Your search keyword '"Laura Anne Lowery"' showing total 67 results

1. 16p12.1 Deletion Orthologs are Expressed in Motile Neural Crest Cells and are Important for Regulating Craniofacial Development in Xenopus laevis

Author

Micaela Lasser, Jessica Bolduc, Luke Murphy, Caroline O'Brien, Sangmook Lee, Santhosh Girirajan, and Laura Anne Lowery

Subjects

16p12.1 deletion, Xenopus, development, craniofacial, Neural Crest Cells (NCCs), Genetics, QH426-470

Abstract

Copy number variants (CNVs) associated with neurodevelopmental disorders are characterized by extensive phenotypic heterogeneity. In particular, one CNV was identified in a subset of children clinically diagnosed with intellectual disabilities (ID) that results in a hemizygous deletion of multiple genes at chromosome 16p12.1. In addition to ID, individuals with this deletion display a variety of symptoms including microcephaly, seizures, cardiac defects, and growth retardation. Moreover, patients also manifest severe craniofacial abnormalities, such as micrognathia, cartilage malformation of the ears and nose, and facial asymmetries; however, the function of the genes within the 16p12.1 region have not been studied in the context of vertebrate craniofacial development. The craniofacial tissues affected in patients with this deletion all derive from the same embryonic precursor, the cranial neural crest, leading to the hypothesis that one or more of the 16p12.1 genes may be involved in regulating neural crest cell (NCC)-related processes. To examine this, we characterized the developmental role of the 16p12.1-affected gene orthologs, polr3e, mosmo, uqcrc2, and cdr2, during craniofacial morphogenesis in the vertebrate model system, Xenopus laevis. While the currently-known cellular functions of these genes are diverse, we find that they share similar expression patterns along the neural tube, pharyngeal arches, and later craniofacial structures. As these genes show co-expression in the pharyngeal arches where NCCs reside, we sought to elucidate the effect of individual gene depletion on craniofacial development and NCC migration. We find that reduction of several 16p12.1 genes significantly disrupts craniofacial and cartilage formation, pharyngeal arch migration, as well as NCC specification and motility. Thus, we have determined that some of these genes play an essential role during vertebrate craniofacial patterning by regulating specific processes during NCC development, which may be an underlying mechanism contributing to the craniofacial defects associated with the 16p12.1 deletion.

Published

2022

2. Tau, XMAP215/Msps and Eb1 co-operate interdependently to regulate microtubule polymerisation and bundle formation in axons.

Author

Ines Hahn, Andre Voelzmann, Jill Parkin, Judith B Fülle, Paula G Slater, Laura Anne Lowery, Natalia Sanchez-Soriano, and Andreas Prokop

Subjects

Genetics, QH426-470

Abstract

The formation and maintenance of microtubules requires their polymerisation, but little is known about how this polymerisation is regulated in cells. Focussing on the essential microtubule bundles in axons of Drosophila and Xenopus neurons, we show that the plus-end scaffold Eb1, the polymerase XMAP215/Msps and the lattice-binder Tau co-operate interdependently to promote microtubule polymerisation and bundle organisation during axon development and maintenance. Eb1 and XMAP215/Msps promote each other's localisation at polymerising microtubule plus-ends. Tau outcompetes Eb1-binding along microtubule lattices, thus preventing depletion of Eb1 tip pools. The three factors genetically interact and show shared mutant phenotypes: reductions in axon growth, comet sizes, comet numbers and comet velocities, as well as prominent deterioration of parallel microtubule bundles into disorganised curled conformations. This microtubule curling is caused by Eb1 plus-end depletion which impairs spectraplakin-mediated guidance of extending microtubules into parallel bundles. Our demonstration that Eb1, XMAP215/Msps and Tau co-operate during the regulation of microtubule polymerisation and bundle organisation, offers new conceptual explanations for developmental and degenerative axon pathologies.

Published

2021

3. Functional assessment of the 'two-hit' model for neurodevelopmental defects in Drosophila and X. laevis.

Author

Lucilla Pizzo, Micaela Lasser, Tanzeen Yusuff, Matthew Jensen, Phoebe Ingraham, Emily Huber, Mayanglambam Dhruba Singh, Connor Monahan, Janani Iyer, Inshya Desai, Siddharth Karthikeyan, Dagny J Gould, Sneha Yennawar, Alexis T Weiner, Vijay Kumar Pounraja, Arjun Krishnan, Melissa M Rolls, Laura Anne Lowery, and Santhosh Girirajan

Subjects

Genetics, QH426-470

Abstract

We previously identified a deletion on chromosome 16p12.1 that is mostly inherited and associated with multiple neurodevelopmental outcomes, where severely affected probands carried an excess of rare pathogenic variants compared to mildly affected carrier parents. We hypothesized that the 16p12.1 deletion sensitizes the genome for disease, while "second-hits" in the genetic background modulate the phenotypic trajectory. To test this model, we examined how neurodevelopmental defects conferred by knockdown of individual 16p12.1 homologs are modulated by simultaneous knockdown of homologs of "second-hit" genes in Drosophila melanogaster and Xenopus laevis. We observed that knockdown of 16p12.1 homologs affect multiple phenotypic domains, leading to delayed developmental timing, seizure susceptibility, brain alterations, abnormal dendrite and axonal morphology, and cellular proliferation defects. Compared to genes within the 16p11.2 deletion, which has higher de novo occurrence, 16p12.1 homologs were less likely to interact with each other in Drosophila models or a human brain-specific interaction network, suggesting that interactions with "second-hit" genes may confer higher impact towards neurodevelopmental phenotypes. Assessment of 212 pairwise interactions in Drosophila between 16p12.1 homologs and 76 homologs of patient-specific "second-hit" genes (such as ARID1B and CACNA1A), genes within neurodevelopmental pathways (such as PTEN and UBE3A), and transcriptomic targets (such as DSCAM and TRRAP) identified genetic interactions in 63% of the tested pairs. In 11 out of 15 families, patient-specific "second-hits" enhanced or suppressed the phenotypic effects of one or many 16p12.1 homologs in 32/96 pairwise combinations tested. In fact, homologs of SETD5 synergistically interacted with homologs of MOSMO in both Drosophila and X. laevis, leading to modified cellular and brain phenotypes, as well as axon outgrowth defects that were not observed with knockdown of either individual homolog. Our results suggest that several 16p12.1 genes sensitize the genome towards neurodevelopmental defects, and complex interactions with "second-hit" genes determine the ultimate phenotypic manifestation.

Published

2021

4. Corrigendum: Wolf-Hirschhorn Syndrome-Associated Genes Are Enriched in Motile Neural Crest Cells and Affect Craniofacial Development in Xenopus laevis

Author

Alexandra Mills, Elizabeth Bearce, Rachael Cella, Seung Woo Kim, Megan Selig, Sangmook Lee, and Laura Anne Lowery

Subjects

craniofacial development, developmental disorders, Wolf-Hirschhorn Syndrome, WHSC1, WHSC2, LETM1, Physiology, QP1-981

Published

2021

5. NCBP2 modulates neurodevelopmental defects of the 3q29 deletion in Drosophila and Xenopus laevis models.

Author

Mayanglambam Dhruba Singh, Matthew Jensen, Micaela Lasser, Emily Huber, Tanzeen Yusuff, Lucilla Pizzo, Brian Lifschutz, Inshya Desai, Alexis Kubina, Sneha Yennawar, Sydney Kim, Janani Iyer, Diego E Rincon-Limas, Laura Anne Lowery, and Santhosh Girirajan

Subjects

Genetics, QH426-470

Abstract

The 1.6 Mbp deletion on chromosome 3q29 is associated with a range of neurodevelopmental disorders, including schizophrenia, autism, microcephaly, and intellectual disability. Despite its importance towards neurodevelopment, the role of individual genes, genetic interactions, and disrupted biological mechanisms underlying the deletion have not been thoroughly characterized. Here, we used quantitative methods to assay Drosophila melanogaster and Xenopus laevis models with tissue-specific individual and pairwise knockdown of 14 homologs of genes within the 3q29 region. We identified developmental, cellular, and neuronal phenotypes for multiple homologs of 3q29 genes, potentially due to altered apoptosis and cell cycle mechanisms during development. Using the fly eye, we screened for 314 pairwise knockdowns of homologs of 3q29 genes and identified 44 interactions between pairs of homologs and 34 interactions with other neurodevelopmental genes. Interestingly, NCBP2 homologs in Drosophila (Cbp20) and X. laevis (ncbp2) enhanced the phenotypes of homologs of the other 3q29 genes, leading to significant increases in apoptosis that disrupted cellular organization and brain morphology. These cellular and neuronal defects were rescued with overexpression of the apoptosis inhibitors Diap1 and xiap in both models, suggesting that apoptosis is one of several potential biological mechanisms disrupted by the deletion. NCBP2 was also highly connected to other 3q29 genes in a human brain-specific interaction network, providing support for the relevance of our results towards the human deletion. Overall, our study suggests that NCBP2-mediated genetic interactions within the 3q29 region disrupt apoptosis and cell cycle mechanisms during development.

Published

2020

6. The Many Faces of Xenopus: Xenopus laevis as a Model System to Study Wolf–Hirschhorn Syndrome

Author

Micaela Lasser, Benjamin Pratt, Connor Monahan, Seung Woo Kim, and Laura Anne Lowery

Subjects

Wolf–Hirschhorn syndrome, Xenopus, development, craniofacial, neural crest cells, Physiology, QP1-981

Abstract

Wolf–Hirschhorn syndrome (WHS) is a rare developmental disorder characterized by intellectual disability and various physical malformations including craniofacial, skeletal, and cardiac defects. These phenotypes, as they involve structures that are derived from the cranial neural crest, suggest that WHS may be associated with abnormalities in neural crest cell (NCC) migration. This syndrome is linked with assorted mutations on the short arm of chromosome 4, most notably the microdeletion of a critical genomic region containing several candidate genes. However, the function of these genes during embryonic development, as well as the cellular and molecular mechanisms underlying the disorder, are still unknown. The model organism Xenopus laevis offers a number of advantages for studying WHS. With the Xenopus genome sequenced, genetic manipulation strategies can be readily designed in order to alter the dosage of the WHS candidate genes. Moreover, a variety of assays are available for use in Xenopus to examine how manipulation of WHS genes leads to changes in the development of tissue and organ systems affected in WHS. In this review article, we highlight the benefits of using X. laevis as a model system for studying human genetic disorders of development, with a focus on WHS.

Published

2019

7. Wolf-Hirschhorn Syndrome-Associated Genes Are Enriched in Motile Neural Crest Cells and Affect Craniofacial Development in Xenopus laevis

Author

Alexandra Mills, Elizabeth Bearce, Rachael Cella, Seung Woo Kim, Megan Selig, Sangmook Lee, and Laura Anne Lowery

Subjects

craniofacial development, developmental disorders, Wolf-Hirschhorn Syndrome, WHSC1, WHSC2, LETM1, Physiology, QP1-981

Abstract

Wolf-Hirschhorn Syndrome (WHS) is a human developmental disorder arising from a hemizygous perturbation, typically a microdeletion, on the short arm of chromosome four. In addition to pronounced intellectual disability, seizures, and delayed growth, WHS presents with a characteristic facial dysmorphism and varying prevalence of microcephaly, micrognathia, cartilage malformation in the ear and nose, and facial asymmetries. These affected craniofacial tissues all derive from a shared embryonic precursor, the cranial neural crest (CNC), inviting the hypothesis that one or more WHS-affected genes may be critical regulators of neural crest development or migration. To explore this, we characterized expression of multiple genes within or immediately proximal to defined WHS critical regions, across the span of craniofacial development in the vertebrate model system Xenopus laevis. This subset of genes, whsc1, whsc2, letm1, and tacc3, are diverse in their currently-elucidated cellular functions; yet we find that their expression demonstrates shared tissue-specific enrichment within the anterior neural tube, migratory neural crest, and later craniofacial structures. We examine the ramifications of this by characterizing craniofacial development and neural crest migration following individual gene depletion. We observe that several WHS-associated genes significantly impact facial patterning, cartilage formation, neural crest motility in vivo and in vitro, and can separately contribute to forebrain scaling. Thus, we have determined that numerous genes within and surrounding the defined WHS critical regions potently impact craniofacial patterning, suggesting their role in WHS presentation may stem from essential functions during neural crest-derived tissue formation.

