Disorder in nerve myelin: Phasing the higher order reflections by means of the diffuse scatter

Disorder in the stacking of membrane layers in nerve myelin has an important effect on the X-ray diffraction pattern. In a previous report we found broadening of the Bragg reflections and diffuse intensity between them. A model for the disorder was presented to account for these effects, and some of the model parameters were evaluated by analysis of the X-ray diffraction pattern in the region of Bragg reflections 1 to 6, where the phasing is well established. In this paper, we present further data and derive a more complete and precise set of values for the parameters. Then, assuming these values, all possible combinations of phases for reflections 7 to 15 are used to calculate the corresponding diffraction patterns for comparison with observation. The 20 best fitting phase combinations are considered in detail. Sixteen of these are eliminated, leaving four possible combinations which differ only in the phases for orders 8 and 15.Electron density profiles computed using the four possible phase combinations are not very different from one another. All four profiles show a markedly higher electron density in the extracellular half of the membrane bilayer than in the cytoplasmic half. Our calculations indicate that the cytoplasmic half can be accounted for entirely by myelin lipids, including cholesterol. However, an unreasonably high proportion of cholesterol would be needed to account for the extracellular half of the bilayer, and we tentatively conclude that an appreciable part of the myelin protein is inserted into this half of the bilayer.Analytical methods used by other investigators are considered in light of our experimental observations and model predictions in order to reconcile conflicting results. Failure to account properly for diffuse intensity arising from the disorder makes previous determinations of myelin membrane structure at moderate resolution questionable.     

X-ray observations on a collagen fibril lattice structure in peripheral nerve

It has been known for more than two decades that peripheral nerve shows X-ray reflections other than those originating from the myelin sheath. These extra reflections are at small angles of diffraction and arise from a variation of electron density in the radial direction. X-ray diffraction studies since 1973 have identified these reflections as coming from a lattice structure of filaments, the filament axes are parallel to the nerve fibre axis. The present X-ray observations were obtained using a high-resolution X-ray camera and we conclude that these reflections arise from a collagen fibril lattice structure within peripheral nerve. Estimates of fibril radius and the separation distance between fibrils in intact rat, rabbit and frog sciatic nerves have been obtained using X-ray analysis.     

Order-disorder phenomena in myelinated nerve sheaths. II. The structure of myelin in native and swollen rat sciatic nerves and in the course of myelinogenesis

The algorithm described in the accompanying paper was applied to X-ray scattering experiments performed with rat sciatic nerves, either as a function of the age of the animal (4 to 30 days), or with adult nerves swollen in non-isotonic media. The results were all consistent with the model of disorder used in the theoretical treatment. The algorithm leads, in one step, from the data to the numerical values of the parameters, avoiding all intermediate manipulation. For each experiment a variety of parameters was determined: the average D and the variance sigma 2D of the repeat distance, the average number [N] of motifs per crystallite, the set [idiff(h/D)], which defines the diffuse scattering, the fraction alphaloose of myelin that does not belong to the compact sheaths, and the set [imotif (k/2D)], which suffices to define the continuous intensity curve of the motif imotif(s). Note the remarkable wealth of information, especially by contrast with conventional analyses which, as a rule, only yield the values of D and of the set [imotif(h/D)] (insufficient to determine the function imotif(s]. The function imotif(s) and the parameters D and sigma D (and thus the local structure of the myelin sheaths) were shown to be almost invariant in the course of myelinogenesis; what varies is mainly the total amount of myelin in the nerve and the number of membranes per sheath. Swelling agents have a dramatic influence on the X-ray scattering spectra, but in spite of the conspicuous variation of D, sigma D and [N] the structure of the motif is invariant. The structure of the motif was shown to be quite different in the native and in the swollen samples; the stacking disorder appears to involve mainly the cytoplasmic space in native myelin, the external space in swollen nerves. The very notion of electron density profile, when disorder is present, is discussed. Two criteria were proposed to select the "best" signs of the reflections: two sets came out at almost the same rank, one corresponding to Caspar & Kirschner's the other to Worthington & McIntosh's proposals, neither of which can be ruled out according to the criteria used in this work.     

