X-ray diffraction patterns from microtubules and neurofilaments in axoplasm.

Freshly extracted axoplasm from giant axons of the marine fan worm Myxicola infundibulum and the squid Loligo can be pulled into fibres that contain highly oriented cytoskeletal elements suitable for X-ray diffraction. A major advantage of studying axoplasmic components by this technique is that it allows essentially native structures and their interactions to be examined. We describe here the analyses of the X-ray diffraction patterns. We show that in Myxicola the pattern can be explained by diffraction from both neurofilaments and microtubules, whilst in Loligo the pattern arises solely from microtubules. At low resolution, X-ray patterns obtained from dehydrated axoplasmic microtubules resemble strongly the Fourier transforms generated from electron micrographs of negatively stained specimens. Hydration of axoplasmic fibres produced reversible changes in the X-ray pattern intensities, although the layer-line positions were unaltered. On the 4 nm layer-line, the intensity of the J3 reflection was dramatically reduced on hydration, though its position was unchanged. Hydration also affected the J10/J16 reflections, which increased in intensity, though here again the positions of the peaks were little altered. The X-ray patterns from our hydrated fibres resemble those produced by others from fibres of purified microtubules, though in our patterns contrast is generated towards the centre of the wall. We interpret our findings in the light of current ideas about microtubule structure as determined by X-ray diffraction and electron microscope techniques.

Structural similarities and differences amongst neurofilaments.

Neurofilaments purified from cat, ox, Loligo and Myxicola nerve fibres are composed of different numbers of polypeptides with different molecular weights. Mammalian neurofilaments also differ from those of marine invertebrates by being about 20% larger in diameter. Despite the differences, X-ray diffraction patterns from all the neurofilaments indicate a common alpha-helical content with alpha-helices arranged in coiled-coils. The patterns from Myxicola neurofilaments also indicate a long-range periodicity along the length of these filaments which is of the order of 25.2 nm.

The location of phosphorylation sites and Ca2+-dependent proteolytic cleavage sites on the major neurofilament polypeptides from Myxicola infundibulum.

1. When axoplasm is incubated with [32P]Pi the main phosphorylated components are the neurofilament polypeptides. 2. Activation with Ca2+ of the proteinase present in axoplasm causes degradation of these neurofilaments and the peptides produced by this reaction have been analysed by fingerprinting. 3. Fingerprinting shows that initially the Ca2+-activated proteinase cleaves the neurofilament polypeptides at three major sites producing polypeptides with mol.wts. 70,000, 50,000 and 47,000. 4. These polypeptides sediment with filaments, originate from the tail-region of the molecule and contain a little radioactive label. 5. As these polypeptides are produced, other polypeptides that come from the head-region of the molecule are liberated as soluble products that contain the bulk of the radioactivity. 6. Fingerprinting therefore shows that at least two regions on the molecule are phosphorylated and that the major one is located towards the head-end of the polypeptides.

The polypeptide composition of axoplasm and of neurofilaments from the marine worm Myxicola infundibulum.

1. Axoplasm from Myxicola contains two major polypeptides associated with neurofilaments, together with actin, tubulin and many minor polypeptide components. 2. Some of the minor polypeptides with molecular weights between 140,000 and 50,000 purify with neurofilaments under a variety of conditions and they appear to represent an integral part of the filament structure. 3. Peptide fingerprinting shows that the two major neurofilament polypeptides are almost identical. The fingerprint patterns from these major polypeptides share features with those obtained from the minor components. 4. Peptide fingerprinting has enabled us to propose a scheme for the main sites at which papain cleaves the major neurofilament polypeptides. In addition fingerprinting indicates how the minor components are related to the major polypeptides. 5. It is suggested that many of the minor neurofilament polypeptides could arise by proteolysis in vivo.

Axoplasm architecture and physical properties as seen in the Myxicola giant axon.

