Your search keyword '"Maxwell G. Heiman"' showing total 35 results

1. Loss of the Extracellular Matrix Protein DIG-1 Causes Glial Fragmentation, Dendrite Breakage, and Dendrite Extension Defects

Author

Megan K. Chong, Elizabeth R. Cebul, Karolina Mizeracka, and Maxwell G. Heiman

Subjects

neurodevelopment, dendrites, glia, extracellular matrix, DIG-1, C. elegans, Biology (General), QH301-705.5

Abstract

The extracellular matrix (ECM) guides and constrains the shape of the nervous system. In C. elegans, DIG-1 is a giant ECM component that is required for fasciculation of sensory dendrites during development and for maintenance of axon positions throughout life. We identified four novel alleles of dig-1 in three independent screens for mutants affecting disparate aspects of neuronal and glial morphogenesis. First, we find that disruption of DIG-1 causes fragmentation of the amphid sheath glial cell in larvae and young adults. Second, it causes severing of the BAG sensory dendrite from its terminus at the nose tip, apparently due to breakage of the dendrite as animals reach adulthood. Third, it causes embryonic defects in dendrite fasciculation in inner labial (IL2) sensory neurons, as previously reported, as well as rare defects in IL2 dendrite extension that are enhanced by loss of the apical ECM component DYF-7, suggesting that apical and basolateral ECM contribute separately to dendrite extension. Our results highlight novel roles for DIG-1 in maintaining the cellular integrity of neurons and glia, possibly by creating a barrier between structures in the nervous system.

Published

2021

2. Duplication of a Single Neuron in C. elegans Reveals a Pathway for Dendrite Tiling by Mutual Repulsion

Author

Zhiqi Candice Yip and Maxwell G. Heiman

Subjects

Biology (General), QH301-705.5

Abstract

Simple cell-cell interactions can give rise to complex cellular patterns. For example, neurons of the same type can interact to create a complex patchwork of non-overlapping dendrite arbors, a pattern known as dendrite tiling. Dendrite tiling often involves mutual repulsion between neighboring neurons. While dendrite tiling is found across nervous systems, the nematode Caenorhabditis elegans has a relatively simple nervous system with few opportunities for tiling. Here, we show that genetic duplication of a single neuron, PVD, is sufficient to create dendrite tiling among the resulting ectopic neurons. We use laser ablation to show that this tiling is mediated by mutual repulsion between neighbors. Furthermore, we find that tiling requires a repulsion signal (UNC-6/Netrin and its receptors UNC-40/DCC and UNC-5) that normally patterns the PVD dendrite arbor. These results demonstrate that an apparently complex cellular pattern can emerge in a simple nervous system merely by increasing neuron number.

Published

2016

3. A multicellular rosette-mediated collective dendrite extension

Author

Li Fan, Ismar Kovacevic, Maxwell G Heiman, and Zhirong Bao

Subjects

sensory organ, dendrite morphogenesis, multicellular rosette, collective cell behavior, neuron-epicermis interaction, organogenesis, Medicine, Science, Biology (General), QH301-705.5

Abstract

Coordination of neurite morphogenesis with surrounding tissues is crucial to the establishment of neural circuits, but the underlying cellular and molecular mechanisms remain poorly understood. We show that neurons in a C. elegans sensory organ, called the amphid, undergo a collective dendrite extension to form the sensory nerve. The amphid neurons first assemble into a multicellular rosette. The vertex of the rosette, which becomes the dendrite tips, is attached to the anteriorly migrating epidermis and carried to the sensory depression, extruding the dendrites away from the neuronal cell bodies. Multiple adhesion molecules including DYF-7, SAX-7, HMR-1 and DLG-1 function redundantly in rosette-to-epidermis attachment. PAR-6 is localized to the rosette vertex and dendrite tips, and promotes DYF-7 localization and dendrite extension. Our results suggest a collective mechanism of neurite extension that is distinct from the classical pioneer-follower model and highlight the role of mechanical cues from surrounding tissues in shaping neurites.

Published

2019

4. A sex-specific switch in a single glial cell patterns the apical extracellular matrix

Author

Wendy Fung, Taralyn M. Tan, Irina Kolotuev, and Maxwell G. Heiman

Subjects

Article

Abstract

Apical extracellular matrix (aECM) constitutes the interface between every tissue and the outside world. It is patterned into diverse tissue-specific structures through unknown mechanisms. Here, we show that a male-specific genetic switch in a singleC. elegansglial cell patterns the aECM into a ∼200 nm pore, allowing a male sensory neuron to access the environment. We find that this glial sex difference is controlled by factors shared with neurons (mab-3, lep-2, lep-5) as well as previously unidentified regulators whose effects may be glia-specific (nfya-1, bed-3, jmjd-3.1). The switch results in male-specific expression of a Hedgehog-related protein, GRL-18, that we discover localizes to transient nanoscale rings at sites of aECM pore formation. Blocking male-specific gene expression in glia prevents pore formation, whereas forcing male-specific expression induces an ectopic pore. Thus, a switch in gene expression in a single cell is necessary and sufficient to pattern aECM into a specific structure.

Published

2023

5. Ordered arrangement of dendrites within a C. elegans sensory nerve bundle

Author

Zhiqi Candice Yip and Maxwell G Heiman

Subjects

neural development, Self-organization, dendrites, fasciculation, cell adhesion, Medicine, Science, Biology (General), QH301-705.5

Abstract

Biological systems are organized into well-ordered structures and can evolve new patterns when perturbed. To identify principles underlying biological order, we turned to C. elegans for its simple anatomy and powerful genetics. We developed a method to quantify the arrangement of three dendrites in the main sensory nerve bundle, and found that they exhibit a stereotyped arrangement throughout larval growth. Dendrite order does not require prominent features including sensory cilia and glial junctions. In contrast, loss of the cell adhesion molecule (CAM) CDH-4/Fat-like cadherin causes dendrites to be ordered randomly, despite remaining bundled. Loss of the CAMs PTP-3/LAR or SAX-7/L1CAM causes dendrites to adopt an altered order, which becomes increasingly random as animals grow. Misexpression of SAX-7 leads to subtle but reproducible changes in dendrite order. Our results suggest that combinations of CAMs allow dendrites to self-organize into a stereotyped arrangement and can produce altered patterns when perturbed.

