Bioengineering human microvascular networks in immunodeficient mice

The future of tissue engineering and cell-based therapies for tissue regeneration will likely rely on our ability to generate functional vascular networks in vivo. In this regard, the search for experimental models to build blood vessel networks in vivo is of utmost importance. The feasibility of bioengineering microvascular networks in vivo was first shown using human tissue-derived mature endothelial cells (ECs); however, such autologous endothelial cells present problems for wide clinical use, because they are difficult to obtain in sufficient quantities and require harvesting from existing vasculature. These limitations have instigated the search for other sources of ECs. The identification of endothelial colony-forming cells (ECFCs) in blood presented an opportunity to non-invasively obtain ECs (5-7). We and other authors have shown that adult and cord blood-derived ECFCs have the capacity to form functional vascular networks in vivo. Importantly, these studies have also shown that to obtain stable and durable vascular networks, ECFCs require co-implantation with perivascular cells. The assay we describe here illustrates this concept: we show how human cord blood-derived ECFCs can be combined with bone marrow-derived mesenchymal stem cells (MSCs) as a single cell suspension in a collagen/fibronectin/fibrinogen gel to form a functional human vascular network within 7 days after implantation into an immunodeficient mouse. The presence of human ECFC-lined lumens containing host erythrocytes can be seen throughout the implants indicating not only the formation (de novo) of a vascular network, but also the development of functional anastomoses with the host circulatory system. This murine model of bioengineered human vascular network is ideally suited for studies on the cellular and molecular mechanisms of human vascular network formation and for the development of strategies to vascularize engineered tissues.     

Functional characterization of SAG/RBX2/ROC2/RNF7, an antioxidant protein and an E3 ubiquitin ligase

SAG (Sensitive to Apoptosis Gene), also known as RBX2 (RING box protein 2), ROC2 (Regulator of Cullins 2), or RNF7 (RING Finger Protein 7), was originally cloned in our laboratory as a redox inducible antioxidant protein and later characterized as the second member of the RBX/ROC RING component of the SCF (SKP1-CUL-F-box Proteins) E3 ubiquitin ligase. When acting alone, SAG scavenges oxygen radicals by forming inter- and intra- molecular disulfide bonds, whereas by forming a complex with other components of the SCF E3 ligase, SAG promotes ubiquitination and degradation of a number of protein substrates, including c-JUN, DEPTOR, HIF-1α, IκBα, NF1, NOXA, p27, and procaspase-3, thus regulating various signaling pathways and biological processes. Specifically, SAG protects cells from apoptosis, confers radioresistance, and plays an essential and non-redundant role in mouse embryogenesis and vasculogenesis. Furthermore, stress-inducible SAG is overexpressed in a number of human cancers and SAG overexpression correlates with poor patient prognosis. Finally, SAG transgenic expression in epidermis causes an early stage inhibition, but later stage promotion, of skin tumorigenesis triggered by DMBA/TPA. Given its major role in promoting targeted degradation of tumor suppressive proteins, leading to apoptosis suppression and accelerated tumorigenesis, SAG E3 ligase appears to be an attractive anticancer target.     

Primitive endothelial cell lines from the porcine embryonic yolk sac

Endothelial cell lines have been established from cells that were isolated from porcine yolk sacs from day 18 and day 22 embryos and propagated in vitro under various growth conditions. After expansion in vitro, the general properties of the cells proved similar for the different media used. The endothelial cells expressed cell surface receptors for acetylated low-density lipoprotein and also expressed cell surface-associated angiotensin-converting enzyme. The cells showed a characteristically high level of binding for Bandeiraea simplicifolia lectin I and Dolichos biflorus agglutinin but did not bind significant amounts of Ulex europaeus lectin I. The cells expressed low but serologically detectable levels of Class I major histocompatibility complex (MHC) antigens but failed to bind antibodies directed against Class II MHC antigens. Alpha5beta1 integrins were weakly expressed, whereas vascular cell adhesion molecule-1 (CD106) and alphavbeta3 integrins were not detected. Three-dimensional tube formation was readily observed in cultures grown on Matrigel and occurred even in uncoated plastic dishes in the absence of Matrigel. In contrast to most of the adult porcine endothelial cells, yolk sac-derived endothelial cells did not possess serologically detectable receptors for porcine growth hormone (GH), an observation consistent with the finding that GH did not increase the proliferative rate of these cells. Electron microscopic examination demonstrated the presence of Weibel-Palade bodies, tight endothelial cell junctions, and typical rough endoplasmic reticulum. Exposure of the cells to either concanavalin-A-stimulated porcine splenocyte culture supernatants or to human tumor necrosis factor alpha did not cause upregulation of VCAM-1 or Class II MHC antigens. Addition of porcine interferon-gamma led to an increase in the level of expression of Class I MHC. Yolk sac endothelial cells from day 22 embryos showed a low but detectable level of expression of Class II MHC antigens, whereas the endothelial cells from day 18 embryos showed no expression of Class II antigens after interferon-gamma stimulation. The cells maintained competence to develop vascular structures in vitro and could do so after coinjection with murine tumor cells into adult, immunocompromised mice.     

