ELECTRON MICROSCOPE AND X-RAY DIFFRACTION STUDIES OF THE EFFECTS OF DEHYDRATION ON THE STRUCTURE OF NERVE MYELIN : I. Peripheral Nerve

The dehydration of frog sciatic nerve has been studied by allowing specimens to become partially or fully dried before fixation and preparation for electron microscopy. Low magnification electron micrographs of OsO₄-fixed preparations showed marked tissue shrinkage which could be correlated quantitatively with the loss of water during the preliminary drying. KMnO₄-fixation appeared to cause a rehydration of the dried tissue. Higher magnification electron micrographs of the OsO₄-fixed preparations showed a sequence of modifications of the myelin layers which could be correlated with changes in the small-angle x-ray diffraction data which were recorded during drying. An intermediate stage of drying was characterised by a partial collapse of layers and a disappearance of the intraperiod dense line in some regions of the myelin sheath. Continuity between collapsed and non-collapsed layers was maintained throughout the sheath. The fully dried preparation showed two main modifications of the myelin layers. In many regions the layers (principal layers) resembled those of normal preparations, but showed an intensification and frequently a doubling of the intraperiod dense line. In addition, there was a very extensive system of fine (40 A periodicity) dense layers, some of which could be demonstrated to be continuous with the principal layers. In such cases it was observed that two of the fine layers were related to each principal layer. The correlation between diffraction data and electron microscope data is discussed, and some speculations are made concerning the molecular significance of the observations.     

THE EFFECTS OF UNDERNUTRITION ON THE PROTEINS OF OPTIC AND SCIATIC NERVES DURING DEVELOPMENT

Abstract— Polyacrylamide gel electrophoresis has been used to assess the appearance of some optic and sciatic nerve proteins in normal developing rats and in undernourished rats. Of the myelin proteins, the'Wolfgram'proteolipid is already present about the time myelination begins. The basic myelin proteins appear later, first in sciatic and then in optic nerve. A non-myelin basic protein, assumed to be a histone, is present at high levels in both nerves before myelination begins. There is no apparent effect of undernutrition on the appearance and amount of myelin proteins at 12, 16 and 22 days of age. The'histone'protein is reduced in optic and sciatic nerves at times corresponding roughly to the transition periods from cellular proliferation to myelin formation. The possibilities are discussed that myelin basic proteins are synthesized as compact myelin formation occurs, and that there may be retarded cellular proliferation in nerves of undernourished rats.     

ELECTRON MICROSCOPE AND LOW-ANGLE X-RAY DIFFRACTION STUDIES OF THE NERVE MYELIN SHEATH

1. A close correlation has been obtained between high resolution electron microscopy and low-angle x-ray diffraction studies of the myelin sheath of frog and rat peripheral and central nerves. Extensive studies were performed by application of both techniques to the same specimens, prepared for examination by OsO₄ or KMnO₄ fixation, and embedding either in methacrylate or in gelatin employing a new procedure. Controlled physical and chemical modifications of the myelin sheath prior to fixation were also investigated. 2. A correspondence was established between the layer spacings observed in electron micrographs and the fundamental radial repeating unit indicated by the low-angle x-ray diffraction patterns. The variations in relative intensities of the low-angle x-ray reflections could be related to the radial density distributions seen in the electron micrographs. 3. An analysis of the preparation procedures revealed that OsO₄ fixation introduces a greater shrinkage of the layer spacings and more pronounced changes in the density distribution within the layers than KMnO₄ fixation. The effects of methacrylate and gelatin embedding are described, and their relative merits considered in relation to the preservation of myelin structure by OsO₄ fixation. 4. The experimental modifications introduced by freezing and thawing of fresh whole nerve are described, particularly the enhancement of the intermediate lines and the dissociation of the layer components in the myelin sheath. A characteristic collapsing of the radial period of the sheath is observed after subjecting fresh nerve trunks to prolonged and intense ultracentrifugation. 5. Controlled extraction of fresh nerve with acetone at 0°C., which preferentially removes cholesterol, produces characteristic, differentiated modifications of the myelin sheath structure. Electron microscopy reveals several types of modifications within a single preparation, including both expanded and collapsed layer systems, and internal rearrangements of the layer components. Alcohol extraction leads to a more extensive structural breakdown, but in certain areas collapsed layer systems can still be observed. The components of the lipide extracts could be identified by means of x-ray diffraction. These modifications emphasize the importance of cholesterol in the myelin structure, and disclose a resistance of the dense osmiophilic lines to lipide solvents. 6. The significance of these structures is discussed in relation to present concepts of the molecular organization of myelin. The available evidence is consistent with the suggestion that the primary site of osmium deposition is at the lipoprotein interfaces and that the light bands probably represent regions occupied by lipide chains. The electron microscope and x-ray diffraction data also indicate the possibility of a regular organization within the plane of the layers, probably involving units of 60 to 80 A. The myelin sheath is regarded as a favourable cell membrane model for detailed analysis by combined application of x-ray diffraction and electron microscopy.     