Ferrochelatase activity in wild-type and mutant strains of Spirillum itersonii. Solubilization with chaotropic reagents

New low-angle X-ray diffraction data have been obtained from nerve myelin after rehydration. The X-ray patterns show the first six orders of diffraction of a lamellar repeat unit of about 100 Å. Direct methods of structure analysis have been used to determine uniquely the phases of the first three orders of diffraction. The electron density profile of rehydrated nerve myelin has been obtained on an absolute electron density scale and is compared with the electron density profile of normal nerve myelin at the same resolution of 16–17 Å. Possible electron-density profiles of rehydrated nerve myelin at a resolution of 8 Å are shown.     

An X-ray study of the condensed and separated states of sciatic nerve myelin

Low-angle X-ray diffraction patterns of peripheral nerve myelin after modification by either rehydration in various solutions or by chemical treatment have been recorded. These X-ray patterns and the previously reported modified nerve myelin patterns demonstrate that nerve myelin has at least five different states: the normal state, condensed state I and II and separated state I and II. There are two membranes per unit cell in the normal state and in states II whereas there is one membrane per unit cell in states I. Under certain conditions normal nerve can go reversibly into either of states II. With continued treatment the nerve myelin structure moves irreversibly from state II to state I and, once in state I, the nerve myelin layers cannot return to the normal state. Our results demonstrate that there is a reversible transformation between condensed state I and separated state I. Fourier profiles of nerve myelin in the normal state, condensed state I and separated state I are presented.     

Order-disorder phenomena in myelinated nerve sheaths. IV. The disordering effects of high levels of local anaesthetics on rat sciatic and optic nerves.

Sequences of 15 minute X-ray scattering spectra were recorded with rat sciatic and optic nerves, superfused with tetracaine-containing Ringer solutions. The spectra were analysed using the algorithm advocated in this series of papers. The main results, as a function of the time of exposure to tetracaine, were: the mean value of the repeat distance increases; its variance decreases; the average number of membrane pairs per coherent domain decreases; the fraction of isolated membrane pairs increases. Eventually, the spectra were observed to give way to the continuous intensity curve of a single, isolated membrane pair. At all stages of the experiment the continuous intensity curves were found to differ from one type of nerve to the other, and to be invariant, for each type of nerve, with respect to the tetracaine treatment. The X-ray scattering study clearly identified the nature of the structural differences between the two types of myelin sheaths: in that of native sciatic nerves, packing disorder preferentially affects the cytoplasmic space of the membrane pair, and tetracaine disrupts the packing in that space; in the myelin of optic nerves it is the external space that is preferentially affected by packing disorder and disrupted by tetracaine. The time-course of the structure parameters showed that, at any stage of the experiment, tetracaine acts preferentially on the more highly disordered regions of the structure and totally disrupts them. These results corroborate earlier conclusions reported in the previous papers of this series. An electron microscope study was also performed on tetracaine-treated nerves: the results, in close agreement with those of the X-ray scattering study, neatly confirm the conclusions given above. In a more general way, the remarkable agreement between the results of the analysis of the X-ray scattering spectra and the electron microscope observations strongly supports the validity of the physical model used in this series of papers and the correctness of the mathematical treatment that we advocate. Finally, the relations between this work and the work of others are discussed. It must be stressed that the present work bears on the toxic rather than on the anaesthetic effects of tetracaine.     

An X-ray study of the effect of enzymes on frog sciatic nerve myelin

Low-angle X-ray diffraction patterns have been recorded from frog sciatic nerve after digestion with trypsin and Pronase. Reproducible X-ray patterns were obtained by swelling the nerves in distilled water before treatment with enzymes. The X-ray patterns of enzyme-treated nerves are distinctly different from the X-ray pattern of normal (live) nerve. It would appear that the normal asymmetric nerve myelin membrane becomes symmetric about its center after treatment with enzymes as a result of proteolytic cleavage and a subsequent redistribution of protein components.     

