Anthrax, Matrix Biology, and Angiogenesis: Capillary Morphogenesis Gene 2 Mediates Activity and Uptake of Type IV Collagen-Derived Anti-Angiogenic Peptides

Finnell, Jordan Grant

01 June 2017

Capillary Morphogenesis Gene 2 (CMG2) is a type I transmembrane, integrin-like receptor. It was originally identified as one of several genes upregulated during capillary formation. It was subsequently identified as one of two physiological anthrax toxin receptors, where CMG2 serves as a cell-surface receptor for anthrax toxin and mediates entry of the toxin into cells via clathrin-dependent endocytosis. Additionally, loss-of-function mutations in CMG2 cause the genetic disorder hyaline fibromatosis syndrome (HFS), where the core symptom is dysregulation of extracellular matrix homeostasis (ECM), including excessive accumulation of proteinaceous hyaline material; HFS clearly indicates that CMG2 plays an essential function in ECM homeostasis and repair. Most often, these situational roles have been evaluated as separate intellectual and experimental entities; consequently, whereas details have emerged for each respective situational role, there has been little attempt to synthesize knowledge from each situational role in order to model a holistic map of CMG2 function and mechanism of action in normal physiology.The work presented in this thesis is an example of such a synthesis. Interactions between CMG2 and type IV collagen (Col IV) were evaluated, to better understand this putative interaction and its effect on CMG2 function in angiogenesis. Using an overlapping library peptide array of the Col IV α1 and α2 chains, it was found that CMG2-binding peptides were enriched within the NC1 domains. This finding was corroborated via another epitope mapping peptide array, where we found a major epitope for CMG2-binding within the α2 NC1 domain (canstatin). Identification of CMG2 interactions with Col IV NC1 domains (including canstatin) was both surprising and intriguing, as these domains are potent endogenous inhibitors of angiogenesis. To further evaluate the physiological relevance of interactions with Col IV NC1 domains, a canstatin-derived peptide from the original array was synthesized and used for further studies. This peptide (here known as S16) binds with high affinity (KD = 440 ± 160 nM) to the extracellular, ligand-binding CMG2 vWA domain; specificity was confirmed through competition studies with anthrax toxin PA, and through demonstration of divalent cation-dependent binding. CMG2 was found to be the relevant endothelial receptor for S16. CMG2 in fact mediates endocytic uptake of peptide S16, as demonstrated by flow cytometry, and colocalization studies. S16 further inhibits migration of endothelial cells. These findings demonstrate that CMG2 is a functional receptor for Col IV NC1 domain fragments. CMG2 may exert a pro-angiogenic effect through endocytosis and clearance of anti-angiogenic NC1 domain fragments. Additionally, this is the first demonstration of CMG2-mediated uptake of an endogenous matrix fragment, and suggests a mechanism by which CMG2 regulates ECM and basement membrane homeostasis, thereby establishing a functional connection between the receptor's role in matrix biology and angiogenesis.

angiogenesis

CMG2/ANTXR2

matrix biology

peptide array

type IV collagen

Biochemistry

Inhibition of Cell Adhesion and Actin Localization During Migration Upon Protective Antigen Mutant Ligand Binding to the Capillary Morphogenesis Gene 2

Lee, Sai Lun

15 April 2022

Capillary Morphogenesis Gene 2 protein (CMG2) is a type 1 transmembrane receptor known as the anthrax toxin receptor 2 (ANTXR2). While it is documented that the cell surface receptor CMG2 mediates anthrax toxin entry into the cell via endocytosis, the physiological role of CMG2 is not well understood. Others have suggested that CMG2 may have a role in mediating ECM homeostasis and angiogenesis. Additionally, both anthrax protective antigen (PA) and a furin protease-resistant mutant, PASSSR, inhibit corneal neovascularization in a mouse model, and interestingly PASSSR has a greater affinity to CMG2 receptor. PASSSRalso has a more potent antiangiogenic effect than wild-type PA. However, a mechanism for PASSSR inhibition of the putative CMG2 role in angiogenesis is not yet elucidated. The experimental results in this thesis provide evidence that CMG2 is the key receptor for regulating adhesion, migration, and actin dynamics in cells, and 200-pM PASSSR inhibits cell adhesion, migration, and actin localization at the cell leading edge. Furthermore, we observed that PASSSR remains bound to CMG2 under acidic conditions similar to the lysosome (pH 4). This observation suggests that the PASSSR-CMG2 complex remains intact following internalization and traffic to lysosomes, different from previous reports for PA, which likely results in CMG2 recycling. Together, these results suggest that following PASSSR treatment, CMG2 traffics to the lysosome for degradation; hence, we predict fewer CMG2 receptors are available at the cell surface to function in their native role in signaling angiogenic processes such as adhesion and chemotaxis towards vascular growth factors.

Angiogenesis

CMG2

Cell Adhesion

Cell migration

Actin dynamics

Physical Sciences and Mathematics

Capillary Morphogenesis Gene Protein 2 (CMG2) Mediates Matrix Protein Uptake and is Required for Endothelial Cell Chemotaxis in Response to Multiple Vascular Growth Factors

Tsang, Tsz Ming Jeremy

09 April 2020

Pathological angiogenesis, or new blood vessel formation, is involved in many pathologies, including cancer and serious eye diseases. While traditional anti-angiogenic therapies target vascular endothelial growth factor receptors to reduce or inhibit new vessel formation, this approach has several downsides, including unpleasant side effects and low efficacy over time. Therefore, identifying new targets to treat pathological angiogenesis is still needed. CMG2, one of the two identified anthrax toxin receptors, has been proposed as an alternative target to treat pathological angiogenesis. CMG2’s role as a cell surface receptor that mediates anthrax toxin internalization is very well documented. One physiological function for CMG2, not related to anthrax intoxication, is suggested by the observation that loss-of-function mutations in CMG2 cause hyaline fibromatosis syndrome (HFS), a genetic disease that results in accumulations of extra-cellular matrix (ECM) protein in different parts of the body. While the complete molecular mechanism for CMG2’s role in regulating angiogenesis has not been determined, this dissertation addresses multiple ways CMG2 regulates pathological angiogenesis. We have discovered that CMG2 plays a role in mediating ECM homeostasis via endocytosis of ECM proteins and protein fragments as a way to generate angiogenic signals from the cell. We have also demonstrated that a fragment from Col IV, S16, is endocytosed into the cells by interacting with CMG2, and S16 treatment to endothelial cells leads to a significant reduction in cell migration. Also, an endothelial cell migration assay with CMG2 knockout cells results in abolished directional migration, indicating that CMG2 is required for endothelial cell chemotaxis. Notably, we have identified that bFGF, VEGF, and PDGF are involved in CMG2 mediated chemotaxis but not insulin and sphingosine-1-phosphate (S1P). While recent literature reports show that CMG2 works closely with RhoA GTPase, which is commonly known to regulate cell migration, we have also observed that inhibition of RhoA also reduced cell chemotaxis towards VEGF but not S1P. These results could be leveraged to develop new classes of therapeutic molecules to treat pathological angiogenesis induced by multiple various growth factors via targeting CMG2.

capillary morphogenesis gene 2 (CMG2)

pathological angiogenesis

extracellular matrix

growth factors

chemotaxis

RhoA GTPase

Physical Sciences and Mathematics