Browsing by Subject "notochord"
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Item Open Access Molecular Mechanisms of Notochord Vacuole Formation and Their Role in Zebrafish Development(2014) Ellis, Kathryn LeighThe notochord plays critical structural and signaling roles during vertebrate development. At the center of the vertebrate notochord is a large fluid-filled organelle, the notochord vacuole. While these highly conserved intracellular structures have been described for decades, little is known about the molecular mechanisms involved in their biogenesis and maintenance. Here we show that zebrafish notochord vacuoles are specialized lysosome-related organelles whose formation and maintenance requires late endosomal trafficking regulated by the vacuole-specific Rab32a, and H+-ATPase-dependent acidification. We establish that notochord vacuoles are required for body axis elongation during embryonic development and identify a novel role for notochord vacuoles in spine morphogenesis. Thus, the vertebrate notochord plays important structural roles beyond early development.
Item Open Access Patterning Mechanisms Underlying Notochord and Spine Segmentation in Zebrafish(2021) Wopat, SusanThe defining characteristic of the subphylum Vertebrata is the vertebral column, which is comprised of alternating vertebral bodies and intervertebral discs. In spite of being a highly conserved structure, the morphogenetic events that culminate in building the vertebral column remain poorly understood. In particular, patterning mechanisms underlying how segmentation of the spine is precisely established have not been examined at post-embryonic stages. For several years, vertebral column patterning was thought to hinge upon proper segmentation of the embryo, while the notochord served as a transient scaffold for the vertebral bodies and intervertebral discs. Using genetic, live-imaging, and quantitative approaches, this work illustrates that the notochord sheath in zebrafish, provides a template for osteoblast recruitment and vertebral bone formation in the developing spine. Furthermore, we show that notochord segmentation is influenced by the adjacent muscle segments and connective tissue, which may provide mechanical patterning cues. Insights from this work will better inform how adolescent idiopathic scoliosis and congenital scoliosis arise.
Item Embargo Uncovering the patterning mechanisms governing notochord segmentation and spine evolution(2022) Peskin, Brianna ClaireVertebrates are distinguished by the presence of a segmented spine that supports the body axis and facilitates movement. The establishment of alternating domains of vertebral centra and intervertebral discs is a complex biological phenomenon. Recent studies in teleost fish demonstrate that the epithelial sheath of the notochord segments to provide positional information for the development of vertebral bone. The studies performed for this dissertation uncover specific components of the gene regulatory network guiding notochord segmentation. Genetic manipulations and live confocal imaging of transgenic zebrafish demonstrate that BMP activity triggers sheath cell differentiation and regulates the lateral expansion of notochord segments. Moreover, the importance of notochord segmentation during the development and evolution of the spine is highlighted by a unique extracellular matrix mutant in which notochord patterning is lost. Without a segmented notochord framework, sclerotomal osteoblasts alter their migratory trajectories and solely rely on paraxial mesoderm patterning to form centra structures. The resulting mode of spine morphogenesis shares commonalities with basal gnathostome species, suggesting that notochord signals prompted specific morphological transitions during spine evolution.
Item Open Access Vacuole Formation Guides the Regenerative Path of the Zebrafish Notochord(2021) Garcia, JamieThe notochord is a defining feature of our phylum Chordata and has critical roles in human development that are highly conserved in vertebrates. The notochord functions as a hydrostatic scaffold to provide structural rigidity needed for anterior-posterior axis elongation and later for proper spine development. The notochord’s mechanical properties depend on its unique structure. In zebrafish, the notochord consists of a core of giant vacuolated cells surrounded by an epithelial -like sheath. Previous research from our lab has shown that during early development, the notochord vacuole rapidly accumulates fluid and expands within the inelastic notochord sheath. In this work we first investigated the molecular processes by which large vacuolated cells of the notochord maintain integrity while being subjected to a significant amount of stress. We determined that caveolae play a mechanoprotective role in the zebrafish notochord and are crucial in preserving notochord integrity. Upon loss of caveolae, the vacuolated cell collapses at discrete positions under the mechanical strain of locomotion then sheath cells invade the inner notochord and differentiate into vacuolated cells thereby restoring notochord function and allowing normal spine development. Findings from our caveolae work next allowed us to investigate the arrangement of vacuolated cells within the zebrafish notochord. During notochord morphogenesis, the vacuolated cells in wild-type zebrafish arrange themselves in a staircase pattern. However, in both caveolae and vacuole mutants, this pattern is disrupted. We investigated the basis of this pattern and found that it can be described by simple physical principles. We modeled the arrangement of vacuolated cells using a system composed of silicone tubing and sodium polyacrylate jelly beads demonstrating that what we observe in vivo can be described by the theory developed for the packing of spheres in cylinders. We determined that the organization of vacuolated cells within the zebrafish notochord is controlled by the density of fluid filled vacuoles and the diameter of the notochord tube. Lastly, based on our finding that sheath cells of the notochord can form de novo vacuoles, we wanted to identify key factors contributing to notochord vacuole biogenesis and integrity. We used a two-pronged transcriptomics and proteomics approach to identify proteins involved in de novo vacuole formation. We find that loss of a protein previously linked to lysosome related organelle function, Lyst, leads to fragmentation of notochord vacuoles and impaired axis elongation. Interestingly, upon injury of the notochord, sheath cells fail to form a fully inflated vacuole and continue to grow outside of notochord boundaries, forming a tumor-like mass. The tumor-like mass appears very similar to a rare tumor type called chordoma, which is characterized by overgrowth of intervertebral disc tissue. This work suggests that Lyst is important for notochord vacuole biogenesis in zebrafish and may play an important role in chordoma formation. Our work has elucidated novel mechanisms of cell surface integrity and has shown how proper vacuolated cell inflation leads to a structurally intact notochord. Additionally, we have demonstrated the remarkable regenerative capacity of the zebrafish notochord and identified potential regulators of both vacuole biogenesis and chordoma formation.