An X ray diffraction study of frog sciatic nerve myelin in dimethyl sulfoxide.

Reversible structure modification of frog sciatic nerve myelin bathed in Ringer's solution containing dimethyl sulfoxide (DMSO) at a concentration of 33% has been studied by low-angle X-ray diffraction using a linear position-sensitive counter. Fourier images of native myelin layers, derived using low-order reflections measured at various stages of the DMSO treatment, reveal that the bilayer profile of native myelin membrane undergoes a specific asymmetric change prior to the phase transformation: The high-density peak on the extracellular side of the central lipid hydrocarbon layer decreases reversibly as the nerve is permeated by DMSO, while the internal peak and the central layer remain virtually unaltered. The dynamic process by which the contracted phase of myelin is derived from native myelin is speculated on the basis of the observed profile change.     

THE ROLE OF WATER IN THE STRUCTURE OF PERIPHERAL NERVE MYELIN

In the study of the drying kinetics of nerve fibres, at least five "phases" of water evaporation can be distinguished. A consideration of the accompanying changes in low-angle x-ray diffraction patterns permits a tentative identification of the "phases" and a quantitative interpretation of the data in terms of the water distribution in nerve fibres. These results suggest that the myelin sheath of frog sciatic nerve contains 40 to 50 per cent water, and it is suggested further that the greater part of this water is "organised" in relation to the hydrophilic groups of the lipide and protein components.     

Neurochemical Characteristics of Myelin-like Structure in the Chick Retina

Abstract: Certain characteristics of myelin-like structures in the chick retina were examined morphologically and biochemically. Developmental changes of 2', 3'-cyclic nucleotide 3'-phosphohydrolase (CNPase) in the chick retina and optic nerve were examined. The measurable activity in the retina was first detected at 16 days of incubation and thereafter, it increased rapidly until 4 weeks post-hatching. By contrast, CNPase activity in the optic nerve reached the maximum level at 4 days post-hatching and maintained a constant level thereafter. The purifed myelin fraction from the chick retina showed higher activity of CNPase, whereas its activity in the retinal homogenate was very low. Hence, it was considered that the myelin fraction from the chick retina is similar to that of CNS myelin with respect to CNPase. Protein profiles of the purified myelin fractions isolated from the chick optic tectum, optic nerve, retina and sciatic nerve were analysed by SDS-polyacrylamide gel elec-trophoresis. Myelin fractions from the chick optic tectum and optic nerve contained basic protein (BP) and Folch-Lees proteolipid protein (PLP). Myelin fraction from the chick sciatic nerve contained BP, P2 and two glycoproteins (PO and 23K). In contrast, retinal myelin fraction contained only BP. PLP, PO, 23K and P2 proteins were definitely undetectable. Electron micrographs revealed that some axons in the optic nerve fiber layer of the chick retina were wrapped by a spiral-structured myelin-like sheath, which showed some differences from those of CNS and PNS myelin sheaths. It was suggested that the origin of the myelin-like structure in the chick retina is other than from oligodendroglia or Schwann cells.     

Incorporation of newly formed lecithin into peripheral nerve myelin

Radioactive choline was used to study the metabolism and movement of choline-containing phospholipids in peripheral nerve myelin of adult mice. Incorporation at various times after intraperitoneal injection was measured in serial segments of sciatic nerve as well as in myelin isolated from those segments. At no time (1 h to 35 days) could a proximal-distal difference in the extent of labeling be demonstrated. This finding suggests that incorporation of precursor choline phospholipids into nerve membranes is a local event, with little contribution from the neuronal perikaryon via axoplasmic transport. Autoradiographic investigations were undertaken to elucidate the pattern of movement of radioactive choline-labeled phospholipids, predominantly lecithin, into the myelin sheaths of the sciatic nerve. A sequence of autoradiographs was prepared from animals sacrificed between 20 min and 35 days after a microinjection of precursor directly into the nerve. Analysis of these autoradiograms revealed that labeling is initially concentrated in the Schwann cell cytoplasm. Later, the label moves first into the outer regions of the myelin sheaths and is eventually distributed evenly throughout the inner and outer layers of the sheath. At no time is there a build-up of label in the axon. The rate of uptake of precursor and subsequent redistribution of lecithin into the myelin were also examined in frog sciatic nerve (18 degrees C). Both uptake and redistribution processes were considerably slower in the cold-blooded animal.     