Published

2019

8. The Role of the Microtubule Cytoskeleton in Neurodevelopmental Disorders

Author

Micaela Lasser, Jessica Tiber, and Laura Anne Lowery

Subjects

cytoskeleton, microtubule dynamics, MAPs, neuronal migration, neurodevelopmental disorders, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neurons depend on the highly dynamic microtubule (MT) cytoskeleton for many different processes during early embryonic development including cell division and migration, intracellular trafficking and signal transduction, as well as proper axon guidance and synapse formation. The coordination and support from MTs is crucial for newly formed neurons to migrate appropriately in order to establish neural connections. Once connections are made, MTs provide structural integrity and support to maintain neural connectivity throughout development. Abnormalities in neural migration and connectivity due to genetic mutations of MT-associated proteins can lead to detrimental developmental defects. Growing evidence suggests that these mutations are associated with many different neurodevelopmental disorders, including intellectual disabilities (ID) and autism spectrum disorders (ASD). In this review article, we highlight the crucial role of the MT cytoskeleton in the context of neurodevelopment and summarize genetic mutations of various MT related proteins that may underlie or contribute to neurodevelopmental disorders.

Published

2018

9. TIPsy tour guides: How microtubule plus-end tracking proteins (+TIPs) facilitate axon guidance

Author

Elizabeth A Bearce, Burcu eErdogan, and Laura Anne Lowery

Subjects

Cytoskeleton, axon guidance, Growth cone, +TIPs, microtubule dynamics, plus-end tracking proteins, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The growth cone is a dynamic cytoskeletal vehicle, which drives the end of a developing axon. It serves to interpret and navigate through the complex landscape and guidance cues of the early nervous system. The growth cone’s distinctive cytoskeletal organization offers a fascinating platform to study how extracellular cues can be translated into mechanical outgrowth and turning behaviors. While many studies of cell motility highlight the importance of actin networks in signaling, adhesion, and propulsion, both seminal and emerging works in the field have highlighted a unique and necessary role for microtubules in growth cone navigation. Here, we focus on the role of singular pioneer microtubules, which extend into the growth cone periphery and are regulated by a diverse family of microtubule plus-end tracking proteins (+TIPs). These +TIPs accumulate at the dynamic ends of microtubules, where they are well-positioned to encounter and respond to key signaling events downstream of guidance receptors, catalyzing immediate changes in microtubule stability and actin cross-talk, that facilitate both axonal outgrowth and turning events.

Published

2015

10. Decision letter: Growth cone advance requires EB1 as revealed by genomic replacement with a light-sensitive variant

Author

Laura Anne Lowery and Feng-Quan Zhou

Published

2022

11. Investigating the impact of the phosphorylation status of tyrosine residues within the <scp>TACC</scp> domain of <scp>TACC3</scp> on microtubule behavior during axon growth and guidance

Author

Timothy Zaccaro, Riley M. St. Clair, Bryan A. Ballif, Garrett M. Cammarata, Burcu Erdogan, and Laura Anne Lowery

Subjects

Biology, Microtubules, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Structural Biology, Microtubule, medicine, Humans, Phosphorylation, Axon, Growth cone, 030304 developmental biology, 0303 health sciences, Tyrosine phosphorylation, Cell Biology, Axon Guidance, Cell biology, Intracellular signal transduction, medicine.anatomical_structure, chemistry, Tyrosine, Axon guidance, Neuron, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Signal Transduction

Abstract

Axon guidance is a critical process in forming the connections between a neuron and its target. The growth cone steers the growing axon toward the appropriate direction by integrating extracellular guidance cues and initiating intracellular signal transduction pathways downstream of these cues. The growth cone generates these responses by remodeling its cytoskeletal components. Regulation of microtubule dynamics within the growth cone is important for making guidance decisions. TACC3, as a microtubule plus-end binding (EB) protein, modulates microtubule dynamics during axon outgrowth and guidance. We have previously shown that Xenopus laevis embryos depleted of TACC3 displayed spinal cord axon guidance defects, while TACC3-overexpressing spinal neurons showed increased resistance to Slit2-induced growth cone collapse. Tyrosine kinases play an important role in relaying guidance signals to downstream targets during pathfinding events via inducing tyrosine phosphorylation. Here, in order to investigate the mechanism behind TACC3-mediated axon guidance, we examined whether tyrosine residues that are present in TACC3 have any role in regulating TACC3's interaction with microtubules or during axon outgrowth and guidance behaviors. We find that the phosphorylatable tyrosines within the TACC domain are important for the microtubule plus-end tracking behavior of TACC3. Moreover, TACC domain phosphorylation impacts axon outgrowth dynamics such as growth length and growth persistency. Together, our results suggest that tyrosine phosphorylation of TACC3 affects TACC3's microtubule plus-end tracking behavior as well as its ability to mediate axon growth dynamics in cultured embryonic neural tube explants.

Published

2020

12. 16p12.1 Deletion Orthologs are Expressed in Motile Neural Crest Cells and are Important for Regulating Craniofacial Development in

Author

Micaela, Lasser, Jessica, Bolduc, Luke, Murphy, Caroline, O'Brien, Sangmook, Lee, Santhosh, Girirajan, and Laura Anne, Lowery

Abstract

Copy number variants (CNVs) associated with neurodevelopmental disorders are characterized by extensive phenotypic heterogeneity. In particular, one CNV was identified in a subset of children clinically diagnosed with intellectual disabilities (ID) that results in a hemizygous deletion of multiple genes at chromosome 16p12.1. In addition to ID, individuals with this deletion display a variety of symptoms including microcephaly, seizures, cardiac defects, and growth retardation. Moreover, patients also manifest severe craniofacial abnormalities, such as micrognathia, cartilage malformation of the ears and nose, and facial asymmetries; however, the function of the genes within the 16p12.1 region have not been studied in the context of vertebrate craniofacial development. The craniofacial tissues affected in patients with this deletion all derive from the same embryonic precursor, the cranial neural crest, leading to the hypothesis that one or more of the 16p12.1 genes may be involved in regulating neural crest cell (NCC)-related processes. To examine this, we characterized the developmental role of the 16p12.1-affected gene orthologs

Published

2021

13. Imaging Methods in

Author

Lance A, Davidson and Laura Anne, Lowery

Subjects

Xenopus laevis, Embryo, Nonmammalian, Staining and Labeling, Larva, Morphogenesis, Animals, In Situ Hybridization, Article

Abstract

Xenopus is an excellent vertebrate model system ideally suited for a wide range of imaging methods designed to investigate cell and developmental biology processes. The individual cells of Xenopus are much larger than those in many other vertebrate model systems, such that both cell behavior and subcellular processes can more easily be observed and resolved. Gene function in Xenopus can be manipulated and visualized using a variety of approaches, and the embryonic fate map is stereotypical, such that microinjections can target specific tissues and cell types during development. Tissues, organotypic explants, and individual cells can also be mounted in stable chambers and cultured easily in simple salt solutions without cumbersome environmental controls. Furthermore, Xenopus embryonic tissues can be microsurgically isolated and shaped to expose cell behaviors and protein dynamics in any regions of the embryo to high resolution live-cell imaging. The combination of these attributes make Xenopus a powerful system for understanding cell and developmental processes as well as disease mechanisms, through quantitative analysis of protein dynamics, cell movements, tissue morphogenesis, and regeneration. Here, we describe various methods, of both fixed and living tissues, for visualizing Xenopus cells, embryos, and tadpoles. Specifically, we highlight protocol updates for whole-mount in situ hybridization and immunofluorescence, as well as powerful live imaging approaches including methods for optimizing the time-lapse imaging of whole embryos and explants.

Published

2021

14. Tau, XMAP215/Msps and Eb1 co-operate interdependently to regulate microtubule polymerisation and bundle formation in axons

Author

Judith B Fuelle, André Voelzmann, Laura Anne Lowery, Ines Hahn, Andreas Prokop, Natalia Sanchez-Soriano, Paula G. Slater, and Jill Parkin

Subjects

0301 basic medicine, Cancer Research, Life Cycles, Drosophila Proteins/metabolism, Xenopus, Mutant, Neurons/metabolism, Xenopus Proteins, QH426-470, Microtubules, Polymerization, Xenopus laevis, 0302 clinical medicine, Nerve Fibers, Larvae, Animal Cells, Drosophila Proteins, Axon, Genetics (clinical), Cytoskeleton, Neurons, 0303 health sciences, Chemistry, Drosophila Melanogaster, Neurodegeneration, Chemical Reactions, Eukaryota, Animal Models, Axon growth, Cell biology, Insects, Phenotypes, medicine.anatomical_structure, Experimental Organism Systems, Microtubules/metabolism, Physical Sciences, Vertebrates, Microtubule-Associated Proteins/metabolism, Frogs, Drosophila, Drosophila melanogaster, Cellular Types, Cellular Structures and Organelles, Xenopus laevis/metabolism, Microtubule-Associated Proteins, Research Article, Arthropoda, tau Proteins, Axons/metabolism, macromolecular substances, Biology, Xenopus Proteins/metabolism, Research and Analysis Methods, Drosophila melanogaster/metabolism, Amphibians, 03 medical and health sciences, Model Organisms, tau Proteins/metabolism, Microtubule, medicine, Genetics, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, fungi, Organisms, Biology and Life Sciences, Cell Biology, medicine.disease, biology.organism_classification, Polymer Chemistry, Invertebrates, Axons, 030104 developmental biology, Bundle, Cellular Neuroscience, Axoplasmic transport, Animal Studies, Zoology, Entomology, 030217 neurology & neurosurgery, Neuroscience, Developmental Biology

Abstract

The formation and maintenance of microtubules requires their polymerisation, but little is known about how this polymerisation is regulated in cells. Focussing on the essential microtubule bundles in axons of Drosophila and Xenopus neurons, we show that the plus-end scaffold Eb1, the polymerase XMAP215/Msps and the lattice-binder Tau co-operate interdependently to promote microtubule polymerisation and bundle organisation during axon development and maintenance. Eb1 and XMAP215/Msps promote each other’s localisation at polymerising microtubule plus-ends. Tau outcompetes Eb1-binding along microtubule lattices, thus preventing depletion of Eb1 tip pools. The three factors genetically interact and show shared mutant phenotypes: reductions in axon growth, comet sizes, comet numbers and comet velocities, as well as prominent deterioration of parallel microtubule bundles into disorganised curled conformations. This microtubule curling is caused by Eb1 plus-end depletion which impairs spectraplakin-mediated guidance of extending microtubules into parallel bundles. Our demonstration that Eb1, XMAP215/Msps and Tau co-operate during the regulation of microtubule polymerisation and bundle organisation, offers new conceptual explanations for developmental and degenerative axon pathologies., Author summary Axons are the up-to-meter-long processes of nerve cells that form the cables wiring our nervous system. Once established, they must survive for a century in humans. Improper extension of axons leads to neurodevelopmental defects, and age- or disease-related neurodegeneration usually starts in axons. Axonal architecture and function depend on bundles of filamentous polymers, called microtubules. These bundles run all along the axonal core, and their disruption correlates with axon decay. How these axonal microtubule bundles are formed and dynamically maintained is little understood. We bridge this knowledge gap by studying how different classes of microtubule-binding proteins may regulate these processes. Here we show how three proteins of very different function, Eb1, XMAP215 and Tau, cooperate intricately to promote the polymerisation processes that form new microtubules during axon development and maintenance. If either protein is dysfunctional, polymerisation is slowed down and newly forming microtubules fail to align into proper bundles. These findings provide new explanations for the decay of microtubule bundles, hence axons. To unravel these mechanisms, we used the fruit fly as a powerful organism for biomedical discoveries. We then showed that the same mechanisms act in frog axons, suggesting they might apply also to humans.