Published

2018

6. When is a neuron like an epithelial cell

Author

Maxwell G. Heiman

Subjects

Neurons, Cell Polarity, Epithelial Cells, Cell Biology, Molecular Biology, Epithelium, Article, Developmental Biology, Tight Junctions

Abstract

Neurons and epithelia are viewed as fundamentally different cell types, yet some sensory neurons exhibit hallmarks of epithelial cells. For example, they use tight junctions to form a diffusion barrier continuous with the skin or other epithelia and they exhibit bona fide apical-basal polarity, with an outward-facing apical surface that is biochemically and functionally distinct from their inward-facing basolateral surface. Yet they are unmistakeably neurons with axon-dendrite polarity. Examples include olfactory receptor neurons and photoreceptors. In this review, I highlight how viewing these neurons as specialized epithelial cells informs our understanding of their development and raises intriguing questions about the establishment of apical-basal and axon-dendrite polarity.

Published

2022

7. Axon-dendrite and apical-basolateral sorting in a single neuron

Author

Monique Lillis, Nathan J Zaccardi, and Maxwell G Heiman

Subjects

Mammals, Neurons, Genetics, Animals, Humans, Neural Cell Adhesion Molecule L1, Dendrites, Caenorhabditis elegans, Axons

Abstract

Cells are highly organized machines with functionally specialized compartments. For example, membrane proteins are localized to axons or dendrites in neurons and to apical or basolateral surfaces in epithelial cells. Interestingly, many sensory cells—including vertebrate photoreceptors and olfactory neurons—exhibit both neuronal and epithelial features. Here, we show that Caenorhabditis elegans amphid neurons simultaneously exhibit axon-dendrite sorting like a neuron and apical-basolateral sorting like an epithelial cell. The distal ∼5–10 µm of the dendrite is apical, while the remainder of the dendrite, soma, and axon are basolateral. To determine how proteins are sorted among these compartments, we studied the localization of the conserved adhesion molecule SAX-7/L1CAM. Using minimal synthetic transmembrane proteins, we found that the 91-aa cytoplasmic tail of SAX-7 is necessary and sufficient to direct basolateral localization. Basolateral localization can be fully recapitulated using either of 2 short (10-aa or 19-aa) tail sequences that, respectively, resemble dileucine and Tyr-based motifs known to mediate sorting in mammalian epithelia. The Tyr-based motif is conserved in human L1CAM but had not previously been assigned a function. Disrupting key residues in either sequence leads to apical localization, while “improving” them to match epithelial sorting motifs leads to axon-only localization. Indeed, changing only 2 residues in a short motif is sufficient to redirect the protein between apical, basolateral, and axonal localization. Our results demonstrate that axon-dendrite and apical-basolateral sorting pathways can coexist in a single cell, and suggest that subtle changes to short sequence motifs are sufficient to redirect proteins between these pathways.

Published

2022

8. Cell-type-specific promoters for C. elegans glia

Author

Wendy Fung, Maxwell G. Heiman, and Leigh Wexler

Subjects

0301 basic medicine, Nervous system, Cell type, Cell type specific, Datasets as Topic, Biology, Article, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Sense (molecular biology), Genetics, medicine, Neuropil, Animals, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Promoter Regions, Genetic, Genes, Helminth, Promoter, Amphid, Adaptation, Physiological, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Gene Expression Regulation, nervous system, Organ Specificity, Single-Cell Analysis, Neuroglia, Biomarkers, 030217 neurology & neurosurgery, Function (biology)

Abstract

Glia shape the development and function of the C. elegans nervous system, especially its sense organs and central neuropil (nerve ring). Cell-type-specific promoters allow investigators to label or manipulate individual glial cell types, and therefore provide a key tool for deciphering glial function. In this technical resource, we compare the specificity, brightness, and consistency of cell-type-specific promoters for C. elegans glia. We identify a set of promoters for the study of seven glial cell types (F16F9.3, amphid and phasmid sheath glia; F11C7.2, amphid sheath glia only; grl-2, amphid and phasmid socket glia; hlh-17, cephalic (CEP) sheath glia; and grl-18, inner labial (IL) socket glia) as well as a pan-glial promoter (mir-228). We compare these promoters to promoters that are expressed more variably in combinations of glial cell types (delm-1 and itx-1). We note that the expression of some promoters depends on external conditions or the internal state of the organism, such as developmental stage, suggesting glial plasticity. Finally, we demonstrate an approach for prospectively identifying cell-type-specific glial promoters using existing single-cell sequencing data, and we use this approach to identify two novel promoters specific to IL socket glia (col-53 and col-177).

Published

2020

9. Open Access: Cell-type-specific promoters for C. elegans glia

Author

Wendy Fung, Leigh Wexler, and Maxwell G. Heiman

Published

2022

10. Lineage-specific control of convergent differentiation by a Forkhead repressor

Author

John I. Murray, Shai Shaham, Karolina Mizeracka, Julia M. Rogers, Martha L. Bulyk, Jonathan D. Rumley, and Maxwell G. Heiman

Subjects

Cell type, Lineage (genetic), Cell, Repressor, Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine, Animals, Humans, Cell Lineage, Progenitor cell, FOXD3, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Transcription factor, 030304 developmental biology, 0303 health sciences, fungi, Neural crest, Cell Differentiation, Forkhead Transcription Factors, Cell biology, medicine.anatomical_structure, HEK293 Cells, chemistry, Neuroglia, 030217 neurology & neurosurgery, DNA, Developmental Biology, Research Article, Transcription Factors

Abstract

During convergent differentiation, multiple developmental lineages produce a highly similar or identical cell type. However, few molecular players that drive convergent differentiation are known. Here, we show that the C. elegans Forkhead transcription factor UNC-130 is required in only one of three convergent lineages that produce the same glial cell type. UNC-130 acts transiently as a repressor in progenitors and newly-born terminal cells to allow the proper specification of cells related by lineage rather than by cell type or function. Specification defects correlate with UNC-130:DNA binding, and UNC-130 can be functionally replaced by its human homolog, the neural crest lineage determinant FoxD3. We propose that, in contrast to terminal selectors that activate cell-type specific transcriptional programs in terminally differentiating cells, UNC-130 acts early and specifically in one convergent lineage to produce a cell type that also arises from molecularly distinct progenitors in other lineages.

Published

2021

11. FBN-1, a fibrillin-related protein, is required for resistance of the epidermis to mechanical deformation during C. elegans embryogenesis

Author

Melissa Kelley, John Yochem, Michael Krieg, Andrea Calixto, Maxwell G Heiman, Aleksandra Kuzmanov, Vijaykumar Meli, Martin Chalfie, Miriam B Goodman, Shai Shaham, Alison Frand, and David S Fay

Subjects

extra cellular matrix, fibrillin, mec-8, morphogenesis, epidermis, splicing, Medicine, Science, Biology (General), QH301-705.5

Abstract

During development, biomechanical forces contour the body and provide shape to internal organs. Using genetic and molecular approaches in combination with a FRET-based tension sensor, we characterized a pulling force exerted by the elongating pharynx (foregut) on the anterior epidermis during C. elegans embryogenesis. Resistance of the epidermis to this force and to actomyosin-based circumferential constricting forces is mediated by FBN-1, a ZP domain protein related to vertebrate fibrillins. fbn-1 was required specifically within the epidermis and FBN-1 was expressed in epidermal cells and secreted to the apical surface as a putative component of the embryonic sheath. Tiling array studies indicated that fbn-1 mRNA processing requires the conserved alternative splicing factor MEC-8/RBPMS. The conserved SYM-3/FAM102A and SYM-4/WDR44 proteins, which are linked to protein trafficking, function as additional components of this network. Our studies demonstrate the importance of the apical extracellular matrix in preventing mechanical deformation of the epidermis during development.

