Your search keyword '"Katherine E. Trevers"' showing total 9 results

1. Expression and Roles of Teneurins in Zebrafish

Author

Angela Cheung, Katherine E. Trevers, Marta Reyes-Corral, Paride Antinucci, and Robert Hindges

Subjects

teneurin/Odz, retinal ganglion cell, amacrine cell, visual system, synapse adhesion molecule, zebrafish, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The teneurins, also known as Ten-m/Odz, are highly conserved type II transmembrane glycoproteins widely expressed throughout the nervous system. Functioning as dimers, these large cell-surface adhesion proteins play a key role in regulating neurodevelopmental processes such as axon targeting, synaptogenesis and neuronal wiring. Synaptic specificity is driven by molecular interactions, which can occur either in a trans-homophilic manner between teneurins or through a trans-heterophilic interaction across the synaptic cleft between teneurins and other cell-adhesion molecules, such as latrophilins. The significance of teneurins interactions during development is reflected in the widespread expression pattern of the four existing paralogs across interconnected regions of the nervous system, which we demonstrate here via in situ hybridization and the generation of transgenic BAC reporter lines in zebrafish. Focusing on the visual system, we will also highlight the recent developments that have been made in furthering our understanding of teneurin interactions and their functionality, including the instructive role of teneurin-3 in specifying the functional wiring of distinct amacrine and retinal ganglion cells in the vertebrate visual system underlying a particular functionality. Based on the distinct expression pattern of all teneurins in different retinal cells, it is conceivable that the combination of different teneurins is crucial for the generation of discrete visual circuits. Finally, mutations in all four human teneurin genes have been linked to several types of neurodevelopmental disorders. The opportunity therefore arises that findings about the roles of zebrafish teneurins or their orthologs in other species shed light on the molecular mechanisms in the etiology of such human disorders.

Published

2019

2. A gene regulatory network for neural induction

Author

Katherine E Trevers, Hui-Chun Lu, Youwen Yang, Alexandre P Thiery, Anna C Strobl, Claire Anderson, Božena Pálinkášová, Nidia MM de Oliveira, Irene M de Almeida, Mohsin AF Khan, Natalia Moncaut, Nicholas M Luscombe, Leslie Dale, Andrea Streit, and Claudio D Stern

Subjects

gene regulatory network, neural induction, embryonic induction, organizer, neurulation, cell fate determination, Medicine, Science, Biology (General), QH301-705.5

Abstract

During early vertebrate development, signals from a special region of the embryo, the organizer, can redirect the fate of non-neural ectoderm cells to form a complete, patterned nervous system. This is called neural induction and has generally been imagined as a single signalling event, causing a switch of fate. Here, we undertake a comprehensive analysis, in very fine time course, of the events following exposure of competent ectoderm of the chick to the organizer (the tip of the primitive streak, Hensen’s node). Using transcriptomics and epigenomics we generate a gene regulatory network comprising 175 transcriptional regulators and 5614 predicted interactions between them, with fine temporal dynamics from initial exposure to the signals to expression of mature neural plate markers. Using in situ hybridization, single-cell RNA-sequencing, and reporter assays, we show that the gene regulatory hierarchy of responses to a grafted organizer closely resembles the events of normal neural plate development. The study is accompanied by an extensive resource, including information about conservation of the predicted enhancers in other vertebrates.

Published

2023

3. A gene regulatory network for neural induction

Author

Alexandre P Thiery, Youwen Yang, Hui-Chun Lu, Katherine E Trevers, Anna C Strobl, Claire Anderson, Božena Pálinkášová, Nidia MM de Oliveira, Irene M de Almeida, Mohsin AF Khan, Natalia Moncaut, Nicholas M Luscombe, Leslie Dale, Andrea Streit, and Claudio D Stern

Subjects

General Immunology and Microbiology, General Neuroscience, Gene Expression, General Medicine, Tumour Biology, Genetics & Genomics, General Biochemistry, Genetics and Molecular Biology, Computational & Systems Biology

