Myelin Gene Expression: Implications for Alcohol Abuse and Dependence

Farris, Sean

31 March 2012

Acute behavioral responses to ethanol have predictive value for determining an individual's risk of long-term drinking behavior. Although the neurobiology of alcohol abuse is complex, prior studies from our laboratory demonstrated differential myelin-associated gene expression (MAGE) in medial prefrontal cortex (PFC) as one potential mechanism influencing acute ethanol behaviors between C57BL/6J (B6) and DBA/2J (D2) mice. Our laboratory and others have also shown MAGE is reduced in PFC of alcoholics. Herein, I have extended these findings through expression profiling of PFC into chronic models of ethanol self-administration from non-human primates and mice. Together, these results suggest that regulation of MAGE may be relevant to behavioral phenotypes witnessed in alcoholism. The pathogenesis of alcoholism progresses through multiple stages of drug exposure and withdrawal, however, genetic predisposition is also a major contributing factor for this disease. Therefore, I tested the hypothesis that not only does ethanol have direct effects on MAGE, but also variation in basal MAGE within the PFC is a molecular endophenotype underlying ethanol behavioral sensitivity. Bioinformatics of basal MAGE across the BXD recombinant inbred panel (n=29), derived from B6 and D2 mice, revealed a densely correlated myelin gene network associated with several ethanol behavioral phenotypes. Literature association tools identified Fyn kinase as potential regulator of MAGE. Fyn knockout mice are known to be more sensitive to the sedative-hypnotic properties of ethanol in the loss of righting reflex (LORR) paradigm. Microarray analysis of Fyn knockout mice revealed a significant decrease in MAGE, suggesting MAGE may be an underlying factor for LORR. In support of this premise, microarray analysis of genetic variance in LORR across Inbred Long Sleep and Inbred Short Sleep mice, as well as congenics for the Lore5 quantitative trait locus, also demonstrated an inverse relationship between MAGE and duration of LORR. The hypothesis was further investigated using cuprizone to model demyelination in B6 mice and test them in a battery of acute ethanol behaviors. Cuprizone-treated mice had a significantly greater duration in LORR (p < 0.01), demonstrating that myelin is an important contributor to the genetic variance in LORR. Thus, through genetic, genomic, and pharmacological tools I have ‘molecularly triangulated’ a myelin gene network as a contributing factor influencing acute ethanol behavioral sensitivity. The ability of myelin to alter acute ethanol sensitivity may warrant a prospective study of myelin in humans as a predictive molecular phenotype for an individual’s risk of developing alcohol dependence. Additionally, further genomic dissection of MAGE architecture and associated networks may aid in developing novel pharmacotherapies for an alcohol use disorder. Supported by NIAAA grants F31 AA018615 to SPF

alcoholism

myelin

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences

Opioid Addiction Treatments During Pregnancy and Their Effects on Axonal Growth and Myelination in the Developing Central Nervous System

Magar, Manisha

27 July 2011

Treatment with buprenorphine represents a promising alternative for pregnant opioid addicts but there is a need to understand potential effects on nervous system development. We previously showed effects of perinatal exposure to buprenorphine on axonal caliber and myelination in 26-day-old rat corpus callosum. These changes, detected at the end of rapid brain myelination and accompanied by earlier oligodendrocyte maturation, suggested interference with mechanisms coordinating axonal growth and myelination. To better understand buprenorphine actions and to establish whether these effects extend to the spinal cord, we analyzed the corpus callosum and corticospinal tract at 16 days of age, just before the peak of myelination. Our results point to an important role of the opioid system in regulating early axo-glial interactions coordinating axonal growth and myelination. Moreover, in addition to reinforcing previous findings in the brain, we showed for the first time that these effects are also exerted in the spinal cord.

buprenorphine

myelin

axon caliber

development

Life Sciences

Physiology

The Effects of Reactive Oxygen Species on Internodal Myelin Structure, and Role of Plasmalogen Phospholipids as Endogenous Antioxidants

Luoma, Adrienne M.

January 2009

Thesis advisor: Daniel A. Kirschner / Reactive oxygen species (ROS) are implicated in a range of degenerative conditions, including aging, neurodegenerative diseases, and neurological disorders such as multiple sclerosis. Myelin is a lipid-rich multilamellar assembly that facilitates rapid nerve conduction in higher animals, and may be intrinsically vulnerable to oxidative damage given the high energetic demands and low antioxidant capacity of myelinating cells. To determine whether ROS can cause structural damage to internodal myelin, whole mouse sciatic and optic nerves were incubated ex vivo with a previously-characterized copper (Cu)/hydrogen peroxide (HP)/o-phenanthroline (OP)-based hydroxyl radical-generating system followed by quantitative determination of myelin packing by x-ray diffraction. Exposure to Cu/OP/HP-mediated ROS caused irreversible myelin decompaction in both sciatic and optic nerves. The addition of the hydroxyl radical scavenger, sodium formate, to the ROS-producing incubation solution significantly prevented sciatic nerve myelin decompaction, implicating hydroxyl radical species in causing the damage. Furthermore, Cu/OP/HP-mediated decompaction could be prevented by the addition of EDTA, which can compete with OP for Cu binding and sequester the metal within the bulk solution. These findings suggest that Cu/OP/HP-dependent myelin decompaction is caused by OP-mediated membrane-targeted hydroxyl radical production. Myelin membranes are particularly enriched in plasmalogen phospholipids, which have been linked to antioxidant activity; this enrichment may constitute an endogenous ROS-defense mechanism that protects ROS-vulnerable myelin tissue from damage. Intriguingly, it was found that sciatic nerve myelin from plasmalogen deficient (Pex7 KO) mice was significantly more susceptible to ROS-mediated decompaction than that from WT mice, supporting the role of plasmalogens as endogenous antioxidants. / Thesis (MS) — Boston College, 2009. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

