Structure of an invertebrate gene encoding cytoplasmic intermediate filament (IF) proteins: implications for the origin and the diversification of IF proteins.

The structure of the single gene encoding the cytoplasmic intermediate filament (IF) proteins in non-neuronal cells of the gastropod Helix aspersa is described. Genomic and cDNA sequences show that the gene is composed of 10 introns and 11 exons, spanning greater than 60 kb of DNA. Alternative RNA processing accounts for two mRNA families which encode two IF proteins differing only in their C-terminal sequence. The intron/exon organization of the Helix rod domain is identical to that of the vertebrate type III IF genes in spite of low overall protein sequence homology and the presence of an additional 42 residues in coil 1b of the invertebrate sequence. Intron position homology extends to the entire coding sequence comprising both the rod and tail domains when the invertebrate IF gene is compared with the nuclear lamin LIII gene of Xenopus laevis presented in the accompanying report of Döring and Stick. In contrast the intron patterns of the tail domains of the invertebrate IF and the lamin genes differ from those of the vertebrate type III genes. The combined data are in line with an evolutionary descent of cytoplasmic IF proteins from a nuclear lamin-like progenitor and suggest a mechanism for this derivation. The unique position of intron 7 in the Helix IF gene indicates that the archetype IF gene arose by the elimination of the nuclear localization sequence due to the recruitment of a novel splice site. The presumptive structural organization of the archetype IF gene allows predictions with respect to the later diversification of metazoan IF genes. Whereas models proposing a direct derivation of neurofilament genes seem unlikely, the earlier speculation of an mRNA transposition mechanism is compatible with current results.     

The cephalochordate Branchiostoma genome contains 26 intermediate filament (IF) genes: Implications for evolution of chordate IF proteins

We analyzed the draft genome of the cephalochordate Branchiostoma floridae (B. floridae) for genes encoding intermediate filament (IF) proteins. From 26 identified IF genes 13 were not reported before. Four of the new IF genes belong to the previously established Branchiostoma IF group A, four to the Branchiostoma IF group B, one is homologous to the type II keratin E2 while the remaining four new IF sequences N1 to N4 could not be readily classified in any of the previously established Branchiostoma IF groups. All eleven identified A and B2-type IF genes are located on the same genomic scaffold and arose due to multiple cephalochordate-specific duplications. Another IF gene cluster, identified in the B. floridae genome, contains three keratins (E1, Y1, D1), two keratin-like IF genes (C2, X1), one new IF gene (N1) and one IF unrelated gene, but does not show any similarities to the well defined vertebrate type I or type II keratin gene clusters. In addition, some type III sequence features were documented in the new IF protein N2, which, however, seems to share a common ancestry with the Branchiostoma keratins D1 and two keratin-related genes C. Thus, a few type I and type II keratin genes existed in a common ancestor of cephalochordates and vertebrates, which after separation of these two lineages gave rise to the known complexities of the vertebrate cytoplasmic type I–IV IF proteins, as well as to the multiple keratin and related IF genes in cephalochordates, due to multiple gene duplications, deletions and sequence divergences.     

The gene for a cytoplasmic intermediate filament (IF) protein of the hemichordate Saccoglossus kowalevskii; definition of the unique features of chordate IF proteins

We have isolated full length cDNAs encoding a cytoplasmic intermediate filament (IF) protein of a priapulid (Priapulus caudatus) and of a hemichordate (Saccoglossus kowalevskii) and determined the organisation of the hemichordate gene. As expected, the priapulid protein shows the long coil 1b subdomain and the lamin tail homology segment already known for cytoplasmic IF proteins from 11 other protostomic phyla. Surprisingly, the hemichordate protein follows in domain organisation much more closely the protostomic IF proteins than the chordate IF proteins. Thus, the lack of a lamin tail homology segment together with a deletion of 42 residues in the coil 1b domain is a molecular feature restricted to the chordates. We propose that the known IF subfamilies I to IV developed by gene duplications and sequence drift after the deletion in coil 1b arose at the base of the chordate branch.     

Amino acid sequence and gene organization of cytokeratin no. 19, an exceptional tail-less intermediate filament protein.