Published

2021

15. Regulation of MT dynamics via direct binding of an Abl family kinase

Author

Yuhan Hu, Wanqing Lyu, Laura Anne Lowery, and Anthony J. Koleske

Subjects

Swine, Static Electricity, macromolecular substances, Plasma protein binding, ABL2, Microtubules, Polymerization, 03 medical and health sciences, Mice, Protein Domains, Microtubule, Cell Movement, Tubulin, hemic and lymphatic diseases, Report, Chlorocebus aethiops, Animals, Cytoskeleton, neoplasms, Cell Shape, Research Articles, 030304 developmental biology, 0303 health sciences, COS cells, ABL, biology, Kinase, 030302 biochemistry & molecular biology, Brain, Cell Biology, 3T3 Cells, Fibroblasts, Protein-Tyrosine Kinases, Cell biology, COS Cells, biology.protein, Protein Binding

Abstract

Genetic studies revealed that Abl family kinases interact functionally with microtubules, but the mechanism by which Abl kinases regulate microtubules remains unclear. Hu et al. provide the first evidence that the Abl family kinase Abl2 directly binds microtubules to regulate microtubule dynamics., Abl family kinases are essential regulators of cell shape and movement. Genetic studies revealed functional interactions between Abl kinases and microtubules (MTs), but the mechanism by which Abl family kinases regulate MTs remains unclear. Here, we report that Abl2 directly binds to MTs and regulates MT behaviors. Abl2 uses its C-terminal half to bind MTs, an interaction mediated in part through electrostatic binding to tubulin C-terminal tails. Using purified proteins, we found that Abl2 binds growing MTs and promotes MT polymerization and stability. In cells, knockout of Abl2 significantly impairs MT growth, and this defect can be rescued via reexpression of Abl2. Stable reexpression of an Abl2 fragment containing the MT-binding domain alone was sufficient to restore MT growth at the cell edge. These results show Abl2 uses its C-terminal half to bind MTs and directly regulate MT dynamics.

Published

2019

16. Tacc3 modulates microtubule network dynamicity and focal adhesion remodeling to affect cranial neural crest cell migration in Xenopus laevis

Author

Leslie Carandang, Erin L. Rutherford, Benjamin Pratt, Elizabeth A. Bearce, and Laura Anne Lowery

Subjects

Focal adhesion, Cranial neural crest, biology, Microtubule, Chemistry, Xenopus, Neural crest, Motility, Cell migration, biology.organism_classification, Cytoskeleton, Cell biology

Abstract

Coordinated cell migration is critical during embryogenesis, as cells must leave their point of origin, navigate a complex barrage of signals, and accurately position themselves to facilitate correct tissue and organ formation. The cell motility process relies on dynamic interactions of the F-actin and microtubule (MT) cytoskeletons. Our work focuses on how one MT plus-end regulator, Transforming Acidic Coiled-Coil 3 (Tacc3), can impact migration of cranial neural crest cells in Xenopus laevis. We previously demonstrated that tacc3 expression is expressed in cranial neural crest cells, and that Tacc3 can function as a MT plus-end tracking protein to regulate MT growth velocities. Here, we demonstrate that manipulation of Tacc3 protein levels is sufficient to alter cranial neural crest cell velocity in vitro. Tacc3 overexpression drives increased single-cell migration velocities, while Tacc3 KD results in reduced cell velocity and defective explant dispersion. We also show that Tacc3 can have spatially-enhanced effects on MT plus-end growth velocities as well as effects on focal adhesion remodeling. Together, we demonstrate that Tacc3 can facilitate neural crest cell motility through spatially-enhanced cytoskeletal remodeling, which may underlie the enhanced metastatic potential of Tacc3-overexpressing tumor cells.

Published

2021

17. Wolf-Hirschhorn Syndrome-Associated Genes Are Enriched in Motile Neural Crest Cells and Affect Craniofacial Development in Xenopus laevis

Author

Alexandra Mills, Elizabeth Bearce, Rachael Cella, Seung Woo Kim, Megan Selig, Sangmook Lee, and Laura Anne Lowery

Subjects

TACC3, WHSC2, lcsh:QP1-981, Physiology, Wolf-Hirschhorn Syndrome, Physiology (medical), Correction, developmental disorders, LETM1, craniofacial development, neural crest, WHSC1, lcsh:Physiology

Published

2021

18. 16p12.1 deletion orthologs are expressed in motile neural crest cells and are important for regulating craniofacial development inXenopus laevis

Author

Sangmook Lee, Santhosh Girirajan, Micaela Lasser, Laura Anne Lowery, Bolduc J, O'Brien C, and Murphy L

Subjects

Microcephaly, medicine.anatomical_structure, Cranial neural crest, Craniofacial abnormality, medicine, Neural tube, Neural crest, Context (language use), Biology, Craniofacial, medicine.disease, Pharyngeal arch, Cell biology

Abstract

Copy number variants (CNVs) associated with neurodevelopmental disorders are characterized by extensive phenotypic heterogeneity. In particular, one CNV was identified in a subset of children clinically diagnosed with intellectual disabilities (ID) that results in a hemizygous deletion of multiple genes at chromosome 16p12.1. In addition to ID, individuals with this deletion display a variety of symptoms including microcephaly, seizures, cardiac defects, and growth retardation. Moreover, patients also manifest severe craniofacial abnormalities, such as micrognathia, cartilage malformation of the ears and nose, and facial asymmetries; however, the function of the genes within the 16p12.1 region have not been studied in the context of vertebrate craniofacial development. The craniofacial tissues affected in patients with this deletion all derive from the same embryonic precursor, the cranial neural crest, leading to the hypothesis that one or more of the 16p12.1 genes may be involved in regulating neural crest cell (NCC)-related processes. To examine this, we characterized the developmental role of the 16p12.1-affected gene orthologs,polr3e,mosmo,uqcrc2, andcdr2, during craniofacial morphogenesis in the vertebrate model system,Xenopus laevis. While the currently-known cellular functions of these genes are diverse, we find that they share similar expression patterns along the neural tube, pharyngeal arches, and later craniofacial structures. As these genes show co-expression in the pharyngeal arches where NCCs reside, we sought to elucidate the effect of individual gene depletion on craniofacial development and NCC migration. We find that reduction of several 16p12.1 genes significantly disrupts craniofacial and cartilage formation, pharyngeal arch migration, as well as NCC specification and motility. Thus, we have determined that some of these genes play an essential role during vertebrate craniofacial patterning by regulating specific processes during NCC development, which may be an underlying mechanism contributing to the craniofacial defects associated with the 16p12.1 deletion.

Published

2020

19. Live Imaging of Cytoskeletal Dynamics in Embryonic

Author

Burcu, Erdogan, Elizabeth A, Bearce, and Laura Anne, Lowery

Subjects

Neurons, Actin Cytoskeleton, Xenopus laevis, Embryo, Nonmammalian, Microscopy, Confocal, Microscopy, Fluorescence, Neural Crest, Growth Cones, Animals, Microtubules, Cells, Cultured, Cytoskeleton, Article

Abstract

The cytoskeleton is a dynamic, fundamental network that not only provides mechanical strength to maintain a cell’s shape, but also controls critical events like cell division, polarity, and movement. Thus, how the cytoskeleton is organized and dynamically regulated is critical to our understanding of countless processes. Live imaging of fluorophore tagged cytoskeletal proteins allows us to monitor the dynamic nature of cytoskeleton components in embryonic cells. Here, we describe a protocol to monitor and analyze cytoskeletal dynamics in primary embryonic neuronal growth cones and neural crest cells obtained from Xenopus laevis embryos.

Published

2020

20. Functional assessment of the 'two-hit' model for neurodevelopmental defects inDrosophilaandX. laevis

Author

Connor Monahan, Arjun Krishnan, Emily Huber, Alexis T. Weiner, Laura Anne Lowery, Matthew Jensen, Melissa M. Rolls, Lucilla Pizzo, Sneha Yennawar, Inshya Desai, Vijay Kumar Pounraja, Tanzeen Yusuff, Phoebe Ingraham, Siddharth Karthikeyan, Janani Iyer, Santhosh Girirajan, Micaela Lasser, Mayanglambam Dhruba Singh, and Dagny J. Gould

Subjects

Proband, Genetics, DSCAM, Homologous chromosome, Xenopus, Biology, Drosophila melanogaster, biology.organism_classification, Gene, Phenotype, Genome

Abstract

We previously identified a deletion on chromosome 16p12.1 that is mostly inherited and associated with multiple neurodevelopmental outcomes, where severely affected probands carried an excess of rare pathogenic variants compared to mildly affected carrier parents. We hypothesized that the 16p12.1 deletion sensitizes the genome for disease, while “second-hits” in the genetic background modulate the phenotypic trajectory. To test this model, we examined how neurodevelopmental defects conferred by knockdown of individual 16p12.1 homologs are modulated by simultaneous knockdown of homologs of “second-hit” genes inDrosophila melanogasterandXenopus laevis. We observed that knockdown of 16p12.1 homologs affect multiple phenotypic domains, leading to delayed developmental timing, seizure susceptibility, brain alterations, abnormal dendrite and axonal morphology, and cellular proliferation defects. Compared to genes within the 16p11.2 deletion, which has higherde novooccurrence, 16p12.1 homologs were less likely to interact with each other inDrosophilamodels or a human brain-specific interaction network, suggesting that interactions with “second-hit” genes may confer higher impact towards neurodevelopmental phenotypes. Assessment of 212 pairwise interactions inDrosophilabetween 16p12.1 homologs and 76 homologs of patient-specific “second-hit” genes (such asARID1BandCACNA1A), genes within neurodevelopmental pathways (such asPTENandUBE3A), and transcriptomic targets (such asDSCAMandTRRAP) identified genetic interactions in 63% of the tested pairs. In 11 out of 15 families, homologs of patient-specific “second-hits” enhanced or suppressed the phenotypic effects of one or many 16p12.1 homologs. In fact, homologs ofSETD5synergistically interacted with homologs ofMOSMOin bothDrosophilaandX. laevis, leading to modified cellular and brain phenotypes, as well as axon outgrowth defects that were not observed with knockdown of either individual homolog. Our results suggest that several 16p12.1 genes sensitize the genome towards neurodevelopmental defects, and complex interactions with “second-hit” genes determine the ultimate phenotypic manifestation.Author SummaryCopy-number variants, or deletions and duplications in the genome, are associated with multiple neurodevelopmental disorders. The developmental delay-associated 16p12.1 deletion is mostly inherited, and severely affected children carry an excess of “second-hits” variants compared to mildly affected carrier parents, suggesting that additional variants modulate the clinical manifestation. We studied this “two-hit” model usingDrosophilaandXenopus laevis, and systematically tested how homologs of “second-hit” genes modulate neurodevelopmental defects observed for 16p12.1 homologs. We observed that 16p12.1 homologs independently led to multiple neurodevelopmental features and weakly interacted with each other, suggesting that interactions with “second-hit” homologs potentially have a higher impact towards neurodevelopmental defects than interactions between 16p12.1 homologs. We tested 212 pairwise interactions of 16p12.1 homologs with “second-hit” homologs and genes within conserved neurodevelopmental pathways, and observed modulation of neurodevelopmental defects caused by 16p12.1 homologs in 11 out of 15 families, and 16/32 of these changes could be attributed to genetic interactions. Interestingly, we observed thatSETD5homologs interacted with homologs ofMOSMO, which conferred additional neuronal phenotypes not observed with knockdown of individual homologs. We propose that the 16p12.1 deletion sensitizes the genome to multiple neurodevelopmental defects, and complex interactions with “second-hit” genes determine the clinical trajectory of the disorder.

Published

2020

21. Abelson-induced phosphorylation of TACC3 modulates its interaction with microtubules and affects its impact on axon outgrowth and guidance

Author

Riley M. St. Clair, Bryan A. Ballif, Burcu Erdogan, Laura Anne Lowery, Timothy Zaccaro, and Garrett M. Cammarata

Subjects

0303 health sciences, Chemistry, Tyrosine phosphorylation, Cell biology, Intracellular signal transduction, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine.anatomical_structure, nervous system, Microtubule, medicine, Phosphorylation, Axon guidance, Neuron, Axon, Growth cone, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Axon guidance is a critical process in forming the connections between a neuron and its target. The growth cone steers the growing axon towards the appropriate direction by integrating extracellular guidance cues and initiating intracellular signal transduction pathways downstream of these cues. The growth cone generates these responses by remodeling its cytoskeletal components. Regulation of microtubule dynamics within the growth cone is important for making guidance decisions. TACC3, as a microtubule plus-end binding protein, modulates microtubule dynamics during axon outgrowth and guidance. We have previously shown that embryos depleted of TACC3 displayed spinal cord axon guidance defects, while TACC3-overexpressing spinal neurons showed increased resistance to Slit2-induced growth cone collapse. Here, in order to investigate the mechanism behind TACC3-mediated axon guidance, we studied the importance of tyrosine phosphorylation induced by Abelson tyrosine kinase. We find that the phosphorylatable tyrosines within the TACC domain are important for the microtubule plus-end tracking behavior of TACC3. Moreover, TACC domain phosphorylation impacts axon outgrowth and guidance, and it also regulates microtubule extension into the growth cone periphery. Together, our results suggest that phosphorylation of TACC3 is a key regulatory mechanism by which TACC3 controls axon outgrowth and pathfinding decisions of neurons during embryonic development.