Myelin

plasmalogens

Reactive oxygen species

X-ray diffraction

A Biochemical Analysis of the Factors Influencing P0 Oligomerization in Xenopus laevis Peripheral Nerve Myelin

Priest, Christina Marie

January 2004

Thesis advisor: Daniel A. Kirschner / Protein zero (P0), the major structural protein of peripheral nerve myelin, is a ~30 kDa integral membrane glycoprotein consisting of an extracellular domain, a transmembrane domain, and a palmitoylated cytoplasmic domain. In native membranes of Xenopus laevis it exists primarily as a dimer. To determine the effects of glycosylation, acylation, and hydrophobic interactions on protein dimerization, I used SDS polyacrylamide gel electrophoresis (SDS-PAGE), Western blotting, and high-performance thin layer chromatography (HPTLC) to analyze the effects of deglycosylation, deacylation, and various detergent treatments on myelin isolated from Xenopus laevis sciatic nerve. These treatments showed no effect on P0 oligomerization, suggesting that glycosylation, acylation, and hydrophobic interactions disrupted by these detergents do not underlie P0 dimerization. The data points to the likelihood that covalent linkages contribute to P0 oligomerizaztion in Xenopus. / Thesis (BS) — Boston College, 2004. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Biology. / Discipline: College Honors Program.

Biology, Neuroscience

myelin

P0

biology

protein

nerve

xenopus

Oligodendroglial anillin facilitates septin assembly to prevent myelin outfoldings

Erwig, Michelle Scarlett

28 January 2019

No description available.

570

Biologie (PPN619462639)

Myelin and glial pathology in aging and congnitive decline: evidence for faulty myelin clearance in the rhesus monkey

Townsend-Shobin, Eli

12 June 2018

Aging is associated with a loss of cognitive function related to learning, memory, and executive function with varying severity. Although there is no age-related loss of neurons in healthy aging, myelin damage accumulates and is associated with cognitive decline. The brain’s resident macrophages, microglia, are responsible for clearing damaged myelin and promoting subsequent oligodendrocyte-mediated remyelination. To test the hypothesis that age-related dysfunction of microglial phagocytosis and oligodendrocyte remyelination capacity contributes to myelin pathology and cognitive impairment. To test this, rhesus monkeys from across the lifespan (7-30 years of age) were tested in three specific aims. 1) To characterize gene expression of myelin basic protein (MBP) in the brain and clearance of MBP to the cerebrospinal fluid (CSF) in relation to age-related myelin pathology. The density of myelinated axons visualized using label-free spectral confocal reflectance imaging did not correlate with age, but was significantly lower in aged animals with cognitive impairment. Next, MBP gene expression was measured using qPCR in the dorsal prefrontal cortex along with quantification of MBP protein levels in the CSF using ELISA. Age-dependent increases of MBP gene expression in the brain and MBP protein levels in the CSF were observed. Interestingly, MBP levels in the CSF were lower in animals with cognitive impairment. 2) To test the hypothesis that microglia would become increasingly primed for phagocytosis with age-related myelin pathology. The number of microglia immunostained with galectin-3, a marker for phagocytic activation, was quantified in the frontal white matter and increases in both aging and cognitive decline were detected. 3) To evaluate the hypothesis that lipofuscin, an age-related accumulation indicative of autophagic dysfunction, would accumulate and impair glial cells of the white matter in aged animals. Lipofuscin accumulation was increased with age in the frontal white matter and the size of lipofuscin clusters was associated with cognitive impairment. Lipofuscin was found primarily in microglia and oligodendrocytes, but not in astrocytes. These data suggest that lipofuscin burden in microglia and oligodendrocytes inhibits their homeostatic functions resulting in improper myelin clearance and turnover, leading to a devastating feed-forward cycle of myelin damage that contributes to age-related cognitive impairment.

Aging

Immunology

Macrophage

Microglia

Myelin

Oligodendrocytes

White matter

Myelin pruning by microglia during development

Weikert, Ulrich

24 April 2019

No description available.