Abstract

During early vertebrate development, signals from a special region of the embryo, the organizer, can redirect the fate of non-neural ectoderm cells to form a complete, patterned nervous system. This is called neural induction and has generally been imagined as a single signalling event, causing a switch of fate. Here, we undertake a comprehensive analysis, in very fine time course, of the events following exposure of competent ectoderm of the chick to the organizer (the tip of the primitive streak, Hensen’s node). Using transcriptomics and epigenomics we generate a gene regulatory network comprising 175 transcriptional regulators and 5614 predicted interactions between them, with fine temporal dynamics from initial exposure to the signals to expression of mature neural plate markers. Using in situ hybridization, single-cell RNA-sequencing, and reporter assays, we show that the gene regulatory hierarchy of responses to a grafted organizer closely resembles the events of normal neural plate development. The study is accompanied by an extensive resource, including information about conservation of the predicted enhancers in other vertebrates.

Published

2023

4. Author response: A gene regulatory network for neural induction

Author

Alexandre P Thiery, Youwen Yang, Hui-Chun Lu, Katherine E Trevers, Anna C Strobl, Claire Anderson, Božena Pálinkášová, Nidia MM de Oliveira, Irene M de Almeida, Mohsin AF Khan, Natalia Moncaut, Nicholas M Luscombe, Leslie Dale, Andrea Streit, and Claudio D Stern

Published

2022

5. Abstract LB080: SAVANA: a computational method to characterize structural variation in human cancer genomes using nanopore sequencing

Author

Hillary Elrick, Jose Espejo Valle-Inclan, Katherine E. Trevers, Francesc Muyas, Rita Cascão, Angela Afonso, Cláudia C. Faria, Adrienne M. Flanagan, and Isidro Cortés-Ciriano

Subjects

Cancer Research, Oncology

Abstract

Whole-genome sequencing (WGS) of human cancers has revealed that structural variation, which refers to the rearrangement of the genome leading to the deletion, amplification of reshuffling of DNA segments ranging from a few hundred bp to entire chromosomes, is a key mutational process in cancer evolution. Notably, pan-cancer analyses have revealed that both simple and complex forms of structural variation are pervasive across diverse human cancers, and often underpin drug resistance and metastasis. To date, the study of cancer genomes has relied on the analysis of short-read WGS on the dominant Illumina platform, which generates short, highly-accurate reads of 100-300bp that allow the study of point mutations at high resolution. However, detection of structural variants (SVs) using short reads is limited, as breakpoints falling in repetitive regions cannot be reliably mapped to the human genome. As a result, our understanding of the patterns and mechanisms underpinning structural variation in cancer genomes remains incomplete. In contrast to short-read sequencing, long-read sequencing technologies, such as Oxford Nanopore and PacBio, permit continuous reading of individual DNA molecules over 10 kilobases, thus providing unparalleled information to resolve SVs in repetitive regions and complex genome rearrangements. However, novel bioinformatics methods that account for the higher error rate of long-read methods are needed to take advantage of their capabilities for cancer genome analysis. Here, we present SAVANA, a novel structural variant caller for long-read sequencing data specifically designed for the analysis of cancer genomes. To identify both somatic and germline SVs, SAVANA takes as input long-read WGS data from a tumor and normal sample pair. SAVANA scans sequencing reads to detect split reads and gapped alignments, which are then clustered to define putative SVs. Next, SAVANA applies a machine learning-informed set of heuristics to remove false positives arising from mapping errors and sequencing artifacts. Extensively validated against a multi-platform truthset, we show that SAVANA identifies a range of somatic rearrangements with high recall and precision, outperforming existing tools while maintaining a lower execution time than competing methods. In patient samples, SAVANA identifies clinically relevant alterations, such as oncogenic gene fusions, with high accuracy. Additionally, SAVANA permits the reconstruction of double minutes, multi-chromosomal chromothripsis events, and SVs mapping to highly repetitive regions, including centromeres. In sum, SAVANA permits the characterization of complex structural variants and can uncover clinically relevant mutations across diverse cancer types with high accuracy. Citation Format: Hillary Elrick, Jose Espejo Valle-Inclan, Katherine E. Trevers, Francesc Muyas, Rita Cascão, Angela Afonso, Cláudia C. Faria, Adrienne M. Flanagan, Isidro Cortés-Ciriano. SAVANA: a computational method to characterize structural variation in human cancer genomes using nanopore sequencing [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 2 (Clinical Trials and Late-Breaking Research); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(8_Suppl):Abstract nr LB080.

