Four fibroblast tropomyosin isoforms are expressed from the rat alpha-tropomyosin gene via alternative RNA splicing and the use of two promoters

cDNA clones encoding four rat tropomyosin isoforms, termed TM-2, TM-3, TM-5a, and TM-5b, were isolated and characterized. All are derived from the alpha-tropomyosin gene via alternative RNA processing and the use of two alternate promoters. The cDNA sequences predict that TM-2 and TM-3 both contain 284 amino acids and differ from each other only at an internal region of the protein from amino acids 189 through 213, due to alternative splicing of exons 6a and 6b. TM-5a and TM-5b both contain 248 amino acids and differ from each other only at an internal exon encoding amino acids 153 through 177, also due to alternative splicing of exons 6a and 6b. The differences in the amino acid sequence encoded by these alternate exons affects the theoretical actin-binding pattern of the tropomyosins, such that TM-5b is expected to bind actin with greater affinity than TM-5a. TM-2 and TM-3 are transcribed from the upstream promoter, and TM-5a and TM-5b are transcribed from an internal promoter. In addition, all four isoforms contain the identical COOH-terminal coding region. RNA protection analyses revealed that the mRNA for each isoform is expressed in a number of different tissues and cell types, although the expression of some isoforms is restricted to particular cell types. Furthermore, the expression of mRNA encoding these isoforms was found to be altered in a number of different virally transformed cell lines. The changes in the expression of tropomyosin mRNAs in transformed cells reflect changes in the relative use of the two promoters, as well as the relative use of alternatively spliced exons 6a and 6b.     

Regulation of coiled-coil assembly in tropomyosins

Tropomyosins (TMs) are a family of actin filament-binding proteins. They consist of nearly 100% alpha-helix and assemble into parallel coiled-coil dimers. In vertebrates, TMs are encoded by four genes that give rise to at least 17 distinct isoforms through the use of alternative RNA splicing and alternative promoters. We have studied various aspects of the coiled-coil interactions among muscle and nonmuscle isoforms by the use of transfection of epitope-tagged constructs, followed by immunoprecipitation, SDS-PAGE, and Western blot analyses. For coiled-coil interactions between high-molecular-weight isoforms (284 amino acids), the information for homo- versus heterodimerization is contained in large part within the alternatively spliced exons of nonmuscle and muscle (skeletal and smooth) isoforms. Furthermore, sequences located in alternatively spliced exons encoding amino acids 39-80 (exons 2a/2b), amino acids 189-213 (exons 6a/6b), and amino acids 258-284 (exons 9a/9d) are critical for the selective formation of homo- versus heterodimers. Among low-molecular-weight isoforms (248 amino acids), TM-4 and TM-5 can form either homodimers or heterodimers. The trigger sequence (amino acids 190-202) is required for homodimerization of TM-4, but not heterodimerization of TM-4 with TM-5. How the dimeric state of TMs might play a role in their cellular localization and function is discussed.     

Cloning of a differentially expressed tropomyosin isoform from cultured rabbit aortic smooth muscle cells

The four known tropomyosin genes have highly conserved DNA and amino acid sequences, and at least 18 isoforms are generated by alternative RNA splicing in muscle and non-muscle cells. No rabbit tropomyosin nucleotide sequences are known, although protein sequences for alpha- and beta-tropomyosin expressed by rabbit skeletal muscle have been described. Subtractive hybridisation was used to select for genes differentially expressed in rabbit aortic smooth muscle cells (SMC), during the change in cell phenotype in primary culture that is characterised by a loss of cytoskeletal filaments and contractile proteins. This led to the cloning of a tropomyosin gene predominantly expressed in rabbit SMC during this change. The full-length cDNA clone, designated "rabbit TM-beta", contains an open reading frame of 284 amino acids, 5' untranslated region (UTR) of 117 base pairs and 3' UTR of 79 base pairs. It is closely related to the beta-gene isoforms in other species, with the highest homology in DNA and protein sequences to the human fibroblast isoform TM-1 (91.7% identity in 1035 bp and 93.3% identity in the entire 284 amino acid sequence of the protein). It differs from rabbit skeletal muscle beta-tropomyosin (81.7% homology at the protein level) mainly in two regions at amino acids 189-213 and 258-283 suggesting alternative splicing of exons 6a for 6b and 9d for 9a. Since this TM-beta gene was the only gene strongly enough expressed in SMC changing phenotype to be observed by the subtractive hybridisation screen, it likely plays a significant role in this process.     

