Neurofilaments from ox spinal nerves. Isolation, disassembly, reassembly and cross-linking properties.

An isolation procedure for neurofilaments from ox spinal nerves is described where the triplet polypeptides (which have molecular weights of 205 000, 158 000 and 72 000) constitute more than 80% of the preparation. Soon after purification, the neurofilaments form a gel that is stable for many weeks. The purified neurofilaments disassemble in low-salt buffers at pH greater than 7.0 into soluble particles that contain all of the triplet polypeptides. Greater than 90% of the protein can reassemble to form filaments. The thiol-containing residues in the filaments can be cross-linked. Analyses of the complexes formed show that in the filament the 205 000-mol.wt. components are arranged to that they can be cross-linked to themselves and to the 158 000-mol.wt. polypeptides, and that the 72 000-mol.wt. components are arranged so that their thiol groups can be cross-linked together.     

The polypeptides of isolated brain 10nm filaments and their association with polymerized tubulin.

Brain 10 nm filaments were isolated from bovine, rabbit and rat brains by a modification of an existing procedure. The overall polypeptide composition of these preparations was similar to that previously reported for brain neurofilaments. In addition to the major polypeptide component, which has mol. wt. approx. 50 000, three other polypeptides with chain mol. wts. approx. 210 000, 155 000 and 70 000, which correspond to peripheral-nerve neurofilament polypeptides, were consistently found to be present. The mol. wt.-50 000 species was found to be heterogeneous and may contain a component derived from the mol. wt. 70 000 polypeptide. The three higher-molecular-weight polypeptides did not appear to be obviously homologous or to be homologous with myosin or Myxicola neurofilament polypeptides. These same three higher-molecular-weight components were shown to be identical with the polypeptides probably responsible for the 10 nm filaments formed during the early cycles of the tubulin-purification protocol.     

The proteolytic digestion of ox neurofilaments with trypsin and alpha-chymotrypsin.

Brief digestion of ox neurofilaments with trypsin liberates fragments that are soluble and have molecular weights ranging from 164 000 to 97 000. Peptide fingerprinting indicates that these regions, termed the tryptic head-regions, arise from the 205 000- and 158 000-mol.wt. components of the triplet. The remains of the parent polypeptides sediment with normal filaments and have been termed tail-regions. Digestion of neurofilaments with chymotrypsin also liberates soluble fragments (chymotryptic head-regions) but these have mol.wts. 171 000 and 119 000, though they too originate from the higher-molecular-weight triplet polypeptides. Tryptic and chymotryptic head-regions have extensive homology, and a low (less than or equal to 20%) helix content. Electron microscopy shows that chymotryptic digestion rapidly reduces the length of filaments, probably because this enzyme preferentially attacks the 72 000-mol.wt. polypeptide. In contrast, brief digestion with trypsin does not reduce filament length even though more than 90% of the two higher-molecular-weight components have been cleaved. These results indicate that the backbone of native filaments is formed from the 72 000-mol.wt. polypeptide together with the tail-regions from the 205 000- and 158 000-mol.wt. polypeptides. The corresponding head-regions of these components, which can represent nearly 75% of each molecule, are not necessary for preserving the backbone of native neurofilaments and are therefore good candidates for being the side arms that connect these filaments in nerve cells.     

Chemical cross-linking indicates a staggered and antiparallel protofilament of desmin intermediate filaments and characterizes one higher-level complex between protofilaments.

Tetrameric rods, protofilaments and assembled filaments of desmin, the intermediate filament protein of muscle, have been chemically cross-linked with the lysine specific cross-linkers EGS [ethylene glycol bis(succinimidylsuccinate), 1.61 nm span] and bis(sulfosuccinimidyl) suberate (1.14 nm span). One bis(sulfosuccinimidyl)suberate and two EGS cross-links were isolated from the rod and characterized. They show that the two coiled coils in the rod tetramer are staggered by approximately 15-20 nm and strongly indicate an antiparallel arrangement in which the inner overlapping part of the rod is formed by the amino-terminal helices 1A, 1B and 2A. Both EGS cross-links identified in the rod were also isolated from cross-linked filaments. The isolated rod, therefore, represents a complex also present in identical, or very similar form in protofilaments and in assembled filaments. Cross-linked filaments yielded a third EGS cross-link that must have been formed between neighboring protofilaments. It connects the highly conserved carboxy-terminus of helix 2B of the first protofilament to the overlap region formed by helices 1A and 2A of the second protofilament. The restrictions posed by these cross-links on current filament models are discussed.     