A technique is described for extracting axoplasm from the giant axon of a marine worm, Myxicola infundibulum. The operation can be completed in 10 sec. 2. Axoplasm is pulled from the axon of a living worm as a long, clear cylinder, up to 35 cm long and 70 mg wet weight. The worm regenerates a new giant axon in about 4 months. 3. Myxicola axoplasm is a gel, 87% water, held together by protein neurofilaments. It contains small amounts of mitochondria and vesicles, but no detectable microtubules. 4. The internal structure of the gel is superficially similar to that of yarn. Closer inspection with light and electron microscopy, and X-ray diffraction, show it to be organized in a hierarchy of helical forms. Squid giant axons have a similar structure. 5. Initial estimates of the bulk physical properties of extracted Myxicola axoplasm give: breaking strength, 1400 g/cm2; specific gravity, 1-05 g/cm3; birefringence, 1-6 X 10(-4); index of refraction, 1-351; resistivity, 57 omega cm. These average values are shown to be compatible with the observed structure and composition. 6. Despite its mechanical strength, the axoplasm gel is so hydrated that Na+, K+ and homarine diffuse through it at rates approaching those in free solution. Fewer than about 5% of each of these ions are tightly bound to the gel. 7. It is argued that (a) the structure and physical properties of Myxicola axoplasm are representative of those in other axons, (b) the compound helix architecture results from twist of parallel, cross-linked fibrous proteins, and (c) this sturcture serves as a flexible internal skeleton for nerve cell processes.

Axoplasm chemical composition in Myxicola and solubility properties of its structural proteins.

The chemical composition of axoplasm extracted from the giant axon of Myxicola infundibulum has been analysed, and some of the factors which disperse its gel structure have been identified. 2. The axoplasm contains about 3-6% protein, and 0-12% lipid. It is isosmotic with sea water and has a pH near 7-0. 3. Inorganic ions in extracted axoplasm include: Na+, 13m-mole/kg wet wtl; K+, 280; Cl-, 24; Ca2+, 0-3; Mg2+, 3. 4. Free organic ions in axoplasm include: gly, 180 m-mole/kg wet st.; cysteic acid, 120; asp, 75; glu, 10; ala, 7; tau, 5; thr, 2; gln and ser, trace; homarine, 63; isethionate, 0. 5. The gel structure is dispersed by solutions containing 1--10 mM-Ca2+, because this ion activates an endogenous protease. The gel can also be dispersed without proteilysis by solutions containing 0-5 M-KCl, or 0-5 M guanidine hydrochloride, or 3-5 M urea, all of which break down neurofilaments. 6. It is argued that many aspects of the composition and dispersal properties of Myxicola axoplasm are similar to those in other axons.

Sodium transport by perfused giant axons of Loligo.

The sodium efflux from perfused squid giant axons has been studied using radioactive sodium, and the sufficient conditions for the maintenance of a potassium- and ouabain-sensitive sodium efflux have been established. The following were found.1. Axons extruded and then perfused with their own axoplasm had a sodium efflux which was sensitive to cyanide, potassium and ouabain and was thus similar to the efflux from intact axons.2. A method for replacing natural axoplasm into fibres previously perfused with artificial axoplasm was developed and used to establish an artificial perfusate that was not irreversibly toxic.3. Short perfusion (5 min) with a variety of artificial perfusates was then found to give fibres which had potassium- and ouabain-sensitive sodium effluxes when ATP was present in the perfusate.4. In the absence of ATP the sodium efflux was small and relatively insensitive to both external potassium and to ouabain.5. With ADP in the perfusate, fibres gave a sodium efflux which was ouabain-sensitive but was little affected by the removal of external potassium from the sodium-rich sea water bathing the fibres.6. The perfused fibres differed from intact fibres in having large ouabain-insensitive sodium effluxes.7. After very long perfusions (40-90 min), with the simple media containing ATP, the rate constant for sodium efflux from the fibres tended to be large and was relatively insensitive to potassium or to ouabain.8. Fibres refilled with natural axoplasm after long perfusion showed increased sensitivity to external potassium; refilled with dispersed axoplasm the sodium efflux tended to become very large.9. After very long perfusions with artificial axoplasms containing ATP, a potassium- and ouabain-sensitive sodium efflux was found to persist provided that dextran was present and the total osmotic pressure and the hydrostatic pressure of the perfusate were controlled. Under these conditions the sodium efflux resembled that from briefly perfused fibres. The necessary and sufficient conditions for the maintenance of sodium transport by perfused giant axons are discussed.