1、Inducing Angiogenesis诱导血管生产Like normal tissues, tumors require sustenance(食物) in the form of nutrients and oxygen as well as an ability to evacuate metabolic wastes and carbon dioxide. The tumor-associated neovasculature, generated by the process of angiogenesis, addresses these needs. During embryo
2、genesis, the development of the vasculature involves the birth of new endothelial cells and their assembly into tubes (vasculogenesis) in addition to the sprouting (angiogenesis) of new vessels from existing ones. Following this morphogenesis, the normal vasculature becomes largely quiescent. In the
3、 adult, as part of physiologic processes such as wound healing and female reproductive cycling, angiogenesis is turned on, but only transiently. In contrast, during tumor progression, an angiogenic switch is almost always activated and remains on, causing normally quiescent vasculature to continuall
4、y sprout(萌芽) new vessels that help sustain expanding neoplastic growths (Hanahan and Folkman, 1996).就像其他正常的细胞一样,肿瘤需要营养供应,需要养分,同时也需要清除代谢垃圾和二氧化碳。肿瘤相关的血管生成保证了肿瘤的这一个特点。在胚胎形成过程中,血管的生存需要产生新的内皮细胞,然后将这些内皮细胞移入到小管当中,这一过程能促进新兴血管的表达。人体的血管系统基本上是静止的。在成年人当中,比如伤口愈合或者女性月经周期中,也会有新的血管生成,但是,这些血管产生只是一过性的。然而,在肿瘤形成过程中,血管生
5、成按钮持续性的被激活,而且一直保持激活的状态,导致静止的静脉形成转化为持续性的血管生成,从而保证肿瘤的血供。A compelling body of evidence indicates that the angiogenic switch is governed by countervailing factors that either induce or oppose angiogenesis (Baeriswyl and Christofori, 2009; Bergers and Benjamin, 2003). Some of these angiogenic regulators
6、are signaling proteins that bind to stimulatory or inhibitory cellsurface receptors displayed by vascular endothelial cells. The well-known prototypes of angiogenesis inducers and inhibitors are vascular endothelial growth factor-A (VEGF-A) and thrombospondin-1 (TSP-1), respectively. The VEGF-A gene
7、 encodes ligands that are involved in orchestrating new blood vessel growth during embryonic and postnatal development, and then in homeostatic survival of endothelial cells, as well as in physiological and pathological situations in the adult. VEGF signaling via three receptor tyrosine kinases (VEG
8、FR-13) is regulated at multiple levels, reecting this complexity of purpose. Thus, VEGF gene expression can by upregulated both by hypoxia and by oncogene signaling (Ferrara, 2009; Mac Gabhann and Popel, 2008; Carmeliet, 2005). Additionally, VEGF ligands can be sequestered in the extracellular matri
9、x in latent forms that are subject to release and activation by extracellular matrix-degrading proteases (e.g., MMP-9;Kessenbrock et al., 2010). In addition, other proangiogenic signals, such as members of the broblast growth factor (FGF) family, have been implicated in sustaining tumor angiogenesis
10、 when their expression is chronically upregulated (Baeriswyl and Christofori, 2009). TSP-1, a key counterbalance in the angiogenic switch, also binds transmembrane receptors displayed by endothelial cells and thereby evokes suppressive signals that can counteract proangiogenic stimuli (Kazerounian e
11、t al., 2008).一大堆的实验证实,血管生成按钮被一些因子控制,这些因子能够诱导或者抑制血管生成。这些调控血管生成的因子多半是一些信号蛋白,他们可以和内皮细胞上的一些刺激性受体或者抑制性受体相互结合,从而完成其生物学功能。经典的血管生成控制因子是内皮细胞生长因子 A(VEGF-A)和血小板反应蛋白 1(TSP-1),前者可以促进血管生成,后者可以抑制血管生成。VEGF-A 能够编码一些配体,这些配体可以在胚胎形成、产后发育过程中支持血管生成、维持内皮细胞自我平衡,并且在病理性、生理性的过程中展现一定的作用。VEGF-A 可以通过三种络氨酸激酶受体来完成信号传导,而且这一信号传导在多重水
12、平上有调控机制存在,表现出血管生成调控的复杂性。VEGF-A 的表达可以被缺氧和原癌基因信号的增加而过度表达。VEGF 的配体在细胞外基质中可以以一种潜在的形式被扣押,因此避免了释放和激活。这些扣押前体 VEGF 配体的介质包括 MMP-9 等,统称为细胞外基质降解蛋白酶 。此外,还有其他一些血管生成因子,比如说纤维母细胞生长因子家族(FGF),这个家族的蛋白在维持肿瘤细胞生存过程中异常重要,在肿瘤生长过程中,这个蛋白往往是高表达的。TSP-1 作为一个抗血管生成的物质,同样能够结合在跨膜受体上,从而完成抑制血管生成的作用。The blood vessels produced within t