Organization of mammalian neurofilament polypeptides within the neuronal cytoskeleton

Neurofilaments in the axons of mammalian spinal cord neurons are extensively cross-linked; consequently, the filaments and their cross- bridges compose a three-dimensional lattice. We have used antibody decoration in situ combined with tissue preparation by the quick- freeze, deep-etch technique to locate three neurofilament polypeptides (195, 145, and 73 Kd) within this lattice. When antibodies against each polypeptide were incubated with detergent-extracted, formaldehyde-fixed samples of rabbit spinal cord, each antibody assumed a characteristic distribution: anti-73-Kd decorated the neurofilament core uniformly, but not the cross-bridges; anti-145-Kd also decorated the core, but less uniformly; sometimes the anti-145-Kd antibodies were located over the bases of cross-bridges. In contrast, anti-195-Kd primarily decorated the cross-bridges between the neurofilaments. These observations show that the 73-Kd polypeptide is a component of the central core of neurofilaments, and that the 195-Kd polypeptide is a component of the inter-neurofilamentous cross-bridges. It is consistent with this conclusion that we found few cross-bridges between neurofilaments in the optic nerves of neonatal rabbits during a developmental period when the ratio of 195 to 73 or 145-Kd polypeptides is much lower than in adults. The ratio of 195-Kd polypeptide to the other two neurofilament polypeptides also appeared much lower in the cell bodies and dendrites than in axons of adult spinal cord neurons, when the dispositions of the three polypeptides were studied by immunofluorescence experiments. The cell bodies apparently contain neurofilaments composed primarily of 145- and 73-Kd polypeptides, because we observed antibody decoration of individual neurofilaments in the cell bodies with anti-73- and -145-Kd, but not with anti-195-Kd. We conclude that the 195-Kd polypeptide participates in a cross-linking function, and that this function is, at least in certain neurons, most prevalent in the mature axon.     

The structure, biochemical properties, and immunogenicity of neurofilament peripheral regions are determined by phosphorylation state

Treatment of freshly isolated, bovine neurofilaments with Escherichia coli alkaline phosphatase removes over 90% of the phosphate groups from serine residues of the Mr 200,000 and 150,000 polypeptide components (NF200 and NF150). Dephosphorylated NF200 and NF150 remain associated with filaments, but migrate in sodium dodecyl sulfate gels with reduced apparent molecular weights. Unusual migration appears to be due to modification at regions of these polypeptides that are peripheral to the neurofilament backbone as defined by limited chymotryptic digestion. Over 90 monoclonal antibodies recognizing epitopes located within the peripheral domain of native NF200 all show reduced affinity for dephosphorylated NF200. A single monoclonal antibody binds within the filament-associated domain of NF200 and its recognition of NF200 is unaffected upon treatment of neurofilaments with phosphatase. Around 50% of our monoclonal antibodies that bind NF150 monospecifically and at epitopes within its peripheral domain have reduced affinities for NF150 from phosphatase-treated filaments, while the remaining 50% bind native and dephosphorylated NF150 equally well. The smallest neurofilament component (NF70) contains few phosphate groups, most of which remain after treatment of neurofilaments with phosphatase. The resulting form of NF70 migrates normally in gels and its recognition by antibodies is unchanged. We conclude that phosphorylation modifies the structure of the two larger neurofilament polypeptides along domains that are peripheral to the filamentous backbone and that these effects are more pronounced for NF200 than for NF150.     

Conformational states of the (Na+ + K+)-transporting ATPase. Formation of 240 000-Mr and 116 000-Mr polypeptides in the presence of a bifunctional thiol probe.

