TY - JOUR
T1 - Dendritic dynamics in vivo change during neuronal maturation
AU - Wu, Gang Yi
AU - Zou, Dong Jing
AU - Rajan, Indrani
AU - Cline, Hollis
PY - 1999/6/1
Y1 - 1999/6/1
N2 - In vivo imaging of optic tectal neurons in the intact Xenopus tadpole permits direct observation of the structural dynamics that occur during dendritic arbor formation. Based on images of single Dil-labeled neurons collected at daily intervals over a period of 6 d, we divided tectal cell development into three phases according to the total length of the dendritic arbor. During phase 1, the cell differentiates from a neuroepithelial cell type and extends an axon out of the tectum. The total dendritic branch length (TDBL) is <100 μm. During phase 2, when TDBL is 100-400 μm, the dendritic arbor grows rapidly. During phase 3, when TDBL is >400 μm, the dendritic arbor grows slowly and appears stable. Neurons at different positions along the rostrocaudal developmental axis of the rectum were imaged at 2 hr intervals over 6 hr and at 24 hr intervals over several days. Images collected at 2 hr intervals were analyzed to determine rates of branch additions and retractions. Morphologically complex, phase 3 neurons show half the rate of branch additions and retractions as phase 2 neurons. Therefore, rapidly growing neurons have dynamic dendritic arbors, and slower-growing neurons are structurally stable. The change in growth rate and dendritic arbor dynamics from phase 2 to phase 3 correlates with the developmental increase in synaptic strength in neurons located along the rostrocaudal tectal axis. The data are consistent with the idea that strong synaptic inputs stabilize dendritic arbor structures and that weaker synaptic inputs are permissive for a greater degree of dynamic rearrangements and a faster growth rate in the dendritic arbor.
AB - In vivo imaging of optic tectal neurons in the intact Xenopus tadpole permits direct observation of the structural dynamics that occur during dendritic arbor formation. Based on images of single Dil-labeled neurons collected at daily intervals over a period of 6 d, we divided tectal cell development into three phases according to the total length of the dendritic arbor. During phase 1, the cell differentiates from a neuroepithelial cell type and extends an axon out of the tectum. The total dendritic branch length (TDBL) is <100 μm. During phase 2, when TDBL is 100-400 μm, the dendritic arbor grows rapidly. During phase 3, when TDBL is >400 μm, the dendritic arbor grows slowly and appears stable. Neurons at different positions along the rostrocaudal developmental axis of the rectum were imaged at 2 hr intervals over 6 hr and at 24 hr intervals over several days. Images collected at 2 hr intervals were analyzed to determine rates of branch additions and retractions. Morphologically complex, phase 3 neurons show half the rate of branch additions and retractions as phase 2 neurons. Therefore, rapidly growing neurons have dynamic dendritic arbors, and slower-growing neurons are structurally stable. The change in growth rate and dendritic arbor dynamics from phase 2 to phase 3 correlates with the developmental increase in synaptic strength in neurons located along the rostrocaudal tectal axis. The data are consistent with the idea that strong synaptic inputs stabilize dendritic arbor structures and that weaker synaptic inputs are permissive for a greater degree of dynamic rearrangements and a faster growth rate in the dendritic arbor.
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U2 - 10.1523/jneurosci.19-11-04472.1999
DO - 10.1523/jneurosci.19-11-04472.1999
M3 - Article
C2 - 10341248
AN - SCOPUS:0342749478
SN - 0270-6474
VL - 19
SP - 4472
EP - 4483
JO - Journal of Neuroscience
JF - Journal of Neuroscience
IS - 11
ER -