13、umors by chronically activated angiogenesis and an unbalanced mix of proangiogenic signals are typically aberrant: tumor neovasculature is marked by precocious capillary sprouting, convoluted and excessive vessel branching, distorted and enlarged vessels, erratic blood ow, microhemorrhaging, leakine
14、ss, and abnormal levels of endothelial cell proliferation and apoptosis (Nagy et al., 2010; Baluk et al., 2005). Angiogenesis is induced surprisingly early during the multistage development of invasive cancers both in animal models and in humans. Histological analyses of premalignant, noninvasive le
15、sions, including dysplasias and in situ carcinomas arising in a variety of organs, have revealed the early tripping of the angiogenic switch (Raica et al., 2009; Hanahan and Folkman, 1996). Historically, angiogenesis was envisioned to be important only when rapidly growing macroscopic tumors had for
16、med, but more recent data indicate that angiogenesis also contributes to the microscopic premalignant phase of neoplastic progression, further cementing its status as an integral hallmark of cancer. The past decade has witnessed an astonishing outpouring of research on angiogenesis. Amid this wealth
17、 of new knowledge, we highlight several advances of particular relevance to tumor physiology.因为各种各样的血管信号的刺激,肿瘤内会产生很多的血管,这些血管常常是畸形的:他们的血管早熟、复杂、有过多的分支、扭曲、增大、有不稳定的血流,有血液渗出、出血,此外,这些血管的内皮细胞也处于一种不稳定的增生和凋亡过程中。不管在人类肿瘤还是在动物肿瘤中,血管生成在恶性肿瘤中很早就被诱导出来了,常常在肿瘤多阶段发展的极早期出现血管生成。研究那些早期的肿瘤、非侵袭性肿瘤的组织学特点,包括生长不良、原位癌,我们发现,在极
18、早期就有血管生成。以前认为,只有在肿瘤迅速发展的过程中,血管形成才非常重要。但是,现在的数据表明,血管生成在肿瘤早期也有一定的促进肿瘤发生的作用,这被当做是肿瘤发生的一个重要的特点。过去十年的研究已经着重体现在血管研究上了。我们着重强调肿瘤病理学当中的一些特点。Gradations of the Angiogenic Switch血管生成调控的层次学特点Once angiogenesis has been activated, tumors exhibit diverse patterns of neovascularization. Some tumors, including such h
19、ighly aggressive types as pancreatic ductal adenocarcinomas, are hypovascularized and replete with stromal deserts that are largely avascular and indeed may even be actively antiangiogenic (Olive et al., 2009). Many other tumors, including human renal and pancreatic neuroendocrine carcinomas, are hi
20、ghly angiogenic and consequently densely vascularized (Zee et al.,2010; Turner et al., 2003).Collectively, such observations suggest an initial tripping of the angiogenic switch during tumor development that is followed by a variable intensity of ongoing neovascularization, the latter being controll
21、ed by a complex biological rheostat that involves both the cancer cells and the associated stromal microenvironment (Baeriswyl and Christofori, 2009; Bergers and Benjamin, 2003). Of note, the switching mechanism can vary in its form,even though the net result is a common inductive signal (e.g.,VEGF)
22、. In some tumors, dominant oncogenes operating within tumor cells, such as Ras and Myc, can upregulate expression of angiogenic factors, whereas in others, such inductive signals are produced indirectly by immune inammatory cells, as discussed below. The direct induction of angiogenesis by oncogenes
23、 that also drive proliferative signaling illustrates the important principle that distinct hallmark capabilities can be coregulated by the same transforming agents. 一旦肿瘤中的血管生成机制被激活,肿瘤就会展现出各种各样的血管生成。一些肿瘤(包括胰腺胆管细胞腺癌)是乏血管的,而且有一些细胞外基质是压根没有血管的,这些基质甚至有抗血管生存的作用。然而,其他的肿瘤,病比如说肾脏肿瘤、胰腺神经内分泌肿瘤却是高度血管化的,而且,他们的血管很
24、密集。这表明,在不同的肿瘤形成过程中,早期的血管生成信号会在后来被各种各样的血管形成机制取代,而这种取代是被可种各样的复杂的机制调控的,这些调控涉及到肿瘤细胞,也涉及到基质微环境。也就是说,血管生成机制尽管有着类似的开始,但是后来却会分道扬镳。一些原癌基因,比如说 Ras 和 Myc,他们在肿瘤形成过程中能够上调血管刺激因子。在其他一些情况下,炎症细胞能够协助肿瘤细胞促进血管生成。原癌基因直接刺激血管生成这一机制证明了这样一个结论:肿瘤的各种特点之间可以通过共同的转录因子相互协调。Endogenous Angiogenesis Inhibitors Present Natural Barrie
25、rs to Tumor Angiogenesis内生性的血管生成物质抑制剂是一种天然的血管生成抑制物Research in the 1990s revealed that TSP-1 as well as fragments of plasmin (angiostatin) and type 18 collagen (endostatin) can act as endogenous inhibitors of angiogenesis (Ribatti, 2009; Kazerounian, et al., 2008; Folkman, 2006, 2002; Nyberg et al.,2
