The association of the sulphogalactosylglycerolipid of rat brain with myelination

The sulphogalactosylglycerolipid of rat brain is closely associated with the process of myelination, as demonstrated by the following observations. 1. The lipid is barely detectable in rat brain before 10 days of age, accumulates rapidly between age 10 and 25 days, and remains relatively constant in amount (between 0.3 and 0.4mumol per brain) thereafter into adult life. 2. The activity of adenosine 3'-phosphate 5'-sulphatophosphate-galactosyldiacylglycerol sulphotransferase is almost absent before 10 days of age, attains a maximum at age 20 days, and slowly decreases thereafter with increasing age. This developmental pattern correlates well with that of other myelin-specific metabolites. 3. Both the concentration of the sulphogalactosylglycerolipid and the activity of sulphotransferase are greatly decreased in the non-myelinating jimpy mouse. 4. The myelin fraction of rat brain contains most of the sulphogalactosylglycerolipid. The lipid occurs in a diacyl and an alkylacyl form. Determinations of the relative amount of each type in brain showed about a 1:1 mixture in both 21-day-old and adult rats. Rats injected with H(2) (35)SO(4) at 20 days of age lost (35)S from the diacyl form at a higher rate than from the alkylacyl compound over a 21-day period. These data suggest that the diacyl form has a higher turnover than the alkylacyl derivative. The percentage of the total sulpholipid content of brain contributed by the sulphogalactosylglycerolipid is 16% in 21-day-old rats and 8.4% in adult rats.     

Microtubule alterations in cultured taiep rat oligodendrocytes lead to deficits in myelin membrane formation

The taiep rat is a myelin mutant in which hypomyelination and progressive demyelination of the CNS are accompanied by an accumulation of microtubules within oligodendrocytes. To investigate whether and how the myelin defects were caused by microtubule abnormalities, we have established a taiep oligodendrocyte culture system in which mutant cells produce abnormally high levels of tubulin and microtubule-associated proteins and exhibit myelin defects. The studies show that abnormal microtubule accumulation and tight microtubule bundles developed in the taiep oligodendrocytes, with a higher ratio of minus-end-distal to plus-end-distal microtubules in their processes. Initially, in culture, immature taiep oligodendrocytes which have higher levels of tubulin than controls extend roughly twice as much membrane sheet as controls. The membrane sheets of the mature taiep oligodendrocytes which display the microtubule accumulation, however, grew much less rapidly compared to controls. By the fifth day in culture, a majority of the taiep oligodendrocytes had ceased the expansion of their membrane sheets and in some cases the sheets retracted. The levels of the myelin proteins, proteolipid protein and myelin-associated glycoprotein, were also markedly diminished in the mature taiep oligodendrocytes. Treatment with the microtubule depolymerizing drug nocodazole prevented not only the accumulation of microtubules but also restored the normal distribution of proteolipid proteins within the taiep oligodendrocytes. These data demonstrate that myelin synthesis in the oligodendrocyte cultures relies on the formation of a normal microtubule array, and the microtubule abnormalities are directly responsible for the myelin deficit in the taiep oligodendrocytes.     

Effect of inorganic lead exposure on myelination in the rat

The effect of defined lead burdens on myelination of the central and peripheral nervous systems was studied in neonatal Long-Evans rats. Pups were exposed to inorganic lead (100 or 400 mg Pb as lead acetate/kg body wt/day by gastric intubation) from day 2 following birth to 30 days of age. Accumulation of myelin in forebrain was not affected by the 100-mg dosage, but at the 400 mg/kg dosage level, myelin accumulation was reduced by approximately 42% on a per gram forebrain basis relative to vehicle-intubated animals. The deficit was over 50% on a per forebrain basis, since there was also a slight reduction in brain weight. This lead effect was observed at both 15 and 30 days of age. Accumulation of myelin in optic nerve (determined on the basis of proteolipid protein concentration) was also reduced by 30% relative to controls by this dosage level. However, myelination in sciatic nerve (determined on the basis of P₀ protein concentration) was not affected by this exposure regimen. Myelin deficits were greater than could be accounted for by undernutrition arising secondary to lead exposure and were not due to a developmental delay in the onset of myelination.     

The origin of the myelination program in vertebrates

The myelin sheath was a transformative vertebrate acquisition, enabling great increases in impulse propagation velocity along axons. Not all vertebrates possess myelinated axons, however, and when myelin first appeared in the vertebrate lineage is an important open question. It has been suggested that the dual, apparently unrelated acquisitions of myelin and the hinged jaw were actually coupled in evolution [1,2]. If so, it would be expected that myelin was first acquired during the Devonian period by the oldest jawed fish, the placoderms [3]. Although myelin itself is not retained in the fossil record, within the skulls of fossilized Paleozoic vertebrate fish are exquisitely preserved imprints of cranial nerves and the foramina they traversed. Examination of these structures now suggests how the nerves functioned in vivo. In placoderms, the first hinge-jawed fish, oculomotor nerve diameters remained constant, but nerve lengths were ten times longer than in the jawless osteostraci. We infer that to accommodate this ten-fold increase in length, while maintaining a constant diameter, the oculomotor system in placoderms must have been myelinated to function as a rapidly conducting motor pathway. Placoderms were the first fish with hinged jaws and some can grow to formidable lengths, requiring a rapid conduction system, so it is highly likely that they were the first organisms with myelinated axons in the craniate lineage.     