Published

2023

6. A gene regulatory network for neural induction

Author

Claudio D. Stern, Hui-Chun Lu, Dale L, Nicholas M. Luscombe, de Almeida Im, Katherine E. Trevers, Moncaut N, de Oliveira Nmm, Khan Maf, Anna C Strobl, Andrea Streit, Yang Yang, Alexandre P. Thiery, and Pálinkášová B

Subjects

Nervous system, medicine.anatomical_structure, medicine, Ectoderm, In situ hybridization, Biology, Enhancer, Gene, Neural plate, Neural development, Epigenomics, Cell biology

Abstract

During early vertebrate development, signals from a special region of the embryo, the organizer, can re-direct the fate of non-neural ectoderm cells to form a complete, patterned nervous system. This is called neural induction and has generally been imagined as a single signalling event, causing a switch of fate. Here we undertake a comprehensive analysis, in very fine time-course, of the events following exposure of ectoderm to the organizer. Using transcriptomics and epigenomics we generate a Gene Regulatory Network comprising 175 transcriptional regulators and 5,614 predicted interactions between them, with fine temporal dynamics from initial exposure to the signals to expression of mature neural plate markers. Using in situ hybridization, single-cell RNA-sequencing and reporter assays we show that neural induction by a grafted organizer closely resembles normal neural plate development. The study is accompanied by a comprehensive resource including information about conservation of the predicted enhancers in different vertebrate systems.

Published

2021

7. Distinct steps of neural induction revealed by Asterix, Obelix and TrkC, genes induced by different signals from the organizer.

Author

Sonia Pinho, Pamela R Simonsson, Katherine E Trevers, Matthew J Stower, William T Sherlock, Mohsin Khan, Andrea Streit, Guojun Sheng, and Claudio D Stern

Subjects

Medicine, Science

Abstract

The amniote organizer (Hensen's node) can induce a complete nervous system when grafted into a peripheral region of a host embryo. Although BMP inhibition has been implicated in neural induction, non-neural cells cannot respond to BMP antagonists unless previously exposed to a node graft for at least 5 hours before BMP inhibitors. To define signals and responses during the first 5 hours of node signals, a differential screen was conducted. Here we describe three early response genes: two of them, Asterix and Obelix, encode previously undescribed proteins of unknown function but Obelix appears to be a nuclear RNA-binding protein. The third is TrkC, a neurotrophin receptor. All three genes are induced by a node graft within 4-5 hours but they differ in the extent to which they are inducible by FGF: FGF is both necessary and sufficient to induce Asterix, sufficient but not necessary to induce Obelix and neither sufficient nor necessary for induction of TrkC. These genes are also not induced by retinoic acid, Noggin, Chordin, Dkk1, Cerberus, HGF/SF, Somatostatin or ionomycin-mediated Calcium entry. Comparison of the expression and regulation of these genes with other early neural markers reveals three distinct "epochs", or temporal waves, of gene expression accompanying neural induction by a grafted organizer, which are mirrored by specific stages of normal neural plate development. The results are consistent with neural induction being a cascade of responses elicited by different signals, culminating in the formation of a patterned nervous system.