570

myelin

pruning

microglia

development

oligodendrocytes

Biologie (PPN619462639)

Nuclear Factor-κB Activation in Schwann Cells Regulates Regeneration and Re-Myelination

Morton, Paul D

22 November 2011

Schwann cells (SCs) are crucial for peripheral nerve development and regeneration; however, the intrinsic regulatory mechanisms governing post-injury responses are poorly understood. Activation and deacetylation of nuclear factor-κB (NF- κB) in SCs have been implicated as prerequisites for peripheral nerve myelination. Using GFAP-IκBα-dn mice, in which NF- κB transcriptional activation is inhibited in SCs, we found no discernable differences in the quantity or structure of myelinated axons in adult facial nerves. Following crush injury, axonal regeneration was impaired at 31 days and greatly improved at 65 days in GFAP-IκBα-dn mutants. Compact re-myelination and sensory fiber organization were significantly compromised at 31 days and restored by 65 days. Together, these data indicate that NF- κB activation in SCs is dispensable for peripheral nerve myelination in adults, but required for early re-myelination and axonal regeneration. SC myelination during development and following injury in adult mice may hinge on different transcriptional cascades; these findings may offer new therapeutic avenues for PNS and CNS regeneration.

myelin

peripheral

nerve

injury

schwann

nf-kb

regeneration

gfap

Schwann cells and mesenchymal stem cells as promoter of peripheral nerve regeneration

Mantovani, Maria Cristina

January 2011

The transplantation of primary Schwann cells (SC) has been shown to improve nerve regeneration. However, to monitor the survival of transplanted cells within the host, a stable labelling method is required. The in vitro characteristics of green fluorescent protein labelled SC (GFP SC) and their effects in an in vivo peripheral nerve injury model were investigated.   The GFP-SC were readily visualised ex vivo and stimulated significantly better axonal regeneration compared to controls. Clinical use of autologous SC for the treatment of nerve injuries is of limited use due to difficulty in obtaining clinically useful numbers. However, bone marrow mesenchymal stem cells (MSC) can trans-differentiate into SC like cells (dMSC). The in vitro and in vivo differentiation of MSC was explored, and the study extended to include the easily-accessible adipose stem cells (ASC).  In vitro, glial growth factor stimulated MSC express S100, a SC marker, and its expression is maintained following in vivo transplantation.  Similarly, untreated MSC transplanted in vivo also expressed S100, which indicates glial differentiation in response to local cytokines and growth factors. Using an in vitro model, comprising dMSC or dASC co-cultured with adult dorsal root ganglia (DRG) neurons, the capacity of the dMSC and SC like differentiated ASC (dASC) to promote axon myelination was verified: both cell types expressed transcripts for protein zero, peripheral myelin protein-22 and myelin basic protein. The potential of stem cells in nerve repair may be limited by innate cellular senescence or donor age affecting cell functionality thus it was essential to determine the effects of donor age on morphology and functionality of stem cells.  The proliferation rates, expression of senescence markers (p38 and p53) and the stimulation of neurite outgrowth from DRG neurons by stem cells isolated from neonatal, young or old rats were very similar. However, the distribution and ultrastructure of mitochondria in dMSC and dASC from young and old rats were quite different, and seem to indicate physiological senescence of the aged cells.  Given the wide-ranging influence of Notch signalling in cell differentiation, including the neural crest to a glial cell type switch, and self-renewal in mammals, its role in the differentiation of stem cells to SC was investigated. The mRNA for notch-1 and -2 receptors were expressed in the dASC, blockage of notch signaling did not affect the neurotrophic and myelination potential of dASC.  In conclusion, these findings show that GFP labelling has no deleterious effect on SC survival and function. MSC and ASC differentiated into glial-type cells acquire SC morphology, and express characteristic SC markers, and the differentiation process was independent of the Notch signaling pathway. Also, following transplantation into a nerve gap injury dMSC improve regeneration. This study established that following co-culture with DRG neurons, dMSC and dASC were able to express peripheral myelin proteins.  Also, the functional bioactivity of these cells is independent of the donor animal age. Finally, although the glial lineage differentiated aged cells characterized in this study expressed markers typical of senescence they retained the potential to support axon regeneration.

peripheral nerve regeneration

Schwann cell

adult stem cell

myelin

senescence

Generation and Characterization of Neural Stem Cells Derived from Embryonic Stem Cells using the Default Mechanism

Rowland, James W.

20 December 2011

In embryonic stem cells (ESCs) neural differentiation is elicited in the absence of extrinsic signaling in minimal conditions. This ‘default mechanism’ in ESCs produces neural stem cells termed primitive neural stem cells, which can subsequently yield FGF2-dependent definitive neural stem cells (dNSCs). We hypothesized that dNSCs have properties similar to neural stem/progenitor cells derived from the adult brain (aNPCs). The neural differentiation profile of the cell-types was characterized in vitro and in vivo following transplantation into the Shiverer mouse. The dNSCs produced a differentiation profile similar to that of aNPCs and both cell-types produced oligodendrocytes. This is the first demonstration of the in vivo differentiation of neural stem cells, derived from ESCs through the default mechanism, into the oligodendrocyte lineage. We conclude that dNSCs are a similar cell population to aNPCs. The default mechanism is a promising approach to generate neural stem cells and their progeny from pluripotent cell populations.

Neural Stem Cells

Oligodendrocytes

Myelin

Differentiation

0317

0379