We have isolated a cDNA clone from a bovine bladder urothelium library which encodes the smallest intermediate filament (IF) protein known, i.e. the simple epithelial cytokeratin (equivalent to human cytokeratin 19) previously thought to have mol. wt 40,000. This clone was then used to isolate the corresponding gene from which we have determined the complete nucleotide sequence and deduced the amino acid sequence of the encoded protein. This cytokeratin of 399 amino acids (mol. wt 43,893) is identified as a typical acidic (type I) cytokeratin but differs from all other IF proteins in that it does not show the carboxyterminal, non-alpha-helical tail domain. Instead it contains a 13 amino acids extension of the alpha-helical rod. The gene encoding cytokeratin 19 is also exceptional. It contains only five introns which occur in positions corresponding to intron positions in other IF protein genes. However, an intron which in all other IF proteins demarcates the region corresponding to the transition from the alpha-helical rod into the non-alpha-helical tail is missing in the cytokeratin 19 gene. Using in vitro reconstitution of purified cytokeratin 19 we show that it reacts like other type I cytokeratins in that it does not form, in the absence of a type II cytokeratin partner, typical IF. Instead it forms 40-90 nm rods of 10-11 nm diameter which appear to represent lateral associations of a number of cytokeratin molecules. Our results demonstrate that the non-alpha-helical tail domain is not an indispensable feature of IF proteins. The gene structure of this protein provides a remarkable case of a correlation of a change in protein conformation with an exon boundary.     

Gene structure of nuclear lamin LIII of Xenopus laevis; a model for the evolution of IF proteins from a lamin-like ancestor.

The lamin LIII gene of Xenopus laevis has been characterized. The gene is duplicated in the Xenopus genome. The transcribed region spreads over 22 kb of genomic DNA encoding 12 exons. Two alternatively spliced mRNAs are observed which encode LIII isoforms that differ only by the 12 C-terminal amino acids which, however, both contain the CaaX motif known to be the target of post-translational modifications. The intron pattern of the lamin LIII gene is strikingly similar to that of an invertebrate intermediate filament (IF) gene over the entire protein coding sequence. The similarity in gene structure is restricted to the rod domain when compared with vertebrate types I-III IF genes. Our data suggest a model of how IF proteins evolved from a lamin-like ancestor by deletion of two signal sequences; the nuclear localization signal and the C-terminal ras-related CaaX motif. The data rule out the previously proposed hypothesis that IF proteins evolved from an intronless ancestor with an early divergence of neuronal and non-neuronal IF proteins. Together with the data presented in the accompanying paper by Dodemond et al. it can be concluded that the tail domains of lamins and invertebrate IF proteins, but not those of vertebrate IF proteins, are homologous. Thus, the different vertebrate IF proteins probably evolved by combination of the central rod domain with different tail domains by exon shuffling.     

Structure of the mouse glial fibrillary acidic protein gene: implications for the evolution of the intermediate filament multigene family.

We report the complete sequence of the gene encoding mouse glial fibrillary acidic protein (GFAP), the intermediate filament (IF) protein specific to astrocytes. The 9.8 kb gene includes nine exons separated by introns ranging in size from 0.2 to 2.5 kb. A comparison of the organization of the GFAP gene with that of genes encoding other IF proteins reveals that the structure of IF genes is highly conserved in spite of considerable divergence at the amino acid level. Thus, most of the evolutionary events leading to the placement of introns in IF genes must have occurred prior to the duplication and subsequent divergence of IF genes from a presumptive common ancestral sequence. The conserved gene organization is unrelated to structural features of IF proteins. A curious feature of the GFAP gene is the large number of repeated sequences found in the introns. Six tracts of reiterated di- or trinucleotides are present, plus tandem repeats of two different novel sequences. One repeat is unique to the GFAP gene; the other occurs elsewhere in the mouse genome, although at relatively low frequency.     

Molecular Phylogeny of Metazoan Intermediate Filament Proteins

We have cloned cytoplasmic intermediate filament (IF) proteins from a large number of invertebrate phyla using cDNA probes, the monoclonal antibody IFA, peptide sequence information, and various RT-PCR procedures. Novel IF protein sequences reported here include the urochordata and nine protostomic phyla, i.e., Annelida, Brachiopoda, Chaetognatha, Echiura, Nematomorpha, Nemertea, Platyhelminthes, Phoronida, and Sipuncula. Taken together with the wealth of data on IF proteins of vertebrates and the results on IF proteins of Cephalochordata, Mollusca, Annelida, and Nematoda, two IF prototypes emerge. The L-type, which includes 35 sequences from 11 protostomic phyla, shares with the nuclear lamins the long version of the coil 1b subdomain and, in most cases, a homology segment of some 120 residues in the carboxyterminal tail domain. The S-type, which includes all four subfamilies (types I to IV) of vertebrate IF proteins, lacks 42 residues in the coil 1b subdomain and the carboxyterminal lamin homology segment. Since IF proteins from all three phyla of the chordates have the 42-residue deletion, this deletion arose in a progenitor prior to the divergence of the chordates into the urochordate, cephalochordate, and vertebrate lineages, possibly already at the origin of the deuterostomic branch. Four phyla recently placed into the protostomia on grounds of their 18S rDNA sequences (Brachiopoda, Nemertea, Phoronida, and Platyhelminthes) show IF proteins of the L-type and fit by sequence identity criteria into the lophotrochozoic branch of the protostomia. Received: 2 April 1998 / Accepted: 19 June 1998     