Branch point selection in alternative splicing of tropomyosin pre-mRNAs.

The rat tropomyosin 1 gene gives rise to two mRNAs encoding rat fibroblast TM-1 and skeletal muscle beta-tropomyosin via an alternative splicing mechanism. The gene is comprised of 11 exons. Exons 1 through 5 and exons 8 and 9 are common to all mRNAs expressed from this gene. Exons 6 and 11 are used in fibroblasts as well as smooth muscle whereas exons 7 and 10 are used exclusively in skeletal muscle. In the present studies we have focused on the mutually exclusive internal alternative splice choice involving exon 6 (fibroblast-type splice) and exon 7 (skeletal muscle-type splice). To study the mechanism and regulation of alternative splice site selection we have characterized the branch points used in processing of the tropomyosin pre-mRNAs in vitro using nuclear extracts obtained from HeLa cells. Splicing of exon 5 to exon 6 (fibroblast-type splice) involves the use of three branch points located 25, 29, and 36 nucleotides upstream of the 3' splice site of exon 6. Splicing of exon 6 (fibroblast-type splice) or exon 7 (skeletal muscle type-splice) to exon 8 involves the use of the same branch point located 24 nucleotides upstream of this shared 3' splice site. In contrast, the splicing of exon 5 to exon 7 (skeletal muscle-type splice) involves the use of three branch sites located 144, 147 and 153 nucleotides, upstream of the 3' splice site of exon 7. In addition, the pyrimidine content of the region between these unusual branch points and the 3' splice site of exon 7 was found to be greater than 80%. These studies raise the possibility that the use of branch points located a long distance from a 3' splice site may be an essential feature of some alternatively spliced exons. The possible significance of these unusual branch points as well as a role for the polypyrimidine stretch in intron 6 in splice site selection are discussed.     

Sequences of complete cDNAs encoding four variants of chicken skeletal muscle troponin T

cDNAs containing the complete coding sequences of four isoforms of troponin T derived from 1-week-old chick skeletal muscle have been isolated and sequenced. While the 5' and 3' untranslated regions and most of the coding sequence were identical for each, dramatic differences were observed in the NH2-terminal region corresponding to amino acid residues 10-37 of rabbit skeletal troponin T. These sequence differences correspond to the alternatively spliced but not mutually exclusive exons 4 to 8 of the rat skeletal muscle troponin T gene. In addition, we observe a sequence corresponding to an extra exon or exons (between 5 and 6) present in the chicken skeletal muscle gene and not previously detected in the rat skeletal or chicken cardiac genes. This sequence of 63 nucleotides consists of an almost perfect repeat of 30 and 33 nucleotides and has previously been shown to be represented as a protein variant in chicken skeletal muscle. A difference is also present in one cDNA clone corresponding to the alternatively spliced (mutually exclusive) exons 16 and 17 of the rat gene. In the protein, this corresponds to a region implicated in the interaction of troponin T with troponin C, tropomyosin, and perhaps troponin I and F-actin.     

Identification and cDNA sequence of delta-preprotachykinin, a fourth splicing variant of the rat substance P precursor.

The neuropeptides substance P and neurokinin A are synthesised from a family of precursor polypeptides encoded by the preprotachykinin A (PPT) gene. In addition to a mRNA (beta-PPT) containing all 7 exons of the gene, alternatively spliced mRNAs lacking either exon 4 (gamma-PPT) or exon 6 (alpha-PPT) have been identified. We have determined the sequences of cDNA clones encoding four variants of PPT mRNA from rat dorsal root ganglion (DRG), including a novel mRNA species (delta-PPT) in which both exons 4 and 6 are absent. The sequence of delta-PPT predicts the existence of a novel tachykinin precursor polypeptide.     

