Mirjana Tosic

Impaired glutathione synthesis in schizophrenia: Convergent genetic and functional evidence

Schizophrenia is a complex multifactorial brain disorder with a genetic component. Convergent evidence has implicated oxidative stress and glutathione (GSH) deficits in the pathogenesis of this disease. The aim of the present study was to test whether schizophrenia is associated with a deficit of GSH synthesis. Cultured skin fibroblasts from schizophrenia patients and control subjects were challenged with oxidative stress, and parameters of the rate-limiting enzyme for the GSH synthesis, the glutamate cysteine ligase (GCL), were measured. Stressed cells of patients had a 26% (P = 0.002) decreased GCL activity as compared with controls. This reduction correlated with a 29% (P < 0.001) decreased protein expression of the catalytic GCL subunit (GCLC). Genetic analysis of a trinucleotide repeat (TNR) polymorphism in the GCLC gene showed a significant association with schizophrenia in two independent case-control studies. The most common TNR genotype 7/7 was more frequent in controls [odds ratio (OR) = 0.6, P = 0.003], whereas the rarest TNR genotype 8/8 was three times more frequent in patients (OR = 3.0, P = 0.007). Moreover, subjects with disease-associated genotypes had lower GCLC protein expression (P = 0.017), GCL activity (P = 0.037), and GSH contents (P = 0.004) than subjects with genotypes that were more frequent in controls. Taken together, the study provides genetic and functional evidence that an impaired capacity to synthesize GSH under conditions of oxidative stress is a vulnerability factor for schizophrenia.

Triiodothyronine Has Diverse and Multiple Stimulating Effects on Expression of the Major Myelin Protein Genes

Abstract: If the importance of triiodothyronine (T3) on brain development including myelinogenesis has long been recognized, its mechanism of action at the gene level is still not fully elucidated. We studied the effect of T3 on the expression of myelin protein genes in aggregating brain cell cultures. T3 increases the concentrations of mRNA transcribed from the following four myelin protein genes: myelin basic protein (Mbp), myelin‐associated glycoprotein (Mag), proteolipid protein (Plp), and 2′,3′‐cyclic nucleotide 3′‐phosphodiesterase (Cnp). T3 is not only a triggering signal for oligodendrocyte differentiation, but it has continuous stimulatory effects on myelin gene expression. Transcription in isolated nuclei experiments shows that T3 increases Mag and Cnp transcription rates. After inhibiting transcription with actinomycin D, we measured the half‐lives of specific mRNAs. Our results show that T3 increases the stability of mRNA for myelin basic protein, and probably proteolipid protein. In vitro translation followed by myelin basic protein‐specific immunoprecipitation showed a direct stimulatory effect of T3 on myelin basic protein mRNA translation. Moreover, this stimulation was higher when the mRNA was already stabilized in culture, indicating that stabilization is achieved through mRNA structural modifications. These results demonstrate the diverse and multiple mechanisms of T3 stimulation of myelin protein genes.

Myelin gene expression during demyelination and remyelination in aggregating brain cell cultures.

Remyelination can be studied in aggregating rat brain cell cultures after limited demyelination. Demyelination was induced using a monoclonal antibody against myelin/oligodendrocyte glycoprotein (MOG mAb), in the presence of complement. De- and remyelination were assessed by measuring myelin basic protein (MBP). Two days after removing the MOG mAb, MBP levels reached 50% of controls and after 7 days 93%. During this period, cell proliferation determined by [14C]thymidine incorporation was similar in remyelinating and control cultures. Hormones and growth factors were tested for possible stimulatory effect on remyelinating cultures. Bovine growth hormone (bGH), triiodothyronine (T3), basic fibroblast growth factor (bFGF) and platelet-derived growth factor (PDGF) did not improve remyelination. Only epidermal growth factor (EGF) increased the level of remyelination. PDGF increased the rate of cell proliferation in both control and remyelinating cultures. A significant proportion of oligodendrocytes entered the cell division cycle and were not available for remyelination. The results obtained with PDGF and FGF (inhibition) support the idea that a pool of progenitor cells was still present and able to proliferate and differentiate into myelinating oligodendrocytes. The levels of myelin protein mRNAs were investigated during de- and remyelination. During demyelination, myelin protein mRNA levels decreased to approximately 50% of control cultures and returned to normal during remyelination. These preliminary results indicate that normal levels of gene transcription are sufficient to meet the increased need for newly synthesized myelin proteins during remyelination.

Paralytic tremor (pt) : a new allele of the proteolipid protein gene in rabbits

Abstract: Paralytic tremor (pt) is a sex‐linked mutation in rabbit that affects myelination of the CNS. Myelin in the pt brains represents ∼30% of the normal levels. Previously we showed that the pt mutation affects primarily proteolipid protein (Plp) gene expression. In the present study we investigated the relative effect of the pt mutation on two distinctive Plp gene products, PLP‐ and DM‐20‐specific messenger RNAs. Our results showed that both PLP and DM‐20 are affected and that the ratio DM‐20/PLP was higher in pt rabbits than in age‐matched controls. We sequenced normal rabbit PLP cDNA and characterized pt mutation at the DNA level. Rabbit PLP sequence, deduced from cDNA, differs from the human protein only at Thr198. Sequence analysis of the mutant cDNA revealed a transversion T → A in exon 2 of the Plp gene. This point mutation, which is placed at the end of the first potential transmembrane domain, results in a substitution of His36 by a glutamine. This transversion abolishes a restriction site that enabled us to screen a large number of animals and observe a perfect correlation between the pt allele and the abnormal phenotype.