THE FINE STRUCTURE OF NERVE CELL BODIES AND THEIR MYELIN SHEATHS IN THE EIGHTH NERVE GANGLION OF THE GOLDFISH

The eighth cranial nerve ganglion consists of bipolar nerve cell bodies each occupying part of an internodal segment. The perikaryal sheaths range from a single layer of Schwann cell cytoplasm on the smallest cells to typical thick compact myelin on the largest. On most perikarya, the sheath displays an intermediate form, consisting of multiple layers of Schwann cell cytoplasm (loose myelin), or of loose and compact myelin continuous with each other. Internodes beyond the one containing the cell body bear only compact myelin. In loose myelin the thickness of each layer of Schwann cell cytoplasm is about 100 A. It may be much greater (~ 3000 A) particularly in the outermost layers of the sheath, or the cytoplasm may thin and even disappear with formation of a major dense line. The cytoplasmic layers are separated from each other by a light zone, 40 to 200 A wide, which in its broader portions may contain an intermediate line. Desmosomes sometimes occur between lamellae. In addition to the usual organelles, the perikaryal cytoplasm contains granular and membranous inclusions. Large cells covered by compact myelin have a consistently higher concentration of neurofilaments, and some of the largest cells, in addition, show a reduced concentration of ribosomes. The functional significance and possible origins of perikaryal myelin sheaths are discussed.     

The Ultrastructure of Schmidt-Lanterman Clefts and Related Shearing Defects of the Myelin Sheath

Schmidt-Lanterman clefts in frog sciatic nerves have been studied in thin sections by electron microscopy utilizing permanganate fixation and araldite embedding. It is shown that they are shearing defects in myelin in which the lamellae are separated widely at the major dense lines. Each lamella consisting of two apposed Schwann cell unit membranes ~ 75 A across traverses the cleft intact. The unit membranes composing each lamella sometimes are slightly (~ 50 to 100 A) separated in the clefts. The layers between the lamellae contain membranous structures which may be components of the endoplasmic reticulum. These layers are continuous with the outer layer of Schwann cytoplasm and the thin and inconstant cytoplasmic layer next to the axon (Mauthner's sheath). Each of these layers in perfect clefts constitutes a long helical pathway through the myelin from the axon. One of these is connected with Schwann cytoplasm and the other directly with the outside. A type of cross-sectional shearing defect, not hitherto recognized, is described and shown to be a kind of Schmidt-Lanterman cleft. Incomplete clefts are seen and interpreted as representing stages in a dynamic process whereby the myelin lamellae may be constantly separating and coming together again in life.     

Reversible changes in myelin structure and electrical activity during anesthesia in vivo

X-ray diffraction patterns have been recorded from sciatic nerve myelin by means of dynamic X-ray diffraction either from frogs, during the early stages of anesthesia in vivo induced by n-pentane inhalation, and from frog and rat sciatic nerves isolated immediately after the animal was anesthetized. This approach has enabled to resolve minor changes in myelin structure that occur during anesthesia which were found to be similar in frogs and mammals. The X-ray patterns show a reversible slight decrease in intensity of the even reflections during anesthesia. The electron density profiles from myelin of anesthetized and recovered nerves revealed that the unit membrane structure is practically identical in both circumstances. However, during anesthesia myelin membrane pairs move toward the cytoplasmic side becoming more closely packed by 1.6 A. Physiological activity was estimated during the recovery process: compound action potential recovered its maximal amplitude before myelin recovered its native structure. On the contrary, the conduction velocity seemed to be closely related to the structural recovery. This work provides evidence that early stages of anesthesia by n-pentane in vivo does not change membrane bilayer structure but perturbs the surface interactions between adjacent membrane pairs.     

Analysis of the mechanism of the fixation of membrane structures using osmium tetroxide. II. An electron microscopic and x-ray structural study of myelin frozen and lyophilized at low temperature]

Comparative electron microscope and X-ray studies were made on the frog sciatic nerve myelin after freeze-drying technique. The specimens were fixed with OsO4 before and after freeze-drying. In the latter case, osmium was used as a hydrophobic solution (OsO4 in CCl4), or in the high vacuum during osmium sublimation. The results obtained in this study do not fit in the accepted mechanism operating during osmium fixation of membranes. Another mechanism is proposed by the authors, and the problem of osmium localization within the space of the myelin repeated unit is discussed.     