Surprising thermal transition in fish myelin

A new structural transition in nerve myelin has been discovered by means of X-ray diffraction of excised teleost nerves in physiological saline. The reversible transition is between two structures, designated AS and AL, with repeating distances (d spacings) differing by 25-35 A. When the temperature of bream spinal cord is lowered from room temperature to 4 degrees C, much but not all of the AS (short spacing) myelin changes into AL (long spacing) myelin. The change is reversed when the temperature is raised back to 22 degrees C, and it occurs a second time when the temperature is lowered again to 4 degrees C. The myelin in bream optic nerve undergoes a similar thermal transition, but the myelin in brachial plexus does not. The thermal transition does not involve the liquid crystal-to-gel transition observed in lipids and natural membranes. When a specimen is kept at constant temperature, there is a gradual conversion from AS to AL myelin which is not thermally reversible, suggesting the existence of two distinct subclasses of AL. Similarly, two subclasses are indicated for AS myelin since part of it does not transform thermally. The observations reported here may have significance for the evolutionary development of myelin.     

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.     

Structure of sarcoplasmic reticulum membranes at low resolution (17A)

Vesicles of fragmented sarcoplasmic reticulum membranes have been prepared and centrifuged into a multilayered form suitable for analysis by X-ray diffraction. X-ray diffraction has been recorded from a regular stacking of flattened vesicles in the presence of excess fluid. Discrete orders of a lamellar repeat distance ranging from 220 to 270 Å have been recorded. The diffraction data extend out to a minimum Bragg spacing of 33 Å. An electron density profile at a resolution of 17 Å has been derived using direct methods of structure analysis. The membrane has a bilayer construction (similar to nerve myelin and retina at low resolution) but the profile is markedly asymmetrical. The protein molecules are predominantly on the inside of the vesicle. A striking resemblance between the disc membranes in retina and the sarcoplasmic reticulum membranes has been noted and is described. X-ray diffraction has been recorded from the protein molecules in the surface of the sarcoplasmic reticulum membrane. The protein molecules are not in an ordered array but appear to have a liquid-like ordering. The observation that vesicles can be prepared in a suitable form for X-ray analysis has importance for membrane research for many different membranes form vesicles and it follows that these membranes can now be profitably studied by X-ray diffraction using a similar method.     

X-ray diffraction of myelin membrane. I. Optimal conditions for obtaining unmodified small angle diffraction data from frog sciatic nerve

The X-ray diffraction pattern of myelin of frog sciatic nerve has been investigated, using a Kratky small angle slit camera to obtain the electron density distribution across the membrane. All major reflections observed were related to a fundamental repeat distance of 171 ± 2.8 A. There was no further increase in the number of reflections on varying the experimental conditions (varying pH, applying tension, immersion in various isotonic buffer solutions, etc.) or by varying the camera slit arrangement. The degree of disorder within the myelin sheath was examined by comparing the crystallite size to the half-width of the diffraction peak at half-height. The limiting of the diffraction spectra to five major reflections was determined not to be caused by disorder. It is concluded that the observed X-ray diffraction pattern is a consequence of the particular electron density distribution of the membrane. Therefore, the membrane cannot contain sharply distinct step-function regions of electron density, but approaches a modified cosine distribution.     

A Structural Analysis of Nerve Myelin

A structure analysis of the low-angle X-ray diffraction data from nerve myelin is described. The low-angle X-ray data are interpreted in terms of an electron density strip model which has five parameters, these refer to the dimensions of the membrane pair and their component electron densities. Three sets of low-angle X-ray data from peripheral nerve swollen in media of different electron densities are analyzed and membrane pair dimensions and component electron densities on an absolute scale are assigned. Membrane pair dimensions are given for a variety of peripheral nerve myelins and central nervous system myelins.     

