Your search keyword '"Ava E. Brent"' showing total 7 results

1. AcaudalmRNA gradient controls posterior development in the waspNasonia

Author

David S. Leaf, Ava E. Brent, Megan Walker, Claude Desplan, Eugenia C. Olesnicky, Lori Tonnes, and Mary Anne Pultz

Subjects

Embryo, Nonmammalian, animal structures, Zygote, Wasps, Biology, Nasonia vitripennis, Gene expression, Animals, Drosophila Proteins, RNA, Messenger, Molecular Biology, Gap gene, Body Patterning, Homeodomain Proteins, Genetics, Ovary, fungi, Embryogenesis, Gene Expression Regulation, Developmental, Drosophila embryogenesis, Embryo, biology.organism_classification, Cell biology, Body plan, Mutation, Insect Proteins, Drosophila, Female, RNA Interference, Nasonia, Transcription Factors, Developmental Biology

Abstract

One of the earliest steps of embryonic development is the establishment of polarity along the anteroposterior axis. Extensive studies of Drosophila embryonic development have elucidated mechanisms for establishing polarity, while studies with other model systems have found that many of these molecular components are conserved through evolution. One exception is Bicoid, the master organizer of anterior development in Drosophila and higher dipterans, which is not conserved. Thus, the study of anteroposterior patterning in insects that lack Bicoid can provide insight into the evolution of the diversity of body plan patterning networks. To this end, we have established the long germ parasitic wasp Nasonia vitripennis as a model for comparative studies with Drosophila.Here we report that, in Nasonia, a gradient of localized caudal mRNA directs posterior patterning, whereas, in Drosophila, the gradient of maternal Caudal protein is established through translational repression by Bicoid of homogeneous caudalmRNA. Loss of caudal function in Nasonia results in severe segmentation defects. We show that Nasonia caudal is an activator of gap gene expression that acts far towards the anterior of the embryo, placing it atop a cascade of early patterning. By contrast, activation of gap genes in flies relies on redundant functions of Bicoid and Caudal, leading to a lack of dramatic action on gap gene expression: caudal instead plays a limited role as an activator of pair-rule gene expression. These studies,together with studies in short germ insects, suggest that caudal is an ancestral master organizer of patterning, and that its role has been reduced in higher dipterans such as Drosophila.

Published

2006

2. Genetic analysis of interactions between the somitic muscle, cartilage and tendon cell lineages during mouse development

Author

Ava E. Brent, Clifford J. Tabin, and Thomas Braun

Subjects

animal structures, Muscle Proteins, Cartilage metabolism, Biology, Tendons, Mice, Tendon cell, Myotome, medicine, Paraxial mesoderm, Animals, Cell Lineage, Molecular Biology, Mice, Knockout, Muscles, Stem Cells, Cartilage, High Mobility Group Proteins, Gene Expression Regulation, Developmental, Nuclear Proteins, Cell Differentiation, Tendon formation, Anatomy, musculoskeletal system, Cell biology, DNA-Binding Proteins, Fibroblast Growth Factors, Somite, medicine.anatomical_structure, Somites, Mutation, embryonic structures, Trans-Activators, MYF5, Myogenic Regulatory Factor 5, SOXD Transcription Factors, Signal Transduction, Transcription Factors, Developmental Biology

Abstract

Proper formation of the musculoskeletal system requires the coordinated development of the muscle, cartilage and tendon lineages arising from the somitic mesoderm. During early somite development, muscle and cartilage emerge from two distinct compartments, the myotome and sclerotome, in response to signals secreted from surrounding tissues. As the somite matures, the tendon lineage is established within the dorsolateral sclerotome, adjacent to and beneath the myotome. We examine interactions between the three lineages by observing tendon development in mouse mutants with genetically disrupted muscle or cartilage development. Through analysis of embryos carrying null mutations in Myf5 and Myod1, hence lacking both muscle progenitors and differentiated muscle, we identify an essential role for the specified myotome in axial tendon development, and suggest that absence of tendon formation in Myf5/Myod1 mutants results from loss of the myotomal FGF proteins, which depend upon Myf5 and Myod1 for their expression, and are required, in turn, for induction of the tendon progenitor markers. Our analysis of Sox5/Sox6 double mutants, in which the chondroprogenitors are unable to differentiate into cartilage,reveals that the two cell fates arising from the sclerotome, axial tendon and cartilage are alternative lineages, and that cartilage differentiation is required to actively repress tendon development in the dorsolateral sclerotome.

