The structural relation between intermediate filament proteins in living cells and the alpha-keratins of sheep wool.

Although not complete, the available sequence data on smooth muscle desmin, a prototype of 10 nm filaments present in living vertebrate cells, and two wool alpha-keratin components indicate a common structural motif . A similarly sized rod-like middle domain based mainly on alpha-helices probably able to form coiled-coils is flanked by differently sized terminal domains of non-alpha-helical nature. Within the middle domain there seem to be at least two regions where wool keratins and 10 nm filament proteins show a noticeable degree of sequence homology. In general, however, the proteins have diverged to an astonishing degree. Although the analysis seems to support, in general terms, a separation of the rod into two nearly equally long coiled-coils it raises doubts about additional aspects of current models of 10 nm filament organization. We propose that the terminal domains are directly involved in filament assembly making this process permanent in wool alpha-keratins because of the many disulfide bonds present in these regions. The 10 nm filaments of most living cells seem to avoid this frozen state and lack a similar wealth of cysteine residues.     

Antiparallel orientation of the two double-stranded coiled-coils in the tetrameric protofilament unit of intermediate filaments

The chymotryptically excised middle domain of desmin slightly exceeds in length the structurally conserved alpha-helical middle region documented in all intermediate filament proteins by amino acid sequence data. This rod domain is a protofilament derivative with a tetrameric organization, thus indicating the presence of two double-stranded coiled-coil units. We now show by immunoelectron microscopy that Fab fragments of a desmin-specific monoclonal antibody mixed with the rod lead to dumb-bell-shaped structures. The tagging of both ends together with the length of the rod (48 nm) argues for an antiparallel orientation of the two coiled-coils without a major stagger. This information combined with the lateral 21 nm periodicity of the intermediate filament observed by us and others leads to a structural hypothesis similar to those entertained from X-ray data on wool alpha-keratins, although here an antiparallel tetrameric unit of some 60 to 66 nm is invoked, which has never been isolated. The structure that we discuss allows for the existence of both the particles, and the antibody experiment strongly supports the antiparallel orientation postulated in both approaches. The tube-like filament structure proposed for the intermediate filament agrees with recent mass per unit length measurements and allows for two minor classes of intermediate filaments with different values in this property as also found experimentally.     

Hybrid character of a large neurofilament protein (NF-M): intermediate filament type sequence followed by a long and acidic carboxy-terminal extension

The sequence of the amino-terminal 436 residues of porcine neurofilament component NF-M (apparent mol. wt. in gel electrophoresis 160 kd), one of the two high mol. wt. components of mammalian neurofilaments, reveals the typical structural organization of an intermediate filament (IF) protein of the non-epithelial type. A non-alpha-helical arginine-rich headpiece with multiple beta-turns (residues 1-98) precedes a highly alpha-helical rod domain able to form double-stranded coiled-coils (residues 99-412) and a non-alpha-helical tailpiece array starting at residue 413. All extra mass of NF-M forms, as a carboxy-terminal tailpiece extension of approximately 500 residues, an autonomous domain of unique composition. Limited sequence data in the amino-terminal region of this domain document a lysine- and particularly glutamic acid-rich array somewhat reminiscent of the much shorter tailpiece extension of NF-L (apparent mol. wt. 68 kd), the major neurofilament protein. NF-M is therefore a true intermediate filament protein co-polymerized with NF-L via presumptive coiled-coil type interactions and not a peripherally bound associated protein of a filament backbone built exclusively from NF-L. Along the structurally conserved coiled-coil domains the two neurofilament proteins show only approximately 65% sequence identity, a value similar to that seen when NF-L and NF-M are compared with mesenchymal vimentin. The highly charged and acidic tailpiece extensions of all triplet proteins particularly rich in glutamic acid seem unique to the neurofilament type of IFs. They could form extra-filamentous scaffolds suitable for interactions with other neuronal components.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neurofilament architecture combines structural principles of intermediate filaments with carboxy-terminal extensions increasing in size between triplet proteins