26、005). The last decade has seen reports of another dozen such agents (Ribatti, 2009; Folkman, 2006; Nyberg et al.,2005). Most are proteins, and many are derived by proteolytic cleavage of structural proteins that are not themselves angiogenic regulators. A number of these endogenous inhibitors of ang
27、iogenesis can be detected in the circulation of normal mice and humans.上世纪 90 年代的研究就已经证实, TSP-1 和胞浆素、18 型胶原(内皮抑制素)的片段可以被当做内生性的血管生成抑制物质。过去 10 年又陆续发现了很多的这些相似的物质。他们大多数是蛋白质,部分来自于蛋白水解酶水解一些蛋白得到的片段,也就是说,他们本来或许根本就不是一种调控因子。这些抑制物质可以从正常人、正常大鼠的血液中找到。The genes encoding several endogenous angiogenesis inhibitors
28、have been deleted from the mouse germline without untoward physiological effects; the growth of autochthonous and implanted tumors, however, is enhanced as a consequence (Ribatti, 2009; Nyberg et al., 2005). 编码内生性血管抑制物的基因已经从无繁殖功能的老鼠中找到了。通过研究,我们发现,移植的肿瘤或者原发性的肿瘤在这些老鼠中是增加的。By contrast, if the circulati
29、ng levels of an endogenous inhibitor are genetically increased (e.g., via overexpression in transgenic mice or in xenotransplanted tumors), tumor growth is impaired (Ribatti, 2009; Nyberg et al., 2005); interestingly, wound healing and fat deposition are impaired or accelerated by elevated or ablate
30、d expression of such genes (Cao, 2010; Seppinen et al., 2008). The data suggest that such endogenous angiogenesis inhibitors serve under normal circumstances as physiologic regulators that modulate transitory angiogenesis during tissue remodeling and wound healing; they may also act as intrinsic bar
31、riers to induction(感应) and/or persistence of angiogenesis by incipient neoplasias. 可以看出来,当血液中的这些物质增加的时候,肿瘤的生长就会被抑制。当然,伤口的愈合和脂肪的沉积随着这些基因的表达而有相应的变化。这表明,这些血管生长抑制物质在正常机体中起到一定的生理性作用,可以调控伤口愈合和机体修复系统。他们同事可以被当作Pericytes Are Important Components of the Tumor Neovasculature Pericytes have long been known as s
32、upporting cells that are closely apposed to the outer surfaces of the endothelial tubes in normal tissue vasculature, where they provide important mechanical and physiologic support to the endothelial cells. Tumor-associated vasculature, in contrast, was portrayed as lacking appreciable coverage by
33、these auxiliary cells. However, careful microscopic studies conducted in recent years have revealed that pericytes are associated, albeit loosely, with the neovasculature of most if not all tumors (Raza et al., 2010; Bergers and Song, 2005). More importantly, mechanistic studies discussed below have
34、 revealed that pericyte coverage is important for the maintenance of a functional tumor neovasculature. A Variety of Bone Marrow-Derived Cells Contribute to Tumor AngiogenesisIt is nowclear that a repertoire of cell types originating in the bone marrow play crucial roles in pathological angiogenesis
35、 (Qian and Pollard, 2010; Zumsteg and Christofori, 2009; Murdoch et al., 2008; De Palma et al., 2007). These include cells of the innate immune systemnotablymacrophages, neutrophils,mast cells, and myeloid progenitorsthat inltrate premalignant lesions and progressed tumors and assemble at the margin
36、s of such lesions; the peri-tumoral inammatory cells help to trip the angiogenic switch in previously quiescent tissue and to sustain ongoing angiogenesis associated with tumor growth, in addition to facilitating local invasion, as noted below. In addition, they can help protect the vasculature from
37、 the effects of drugs targeting endothelial cell signaling (Ferrara, 2010). Additionally, several types of bone marrow-derived vascular progenitor cells have been observed in certain cases to have migrated into neoplastic lesions and become intercalated into the neovasculature as pericytes or endoth