Effects of glycoprotein synthesis inhibitor on myelination in rat cerebellum

Effects of a glycoprotein synthesis inhibitor on myelination were investigated in rat cerebellum. The glycoprotein synthesis inhibitor, tunicamycin (TM), was injected intracranially into newborn rats. The activity of 2,3-cyclic nucleotide 3-phosphodiesterase (CNPase) in the cerebellum was significantly reduced in 2-week-old animals and was restored to the normal level by age 3 weeks. When TM was injected into newborn rats every 3–4 days for a total of 6 times, CNPase activity was still low at 3 and 4 weeks. Immunohistochemical stainings for CNPase and myelin-associated glycoprotein (MAG) were performed on paraffin sections of multiple-TM-injected cerebellum at 3 weeks. The intensity of the staining with MAG antiserum in the white matter was clearly decreased in TM-treated cerebellum compared with the control. The myelin in the granule cell layer was poorly stained with CNPase antiserum in TM-treated cerebellum. Subcellular fractionation was carried out and the CNPase activity in each fraction was measured. The CNPase activity in the myelin fraction (P₂A) from the TM-treated cerebellum was significantly lower than that in the control. In contrast, the activity in the synaptosomal (P₂B) and microsomal (P₃) fractions from the multiple-TM-injected cerebellum was higher than in those from the controls. Polyacrylamide gel electrophoretic patterns of the P₂A fractions were analyzed. The P₂A fraction from TM-treated cerebellum contained less Wolfgram protein than the control. These results suggest that glycoprotein synthesis plays certain roles in myelination in the central nervous system.     

The myelination of the cerebellar cortex in the cat

Summary The myelination of the cerebellar cortex of the cat was investigated in 61 cats aged from 3 hrs post partum to two and a half years. The first myelinated fibers appear at the time of birth in the central medullary ray. Before the onset of myelination, all fibers reach a critical diameter of about 1 m. About the 14th day of life the number of oligodendrocytes in the prospective white matter increases markedly. Thereafter, the oligodendrocytes invade the inner granular layer. It therefore seems that the myelination of the cerebellar cortex proceeds from the central medullary ray towards the granular layer. At the 60th day of postnatal life, most of the afferent and efferent fiber systems are myelinated. These findings are discussed in relation to the development of function and the maturation of the electrical activity of the cerebellar circuit.Dedicated to Prof. Dr. H. Leonhardt in honour of his 60th birthdaySupported by the Deutsche Forschungsgemeinschaft (La 184/3)     

The non-synchronous synthesis of myelin components during early stages of myelination in the rat optic nerve.

—Analysis of lipids and proteins in whole optic nerves during initial stages of myelination indicate a sequential deposition of myelin components. During this period sulfatide levels increase from 4 nmol/pair of nerves at 9 days to 29 nmol/pair of nerves at 21 days. Cerebrosides are not detected until the 12th day and attain a level of 46 nmol/pair of nerves in the 21-day old rat. Plasma-logen values increase from 2.1 to 31 nmol/pair of nerves and cholesterol values from 12 to 158 nmol/pair of nerves between 9 and 21 days. High molecular weight proteins are present in samples from 9-day old rats analyzed by discontinuous sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Under identical conditions myelin basic proteins are first observed in the 10 day sample, and the proteolipid protein is first detected in the 12 day sample. The 2′, 3′-cyclic nucleotide 3′-phosphohydrolase activity increases from 1.13 to 5.50 μmol/min per mg protein between 9 and 21 days.     

Temporal oligodendrocyte lineage progression: In vitro models of proliferation,differentiation and myelination

Oligodendrocytes are neuroglial cells responsible, within the central nervous system, for myelin sheath formation that provides an electric insulation of axons and accelerate the transmission of electrical signals. In order to be able to produce myelin, oligodendrocytes progress through a series of differentiation steps from oligodendrocyte precursor cells to mature oligodendrocytes (migration, increase in morphologic complexity and expression pattern of specific markers), which are modulated by cross talk with other nerve cells. If during the developmental stage any of these mechanisms is affected by toxic or external stimuli it may result into impaired myelination leading to neurological deficits. Such being the case, several approaches have been developed to evaluate how oligodendrocyte development and myelination may be impaired. The present review aims to summarize changes that oligodendrocytes suffer from precursor cells to mature ones, and to describe and discuss the different in vitro models used to evaluate not only oligodendrocyte development (proliferation, migration, differentiation and ability to myelinate), but also their interaction with neurons and other glial cells. First we discuss the temporal oligodendrocyte lineage progression, highlighting the differences between human and rodent, usually used as tissue supply for in vitro cultures. Second we describe how to perform and characterize the different in vitro cultures, as well as the methodologies to evaluate oligodendrocyte functionality in each culture system, discussing their advantages and disadvantages. Finally, we briefly discuss the current status of in vivo models for oligodendrocyte development and myelination.     

Effects of ethanol on rat schwann cell proliferation and myelination in culture

Summary It is possible to treat dissociated embryonic rat dorsal root ganglia in culture to inhibit proliferation of all nonneuronal cells except Schwann cells. Neurons have been shown to produce a mitogenic stimulus for Schwann cells under these conditions. Additionally, myelin-competent neurons induce Schwann cells to elaborate myelin sheaths. Groups of sibling cultures were exposed to various nonlethal concentrations of ethanol (0, 43, 86, or 172 mM) for 4 wk. Culture were assessed weekly by light microscopy in a blind fashion for evidence of Schwann cell proliferation and myelin formation. Ethanol adversely affected both Schwann cell proliferation and myelin formation in culture. No obvious differences in neuronal morphology were observed among the various groups of cultures by light or electron microscopy. These observations suggest that ethanol might interfere with Schwann cell proliferation and myelin formation in culture by one or both of the following means: a) inhibit neuronal production of signals for Schwann cell proliferation and myelination or b) impede Schwann cell responses to neuronal signals. Investigation of these possibilities in culture may provide insight into neuropathologic mechanisms operative in the fetal alcohol syndrome or alcohol-associated peripheral neuropathy in humans. This work was supported by the Department of Veterans Affairs, Washington, D.C.