Isolation and characterization of cDNA clones encoding a low molecular weight nonmuscle tropomyosin isoform

cDNA clones encoding rat fibroblast tropomyosin 4 (TM-4) were isolated and characterized. DNA sequence analysis was carried out to determine the sequence of the protein. The derived amino acid sequence revealed that rat fibroblast TM-4 was found to contain 248 amino acids. The amino acid sequence of rat fibroblast TM-4 was compared with two other low molecular weight TM isoforms, equine platelet beta-TM and a human fibroblast TM. Rat TM-4 exhibited 98% sequence identity with the equine platelet TM but only 75% identity with the human fibroblast TM isoform. The high degree of conservation between the rat and equine proteins indicates that they belong to the same isotype of TM. Comparison of the amino acid sequences of the three low molecular TM isoforms along the length of the proteins reveals regions that are strongly conserved and regions that have considerably diverged. In the regions from amino acid residues 1 to 148 and 176 to 221, amino acid substitutes are moderate. The most variant regions in the sequence are in the middle part of the proteins from amino acids 149 to 175 and at the carboxyl-terminal region of the proteins from amino acids 222 to 248. The differences in the sequence of the rat and platelet TMs compared to the human TM may define distinct functional domains among the low molecular weight TMs. In addition, expression of tropomyosin was studied in a variety of tissues and transformed cells. We also demonstrate that at least three separate genes encode tropomyosins expressed in rat fibroblasts.     

Alpha-tropomyosin gene organization. Alternative splicing of duplicated isotype-specific exons accounts for the production of smooth and striated muscle isoforms

We have previously isolated and characterized cloned complementary DNAs (cDNAs) for striated and smooth muscle alpha-tropomyosin. The sequences of these cDNA clones suggested that these two isoforms were encoded by the same gene. Here, we have determined the complete structure of the alpha-tropomyosin (alpha-TM) gene, establishing that a single gene, with a sequence complexity of 28 kilobase pairs, is split into 12 exons and produces the smooth and striated muscle alpha-TM mRNA isoforms by alternative splicing of a minimum of five exchangeable isotype-specific exons. The elucidation of the intron/exon organization of alpha-TM suggests that this gene evolved from an ancestral gene encoding a 21-aa protein that might represent the primordial actin binding domain. Sequence comparison between the pairs of exons coding for the "isotype switch regions" and among the corresponding regions of tropomyosin genes in a variety of species ranging from insects to mammals, suggests that the alternatively spliced exons are very old and might have arisen before the radiation of the arthropods, more than 600 million years ago. Additionally, the examination of the intronic sequences has uncovered potential alternative intramolecular secondary structures (hairpin-loop structures) which might be involved in the tissue-specific expression of the duplicated and mutually exclusive alpha-TM isotype-specific exons.     

Nonmuscle and muscle tropomyosin isoforms are expressed from a single gene by alternative RNA splicing and polyadenylation.