Using microwave irradiation in Marchi's method for demonstrating degenerated myelin.

Conventional methods for histological preparation of degenerated myelin are time-consuming and difficult. The purpose of our study was to shorten the time required for the procedure and to obtain better quality results for light microscopic demonstration of degenerated myelin in the central and peripheral nervous systems by using microwave irradiation. Rat brain and sciatic nerve were used for the study. The middle cerebral artery was occluded and the sciatic nerve was cut to produce myelin degeneration. Marchi's method was used for staining degenerated myelin. Fixation for light microscopy that would take two days using the conventional procedure was completed in 16.5-18.5 min using microwave irradiation. While staining of degenerated myelin requires 10 days for the conventional Marchi method, we decreased it to 7 h for brain tissue and 1 h for sciatic nerve by using the microwave oven. Moreover, a better quality preparation was achieved in the groups stained under microwave irradiation than those prepared by the conventional method.     

Using microwave irradiation in Marchi's method for demonstrating degenerated myelin

Conventional methods for histological preparation of degenerated myelin are time-consuming and difficult. The purpose of our study was to shorten the time required for the procedure and to obtain better quality results for light microscopic demonstration of degenerated myelin in the central and peripheral nervous systems by using microwave irradiation. Rat brain and sciatic nerve were used for the study. The middle cerebral artery was occluded and the sciatic nerve was cut to produce myelin degeneration. Marchi's method was used for staining degenerated myelin. Fixation for light microscopy that would take two days using the conventional procedure was completed in 16.5–18.5 min using microwave irradiation. While staining of degenerated myelin requires 10 days for the conventional Marchi method, we decreased it to 7 h for brain tissue and 1 h for sciatic nerve by using the microwave oven. Moreover, a better quality preparation was achieved in the groups stained under microwave irradiation than those prepared by the conventional method.     

THE RESPIRATORY RATE OF THE SCIATIC NERVE OF THE FROG IN REST AND ACTIVITY

1. With the indicator method of Haas, the rates of carbon dioxide production have been measured in the case of the sciatic nerve, various parts of the brain, and the sartorius muscle of the frog. The rate of respiration of the sciatic nerve is from 10 to 30 per cent of that of the other tissues, varying somewhat with the individual. 2. Stimulation of the sciatic nerve with induction shocks sufficient to induce tetanus of the muscle does not increase the output of carbon dioxide from the sciatic nerve, even if continued as long as 30 minutes. Sartorius muscle used as a control showed a marked increase in carbon dioxide production upon relaxation after contraction resulting from such stimulation. 3. These facts indicate that the nerve impulse does not depend upon processes leading to the production of carbon dioxide.     

Using microwave irradiation in Marchi's method for demonstrating degenerated myelin

Conventional methods for histological preparation of degenerated myelin are time-consuming and difficult. The purpose of our study was to shorten the time required for the procedure and to obtain better quality results for light microscopic demonstration of degenerated myelin in the central and peripheral nervous systems by using microwave irradiation. Rat brain and sciatic nerve were used for the study. The middle cerebral artery was occluded and the sciatic nerve was cut to produce myelin degeneration. Marchi's method was used for staining degenerated myelin. Fixation for light microscopy that would take two days using the conventional procedure was completed in 16.5-18.5 min using microwave irradiation. While staining of degenerated myelin requires 10 days for the conventional Marchi method, we decreased it to 7 h for brain tissue and 1 h for sciatic nerve by using the microwave oven. Moreover, a better quality preparation was achieved in the groups stained under microwave irradiation than those prepared by the conventional method.     

ELECTRON MICROSCOPE STUDIES OF THE FORMATION OF NODES OF RANVIER IN MOUSE SCIATIC NERVES

Observations with the electron microscope of longitudinal sections of the sciatic nerves of infant mice during the period of early myelin formation are described. These observations are interpreted in relation to previous studies of transverse sections, and a general picture of the formation of an internodal length of the myelin sheath in three dimensions is formulated. In general, an internodal length of myelin sheath is attained by the spiral wrapping of the infolded Schwann cell surface; the increase in length of the internode during maturation is at least partially explained by the increased length of axon covered by the overlapping of successive layers during the wrapping of the infolded Schwann cell surface; and the nodes of Ranvier refer to the structure complex at the junctions of adjacent non-syncytial Schwann cells. The fact that the mode of formation of myelin brings each of its layers into intimate contact with the axon surface at the nodes is emphasized because of the possible functional significance of this arrangement. The manner of origin of Schmidt-Lantermann clefts remains obscure. Certain isolated observations provide evidence for the possibility that occasional internodes of myelin may form from several small segments of myelin within a single Schwann cell.     

