Investigating glial dynamics in the developing hippocampus

Haber, Michael.

January 2008

Glial cells represent the most abundant cell population in the central nervous system (CNS), and yet, have historically been thought of as merely support cells for neurons. Over the past few decades, however, the number of identified roles that glial cells play in the CNS has expanded at an exponential rate, revealing new and exciting functions in neuron-glial communication. At synapses, astrocytes are now recognized as part of a "tripartite" complex with pre- and postsynaptic structures and can modulate synaptic transmission and plasticity. Accumulating evidence has also revealed new roles for oligodendrocytes in regulating axon diameter and integrity, and ion channel clustering. Despite our knowledge of the physiological connections between neurons and glia, relatively little is known about the morphological interplay of these cells during development and in the mature brain. The results presented in this thesis reveal the extent and time-course of rapid remodelling of astrocytes and oligodendrocytes in close proximity to dendritic spines and axons respectively. These findings provide further evidence that glia play an important role in regulating the structural plasticity of the brain. The methodology developed also provides a powerful system for the study of neuron-glial structural dynamics and may contribute to the development of novel therapeutic strategies for diseases affecting the central nervous system.

Hippocampus -- growth & development.

Hippocampus -- physiology.

Astrocytes -- physiology.

Oligodendroglia -- physiology.

Dendritic Spines -- physiology.

Axons -- physiology.

Cell Communication -- physiology.

Investigating glial dynamics in the developing hippocampus

Haber, Michael

January 2008

No description available.

Oligodendroglia -- physiology.

Hippocampus -- growth & development.

Astrocytes -- physiology.

Hippocampus -- physiology.

Axons -- physiology.

Dendritic Spines -- physiology.

Cell Communication -- physiology.