Mammalian neurofilament triplet proteins (68 K, 160 K and 200 K) have been correlated by a biochemical, immunological and protein chemical study. The 160 K and 200 K triplet proteins are intermediate filament proteins in their own right, since they reveal the alpha-helical coiled-coil rod domain analyzed in detail for the 68 K protein. Triplet proteins display two distinct arrays. Their amino-terminal region built analogously to non-neuronal intermediate filament proteins should allow a co-polymerization process via the interaction of coiled-coil domains. The extra mass of all triplet proteins is allocated to carboxy-terminally located extensions of increasing size and unique amino acid sequences. These may provide highly charged scaffolds suitable for interactions with other neuronal components. Such a domain of 68 K reveals, in sequence analysis, 47 glutamic acids within 106 residues. The epitope recognized by a monoclonal antibody reacting probably with all intermediate filament proteins has been mapped. It is located within the last 20 residues of the rods, where six distinct intermediate filament proteins point to a consensus sequence.     

Structure of the gene encoding peripherin, an NGF-regulated neuronal-specific type III intermediate filament protein

We have cloned the rat gene encoding peripherin, a neuronal-specific intermediate filament protein that is NGF-regulated. Determination of the complete sequence, including 821 nucleotides of the 5'-flanking region, allows us to make conclusions about the evolutionary origin of the peripherin gene, its homology with other intermediate filament proteins, and possible mechanisms of regulation of peripherin expression in neurons. The positions of the eight peripherin gene introns correspond to the intron patterns of desmin, vimentin, and GFAP, with one example of intron sliding. Together with protein sequence homologies, this conclusively demonstrates that peripherin is a type III intermediate filament protein. The peripherin promoter contains sequences homologous to regions of other NGF-regulated promoters, which may function in peripherin induction by NGF.     

Amino acid sequence data on glial fibrillary acidic protein (GFA); implications for the subdivision of intermediate filaments into epithelial and non-epithelial members.

Determination of 50% of the sequence of the astrocyte-specific intermediate filament (IF) protein documents the hypervariable regions as well as parts of the coiled-coil array of glial fibrillary acidic protein (GFA). The results show that the four non-epithelial IF proteins (myogenic desmin, mesenchymal vimentin, GFA and neurofilament 68 K protein) known to form homopolymers are much more closely related than the epithelial keratins, which seem to form heteropolymers only. Of the four non-epithelial proteins, desmin and vimentin are the most closely related, since GFA has a shorter non-alpha-helical array at the amino terminus. We discuss the possibility that the non-alpha-helical terminal arrays, because of their sequence and length variability, are responsible for differences of distinct IF with respect to physical-chemical properties such as the low ionic strength-induced depolymerization into protofilaments.     

The primary structure of component 8c-1, a subunit protein of intermediate filaments in wool keratin. Relationships with proteins from other intermediate filaments.