STUDIES ON THE PROBLEM OF PRESERVATION OF MYELIN SHEATH ULTRASTRUCTURE: EVALUATION OF FIXATION, DEHYDRATION, AND EMBEDDING TECHNIQUES

Currently accepted methods of tissue preparation for electron microscopy result in alterations of myelinated nerve fibers. In an attempt to minimize distortion of myelin, various fixation techniques, dehydration schedules, and embedding methods have been evaluated. It was found that the major damage to myelinated nerves occurs in the embedding procedure. A technique for embedding nerve tissue using the polyester Vestopal W is described which was found to result in improved preservation of myelin.     

X-ray diffraction study of myelin structure in immature and mutant mice

X-ray diffraction patterns were obtained from freshly dissected central and peripheral nerves of quaking, myelin synthesis deficiency ($\text{msd}$), and trembler mutants, as well as immature and adult normal mice. The patterns were compared with respect to strength of myelin diffraction, background scatter level, repeat period, and intensity and linewidth of Bragg reflections. The deficiency of myelin in optic nerves was found to be (in decreasing severity): quaking > immature > trembler ? normal adult; and in sciatic nerves: $\text{trembler > immature > quaking}\text{msd ?}\text{normal}$ adult. Repeat periods about 3 Å less than that for normal adult sciatic myelin were detected in corresponding nerves from immature, quaking, and trembler mice. In some trembler sciatic nerves a second phase having a 190–200 Å period and accounting for about 60% of the total ordered myelin was also evident. Comparison of electron density profiles of membrane units calculated from the repeat periods and diffracted intensities for sciatic myelins indicate structural differences at the molecular level. The main findings are: (1) quaking myelin shows a significant elevation of density in the external protein-water layer between membrane bilayers; (2) the membrane bilayer of immature myelin is ≈ 2 Å thinner than that for normal adult; (3) the membrane bilayer of the more compact phase in trembler myelin is ≈ 5 Å thinner than for normal; and (4) the difference in repeat periods for the two phases present in some of the trembler nerves can be accounted for predominantly by distinct membrane bilayer separations at the external boundary.     

CHANGES IN THE OSMIOPHILIA OF MYELIN AND LIPID CONTENT IN THE KITTEN OPTIC NERVE

Myelin osmiophilia has been shown to develop significantly later than myelin staining by Luxol fast blue and Sudan black, in the developing kitten optic nerve. These histological changes are accompanied by alterations in the lipid composition of the optic nerve. Although myelination commences at about 10 days post partum in the nerve the appearance of cerebrosides is unexpectedly delayed. Changes in fatty acid chain length and lipid composition of optic nerve are consistent with the suggestion that ‘early’ myelin may be unchanged glial plasma membrane.     

Myelin Abnormalities in the Optic and Sciatic Nerves in Mice With GM1-Gangliosidosis

GM1-gangliosidosis is a glycosphingolipid lysosomal storage disease involving accumulation of GM1 and its asialo form (GA1) primarily in the brain. Thin-layer chromatography and X-ray diffraction were used to analyze the lipid content/composition and the myelin structure of the optic and sciatic nerves from 7- and 10-month old β-galactosidase (β-gal) +/? and β-gal −/− mice, a model of GM1gangliosidosis. Optic nerve weight was lower in the β-gal −/− mice than in unaffected β-gal +/? mice, but no difference was seen in sciatic nerve weight. The levels of GM1 and GA1 were significantly increased in both the optic nerve and sciatic nerve of the β-gal −/− mice. The content of myelin-enriched cerebrosides, sulfatides, and plasmalogen ethanolamines was significantly lower in optic nerve of β-gal −/− mice than in β-gal +/? mice; however, cholesteryl esters were enriched in the β-gal −/− mice. No major abnormalities in these lipids were detected in the sciatic nerve of the β-gal −/− mice. The abnormalities in GM1 and myelin lipids in optic nerve of β-gal −/− mice correlated with a reduction in the relative amount of myelin and periodicity in fresh nerve. By contrast, the relative amount of myelin and periodicity in the sciatic nerves from control and β-gal −/− mice were indistinguishable, suggesting minimal pathological involvement in sciatic nerve. Our results indicate that the greater neurochemical pathology observed in the optic nerve than in the sciatic nerve of β-gal −/− mice is likely due to the greater glycolipid storage in optic nerve.