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This protocol presents a novel in vitro bead assay that more appropriately models the process of in vivo sprouting angiogenesis by incorporating pericytes. This modification enables the bead assay to more faithfully recapitulate the heterotypic cellular interactions between endothelial cells and mural cells that are critical for angiogenesis.
Angiogenesis is the growth of new vessels from pre-existing vasculature and is an important component of many biological processes, including embryogenesis and development, wound healing, tumor growth and metastasis, and ocular and cardiovascular diseases. Effective in vitro models that recapitulate the biology of angiogenesis are needed to appropriately study this process and identify mechanisms of regulation that can be ultimately targeted for novel therapeutic strategies. The bead angiogenesis assay has been previously demonstrated to recapitulate the multiple stages of endothelial sprouting in vitro. However, a limitation of this assay is a lack of endothelial – mural cell interactions, which are key to the molecular and phenotypic regulation of endothelial cell function in vivo. The protocol given here presents a methodology for the incorporation of mural cells into the bead angiogenesis assay and demonstrates a tight association of endothelial cells and pericytes during sprouting in vitro. The protocol also details a methodology for effective silencing of target genes using siRNA in endothelial cells for mechanistic studies. Altogether, this protocol provides an in vitro assay that more appropriately models the diverse cell types involved in sprouting angiogenesis, and provides a more physiologically-relevant platform for therapeutic assessment and novel discovery of mechanisms of angiogenesis regulation.
Angiogenesis is vital to appropriate embryogenesis and wound healing, and it also plays key roles in numerous diseases including cancer progression1 and coronary artery disease.2,3 Having a better understanding of how angiogenesis occurs during normal development, and how it is reactivated in pathologic contexts, is critical for the development of novel, effective therapeutics. Faithful in vitro models that recapitulate the important stages and cell types involved in angiogenesis in vivo are needed to allow researchers to better characterize the molecular mechanisms dr....
Day 1:
1. Transient Transfection of Endothelial Cells
This protocol allows for a tight association of the two cell types in vitro, and the presence of the pericytes complements the occurrence of sprouting (Figure 1A, B). The protocol also enables effective silencing (e.g. via RNA interference) of a gene of interest in a cell type of interest (such as VEGFA specifically in endothelial cells or PDGFRβ in pericytes)7,12
This protocol presents a method for characterizing the complex stages and heterotypic cellular interactions of sprouting angiogenesis by enabling the researcher to employ genetic and imaging approaches to conduct thorough mechanistic investigations. When performing the assay, it is essential that efficient endothelial coating of the beads takes place during the bead agitation steps. Poor endothelial coating will be made evident, if the beads do not appear to have a golf ball-like rough surface the next morning prior to g.......
We thank Drs. Victoria Bautch and Joshua Boucher for helpful discussions and advice on optimizing standard bead sprouting assay conditions and a sprouting assay staining protocol. S.H.A. was supported in part by a grant from the National Institute of General Medical Sciences under award 5T32 GM007092.
....Name | Company | Catalog Number | Comments |
Sterile Pipette tips | VWR | ||
Pipettors | Eppendorf | ||
Complete EGM2 Media Bullet Kit | Lonza | CC-3162 | HUVEC Media |
MEM | Gibco | 11095114 | 10T1/2 Media |
DMEM | Gibco | 11965118 | NHLF Media |
Tissue culture-grade PBS | Gibco | 14190-144 | Magnesium and calcium free |
Accutase | Life Technologies | A1110501 | For lifting HUVEC |
Trypsin | Life Technologies | 15050065 | For lifting 10T 1/2 and NHLF |
Customs siRNAs | Sigma | ||
Lipofectamine RNAiMax | Life Technologies | 13778150 | |
HUVEC | Lonza | C2517A | |
10T 1/2 | ATCC | ||
NHLF | ATCC | ||
Cytodex 3 microcarrier beads | Sigma | C3275 | |
Tissue culture-coated 6 and 10 cm plates | Corning | ||
Fibrinogen from bovine plasma | Sigma | F8630 | |
Thrombin | Sigma | t9549 | |
Aprotinin | Sigma | a3428 | |
Falcon Round-Bottom Tubes | Corning | ||
Tissue culture incubator and hood | |||
24-well glass bottom plates | MatTek | P24G1.513F | Glass-bottom plates are needed only if the sprouts are going to be imaged. If not, tissue culture plastic is also acceptable. |
Sterile Filtration Device |
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