Complete sequence of a bovine type I cytokeratin gene: conserved and variable intron positions in genes of polypeptides of the same cytokeratin subfamily

The complete sequence of a bovine gene encoding an epidermal cytokeratin of mol. wt. 54 500 (No VIb) of the acidic (type I) subfamily is presented, including an extended 5' upstream region. The gene (4377 bp, seven introns) which codes for a representative of the glycine-rich subtype of cytokeratins of this subfamily, is compared with genes coding for: another subtype of type I cytokeratin; a basic (type II) cytokeratin gene; and vimentin, a representative of another intermediate filament (IF) protein class. The positions of the five introns located within the highly homologous alpha-helix-rich rod domain are identical or equivalent, i.e., within the same triplet, in the two cytokeratin I genes. Four of these intron positions are also identical with intron sites in the vimentin gene, and three of these intron positions are identical or similar in the type I and type II cytokeratin subfamilies. On the other hand, the gene organization of both type I cytokeratins differs from that of the type II cytokeratin in the rod region in five intron positions and in the introns located in the carboxy-terminal tail region, with the exception of one position at the rod-tail junction. Remarkably, the two type I cytokeratins also differ from each other in the positions of two introns located at and in the region coding for the hypervariable, carboxy-terminal portion. The introns and the 5' upstream regions of the cytokeratin VIb gene do not display notable sequence homologies with the other IF protein genes, but sequences identical with--or very similar to--certain viral and immunoglobulin enhancers have been identified.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytoplasmic intermediate filament protein expression in tunicate development: a specific marker for the test cells

The urochordate Ciona intestinalis is a well established system for embryological studies, and large scale EST sequences begin to emerge. We cloned five cytoplasmic intennediate filament (IF) cDNAs and made specific antibodies to the recombinant proteins. Self-assembly studies and immunofluorescence microscopy were used to study these proteins and their distribution. Confirming and extending previous studies in Styela, we found that Ciona protein IF-A is expressed in muscle and forms homopolymeric filaments while proteins IF-C and IF-D, which form only obligatory heteropolymeric filaments, resemble a keratin pair exclusively found in the entire epidermis. Protein IF-B and the new protein IF-F potentially reflect tunicate-specific IF proteins. They are found in the entire internal epithelia including the neural gland. We also extended the analysis to earlier developmental stages of Ciona. Protein IF-A is expressed in muscle from larval stages, whereas proteins IF-C and IF-D are found only in the tail epidermis. Protein IF-F is detected abundantly in the test cells of eggs, embryos and premetamorphic larvae. Our studies show that IF proteins could prove very useful markers in the study of cell fate determination in Ciona. They also support previous findings on the evolutionary relationships of different IF proteins. Non-vertebrate chordates have IF proteins which represent orthologs of vertebrate type I to III proteins, but also IF proteins that do not seem to fit into these classes. However, the intron positions of all tunicate IF genes are conserved with vertebrate type I to III genes, pointing to a common evolutionary origin.     

Amphioxus type I keratin cDNA and the evolution of intermediate filament genes.

We report the cloning of an intermediate filament (IF) cDNA from the cephalochordate amphioxus that encodes a protein assignable to the type I keratin group. This is the first type I keratin reported from an invertebrate. Molecular phylogenetic analyses reveal that amphioxus also possesses a type II keratin, and that the genes encoding short-rod IF proteins underwent different patterns of duplication in vertebrates and their closest relatives, the cephalochordates. Extensive IF gene duplication and divergence may have facilitated the origin of new specialised cell types in vertebrates.     