The molecular basis for the expression of rat embryonic fibroblast tropomyosin 1 and skeletal muscle beta-tropomyosin was determined. cDNA clones encoding these tropomyosin isoforms exhibit complete identity except for two carboxy-proximal regions (amino acids 189 to 213 and 258 to 284) and different 3'-untranslated sequences. The isoform-specific regions delineate the troponin T-binding domains of skeletal muscle tropomyosin. Analysis of genomic clones indicates that there are two separate loci in the rat genome that contain sequences complementary to these mRNAs. One locus is a pseudogene. The other locus contains a single gene made up of 11 exons and spans approximately 10 kilobases. Sequences common to all mRNAs were found in exons 1 through 5 (amino acids 1 to 188) and exons 8 and 9 (amino acids 214 to 257). Exons 6 and 11 are specific for fibroblast mRNA (amino acids 189 to 213 and 258 to 284, respectively), while exons 7 and 10 are specific for skeletal muscle mRNA (amino acids 189 to 213 and 258 to 284, respectively). In addition, exons 10 and 11 each contain the entire 3'-untranslated sequences of the respective mRNAs including the polyadenylation site. Although the gene is also expressed in smooth muscle (stomach, uterus, and vas deferens), only the fibroblast-type splice products can be detected in these tissues. S1 and primer extension analyses indicate that all mRNAs expressed from this gene are transcribed from a single promoter. The promoter was found to contain G-C-rich sequences, a TATA-like sequence TTTTA, no identifiable CCAAT box, and two putative Sp1-binding sites.     

Structure and evolution of the alternatively spliced fast troponin T isoform gene.

The vertebrate fast skeletal muscle troponin T gene, TnTf, produces a complexity of isoforms through differential mRNA splicing. The mechanisms that regulate splicing and the physiological significance of TnTf isoforms are poorly understood. To investigate these questions, we have determined the complete sequence structure of the quail TnTf gene, and we have characterized the developmental expression of alternatively spliced TnTf mRNAs in quail embryonic muscles. We report the following: 1) the quail TnTf gene is significantly larger than the rat TnTf gene and has 8 non-homologous exons, including a pectoral muscle-specific set of alternatively spliced exons; 2) specific sequences are implicated in regulated exon splicing; 3) a 900-base pair sequence element, composed primarily of intron sequence flanking the pectoral muscle-specific exons, is tandemly repeated 4 times and once partially, providing direct evidence that the pectoral-specific TnT exon domain arose by intragenic duplications; 4) a chicken repeat 1 retrotransposon element resides upstream of this repeated intronic/pectoral exon sequence domain and is implicated in transposition of this element into an ancestral genome; and 5) a large set of novel isoforms, produced by regulated exon splicing, is expressed in quail muscles, providing insights into the developmental regulation, physiological function, and evolution of the vertebrate TnTf isoforms.     

Chicken cardiac tropomyosin and a low-molecular-weight nonmuscle tropomyosin are related by alternative splicing

We have isolated and characterized complementary DNAs (cDNAs) encoding chicken cardiac muscle tropomyosin and a low-molecular-weight nonmuscle tropomyosin. The cardiac muscle cDNA (pCHT-4) encodes a 284-amino acid protein that differs from chicken skeletal muscle alpha- and beta-tropomyosins throughout its length. The nonmuscle cDNA (pFT-C) encodes a 248-amino acid protein that is most similar (93-94%) to the tropomyosin class including rat fibroblast TM-4, equine platelet tropomyosin, and human fibroblast TM30pl. The nucleotide sequences of the cardiac and nonmuscle cDNAs are identical from the position encoding cardiac amino acid 81 (nonmuscle amino acid 45) through cardiac amino acid 257 (nonmuscle amino acid 221). The sequences differ both 5' and 3' of this region of identity. These comparisons suggest that the chicken cardiac tropomyosin and low-molecular-weight "platelet-like" tropomyosin are derived from the same genomic locus by alternative splicing. S1 analysis suggests that this locus encodes at least one other tropomyosin isoform.     

Evolution of tropomyosin functional domains: Differential splicing and genomic constraints