38、elial cells (Patenaude et al., 2010; Kovacic and Boehm, 2009; Lamagna and Bergers, 2006). Activating Invasion and Metastasis In 2000, the mechanisms underlying invasion and metastasis were largely an enigma. It was clear that as carcinomas arising from epithelial tissues progressed to higher patholo
39、gical grades of malignancy, reected in local invasion and distant metastasis,the associated cancer cells typically developed alterations in their shape as well as in their attachment to other cells and to the extracellular matrix (ECM). The best characterized alteration involved the loss by carcinom
40、a cells of E-cadherin, a key cell-to-cell adhesion molecule. By forming adherens junctions with adjacent epithelial cells, E-cadherin helps to assemble epithelial cell sheets and maintain the quiescence of the cells within these sheets. Increased expression of E-cadherin was well established as an a
41、ntagonist of invasion and metastasis, whereas reduction of its expressionwas known to potentiate these phenotypes. The frequently observed downregulation and occasional mutational inactivation of E-cadherin in human carcinomas provided strong support for its role as a key suppressor of this hallmark
42、 capability (Berx and van Roy, 2009; Cavallaro and Christofori, 2004). Additionally, expression of genes encoding other cell-to-cell and cell-to-ECM adhesion molecules is demonstrably altered in some highly aggressive carcinomas, with those favoring cytostasis typically being downregulated. Converse
43、ly, adhesion molecules normally associated with the cell migrations that occur during embryogenesis and inammation are often upregulated. For example, N-cadherin, which is normally expressed in migrating neurons and mesenchymal cells during organogenesis, is upregulated in many invasive carcinoma ce
44、lls. Beyond the gain and loss of such cell-cell/matrix attachment proteins, the master regulators of invasion and metastasis were largely unknown or, when suspected, lacking in functional validation(Cavallaro and Christofori, 2004). The multistep process of invasion and metastasis has been schematiz
45、ed as a sequence of discrete steps, often termed the invasion-metastasis cascade (Talmadge and Fidler, 2010; Fidler,2003). This depiction envisions a succession of cell-biologic changes, beginning with local invasion, then intravasation by cancer cells into nearby blood and lymphatic vessels, transi
46、t of cancer cells through the lymphatic and hematogenous systems, followed by escape of cancer cells from the lumina of such vessels into the parenchyma of distant tissues (extravasation),the formation of small nodules of cancer cells (micrometastases), and nally the growth of micrometastatic lesion
47、s into macroscopic tumors, this last step being termed colonization. Research into the capability for invasion and metastasis has accelerated dramatically over the past decade as powerful new research tools and rened experimental models have become available, and as critical regulatory genes were id
48、entied. While still an emerging eld replete with major unanswered questions, signicant progress has been made in delineating mportant features of this complex hallmark capability. An admitedly incomplete representation of these advances is highlighted below. The EMT Program Broadly Regulates Invasio
49、n and Metastasis A developmental regulatory program, referred to as the epithelial-mesenchymal transition (EMT), has become prominently implicated as a means by which transformed epithelial cells can acquire the abilities to invade, to resist apoptosis, and to disseminate (Klymkowsky and Savagner, 2009; Polyak and Weinberg, 2009; Thiery et al., 2009; Yilmaz and Christofori,2009; Barrallo-Gimeno and Nieto, 2005). By co-opting a process involved in various steps of embryonic morphogenesis and wound healing, carcinoma cells can concomitantly acquire multiple at