Published

2015

12. Dendrites with specialized glial attachments develop by retrograde extension using SAX-7 and GRDN-1

Author

Ian G. McLachlan, Elizabeth R. Cebul, and Maxwell G. Heiman

Subjects

Cytoplasm, Sensory Receptor Cells, Neurogenesis, Morphogenesis, Biology, Epithelium, Adhesion protein, Cytoplasmic protein, Dendrite (crystal), Animals, Protein Isoforms, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Neural Cell Adhesion Molecules, Alleles, Cell Membrane, Microfilament Proteins, Brain, Dendrites, Mammalian brain, nervous system, Molecular mechanism, Dendrite extension, Neuroglia, Neuroscience, Developmental Biology, Research Article, Retrograde extension

Abstract

Dendrites develop elaborate morphologies in concert with surrounding glia, but the molecules that coordinate dendrite and glial morphogenesis are mostly unknown.C. elegansoffers a powerful model for identifying such factors. Previous work in this system examined dendrites and glia that develop within epithelia, similar to mammalian sense organs. Here, we focus on the neurons BAG and URX, which are not part of an epithelium but instead form membranous attachments to a single glial cell at the nose, reminiscent of dendrite-glia contacts in the mammalian brain. We show that these dendrites develop by retrograde extension, in which the nascent dendrite endings anchor to the presumptive nose and then extend by stretch during embryo elongation. Using forward genetic screens, we find that dendrite development requires the adhesion protein SAX-7/L1CAM and the cytoplasmic protein GRDN-1/CCDC88C to anchor dendrite endings at the nose. SAX-7 acts in neurons and glia, while GRDN-1 acts in glia to non-autonomously promote dendrite extension. Thus, this work shows how glial factors can help to shape dendrites, and identifies a novel molecular mechanism for dendrite growth by retrograde extension.

Published

2019

13. Long-term activity drives dendritic branch elaboration of a C. elegans sensory neuron

Author

Mario de Bono, Lotti Brose, Jesse Cohn, Elizabeth R. Cebul, Giulio Valperga, Maxwell G. Heiman, and Jonathan T. Pierce

Subjects

Nervous system, Aging, Sensory Receptor Cells, ved/biology.organism_classification_rank.species, Mutant, Cell Plasticity, Sensory system, Dendritic branch, Biology, Nervous System, 03 medical and health sciences, 0302 clinical medicine, medicine, Premovement neuronal activity, Animals, Anaerobiosis, Model organism, Caenorhabditis elegans, Molecular Biology, 030304 developmental biology, 0303 health sciences, ved/biology, Cell Biology, Dendrites, Sensory neuron, Oxygen, medicine.anatomical_structure, Neuron, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Neuronal activity often leads to alterations in gene expression and cellular architecture. The nematode Caenorhabditis elegans, owing to its compact translucent nervous system, is a powerful system in which to study conserved aspects of the development and plasticity of neuronal morphology. Here we focus on one pair of sensory neurons, termed URX, which the worm uses to sense and avoid high levels of environmental oxygen. Previous studies have reported that the URX neuron pair has variable branched endings at its dendritic sensory tip. By controlling oxygen levels and analyzing mutants, we found that these microtubule-rich branched endings grow over time as a consequence of neuronal activity in adulthood. We also find that the growth of these branches correlates with an increase in cellular sensitivity to particular ranges of oxygen that is observable in the behavior of older worms. Given the strengths of C. elegans as a model organism, URX may serve as a potent system for uncovering genes and mechanisms involved in activity-dependent morphological changes in neurons and possible adaptive changes in the aging nervous system.

Published

2019

14. Morphogenesis of neurons and glia within an epithelium

Author

Claire R. Williams, Megan K. Chong, Isabel I. C. Low, Bradley M. Wierbowski, Irina Kolotuev, Maxwell G. Heiman, Ian G. McLachlan, Harvard Medical School [Boston] (HMS), Boston Children's Hospital, Centre de Microscopie de Rennes (MRic), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique ), National Science Foundation, GM108754, National Institutes of Health, March of Dimes Foundation, and Université de Rennes (UR)-Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique )

Subjects

Male, dendrites, glia, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Morphogenesis, Biology, Epithelium, Tight Junctions, Sensory epithelia, 03 medical and health sciences, 0302 clinical medicine, C elegans, medicine, Animals, amphid, Caenorhabditis elegans/metabolism, Caenorhabditis elegans Proteins/metabolism, Cytoskeleton/metabolism, Dendrites/metabolism, Drosophila melanogaster/metabolism, Epithelial Cells/metabolism, Epithelium/metabolism, Female, Membrane Proteins/metabolism, Mutation, Neuroglia/metabolism, Neurons/metabolism, Tight Junctions/metabolism, Amphid, C. elegans, Dendrites, Glia, Neurodevelopment, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Cytoskeleton, 030304 developmental biology, Neurons, 0303 health sciences, Polarity (international relations), Tight junction, neurodevelopment, Membrane Proteins, Epithelial Cells, [SDV.BDD.MOR]Life Sciences [q-bio]/Development Biology/Morphogenesis, Cell biology, medicine.anatomical_structure, Drosophila melanogaster, nervous system, sensory epithelia, Developmental biology, Neuroglia, 030217 neurology & neurosurgery, Developmental Biology, Research Article

Abstract

To sense the outside world, some neurons protrude across epithelia, the cellular barriers that line every surface of our bodies. To study the morphogenesis of such neurons, we examined theC. elegansamphid, in which dendrites protrude through a glial channel at the nose. During development, amphid dendrites extend by attaching to the nose via DYF-7, a type of protein typically found in epithelial apical ECM. Here, we show that amphid neurons and glia exhibit epithelial properties, including tight junctions and apical-basal polarity, and develop in a manner resembling other epithelia. We find that DYF-7 is a fibril-forming apical ECM component that prevents rupture of the tube-shaped glial channel, reminiscent of roles for apical ECM in other narrow epithelial tubes. We also identify a role for FRM-2, a homolog of EPBL15/moe/Yurt which promote epithelial integrity in other systems. Finally, we show that other environmentally-exposed neurons share a requirement for DYF-7. Together, our results suggest that these neurons and glia can be viewed as part of an epithelium continuous with the skin, and are shaped by mechanisms shared with other epithelia.

