The vasculature plays a principal role in health and disease, by establishing stereotypical vessel organization to ensure proper tissue perfusion. Arteries carry blood from the heart to capillaries, successively reducing vessel caliber. Capillaries, the arterial-venous (AV) interface where exchange of nutrients and waste with tissues occurs, are by necessity the smallest diameter vessels. Post-capillary venules join successively wider veins to return blood to the heart. During development, Notch signaling has emerged as a critical mediator of AV specification during assembly of the first artery/vein pair from endothelial cells (ECs), by promoting arterial over venous EC fate. Notch gene expression is maintained in postnatal vascular endothelium, suggesting that Notch has a role in establishing and/or maintaining postnatal AV organization. Shortly after birth, the immature brain vasculature undergoes a dynamic period of morphogenesis, during which a refined organization of arteries/capillaries/veins forms from a primitive plexus of wide-bore AV connections. Currently, little is known about the genetic controls to ensure such AV organization in the brain. We hypothesize that Notch signaling governs AV organization in the immature mammalian cerebrovasculature, by dictating the allocation of individual ECs from immature AV connections to artery vs. vein.
In Aim 1, we hypothesize that individual ECs within the immature brain vascular plexus are allocated to artery vs. vein, thereby permitting vessel narrowing at the AV interface. Toward a comprehensive analysis of AV organization within the brain, we will: 1) examine, over time, AV marker expression in ECs within immature AV connections; 2) monitor EC migration in vivo.
In Aim 2, we hypothesize that loss of Notch promotes a venous program and increases EC allocation to the vein from immature AV connections in the brain. We will abrogate Notch signaling specifically in immature ECs and analyze the phenotypic consequences, as relate to AV marker expression and EC migration in the cerebrovasculature.
In Aim 3, we hypothesize that activated Notch promotes an arterial program and increases EC allocation to the artery from immature AV connections in the brain. We will activate Notch signaling specifically in immature vascular endothelium and assess phenotypic effects, as relate to AV marker expression and EC allocation to artery vs. vein. During this dynamic period of vessel narrowing and circuitry formation in the immature brain, the vasculature is particularly susceptible to aberrations and associated neurological impairments, underscoring the necessity for proper AV connectivity. These studies will provide molecular and cellular resolution toward the current view of postnatal cerebrovascular morphogenesis and open avenues for therapeutic application.

Public Health Relevance

Cerebrovascular disease, including stroke and arterial-venous malformations, often lead to devastating neurological dysfunction. Indeed, 50% of survivors of cerebrovascular disease experience neurological deficit, half of which require chronic care. Despite affecting millions of people worldwide, the mechanisms that trigger cerebrovascular disease remain poorly understood. Herein, we propose experiments to investigate the cellular and molecular mechanisms of mammalian cerebral angiogenesis (the growth of new blood vessels). The success of these studies will provide conceptual advances toward understanding the normal course of cerebral angiogenesis and fostering therapeutic advances for cerebrovascular disease.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Postdoctoral Individual National Research Service Award (F32)
Project #
4F32HL110724-03
Application #
8975791
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Meadows, Tawanna
Project Start
2013-12-01
Project End
2016-07-27
Budget Start
2015-12-01
Budget End
2016-07-27
Support Year
3
Fiscal Year
2016
Total Cost
Indirect Cost
Name
University of California San Francisco
Department
Surgery
Type
Schools of Medicine
DUNS #
094878337
City
San Francisco
State
CA
Country
United States
Zip Code
94118
Nielsen, Corinne M; Huang, Lawrence; Murphy, Patrick A et al. (2016) Mouse Models of Cerebral Arteriovenous Malformation. Stroke 47:293-300
Cuervo, Henar; Nielsen, Corinne M; Simonetto, Douglas A et al. (2016) Endothelial notch signaling is essential to prevent hepatic vascular malformations in mice. Hepatology 64:1302-1316
Murphy, Patrick A; Kim, Tyson N; Huang, Lawrence et al. (2014) Constitutively active Notch4 receptor elicits brain arteriovenous malformations through enlargement of capillary-like vessels. Proc Natl Acad Sci U S A 111:18007-12
Nielsen, Corinne M; Cuervo, Henar; Ding, Vivianne W et al. (2014) Deletion of Rbpj from postnatal endothelium leads to abnormal arteriovenous shunting in mice. Development 141:3782-92