Summary We have cloned and determined the nucleotide sequence of a complementary DNA (cDNA) encoded by a newly isolated human tropomyosin gene and expressed in liver. Using the leastsquare method of Fitch and Margoliash, we investigated the nucleotide divergences of this sequence and those published in the literature, which allowed us to clarify the classification and evolution of the tropomyosin genes expressed in vertebrates. Tropomyosin undergoes alternative splicing on three of its nine exons. Analysis of the exons not involved in differential splicing showed that the four human tropomyosin genes resulted from a duplication that probably occurred early, at the time of the amphibian radiation. The study of the sequences obtained from rat and chicken allowed a classification of these genes as one of the types identified for humans.The divergence of exons 6 and 9 indicates that functional pressure was exerted on these sequences, probably by an interaction with proteins in skeletal muscle and perhaps also in smooth muscle; such a constraint was not detected in the sequences obtained from nonmuscle cells. These results have led us to postulate the existence of a protein in smooth muscle that may be the counterpart of skeletal muscle troponin.We show that different kinds of functional pressure were exerted on a single gene, resulting in different evolutionary rates and different convergences in some regions of the same molecule.Codon usage analysis indicates that there is no strict relationship between tissue types (and hence the tRNA precursor pool) and codon usage. G+C content is characteristic of a gene and does not change significantly during evolution. These results are in good agreement with an isochore composition of the genome, and thus suggest a similar chromosomal environment in chicken, rat, and human.     

Rat embryonic fibroblast tropomyosin 1. cDNA and complete primary amino acid sequence

A cDNA expression library of approximately 80,000 members was prepared from rat embryonic fibroblast mRNA using the plasmid expression vectors pUC8 and pUC9. Using an immunological screening procedure and 32P-labeled cDNA probes, clones encoding rat embryonic fibroblast tropomyosin 1 (TM-1) were identified and isolated. DNA sequence analysis was carried out to determine the amino acid sequence of the protein. Rat embryonic fibroblast TM-1 was found to contain 284 amino acids and is most homologous to smooth muscle alpha-tropomyosin compared with skeletal muscle alpha- and beta-tropomyosins and platelet beta-tropomyosin. Among the various tropomyosins, two regions where the greatest sequence divergence is evident are between amino acids 185 and 216 and amino acids 258 and 284. Rat embryonic fibroblast TM-1 and chicken smooth muscle alpha-tropomyosin are most closely related from amino acids 185 and 216 compared with skeletal muscle and platelet tropomyosins. In contrast, rat embryonic fibroblast TM-1, smooth muscle alpha-tropomyosin, and platelet tropomyosin are most homologous from amino acids 258 and 284 compared with skeletal muscle tropomyosins. These differences in sequences at the carboxyl-terminal region of the various tropomyosins are discussed in relation to differences in their binding to skeletal muscle troponin and its T1 fragment.     

In vitro and in vivo characterization of four fibroblast tropomyosins produced in bacteria: TM-2, TM-3, TM-5a, and TM-5b are co-localized in interphase fibroblasts

Most cell types express several tropomyosin isoforms, the individual functions of which are poorly understood. In rat fibroblasts there are at least six isoforms; TM-1, TM-2, TM-3, TM-4, TM-5a, and TM-5b. TM-1 is the product of the beta gene. TM-4 is produced from the TM-4 gene, and TMs 2, 3, 5a, and 5b are the products of the alpha gene. To begin to study the localization and function of the isoforms in fibroblasts, cDNAs for TM isoforms 2, 3, 5a, and 5b were placed into bacterial expression vectors and used to produce TM isoforms. The bacterially produced TMs were determined to be full length by sequencing the amino- and carboxy termini. These TMs were found to bind to F-actin in vitro, with properties similar to that of skeletal muscle TM. In addition, competition experiments demonstrated that TM-5b was better than TM-5a in displacing other TM isoforms from F-actin in vitro. To investigate the intracellular localization of these fibroblast isoforms, each was derivatized with a fluorescent chromophore and microinjected into rat fibroblasts. TM-2, TM-3, TM-5a, and TM-5b were each found to associate along actin filaments. There was no preferred cellular location or subset of actin filaments for these isoforms. Furthermore, co-injection of two isoforms labeled with different fluorochromes showed identical staining. At the level of the light microscope, these isoforms from the alpha gene do not appear to achieve different functions by binding to particular subsets of actin filaments or locations in cells. Some alternative possibilities are discussed. The results show that bacterially produced TMs can be used to study in vitro and in vivo properties of the isoforms.