Angiogenesis and lymphangiogenesis often occur in response to tissue injury or in the presence of pathology (e.g. cancer), and it is these types of environments in which macrophages are activated and increased in number. Moreover, the blood vascular microcirculation and the lymphatic circulation serve as the conduits for entry and exit for monocyte-derived macrophages in nearly every tissue and organ. Macrophages both affect and are affected by the vessels through which they travel. Therefore, it is not surprising that examination of macrophage behaviors in both angiogenesis and lymphangiogenesis has yielded interesting observations that suggest macrophages may be key regulators of these complex growth and remodeling processes. In this review, we will take a closer look at macrophages through the lens of angiogenesis and lymphangiogenesis, examining how their dynamic behaviors may regulate vessel sprouting and function. We present macrophages as a cellular link that spatially and temporally connects angiogenesis with lymphangiogenesis, in both physiological growth and in pathological adaptations, such as tumorigenesis. As such, attempts to therapeutically target macrophages in order to affect these processes may be particularly effective, and studying macrophages in both settings will accelerate the field’s understanding of this important cell type in health and disease.
Developing therapies aimed at manipulating microvascular remodeling requires a better understanding of angiogenesis and how angiogenesis relates to other network remodeling processes, such as lymphangiogenesis and neurogenesis. The objective of this study was to develop an angiogenesis model that enables probing of multicellular and multisystem interactions at the molecular level across an intact adult microvascular network. Adult male Wistar rat mesenteric windows were aseptically harvested and cultured in serum-free minimum essential media. Viability/cytotoxicity analysis revealed that cells remain alive for at least 7 days. Immunohistochemical labeling at 3 days for platelet endothelial cell adhesion molecule (PECAM), neuron-glial antigen 2 (NG2), lymphatic vessel endothelial hyaluronan receptor-1 (LYVE-1), and class III β-tubulin identified endothelial cells, pericytes, lymphatics, and nerves, respectively. Media supplemented with bFGF or VEGF induced an increase in endothelial cell sprouting off existing vessels. Endothelial cell sprouting in both growth factor groups was inhibited by targeting pericytes with NG2 functional blocking antibody. VEGF caused an increase in the number of lymphatic/blood endothelial cell connections compared with media alone or bFGF groups. Finally, the comparison of the same network before and after angiogenesis stimulated by the supplement of media with 20% serum identified the ability of disconnected endothelial segments to reconnect to nearby vessels. The results establish a novel in situ angiogenesis model for investigating the location of capillary sprouting within an intact network, the role of pericytes, lymphatic/blood endothelial cell interactions, and the fate of specific endothelial cell segments. The rat mesentery culture system offers a unique tool for understanding the complex dynamics associated with angiogenesis in an intact adult tissue.
While cancer cell invasion and metastasis is dependent on cancer cell-stroma, cancer cell-blood vessel, and cancer cell-lymphatic vessel interactions, our understanding of these interactions remain largely unknown. A need exists for physiologically-relevant models that more closely mimic the complexity of cancer cell dynamics in a real tissue environment. The objective of this study was to combine laser-based cell printing and tissue culture methods to create a novel ex vivo model in which cancer cell dynamics can be tracked during angiogenesis in an intact microvascular network. Laser direct-write (LDW) was utilized to reproducibly deposit breast cancer cells (MDA-MB-231 and MCF-7) and fibroblasts into spatially-defined patterns on cultured rat mesenteric tissues. In addition, heterogeneous patterns containing co-printed MDA-MB-231/fibroblasts or MDA-MB-231/MCF-7 cells were generated for fibroblast-directed and collective cell invasion models. Printed cells remained viable and the cells retained the ability to proliferate in serum-rich media conditions. Over a culture period of five days, time-lapse imaging confirmed fibroblast and MDA-MB-231 cell migration within the microvascular networks. Confocal microscopy indicated that printed MDA-MB-231 cells infiltrated the tissue thickness and were capable of interacting with endothelial cells. Angiogenic network growth in tissue areas containing printed cancer cells was characterized by significantly increased capillary sprouting compared to control tissue areas containing no printed cells. Our results establish an innovative ex vivo experimental platform that enables time-lapse evaluation of cancer cell dynamics during angiogenesis within a real microvascular network scenario.
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