BIOMAT Database Logo BIOMAT Database Logo

Glial-guided granule neuron migration in vitro: a high-resolution time-lapse video microscopic study. 1987

J C Edmondson, and M E Hatten

To study neuronal migration, migrating granule neurons in microcultures prepared from early postnatal cerebellum have been analyzed with time-lapse, video-enhanced differential interference contrast microscopy. The morphology of migrating neurons resembles the elongated forms of migrating neurons described both in vivo and in vitro (Rakic, 1971; Hatten et al., 1984). The neuron closely apposes its soma along the glial fiber and extends a thickened leading process in the direction of migration. This leading tip is highly motile, with several filopodial extensions. Intracellular vesicular structures extend from the nucleus into the leading process of migrating neurons in vitro. Quantitation of the motions of migrating neurons revealed a saltatory pattern of advance along the glial fiber. Periods of cell soma movement at the rate of 56 +/- 26 micron/hr along the glial fiber are punctuated by periods during which the cell soma slows to a complete stop. The overall rate of migration is 33 +/- 20 micron/hr. The growing tip of the leading process rapidly extends and retracts, resulting in a net advance along the glial fiber. However, the periods of the extension and retraction of the leading process growing tip are not synchronized with the motions of the cell soma.

UI MeSH Term Description Entries
D008810 Mice, Inbred C57BL One of the first INBRED MOUSE STRAINS to be sequenced. This strain is commonly used as genetic background for transgenic mouse models. Refractory to many tumors, this strain is also preferred model for studying role of genetic variations in development of diseases. Mice, C57BL,Mouse, C57BL,Mouse, Inbred C57BL,C57BL Mice,C57BL Mice, Inbred,C57BL Mouse,C57BL Mouse, Inbred,Inbred C57BL Mice,Inbred C57BL Mouse
D008853 Microscopy The use of instrumentation and techniques for visualizing material and details that cannot be seen by the unaided eye. It is usually done by enlarging images, transmitted by light or electron beams, with optical or magnetic lenses that magnify the entire image field. With scanning microscopy, images are generated by collecting output from the specimen in a point-by-point fashion, on a magnified scale, as it is scanned by a narrow beam of light or electrons, a laser, a conductive probe, or a topographical probe. Compound Microscopy,Hand-Held Microscopy,Light Microscopy,Optical Microscopy,Simple Microscopy,Hand Held Microscopy,Microscopy, Compound,Microscopy, Hand-Held,Microscopy, Light,Microscopy, Optical,Microscopy, Simple
D009412 Nerve Fibers Slender processes of NEURONS, including the AXONS and their glial envelopes (MYELIN SHEATH). Nerve fibers conduct nerve impulses to and from the CENTRAL NERVOUS SYSTEM. Cerebellar Mossy Fibers,Mossy Fibers, Cerebellar,Cerebellar Mossy Fiber,Mossy Fiber, Cerebellar,Nerve Fiber
D009457 Neuroglia The non-neuronal cells of the nervous system. They not only provide physical support, but also respond to injury, regulate the ionic and chemical composition of the extracellular milieu, participate in the BLOOD-BRAIN BARRIER and BLOOD-RETINAL BARRIER, form the myelin insulation of nervous pathways, guide neuronal migration during development, and exchange metabolites with neurons. Neuroglia have high-affinity transmitter uptake systems, voltage-dependent and transmitter-gated ion channels, and can release transmitters, but their role in signaling (as in many other functions) is unclear. Bergmann Glia,Bergmann Glia Cells,Bergmann Glial Cells,Glia,Glia Cells,Satellite Glia,Satellite Glia Cells,Satellite Glial Cells,Glial Cells,Neuroglial Cells,Bergmann Glia Cell,Bergmann Glial Cell,Cell, Bergmann Glia,Cell, Bergmann Glial,Cell, Glia,Cell, Glial,Cell, Neuroglial,Cell, Satellite Glia,Cell, Satellite Glial,Glia Cell,Glia Cell, Bergmann,Glia Cell, Satellite,Glia, Bergmann,Glia, Satellite,Glial Cell,Glial Cell, Bergmann,Glial Cell, Satellite,Glias,Neuroglial Cell,Neuroglias,Satellite Glia Cell,Satellite Glial Cell,Satellite Glias
D009474 Neurons The basic cellular units of nervous tissue. Each neuron consists of a body, an axon, and dendrites. Their purpose is to receive, conduct, and transmit impulses in the NERVOUS SYSTEM. Nerve Cells,Cell, Nerve,Cells, Nerve,Nerve Cell,Neuron
D002450 Cell Communication Any of several ways in which living cells of an organism communicate with one another, whether by direct contact between cells or by means of chemical signals carried by neurotransmitter substances, hormones, and cyclic AMP. Cell Interaction,Cell-to-Cell Interaction,Cell Communications,Cell Interactions,Cell to Cell Interaction,Cell-to-Cell Interactions,Communication, Cell,Communications, Cell,Interaction, Cell,Interaction, Cell-to-Cell,Interactions, Cell,Interactions, Cell-to-Cell
D002465 Cell Movement The movement of cells from one location to another. Distinguish from CYTOKINESIS which is the process of dividing the CYTOPLASM of a cell. Cell Migration,Locomotion, Cell,Migration, Cell,Motility, Cell,Movement, Cell,Cell Locomotion,Cell Motility,Cell Movements,Movements, Cell
D006098 Granulocytes Leukocytes with abundant granules in the cytoplasm. They are divided into three groups according to the staining properties of the granules: neutrophilic, eosinophilic, and basophilic. Mature granulocytes are the NEUTROPHILS; EOSINOPHILS; and BASOPHILS. Granulocyte
D000818 Animals Unicellular or multicellular, heterotrophic organisms, that have sensation and the power of voluntary movement. Under the older five kingdom paradigm, Animalia was one of the kingdoms. Under the modern three domain model, Animalia represents one of the many groups in the domain EUKARYOTA. Animal,Metazoa,Animalia
D014741 Video Recording The storing or preserving of video signals to be played back later via a transmitter or receiver. Audiovisual Recording,Videorecording,Audiovisual Recordings,Recording, Audiovisual,Recording, Video,Recordings, Audiovisual,Recordings, Video,Video Recordings,Videorecordings