Paralytic tremor (pt) rabbit: a sex-linked mutation affecting proteolipid protein-gene expression

Paralytic tremor (pt) is a neurological sex-linked recessive mutation in rabbits which is characterized by a coarse body tremor and limb paresis. Morphological studies showed that this mutation affects CNS myelination. Although the number of oligodendrocytes is not reduced, myelination is slower, irregular and defective. We have made a biochemical and molecular analysis of 4-wk-old mutant and normal rabbits. The amount of myelin in the mutant represents only approximately 25% of the normal level. Radioimmunoassay for myelin basic protein showed a reduction to approximately 40% in pt whole-brain homogenate but the difference was not significant in purified myelin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of brain homogenates followed by immunoblotting showed that all major myelin proteins are affected by the pt mutation, although to different degrees. While most of the myelin proteins are reduced to approximately 60-80% of the normal level, an important reduction to approximately 30%, was measured for the proteolipid protein (PLP). In purified myelin, the difference in PLP concentration was significant while the other specific proteins were less affected. A similar reduction in myelin-protein gene expression was detected at the mRNA level. Sex-linked transmission, low concentrations of PLP and its specific mRNA in the CNS indicate that the pt mutation primarily affects the expression of the Plp gene.

Proteolipid/DM-20 proteins bearing the paralytic tremor mutation in peripheral nerves and transfected Cos-7 cells

Paralytic tremor (Plp-pt) is a missense mutation of the myelin proteolipid gene (Plp) in rabbits. The myelin yield in the Plp-pt brain is reduced and the protein and lipid composition of central nervous system (CNS) myelin is abnormal. We studied the intracellular transport of the normal and Plp-pt mutant PLP and DM-20 in transiently transfected Cos-7 cells. While the mutant PLP accumulates in the rough endoplasmic reticulum and does not reach the plasma membrane, the spliced isoform of PLP, mutant DM-20, is normally transported to the cell surface and integrated into the membrane. Analysis of rabbit sciatic nerves revealed that concentration of peripheral nervous system (PNS) myelin proteins is normal in Plp-pt myelin. In the PNS like in the CNS, the level of Plp gene products is subnormal. But this does not affect myelination, in the PNS where PLP, present in low concentration, is not a structural component of compact myelin. The normal level of Plp gene expression in Schwann cells is low and these results suggest that, in the Plp-pt PNS, Schwann cell function is not affected by the deficiency in PLP and/or the impairment of intracellular PLP transport.

The duplicated myelin basic protein gene in mld mutant mice does not impair transcription.

Myelin basic protein (MBP) gene organization and expression were analyzed in wild type and myelin deficient (mld) mutant mice. Southern analysis demonstrated MBP gene duplication in mld mice. In addition, we present evidence that one MBP gene in mld mice is normal for at least 14 kilobases (kb) upstream from exon I, whereas the second gene is normal for at least 3.5 kb but not more than 7 kb upstream from exon I. Run-on experiments showed that the rate of MBP gene transcription in mld mice is similar to that seen in normal mice. Detailed analysis of the transcriptional activity of various regions of the gene led us to conclude that all portions of the MBP gene are transcribed in mld mice. Consequently, we propose that the low levels of MBP mRNA observed in these mice (2-5% of the wild-type level) are not due to deficient transcriptional activity.

Analysis of cis‐Acting Sequences from the Myelin Oligodendrocyte Glycoprotein Promoter

Abstract: Myelin oligodendrocyte glycoprotein (MOG), a minor component of the myelin sheath, appears to be implicated in the late events of CNS myelinogenesis. To investigate the transcriptional regulation of MOG, 657 bp of the 5′‐flanking sequence of the murine MOG gene, previously shown to induce the highest level of transcription in an oligodendroglial cell line, was analyzed by in vitro footprinting and electrophoretic mobility shift assays. This region contains at least three sites that contact nuclear proteins in vitro. Each region described in this study binds specific nuclear proteins and enhances transcription in the OLN‐93 glial cell line. More specifically, a region located at position ‐93 to ‐73 bp, which displays 100% homology in mouse and human MOG promoters, presents distinct binding affinities between brain and liver nuclear proteins. The results obtained by supershift assay and site‐directed mutagenesis reveal that this region contains an essential positive element (TGACGTGG) related to the cyclic AMP‐responsive element CREB‐1 and are additional evidence for the involvement of the cyclic AMP transduction pathway in oligodendrocyte development.

Implication of the extracellular disulfide bond on myelin protein zero expression.

Mutations in myelin protein zero (P0) are responsible for several peripheral neuropathies. We studied transport and membrane integration of the truncated P0 mutants using transfected oligodendroglial cell line (Oln93). Starting with rat cDNA, we produced two P0 deletions. The first, called P0-Tyr contains a 66 amino acid deletion in the extracellular domain and a tyrosine at the new position 32. In the second, called P0-Cys, the tyrosine 32 is replaced by a cysteine. This replacement restores a disulfide bond in the extracellular domain. Our results show that P0 proteins, truncated or not, were expressed in the plasma membrane of the transfected cells. Transcription rates of both mutants were normal. However, P0-Tyr was detected in only 3-5% of the cells compared to the P0-Cys and the wild type. Thus, the disulfide bond in the extracellular domain is important for stability and correct addressing of the P0 protein.