Published

2005

3. Dual mode of embryonic development is highlighted by expression and function of Nasonia pair-rule genes

Author

Ava E. Brent, Claude Desplan, Miriam I. Rosenberg, François Payre, Centre de biologie du développement (CBD), Centre National de la Recherche Scientifique (CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre de Biologie Intégrative (CBI), Université Toulouse III - Paul Sabatier (UT3), and Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Embryo, Nonmammalian, [SDV]Life Sciences [q-bio], Wasps, pair-rule genes, Nasonia vitripennis, 0302 clinical medicine, Gene Regulatory Networks, Biology (General), Phylogeny, Genetics, 0303 health sciences, Tribolium, pair-rule gene, biology, D. melanogaster, General Neuroscience, Runt, Gene Expression Regulation, Developmental, Embryo, General Medicine, Cell biology, Genomics and Evolutionary Biology, embryonic structures, Medicine, Insect Proteins, Nasonia, Blastoderm, Research Article, animal structures, QH301-705.5, Science, Pair-rule gene, Embryonic Development, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, evolution, Animals, Gap gene, 030304 developmental biology, Body Patterning, General Immunology and Microbiology, embryonic patterning, fungi, segmentation, other, biology.organism_classification, Developmental Biology and Stem Cells, Cellularization, 030217 neurology & neurosurgery

Abstract

Embryonic anterior–posterior patterning is well understood in Drosophila, which uses ‘long germ’ embryogenesis, in which all segments are patterned before cellularization. In contrast, most insects use ‘short germ’ embryogenesis, wherein only head and thorax are patterned in a syncytial environment while the remainder of the embryo is generated after cellularization. We use the wasp Nasonia (Nv) to address how the transition from short to long germ embryogenesis occurred. Maternal and gap gene expression in Nasonia suggest long germ embryogenesis. However, the Nasonia pair-rule genes even-skipped, odd-skipped, runt and hairy are all expressed as early blastoderm pair-rule stripes and late-forming posterior stripes. Knockdown of Nv eve, odd or h causes loss of alternate segments at the anterior and complete loss of abdominal segments. We propose that Nasonia uses a mixed mode of segmentation wherein pair-rule genes pattern the embryo in a manner resembling Drosophila at the anterior and ancestral Tribolium at the posterior. DOI: http://dx.doi.org/10.7554/eLife.01440.001, eLife digest Networks of genes that work together are widespread in nature. The conservation of individual genes across species and the tendency of their networks to stick together is a sign that they are working efficiently. Furthermore, it is common for existing gene networks to be adapted to perform new tasks, instead of new networks being invented every time a similar but distinct demand arises. One important question is: how can evolution use the same building blocks—such as the genes in a functioning network—in different ways to achieve new outcomes? The gene network that sets up the ‘body plan’ of insects during development has been well studied, most deeply in the fruit fly, Drosophila. Like all insects, the body of a fruit fly is divided into three main parts—the head, the thorax and the abdomen—and each of these parts is made up of several smaller segments. There is a remarkable diversity of insect body plans in nature, and yet, these seem to arise from the same gene networks in the embryo. When a Drosophila embryo is growing into a larva, all the different body segments develop at the same time. In most other insects, however, segments of the abdomen emerge later and sequentially during the development process. The ancestors of most insects are also thought to have developed in this way, which is known as ‘short germ embryogenesis’. So how did the so-called ‘long germ embryogenesis’, as observed in Drosophila, evolve from the short germ embryogenesis that is observed in most other insects? The gene network that controls development includes the ‘pair-rule genes’ that are expressed in a pattern of alternating stripes that wrap around, top to bottom, along most of the length of the embryo. These stripes mark where the edges of each body segment will eventually develop. In fruit flies, this pattern extends along the entire length of the embryo and the stripes all appear at one time. However, in the abdominal region of short germ insects, the pair-rule genes are expressed in waves that pass through the posterior region as it grows, with new segments being added one behind the other. Now, Rosenberg et al. have attempted to explain how the same genes can be used to direct the segmentation process in such different ways by studying another long germ insect species, the jewel wasp. Analysis of the expression of pair-rule genes in the jewel wasp shows that it uses a mixed strategy to control segmentation. The development of segments at the front of its body is directed in the same way as the fruit fly, with all these segments laid down together. However, the segments at the rear of the body are only patterned later, one after the other, like most other insects. The work of Rosenberg et al. suggests that the jewel wasp represents an intermediate step between ancestral insects and Drosophila in the evolution of the gene network that patterns the ‘body plan’. Identifying and studying these intermediate forms allows us to understand the ways in which evolution can innovate by building upon what has come before. DOI: http://dx.doi.org/10.7554/eLife.01440.002

