Your search keyword '"Paul A. Bump"' showing total 3 results

1. Establishing typical values for hemocyte mortality in individual mussels ( Mytilus californianus ) using fluorescence‐activated cell sorting

Author

Paul A. Bump, George N. Somero, Mark W. Denny, and Nicole E. Moyen

Subjects

Fluorescence-Activated Cell Sorting, biology, Chemistry, Hemocyte, Genetics, biology.organism_classification, Molecular Biology, Biochemistry, Mytilus, Biotechnology, Cell biology

Published

2020

2. Genome-wide analysis of facial skeletal regionalization in zebrafish

Author

Maxwell Bay, Michael A. Bonaguidi, Amjad Askary, Bartosz Balczerski, J. Gage Crump, Pengfei Xu, Paul A. Bump, and Lindsey Barske

Subjects

0301 basic medicine, EMX2, Computational biology, Transcriptome, 03 medical and health sciences, Cranial neural crest, Techniques and Resources, Gene expression, Animals, Craniofacial, Molecular Biology, Zebrafish, Gene, In Situ Hybridization, Body Patterning, Genetics, biology, Endothelin-1, Gene Expression Regulation, Developmental, Zebrafish Proteins, biology.organism_classification, Flow Cytometry, 030104 developmental biology, Branchial Region, biology.protein, HAND2, Developmental Biology

Abstract

Patterning of the facial skeleton involves the precise deployment of thousands of genes in distinct regions of the pharyngeal arches. Despite the significance for craniofacial development, how genetic programs drive this regionalization remains incompletely understood. Here we use combinatorial labeling of zebrafish cranial neural crest-derived cells (CNCCs) to define global gene expression along the dorsoventral axis of the developing arches. Intersection of region-specific transcriptomes with expression changes in response to signaling perturbations demonstrates complex roles for Endothelin1 (Edn1) signaling in the intermediate joint-forming region, yet a surprisingly minor role in ventral-most regions. Analysis of co-variance across multiple sequencing experiments further reveals clusters of co-regulated genes, with in situ hybridization confirming the domain-specific expression of novel genes. We then created loss-of-function alleles for 12 genes and uncovered antagonistic functions of two new Edn1 targets, follistatin a (fsta) and emx2, in regulating cartilaginous joints in the hyoid arch. Our unbiased discovery and functional analysis of genes with regional expression in zebrafish arch CNCCs reveals complex regulation by Edn1 and points to novel candidates for craniofacial disorders.

Published

2017

3. Competition between Jagged-Notch and Endothelin1 Signaling Selectively Restricts Cartilage Formation in the Zebrafish Upper Face

Author

James T. Nichols, J. Gage Crump, Lindsey Barske, Amjad Askary, Paul A. Bump, Bartosz Balczerski, and Elizabeth Zuniga

Subjects

0301 basic medicine, Embryology, Cancer Research, Condensation, Mutant, Cell Signaling, Medicine and Health Sciences, Membrane Receptor Signaling, Zebrafish, Genetics (clinical), Notch Signaling, Genetics, Regulation of gene expression, biology, Physics, Fishes, Gene Expression Regulation, Developmental, Animal Models, Immune Receptor Signaling, Condensed Matter Physics, Cell biology, medicine.anatomical_structure, Connective Tissue, Osteichthyes, Vertebrates, Physical Sciences, Anatomy, Signal transduction, Phase Transitions, Research Article, Signal Transduction, BMP signaling, lcsh:QH426-470, Notch signaling pathway, Research and Analysis Methods, 03 medical and health sciences, Model Organisms, medicine, Animals, Molecular Biology, Transcription factor, Ecology, Evolution, Behavior and Systematics, Cartilage, Embryos, Organisms, Biology and Life Sciences, Cell Biology, Zebrafish Proteins, biology.organism_classification, lcsh:Genetics, Biological Tissue, 030104 developmental biology, Face, Facial skeleton, Head, Developmental Biology

Abstract

The intricate shaping of the facial skeleton is essential for function of the vertebrate jaw and middle ear. While much has been learned about the signaling pathways and transcription factors that control facial patterning, the downstream cellular mechanisms dictating skeletal shapes have remained unclear. Here we present genetic evidence in zebrafish that three major signaling pathways − Jagged-Notch, Endothelin1 (Edn1), and Bmp − regulate the pattern of facial cartilage and bone formation by controlling the timing of cartilage differentiation along the dorsoventral axis of the pharyngeal arches. A genomic analysis of purified facial skeletal precursors in mutant and overexpression embryos revealed a core set of differentiation genes that were commonly repressed by Jagged-Notch and induced by Edn1. Further analysis of the pre-cartilage condensation gene barx1, as well as in vivo imaging of cartilage differentiation, revealed that cartilage forms first in regions of high Edn1 and low Jagged-Notch activity. Consistent with a role of Jagged-Notch signaling in restricting cartilage differentiation, loss of Notch pathway components resulted in expanded barx1 expression in the dorsal arches, with mutation of barx1 rescuing some aspects of dorsal skeletal patterning in jag1b mutants. We also identified prrx1a and prrx1b as negative Edn1 and positive Bmp targets that function in parallel to Jagged-Notch signaling to restrict the formation of dorsal barx1+ pre-cartilage condensations. Simultaneous loss of jag1b and prrx1a/b better rescued lower facial defects of edn1 mutants than loss of either pathway alone, showing that combined overactivation of Jagged-Notch and Bmp/Prrx1 pathways contribute to the absence of cartilage differentiation in the edn1 mutant lower face. These findings support a model in which Notch-mediated restriction of cartilage differentiation, particularly in the second pharyngeal arch, helps to establish a distinct skeletal pattern in the upper face., Author Summary The exquisite functions of the vertebrate face require the precise formation of its underlying bones. Remarkably, many of the genes required to shape the facial skeleton are the same from fish to man. In this study, we use the powerful zebrafish system to understand how the skeletal components of the face acquire different shapes during development. To do so, we analyze a series of mutants that disrupt patterning of the facial skeleton, and then assess how the genes affected in these mutants control cell fate in skeletal progenitor cells. From these genetic studies, we found that several pathways converge to control when and where progenitor cells commit to a cartilage fate, thus controlling the size and shape of cartilage templates for the later-arising bones. Our work thus reveals how regulating the timing of when progenitor cells make skeleton helps to shape the bones of the zebrafish face. As mutations in many of the genes studied are implicated in human craniofacial defects, differences in the timing of progenitor cell differentiation may also explain the wonderful diversity of human faces.

Published

2016