Stabilization of myelin mRNAs as measured in a brain slice system

QKI binds MAP1B mRNA and enhances MAP1B expression during oligodendrocyte development

Microtubule-associated protein 1B (MAP1B) is essential for neural development. Besides the abundant expression in neurons, MAP1B recently was found in myelinating oligodendroglia. Moreover, MAP1B deficiency causes delayed myelin development, suggesting the functional importance of MAP1B in oligodendroglia. However, molecular mechanisms that control MAP1B expression in oligodendroglia remain elusive. We report here that MAP1B mRNA is markedly up-regulated in the oligodendroglia cell line CG4 upon induced differentiation, leading to elevated MAP1B protein production. A coordinated regulation of homeoprotein transcription factors was observed during CG4 cell differentiation, which recapitulates the regulation in neurons that promotes MAP1B transcription. Hence, transcriptional regulation of MAP1B appears to be a common mechanism in both neurons and oligodendroglia. In addition, we found posttranscriptional regulation of MAP1B mRNA by the selective RNA-binding protein QKI in oligodendroglia. The 3'UTR of MAP1B mRNA interacts with QKI, and oligodendroglia-specific QKI-deficiency in the quakingviable mutant mice resulted in reduced MAP1B mRNA expression. Moreover, RNAi-mediated QKI-knockdown caused destabilization of the MAP1B mRNA in CG4 cells. Furthermore, forced expression of exogenous QKI was sufficient for promoting MAP1B expression. Because QKI is absent in neurons, QKI-dependent stabilization of MAP1B mRNA provides a novel mechanism for advancing MAP1B expression specifically in oligodendroglia during brain development.

Phosphodiesterase-I alpha/autotaxin controls cytoskeletal organization and FAK phosphorylation during myelination

Myelination within the central nervous system (CNS) involves substantial morphogenesis of oligodendrocytes requiring plastic changes in oligodendrocyte-extracellular matrix (ECM) interactions, that is, adhesion. Our previous studies indicated that a regulator of such adhesive plasticity is oligodendrocyte-released phosphodiesterase-I alpha/autotaxin (PD-I alpha/ATX). We report here, that PD-I alpha/ATX's adhesion antagonism is mediated by a protein fragment different from the one that stimulates tumor cell motility. Furthermore, PD-I alpha/ATX's adhesion-antagonizing fragment causes a reorganized distribution of the focal adhesion components vinculin and paxillin and an integrin-dependent reduction in focal adhesion kinase (FAK) phosphorylation at tyrosine residue 925 (pFAK-925). In vivo, a similar reduction in pFAK-925 occurs at the onset of myelination when PD-I alpha/ATX expression is significantly upregulated. Most importantly, it can also be induced by the application of exogenous PD-I alpha/ATX. Our data, therefore, suggest that PD-I alpha/ATX participates in the regulation of myelination via a novel signaling pathway leading to changes in integrin-dependent focal adhesion assembly and consequently oligodendrocyte-ECM interactions.

Variability in the benzodiazepine response of serotonin 5-HT1A receptor null mice displaying anxiety-like phenotype: evidence for genetic modifiers in the 5-HT-mediated regulation of GABA(A) receptors

Benzodiazepines (BZs) acting as modulators of GABA(A) receptors (GABA(A)Rs) are an important group of drugs for the treatment of anxiety disorders. However, a large inter-individual variation in BZ sensitivity occurs in the human population with some anxiety disorder patients exhibiting diminished sensitivity to BZ and reduced density of GABA(A)Rs. The mechanism underlying BZ treatment resistance is not known, and it is not possible to predict whether an anxiety patient will respond to BZ. 5-hydroxytryptamine1A receptor (5-HT1AR) null mice (R-/-) on the Swiss-Webster (SW) background reproduce several features of BZ-resistant anxiety; they exhibit anxiety-related behaviors, do not respond to BZ, have reduced BZ binding, and have decreased expression of the major GABA(A)R subunits alpha1 and alpha2. Here, we show that R-/- mice on the C57Bl6 (B6) background also have anxiety phenotype, but they respond to BZ and have normal GABA(A)R subunit expression. This indicates that the 5-HT1AR-mediated regulation of GABA(A)R alpha subunit expression is subject to genetic modification. Hybrid SW/B6-R-/- mice also exhibit BZ-resistant anxiety, suggesting that SW mice carry a genetic modifier, which mediates the effect of the 5-HT1AR on the expression of GABA(A)Ralpha subunits. In addition, we show that this genetic interaction in SW mice operates early in postnatal life to influence the expression of GABA(A)R alpha subunits at the transcriptional level. These data indicate that BZ-resistant anxiety results from a developmental arrest of GABA(A)R expression in SW-R-/- mice, and a similar mechanism may be responsible for the BZ insensitivity of some anxiety patients.

Staufen recruitment into stress granules does not affect early mRNA transport in oligodendrocytes

Staufen is a conserved double-stranded RNA-binding protein required for mRNA localization in Drosophila oocytes and embryos. The mammalian homologues Staufen 1 and Staufen 2 have been implicated in dendritic RNA targeting in neurons. Here we show that in rodent oligodendrocytes, these two proteins are present in two independent sets of RNA granules located at the distal myelinating processes. A third kind of RNA granules lacks Staufen and contains major myelin mRNAs. Myelin Staufen granules associate with microfilaments and microtubules, and their subcellular distribution is affected by polysome-disrupting drugs. Under oxidative stress, both Staufen 1 and Staufen 2 are recruited into stress granules (SGs), which are stress-induced organelles containing transiently silenced messengers. Staufen SGs contain the poly(A)-binding protein (PABP), the RNA-binding proteins HuR and TIAR, and small but not large ribosomal subunits. Staufen recruitment into perinuclear SGs is paralleled by a similar change in the overall localization of polyadenylated RNA. Under the same conditions, the distribution of recently transcribed and exported mRNAs is not affected. Our results indicate that Staufen 1 and Staufen 2 are novel and ubiquitous SG components and suggest that Staufen RNPs are involved in repositioning of most polysomal mRNAs, but not of recently synthesized transcripts, during the stress response.

