Induction of fibulin-5 gene is regulated by tropoelastin gene, and correlated with tropoelastin accumulation in vitro

Fibulin-5 (also known as DANCE) is an elastin-binding protein that is thought to play a role in elastogenesis. We examined the relationship between the gene expression of fibulin-5 and the gene expression and accumulation of tropoelastin by comparing elastin-producing cells (human gingival fibroblasts) with non-elastin-producing cells (human periodontal ligament fibroblasts) by Northern blot analysis. Fibulin-5 gene induction was found only in elastin-producing cells. Induction of the fibulin-5 gene in elastin-producing cells occurred after induction of the tropoelastin gene, and the fibulin-5 level was reduced upon RNA interference-mediated down-regulation of tropoelastin. Fibulin-5 gene induction was also correlated with a rapid increase of tropoelastin accumulation within the cell layer. These results may suggest that the fibulin-5 gene induction is directly or indirectly regulated by tropoelastin gene expression and plays a role in the accumulation of elastic fibers within matrices.     

Differential expression of two tropoelastin genes in zebrafish.

Elastin is the extracellular matrix protein responsible for properties of extensibility and elastic recoil in large blood vessels, lung and skin of most vertebrates. Elastin is synthesized as a monomer, tropoelastin, but is rapidly transformed into its final polymeric form in the extracellular matrix. Until recently information on sequence and developmental expression of tropoelastins was limited to mammalian and avian species. We have recently identified and characterized two expressed tropoelastin genes in zebrafish. This was the first example of a species with multiple tropoelastin genes, raising the possibility of differential expression and function of these tropoelastins in elastic tissues of the zebrafish. Here we have investigated the temporal expression and tissue distribution of the two tropoelastin genes in developing and adult zebrafish. Expression was detected early in skeletal cartilage structures of the head, in the developing outflow tract of the heart, including the bulbus arteriosus and the ventral aorta, and in the wall of the swim bladder. While the temporal pattern of expression was similar for both genes, the upregulation of eln2 was much stronger than that of eln1. In general, both genes were expressed and their gene products deposited in most of the elastic tissues examined, with the notable exception of the bulbus arteriosus in which eln2 expression and its gene product was predominant. This finding may represent a sub-specialization of eln2 to provide the unique architecture of elastin and the specific mechanical properties required by this organ.     

Multiple chick tropoelastin mRNAs

Several overlapping chick tropoelastin cDNAs were isolated from a lambda gt11 cDNA library constructed from whole 10 day chick embryo total RNA. Comparison of the nucleotide sequence of the 2.3 kb tropoelastin cDNA to the sequences published by Bressan et al. (1) and Tokimitsu et al. (2) revealed the presence of two inserts (72 and 30 base pairs) in the cDNA derived from embryonic tissue. Northern blot analysis of 14 day embryonic aortae RNA with tropoelastin cDNA clones showed hybridization to a 3.5 kb mRNA. However, S1 nuclease protection experiments performed on RNA extracted from the same tissue showed that at least two if not more tropoelastin mRNAs exist and that the proportion of each varies in the ages examined. These results provide an origin and substantiate the differential expression of the multiple tropoelastin polypeptides found in developing chick aortic tissue.     

Characterization of an unusual tropoelastin with truncated C-terminus in the frog

Tropoelastin is the monomeric form of elastin, a major polymeric protein of the extracellular elastic matrix of vertebrate tissues with properties of extensibility and elastic recoil. Mammalian and avian species contain a single gene for tropoelastin. A tropoelastin gene has also previously been identified in amphibians. In contrast, two tropoelastin genes with different tissue expression patterns have been described in teleosts. While general characteristics of tropoelastins, such as alternating arrangements of hydrophobic and crosslinking domains, are conserved across a wide phylogenetic range, sequences of these domains are highly variable, particularly when amphibian and teleost tropoelastins are included. For this reason exon-to-exon correspondence is not clear, and overall alignment of tropoelastin sequences across all species is not possible. An exception to this is the C-terminal exon, whose coding sequence has been very well-conserved across all species described to date. In mammalians this C-terminal domain has been shown to be important for interactions with cells and other matrix-associated proteins involved in matrix assembly. Here we identify and characterize a second tropoelastin gene in the frog with several unusual characteristics, the most striking of which is truncation of the C-terminal domain, deleting normally conserved sequence motifs. We demonstrate that, in spite of the absence of these motifs, both frog tropoelastin genes are expressed and incorporated into the elastic matrix, although with differential tissue localizations.     

Deficient coacervation of two forms of human tropoelastin associated with supravalvular aortic stenosis.