Component 8c-1, one of four highly homologous component-8 subunit proteins present in the microfibrils of wool, was isolated as its S-carboxymethyl derivative and its amino acid sequence was determined. Large peptides were isolated after cleaving the protein chemically or enzymically and the sequence of each was determined with an automatic Sequenator. The peptides were ordered by sequence overlaps and, in some instances, by homology with known sequences from other component-8 subunits. The C-terminal residues were identified by three procedures. Full details of the various procedures used have been deposited as Supplementary Publication SUP 50133 (4 pp.) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1986) 233, 5. The result showed that the protein comprises 412 residues and has an Mr, including the N-terminal acetyl group, of 48,300. The sequence of residues 98-200 of component 8c-1 was found to correspond to the partial or complete sequences of four homologous type I helical segments previously isolated from helical fragments recovered from chymotryptic digests of microfibrillar proteins of wool [Crewther & Dowling (1971) Appl. Polym. Symp. 18, 1-20; Crewther, Gough, Inglis & McKern (1978) Text. Res. J. 48, 160-162; Gough, Inglis & Crewther (1978) Biochem. J. 173, 385]. Considered in relation to amino acid sequences of other intermediate-filament proteins, the sequence is in accord with the view that keratin filament proteins are of two types [Hanukoglu & Fuchs (1983) Cell (Cambridge, Mass.) 33, 915-924]. Filament proteins from non-keratinous tissues, such as desmin, vimentin, neurofilament proteins and the glial fibrillary acidic protein, which form monocomponent filaments, constitute a third type. It is suggested that as a whole the proteins from intermediate filaments be classed as filamentins, the three types at present identified forming subgroups of this class. The significant homologies between types I, II and III occur almost exclusively in segments of the chain that have been identified as having a coiled-coil structure together with the relatively short sections connecting these segments. The non-coiled-coil segments at the C- and N-termini show no significant homology between types, nor is homology in these segments apparent in all members of one type. Component 8c-1 does not show homology in its terminal segments with the known sequence of any other filamentin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Assembly of carboxy-terminally deleted desmin in vimentin-free cells.

Using a vimentin-free expression system we were able to demonstrate that the carboxy terminus of desmin is necessary for filament assembly in the living cell. Desmin subunits missing only 4 carboxy-terminal residues of their rod domain are incapable of homopolymeric filament assembly. Moreover, even single amino acid substitutions in the conserved carboxy-terminal part of the rod domain prevent desmin subunits from homopolymeric filament assembly. Desmin subunits missing 18 or more carboxy-terminal residues of their rod domain (including the complete conserved carboxy-terminal region) are unstable in cells devoid of intact type III intermediate filaments (IFs). Interaction with an intact type III IF, however, stabilizes these mutated desmin subunits. Expression of a desmin subunit missing both its non-helical end domains in vimentin-containing cells disrupts the endogenous vimentin network completely.     

Desmin-binding specificities of two desmin CNBr fragments that correspond to the headpiece domain and Helix 1B

D88 and D109, two cyanogen bromide fragments of desmin which essentially correspond to the amino terminal headpiece domain and Helix 1B, respectively, bind to intact desmin with different topological specificities. D88, the headpiece domain fragment, binds only to the headpiece of intact desmin. In contrast, D109, which encompasses Helix 1B and most of the linker L10 binds to desmin even when its headpiece is removed. Additionally, these fragments only bind desmin if they are present during filament assembly; they do not bind pre-assembled desmin IF or tetramers. These observations suggest that, while alpha-helical coiled-coil interaction between rod domains provides the major driving force behind IF protein dimer formation, homophilic binding of head domains of these proteins may provide an additional stabilizing force and/or specify axial registration in certain IF proteins.     

The chicken vimentin gene. Nucleotide sequence, regulatory elements, and comparison to the hamster gene

Here we report the nucleotide sequence of the chicken vimentin gene and its deduced primary amino acid sequence. A comparison of this gene to other intermediate filament protein genes demonstrates that both exon size and position are strongly conserved features of this multigene family. In addition, the hamster and chicken vimentin genes exhibit strong identity at the level of nucleotide (74%) and amino acid (80%) sequence. Interestingly, 40% of total sequence diversity is localized to the N terminus or "head" region of these genes whereas other protein domains (rod and C terminus) are remarkably identical in both nucleotide (81%) and amino acid (89%) sequence. Even stronger amino acid identity (100%) is exhibited in certain subdomains which may define regions crucial for filament formation and function. Not surprisingly, vimentin is more homologous across animal species than it is to other intermediate filament protein members (e.g. desmin) within the same species. A comparison of 5'-flanking sequences of the hamster and chicken genes as well as other characterized promoter elements (SV40, HSV-TK) reveals homologous sequence elements which may define common and/or unique sites involved in the modulation of gene expression. The implications of these sequence elements for both tissue-specific and developmental expression of the vimentin gene are discussed.