Explosive Expansion of βγ-Crystallin Genes in the Ancestral Vertebrate

In jawed vertebrates, βγ-crystallins are restricted to the eye lens and thus excellent markers of lens evolution. These βγ-crystallins are four Greek key motifs/two domain proteins, whereas the urochordate βγ-crystallin has a single domain. To trace the origin of the vertebrate βγ-crystallin genes, we searched for homologues in the genomes of a jawless vertebrate (lamprey) and of a cephalochordate (lancelet). The lamprey genome contains orthologs of the gnathostome βB1-, βA2- and γN-crystallin genes and a single domain γN-crystallin-like gene. It contains at least two γ-crystallin genes, but lacks the gnathostome γS-crystallin gene. The genome also encodes a non-lenticular protein containing βγ-crystallin motifs, AIM1, also found in gnathostomes but not detectable in the uro- or cephalochordate genome. The four cephalochordate βγ-crystallin genes found encode two-domain proteins. Unlike the vertebrate βγ-crystallins but like the urochordate βγ-crystallin, three of the predicted proteins contain calcium-binding sites. In the cephalochordate βγ-crystallin genes, the introns are located within motif-encoding region, while in the urochordate and in the vertebrate βγ-crystallin genes the introns are between motif- and/or domain encoding regions. Coincident with the evolution of the vertebrate lens an ancestral urochordate type βγ-crystallin gene rapidly expanded and diverged in the ancestral vertebrate before the cyclostomes/gnathostomes split. The β- and γN-crystallin genes were maintained in subsequent evolution, and, given the selection pressure imposed by accurate vision, must be essential for lens function. The γ-crystallin genes show lineage specific expansion and contraction, presumably in adaptation to the demands on vision resulting from (changes in) lifestyle.     

Cytoplasmic intermediate filament proteins of invertebrates are closer to nuclear lamins than are vertebrate intermediate filament proteins; sequence characterization of two muscle proteins of a nematode.

The giant body muscle cells of the nematode Ascaris lumbricoides show a complex three dimensional array of intermediate filaments (IFs). They contain two proteins, A (71 kd) and B (63 kd), which we now show are able to form homopolymeric filaments in vitro. The complete amino acid sequence of B and 80% of A have been determined. A and B are two homologous proteins with a 55% sequence identity over the rod and tail domains. Sequence comparisons with the only other invertebrate IF protein currently known (Helix pomatia) and with vertebrate IF proteins show that along the coiled-coil rod domain, sequence principles rather than actual sequences are conserved in evolution. Noticeable exceptions are the consensus sequences at the ends of the rod, which probably play a direct role in IF assembly. Like the Helix IF protein the nematode proteins have six extra heptads in the coil 1b segment. These are characteristic of nuclear lamins from vertebrates and invertebrates and are not found in vertebrate IF proteins. Unexpectedly the enhanced homology between lamins and invertebrate IF proteins continues in the tail domains, which in vertebrate IF proteins totally diverge. The sequence alignment necessitates the introduction of a 15 residue deletion in the tail domain of all three invertebrate IF proteins. Its location coincides with the position of the karyophilic signal sequence, which dictates nuclear entry of the lamins. The results provide the first molecular support for the speculation that nuclear lamins and cytoplasmic IF proteins arose in eukaryotic evolution from a common lamin-like predecessor.     

Organization of a type I keratin gene. Evidence for evolution of intermediate filaments from a common ancestral gene

The genomic structure of the mouse 59-kDa keratin gene, a Type I intermediate filament (IF) gene is presented. A comparison of the organization of this gene with that of the human 67-kDa keratin, a Type II IF gene, and hamster vimentin, a Type III IF gene, suggests a common evolutionary origin for Type I, II, and III IF genes. Most introns in these three types of IF genes occur at similar positions within the region encoding sequences predicted to form coiled-coils, but do not delineate structural subdomains. Interestingly though, most of the introns interrupt at or near the beginning of the characteristic 7-residue (heptad) repeat of sequences which form the coiled-coil. These data suggest that the three types of IF genes arose from a common ancestor which may have been assembled from smaller units containing multiple heptad repeats. Subsequent duplication events may then have formed the three known alpha-helical types and each of their various members.     

Sorting out IF networks: consequences of domain swapping on IF recognition and assembly

Vimentin and keratin are coexpressed in many cells, but they segregate into two distinct intermediate filament (IF) networks. To understand the molecular basis for the sorting out of these IF subunits, we genetically engineered cDNAs encoding hybrid IF proteins composed of part vimentin and part type I keratin. When these cDNAs were transiently expressed in cells containing vimentin, keratin, or both IFs, the hybrid IF proteins all recognized one or the other or both networks. The ability to distinguish networks was dependent upon which segments of IF proteins were present in each construct. Constructs containing sequences encoding either helix 1B or helix 2B seemed to be the most critical in conferring IF recognition. At least for type I keratins, recognition was exerted at the level of dimer formation with wild-type type II keratin, as demonstrated by anion exchange chromatography. Interestingly, despite the fact that swapping of helical domains was not as deleterious to IF structure/function as deletion of helical domains, keratin/vimentin hybrids still caused structural aberrations in one or more of the cytoplasmic IF network. Thus, sequence diversity among IF proteins seems to influence not only coiled-coil but also higher ordered associations leading to 10-nm filament formation and/or IF interactions with other cellular organelles/proteins.     