Interpeptide cross-linking of alpha-subunits with concomitant loss of Na+ + K+-transporting ATPase (Na+, K+-ATPase) activity was found when the purified lamb kidney enzyme was treated with the bifunctional thiol reagent 4,4'-difluoro-3,3'-dinitrodiphenyl sulphone (F2DNS). Several forms of the enzyme could be clearly distinguished: one binding ATP (non-phosphorylated enzyme, E1 X ATP), a phosphorylated form (E2-P) and a phosphoenzyme-ouabain complex (E2P X ouabain). A polypeptide of approx. Mr 240 000 and probable alpha 2 composition comprised up to 5-20% of the total polypeptides after reaction of the lamb kidney Na+, K+-ATPase with F2DNS. The amount of this polypeptide formed was related to the conformational state of the enzyme. The presence of adenine nucleotide greatly diminished the amount of 240 000-Mr polypeptide formed and provides evidence for an enzyme-adenine-nucleotide complex under conditions where the enzyme is not phosphorylated. F2DNS reacted with the enzyme in the presence of Mg2+, Pi and ouabain to form a new polypeptide with an approx. Mr of 116 000, and comprised 23% of the total, whereas the 240 000-Mr polypeptide comprised 9% of the total. This suggests that the 116 000-Mr polypeptide is a characteristic marker of the E2P X ouabain complex. By using specific antibodies it was established that both the 240 000- and 116 000-Mr polypeptides contained alpha-, but not beta-, subunits of the Na+, K+-ATPase.     

Fibrillation of human insulin A and B chains

Human insulin, which consists of disulfide cross-linked A and B polypeptide chains, readily forms amyloid fibrils under slightly destabilizing conditions. We examined whether the isolated A and B chain peptides of human insulin would form fibrils at neutral and acidic pH. Although insulin exhibits a pH-dependent lag phase in fibrillation, the A chain formed fibrils without a lag at both pHs. In contrast, the B chain exhibited complex concentration-dependent fibrillation behavior at acidic pH. At higher concentrations, e.g., >0.2 mg/mL, the B chains preferentially and rapidly formed stable protofilaments rather than mature fibrils upon incubation at 37 degrees C. Surprisingly, these protofilaments did not convert into mature fibrils. At lower B chain concentrations, however, mature fibrils were formed. The explanation for the concentration dependence of B chain fibrillation is as follows. The B chains exist as soluble oligomers at acidic pH, have a beta-sheet rich conformation as determined by CD, and bind ANS strongly, and these oligomers rapidly form dead-end protofilaments. However, under conditions in which the B chain monomer is present, such as low B chain concentration (<0.2 mg/mL) or in the presence of low concentrations of GuHCl, which dissociates the soluble oligomers, mature fibrils were formed. Thus, both A and B chain peptides can form amyloid fibrils, and both are likely to be involved in the interactions leading to the fibrillation of intact insulin.     

Intermediate filaments in nervous tissues

Intermediate filaments have been isolated from rabbit intradural spinal nerve roots by the axonal flotation method. This method was modified to avoid exposure of axons to low ionic strength medium. The purified filaments are morphologically 75-80 percent pure. The gel electrophoretogram shows four major bands migrating at 200,000, 145,000, 68,000, and 60,000 daltons, respectively. A similar preparation from rabbit brain shows four major polypeptides with mol wt of 200,000 145,000, 68,000, and 51,000 daltons. These results indicate that the neurofilament is composed of a triplet of polypepetides with mol wt of 200,000, 145,000, and 68,000 daltons. The 51,000-dalton band that appears in brain filament preparations as the major polypeptide seems to be of glial origin. The significance of the 60,000- dalton band in the nerve root filament preparation is unclear at this time. Antibodies raised against two of the triplet proteins isolated from calf brain localize by immunofluorescence to neurons in central and peripheral nerve. On the other hand, an antibody to the 51,000-dalton polypeptide gives only glial staining in the brain, and very weak peripheral nerve staining. Prolonged exposure of axons to low ionic strength medium solubilizes almost all of the triplet polypeptides, leaving behind only the 51,000- dalton component. This would indicate that the neurofilament is soluble at low ionic strength, whereas the glial filament is not. These results indicate that neurofilaments and glial filaments are composed of different polypeptides and have different solubility characteristics.     

The cross-linking of rabbit skeletal muscle sarcoplasmic reticulum protein.