Published

2019

15. Author response: A multicellular rosette-mediated collective dendrite extension

Author

Ismar Kovacevic, Li Fan, Zhirong Bao, and Maxwell G. Heiman

Subjects

Multicellular organism, Rosette (schizont appearance), Dendrite extension, Biology, Cell biology

Published

2018

16. Ordered arrangement of dendrites within a C. elegans sensory nerve bundle

Author

Maxwell G. Heiman and Zhiqi Candice Yip

Subjects

0301 basic medicine, Self-organization, Nerve net, dendrites, QH301-705.5, Science, Sensory system, Dendrite, Biology, fasciculation, General Biochemistry, Genetics and Molecular Biology, neural development, 03 medical and health sciences, 0302 clinical medicine, medicine, Biology (General), 030304 developmental biology, 0303 health sciences, General Immunology and Microbiology, Chemistry, Cadherin, General Neuroscience, Cilium, cell adhesion, General Medicine, Sensory Receptor Cells, 030104 developmental biology, Order (biology), medicine.anatomical_structure, Bundle, Medicine, Neural cell adhesion molecule, Neural development, Developmental biology, Neuroscience, 030217 neurology & neurosurgery, Sensory nerve

Abstract

Biological systems are organized into well-ordered structures and can evolve new patterns when perturbed. To identify principles underlying biological order, we turned toC. elegansfor its simple anatomy and powerful genetics. We developed a method to quantify the arrangement of three dendrites in the main sensory nerve bundle, and found that they exhibit a stereotyped arrangement throughout larval growth. Dendrite order does not require prominent features including sensory cilia and glial junctions. In contrast, loss of the cell adhesion molecule (CAM) CDH-4/Fat-like cadherin causes dendrites to be ordered randomly, despite remaining bundled. Loss of the CAMs PTP-3/LAR or SAX-7/L1CAM causes dendrites to adopt an altered order, which becomes increasingly random as animals grow. Misexpression of SAX-7 leads to subtle but reproducible changes in dendrite order. Our results suggest that differential expression of CAMs allows dendrites to self-organize into a stereotyped arrangement that readily gives rise to new patterns when perturbed.

Published

2018

17. Author response: Ordered arrangement of dendrites within a C. elegans sensory nerve bundle

Author

Zhiqi Candice Yip and Maxwell G. Heiman

Subjects

medicine.anatomical_structure, Bundle, medicine, Biology, Neuroscience, Sensory nerve

Published

2018

18. A neuronal MAP kinase constrains growth of a C. elegans sensory dendrite throughout the life of the organism

Author

Mario de Bono, Maxwell G. Heiman, Isabel Beets, and Ian G. McLachlan

Subjects

0303 health sciences, Dendritic spine, Biology, Dendrite morphogenesis, Cell biology, 03 medical and health sciences, Dendrite (crystal), 0302 clinical medicine, medicine.anatomical_structure, medicine, Sensory dendrite, Compartment (development), Neuron, Kinase activity, Developmental biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Neurons develop elaborate morphologies that provide a model for understanding cellular architecture. By studyingC. eleganssensory dendrites, we previously identified genes that act to promote the extension of ciliated sensory dendrites during embryogenesis. Interestingly, the nonciliated dendrite of the oxygen-sensing neuron URX is not affected by these genes, suggesting it develops through a distinct mechanism. Here, we use a visual forward genetic screen to identify mutants that affect URX dendrite morphogenesis. We find that disruption of the MAP kinase MAPK-15 or the βH-spectrin SMA-1 causes a phenotype opposite to what we had seen before: dendrites extend normally during embryogenesis but begin to overgrow as the animals reach adulthood, ultimately extending up to 150% of their normal length. SMA-1 is broadly expressed and acts non-cell-autonomously, while MAPK-15 is expressed in many sensory neurons including URX and acts cell-autonomously. MAPK-15 acts at the time of overgrowth, localizes at the dendrite ending, and requires its kinase activity, suggesting it acts locally in time and space to constrain dendrite growth. Finally, we find that the oxygen-sensing guanylate cyclase GCY-35, which normally localizes at the dendrite ending, is localized throughout the overgrown region, and that overgrowth can be suppressed by overexpressing GCY-35 or by genetically mimicking elevated cGMP signaling. These results suggest that overgrowth may correspond to expansion of a sensory compartment at the dendrite ending, reminiscent of the remodeling of sensory cilia or dendritic spines. Thus, in contrast to established pathways that promote dendrite growth during early development, our results reveal a distinct mechanism that constrains dendrite growth throughout the life of the animal, possibly by controlling the size of a sensory compartment at the dendrite ending.AUTHOR SUMMARYLewis Carroll’s Alice told the Caterpillar, “Being so many different sizes in a day is very confusing.” Like Alice, the cells of our bodies face a problem in size control – they must become the right size and remain that way throughout the life of the organism. This problem is especially relevant for nerve cells (neurons), as the lengths of their elaborate dendrites determine the connections they can make. To learn how neurons control their size, we turned not to a Caterpillar but to a worm: the microscopic nematodeC. elegans, in which single neurons can be easily visualized and the length of each dendrite is highly predictable across individuals. We focused on a single dendrite, that of the oxygen-sensing neuron URX, and we identified two genes that control its length. When these genes are disrupted, the dendrite develops correctly in embryos but then, like Alice, grows too much, eventually extending up to 1.5x its normal length. Thus, in contrast to known pathways that promote the initial growth of a dendrite early in development, our results help to explain how a neuron maintains its dendrite at a consistent length throughout the animal’s life.