A dynamic x-ray diffraction study of anesthesia action. Thickening of the myelin membrane by n-pentane.

The structural changes induced in the myelin sheath by n-pentane nerve impulse blockage were studied by small-angle X-ray diffraction using a linear position-sensitive detector. The results show that the thickness of the myelin period lattice increases from 170 to 180 A during n-pentane treatment.     

PROTEIN COMPOSITION OF AXONS and MYELIN FROM RAT and HUMAN PERIPHERAL NERVES

Abstract— Proteins of rat and human peripheral nerves were studied in whole nerve homogenates and in purified myelin and axonal preparations of peripheral nerve. Both myelin and axonal fractions were obtained from desheathed and minced nerve segments by flotation and sedimentation, respectively, in 0.85 m -sucrose following hypotonic treatment. The purity of myelin and axonal preparations was confirmed by electron microscopic examination of pelleted material. Nerve proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis at pH 8.3 and 7.4. Major protein bands of fresh whole nerve homogenates corresponded to polypeptide bands of either the purified myelin or axon preparations. The most prominent electrophoretic band in peripheral nerve was identified as a myelin glycoprotein with molecular weight of 27,000. The major polypeptides of axon preparations had molecular weights of 200,000, 150,000, 69,000, 55,000 and 27,000. The latter two proteins were believed to represent tubulin and residual major myelin protein, respectively. The three largest axonal polypeptides were believed to be derived from neurofilaments, which represented the predominant organelle of the purified axons. Collagen was also seen in whole nerve homogenates and in purified axons but could be distinguished by its metachromatic staining with Coomassie blue.     

Molecular Mechanics Simulations in Structure Analysis of Intercalate VOPO4·2CH3CH2OH

Molecular mechanics simulations using Cerius² combined with X-ray diffraction and supported with vibrational spectroscopy have been used to investigate the layered structure of vanadyl phosphate VOPO₄ intercalated with ethanol. This intercalated structure exhibits certain degree of disorder, which affects the diffraction diagram and obstructs the conventional structure analysis based on diffraction methods only. Present structure analysis is focused to the crystal packing in the interlayer space and layer stacking in the intercalate. The bilayer arrangement of ethanol molecules in the interlayer has been found, giving the basal spacing d = 13.21 Å, experimental d-value obtained from X-ray diffraction is 13.17 Å. One half from the total number of CH₃CH₂OH molecules is anchored with their oxygens to VOPO₄ layers to complete vanadium octahedra and their orientation is not very strictly defined. The second half of ethanoles is linked with hydrogen bridges to the anchored etahanoles and sometimes also to the layer oxygens. Positions and orientations of these unachored ethanoles with respect to VOPO₄ layers exhibit certain degree of disorder, resulting in the disorder in layer stacking. Molecular mechanics simulations revealed the character of this displacement disorder in layer stacking and enabled to determine the components of the displacement vector.     