Published

2020

22. Imaging Methods in Xenopus Cells, Embryos, and Tadpoles

Author

Lance A. Davidson and Laura Anne Lowery

Subjects

Cell type, Live cell imaging, Fate mapping, Regeneration (biology), Morphogenesis, Xenopus, Biology, biology.organism_classification, Developmental biology, Embryonic stem cell, General Biochemistry, Genetics and Molecular Biology, Cell biology

Abstract

Xenopus is an excellent vertebrate model system ideally suited for a wide range of imaging methods designed to investigate cell and developmental biology processes. The individual cells of Xenopus are much larger than those in many other vertebrate model systems, such that both cell behavior and subcellular processes can more easily be observed and resolved. Gene function in Xenopus can be manipulated and visualized using a variety of approaches, and the embryonic fate map is stereotypical, such that microinjections can target specific tissues and cell types during development. Tissues, organotypic explants, and individual cells can also be mounted in stable chambers and cultured easily in simple salt solutions without cumbersome environmental controls. Furthermore, Xenopus embryonic tissues can be microsurgically isolated and shaped to expose cell behaviors and protein dynamics in any regions of the embryo to high-resolution live-cell imaging. The combination of these attributes makes Xenopus a powerful system for understanding cell and developmental processes as well as disease mechanisms, through quantitative analysis of protein dynamics, cell movements, tissue morphogenesis, and regeneration. Here, we introduce various methods, of both fixed and living tissues, for visualizing Xenopus cells, embryos, and tadpoles. Specifically, we highlight protocol updates for whole-mount in situ hybridization and immunofluorescence, as well as robust live imaging approaches including methods for optimizing the time-lapse imaging of whole embryos and explants.

Published

2021

23. NCBP2 modulates neurodevelopmental defects of the 3q29 deletion in Drosophila and Xenopus laevis models

Author

Mayanglambam Dhruba Singh, Tanzeen Yusuff, Lucilla Pizzo, Santhosh Girirajan, Matthew Jensen, Sneha Yennawar, Sydney Kim, Micaela Lasser, Inshya Desai, Alexis Kubina, Laura Anne Lowery, Brian Lifschutz, Diego E. Rincon-Limas, Janani Iyer, and Emily Huber

Subjects

Cancer Research, Embryo, Nonmammalian, Developmental Disabilities, Xenopus, Apoptosis, QH426-470, Xenopus Proteins, Biochemistry, Xenopus laevis, 0302 clinical medicine, RNA interference, Medicine and Health Sciences, Drosophila Proteins, Gene Regulatory Networks, Genetics (clinical), Regulation of gene expression, Staining, 0303 health sciences, Gene knockdown, biology, Cell Death, Drosophila Melanogaster, Cell Cycle, Brain, Gene Expression Regulation, Developmental, Eukaryota, Cell Staining, Animal Models, Phenotype, Cell biology, Nucleic acids, Insects, Phenotypes, Genetic interference, Experimental Organism Systems, Cell Processes, Gene Knockdown Techniques, Vertebrates, Frogs, Hyperexpression Techniques, Female, Epigenetics, Drosophila, Chromosomes, Human, Pair 3, Drosophila melanogaster, Chromosome Deletion, Anatomy, Research Article, Arthropoda, Embryonic Development, Research and Analysis Methods, Amphibians, 03 medical and health sciences, Model Organisms, Ocular System, Intellectual Disability, Homologous chromosome, Genetics, Gene Expression and Vector Techniques, Animals, Humans, Molecular Biology Techniques, Gene, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Nuclear Cap-Binding Protein Complex, 030304 developmental biology, Molecular Biology Assays and Analysis Techniques, Organisms, Biology and Life Sciences, Cell Biology, biology.organism_classification, Invertebrates, Disease Models, Animal, Specimen Preparation and Treatment, Animal Studies, Eyes, RNA, Gene expression, Head, 030217 neurology & neurosurgery

Abstract

The 1.6 Mbp deletion on chromosome 3q29 is associated with a range of neurodevelopmental disorders, including schizophrenia, autism, microcephaly, and intellectual disability. Despite its importance towards neurodevelopment, the role of individual genes, genetic interactions, and disrupted biological mechanisms underlying the deletion have not been thoroughly characterized. Here, we used quantitative methods to assay Drosophila melanogaster and Xenopus laevis models with tissue-specific individual and pairwise knockdown of 14 homologs of genes within the 3q29 region. We identified developmental, cellular, and neuronal phenotypes for multiple homologs of 3q29 genes, potentially due to altered apoptosis and cell cycle mechanisms during development. Using the fly eye, we screened for 314 pairwise knockdowns of homologs of 3q29 genes and identified 44 interactions between pairs of homologs and 34 interactions with other neurodevelopmental genes. Interestingly, NCBP2 homologs in Drosophila (Cbp20) and X. laevis (ncbp2) enhanced the phenotypes of homologs of the other 3q29 genes, leading to significant increases in apoptosis that disrupted cellular organization and brain morphology. These cellular and neuronal defects were rescued with overexpression of the apoptosis inhibitors Diap1 and xiap in both models, suggesting that apoptosis is one of several potential biological mechanisms disrupted by the deletion. NCBP2 was also highly connected to other 3q29 genes in a human brain-specific interaction network, providing support for the relevance of our results towards the human deletion. Overall, our study suggests that NCBP2-mediated genetic interactions within the 3q29 region disrupt apoptosis and cell cycle mechanisms during development., Author summary Rare copy-number variants, or large deletions and duplications in the genome, are associated with a wide range of neurodevelopmental disorders. The 3q29 deletion confers an increased risk for schizophrenia and autism. To understand the conserved biological mechanisms that are disrupted by this deletion, we systematically tested 14 individual homologs and 314 pairwise interactions of 3q29 genes for neuronal, cellular, and developmental phenotypes in Drosophila melanogaster and Xenopus laevis models. We found that multiple homologs of genes within the deletion region contribute towards developmental defects, such as larval lethality and disrupted cellular organization. Interestingly, we found that NCBP2 acts as a key modifier gene within the region, enhancing the developmental phenotypes of each of the homologs for other 3q29 genes and leading to disruptions in apoptosis and cell cycle pathways. Our results suggest that multiple genes within the 3q29 region interact with each other through shared mechanisms and jointly contribute to neurodevelopmental defects.

Published

2019

24. NCBP2modulates neurodevelopmental defects of the 3q29 deletion inDrosophilaandX. laevismodels

Author

Santhosh Girirajan, Mayanglambam Dhruba Singh, Tanzeen Yusuff, Alexis Kubina, Brian Lifschutz, Matthew Jensen, Lucilla Pizzo, Micaela Lasser, Sydney Kim, Emily Huber, Janani Iyer, Diego E. Rincon-Limas, Sneha Yennawar, Laura Anne Lowery, and Inshya Desai

Subjects

Genetics, 0303 health sciences, Gene knockdown, biology, Apoptosis Inhibitor, Xenopus, biology.organism_classification, Genome, Phenotype, XIAP, 03 medical and health sciences, 0302 clinical medicine, Drosophila melanogaster, Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The 1.6 Mbp deletion on chromosome 3q29 is associated with a range of neurodevelopmental disorders, including schizophrenia, autism, microcephaly, and intellectual disability. Despite its importance towards neurodevelopment, the role of individual genes, genetic interactions, and disrupted biological mechanisms underlying the deletion have not been thoroughly characterized. Here, we used quantitative methods to assayDrosophila melanogasterandXenopus laevismodels with tissue-specific individual and pairwise knockdown of 14 homologs of genes within the 3q29 region. We identified developmental, cellular, and neuronal phenotypes for multiple homologs of 3q29 genes, potentially due to altered apoptosis and cell cycle mechanisms during development. Using the fly eye, we screened for 314 pairwise knockdowns of homologs of 3q29 genes and identified 44 interactions between pairs of homologs and 34 interactions with other neurodevelopmental genes. Interestingly,NCBP2homologs inDrosophila(Cbp20) andX. laevis(ncbp2) enhanced the phenotypes of homologs of the other 3q29 genes, leading to significant increases in apoptosis that disrupted cellular organization and brain morphology. These cellular and neuronal defects were rescued with overexpression of the apoptosis inhibitorsDiap1andxiapin both models, suggesting that apoptosis is one of several potential biological mechanisms disrupted by the deletion.NCBP2was also highly connected to other 3q29 genes in a human brain-specific interaction network, providing support for the relevance of our results towards the human deletion. Overall, our study suggests thatNCBP2-mediated genetic interactions within the 3q29 region disrupt apoptosis and cell cycle mechanisms during development.AUTHOR SUMMARYRare copy-number variants, or large deletions and duplications in the genome, are associated with a wide range of neurodevelopmental disorders. The 3q29 deletion confers an increased risk for schizophrenia, autism, and microcephaly. To understand the conserved biological mechanisms that are disrupted by this deletion, we systematically tested 14 individual homologs and 314 pairwise interactions of 3q29 genes for neuronal, cellular, and developmental phenotypes inDrosophila melanogasterandXenopus laevismodels. We found that multiple homologs of genes within the deletion region contribute towards developmental defects, such as larval lethality and disrupted cellular organization. Interestingly, we found thatNCBP2acts as a key modifier gene within the region, enhancing the developmental phenotypes of each of the homologs for other 3q29 genes and leading to disruptions in apoptosis and cell cycle pathways. Our results suggest that multiple genes within the 3q29 region interact with each other through shared mechanisms and jointly contribute to neurodevelopmental defects.

Published

2019

25. Wolf-Hirschhorn Syndrome-Associated Genes Are Enriched in Motile Neural Crest Cells and Affect Craniofacial Development in Xenopus laevis

Author

Laura Anne Lowery, Megan Selig, Rachael Cella, Alexandra Mills, Sangmook Lee, Seung Woo Kim, and Elizabeth A. Bearce

Subjects

Microcephaly, Physiology, Xenopus, lcsh:Physiology, 03 medical and health sciences, 0302 clinical medicine, Cranial neural crest, WHSC2, Physiology (medical), medicine, developmental disorders, Craniofacial, Wolf–Hirschhorn syndrome, WHSC1, 030304 developmental biology, Original Research, 0303 health sciences, biology, lcsh:QP1-981, Wolf-Hirschhorn Syndrome, Neural tube, Neural crest, LETM1, biology.organism_classification, medicine.disease, craniofacial development, TACC3, medicine.anatomical_structure, Forebrain, Neuroscience, neural crest, 030217 neurology & neurosurgery

Abstract

Wolf-Hirschhorn Syndrome (WHS) is a human developmental disorder arising from a hemizygous perturbation, typically a microdeletion, on the short arm of chromosome four. In addition to pronounced intellectual disability, seizures, and delayed growth, WHS presents with a characteristic facial dysmorphism and varying prevalence of microcephaly, micrognathia, cartilage malformation in the ear and nose, and facial asymmetries. These affected craniofacial tissues all derive from a shared embryonic precursor, the cranial neural crest (CNC), inviting the hypothesis that one or more WHS-affected genes may be critical regulators of neural crest development or migration. To explore this, we characterized expression of multiple genes within or immediately proximal to defined WHS critical regions, across the span of craniofacial development in the vertebrate model systemXenopus laevis. This subset of genes,whsc1,whsc2,letm1, andtacc3, are diverse in their currently-elucidated cellular functions; yet we find that their expression demonstrates shared tissue-specific enrichment within the anterior neural tube, migratory neural crest, and later craniofacial structures. We examine the ramifications of this by characterizing craniofacial development and neural crest migration following individual gene depletion. We observe that several WHS-associated genes significantly impact facial patterning, cartilage formation, neural crest motilityin vivoandin vitro, and can separately contribute to forebrain scaling. Thus, we have determined that numerous genes within and surrounding the defined WHS critical regions potently impact craniofacial patterning, suggesting their role in WHS presentation may stem from essential functions during neural crest-derived tissue formation.

