Previous imaging and postmortem studies have reported a reduction in brain volume and a decrease in the size and density of neurons in the dorsolateral prefrontal cortex (dlPFC, area 9) of subjects with major depressive disorder (MDD).1,2 These findings suggest that synapse number and function are decreased in dlPFC of depressed patients. However, there has been no direct evidence for synapse loss in MDD and the gene expression alterations underlying these effects have not been identified. Here we use microarray gene profiling and electron microscopic stereology to reveal decreased expression of synaptic function-related genes in dlPFC of MDD subjects and a corresponding reduction in the number of synapses. We also identify a transcriptional repressor that is increased in MDD, and that when expressed in PFC neurons is sufficient to decrease expression of synapse-related genes, cause loss of spines and dendrites, and produce depressive behavior in rodent models of depression.
Background-Imaging studies report that hippocampal volume is decreased in major depressive disorder (MDD). A cellular basis for reduced hippocampal volume in MDD has not been identified.
Recent research has changed the perception of glia from being no more than silent supportive cells of neurons to being dynamic partners participating in brain metabolism and communication between neurons. This discovery of new glial functions coincides with growing evidence of the involvement of glia in the neuropathology of mood disorders. Unanticipated reductions in the density and number of glial cells are reported in fronto-limbic brain regions in major depression and bipolar illness. Moreover, age-dependent decreases in the density of glial fibrillary acidic protein (GFAP) -immunoreactive astrocytes and levels of GFAP protein are observed in the prefrontal cortex of younger depressed subjects. Since astrocytes participate in the uptake, metabolism and recycling of glutamate, we hypothesize that an astrocytic deficit may account for the alterations in glutamate/GABA neurotransmission in depression. Reductions in the density and ultrastructure of oligodendrocytes are also detected in the prefrontal cortex and amygdala in depression. Pathological changes in oligodendrocytes may be relevant to the disruption of white matter tracts in mood disorders reported by diffusion tensor imaging. Factors such as stress, excess of glucocorticoids, altered gene expression of neurotrophic factors and glial transporters, and changes in extracellular levels of neurotransmitters released by neurons may modify glial cell number and affect the neurophysiology of depression. Therefore, we will explore the role of these events in the possible alteration of glial number and activity, and the capacity of glia as a promising new target for therapeutic medications. Finally, we will consider the temporal relationship between glial and neuronal cell pathology in depression.Glial cells were first identified as non-neuronal elements in the nineteenth century by the anatomist R. Virchow (after [1]). At that time glia were thought to be no more than silent supportive "glue" for neurons and that glia were unable to participate in information processing. In the past two decades, research has changed this perception and provided evidence for glia being important dynamic partners of neuronal cells actively participating in brain metabolism, synaptic neurotransmission and communication between neurons [2]. The discovery of new glial functions coincides with growing evidence for the involvement of glia in the neuropathology of neurological [3] and more recently, psychiatric disorders, such as major depression and manic-depressive (bipolar) illness (reviewed in [4])
TYPES OF GLIAL CELLSGlia are the most numerous cells in the human brain, outnumbering neurons by a ratio of ten to one [5] (Fig. 1). This ratio drops to one-to-one in rodents [5,6] implying that increases in glia over neurons are associated with the progressive development of higher brain functions [7]. Although anecdotal, it is interesting that in the brain of Albert Einstein, the neuron/glia ratio in the associational parieto-temporal cortical area 39 was found to be smaller
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The present paper reviews astrocyte pathology in major depressive disorder (MDD) and proposes that reductions in astrocytes and related markers are key features in the pathology of MDD. Astrocytes are the most numerous and versatile of all types of glial cells. They are crucial to the neuronal microenvironment by regulating glucose metabolism, neurotransmitter uptake (particularly for glutamate), synaptic development and maturation and the blood brain barrier. Pathology of astrocytes has been consistently noted in MDD as well as in rodent models of depressive-like behavior. This review summarizes evidence from human postmortem tissue showing alterations in the expression of protein and mRNA for astrocyte markers such as glial fibrillary acidic protein (GFAP), gap junction proteins (connexin 40 and 43), the water channel aquaporin-4 (AQP4), a calcium-binding protein S100B and glutamatergic markers including the excitatory amino acid transporters 1 and 2 (EAAT1, EAAT2) and glutamine synthetase. Moreover, preclinical studies are presented that demonstrate the involvement of GFAP and astrocytes in animal models of stress and depressive-like behavior and the influence of different classes of antidepressant medications on astrocytes. In light of the various astrocyte deficits noted in MDD, astrocytes may be novel targets for the action of antidepressant medications. Possible functional consequences of altered expression of astrocytic markers in MDD are also discussed. Finally, the unique pattern of cell pathology in MDD, characterized by prominent reductions in the density of astrocytes and in the expression of their markers without obvious neuronal loss, is contrasted with that found in other neuropsychiatric and neurodegenerative disorders.
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