Effects of ZnCl2 on membrane interactions in myelin of normal and shiverer mice

X-ray diffraction was used to record the effects of metal cations on the structure of peripheral nerve myelin. Acidic saline (pH 5.0) either with or without added metal cations caused myelin to swell by 10-20 A from its native period of 178 A. The X-ray patterns usually showed broad reflections, and higher orders were either weak or unobserved. With added ZnCl2, however, the swollen myelin gave diffraction patterns that retained sharp reflections to approx. 15 A spacing. Alkaline saline (pH 9.7) containing ZnCl2 produced a reduction of the myelin period by approx. 5 A which was at least twice as much as that produced by other metals. To examine the underlying chemical basis for these unique interactions of Zn2+ with myelin, we carried out parallel X-ray experiments on sciatic nerve from the shiverer mutant mouse, which lacks the major myelin basic proteins. Shiverer myelin responded like normal myelin to ZnCl2 in acidic saline; however, in alkaline saline shiverer myelin showed broadened X-ray reflections which indicated disordering of the regularity of the membrane arrays, and additional reflections were recorded which indicated lipid phase separation. This breakdown may come about by the binding of Zn2+ to negatively-charged lipids which could be more exposed due to the absence of myelin basic proteins. Electron density profiles were calculated on the assumption that, except for changes in their packing, the myelin membranes were minimally altered in structure. For both normal and shiverer myelins, treatments under acidic conditions resulted in swelling at the extracellular apposition and a slight narrowing of the cytoplasmic space. This swelling is likely due to adsorption of protons and divalent cations. Interaction between Zn2+ and myelin P0 glycoprotein could preserve an ordered arrangement of the apposed membrane surfaces. Alkaline saline containing ZnCl2 produced compaction at the cytoplasmic apposition in both normal and shiverer myelins possibly through interactions with a portion of P0 glycoprotein which extends into the cytoplasmic space between membranes.     

COMPARATIVE STUDIES ON THE MYELIN PROTEINS OF BOVINE PERIPHERAL NERVE AND SPINAL CORD

Abstract— (1) Two myelin fractions of bovine peripheral nerve and spinal cord have been studied comparatively. Cholesterol as well as cerebroside content per mg of protein in the peripheral nerve myelin was less than that in the spinal cord myelin, while no significant difference in the total phospholipid content was noted.
(2) The basic proteins in myelin fractions were quantitatively estimated by disc gel electrophoresis. Around one-fourth of the total myelin protein in the bovine peripheral nerve was a basic protein with a mobility of 1.07 relative to lysozyme by Reisfeld's disc gel electrophoresis.
(3) The myelin proteins in the peripheral nerve were less completely solubilized than those of the spinal cord by treatment with deoxycholate as well as by Triton-salt solution. The protein fractions obtained from the peripheral nerve myelin by techniques similar to that for obtaining the proteolipids from the spinal cord myelin, contained different types of protein.
(4) 2',3'-Cyclic nucleotide 3'-phosphohydrolase activity in the peripheral nerve myelin was only one tenth of that in the spinal cord myelin. The Triton-salt insoluble fraction showed remarkable high activity among subfractions of the spinal cord myelin.
(5) By immunological studies, it may be concluded that an antigenic substance for experimental allergic neuritis was localized in the peripheral nerve myelin, but not in its basic protein.     

Simulating focal demyelinating neuropathies: membrane property abnormalities

Membrane properties such as potentials (intracellular, extracellular, electrotonic) and axonal excitability indices (strength–duration and charge–duration curves, strength–duration time constants, rheobasic currents, recovery cycles) can now be measured in healthy subjects and patients with demyelinating neuropathies. They are regarded here in two cases of simultaneously reduced paranodal seal resistance and myelin lamellae in one to three consecutive internodes of human motor nerve fiber. The investigations are performed for 70 and 96% myelin reduction values. The first value is not sufficient to develop a conduction block, but the second leads to a block and the corresponding demyelinations are regarded as mild and severe. For both the mild and severe demyelinations, the paranodally internodally focally demyelinated cases (termed as PIFD1, PIFD2, and PIFD3, respectively, with one, two, and three demyelinated internodes) are simulated using our previous double-cable model of the fiber. The axon model consists of 30 nodes and 29 internodes. The membrane property abnormalities obtained can be observed in vivo in patients with demyelinating forms of Guillain-Barré syndrome (GBS) and multifocal motor neuropathy (MMN). The study confirms that focal demyelinations are specific indicators for acquired demyelinating neuropathies. Moreover, the following changes have been calculated in our previous papers: (1) uniform reduction of myelin thickness in all internodes (Stephanova et al. in Clin Neurophysiol 116: 1153–1158, 2005); (2) demyelination of all paranodal regions (Stephanova and Daskalova in Clin Neurophysiol 116: 1159–1166, 2005a); (3) simultaneous reduction of myelin thickness and paranodal demyelination in all internodes (Stephanova and Daskalova in Clin Neurophysiol 116: 2334–2341, 2005b); and (4) reduction of myelin thickness of up to three internodes (Stephanova et al., in J Biol Phys, 2006a,b, DOI: 10.1007/s10867-005-9001-9; DOI: 10.1007/s10867-006-9008-x). The mem- brane property abnormalities obtained in the homogenously demyelinated cases are quite different and abnormally greater than those in the case investigated here of simultaneous reduction in myelin thickness and paranodal demyelination of up to three internodes. Our previous and present results show that unless focal demyelination is severe enough to cause outright conduction block, changes are so slight as to be essentially indistinguishable from normal values. Consequently, the excitability-based approaches that have shown strong potential as diagnostic tools in systematically demyelinated conditions may not be useful in detecting mild focal demyelinations, independently of whether they are internodal, paranodal, or paranodal internodal.     