Published

2019

26. XMAP215 promotes microtubule-F-actin interactions to regulate growth cone microtubules during axon guidance

Author

Yuhan Hu, Annika G. Samuelson, Alexandra Magee, Laura Anne Lowery, Garrett M. Cammarata, and Paula G. Slater

Subjects

CKAP5, Growth Cones, Xenopus, macromolecular substances, Xenopus Proteins, Biology, Microtubules, Xenopus laevis, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Animals, Cytoskeleton, Growth cone, Actin, 030304 developmental biology, 0303 health sciences, Cell Biology, biology.organism_classification, Ephrin-A5, Actins, Axons, Axon Guidance, Cell biology, Actin Cytoskeleton, Axon guidance, Ephrin A5, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Research Article

Abstract

It has long been established that neuronal growth cone navigation depends on changes in microtubule (MT) and F-actin architecture downstream of guidance cues. However, the mechanisms by which MTs and F-actin are dually coordinated remain a fundamentally unresolved question. Here, we report that the well-characterized MT polymerase, XMAP215 (also known as CKAP5), plays an important role in mediating MT–F-actin interaction within the growth cone. We demonstrate that XMAP215 regulates MT–F-actin alignment through its N-terminal TOG 1–5 domains. Additionally, we show that XMAP215 directly binds to F-actin in vitro and co-localizes with F-actin in the growth cone periphery. We also find that XMAP215 is required for regulation of growth cone morphology and response to the guidance cue, Ephrin A5. Our findings provide the first strong evidence that XMAP215 coordinates MT and F-actin interaction in vivo. We suggest a model in which XMAP215 regulates MT extension along F-actin bundles into the growth cone periphery and that these interactions may be important to control cytoskeletal dynamics downstream of guidance cues. This article has an associated First Person interview with the first author of the paper.

Published

2019

27. Functional assessment of the 'two-hit' model for neurodevelopmental defects in Drosophila and X. laevis

Author

Sneha Yennawar, Emily Huber, Janani Iyer, Tanzeen Yusuff, Alexis T. Weiner, Siddharth Karthikeyan, Phoebe Ingraham, Vijay Kumar Pounraja, Micaela Lasser, Connor Monahan, Mayanglambam Dhruba Singh, Dagny J. Gould, Inshya Desai, Laura Anne Lowery, Lucilla Pizzo, Arjun Krishnan, Santhosh Girirajan, Matthew Jensen, and Melissa M. Rolls

Subjects

Life Cycles, Cancer Research, Xenopus, Gene Identification and Analysis, Oligonucleotides, Xenopus Proteins, Morpholino, QH426-470, Biochemistry, Genome, Xenopus laevis, RNA interference, Larvae, 0302 clinical medicine, Medicine and Health Sciences, Drosophila Proteins, Antisense Oligonucleotides, Genetics (clinical), Genetics, 0303 health sciences, Gene knockdown, biology, Nucleotides, Drosophila Melanogaster, Brain, Gene Expression Regulation, Developmental, Nuclear Proteins, Eukaryota, Animal Models, Phenotype, DNA-Binding Proteins, Insects, Nucleic acids, Phenotypes, Experimental Organism Systems, Genetic interference, Vertebrates, Frogs, Drosophila, Epigenetics, Chromosome Deletion, Anatomy, Drosophila melanogaster, Research Article, Arthropoda, Ubiquitin-Protein Ligases, Research and Analysis Methods, Amphibians, 03 medical and health sciences, DSCAM, Model Organisms, Ocular System, Animals, Humans, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, Adaptor Proteins, Signal Transducing, 030304 developmental biology, PTEN Phosphohydrolase, Organisms, Biology and Life Sciences, Epistasis, Genetic, Methyltransferases, biology.organism_classification, Invertebrates, Disease Models, Animal, Genetic Interactions, Neurodevelopmental Disorders, Animal Studies, Eyes, RNA, Calcium Channels, Gene expression, Cell Adhesion Molecules, Head, Zoology, Entomology, Chromosomes, Human, Pair 16, 030217 neurology & neurosurgery, Transcription Factors, Developmental Biology

Abstract

We previously identified a deletion on chromosome 16p12.1 that is mostly inherited and associated with multiple neurodevelopmental outcomes, where severely affected probands carried an excess of rare pathogenic variants compared to mildly affected carrier parents. We hypothesized that the 16p12.1 deletion sensitizes the genome for disease, while “second-hits” in the genetic background modulate the phenotypic trajectory. To test this model, we examined how neurodevelopmental defects conferred by knockdown of individual 16p12.1 homologs are modulated by simultaneous knockdown of homologs of “second-hit” genes in Drosophila melanogaster and Xenopus laevis. We observed that knockdown of 16p12.1 homologs affect multiple phenotypic domains, leading to delayed developmental timing, seizure susceptibility, brain alterations, abnormal dendrite and axonal morphology, and cellular proliferation defects. Compared to genes within the 16p11.2 deletion, which has higher de novo occurrence, 16p12.1 homologs were less likely to interact with each other in Drosophila models or a human brain-specific interaction network, suggesting that interactions with “second-hit” genes may confer higher impact towards neurodevelopmental phenotypes. Assessment of 212 pairwise interactions in Drosophila between 16p12.1 homologs and 76 homologs of patient-specific “second-hit” genes (such as ARID1B and CACNA1A), genes within neurodevelopmental pathways (such as PTEN and UBE3A), and transcriptomic targets (such as DSCAM and TRRAP) identified genetic interactions in 63% of the tested pairs. In 11 out of 15 families, patient-specific “second-hits” enhanced or suppressed the phenotypic effects of one or many 16p12.1 homologs in 32/96 pairwise combinations tested. In fact, homologs of SETD5 synergistically interacted with homologs of MOSMO in both Drosophila and X. laevis, leading to modified cellular and brain phenotypes, as well as axon outgrowth defects that were not observed with knockdown of either individual homolog. Our results suggest that several 16p12.1 genes sensitize the genome towards neurodevelopmental defects, and complex interactions with “second-hit” genes determine the ultimate phenotypic manifestation., Author summary Copy-number variants, or deletions and duplications in the genome, are associated with multiple neurodevelopmental disorders. The developmental delay-associated 16p12.1 deletion is mostly inherited, and severely affected children carry an excess of “second-hits” variants compared to mildly affected carrier parents, suggesting that additional variants modulate the clinical manifestation. We studied this “two-hit” model using Drosophila and Xenopus laevis, and systematically tested how homologs of “second-hit” genes modulate neurodevelopmental defects observed for 16p12.1 homologs. We observed that 16p12.1 homologs independently led to multiple neurodevelopmental features and weakly interacted with each other, suggesting that interactions with “second-hit” homologs potentially have a higher impact towards neurodevelopmental defects than interactions between 16p12.1 homologs. We tested 212 pairwise interactions of 16p12.1 homologs with “second-hit” homologs and genes within conserved neurodevelopmental pathways, and observed modulation of neurodevelopmental defects caused by 16p12.1 homologs in 11 out of 15 families, and 16/32 of these changes could be attributed to genetic interactions. Interestingly, we observed that SETD5 homologs interacted with homologs of MOSMO, which conferred additional neuronal phenotypes not observed with knockdown of individual homologs. We propose that the 16p12.1 deletion sensitizes the genome to multiple neurodevelopmental defects, and complex interactions with “second-hit” genes determine the clinical trajectory of the disorder.

Published

2021

28. Live Imaging of Cytoskeletal Dynamics in Embryonic Xenopus laevis Growth Cones and Neural Crest Cells

Author

Elizabeth A. Bearce, Laura Anne Lowery, and Burcu Erdogan

Subjects

0303 health sciences, biology, Cell division, Xenopus, Neural crest, Embryo, biology.organism_classification, Embryonic stem cell, General Biochemistry, Genetics and Molecular Biology, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Live cell imaging, Cytoskeleton, Growth cone, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The cytoskeleton is a dynamic, fundamental network that not only provides mechanical strength to maintain a cell's shape but also controls critical events like cell division, polarity, and movement. Thus, how the cytoskeleton is organized and dynamically regulated is critical to our understanding of countless processes. Live imaging of fluorophore-tagged cytoskeletal proteins allows us to monitor the dynamic nature of cytoskeleton components in embryonic cells. Here, we describe a protocol to monitor and analyze cytoskeletal dynamics in primary embryonic neuronal growth cones and neural crest cells obtained from Xenopus laevis embryos.

Published

2020

29. Xenopus TACC2 is a microtubule plus end–tracking protein that can promote microtubule polymerization during embryonic development

Author

Leslie Carandang, Erin L. Rutherford, Laura Anne Lowery, Alexandra Mills, Jackson T. Bowers, and Patrick T. Ebbert

Subjects

0301 basic medicine, Xenopus, Growth Cones, Embryonic Development, Gene Expression, Cell Cycle Proteins, Xenopus Proteins, Microtubules, Polymerization, Microtubule polymerization, Structure-Activity Relationship, Xenopus laevis, 03 medical and health sciences, 0302 clinical medicine, Protein Domains, Microtubule, Animals, Molecular Biology, Microtubule nucleation, biology, fungi, Embryogenesis, TACC2, Nuclear Proteins, Cell Biology, biology.organism_classification, Embryonic stem cell, Microtubule plus-end, Cell biology, 030104 developmental biology, Brief Reports, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Transcription Factors

Abstract

Xenopus TACC2 is a microtubule plus end–tracking protein that localizes in front of EB1 and overlaps with TACC1 and TACC3 in cultured embryonic mesenchymal cells and neuronal growth cones. TACC2 OE can promote increased microtubule polymerization in mesenchymal cells but not growth cones, suggesting cell-type specificity to its function., Microtubule dynamics is regulated by plus end–tracking proteins (+TIPs), which localize to the plus ends of microtubules (MTs). We previously showed that TACC1 and TACC3, members of the transforming acidic coiled-coil protein family, can act as +TIPs to regulate MT dynamics in Xenopus laevis. Here we characterize TACC2 as a +TIP that localizes to MT plus ends in front of EB1 and overlapping with TACC1 and TACC3 in multiple embryonic cell types. We also show that TACC2 can promote MT polymerization in mesenchymal cells but not neuronal growth cones, thus displaying cell-type specificity. Structure–function analysis demonstrates that the C-terminal region of TACC2 is both necessary and sufficient to localize to MT plus ends and promote increased rates of MT polymerization, whereas the N-terminal region cannot bind to MT plus ends but can act in a dominant-negative capacity to reduce polymerization rates. Finally, we analyze mRNA expression patterns in Xenopus embryos for each TACC protein and observe neural enrichment of TACC3 expression compared with TACC1 and TACC2, which are also expressed in mesodermal tissues, including somites. Overall these data provide a novel assessment of all three TACC proteins as a family of +TIPs by highlighting the unique attributes of each, as well as their collective characteristics.

Published

2016

30. Exploring the developmental mechanisms underlying Wolf-Hirschhorn Syndrome: Evidence for defects in neural crest cell migration

Author

Erin L. Rutherford and Laura Anne Lowery

Subjects

0301 basic medicine, Context (language use), Biology, Article, Epigenesis, Genetic, 03 medical and health sciences, Neural crest, Neurodevelopmental disorder, Cell Movement, medicine, Animals, Humans, Cell migration, Craniofacial, 10. No inequality, Wolf–Hirschhorn syndrome, Molecular Biology, Wnt Signaling Pathway, Genetic Association Studies, Genetics, Wolf-Hirschhorn Syndrome, Wnt signaling pathway, Cell Biology, medicine.disease, Phenotype, 030104 developmental biology, Embryonic development, Neural crest cell migration, Neuroscience, Developmental Biology

Abstract

Wolf-Hirschhorn Syndrome (WHS) is a neurodevelopmental disorder characterized by mental retardation, craniofacial malformation, and defects in skeletal and heart development. The syndrome is associated with irregularities on the short arm of chromosome 4, including deletions of varying sizes and microduplications. Many of these genotypic aberrations in humans have been correlated with the classic WHS phenotype, and animal models have provided a context for mapping these genetic irregularities to specific phenotypes; however, there remains a significant knowledge gap concerning the cell biological mechanisms underlying these phenotypes. This review summarizes literature that has made recent contributions to this topic, drawing from the vast body of knowledge detailing the genetic particularities of the disorder and the more limited pool of information on its cell biology. Finally, we propose a novel characterization for WHS as a pathophysiology owing in part to defects in neural crest cell motility and migration during development.