Published

2014

4. Generation of transgenic tendon reporters, ScxGFP and ScxAP, using regulatory elements of the scleraxis gene

Author

Brian A. Pryce, Ava E. Brent, Nicholas D. Murchison, Ronen Schweitzer, and Clifford J. Tabin

Subjects

Regulation of gene expression, Time Factors, Transgene, Scleraxis, Gene Expression Regulation, Developmental, Tendon formation, Extremities, Mice, Transgenic, Biology, Regulatory Sequences, Nucleic Acid, musculoskeletal system, Molecular biology, Green fluorescent protein, Tendons, Mice, Tendon cell, Regulatory sequence, Genes, Reporter, Basic Helix-Loop-Helix Transcription Factors, Animals, Promoter Regions, Genetic, Gene, Developmental Biology

Abstract

Defects in tendon patterning and differentiation are seldom assessed in mouse mutants due to the difficulty in visualizing connective tissue structures. To facilitate tendon analysis, we have generated mouse lines harboring two different transgene reporters, alkaline phosphatase (AP) and green fluorescent protein (GFP), each expressed using regulatory elements derived from the endogenous Scleraxis (Scx) locus. Scx encodes a transcription factor expressed in all developing tendons and ligaments as well as in their progenitors. Both the ScxGFP and ScxAP transgenes are expressed in patterns recapitulating almost entirely the endogenous developmental expression of Scx including very robust expression in the tendons and ligaments. These reporter lines will facilitate isolation of tendon cells and phenotypic analysis of these tissues in a variety of genetic backgrounds.

Published

2007

5. Localized maternal orthodenticle patterns anterior and posterior in the long germ wasp Nasonia

Author

Ava E. Brent, Claude Desplan, David S. Leaf, Jeremy A. Lynch, and Mary Anne Pultz

Subjects

animal structures, Molecular Sequence Data, Wasps, Genes, Insect, Biology, Models, Biological, Nasonia vitripennis, Animals, Drosophila Proteins, RNA, Messenger, Gap gene, Body Patterning, Homeodomain Proteins, Multidisciplinary, fungi, Drosophila embryogenesis, Gene Expression Regulation, Developmental, Embryo, Anatomy, biology.organism_classification, Cell biology, Gastrulation, Coleoptera, Drosophila melanogaster, embryonic structures, Trans-Activators, Insect Proteins, RNA Interference, Nasonia, Blastoderm, Morphogen