Overexpression of the 3'-untranslated region of myelin proteolipid protein mRNA leads to reduced expression of endogenous proteolipid mRNA

The current studies focus on what mechanisms regulate the concentration of PLP mRNA in cells. The PLP mRNA is very stable and these studies suggest that its stability is regulated by a trans-acting factor specific to oligodendrocytes. In order to test whether the 3'untranslated region (3'UTR) of the PLP mRNA might regulate PLP RNA stability, C6 cells were transfected with cDNAs that expressed either luciferase or luciferase fused to the 3'UTR of PLP. Although transgene expression was low, in cells transfected with the PLP 3'UTR, there was a significant decrease in the endogenous PLP mRNA. These cells showed a distinct change in morphology and in adhesion properties. Thus, there may be a role for plp gene products in cell adhesion, which was downregulated in these cells, or an unknown function may be encoded by the PLP 3'UTR. Transgenic mice that overexpress enhanced green fluorescent protein fused to the PLP 3'UTR under control of PLP regulatory sequences were tested for the expression of the endogenous PLP mRNA. Three of four lines of transgenic mice had decreased endogenous PLP mRNA, relative to their non-transgenic littermates; the EGFP-PLP 3'UTR mouse line that expressed the highest level of transgene mRNA had a 54% reduction in PLP mRNA. We hypothesize that the PLP mRNA is regulated by elements in the 3'UTR and stabilizing proteins specific to oligodendrocytes, and that in cells that overexpress the PLP 3'UTR, these stabilizing proteins may be insufficient to maintain the normal level of the endogenous PLP mRNA.

Molecular mechanisms involved in the actions of apotransferrin upon the central nervous system: Role of the cytoskeleton and of second messengers

Apotransferrin (aTf), intracranially administered into newborn rats, produces increased myelination with marked increases in the levels of myelin basic protein (MBP), phospholipids and galactolipids, and mRNAs of MBP and 2', 3' cyclic nucleotide 3'-phosphohydrolase (CNPase). Cytoskeletal proteins such as tubulin, actin, and microtubule-associated proteins are also increased after aTf injection. In contrast, almost no changes are observed in myelin proteolipid protein (PLP) or in its mRNA or cholesterol. In the present study, we used brain-tissue slices and cell cultures highly enriched for oligodendroglia to investigate signaling pathways involved in the action of aTf, and to find out whether cytoskeletal integrity and dynamics were essential for its action upon the neural expression of certain genes. Treatment of brain-tissue slices with aTf produced a marked increase in the expression of MBP, CNPase, and tubulin mRNAs. Colchicine, cytochalasin, and taxol severely reduced the effect of aTf. Addition to cultures of an antibody against transferrin receptor (TfR), protein kinase inhibitors, or a cyclic AMP (cAMP) analogue showed that a functionally intact TfR was necessary, and that tyrosine kinase, protein kinase C and A, as well as calcium-calmodulin-dependent kinase (Ca-CaMK) activities appeared to mediate aTf actions upon the expression of the above mentioned genes. Changes in the levels of phosphoinositides and cAMP induced by aTf in oligodendroglial cell (OLGc) cultures correlated with these results and coincide with an activation of the cyclic response element binding protein (CREB) and of mitogen activated protein kinases. The increased expression of certain myelin genes produced by aTf appear to be mediated by interaction of this glycoprotein with its receptor, by the cytoskeleton of the OLGc, and by a complex activation of protein kinases which lead to CREB phosphorylation.

Differential DM20 mRNA expression distinguishes two distinct patterns of spontaneous recovery from murine autoimmune encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is an animal model for multiple sclerosis (MS) mediated by T cells responding to CNS myelin proteins. Immunization of SWXJ mice with the immunodominant p139-151 peptide of myelin proteolipid protein (PLP) results in a relapsing-remitting pattern of EAE characterized by incomplete remyelination during clinical recovery. In the present study we observed two distinct clinical patterns of spontaneous remission during recovery from EAE, viz., sustained remission involving continuous neurologic improvement and aborted remission involving modest transient clinical improvement. We hypothesized that the ability to recover from autoimmune demyelination was directly linked to remyelination events that recapitulated developmental processes. Quantitative immunocytochemistry of CNS tissue showed decreased demyelination in mice undergoing sustained remission compared to mice undergoing aborted remission. Quantitative RT-PCR analysis showed elevated expression of DM20, the developmental isoform of PLP, in CNS tissue from mice undergoing sustained remission compared to mice undergoing aborted recovery. Moreover, DM20 expression was similarly elevated in CNS tissue from mice undergoing sustained recovery from EAE relapse. Our data indicate that expression of the developmental DM20 isoform of PLP is intimately associated with decreased demyelination and sustained clinical recovery from EAE. Thus, DM20 gene expression may provide an appropriate molecular target for promoting CNS remyelination and may serve as a useful marker for predicting clinical outcome and assessing the effectiveness of strategies aimed at promoting CNS tissue repair during autoimmune demyelinating disease.