Published

2018

19. A multicellular rosette-mediated collective dendrite extension

Author

Ismar Kovacevic, Maxwell G. Heiman, Zhirong Bao, and Li Fan

Subjects

Embryo, Nonmammalian, Neurite, QH301-705.5, Science, organogenesis, Dendrite, Biology, General Biochemistry, Genetics and Molecular Biology, Rosette (botany), 03 medical and health sciences, 0302 clinical medicine, dendrite morphogenesis, Cell Movement, collective cell behavior, medicine, Biological neural network, Animals, multicellular rosette, Biology (General), Caenorhabditis elegans, Caenorhabditis elegans Proteins, neuron-epicermis interaction, 030304 developmental biology, 0303 health sciences, Sensory depression, General Immunology and Microbiology, sensory organ, General Neuroscience, Amphid, General Medicine, Dendrites, Dendrite morphogenesis, Cell biology, medicine.anatomical_structure, C. elegans, Medicine, Dendrite extension, Epidermis, Cell Adhesion Molecules, 030217 neurology & neurosurgery, Sensory nerve, Research Article, Neuroscience

Abstract

Coordination of neurite morphogenesis with surrounding tissues is crucial to the establishment of neural circuits, but the underlying cellular and molecular mechanisms remain poorly understood. We show that neurons in a C. elegans sensory organ, called the amphid, undergo a collective dendrite extension to initiate formation of the sensory nerve. The amphid neurons first assemble into a multicellular rosette. The vertex of the rosette, which becomes the dendrite tips, is attached to the anteriorly migrating epidermis and carried to the sensory depression, extruding the dendrites away from the neuronal cell bodies. Multiple adhesion molecules including DYF-7, SAX-7, HMR-1 and DLG-1 function redundantly in rosette-to-epidermis attachment. PAR-6 is localized to the rosette vertex and dendrite tips, and promotes DYF-7 localization and dendrite extension. Our results suggest a collective mechanism of neurite extension that is distinct from the classical pioneer-follower model and highlight the role of mechanical cues from surrounding tissues in shaping neurites.

Published

2018

20. Computer-Assisted Transgenesis of Caenorhabditis elegans for Deep Phenotyping

Author

Maxwell G. Heiman, Mehmet Fatih Yanik, James Noraky, Adam T. Falls, and Cody L. Gilleland

Subjects

Microinjections, Transgene, Mutant, ved/biology.organism_classification_rank.species, deep phenotyping, high throughput, Investigations, Biology, transgenesis, Animals, Genetically Modified, Genetics, Animals, Humans, Caenorhabditis elegans, Model organism, Gene, automation, Automation, Laboratory, ved/biology, Gene Transfer Techniques, Methods, Technology, and Resources, Robotics, biology.organism_classification, Phenotype, Transgenesis, C. elegans, Human genome, Algorithms

Abstract

A major goal in the study of human diseases is to assign functions to genes or genetic variants. The model organism Caenorhabditis elegans provides a powerful tool because homologs of many human genes are identifiable, and large collections of genetic vectors and mutant strains are available. However, the delivery of such vector libraries into mutant strains remains a long-standing experimental bottleneck for phenotypic analysis. Here, we present a computer-assisted microinjection platform to streamline the production of transgenic C. elegans with multiple vectors for deep phenotyping. Briefly, animals are immobilized in a temperature-sensitive hydrogel using a standard multiwell platform. Microinjections are then performed under control of an automated microscope using precision robotics driven by customized computer vision algorithms. We demonstrate utility by phenotyping the morphology of 12 neuronal classes in six mutant backgrounds using combinations of neuron-type-specific fluorescent reporters. This technology can industrialize the assignment of in vivo gene function by enabling large-scale transgenic engineering.

Published

2015

21. The many glia of a tiny nematode: studying glial diversity using Caenorhabditis elegans

Author

Karolina Mizeracka and Maxwell G. Heiman

Subjects

Nervous system, education.field_of_study, Nematode caenorhabditis elegans, media_common.quotation_subject, Population, Cell Biology, Anatomy, Biology, biology.organism_classification, Nematode, medicine.anatomical_structure, nervous system, medicine, education, human activities, Molecular Biology, Neuroscience, Function (biology), Organism, Caenorhabditis elegans, Developmental Biology, Diversity (politics), media_common

Abstract

Glia constitute a major, understudied population of cells in the nervous system. Currently, it is appreciated that these cells exhibit vast morphological, functional, and molecular diversity, but our understanding of glial biology is limited. Some key unanswered questions include how glial diversity is generated during development and what functions distinct glial subtypes serve in the mature nervous system. The nematode Caenorhabditis elegans contains a defined set of glia, which have clear morphological and molecular differences, and thus provides a simplified model for understanding glial diversity. In addition, recent experiments suggest that the molecular mechanisms underlying the generation of glial diversity in C. elegans are conserved with those in mammals. In this review, we summarize the surprising diversity of glial subtypes present in this simple organism, and highlight current thinking about what roles they perform in the nervous system. We emphasize how genetic approaches may be used to identify the mechanistic origins of glial diversity, which is key to understanding how glia function in health and disease. WIREs Dev Biol 2015, 4:151–160. doi: 10.1002/wdev.171 For further resources related to this article, please visit the WIREs website. Conflict of interest: The authors have declared no conflicts of interest for this article.

Published

2015

22. A conserved role for Girdin in basal body positioning and ciliogenesis

Author

Anna Kazatskaya, Ian G. McLachlan, Anique Olivier-Mason, Oliver E. Blacque, Inna V. Nechipurenko, Julie Kennedy, Piali Sengupta, and Maxwell G. Heiman

Subjects

0301 basic medicine, Scaffold protein, Centriole, Sensory Receptor Cells, Vesicular Transport Proteins, Context (language use), Biology, Microtubules, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Ciliogenesis, Ciliary rootlet, Morphogenesis, Basal body, Animals, Humans, Cilia, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Cytoskeleton, Centrioles, Organelles, Cilium, Microfilament Proteins, Cell Biology, Basal Bodies, Cell biology, Cytoskeletal Proteins, 030104 developmental biology, Rootletin, Developmental Biology, Signal Transduction

Abstract

Primary cilia are ubiquitous sensory organelles that mediate diverse signaling pathways. Cilia position on the cell surface is determined by the location of the basal body (BB) that templates the cilium. The mechanisms that regulate BB positioning in the context of ciliogenesis are largely unknown. Here we show that the conserved signaling and scaffolding protein Girdin localizes to the proximal regions of centrioles and regulates BB positioning and ciliogenesis in Caenorhabditis elegans sensory neurons and human RPE-1 cells. Girdin depletion alters localization of the intercentriolar linker and ciliary rootlet component rootletin, and rootletin knockdown in RPE-1 cells mimics Girdin-dependent phenotypes. C. elegans Girdin also regulates localization of the apical junction component AJM-1, suggesting that in nematodes Girdin may position BBs via rootletin- and AJM-1-dependent anchoring to the cytoskeleton and plasma membrane, respectively. Together, our results describe a conserved role for Girdin in BB positioning and ciliogenesis.