X-Ray Diffraction of Myelin Membrane: II. Determination of the Phase Angles of the Frog Sciatic Nerve by Heavy Atom Labeling and Calculation of the Electron Density Distribution of the Membrane

The phase signs of the five main X-ray reflections from normal frog sciatic nerve have been determined as all positive using a technique of labeling with very small amounts of heavy metal. The changes in intensity of the individual reflections were studied as a function of uptake of metal label by the membrane. The possible localization of the metal label was decided from computer-analogue studies and from Patterson calculations. These phases are different from those determined by previous workers using techniques of trial of the best set of phases, or a step model, to give the best fit of the combined intensity data of normal and swollen myelin membranes. The electron density map has been calculated using eight reflections and their experimentally determined phases. The map shows an inner low electron density region which is different from that shown by earlier calculations. The center of the low electron density region shows a small region of increased electron density. However, without fixing absolute electron density levels in the map, it is not yet possible to allocate regions of low electron density to pure lipid or lipoprotein. The map shows the two sides of the membranes to be different in molecular structure without significant water spaces between the membranes.     

Myelin Structure and Composition in Zebrafish

To establish a standard for genotype/phenotype studies on the myelin of zebrafish (Danio rerio), an organism increasingly popular as a model system for vertebrates, we have initiated a detailed characterization of the structure and biochemical composition of its myelinated central and peripheral nervous system (CNS; PNS) tissues. Myelin periods, determined by X-ray diffraction from whole, unfixed optic and lateral line nerves, were approximately 153 and approximately 162 Angstrom, respectively. In contrast with the lability of PNS myelin in higher vertebrates, zebrafish lateral line nerve myelin exhibited structural stability when exposed to substantial changes in pH and ionic strength. Neither optic nor lateral line nerves showed swelling at the cytoplasmic apposition in CaCl(2)-containing Ringer's solution, in contrast with nerves from other teleost and elasmobranch fishes. Zebrafish optic nerve showed greater stability against changes in NaCl and CaCl(2) than lateral line nerve. The nerves from zebrafish having mutations in the gene for myelin basic protein (mbpAla2Thr and mbpAsp25Val) showed similar myelin periods as the wildtype (WT), but gave approximately 20% less compact myelin. Analysis of proteins by SDS-PAGE and Western blotting identified in both CNS and PNS of WT zebrafish two orthologues of myelin P0 glycoprotein that have been characterized extensively in trout--intermediate protein 1 (24 kDa) and intermediate protein 2 (28 kDa). Treatment with endoglycosidase-F demonstrated a carbohydrate moiety of approximately 7 kDa, which is nearly threefold larger than for higher vertebrates. Thin-layer chromatography for lipids revealed a similar composition as for other teleosts. Taken together, these data will serve as a baseline for detecting changes in the structure and/or amount of myelin resulting from mutations in myelin-related genes or from exogenous, potentially cytotoxic compounds that could affect myelin formation or stability.