Multicellular Tubes Research Articles

Endothelial Extracellular Matrix

The extracellular matrix (ECM) is critical for all aspects of vascular biology. In concert with supporting cells, endothelial cells (ECs) assemble a laminin-rich basement membrane matrix that provides structural and organizational stability. During the onset of angiogenesis, this basement membrane matrix is degraded by proteinases, among which membrane-type matrix metalloproteinases (MT-MMPs) are particularly significant. As angiogenesis proceeds, ECM serves essential functions in supporting key signaling events involved in regulating EC migration, invasion, proliferation, and survival. Moreover, the provisional ECM serves as a pliable scaffold wherein mechanical guidance forces are established among distal ECs, thereby providing organizational cues in the absence of cell-cell contact. Finally, through specific integrin-dependent signal transduction pathways, ECM controls the EC cytoskeleton to orchestrate the complex process of vascular morphogenesis by which proliferating ECs organize into multicellular tubes with functional lumens. Thus, the composition of ECM and therefore the regulation of ECM degradation and remodeling serves pivotally in the control of lumen and tube formation and, finally, neovessel stability and maturation.

Design of GFRP deck and deck-to-girder connections for girder bridges

This paper presents the design and analysis of GFRP (glass fiber reinforced polymer) decks for the girder bridges. In the material design, Eglass fibers with vinyl ester resin are assumed for the materials. Five GFRP plates having different stacking patterns and material compositions are designed and pultruded. Total 100 specimens are tested for tension, compression, shear, and flexure. Based on the material properties determined in the material test, structural shape of deck profile having multi-cellular tube section is proposed. The proposed profile is finally optimized by using a genetic algorithm-based optimization procedure. Based on the results of this study, viable GFRP patterns and cross-sectional dimensions of deck profile with deck-to-girder connections suitable for the deck renewal projects are proposed. Using the proposed cross-sectional shape and GFRP patterns, a design of GFRP deck for the typical steel I-girder bridge is also presented in this paper.

Epithelial tube morphogenesis during Drosophila tracheal development requires Piopio, a luminal ZP protein.

The formation of branched epithelial networks is fundamental to the development of many organs, such as the lung, the kidney or the vasculature. Little is known about the mechanisms that control cell rearrangements during tubulogenesis and regulate the size of individual tubes. Recent studies indicate that whereas the basal surface of tube cells interacts with the surrounding tissues and helps to shape the ramification pattern of tubular organs, the apical surface has an important role in the regulation of tube diameter and tube growth. Here we report that two proteins, Piopio (Pio) and Dumpy (Dp), containing a zona pellucida (ZP) domain are essential for the generation of the interconnected tracheal network in Drosophila melanogaster. Pio is secreted apically, accumulates in the tracheal lumen and possibly interacts with Dp through the ZP domains. In the absence of Pio and Dp, multicellular tubes do not rearrange through cell elongation and cell intercalation to form narrow tubes with autocellular junctions; instead they are transformed into multicellular cysts, which leads to a severe disruption of the branched pattern. We propose that an extracellular matrix containing Pio and Dp provides a structural network in the luminal space, around which cell rearrangements can take place in an ordered fashion without losing interconnections. Our results suggest that a similar structural role might be attributed to other ZP-domain proteins in the formation of different branched organs.

VE-Cadherin Mediates Endothelial Cell Capillary Tube Formation in Fibrin and Collagen Gels1

Various cell adhesion molecules mediate the diverse functions of the vascular endothelium, such as cell adhesion, neutrophil migration, and angiogenesis. In order to identify cell adhesion molecules important for angiogenesis, we used anin vitromodel (Chalupowicz, Chowdhury, Bach, Barsigian, and Martinez,J. Cell Biol.130, 207–215, 1995) in which human umbilical vein endothelial cell monolayers are induced to form capillary-like tubes when a second gel, composed of either fibrin or collagen, is formed overlying the apical surface. In the present investigation, we observed that a monoclonal antibody directed against the first extracellular domain of human vascular endothelial cadherin (VE-cadherin, cadherin 5) inhibited the formation of capillary tubes formed between either fibrin or collagen gels. Moreover, when added to preformed capillary tubes, this antibody disrupted the capillary network. In contrast, monoclonal antibodies directed against the extracellular domain of N-cadherin, the αvβ3integrin, and PECAM-1 failed to inhibit capillary tube formation. During capillary tube formation, Western blot and RT-PCR analysis revealed no marked change in VE-cadherin expression. Immunocytochemical studies demonstrated that VE-cadherin was concentrated at intercellular junctions in multicellular capillary tubes. Thus, VE-cadherin plays a specific role in fibrin-induced or collagen-induced capillary tube formation and is localized at areas of intercellular contact where it functions to maintain the tubular architecture. Moreover, its function at tubular intercellular junctions is distinct from that at intercellular junctions present in confluent monolayers, since only the former was inhibited by monoclonal antibodies.

Development of the Drosophila tracheal system occurs by a series of morphologically distinct but genetically coupled branching events.

The tracheal (respiratory) system of Drosophila melanogaster is a branched network of epithelial tubes that ramifies throughout the body and transports oxygen to the tissues. It forms by a series of sequential branching events in each hemisegment from T2 to A8. Here we present a cellular and initial genetic analysis of the branching process. We show that although branching is sequential it is not iterative. The three levels of branching that we distinguish involve different cellular mechanisms of tube formation. Primary branches are multicellular tubes that arise by cell migration and intercalation; secondary branches are unicellular tubes formed by individual tracheal cells; terminal branches are subcellular tubes formed within long cytoplasmic extensions. Each level of branching is accompanied by expression of a different set of enhancer trap markers. These sets of markers are sequentially activated in progressively restricted domains and ultimately individual tracheal cells that are actively forming new branches. A clonal analysis demonstrates that branching fates are not assigned to tracheal cells until after cell division ceases and branching begins. We further show that the breathless FGF receptor, a tracheal gene required for primary branching, is also required to activate expression of markers involved in secondary branching and that the pointed ETS-domain transcription factor is required for secondary branching and also to activate expression of terminal branch markers. The combined morphological, marker expression and genetic data support a model in which successive branching events are mechanistically and genetically distinct but coupled through the action of a tracheal gene regulatory hierarchy.