Published

2016

23. Twigs into branches: how a filopodium becomes a dendrite

Author

Maxwell G. Heiman and Shai Shaham

Subjects

animal structures, General Neuroscience, Cell Membrane, Dendrites, Adhesion, Neurotransmission, Biology, Synaptic Transmission, Article, Cell biology, Cell membrane, medicine.anatomical_structure, Neurotransmitter receptor, Synapses, Cell Adhesion, Dendrite (mathematics), medicine, Animals, Calcium, Pseudopodia, Cell adhesion, Neuroscience, Filopodia

Abstract

A dendrite grows by sprouting filopodia, some of which mature into stable dendrite branches that bear synapses and sprout filopodia of their own. Recent work has shown that a filopodium begins deciding to become a stable branch within one minute of contacting a presynaptic partner, but what triggers this decision remains unknown. We consider the evidence for three possible triggers: activity of neurotransmitter receptors, signaling through adhesion proteins, and heightened membrane tension as the filopodium attempts to retract but is held in place by adhesive contacts with the target. Of these, membrane tension-induced signaling is especially appealing, as it would serve as a general reporter of attachment, independent of which specific adhesion molecules are used.

Published

2010

24. Duplication of a Single Neuron in C. elegans Reveals a Pathway for Dendrite Tiling by Mutual Repulsion

Author

Zhiqi Candice, Yip and Maxwell G, Heiman

Subjects

Mutation, Animals, Cell Count, Dendrites, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Models, Biological, Signal Transduction

Abstract

Simple cell-cell interactions can give rise to complex cellular patterns. For example, neurons of the same type can interact to create a complex patchwork of non-overlapping dendrite arbors, a pattern known as dendrite tiling. Dendrite tiling often involves mutual repulsion between neighboring neurons. While dendrite tiling is found across nervous systems, the nematode Caenorhabditis elegans has a relatively simple nervous system with few opportunities for tiling. Here, we show that genetic duplication of a single neuron, PVD, is sufficient to create dendrite tiling among the resulting ectopic neurons. We use laser ablation to show that this tiling is mediated by mutual repulsion between neighbors. Furthermore, we find that tiling requires a repulsion signal (UNC-6/Netrin and its receptors UNC-40/DCC and UNC-5) that normally patterns the PVD dendrite arbor. These results demonstrate that an apparently complex cellular pattern can emerge in a simple nervous system merely by increasing neuron number.

Published

2015

25. Author response: FBN-1, a fibrillin-related protein, is required for resistance of the epidermis to mechanical deformation during C. elegans embryogenesis

Author

Alison R. Frand, Shai Shaham, David S. Fay, Martin Chalfie, John Yochem, Aleksandra Kuzmanov, Andrea Calixto, Melissa Kelley, Vijaykumar S. Meli, Miriam B. Goodman, Maxwell G. Heiman, and Michael Krieg

Subjects

Epidermis (zoology), Chemistry, Embryogenesis, Deformation (meteorology), Fibrillin, Cell biology

Published

2015

26. The many glia of a tiny nematode: studying glial diversity using Caenorhabditis elegans

Author

Karolina, Mizeracka and Maxwell G, Heiman

Subjects

Animals, Sense Organs, Caenorhabditis elegans, Models, Biological, Neuroglia

Abstract

Glia constitute a major, understudied population of cells in the nervous system. Currently, it is appreciated that these cells exhibit vast morphological, functional, and molecular diversity, but our understanding of glial biology is limited. Some key unanswered questions include how glial diversity is generated during development and what functions distinct glial subtypes serve in the mature nervous system. The nematode Caenorhabditis elegans contains a defined set of glia, which have clear morphological and molecular differences, and thus provides a simplified model for understanding glial diversity. In addition, recent experiments suggest that the molecular mechanisms underlying the generation of glial diversity in C. elegans are conserved with those in mammals. In this review, we summarize the surprising diversity of glial subtypes present in this simple organism, and highlight current thinking about what roles they perform in the nervous system. We emphasize how genetic approaches may be used to identify the mechanistic origins of glial diversity, which is key to understanding how glia function in health and disease. For further resources related to this article, please visit the WIREs website.The authors have declared no conflicts of interest for this article.

Published

2014

27. Shaping dendrites with machinery borrowed from epithelia

Author

Ian G. McLachlan and Maxwell G. Heiman

Subjects

Tight junction, Cadherin, General Neuroscience, Neurogenesis, Morphogenesis, Dendrites, Biology, Dendrite morphogenesis, Cell biology, Extracellular matrix, medicine.anatomical_structure, Catenin, medicine, Animals, Humans, Zona pellucida, Claudin, Neuroscience, Cell Adhesion Molecules

Abstract

The ciliated receptive endings of sensory cells and the dendrites of other neurons are shaped by adhesive interactions, many of which depend on machinery also present in epithelia. Sensory cells are shaped by interactions with support cells through adhesion junctions via the Crumbs complex, tight junction components such as claudins, as well as interactions with apical extracellular matrix composed of zona pellucida domain proteins. Neuronal dendrites are shaped by adhesion machinery that includes cadherins, catenins, afadin, L1CAM, CHL1, Sidekicks, Contactin and Caspr, many of which are shared with epithelia. This review highlights this shared machinery, and suggests that mechanisms of epithelial morphogenesis may thus provide a guide to understanding dendrite morphogenesis.

Published

2013

28. Structure of sterol aliphatic chains affects yeast cell shape and cell fusion during mating

Author

Peter Walter, Alex Engel, Pablo S. Aguilar, Teymuras V. Kurzchalia, Maxwell G. Heiman, Dominik Schwudke, Nathan Gushwa, and Tobias C. Walther

Subjects

Saccharomyces cerevisiae Proteins, Cell, Mutant, Genes, Fungal, Saccharomyces cerevisiae, Biology, Cell wall, Cell Fusion, chemistry.chemical_compound, Cytochrome P-450 Enzyme System, Ergosterol, medicine, Mating, Cell Shape, Multidisciplinary, Cell fusion, Biological Sciences, Sterol, Yeast, Cell biology, medicine.anatomical_structure, Biochemistry, chemistry, Mutation, Biocatalysis, Oxidoreductases, Gene Deletion

Abstract

Under mating conditions, yeast cells adopt a characteristic pear-shaped morphology, called a “shmoo,” as they project a cell extension toward their mating partners. Mating partners make contact at their shmoo tips, dissolve the intervening cell wall, and fuse their plasma membranes. We identified mutations in ERG4 , encoding the enzyme that catalyzes the last step of ergosterol biosynthesis, that impair both shmoo formation and cell fusion. Upon pheromone treatment, erg4 Δ mutants polarized growth, lipids, and proteins involved in mating but did not form properly shaped shmoos and fused with low efficiency. Supplementation with ergosterol partially suppressed the shmooing defect but not the cell fusion defect. By contrast, removal of the Erg4 substrate ergosta-5,7,22,24(28)-tetraenol, which accumulates in erg4 Δ mutant cells and contains an extra double bond in the aliphatic chain of the sterol, restored both shmooing and cell fusion to wild-type levels. Thus, a two-atom change in the aliphatic moiety of ergosterol is sufficient to obstruct cell shape remodeling and cell fusion.