Published

2016

31. Conserved roles for cytoskeletal components in determining laterality

Author

Garrett M. Cammarata, Jean-François Paré, Joan M. Lemire, Laura Anne Lowery, Michael Levin, and Gary S. McDowell

Subjects

0301 basic medicine, Body Patterning, Ubiquitin-Protein Ligases, Arabidopsis, Biophysics, Xenopus, Context (language use), Myosins, Microtubules, Biochemistry, Article, Mice, Xenopus laevis, 03 medical and health sciences, Tubulin, Microtubule, Animals, Cytoskeleton, Genetics, biology, Gene Expression Regulation, Developmental, biology.organism_classification, Actin cytoskeleton, Cell biology, 030104 developmental biology, Neurulation, Drosophila, NODAL, Protein Processing, Post-Translational

Abstract

Consistently-biased left-right (LR) patterning is required for the proper placement of organs including the heart and viscera. The LR axis is especially fascinating as an example of multi-scale pattern formation, since here chiral events at the subcellular level are integrated and amplified into asymmetric transcriptional cascades and ultimately into the anatomical patterning of the entire body. In contrast to the other two body axes, there is considerable controversy about the earliest mechanisms of embryonic laterality. Many molecular components of asymmetry have not been widely tested among phyla with diverse bodyplans, and it is unknown whether parallel (redundant) pathways may exist that could reverse abnormal asymmetry states at specific checkpoints in development. To address conservation of the early steps of LR patterning, we used the Xenopus laevis (frog) embryo to functionally test a number of protein targets known to direct asymmetry in plants, fruit fly, and rodent. Using the same reagents that randomize asymmetry in Arabidopsis, Drosophila, and mouse embryos, we show that manipulation of the microtubule and actin cytoskeleton immediately post-fertilization, but not later, results in laterality defects in Xenopus embryos. Moreover, we observed organ-specific randomization effects and a striking dissociation of organ situs from effects on the expression of left side control genes, which parallel data from Drosophila and mouse. Remarkably, some early manipulations that disrupt laterality of transcriptional asymmetry determinants can be subsequently "rescued" by the embryo, resulting in normal organ situs. These data reveal the existence of novel corrective mechanisms, demonstrate that asymmetric expression of Nodal is not a definitive marker of laterality, and suggest the existence of amplification pathways that connect early cytoskeletal processes to control of organ situs bypassing Nodal. Counter to alternative models of symmetry breaking during neurulation (via ciliary structures absent in many phyla), our data suggest a widely-conserved role for the cytoskeleton in regulating left-right axis formation immediately after fertilization of the egg. The novel mechanisms that rescue organ situs, even after incorrect expression of genes previously considered to be left-side master regulators, suggest LR patterning as a new context in which to explore multi-scale redundancy and integration of patterning from the subcellular structure to the entire bodyplan.

Published

2016

32. Cytoskeletal social networking in the growth cone: How +TIPs mediate microtubule-actin cross-linking to drive axon outgrowth and guidance

Author

Garrett M. Cammarata, Laura Anne Lowery, and Elizabeth A. Bearce

Subjects

0301 basic medicine, macromolecular substances, Cell Biology, Biology, Actin cytoskeleton, Cell biology, Protein filament, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Structural Biology, Microtubule, Axon Outgrowth, Axon guidance, Cytoskeleton, Growth cone, 030217 neurology & neurosurgery, Actin

Abstract

The growth cone is a unique structure capable of guiding axons to their proper destinations. Within the growth cone, extracellular guidance cues are interpreted and then transduced into physical changes in the actin filament (F-actin) and microtubule cytoskeletons, providing direction and movement. While both cytoskeletal networks individually possess important growth cone-specific functions, recent data over the past several years point towards a more cooperative role between the two systems. Facilitating this interaction between F-actin and microtubules, microtubule plus-end tracking proteins (+TIPs) have been shown to link the two cytoskeletons together. Evidence suggests that many +TIPs can couple microtubules to F-actin dynamics, supporting both microtubule advance and retraction in the growth cone periphery. In addition, growing in vitro and in vivo data support a secondary role for +TIPs in which they may participate as F-actin nucleators, thus directly influencing F-actin dynamics and organization. This review focuses on how +TIPs may link F-actin and microtubules together in the growth cone, and how these interactions may influence axon guidance. © 2016 Wiley Periodicals, Inc.

Published

2016

33. Regulation of cytoskeletal dynamics and transport

Author

Laura Anne Lowery and Kassandra M. Ori-McKenney

Subjects

ASCB Annual Meeting Highlights, Dynamics (mechanics), Biological Transport, Cell Biology, Biology, Congresses as Topic, Microtubules, Biophysical Phenomena, Cytoskeletal Proteins, Biophysics, Animals, Cytoskeleton, Caenorhabditis elegans, Molecular Biology

Published

2020

34. Wolf-Hirschhorn Syndrome-associated genes are enriched in motile neural crest and affect craniofacial development in Xenopus laevis

Author

Rachael Cella, Alexandra Mills, Sangmook Lee, Laura Anne Lowery, Megan Selig, Elizabeth A. Bearce, and Seung Woo Kim

Subjects

Microcephaly, medicine.anatomical_structure, Cranial neural crest, Forebrain, Neural tube, medicine, Neural crest, Craniofacial, Biology, medicine.disease, Wolf–Hirschhorn syndrome, Neuroscience, Pharyngeal arch

Abstract

Wolf-Hirschhorn Syndrome (WHS) is a human developmental disorder arising from a hemizygous perturbation, typically a microdeletion, on the short arm of chromosome four. In addition to pronounced intellectual disability, seizures, and delayed growth, WHS presents with a characteristic facial dysmorphism and varying prevalence of microcephaly, micrognathia, cartilage malformation in the ear and nose, and facial asymmetries. These affected craniofacial tissues all derive from a shared embryonic precursor, the cranial neural crest, inviting the hypothesis that one or more WHS-affected genes may be critical regulators of neural crest development or migration. To explore this, we characterized expression of multiple genes within or immediately proximal to defined WHS critical regions, across the span of craniofacial development in the vertebrate model systemXenopus laevis. This subset of genes,WHSC1, WHSC2, LETM1, andTACC3, are diverse in their currently-elucidated cellular functions; yet we find that their expression demonstrates shared tissue-specific enrichment within the anterior neural tube, pharyngeal arches, and later craniofacial structures. We examine the ramifications of this by characterizing craniofacial development and neural crest migration following individual gene depletion. We observe that several WHS-associated genes significantly impact facial patterning, cartilage formation, pharyngeal arch migration, and neural crest motility, and can separately contribute to forebrain scaling. Thus, we have determined that numerous genes within and surrounding the defined WHS critical regions potently impact craniofacial patterning, suggesting their role in WHS presentation may stem from essential functions during neural crest-derived tissue formation.Author SummaryWolf-Hirschhorn Syndrome (WHS), a developmental disorder caused by small deletions on chromosome four, manifests with pronounced and characteristic facial malformation. While genetic profiling and case studies provide insights into how broader regions of the genome affect the syndrome’s severity, we lack a key component of understanding its pathology; a basic knowledge of how individual WHS-affected genes function during development. Importantly, many tissues affected by WHS derive from shared embryonic origin, the cranial neural crest. This led us to hypothesize that genes deleted in WHS may hold especially critical roles in this tissue. To this end, we investigated the roles of four WHS-associated genes during neural crest cell migration and facial patterning. We show that during normal development, expression of these genes is enriched in migratory neural crest and craniofacial structures. Subsequently, we examine their functional roles during facial patterning, cartilage formation, and forebrain development, and find that their depletion recapitulates features of WHS craniofacial malformation. Additionally, two of these genes directly affect neural crest cell migration rate. We report that depletion of WHS-associated genes is a potent effector of neural crest-derived tissues, and suggest that this explains why WHS clinical presentation shares so many characteristics with classic neurochristopathies.

Published

2018

35. Characterization of Xenopus laevis guanine deaminase reveals new insights for its expression and function in the embryonic kidney

Author

Connor Monahan, Oliver Yan, Laura Anne Lowery, Garrett M. Cammarata, Sangmook Lee, Paula G. Slater, and Jackson T. Bowers

Subjects

0301 basic medicine, Embryo, Nonmammalian, Xenopus, Kidney development, Biology, Xenopus Proteins, Kidney, Microtubules, Homology (biology), Article, 03 medical and health sciences, Guanine deaminase, Xenopus laevis, 0302 clinical medicine, Microtubule, Animals, Humans, Guanine Deaminase, Embryogenesis, biology.organism_classification, Embryonic stem cell, Cell biology, 030104 developmental biology, Neural development, 030217 neurology & neurosurgery, Developmental Biology

Abstract

BACKGROUND The mammalian guanine deaminase (GDA), called cypin, is important for proper neural development, by regulating dendritic arborization through modulation of microtubule (MT) dynamics. Additionally, cypin can promote MT assembly in vitro. However, it has never been tested whether cypin (or other GDA orthologs) binds to MTs or modulates MT dynamics. Here, we address these questions and characterize Xenopus laevis GDA (Gda) for the first time during embryonic development. RESULTS We find that exogenously expressed human cypin and Gda both display a cytosolic distribution in primary embryonic cells. Furthermore, while expression of human cypin can promote MT polymerization, Xenopus Gda has no effect. Additionally, we find that the tubulin-binding collapsin response mediator protein (CRMP) homology domain is only partially conserved between cypin and Gda. This likely explains the divergence in function, as we discovered that the cypin region containing the CRMP homology and PDZ-binding domain is necessary for regulating MT dynamics. Finally, we observed that gda is strongly expressed in the kidneys during late embryonic development, although it does not appear to be critical for kidney development. CONCLUSIONS Together, these results suggest that GDA has diverged in function between mammals and amphibians, and that mammalian GDA plays an indirect role in regulating MT dynamics. Developmental Dynamics 248:296-305, 2019. © 2019 Wiley Periodicals, Inc.

Published

2018

36. The Role of the Microtubule Cytoskeleton in Neurodevelopmental Disorders

Author

Laura Anne Lowery, Jessica Tiber, and Micaela Lasser

Subjects

0301 basic medicine, neuronal migration, Cell division, neurodevelopmental disorders, Context (language use), cytoskeleton, Review, Biology, medicine.disease, microtubule dynamics, Review article, lcsh:RC321-571, 03 medical and health sciences, Cellular and Molecular Neuroscience, 030104 developmental biology, Microtubule, MAPs, medicine, Autism, Axon guidance, Signal transduction, Cytoskeleton, Neuroscience, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry

Abstract

Neurons depend on the highly dynamic microtubule (MT) cytoskeleton for many different processes during early embryonic development including cell division and migration, intracellular trafficking and signal transduction, as well as proper axon guidance and synapse formation. The coordination and support from MTs is crucial for newly formed neurons to migrate appropriately in order to establish neural connections. Once connections are made, MTs provide structural integrity and support to maintain neural connectivity throughout development. Abnormalities in neural migration and connectivity due to genetic mutations of MT-associated proteins can lead to detrimental developmental defects. Growing evidence suggests that these mutations are associated with many different neurodevelopmental disorders, including intellectual disabilities (ID) and autism spectrum disorders (ASD). In this review article, we highlight the crucial role of the MT cytoskeleton in the context of neurodevelopment and summarize genetic mutations of various MT related proteins that may underlie or contribute to neurodevelopmental disorders.