Endothelial progenitor cells: A source for therapeutic vasculogenesis?

Angiogenesis has been defined as sprouting of blood vessels from pre-existing vascular structures. Risau and co-workers defined the term vasculogenesis while studying the formation of new blood vessels in embryoid bodies. This process is characterized by the recruitment of endothelial progenitor cells (EPC) to sites of new vessel formation with subsequent differentiation of EPC into mature endothelial cells, extensively proliferating in situ. Data from recent years provided evidence that EPC also exist in the adult and contribute to new vessel formation, a process called post-natal vasculogenesis. The existence of EPC has been convincingly shown in both, animals and humans. They represent a perfect cellular progenitor cell population for the ex vivo generation of EC, which in turn serve as cellular source for therapeutic vasculogenesis or tumor targeting. This review provides an overview on this hot topic of cellular-based therapeutic concepts and the therapeutic potential of ex vivo generated EPC.     

心脏血管的形成

心脏的血 管 形成 是 血管 发生 (vasculogenesis)、血 管 生成 (angiogenesis)及 动 脉生 成 (arteriogenesis)三种 机制 共同 作 用的 结 果 .血管 发 生是 指在 胚 胎期 ,来 源 于中 胚 层的 干细 胞增 殖 和分 化 ,形 成 内皮 细胞 ,进而 与其 他细 胞形 成 原始 的 心血 管系 统 .血 管生 成 出现 在血 管 发生 之后 ,是指 通过 内 皮细 胞的 增 殖由 原始 血 管丛 或已 存在 的血 管 形成 无 完好 血管 的 膜中 的毛 细 血管 .而 动 脉生 成是 指 具有 完好 的 动脉 中膜 的 小动 脉 的生 成,也包 括原 有的 侧 支循 环 的改 建及 成 熟 .总结 了 出生 前后 心 脏脉 管系 统 形成 的细 胞 及分 子机 理 ,并 从生 物 学及 临床 治疗 上就 一 些内 皮 前体 细胞 及 其它 脉管 起 源相 关问 题 进行 简单 的 介绍 .     

神经迁移因子在血管系统中的表达与功能

神经迁移因子是近10年来在发育神经生物学中的研究热点,主要由ephrin、neuropilin、Slit和netrin四大家族成员构成,其主要功能是吸引或排斥神经元轴突的迁移,在神经系统中发挥着重要作用。现在,越来越多的实验证据表明：神经迁移因子的作用不仅仅局限在神经系统发育过程中,在血管发生或新生血管形成中同样具有不可替代的功能。     

Clock controls angiogenesis

Circadian rhythms control multiple physiological and pathological processes, including embryonic development in mammals and development of various human diseases. We have recently, in a developing zebrafish embryonic model, discovered that the circadian oscillation controls developmental angiogenesis. Disruption of crucial circadian regulatory genes, including Bmal1 and Period2, results in marked impairment or enhancement of vascular development in zebrafish. At the molecular level, we show that the circadian regulator Bmal1 directly targets the promoter region of the vegf gene in zebrafish, leading to an elevated expression of VEGF. These findings can reasonably be extended to developmental angiogenesis in mammals and even pathological angiogenesis in humans. Thus, our findings, for the first time, shed new light on mechanisms that underlie circadian clock-regulated angiogenesis.