Abstract

The Bicoid (Bcd) gradient in Drosophila has long been a model for the action of a morphogen in establishing embryonic polarity. However, it is now clear that bcd is a unique feature of higher Diptera. An evolutionarily ancient gene, orthodenticle (otd), has a bcd-like role in the beetle Tribolium. Unlike the Bcd gradient, which arises by diffusion of protein from an anteriorly localized messenger RNA, the Tribolium Otd gradient forms by translational repression of otd mRNA by a posteriorly localized factor. These differences in gradient formation are correlated with differences in modes of embryonic patterning. Drosophila uses long germ embryogenesis, where the embryo derives from the entire anterior-posterior axis, and all segments are patterned at the blastoderm stage, before gastrulation. In contrast, Tribolium undergoes short germ embryogenesis: the embryo arises from cells in the posterior of the egg, and only anterior segments are patterned at the blastoderm stage, with the remaining segments arising after gastrulation from a growth zone. Here we describe the role of otd in the long germband embryo of the wasp Nasonia vitripennis. We show that Nasonia otd maternal mRNA is localized at both poles of the embryo, and resulting protein gradients pattern both poles. Thus, localized Nasonia otd has two major roles that allow long germ development. It activates anterior targets at the anterior of the egg in a manner reminiscent of the Bcd gradient, and it is required for pre-gastrulation expression of posterior gap genes.

Published

2005

6. Developmental regulation of somite derivatives: muscle, cartilage and tendon

Author

Ava E. Brent and Clifford J. Tabin

Subjects

Body Patterning, Dermomyotome, Chick Embryo, Biology, Mesoderm, Tendons, Tendon cell, Myotome, Genetics, medicine, Animals, Muscle, Skeletal, Myogenesis, Cartilage, Gene Expression Regulation, Developmental, Cell Differentiation, Anatomy, Chondrogenesis, Cell biology, DNA-Binding Proteins, Somite, medicine.anatomical_structure, Somites, Developmental Biology, Signal Transduction, Transcription Factors

Abstract

Recent research has broadened significantly our understanding of how the somite, a specialized mesodermal structure found in vertebrate embryos, gives rise to the cartilage, muscle and tendon cell lineages. The specification of somite derivatives involves the action of patterning signals secreted from adjacent tissue combined with the activation, in particular somitic compartments, of genes promoting cell lineage specification.

Published

2002

7. Analysis of the tendon cell fate using Scleraxis, a specific marker for tendons and ligaments

Author

Ronen Schweitzer, Vicki Rosen, Eric N. Olson, Clifford J. Tabin, Ava E. Brent, Lewis C. Murtaugh, Andrew B. Lassar, and Jay H. Chyung

Subjects

Limb Buds, Chick Embryo, Biology, Avian Proteins, Tendons, Limb bud, Tendon cell, Ectoderm, Basic Helix-Loop-Helix Transcription Factors, Animals, Noggin, Molecular Biology, Stem Cells, Scleraxis, Gene Expression Regulation, Developmental, Proteins, Tendon formation, Anatomy, Tendon cell differentiation, Tenomodulin, Cell biology, Connective tissue metabolism, Connective Tissue, Bone Morphogenetic Proteins, Carrier Proteins, Biomarkers, Developmental Biology, Signal Transduction, Transcription Factors

Abstract

Little is known about the genesis and patterning of tendons and other connective tissues, mostly owing to the absence of early markers. We have found that Scleraxis, a bHLH transcription factor, is a highly specific marker for all the connective tissues that mediate attachment of muscle to bone in chick and mouse, including the limb tendons, and show that early scleraxis expression marks the progenitor cell populations for these tissues. In the early limb bud, the tendon progenitor population is found in the superficial proximomedial mesenchyme. Using the scleraxis gene as a marker we show that these progenitors are induced by ectodermal signals and restricted by bone morphogenetic protein (BMP) signaling within the mesenchyme. Application of Noggin protein antagonizes this endogenous BMP activity and induces ectopic scleraxis expression. However, the presence of excess tendon progenitors does not lead to the production of additional or longer tendons, indicating that additional signals are required for the final formation of a tendon. Finally, we show that the endogenous expression of noggin within the condensing digit cartilage contributes to the induction of distal tendons.

Published

2001