The Role of Sox18 in Blood Vessel Development

Meredith Downes

Unknown Date

No description available.

Exploring the role of transmembrane 4 L six family member 1 (Tm4sf1) in the control of tip cell behaviour during sprouting angiogenesis

Page, Donna

January 2015

Angiogenesis is the process of new blood vessel sprouting from pre-existing vessels and is responsible for generating the majority of nascent vessels during development, tissue regeneration and disease. During angiogenesis, sprouting endothelial cells (ECs) are organised into leading 'tip' cells (TCs) and trailing 'stalk' cells (SCs). This hierarchal organisation of TCs and SCs is essential for the coordinated collective migration of ECs during sprouting. However, the precise mechanisms that define TC verses SC behaviour and identity remains uncertain. Transcriptomic analysis of sprouting vessels in zebrafish embryos led to the identification of a novel TC-associated gene, transmembrane 4 L six family member 1 (tm4sf1). We find that tm4sf1 expression is tightly spatiotemporally restricted to migrating TCs during intersegmental vessel (ISV) sprouting in zebrafish. Furthermore, TC tm4sf1 expression is controlled by the vascular endothelial growth factor receptor (Vegfr) - Notch signalling axis. Morpholino oligonucleotide (MO)-mediated knockdown of tm4sf1 reveals a subtle delay in ISV sprouting upon loss of tm4sf1 expression. Moreover, using multiplexed, real-time imaging approaches and in-depth analysis of TC and SC behaviours at single cell resolution, we reveal that the delay in ISV sprouting is specifically due to reduced TC motility. Furthermore, we find that tm4sf1 functions to induce TC motility in the leading daughter cell following TC mitosis, to rapidly re-establish post-mitotic TC behaviour. Generation of tm4sf1 mutant zebrafish lines using both transcription activator-like effector nucleases (TALENs) and clustered regularly interspaced short palindromic repeats (CRISPR) confirms that Tm4sf1 modulates TC behaviour. Additionally, mechanistic studies in human ECs reveal that tm4sf1 regulates VEGFR-mediated signalling upon VEGF-stimulation, which subsequently controls cell migration and expression of the TC determinants, DLL4 and VEGFR2. Hence, our results suggest that tm4sf1 is a novel modulator of the TC-SC hierarchy and collective EC migration during ISV sprouting. Overall, these findings have potential therapeutic implications since tm4sf1 may be a promising target for the manipulation of pathological angiogenesis in disease.

612.1

Early Vessel Evolution and the Diversification of Wood Function: Insights from the Malagasy Canellales

Hudson, Patrick Joseph

01 May 2010

Xylem vessels have long been proposed as a key innovation for the ecological diversification of angiosperms by providing a breakthrough in hydraulic efficiency to support high rates of photosynthesis and growth. However, recent studies demonstrated that angiosperm woods with structurally ‘primitive’ vessels did not have greater whole stem hydraulic capacities as compared to vesselless angiosperms. As an alternative to the hydraulic superiority hypothesis, the heteroxylly hypothesis proposes that subtle hydraulic efficiencies of primitive vessels over tracheids enabled new directions of functional specialization in the wood. However, the functional properties of early heteroxyllous wood remain unknown. We selected the two species of Canellales from Madagascar to test the heteroxylly hypothesis because Canellaceae (represented by Cinnamosma madagascariensis) produces wood with vessels of an ancestral form, while Winteraceae, the sister-clade (represented by Takhtajania perrieri) is vesselless. We found that heteroxylly correlated with increased wood functional diversity related mostly to biomechanical specialization. However, vessels were not associated with greater stem hydraulic efficiency or increased shoot hydraulic capacity. Our results support the heteroxylly hypothesis and highlight the importance integrating a broader ecological context to understand the evolution of vessels.

Canellales

heteroxylly

xylem evolution

vessel development

Comparative and Evolutionary Physiology

Evolution

Plant Biology

Structural Biology

Early Vessel Evolution and the Diversification of Wood Function: Insights from the Malagasy Canellales

Hudson, Patrick Joseph

01 May 2010

Xylem vessels have long been proposed as a key innovation for the ecological diversification of angiosperms by providing a breakthrough in hydraulic efficiency to support high rates of photosynthesis and growth. However, recent studies demonstrated that angiosperm woods with structurally ‘primitive’ vessels did not have greater whole stem hydraulic capacities as compared to vesselless angiosperms. As an alternative to the hydraulic superiority hypothesis, the heteroxylly hypothesis proposes that subtle hydraulic efficiencies of primitive vessels over tracheids enabled new directions of functional specialization in the wood. However, the functional properties of early heteroxyllous wood remain unknown. We selected the two species of Canellales from Madagascar to test the heteroxylly hypothesis because Canellaceae (represented by <em>Cinnamosma madagascariensis</em>) produces wood with vessels of an ancestral form, while Winteraceae, the sister-clade (represented by <em>Takhtajania perrieri</em>) is vesselless. We found that heteroxylly correlated with increased wood functional diversity related mostly to biomechanical specialization. However, vessels were not associated with greater stem hydraulic efficiency or increased shoot hydraulic capacity. Our results support the heteroxylly hypothesis and highlight the importance integrating a broader ecological context to understand the evolution of vessels.

Canellales

heteroxylly

xylem evolution

vessel development

Comparative and Evolutionary Physiology

Evolution

Plant Biology

Structural Biology