Robert P. Skoff scite author profile

Background Human immunodeficiency virus (HIV) associated neurocognitive disorders (HAND), including memory dysfunction, continue to be a major clinical manifestation of HIV type-1 (HIV-1) infection. Viral proteins released by infected glia are thought to be the principal triggers of inflammation and bystander neuronal injury and death, thereby driving key symptomatology of HAND. Methods We used a GFAP-driven, doxycycline (DOX)-inducible HIV-1 Tat (transactivator of transcription) transgenic mouse model and examined structure-function relationships in hippocampal pyramidal CA1 neurons using morphologic (Golgi-silver impregnations, immunohistochemistry, TUNEL detection, synaptic protein markers, electron microscopy), electrophysiological (long-term potentiation (LTP)), and behavioral (Morris water maze, fear-conditioning) approaches. Results Tat induction caused a variety of different inclusions in astrocytes characteristic of lysosomes, autophagic vacuoles, and lamellar bodies, which were typically present within distal cytoplasmic processes. In pyramidal CA1 neurons, Tat induction reduced the number of apical dendritic spines, while disrupting the distribution of synaptic proteins (synaptotagmin 2 and gephyrin) associated with inhibitory transmission, but with minimal dendritic pathology and no evidence of pyramidal neuron death. Electrophysiological assessment of excitatory postsynaptic field potential (fEPSP) at Schaffer collateral/commissural fiber-CA1 synapses showed near total suppression of LTP in mice expressing Tat. The loss in LTP coincided with disruptions in learning and memory. Conclusion Tat expression in the brain results in profound functional changes in synaptic physiology and in behavior that are accompanied by only modest structural changes and minimal pathology. Tat likely contributes to HAND by causing molecular changes that disrupt synaptic organization, with inhibitory presynaptic terminals containing synaptotagmin 2 appearing especially vulnerable.

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Proliferation and Death of Oligodendrocytes and Myelin Proteins Are Differentially Regulated in Male and Female Rodents

Cerghet

et al. 2006

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Sexual dimorphism of neurons and astrocytes has been demonstrated in different centers of the brain, but sexual dimorphism of oligodendrocytes and myelin has not been examined. We show, using immunocytochemistry and in situ hybridization, that the density of oligodendrocytes in corpus callosum, fornix, and spinal cord is 20 -40% greater in males compared with females. These differences are present in young and aged rodents and are independent of strain and species. Proteolipid protein and carbonic anhydrase-II transcripts, measured by real-time PCR, are approximately two to three times greater in males. Myelin basic protein and 2Ј,3Ј-cyclic nucleotide 3Ј-phosphodiesterase, measured by Western blots, are 20 -160% greater in males compared with females. Surprisingly, both generation of new glia and apoptosis of glia, including oligodendrocytes, are approximately two times greater in female corpus callosum. These results indicate that the lifespan of oligodendrocytes is shorter in females than in males. Castration of males produces a female phenotype characterized by fewer oligodendrocytes and increased generation of new glia. These findings indicate that exogenous androgens differentially affect the lifespan of male and female oligodendrocytes, and they can override the endogenous production of neurosteroids. The data imply that turnover of myelin is greater in females than in males. -Calpain, a protease upregulated in degeneration of myelin, is dramatically increased at both transcriptional and translational levels in females compared with males. These morphological, molecular, and biochemical data show surprisingly large differences in turnover of oligodendrocytes and myelin between sexes. We discuss the potential significance of these differences to multiple sclerosis, a sexually dimorphic disease, whose progression is altered by exogenous hormones.

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PPAR ? agonists stimulate oligodendrocyte differentiation in tissue culture

Saluja

Granneman

Skoff

2001

Glia

175

104

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Peroxisome proliferator–activated receptors (PPARs) are ligand‐activated transcription factors of the nuclear hormone receptor superfamily that have been described as master genes that switch cells from an undifferentiated phenotype to a differentiated phenotype. In the present investigation, we examined the possibility that ligands for PPARs are potent activators of oligodendrocyte (OL) differentiation and/or proliferation. Primary glial cultures and enriched OL cultures of neonatal mouse cerebra were treated with three different PPAR agonists: a PPAR γ–selective agonist, a PPAR δ–selective agonist, and a pan agonist selective for both PPAR γ and δ. Treatment with PPAR γ agonist does not have an effect on the differentiation of OLs; however, PPAR δ agonist and the pan agonist treatment accelerates the differentiation of OLs within 24 h of application in mixed glial cultures. The number of OLs with processes and huge membrane sheets increases two‐ to threefold in both groups. The increase in the size of the sheets is also mirrored by changes in the intensity and distribution of myelin basic protein (MBP) and proteolipid protein (PLP) mRNAs. As compared to controls, the PPAR δ agonist–treated groups contain more OLs that have MBP and PLP mRNA extending into distal processes. These results indicate that PPAR δ plays a significant role in the maturation of OLs and regulates the size of OL sheets. BrdU immunostaining reveals that these agonists do not significantly stimulate proliferation of OLs expressing glycolipids. The studies in enriched OL cultures reproduce the effects of the PPAR agonists seen in the mixed glial cultures, indicating that the effect of the PPAR agonists is directly on the OLs and not via astrocytes. In the enriched cultures, the total number of OLs increases significantly in the PPAR δ agonist–treated groups, but BrdU immunostaining does not show an increased proliferation of cells. These findings suggest that PPAR δ increases the survival of cells and/or prevents cell death in enriched cultures. Although PPAR δ is expressed in various cell types, its role as a factor in the transcriptional regulation of OL differentiation has not been explored. We show for the first time that a ligand that serves as an agonist for PPAR δ activates the program of OL differentiation in primary and enriched OL cultures. GLIA 33:191–204, 2001. © 2001 Wiley‐Liss, Inc.

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Robert P. Skoff

Synaptic Dysfunction in the Hippocampus Accompanies Learning and Memory Deficits in Human Immunodeficiency Virus Type-1 Tat Transgenic Mice

Proliferation and Death of Oligodendrocytes and Myelin Proteins Are Differentially Regulated in Male and Female Rodents

PPAR ? agonists stimulate oligodendrocyte differentiation in tissue culture

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