Published

2010

29. Ancestral roles of glia suggested by the nervous system of Caenorhabditis elegans

Author

Shai Shaham and Maxwell G. Heiman

Subjects

Nervous system, Mammalian nervous system, Cell type, Nematode caenorhabditis elegans, Sensory system, Cell Biology, Biology, biology.organism_classification, Cell biology, Cellular and Molecular Neuroscience, medicine.anatomical_structure, nervous system, medicine, Caenorhabditis elegans

Abstract

The nematode Caenorhabditis elegans has a simple nervous system with glia restricted primarily to sensory organs. Some of the activities that would be provided by glia in the mammalian nervous system are either absent or provided by non-glial cell types in C. elegans, with only a select set of mammalian glial activities being similarly provided by specialized glial cells in this animal. These observations suggest that ancestral roles of glia may be to modulate neuronal morphology and neuronal sensitivity in sensory organs.

Published

2008

30. The Golgi-resident protease Kex2 acts in conjunction with Prm1 to facilitate cell fusion during yeast mating

Author

Alex Engel, Peter Walter, and Maxwell G. Heiman

Subjects

Golgi Apparatus, Carboxypeptidases, Membrane Fusion, Medical and Health Sciences, Cell membrane, Cell Wall, Models, Glucan 1, Mating, Cation Transport Proteins, Research Articles, Heat-Shock Proteins, Adenosine Triphosphatases, Microscopy, Cell fusion, biology, Biological Sciences, Transmembrane protein, Cell biology, medicine.anatomical_structure, Proprotein Convertases, Mitogen-Activated Protein Kinases, Sodium-Potassium-Exchanging ATPase, Saccharomyces cerevisiae Proteins, 1.1 Normal biological development and functioning, Saccharomyces cerevisiae, Models, Biological, Electron, Article, Fungal Proteins, Underpinning research, Osmotic Pressure, medicine, Dipeptidyl-Peptidases and Tripeptidyl-Peptidases, 3-beta-Glucosidase, Glycoproteins, Cell Membrane, Cytoplasmic Vesicles, Lipid bilayer fusion, Membrane Proteins, Congo Red, Cell Biology, Glucan 1,3-beta-Glucosidase, biology.organism_classification, Biological, Microscopy, Electron, Cytoskeletal Proteins, Mating of yeast, Mutation, Fusion mechanism, Developmental Biology

Abstract

The molecular machines that mediate cell fusion are unknown. Previously, we identified a multispanning transmembrane protein, Prm1 (pheromone-regulated membrane protein 1), that acts during yeast mating (Heiman, M.G., and P. Walter. 2000. J. Cell Biol. 151:719–730). Without Prm1, a substantial fraction of mating pairs arrest with their plasma membranes tightly apposed yet unfused. In this study, we show that lack of the Golgi-resident protease Kex2 strongly enhances the cell fusion defect of Prm1-deficient mating pairs and causes a mild fusion defect in otherwise wild-type mating pairs. Lack of the Kex1 protease but not the Ste13 protease results in similar defects. Δkex2 and Δkex1 fusion defects were suppressed by osmotic support, a trait shared with mutants defective in cell wall remodeling. In contrast, other cell wall mutants do not enhance the Δprm1 fusion defect. Electron microscopy of Δkex2-derived mating pairs revealed novel extracellular blebs at presumptive sites of fusion. Kex2 and Kex1 may promote cell fusion by proteolytically processing substrates that act in parallel to Prm1 as an alternative fusion machine, as cell wall components, or both.

Published

2007

31. Prm1p, a pheromone-regulated multispanning membrane protein, facilitates plasma membrane fusion during yeast mating

Author

Maxwell G. Heiman and Peter Walter

Subjects

membrane adherence, Saccharomyces cerevisiae Proteins, Genes, Fungal, Molecular Sequence Data, Biology, Haploidy, Membrane Fusion, Pheromones, Cell membrane, Cell Fusion, Fungal Proteins, Cell Wall, Gene Expression Regulation, Fungal, Yeasts, Plasma membrane fusion, medicine, Amino Acid Sequence, prezygote, Mating, Cloning, Molecular, Conserved Sequence, Cell fusion, Base Sequence, Reproduction, Cell Membrane, genomic expression analysis, Lipid bilayer fusion, Membrane Proteins, Cell Biology, data mining, Molecular biology, Diploidy, Transmembrane protein, Cell biology, Protein Structure, Tertiary, Microscopy, Electron, Protein Transport, medicine.anatomical_structure, Phenotype, Mating of yeast, Original Article, Sequence Alignment, Fusion mechanism, Gene Deletion

Abstract

Cell fusion occurs throughout development, from fertilization to organogenesis. The molecular mechanisms driving plasma membrane fusion in these processes remain unknown. While yeast mating offers an excellent model system in which to study cell fusion, all genes previously shown to regulate the process act at or before cell wall breakdown; i.e., well before the two plasma membranes have come in contact. Using a new strategy in which genomic data is used to predict which genes may possess a given function, we identified PRM1, a gene that is selectively expressed during mating and that encodes a multispanning transmembrane protein. Prm1p localizes to sites of cell-cell contact where fusion occurs. In matings between Deltaprm1 mutants, a large fraction of cells initiate zygote formation and degrade the cell wall separating mating partners but then fail to fuse. Electron microscopic analysis reveals that the two plasma membranes in these mating pairs are tightly apposed, remaining separated only by a uniform gap of approximately 8 nm. Thus, the phenotype of Deltaprm1 mutants defines a new step in the mating reaction in which membranes are juxtaposed, possibly through a defined adherence junction, yet remain unfused. This phenotype suggests a role for Prm1p in plasma membrane fusion.

Published

2000

32. Neurons at the extremes of cell biology

Author

Leo J. Pallanck and Maxwell G. Heiman

Subjects

Neurons, Cell type, ASCB Annual Meeting Highlights, Membrane Traffic, media_common.quotation_subject, Cell, Longevity, Neurodegenerative Diseases, Cell Biology, Congresses as Topic, Biology, Cell biology, medicine.anatomical_structure, medicine, Animals, Humans, Metabolic activity, Cytoskeleton, Molecular Biology, media_common

Abstract

Neurons are the pedestals of human consciousness, yet from a cell biological view they are little more than specialized epithelia. Indeed, as highlighted in the “Neuronal Development and Degeneration” Minisymposium, neurons inhabit conventional cell biology at an extreme: in their diversity of cell types, the specificity of their cell–cell junctions and cell–cell signaling, their degree of asymmetric polarization, their rate and volume of membrane traffic, the size and stability of their cytoskeletal assemblies, and their metabolic activity and ion flux. This extreme lifestyle requires extreme upkeep and, although neurons can be extreme in their longevity, if any of the above processes are compromised then neurodegenerative diseases can ensue. This session highlighted what can be learned by studying cell biology at the extremes, beginning with neuronal development and ending in studies of neurodegenerative disease.

