the recruitment of mobilized endothelial progenitor cells after chemotherapy

It has been suggested that immature progenitor cells mobilize from bone marrow into the peripheral blood in response to the chemotherapy‐induced myelosuppression. We investigated how the mobilization of immature progenitor cells affects tumor growth after chemotherapy. We found significantly increased numbers of CD34⁺/Flk‐1⁺ endothelial progenitor cells in the peripheral blood of mice 1 week after the administration of 100 mg/kg cyclophosphamide vs. a saline injection (0.39 ± 0.09% vs. 0.20 ± 0.10%, respectively; p < 0.05). Tumor growth in the mice given chemotherapy was almost 1.3‐fold faster than that in the mice given saline (268 ± 66 mg vs. 210 ± 3 5 mg, respectively; p < 0.05). Histological examination of tumor tissue revealed significantly higher microvessel density and more Ki67‐positive cells, but significantly fewer apoptotic cells, in the mice given chemotherapy than in those given saline (p < 0.05). Furthermore, we detected significantly more bone marrow‐derived cells, some of which stained positively for CD34 and were localized in the vessels, in tumor tissue from the mice given chemotherapy than in that from the mice given saline. However, the transient disruption of the SDF‐1/CXCR4 axis by the antibody neutralization of CXCR4, which occurred over 1 week, blocked the recruitment of bone marrow‐derived cells into the tumor tissue, and resulted in complete inhibition of accelerated tumor growth after chemotherapy. Our results show that chemotherapy induced the mobilization of endothelial progenitor cells and accelerated tumor growth, but that transient disruption of the SDF‐1/CXCR4 axis could prevent accelerated tumor growth by blocking the recruitment of mobilized endothelial progenitor cells after chemotherapy. © 2008 Wiley‐Liss, Inc.     

反向聚合酶链式反应测定Ewing肉瘤患者骨髓微小残留病变

目的　建立以EWS FLI 1融合基因为标志 ,用反向聚合酶链式反应 (PCR)测定骨髓Ewing肉瘤细胞的体系。方法　用RPMI 16 40培养液培养Ewing肉瘤T1细胞系 ,将其与正常人骨髓单个核细胞按比例混合 ,使T1细胞浓度依次为 10 0 % ,10 -3 ,10 -4 ,10 -5,10 -6,10 -7,0 ,提取总RNA ,合成cDNA ,PCR扩增EWS FLI 1;同时选择 5例骨髓转移的Ewing肉瘤患者 ,测定诊断时及缓解后骨髓EWS FLI 1融合基因。结果　T1细胞浓度为 10 0 % ,10 -3 ～ 10 -6时 ,EWS FLI 1均阳性 ;10 -7及 0时阴性。 5例患者诊断时骨髓EWS FLI 1均阳性 ,完全缓解后 2例转阴。结论　以EWS FLI 1融合基因为标志的反向PCR测定骨髓Ewing肉瘤细胞的灵敏度为 10 -6,它是测定骨髓Ewing肉瘤细胞高度敏感的方法 ;Ewing肉瘤患者完全缓解时 ,部分患者骨髓仍存在肿瘤细胞。