Sarcoplasmic reticulum proteins have been cross-linked in situ with two reagents, the disulphide-bridged bifunctional imido ester, dimethyl-3,3'-dithiobispropionimidate dihydrochloride and the mild oxidant cupric phenanthroline. Analysis of proteins so cross-linked by electrophoresis on agarose/acrylamide gels reveals that a series of new polypeptides, up to a molecular weight of 900 000, are formed. These have molecular weights which are multiples of 100 000. Further analysis of samples by electrophoresis in a second dimensions containing a reducing agent revealed the monomeric polypeptides from which the cross-linked polypeptides were formed. With dimethyl 3,3'-dithiobispropionimidate dihydrochloride homopolymers of the Ca2+-stimulated ATPase, calsequestrin and/or calcium binding protein were formed. With cupric phenanthroline only the Ca2+-stimulated ATPase was involved in polymer formation. It has been confirmed on another gel system that these two proteins which are involved in Ca2+ binding are not cross-linked intermolecularly with this latter reagent. We conclude that the 100 000 dalton Ca2+-stimulated ATPase polypeptides are within 2 A of each other in the membrane while calsequestrin and/or calcium binding protein are within 11 A of each other. Although there appears to be no limit to the extent of cross-linking of any of these polypeptides there is not indication of heteropolymer associations between them.     

Organization of synaptic junction proteins

Most of the polypeptides of isolated brain synaptic junction preparations are cross-linked by disulfide bonds; these bonds are readily reformed following reduction by β-mercaptoethanol, suggesting that other, non-covalent interactions may hold the polypeptides in close contact. When synaptic junctions were treated with β-mercaptoethanol in conjunction with a large variety of reagents known to disrupt certain types of non-covalent bonds, however, the polypeptides could still be cross-linked. Furthermore, virtually all of these species remained associated with β-mercaptoethanol-reduced membrane in the presence of 0.05 N NaOH or 0.5% Triton X-100, although each of these solvents extracts large amounts of protein from extra-junctional membrane, which has a composition apparently similar to that of synaptic junctions.These results indicate that any non-covalent interactions existing among synaptic junction proteins are inaccessible to treatments at the surface of the membrane, being located within the lipid bilayer or perhaps at points of contact with sub-membranous arrays such as the post-synaptic density. Under special conditions, the polypeptides of extra-junctional membrane can also be induced to form disulfide cross-links among one another, and these bonds can likewise be rapidly reformed following reduction, giving this membrane properties similar to that of the junction. This suggests a model by which stabilized junctional membrane may be formed from fluid extra-junctional membrane during synaptogenesis.     

Electron microscope study on human ceruloplasmin.

Electron microscopy of human ceruloplasmin (CP) molecules revealed a few distinctive types of particle images. Analysis of these images allows to propose a tentative model for CP: six "subunits" (which we call domains) not much different in size are arranged with 32 point group pseudosymmetry. The determination of the number of polypeptides arising at the spontaneous specific proteolytic fragmentation of CP and their molecular weights conform with this assumption. The electrophoretic studies of the CP samples prepared both with and without potent proteolytic inhibitor, PMSF, revealed that CP is a single-chain protein with molecular weight of 130 000. Isolated and stored without PMSF the polypeptide chain of CP undergoes specific proteolytic cleavage which results in the appearance of polypeptides with molecular weights of 16 000, 48 000, and 64 000. The latter two polypeptides degradate to about two- and three-fold decreased molecular weights fragments, respectively. Therefore, the single polypeptide chain of CP contains at least five peptide bonds which are particularly susceptible to proteolytic attack and which connect six principal segments of the chain. The hydrolysis of these bonds results in liberation of the six fragments which were integrated in the enzymatically active globule of CP.     