Human tropoelastin associates by coacervation and is subsequently cross-linked to make elastin. In Williams syndrome, defective elastin deposition is associated with hemizygous deletion of the tropoelastin gene in supravalvular aortic stenosis (SVAS). Remarkably, point-mutation forms of SVAS correspond to incomplete forms of tropoelastin which include in-frame termination by nonsense mutations, yet the resulting phenotype of these disorders is not explained because expression variably occurs from both normal and mutant alleles. Proteins corresponding to two truncated tropoelastin mutants were expressed and purified to homogeneity. Coacervation of these proteins occurred as expected with increasing temperature, but substantially contrasted with that of the performance of a normal tropoelastin. Significantly, association by coacervation of the truncated SVAS tropoelastin molecules was negligible at 37 degrees C, which contrasted with the substantial coacervation seen for normal tropoelastin. Furthermore their midpoints of coacervation increased and correlated with the extent of deletion, in accord with the loss of hydrophobic regions required for tropoelastin association. Their secondary structures are similar, as evidenced by CD studies. We propose a model for point-mutation SVAS in which aberrant tropoelastin molecules are incompetent and are mainly excluded from participation in coacervation and consequently in elastogenesis. These forms of SVAS may consequently be considered functionally similar to a hemizygous deletion, and mark point-mutation SVAS as a disorder of defective coacervation.     

Elements of the rat tropoelastin gene associated with alternative splicing

Multiple isoforms of tropoelastin, the soluble precursor of elastin, are the products of translation of splice-variant mRNAs derived from the single-copy tropoelastin gene. Previous data had demonstrated DNA sequence heterogeneity in three domains of rat tropoelastin mRNA, indicating alternative splicing of several exons of the rat tropoelastin gene. Rat tropoelastin genomic clones encompassing the sites of alternative splicing were isolated and sequenced. Two sites of alternative splicing identified in rat tropoelastin mRNA sequences corresponded to exons 13-15 and exon 33 of the rat tropoelastin gene. Furthermore, the variable inclusion of an alanine codon in exon 16 resulted from two functional acceptor sites separated by three nucleotides. DNA sequences flanking exons subject to alternative splicing were analyzed. These exons contained splicing signals that differed from consensus sequences and from splicing signals of constitutively spliced exons. Introns immediately 5' of exons 14 and 33, for example, lacked typical polypyrimidine tracts and had weak, overlapping branch point sequences. Further, a region of secondary structure encompassing the acceptor site of exon 13 may influence alternative splicing of this exon. These results demonstrate that multiple cis-acting sequence elements may contribute to alternative splicing of rat tropoelastin pre-mRNA.     

Heparan sulphate interacts with tropoelastin, with some tropoelastin peptides and is present in human dermis elastic fibers.

A number of reports point to the presence of proteoglycans and/or glycosaminoglycans within elastic fibers in normal and in pathological conditions. We present data that heparan sulphate (HS)-containing proteoglycans are associated with normal elastic fibers in human dermis and that isolated HS chains interact in vitro with recombinant tropoelastin and with peptides encoded by distinct exons of the human tropoelastin gene (EDPs). By immunocytochemistry, HS chains were identified as associated with the amorphous elastin component in the human dermis and remained associated with the residual elastin in the partially degenerated fibers of old subjects. HS appeared particularly concentrated in the mineralization front of elastic fibers in the dermis of patients affected by pseudoxanthoma elasticum (PXE). In in vitro experiments, HS induced substantial changes in the coacervation temperature and in the aggregation properties of recombinant tropoelastin and of synthetic peptides (EDPs) corresponding to sequences encoded by exons 18, 20, 24 and 30 of the human tropoelastin gene. In particular, HS modified the coacervation temperature and favoured the aggregation into ordered structures of tropoelastin molecules and of EDPs 18, 20 and 24, but not of EDP30. These data strongly indicate that HS-elastin interactions may play a role in tissue elastin fibrogenesis as well as modulating elastin stability with time and in diseases.     

The secretion of tropoelastin by chick-embryo artery cells.

Chymotryptic fingerprint analyses of tropoelastin a and tropoelastin b demonstrated a very close relationship between these two polypeptides synthesized in a cell-free system under the direction of chick-embryo polyribosomal mRNA. A similar study on tropoelastin polypeptides extracted in their hydroxylated and under-hydroxylated forms from artery cells incubated with [3H]valine in the absence and presence of alpha alpha'-bipyridine or 3,4-dehydroproline confirmed this close relationship and suggested that tropoelastins a and b are likely to be the products of a single gene. Pulse-chase experiments in which the synthesis and secretion of tropoelastin by artery cells were monitored demonstrated that, after a pulse with [3H]proline, the polypeptides rapidly appeared in the medium and the half-time of tropoelastin secretion was approx. 30 min. Further pulse-chase studies, in which [3H]tropoelastin contents of subcellular fractions were determined, showed that rough and smooth microsomal fractions contained maximal amounts of tropoelastin at different times. The quantity of tropoelastin in the smooth-microsomal fraction was always only a small proportion of that in the rough-microsomal fraction, suggesting rapid translocation of the polypeptides to the plasma membrane. Incubation of the cells with 0.1 mM-colchicine did not markedly alter the rate of secretion or the distribution of tropoelastin between the subcellular fractions, whereas when 1 microM-monensin was included in the incubations the polypeptides were retained in the rough microsomal fraction. The results are consistent with the proposal that tropoelastin may follow a pathway of secretion from rough endoplasmic reticulum to the plasma membrane via secretory vesicles.     