Published

2018

37. Xenopus TACC1 is a microtubule plus‐end tracking protein that can regulate microtubule dynamics during embryonic development

Author

Charlie C. Baker, Christopher M. Lucaj, Matthew F. Evans, Sean P. Ruvolo, Andrew F. Francl, Laura Anne Lowery, Belinda U. Nwagbara, Patrick T. Ebbert, and Joseph G. Volk

Subjects

Microtubule-associated protein, Xenopus, Green Fluorescent Proteins, Short Report, Embryonic Development, Cell Cycle Proteins, Xenopus Proteins, Biology, Microtubules, Mice, Xenopus laevis, Structural Biology, Microtubule, Live cell imaging, Animals, Humans, Nuclear protein, Transcription factor, transforming acid coiled coil domain, Microscopy, Confocal, Gene Expression Regulation, Developmental, Nuclear Proteins, Mesenchymal Stem Cells, live imaging, Cell Biology, microtubule dynamics, biology.organism_classification, Embryonic stem cell, Protein Structure, Tertiary, Microtubule plus-end, Cell biology, Phenotype, plusTipTracker, Female, Microtubule-Associated Proteins, Software, Transcription Factors

Abstract

Microtubule plus‐end dynamics are regulated by a family of proteins called plus‐end tracking proteins (+TIPs). We recently demonstrated that the transforming acidic coiled‐coil (TACC) domain family member, TACC3, can function as a +TIP to regulate microtubule dynamics in Xenopus laevis embryonic cells. Although it has been previously reported that TACC3 is the only TACC family member that exists in Xenopus, our examination of its genome determined that Xenopus, like all other vertebrates, contains three TACC family members. Here, we investigate the localization and function of Xenopus TACC1, the founding member of the TACC family. We demonstrate that it can act as a +TIP to regulate microtubule dynamics, and that the conserved C‐terminal TACC domain is required for its localization to plus‐ends. We also show that, in Xenopus embryonic mesenchymal cells, TACC1 and TACC3 are each required for maintaining normal microtubule growth speed but exhibit some functional redundancy in the regulation of microtubule growth lifetime. Given the conservation of TACC1 in Xenopus and other vertebrates, we propose that Xenopus laevis is a useful system to investigate unexplored cell biological functions of TACC1 and other TACC family members in the regulation of microtubule dynamics. © 2015 The Authors. Cytoskeleton, Published by Wiley Periodicals, Inc.

Published

2015

38. Multiparametric Analysis of CLASP-Interacting Protein Functions during Interphase Microtubule Dynamics

Author

Gaudenz Danuser, Laura Anne Lowery, David Van Vactor, Jennifer B. Long, Haeryun Lee, and Maria Bagonis

Subjects

Microtubule-associated protein, Green Fluorescent Proteins, RNA, Articles, Cell Biology, Biology, biology.organism_classification, Microtubules, Interactome, Cell Line, Cell biology, Drosophila melanogaster, Cytoplasm, Microtubule, RNA interference, Protein Interaction Mapping, Animals, Drosophila Proteins, RNA Interference, RNA, Small Interfering, Interphase, Microtubule-Associated Proteins, Molecular Biology, Drosophila Protein

Abstract

The microtubule (MT) plus-end tracking protein (+TIP) CLASP mediates dynamic cellular behaviors and interacts with numerous cytoplasmic proteins. While the influence of some CLASP interactors on MT behavior is known, a comprehensive survey of the proteins in the CLASP interactome as MT regulators is missing. Ultimately, we are interested in understanding how CLASP collaborates with functionally linked proteins to regulate MT dynamics. Here, we utilize multiparametric analysis of time-lapse MT +TIP imaging data acquired in Drosophila melanogaster S2R+ cells to assess the effects on individual microtubule dynamics for RNA interference-mediated depletion of 48 gene products previously identified to be in vivo genetic CLASP interactors. While our analysis corroborates previously described functions of several known CLASP interactors, its multiparametric resolution reveals more detailed functional profiles (fingerprints) that allow us to precisely classify the roles that CLASP-interacting genes play in MT regulation. Using these data, we identify subnetworks of proteins with novel yet overlapping MT-regulatory roles and also uncover subtle distinctions between the functions of proteins previously thought to act via similar mechanisms.

Published

2013

39. Xenopus laevis as a model system to study cytoskeletal dynamics during axon pathfinding

Author

Paula G, Slater, Laurie, Hayrapetian, and Laura Anne, Lowery

Subjects

Xenopus laevis, urogenital system, Growth Cones, Animals, Microtubule-Associated Proteins, Actins, Axons, Cytoskeleton, Article, Axon Guidance

Abstract

The model system, Xenopus laevis, has been used in innumerable research studies and has contributed to the understanding of multiple cytoskeletal components, including actin, microtubules, and neurofilaments, during axon pathfinding. Xenopus developmental stages have been widely characterized, and the Xenopus genome has been sequenced, allowing gene expression modifications through exogenous molecules. Xenopus cell cultures are ideal for long periods of live imaging because they are easily obtained and maintained, and they do not require special culture conditions. In addition, Xenopus have relatively large growth cones, compared to other vertebrates, thus providing a suitable system for imaging cytoskeletal components. Therefore, Xenopus laevis is an ideal model organism in which to study cytoskeletal dynamics during axon pathfinding.

Published

2016

40. Using Xenopus laevis retinal and spinal neurons to study mechanisms of axon guidance in vivo and in vitro

Author

Burcu Erdogan, Laura Anne Lowery, and Patrick T. Ebbert

Subjects

0301 basic medicine, Nervous system, Retinal Ganglion Cells, Growth Cones, Xenopus, Bioinformatics, Time-Lapse Imaging, Article, 03 medical and health sciences, Xenopus laevis, 0302 clinical medicine, Pioneer axon, In vivo, medicine, Animals, Humans, Growth cone, Cytoskeleton, Cells, Cultured, biology, Cell Biology, biology.organism_classification, Axon Guidance, 030104 developmental biology, medicine.anatomical_structure, nervous system, Microscopy, Fluorescence, Spinal Cord, Second messenger system, Axon guidance, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The intricate and precise establishment of neuronal connections in the developing nervous system relies on accurate navigation of growing axons. Since Ramon y Cajal's discovery of the growth cone, the phenomenon of axon guidance has been revealed as a coordinated operation of guidance molecules, receptors, secondary messengers, and responses driven by the dynamic cytoskeleton within the growth cone. With the advent of new and accelerating techniques, Xenopus laevis emerged as a robust model to investigate neuronal circuit formation during development. We present here the advantages of the Xenopus nervous system to our growing understanding of axon guidance.

Published

2016

41. Multiple roles for the Na,K-ATPase subunits, Atp1a1 and Fxyd1, during brain ventricle development

Author

Hazel Sive, Jessica T. Chang, and Laura Anne Lowery

Subjects

Cell Membrane Permeability, Embryo, Nonmammalian, RHOA, Protein subunit, Neuroepithelial Cells, Permeability, Article, Ouabain, Cerebral Ventricles, 03 medical and health sciences, Cerebrospinal fluid, Brain ventricles, Atp1a1, medicine, Animals, Enzyme Inhibitors, Na+/K+-ATPase, Molecular Biology, In Situ Hybridization, Zebrafish, Cerebrospinal Fluid, 030304 developmental biology, Brain Ventricle, G alpha subunit, 0303 health sciences, biology, Reverse Transcriptase Polymerase Chain Reaction, Sodium, 030302 biochemistry & molecular biology, Gene Expression Regulation, Developmental, Membrane Proteins, Cell Biology, Fxyd1, Zebrafish Proteins, Phosphoproteins, Immunohistochemistry, Molecular biology, Cell biology, Neuroepithelial cell, Na,K-ATPase, Gene Knockdown Techniques, Mutation, biology.protein, Sodium-Potassium-Exchanging ATPase, rhoA GTP-Binding Protein, Neuroepithelium, medicine.drug, Developmental Biology

Abstract

Formation of the vertebrate brain ventricles requires both production of cerebrospinal fluid (CSF), and its retention in the ventricles. The Na,K-ATPase is required for brain ventricle development, and we show here that this protein complex impacts three associated processes. The first requires both the alpha subunit (Atp1a1) and the regulatory subunit, Fxyd1, and leads to formation of a cohesive neuroepithelium, with continuous apical junctions. The second process leads to modulation of neuroepithelial permeability, and requires Atp1a1, which increases permeability with partial loss of function and decreases it with overexpression. In contrast, fxyd1 overexpression does not alter neuroepithelial permeability, suggesting that its activity is limited to neuroepithelium formation. RhoA regulates both neuroepithelium formation and permeability, downstream of the Na,K-ATPase. A third process, likely to be CSF production, is RhoA-independent, requiring Atp1a1, but not Fxyd1. Consistent with a role for Na,K-ATPase pump function, the inhibitor ouabain prevents neuroepithelium formation, while intracellular Na+ increases after Atp1a1 and Fxyd1 loss of function. These data include the first reported role for Fxyd1 in the developing brain, and indicate that the Na,K-ATPase regulates three aspects of brain ventricle development essential for normal function: formation of a cohesive neuroepithelium, restriction of neuroepithelial permeability, and production of CSF.

Published

2012

42. Compartmentalized Toxoplasma EB1 bundles spindle microtubules to secure accurate chromosome segregation

Author

Patrick T. Ebbert, Belinda U. Nwagbara, Chun-Ti Chen, Megan Kelly, Jessica Cruz de Leon, Laura Anne Lowery, Marc-Jan Gubbels, Naomi S. Morrissette, David J. P. Ferguson, and Bloom, Kerry S

Subjects

Protozoan Proteins, Mitosis, Centrosome cycle, Spindle Apparatus, Biology, Microtubules, Medical and Health Sciences, Spindle pole body, Vaccine Related, Xenopus laevis, Chromosome Segregation, parasitic diseases, Genetics, Animals, Kinetochores, Molecular Biology, Centrosome, Kinetochore, Cell Cycle, Articles, Cell Biology, Biological Sciences, 3. Good health, Spindle apparatus, Cell biology, Cell Compartmentation, Spindle checkpoint, Emerging Infectious Diseases, Astral microtubules, Multipolar spindles, Toxoplasma, Microtubule-Associated Proteins, Developmental Biology

Abstract

The opportunistic apicomplexan parasite Toxoplasma gondii divides by intertwined closed mitosis and internal budding. Centrosome positioning and MT acetylation control spindle dynamics, and the MT-associated protein TgEB1 residing in the nucleus contributes to mitotic fidelity by bundling the spindle MTs., Toxoplasma gondii replicates asexually by a unique internal budding process characterized by interwoven closed mitosis and cytokinesis. Although it is known that the centrosome coordinates these processes, the spatiotemporal organization of mitosis remains poorly defined. Here we demonstrate that centrosome positioning around the nucleus may signal spindle assembly: spindle microtubules (MTs) are first assembled when the centrosome moves to the basal side and become extensively acetylated after the duplicated centrosomes reposition to the apical side. We also tracked the spindle MTs using the MT plus end–binding protein TgEB1. Endowed by a C-terminal NLS, TgEB1 resides in the nucleoplasm in interphase and associates with the spindle MTs during mitosis. TgEB1 also associates with the subpellicular MTs at the growing end of daughter buds toward the completion of karyokinesis. Depletion of TgEB1 results in escalated disintegration of kinetochore clustering. Furthermore, we show that TgEB1’s MT association in Toxoplasma and in a heterologous system (Xenopus) is based on the same principles. Finally, overexpression of a high-MT-affinity TgEB1 mutant promotes the formation of overstabilized MT bundles, resulting in avulsion of otherwise tightly clustered kinetochores. Overall we conclude that centrosome position controls spindle activity and that TgEB1 is critical for mitotic integrity.

Published

2015

43. The trip of the tip: understanding the growth cone machinery

Author

David Landreth Van Vactor, Jr. and Laura Anne Lowery

Subjects

genetic structures, Growth Cones, Cell Biology, Anatomy, Biology, Growth cone movement, Microtubules, Article, Actins, Mechanism (engineering), Control theory, Animals, Humans, Axon guidance, sense organs, Growth cone, human activities, Molecular Biology, Cytoskeleton, Protein Binding, Spatial bias

Abstract

The central component in the road trip of axon guidance is the growth cone, a dynamic structure that is located at the tip of the growing axon. During its journey, the growth cone comprises both 'vehicle' and 'navigator'. Whereas the 'vehicle' maintains growth cone movement and contains the cytoskeletal structural elements of its framework, a motor to move forward and a mechanism to provide traction on the 'road', the 'navigator' aspect guides this system with spatial bias to translate environmental signals into directional movement. The understanding of the functions and regulation of the vehicle and navigator provides new insights into the cell biology of growth cone guidance.