Published

2011

33. DEX-1 and DYF-7 Establish Sensory Dendrite Length by Anchoring Dendritic Tips during Cell Migration

Author

Shai Shaham and Maxwell G. Heiman

Subjects

Nervous system, 0303 health sciences, Sense organ, Biochemistry, Genetics and Molecular Biology(all), Stereocilia, Anchoring, Amphid, Cell migration, Biology, General Biochemistry, Genetics and Molecular Biology, MOLNEURO, Cell biology, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Sensory dendrite, medicine, Dendrite extension, CELLBIO, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SummaryCells are devices whose structures delimit function. For example, in the nervous system, neuronal and glial shapes dictate paths of information flow. To understand how cells acquire their shapes, we examined the formation of a sense organ in C. elegans. Using time-lapse imaging, we found that sensory dendrites form by stationary anchoring of dendritic tips during cell-body migration. A genetic screen identified DEX-1 and DYF-7, extracellular proteins required for dendritic tip anchoring, which act cooperatively at the time and place of anchoring. DEX-1 and DYF-7 contain, respectively, zonadhesin and zona pellucida domains, and DYF-7 self-associates into multimers important for anchoring. Thus, unlike other dendrites, amphid dendritic tips are positioned by DEX-1 and DYF-7 without the need for long-range guidance cues. In sequence and function, DEX-1 and DYF-7 resemble tectorins, which anchor stereocilia in the inner ear, suggesting that a sensory dendrite anchor may have evolved into part of a mechanosensor.

34. A neuronal MAP kinase constrains growth of a Caenorhabditis elegans sensory dendrite throughout the life of the organism

Author

Maxwell G. Heiman, Mario de Bono, Isabel Beets, and Ian G. McLachlan

Subjects

0301 basic medicine, C. ELEGANS, EXPRESSION, Cancer Research, CORTEX, Dendritic spine, lcsh:QH426-470, Sensory Receptor Cells, Neurogenesis, PROTEIN, Biology, OXYGEN, Animals, Genetically Modified, 03 medical and health sciences, Dendrite (crystal), Cellular neuroscience, CILIA, Genetics, medicine, Compartment (development), Animals, Kinase activity, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Cyclic GMP, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Genetics & Heredity, Science & Technology, Dendrites, Cell biology, Dendrite morphogenesis, FAMILY, Oxygen, lcsh:Genetics, 030104 developmental biology, medicine.anatomical_structure, Guanylate Cyclase, Mutation, MORPHOGENESIS, Sensory dendrite, SOLUBLE GUANYLATE CYCLASES, Neuron, Mitogen-Activated Protein Kinases, Life Sciences & Biomedicine, BEHAVIOR, Signal Transduction

Abstract

Neurons develop elaborate morphologies that provide a model for understanding cellular architecture. By studying C. elegans sensory dendrites, we previously identified genes that act to promote the extension of ciliated sensory dendrites during embryogenesis. Interestingly, the nonciliated dendrite of the oxygen-sensing neuron URX is not affected by these genes, suggesting it develops through a distinct mechanism. Here, we use a visual forward genetic screen to identify mutants that affect URX dendrite morphogenesis. We find that disruption of the MAP kinase MAPK-15 or the βH-spectrin SMA-1 causes a phenotype opposite to what we had seen before: dendrites extend normally during embryogenesis but begin to overgrow as the animals reach adulthood, ultimately extending up to 150% of their normal length. SMA-1 is broadly expressed and acts non-cell-autonomously, while MAPK-15 is expressed in many sensory neurons including URX and acts cell-autonomously. MAPK-15 acts at the time of overgrowth, localizes at the dendrite ending, and requires its kinase activity, suggesting it acts locally in time and space to constrain dendrite growth. Finally, we find that the oxygen-sensing guanylate cyclase GCY-35, which normally localizes at the dendrite ending, is localized throughout the overgrown region, and that overgrowth can be suppressed by overexpressing GCY-35 or by genetically mimicking elevated cGMP signaling. These results suggest that overgrowth may correspond to expansion of a sensory compartment at the dendrite ending, reminiscent of the remodeling of sensory cilia or dendritic spines. Thus, in contrast to established pathways that promote dendrite growth during early development, our results reveal a distinct mechanism that constrains dendrite growth throughout the life of the animal, possibly by controlling the size of a sensory compartment at the dendrite ending. ispartof: Plos Genetics vol:14 issue:6 ispartof: location:United States status: published

35. A neuronal MAP kinase constrains growth of a Caenorhabditis elegans sensory dendrite throughout the life of the organism.

Author

Ian G McLachlan, Isabel Beets, Mario de Bono, and Maxwell G Heiman

Subjects

Genetics, QH426-470

Abstract

Neurons develop elaborate morphologies that provide a model for understanding cellular architecture. By studying C. elegans sensory dendrites, we previously identified genes that act to promote the extension of ciliated sensory dendrites during embryogenesis. Interestingly, the nonciliated dendrite of the oxygen-sensing neuron URX is not affected by these genes, suggesting it develops through a distinct mechanism. Here, we use a visual forward genetic screen to identify mutants that affect URX dendrite morphogenesis. We find that disruption of the MAP kinase MAPK-15 or the βH-spectrin SMA-1 causes a phenotype opposite to what we had seen before: dendrites extend normally during embryogenesis but begin to overgrow as the animals reach adulthood, ultimately extending up to 150% of their normal length. SMA-1 is broadly expressed and acts non-cell-autonomously, while MAPK-15 is expressed in many sensory neurons including URX and acts cell-autonomously. MAPK-15 acts at the time of overgrowth, localizes at the dendrite ending, and requires its kinase activity, suggesting it acts locally in time and space to constrain dendrite growth. Finally, we find that the oxygen-sensing guanylate cyclase GCY-35, which normally localizes at the dendrite ending, is localized throughout the overgrown region, and that overgrowth can be suppressed by overexpressing GCY-35 or by genetically mimicking elevated cGMP signaling. These results suggest that overgrowth may correspond to expansion of a sensory compartment at the dendrite ending, reminiscent of the remodeling of sensory cilia or dendritic spines. Thus, in contrast to established pathways that promote dendrite growth during early development, our results reveal a distinct mechanism that constrains dendrite growth throughout the life of the animal, possibly by controlling the size of a sensory compartment at the dendrite ending.

Published

2018