J. Ronald Doucette scite author profile

In mammals the olfactory receptor neurons are the only ones that are known to undergo continuous cell renewal in the adult animal. This means that the axon of each newly formed neuron must grow into the olfactory bulb to find its appropriate target cell. It is presumed that astrocytes ensheath the olfactory axons as they course through the nerve fiber layer of the bulb even though the cells in question differ ultrastructurally from typical astrocytes. The purpose of the present study was to examine the glial cells in the nerve fiber layer of the rat olfactory bulb in an effort to resolve this apparent discrepancy. Two morphologically distinct types of glial cell were found in the nerve fiber layer. One type, which resembled the typical astrocytes that are present in other areas of the central nervous system, contained bundles of filaments in an electron-lucent cytoplasm. These cells also formed endfeet on blood vessels and formed part of the external glial limiting membrane. They did not, however, ensheath the olfactory axons. The cytoplasm of the other type of glial cell was denser than that of typical astrocytes and contained fewer filaments, which were seldom grouped into bundles. These cells also formed part of the glial limiting membrane at the surface of the bulb and were the only ones that ensheathed the olfactory axons. It is concluded that the cell ensheathing the olfactory axons in the nerve fiber layer of the rat olfactory bulb is a morphological variant of the typical astrocyte.(ABSTRACT TRUNCATED AT 250 WORDS)

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Transcriptional control of oligodendrogenesis

Nicolay

Doucette

Nazarali

2007

Glia

120

107

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Oligodendrocytes (OGs) assemble the myelin sheath around axons in the central nervous system. Specification of cells into the OG lineage is largely the result of interplay between bone morphogenetic protein, sonic hedgehog and Notch signaling pathways, which regulate expression of transcription factors (TFs) dictating spatial and temporal aspects of oligodendrogenesis. Many of these TFs and others then direct OG development through to a mature myelinating OG. Here we describe signaling pathways and TFs that are inductive, inhibitory, and/or permissive to OG specification and maturation. We develop a basic transcriptional network and identify similarities and differences between regulation of oligodendrogenesis in the spinal cord and brain.

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Sirt2 is a novel in vivo downstream target of Nkx2.2 and enhances oligodendroglial cell differentiation

Doucette

Nazarali

2011

Journal of Molecular Cell Biology

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Although Sirt2 is primarily expressed in oligodendrocytes of the central nervous system, its role in oligodendroglial lineage differentiation is not fully understood. Our findings demonstrate that the transcription factor Nkx2.2 binds to the Sirt2 promoter via histone deacetylase 1 (HDAC-1), the binding site for Nkx2.2 maps close to the start codon of the Sirt2 gene, and Nkx2.2 negatively regulates Sirt2 expression in CG4 cells, an oligodendroglial precursor cell line. HDAC-1 knock-down not only significantly attenuates the binding capacity of Nkx2.2 to the Sirt2 promoter but also releases repression of Sirt2 expression by Nkx2.2. Nkx2.2 over-expression down-regulates Sirt2 expression and delays differentiation of CG4 cells; in contrast, up-regulation of Sirt2 does not impact Nkx2.2 expression level. Sirt2 knock-down via RNAi or inhibition of Sirt2 by sirtinol, a Sirt2 activity inhibitor, blocks CG4 cell differentiation. Over-expression of Sirt2 facilitates CG4 cell differentiation at both molecular and cellular levels, enhancing expression of myelin basic protein and facilitating the growth of cell processes. We have conclusively demonstrated that Sirt2 enhances CG4 oligodendroglial differentiation and report a novel mechanism through which Nkx2.2 represses CG4 oligodendroglial differentiation via Sirt2.

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