Antibody decoration of neurofilaments

We have decorated neurofilaments with antibodies against three polypeptides (designated here as H [mol wt = 195,000], 45[mol wt = 145,000], and 46[mol wt = 73,000]) in an effort to understand the arrangement of these polypeptides within neurofilaments. The three polypeptides were purified and antibodies were raised against each. The cross-reactivity of the antibodies suggested that each polypeptide contains both shared and unique antigenic determinants. The differential reactivities of each antibody preparation were enhanced by adsorption with the two heterologous polypeptides, and the resulting preparations were used to decorate purified neurofilaments, which were then negatively stained and examined in an electron microscope. The appearance of the antibody-decorated structures led to the following conclusions: All three polypeptides are physically associated with the same neurofilament. However, the disposition of H and 46 within a filament is different; 46 antigens appear to be associated with a "central core" of the filament, whereas H antigens compose a structure more loosely and peripherally attached to the central core and periodically arranged along its axis. The antibody-decorated H- containing structure assumes variable configurations; in some cases it appears asa bridge connecting two filaments; in other cases it appears as a helix wrapping the central core with a period of approximately 1,000 A and an apparent unit length of approximately 1.5 periods. These configurations suggest several functional implications, including the possibility that H is a component of the cross-bridges observed between filaments in situ. We also note that the central core-helix relationship could be used in the design of an intracellular transport motor.     

Ultrastructural organization of amyloid fibrils by atomic force microscopy

Atomic force microscopy has been employed to investigate the structural organization of amyloid fibrils produced in vitro from three very different polypeptide sequences. The systems investigated are a 10-residue peptide derived from the sequence of transthyretin, the 90-residue SH3 domain of bovine phosphatidylinositol-3'-kinase, and human wild-type lysozyme, a 130-residue protein containing four disulfide bridges. The results demonstrate distinct similarities between the structures formed by the different classes of fibrils despite the contrasting nature of the polypeptide species involved. SH3 and lysozyme fibrils consist typically of four protofilaments, exhibiting a left-handed twist along the fibril axis. The substructure of TTR(10-19) fibrils is not resolved by atomic force microscopy and their uniform appearance is suggestive of a regular self-association of very thin filaments. We propose that the exact number and orientation of protofilaments within amyloid fibrils is dictated by packing of the regions of the polypeptide chains that are not directly involved in formation of the cross-beta core of the fibrils. The results obtained for these proteins, none of which is directly associated with any human disease, are closely similar to those of disease-related amyloid fibrils, supporting the concept that amyloid is a generic structure of polypeptide chains. The detailed architecture of an individual fibril, however, depends on the manner in which the protofilaments assemble into the fibrillar structure, which in turn is dependent on the sequence of the polypeptide and the conditions under which the fibril is formed.     

Polypeptide composition of purified QH2:cytochrome c oxidoreductase from beef-heart mitochondria

1. The polypeptide composition of purified QH2: cytochrome c oxidoreductase prepared by three different methods from beef-heart mitochondria has been determined. Polyacrylamide gel electrophoresis in the presence of dodecyl sulphate resolves eight intrinsic polypeptide bands; when, in addition, 8 M urea is present and a more highly cross-linked gel is used, the smallest polypeptide band is resolved into three different bands. 2. The identity of several polypeptide bands has been established by fractionation. The two heaviest polypeptides (bands 1 and 2) represent the so-called core proteins, band 3 the hemoprotein of cytochrome b, band 4 the hemoprotein of cytochrome c1, band 5 and Rieske Fe-S protein, band 6 a polypeptide associated with cytochrome c1 and identified with the so-called oxidation factor, and band 7 a polypeptide peptide associated with cytochrome b. 3. The validity of molecular weight estimate for the polypeptides of the enzyme based on their mobility on dodecyl sulphate gels has been examined. The polypeptides of bands 1, 2 and 3 showed anomalous migration rates. The molecular weights of the other polypeptides have been estimated from their relative mobilities on either dodecyl sulphate gels or 8 M urea-dodecyl sulphate gels as 29 000, 24 000, 12 000, 8000, 6000, 5000 and 4000, respectively. 4. The stoicheiometry of the different polypeptides in the intact complex was determined using separate staining factors for the individual polypeptide band.     