Published

2009

44. Characterization and Classification of Zebrafish Brain Morphology Mutants

Author

Laura Anne Lowery, Hazel Sive, Jennifer H. Gutzman, and Gianluca De Rienzo

Subjects

Genetics, Embryo, Nonmammalian, Histology, Mutant, Brain morphometry, Morphogenesis, Neural tube, Brain, Biology, biology.organism_classification, Phenotype, Article, medicine.anatomical_structure, Mutation, medicine, Animals, Female, Anatomy, Zebrafish, Brain morphogenesis, Ecology, Evolution, Behavior and Systematics, Biotechnology, Brain Ventricle

Abstract

The mechanisms by which the vertebrate brain achieves its three-dimensional structure are clearly complex, requiring the functions of many genes. Using the zebrafish as a model, we have begun to define genes required for brain morphogenesis, including brain ventricle formation, by studying 16 mutants previously identified as having embryonic brain morphology defects. We report the phenotypic characterization of these mutants at several timepoints, using brain ventricle dye injection, imaging, and immunohistochemistry with neuronal markers. Most of these mutants display early phenotypes, affecting initial brain shaping, whereas others show later phenotypes, affecting brain ventricle expansion. In the early phenotype group, we further define four phenotypic classes and corresponding functions required for brain morphogenesis. Although we did not use known genotypes for this classification, basing it solely on phenotypes, many mutants with defects in functionally related genes clustered in a single class. In particular, Class 1 mutants show midline separation defects, corresponding to epithelial junction defects; Class 2 mutants show reduced brain ventricle size; Class 3 mutants show midbrain-hindbrain abnormalities, corresponding to basement membrane defects; and Class 4 mutants show absence of ventricle lumen inflation, corresponding to defective ion pumping. Later brain ventricle expansion requires the extracellular matrix, cardiovascular circulation, and transcription/splicing-dependent events. We suggest that these mutants define processes likely to be used during brain morphogenesis throughout the vertebrates. Anat Rec, 2009. (c) 2008 Wiley-Liss, Inc.

Published

2009

45. whitesnake/sfpqis required for cell survival and neuronal development in the zebrafish

Author

Laura Anne Lowery, Jamie Rubin, and Hazel Sive

Subjects

Cell Survival, Mutant, Hindbrain, In Vitro Techniques, Splicing factor, Animals, RNA, Messenger, Zebrafish, Gene, In Situ Hybridization, Cell survival, Neurons, Genetics, Cell Death, biology, Brain, Gene Expression Regulation, Developmental, Neural crest, Embryo, Zebrafish Proteins, biology.organism_classification, Cell biology, Developmental dynamics, Phenotype, Mutation, RNA splicing, Developmental Biology

Abstract

Organogenesis involves both the development of specific cell types and their organization into a functional three-dimensional structure. We are using the zebrafish to assess the genetic basis for brain organogenesis. We show that the whitesnake mutant corresponds to the sfpq (splicing factor, proline/glutamine rich) gene, encoding the PSF protein (polypyrimidine tract-binding protein-associated splicing factor). In vitro studies have shown that PSF is important for RNA splicing and transcription and is a candidate brain-specific splicing factor, however, the in vivo function of this gene is unclear. sfpq is expressed throughout development and in the adult zebrafish, with strong expression in the developing brain, particularly in regions enriched for neuronal progenitors. In the whitesnake mutant, a brain phenotype is visible by 28 hr after fertilization, when it becomes apparent that the midbrain and hindbrain are abnormally shaped. Neural crest, heart, and muscle development or function is also abnormal. sfpq function appears to be required in two distinct phases during development. First, loss of sfpq gene function leads to increased cell death throughout the early embryo, suggesting that cell survival requires functional PSF protein. Second, sfpq function is required for differentiation, but not for determination, of specific classes of brain neurons. These data indicate that, in vertebrates, sfpq plays a key role in neuronal development and is essential for normal brain development.

Published

2007

46. Cytoskeletal social networking in the growth cone: How +TIPs mediate microtubule-actin cross-linking to drive axon outgrowth and guidance

Author

Garrett M, Cammarata, Elizabeth A, Bearce, and Laura Anne, Lowery

Subjects

Actin Cytoskeleton, Growth Cones, Microtubule Proteins, Humans, macromolecular substances, Microtubules, Actins, gamma-Aminobutyric Acid, Article

Abstract

The growth cone is a unique structure capable of guiding axons to their proper destinations. Within the growth cone, extracellular guidance cues are interpreted and then transduced into physical changes in the actin filament (F-actin) and microtubule cytoskeletons, providing direction and movement. While both cytoskeletal networks individually possess important growth cone-specific functions, recent data over the past several years point towards a more cooperative role between the two systems. Facilitating this interaction between F-actin and microtubules, microtubule plus-end tracking proteins (+TIPs) have been shown to link the two cytoskeletons together. Evidence suggests that many +TIPs can couple microtubules to F-actin dynamics, supporting both microtubule advance and retraction in the growth cone periphery. In addition, growing in vitro and in vivo data support a secondary role for +TIPs in which they may participate as F-actin nucleators, thus directly influencing F-actin dynamics and organization. This review focuses on how +TIPs may link F-actin and microtubules together in the growth cone, and how these interactions may influence axon guidance. © 2016 Wiley Periodicals, Inc.

Published

2015

47. Initial formation of zebrafish brain ventricles occurs independently of circulation and requires thenagie okoandsnakehead/atp1a1a.1gene products

Author

Laura Anne Lowery and Hazel Sive

Subjects

Apoptosis, Hindbrain, Cerebral Ventricles, medicine, Animals, Molecular Biology, Zebrafish, Cell Proliferation, Brain Ventricle, biology, Neural tube, Epistasis, Genetic, Anatomy, Zebrafish Proteins, biology.organism_classification, Cell biology, Neuroepithelial cell, medicine.anatomical_structure, Guanylate Cyclase, Ventricle, Blood Circulation, Forebrain, Sodium-Potassium-Exchanging ATPase, Brain morphogenesis, Developmental Biology

Abstract

The mechanisms by which the vertebrate brain develops its characteristic three-dimensional structure are poorly understood. The brain ventricles are a highly conserved system of cavities that form very early during brain morphogenesis and that are required for normal brain function. We have initiated a study of zebrafish brain ventricle development and show here that the neural tube expands into primary forebrain, midbrain and hindbrain ventricles rapidly, over a 4-hour window during mid-somitogenesis. Circulation is not required for initial ventricle formation, only for later expansion. Cell division rates in the neural tube surrounding the ventricles are higher than between ventricles and, consistently, cell division is required for normal ventricle development. Two zebrafish mutants that do not develop brain ventricles are snakehead and nagie oko. We show that snakehead is allelic to small heart, which has a mutation in the Na+K+ ATPase gene atp1a1a.1. The snakehead neural tube undergoes normal ventricle morphogenesis;however, the ventricles do not inflate, probably owing to impaired ion transport. By contrast, mutants in nagie oko, which was previously shown to encode a MAGUK family protein, fail to undergo ventricle morphogenesis. This correlates with an abnormal brain neuroepithelium, with no clear midline and disrupted junctional protein expression. This study defines three steps that are required for brain ventricle development and that occur independently of circulation: (1) morphogenesis of the neural tube, requiring nok function; (2) lumen inflation requiring atp1a1a.1function; and (3) localized cell proliferation. We suggest that mechanisms of brain ventricle development are conserved throughout the vertebrates.

Published

2005

48. Xenopus laevisas a model system to study cytoskeletal dynamics during axon pathfinding

Author

Laura Anne Lowery, Laurie Hayrapetian, and Paula G. Slater

Subjects

0301 basic medicine, Neurofilament, biology, urogenital system, ved/biology, ved/biology.organism_classification_rank.species, Xenopus, Cell Biology, biology.organism_classification, Cell biology, 03 medical and health sciences, 030104 developmental biology, Endocrinology, Microtubule, Live cell imaging, Genetics, Axon guidance, Model organism, Growth cone, Cytoskeleton

Abstract

The model system, Xenopus laevis, has been used in innumerable research studies and has contributed to the understanding of multiple cytoskeletal components, including actin, microtubules, and neurofilaments, during axon pathfinding. Xenopus developmental stages have been widely characterized, and the Xenopus genome has been sequenced, allowing gene expression modifications through exogenous molecules. Xenopus cell cultures are ideal for long periods of live imaging because they are easily obtained and maintained, and they do not require special culture conditions. In addition, Xenopus have relatively large growth cones, compared to other vertebrates, thus providing a suitable system for imaging cytoskeletal components. Therefore, X. laevis is an ideal model organism in which to study cytoskeletal dynamics during axon pathfinding.

Published

2017

49. Using plusTipTracker Software to Measure Microtubule Dynamics in Xenopus laevis Growth Cones

Author

Laura Anne Lowery, Salvatore D'Amico, Patrick T. Ebbert, T. B. Enzenbacher, and Alina C. Stout

Subjects

General Immunology and Microbiology, biology, Microtubule dynamics, Extramural, business.industry, General Chemical Engineering, General Neuroscience, Xenopus, Software package, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, Cell biology, Software, Microtubule, business, Growth cone

Abstract

Microtubule (MT) plus-end-tracking proteins (+TIPs) localize to the growing plus-ends of MTs and regulate MT dynamics1,2. One of the most well-known and widely-utilized +TIPs for analyzing MT dynamics is the End-Binding protein, EB1, which binds all growing MT plus-ends, and thus, is a marker for MT polymerization1. Many studies of EB1 behavior within growth cones have used time-consuming and biased computer-assisted, hand-tracking methods to analyze individual MTs1-3. Our approach is to quantify global parameters of MT dynamics using the software package, plusTipTracker4, following the acquisition of high-resolution, live images of tagged EB1 in cultured embryonic growth cones5. This software is a MATLAB-based, open-source, user-friendly package that combines automated detection, tracking, visualization, and analysis for movies of fluorescently-labeled +TIPs. Here, we present the protocol for using plusTipTracker for the analysis of fluorescently-labeled +TIP comets in cultured Xenopus laevis growth cones. However, this software can also be used to characterize MT dynamics in various cell types6-8.

Published

2014

50. TACC3 is a microtubule plus end-tracking protein that promotes axon elongation and also regulates microtubule plus end dynamics in multiple embryonic cell types

Author

Anna Faris, Elizabeth A. Bearce, Laura Anne Lowery, Belinda U. Nwagbara, Matthew F. Evans, Erin L. Rutherford, T. B. Enzenbacher, Patrick T. Ebbert, and Burcu Erdogan

Subjects

Embryo, Nonmammalian, Microtubule-associated protein, Growth Cones, Biology, Xenopus Proteins, Microtubules, Microtubule polymerization, Embryo Culture Techniques, 03 medical and health sciences, Xenopus laevis, 0302 clinical medicine, Microtubule, medicine, Animals, Axon, Growth cone, Molecular Biology, Interphase, Cytoskeleton, 030304 developmental biology, Microtubule nucleation, 0303 health sciences, Protein Stability, Microtubule organizing center, Cell Biology, Articles, Axons, Microtubule plus-end, Cell biology, Protein Structure, Tertiary, medicine.anatomical_structure, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Transcription Factors

Abstract

TACC3 is a microtubule plus end–tracking protein in vertebrates. TACC3 localizes to the extreme microtubule plus end, where it interacts with XMAP215 to regulate microtubule polymerization. TACC3 is also required to promote normal axon outgrowth, likely through its regulation of microtubule dynamics within the growth cone., Microtubule plus end dynamics are regulated by a conserved family of proteins called plus end–tracking proteins (+TIPs). It is unclear how various +TIPs interact with each other and with plus ends to control microtubule behavior. The centrosome-associated protein TACC3, a member of the transforming acidic coiled-coil (TACC) domain family, has been implicated in regulating several aspects of microtubule dynamics. However, TACC3 has not been shown to function as a +TIP in vertebrates. Here we show that TACC3 promotes axon outgrowth and regulates microtubule dynamics by increasing microtubule plus end velocities in vivo. We also demonstrate that TACC3 acts as a +TIP in multiple embryonic cell types and that this requires the conserved C-terminal TACC domain. Using high-resolution live-imaging data on tagged +TIPs, we show that TACC3 localizes to the extreme microtubule plus end, where it lies distal to the microtubule polymerization marker EB1 and directly overlaps with the microtubule polymerase XMAP215. TACC3 also plays a role in regulating XMAP215 stability and localizing XMAP215 to microtubule plus ends. Taken together, our results implicate TACC3 as a +TIP that functions with XMAP215 to regulate microtubule plus end dynamics.

Published

2014