Characterization of the Hydra Lamin and Its Gene: A Molecular Phylogeny of Metazoan Lamins

We report sequences for nuclear lamins from the teleost fish Danio and six invertebrates. These include two cnidarians (Hydra and Tealia), one priapulid, two echinoderms, and the cephalochordate Branchiostoma. Combining these results with earlier data on Drosophila, Caenorhabditis elegans, and various vertebrates, the following conclusions on lamin evolution can be drawn. First, all invertebrate lamins resemble in size the vertebrate B-type lamin. Second, all lamins described previously for amphibia, birds and mammals as well as the first lamin of a fish, characterized here, show a cluster of 7 to 12 acidic residues in the tail domain. Since this acidic cluster is absent from all invertebrate lamins including that of the cephalochordate Branchiostoma, it was acquired with the vertebrate lineage. The larger A-type lamin of differentiated cells must have arisen subsequently by gene duplication and insertion of an extra exon. This extra exon of the vertebrate A-lamins is the only major change in domain organization in metazoan lamin evolution. Third, the three introns of the Hydra and Priapulus genes correspond in position to the last three introns of vertebrate B-type lamin genes. Thus the entirely different gene organization of the C. elegans and Drosophila Dmo genes seems to reflect evolutionary drift, which probably also accounts for the fact that C. elegans has the most diverse lamin sequence. Finally we discuss the possibility that two lamin types, a constitutively expressed one and a developmentally regulated one, arose independently on the arthropod and vertebrate lineages. Received: 4 February 1999 / Accepted: 1 April 1999     

Unusual ultrastructures of the Branchiostoma IF protein C2 containing heptads in the tail

Branchiostoma intermediate filament (IF) protein C2 contains a long tail domain consisting of several degenerate repeats which display a heptad repeat pattern. This unique tail sequence is predicted to constitute a long coiled coil domain in C2, which is separated from the rod by a glycine-rich linker L3. The recombinant IF protein C2 shows, in electron microscopy (EM), parallel rodlike dimers of 66.7 nm decorated by a larger globule on one side and a smaller globule on the other side. In contrast, the length of the tailless C2 dimers, decorated by only one small globule, is about 26 nm shorter. These results indicate that both the rod domain and the newly predicted coiled coil segment 3 participate in the formation of a double-stranded coiled coil dimer. Moreover, the two to four C2 dimers are able to associate via their globular tail domain into multiarm oligomers, an ability not seen by the tailless C2 mutant or the other currently known protostomic and vertebrate IFs.     

The epidermal intermediate filament proteins of tunicates are distant keratins; a polymerisation-competent hetero coiled coil of the Styela D protein and Xenopus keratin 8

Two novel cytoplasmic intermediate filament (IF) proteins (C and D) from the tunicate (urochordate) Styela are characterised as putative keratin orthologs. The coexpression of C and D in all epidermal cells and the obligatory heteropolymeric IF assembly of the recombinant proteins argue for keratin orthologs, but the sequences do not directly reveal which protein behaves as a keratin I or II ortholog. This problem is solved by the finding that keratin 8, a type II keratin from man or Xenopus, forms chimeric IF when mixed with Styela D. Mutant proteins of Styela D and keratin 8 with a single cysteine in equivalent positions show that these chimeric IF are, like vertebrate keratin filaments, based on the hetero coiled coil. We propose that Styela D retains, in spite of its strong sequence drift, important molecular features of type I keratins. By inference Styela C reflects a type II ortholog. We discuss that type I to III IF proteins are expressed along the chordate branch of metazoa.     

Gene and domain duplication in the chordate Otx gene family: insights from amphioxus Otx

We report the genomic organization and deduced protein sequence of a cephalochordate member of the Otx homeobox gene family (AmphiOtx) and show its probable single-copy state in the genome. We also present molecular phylogenetic analysis indicating that there was single ancestral Otx gene in the first chordates which was duplicated in the vertebrate lineage after it had split from the lineage leading to the cephalochordates. Duplication of a C-terminal protein domain has occurred specifically in the vertebrate lineage, strengthening the case for a single Otx gene in an ancestral chordate whose gene structure has been retained in an extant cephalochordate. Comparative analysis of protein sequences and published gene expression patterns suggest that the ancestral chordate Otx gene had roles in patterning the anterior mesendoderm and central nervous system. These roles were elaborated following Otx gene duplication in vertebrates, accompanied by regulatory and structural divergence, particularly of Otx1 descendant genes.