Characterization of polypeptide chains of epidermal prekeratin and reconstituted filaments

Prekeratin was isolated from bovine snout epidermis with 0.1 M citric acid/sodium citrate buffer, pH 2.6 (buffer A). Filaments, 6.0-9.0 nm wide, were produced by dialysis against low ionic strength buffer A or by dissociating prekeratin in 8 M urea solution followed by dialysis against 0.005 M Tris-HCl buffer, pH 8.0. The polypeptide composition of both prekeratin and filaments was studied by four different SDS-polyacrylamide gel electrophoresis methods. The best resolution was obtained by Laemmli's technique in which both prekeratin and filaments were separated into three major and seven distinct minor bands of polypeptides. The major ones comprise approx. 70% of total polypeptides and their estimated molecular weights are 68 000, 54 000, and 50 000. The molecular weight of minor ones is in decreasing order 65 000, 63 000, 61 000, 58 000, 47 000, 44 000 and 42 000. It is proposed that the major polypeptides form the backbone structure of epidermal filaments and the minor polypeptides play a role in its stabilization.     

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.     

Quaternary structure of (Na+ + K+)-dependent adenosine triphosphatase.

(Na+ + K+)-dependent adenosine triphosphatase (NaK-ATPase) consists of two polypeptide chains, a large polypeptide with a molecular weight of about 100,000, and a sialoglycoprotein with a molecular weight of about 40,000. Cross-linking of purified NaK-ATPase with the (o-phenanthroline)2-cupric ion complex (CP) results in the reversible formation of dimers, trimers, tetramers, and pentamers of the large polypeptide and loss of NaK-ATPase activity. ATPase activity is partially recovered if NaK-ATPase is incubated with beta-mercaptoethanol after treatment with CP. In contrast to these results, if NaK-ATPase is cross-linked in crude canine kidney microsomes, only a dimer of the large polypeptide is formed. No cross-linking of the sialoglycoprotein to the large polypeptide is detected when NaK-ATPase is cross-linked in purified form. However, when NaK-ATPase is reacted with CP in either purified or microsomal form, the sialoglycoprotein cross-links to itself yielding a high molecular weight aggregate. The results show that the functional subunit structure of NaK-ATPase consists of at least two large polypeptides.     

Chemical cross-linking studies of the light-harvesting pigment-protein complex B800-850 of Rhodopseudomonas capsulata

The spatial relationship of the three polypeptides contained in the B800-850 light-harvesting complex of Rhodopseudomonas capsulata has been studied with chemical cross-linking of crude membrane preparations of the phototrophic negative mutant strain Y5. Samples were cross-linked with the cleavable reagent dithiobis (succinimidyl propionate) (1.1 nm chain length) and analyzed by two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. Membranes labelled with 14C-amino acids were used to determine the compositional stoichiometry of cross-linked products. It was found that the two polypeptides with an apparent Mr of 8000 and 10 000, respectively, that are associated with the pigments bacteriochlorophyll a and carotenoid form homooligomers as well as heterooligomers. The data support the idea that these polypeptides are closely arranged in clusters probably containing at least four of each species. The third subunit with an Mr of 14 000, which is not associated with pigments, was found to be most susceptible to cross-linking and formed homooligomers but no heterooligomers with the other two subunits, and is thus likely to be loosely attached to these clusters. Comparative studies with the phototrophic positive wild type strain indicated that the results found with the phototrophic negative mutant strain Y5 reflect the organization of the B800-850 complex in the membrane of Rhodopseudomonas capsulata. Studies with the isolated B800-850 complex revealed that the sterical arrangement of the three constituent polypeptides in dodecyl dimethylamine-N-oxide containing solutions must be very similar to that in the membrane.     

Isolation and characterization of two polypeptides that form intermediate filaments in bovine esophageal epithelium

Cells in the stratified squamous epithelium of bovine esophagus contain abundant tonofilaments measuring 6-10 nm in diameter. Two polypeptides, extracted from esophageal epithelium with 0.05 M Tris, pH 7.4, containing 8 M urea and 25 mM beta-mercaptoethanol, comprise 35% of the total extractable protein. These polypeptides have apparent molecular weights of 46,000 and 56,000 daltons and are rich in glutamic acid- glutamine, glycine, and serine. Each polypeptide can be partially purified by DEAE-cellulose chromatography. Mixtures of the purified polypeptides from filaments in vitro that measured 6-10 nm in diameter. Neither polypeptide formed filaments by itself. Filaments formed in vitro give an alpha-keratin type x-ray diffraction pattern.. These data indicate that the tonofilaments in esophageal epithelium are formed primarily from these two polypeptides.