Related Publications

J C Edmondson, and M E Hatten
Automated time-lapse microscopy and high-resolution tracking of cell migration.
May 2006, Cytotechnology,
J C Edmondson, and M E Hatten
Lizard myogenesis in vitro: a time-lapse and scanning electron microscopic study.
December 1975, Developmental biology,
J C Edmondson, and M E Hatten
Neuron-glia interactions of rat hippocampal cells in vitro: glial-guided neuronal migration and neuronal regulation of glial differentiation.
April 1990, The Journal of neuroscience : the official journal of the Society for Neuroscience,
J C Edmondson, and M E Hatten
Time-lapse imaging reveals stereotypical patterns of Drosophila midline glial migration.
January 2012, Developmental biology,
J C Edmondson, and M E Hatten
Observation of human embryonic behavior in vitro by high-resolution time-lapse cinematography.
July 2016, Reproductive medicine and biology,
J C Edmondson, and M E Hatten
Video time lapse endoscopy.
June 1997, Gastrointestinal endoscopy,
J C Edmondson, and M E Hatten
Video time-lapse microscopy of human laryngeal carcinomas in vitro.
October 1986, Clinical otolaryngology and allied sciences,
J C Edmondson, and M E Hatten
Handling premature neonates: a study using time-lapse video.
January 1995, Nursing times,
J C Edmondson, and M E Hatten
Time lapse and microscopic examinations of insonated in vitro cells.
January 1990, Ultrasound in medicine & biology,
J C Edmondson, and M E Hatten
Quantitative analysis of random migration of cells using time-lapse video microscopy.
May 2012, Journal of visualized experiments : JoVE,
Copied contents to your clipboard!