Published

2011

8. Neural induction by the node and placode induction by head mesoderm share an initial state resembling neural plate border and ES cells

Author

Matthew J. Stower, Monica Tambalo, Andrea Streit, Katherine E. Trevers, Anna C Strobl, Ravindra Singh Prajapati, Mark Hintze, Natalia Moncaut, Ramya Ranganathan, Mohsin A.F. Khan, and Claudio D. Stern

Subjects

Central Nervous System, 0301 basic medicine, animal structures, Chick Embryo, Biology, Mesoderm, 03 medical and health sciences, 0302 clinical medicine, Animals, Embryonic Stem Cells, In Situ Hybridization, Embryonic Induction, Neural Plate, Multidisciplinary, Gene Expression Profiling, Gene Expression Regulation, Developmental, Gastrula, Biological Sciences, Cell biology, Gastrulation, Transplantation, 030104 developmental biology, Neurulation, Hypoblast, Epiblast, embryonic structures, Neural plate, Neural development, 030217 neurology & neurosurgery

Abstract

Around the time of gastrulation in higher vertebrate embryos, inductive interactions direct cells to form central nervous system (neural plate) or sensory placodes. Grafts of different tissues into the periphery of a chicken embryo elicit different responses: Hensen's node induces a neural plate whereas the head mesoderm induces placodes. How different are these processes? Transcriptome analysis in time course reveals that both processes start by induction of a common set of genes, which later diverge. These genes are remarkably similar to those induced by an extraembryonic tissue, the hypoblast, and are normally expressed in the pregastrulation stage epiblast. Explants of this epiblast grown in the absence of further signals develop as neural plate border derivatives and eventually express lens markers. We designate this state as "preborder"; its transcriptome resembles embryonic stem cells. Finally, using sequential transplantation experiments, we show that the node, head mesoderm, and hypoblast are interchangeable to begin any of these inductions while the final outcome depends on the tissue emitting the later signals.

Published

2017

9. Distinct steps of neural induction revealed by Asterix, Obelix and TrkC, genes induced by different signals from the organizer

Author

Andrea Streit, Pamela R. Simonsson, Mohsin A.F. Khan, Katherine E. Trevers, Claudio D. Stern, Guojun Sheng, Sonia Pinho, William T. Sherlock, and Matthew J. Stower

Subjects

Embryology, Time Factors, Retinoic acid, lcsh:Medicine, Chick Embryo, Nervous System, Cell Fate Determination, chemistry.chemical_compound, 0302 clinical medicine, Morphogenesis, Pattern Formation, lcsh:Science, Phylogeny, Embryonic Induction, 0303 health sciences, Neural Plate, Multidisciplinary, Primitive streak formation, biology, Gene Expression Regulation, Developmental, RNA-Binding Proteins, Chordin, Neural development, Neural plate, Neurotrophin, Signal Transduction, Research Article, Models, Biological, 03 medical and health sciences, Developmental Neuroscience, Animals, Receptor, trkC, Noggin, Biology, 030304 developmental biology, Gene Library, lcsh:R, Organizers, Embryonic, Molecular Development, Body Plan Organization, Molecular biology, Signaling, Morphogens, chemistry, biology.protein, lcsh:Q, Organism Development, 030217 neurology & neurosurgery, Developmental Biology, Neuroscience

Abstract

The amniote organizer (Hensen's node) can induce a complete nervous system when grafted into a peripheral region of a host embryo. Although BMP inhibition has been implicated in neural induction, non-neural cells cannot respond to BMP antagonists unless previously exposed to a node graft for at least 5 hours before BMP inhibitors. To define signals and responses during the first 5 hours of node signals, a differential screen was conducted. Here we describe three early response genes: two of them, Asterix and Obelix, encode previously undescribed proteins of unknown function but Obelix appears to be a nuclear RNA-binding protein. The third is TrkC, a neurotrophin receptor. All three genes are induced by a node graft within 4-5 hours but they differ in the extent to which they are inducible by FGF: FGF is both necessary and sufficient to induce Asterix, sufficient but not necessary to induce Obelix and neither sufficient nor necessary for induction of TrkC. These genes are also not induced by retinoic acid, Noggin, Chordin, Dkk1, Cerberus, HGF/SF, Somatostatin or ionomycin-mediated Calcium entry. Comparison of the expression and regulation of these genes with other early neural markers reveals three distinct "epochs'', or temporal waves, of gene expression accompanying neural induction by a grafted organizer, which are mirrored by specific stages of normal neural plate development. The results are consistent with neural induction being a cascade of responses elicited by different signals, culminating in the formation of a patterned nervous system.

Published

2010