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Nervous system function, from sensory perception to motor control and cognition, requires the correct wiring of neural circuits during development. The establishment of these circuits consists of the growth and guidance of signal-sending axons and signal-receiving dendrites to their correct targets. Despite being exposed to the same molecular environment, a neuron's axon and dendrites have different morphologies and targets. Using the C. elegans DA9 motoneuron we explore mechanisms of dendrite growth and how a dendrite-specific response is achieved to a cue regulating axons and dendrites. We found that DA9 dendrite development is spatially and temporally distinct from the axon. While the axon grows embryonically, the dendrite develops postembryonically. Characterizing DA9 dendrite growth in larvae, adults and body size mutants suggests that it is not driven by size, but rather by a local cue. A candidate approach to identify this cue taught us that the guidance cue UNC-6/Netrin is required for both axon and dendrite development in DA9. The UNC-6 repulsive receptor UNC-5 repels the axon from the ventral nerve cord, while the attractive receptor UNC-40 is dendritically enriched and promotes antero-posterior dendrite growth. While ventrally secreted UNC-6 instructs axon guidance, dorsal or even membrane-tethered UNC-6 can support dendrite development. Surprisingly, the kinase PAR-4/LKB1 is selectively required for UNC-40 signaling in dendrite outgrowth. Finally, we found that the C-terminal motor kinesin KLP-16 also promotes DA9 dendrite growth and that its enrichment at the DA9 dendrite distal tip may be partially regulated by PAR-4/LKB1. These data suggest that axon and dendrite of one neuron interpret common environmental cues with different receptors and downstream signaling pathways.
The first of its kind, this laboratory handbook emphasizes diverse methods and technologies needed to investigate C. elegans, both as an integrated organism and as a model system for research inquiries in cell, developmental, and molecular biology, as well as in genetics and pharmacology. Four primary sections--Genetic and Culture Methods, Neurobiology, Cell and Molecular Biology, and Genomics and Informatics--reflect the cross-disciplinary nature of C. elegans research. Because C. elegans is a simple and malleable organism with a small genome and few cell types, it provides an elegant demonstr.
Since the discovery of actin by Straub in the 1950’s and the pioneering work of Oosawa on actin self-assembly in helical laments in the 1960’s, many books and conference proceedings have been published. As one of the most essential p- teins in life, essential for movement in organisms rangingfrom bacteria to higher eukaryotes, it is no surprise that actin has fascinated generations of scientists from many different elds. Actin can be considered as a “living treasure” of biology; the kinetics and thermodynamics of self-assembly, the dissipative nature of actin po- merization, the molecular interactions of monomeric and polymerized actin with regulators, the mechanical properties of actin gels, and more recently the force p- ducing motile and morphogenetic processes organized by the actin nanomachine in response to signaling, are all milestones in actin research. Discoveries that directly derive from and provide deeper insight into the fundamental properties of actin are constantly being made, making actin an ever appealing research molecule. At the same time, the explosion in new technologies and techniques in biological sciences has served to attract researchers from an expanding number of disciplines, to study actin. This book presents the latest developments of these new multiscale approaches of force and movement powered by self-assembly processes, with the hope to opening our perspectives on the many areas of actin-based motility research.
Intracellular Signalling Proteins, Volume 116, presents an overview of the current developments in mechanisms of intracellular signaling and involvement of these mechanisms in the development of a number of disorders and diseases. Opportunities for targeting the intracellular signaling cascades for benefiting patients are also discussed, along with chapters that focus on Voices from the Dead: The Complex Language of Dead Cells, Nucleobindins and Encoded Peptides: From Cell Signalling to Physiology, Estrogen Receptor Signaling Mechanisms, Intracellular Signaling of the AMP-Activating Protein Kinase, the Relationship between Mitofusin 2 and Cancer, Molecular Signaling in Bone Cells: Regulation Cell Differentiation and Survival, and more. - Describes advances in the discovery and application of therapeutics that target intracellular signaling mechanisms - Targeted to a very wide audience of specialists, researchers and students - Contains timely chapters written by well-renowned authorities in their field - Includes a number of high quality illustrations, figures and tables
The genetic, molecular, and cellular mechanisms of neural development are essential for understanding evolution and disorders of neural systems. Recent advances in genetic, molecular, and cell biological methods have generated a massive increase in new information, but there is a paucity of comprehensive and up-to-date syntheses, references, and historical perspectives on this important subject. The Comprehensive Developmental Neuroscience series is designed to fill this gap, offering the most thorough coverage of this field on the market today and addressing all aspects of how the nervous system and its components develop. Particular attention is paid to the effects of abnormal development and on new psychiatric/neurological treatments being developed based on our increased understanding of developmental mechanisms. Each volume in the series consists of review style articles that average 15-20pp and feature numerous illustrations and full references. Volume 2 offers 56 high level articles devoted mainly to Formation of Axons and Dendrites, Migration, Synaptogenesis, Developmental Sequences in the Maturation of Intrinsic and Synapse Driven Patterns. - Series offers 144 articles for 2904 full color pages addressing ways in which the nervous system and its components develop - Features leading experts in various subfields as Section Editors and article Authors - All articles peer reviewed by Section Editors to ensure accuracy, thoroughness, and scholarship - Volume 2 sections include coverage of mechanisms which regulate: the formation of axons and dendrites, cell migration, synapse formation and maintenance during development, and neural activity, from cell-intrinsic maturation to early correlated patterns of activity
This book, which was written by the current leaders in the field of Ras research, provides the readers with the most comprehensive and up-to-date view of the major oncogene Ras. This volume is valuable not only for university students in molecular biology, biochemistry or medicine, but also for senior scientists currently conducting cancer research.
Cellular Migration and Formation of Neuronal Connections, Second Edition, the latest release in the Comprehensive Developmental Neuroscience series, presents the latest information on the genetic, molecular and cellular mechanisms of neural development. This book provides a much-needed update that underscores the latest research in this rapidly evolving field, with new section editors discussing the technological advances that are enabling the pursuit of new research on brain development. This volume focuses on the formation of axons and dendrites and cellular migration. - Features leading experts in various subfields as section editors and article authors - Presents articles that have been peer reviewed to ensure accuracy, thoroughness and scholarship - Includes coverage of mechanisms which regulate the formation of axons and dendrites and cellular migration - Covers neural activity, from cell-intrinsic maturation, to early correlated patterns of activity