Role of polyproline II conformation in human tropoelastin structure

In this review, we present a comprehensive overview of the molecular studies on human tropoelastin domains accomplished by Tamburro and co-workers in the last decade. The used approach is the reductionist approach applied to human tropoelastin and is based on the observation that the tropoelastin gene exhibits a cassette-like organization, with a regular alternation of cross-linking and hydrophobic domains putatively responsible for the elasticity of the protein. The peculiar structure of human tropoelastin gene prompted us to study the isolated domains encoded by the exons of tropoelastin, with the perspective to get deep insights into the structural properties of the whole protein. At the molecular level, the results clearly evidence large flexibility of the polypeptide chains in the hydrophobic domains, which oscillate between rather extended and folded conformations. An important role was assigned to poly-proline II conformation considered as the hinge structure in the dynamic conformational equilibrium suggested for the hydrophobic domains. For the lysine-rich cross-linking domains, the structural studies exactly localized α-helix along the polypeptide sequence. Furthermore, at supramolecular level, these studies showed that several domains are able to self-assemble in two different aggregation patterns, the fibrous elastin-like structure for some proline-rich hydrophobic domains and the amyloid-like for some glycine-rich hydrophobic domains. Accordingly, the studies suggest that the reductionist approach was a valid tool for studying a complex protein, such as elastin, elucidating not only the structure but also the specific role played by its constituent domains.     

Characterization of rat heart tropoelastin

Several overlapping rat tropoelastin cDNA clones were isolated from a lambda gt11 rat heart cDNA library and their nucleotide sequence was determined. The corresponding deduced amino acid sequence of rat tropoelastin revealed strong homology to bovine and human tropoelastins although possessing some unique features including greater size (18%) and composition of repetitive units. Comparison of the amino acid sequence of rat tropoelastin to four other tropoelastin species reveals that the hydrophobic peptide repeat regions in the middle of each molecule and the crosslinking areas containing three lysine residues are remarkably conserved. A possible function for the clustering of three lysine residues in providing a mechanism for the in vivo reduction of dehydrolysinonorleucine via a redox shuttle with dihydrodesmosine is proposed. In addition, the COOH-terminal sequence of the rat tropoelastin is virtually identical to tropoelastins of other species in possessing a cysteine/arginine/lysine containing segment. There are no obvious amino acid insertions or substitutions in the COOH-terminal half of the rat tropoelastin molecule which would signal unique cleavage or glycosylation sites. Examination of the steady-state levels of rat tropoelastin mRNA in 8- and 12-day neonatal lung, heart, and aortic tissues showed that the amount of tropoelastin mRNA was abundant and of similar size (3.9 kb) in all three tissues.     

Significant decrease in tropoelastin gene expression in fibroblasts from a Japanese Costello syndrome patient with impaired elastogenesis and enhanced proliferation

Costello syndrome is a connective tissue disorder associated with sparse, thin, and fragmented elastic fibers in tissues. In this study we demonstrated a significant decrease in the expression of tropoelastin mRNA in fibroblasts derived from a Japanese Costello syndrome patient with impaired elastogenesis and enhanced proliferation. In contrast, there were no changes in expression of the Harvey ras (HRAS), fibrillin-1, fibulin-5, microfibril-associated glycoprotein-1 (MAGP-1), lysyl oxidase (LOX), or 67-kDa non-integrin elastin-binding protein (EBP) gene. The proliferative activity of the Costello fibroblasts was about 4-fold higher than that of the normal and pathological control ones. However, no mutations were detected in the coding region of HRAS mRNA. Transduction of the bovine tropoelastin (bTE) gene with the lentiviral vector restored the elastic fiber formation and decreased the growth rate in the Costello fibroblasts. These results strongly suggest that the defect of human tropoelastin (hTE) gene expression should induce the impaired elastogenesis and enhanced proliferation of Costello fibroblasts, and that a primary cause other than the HRAS gene mutation should contribute to the pathogenesis in the present Costello case.     

Chick tropoelastin isoforms. From the gene to the extracellular matrix

Studies from several laboratories have demonstrated the existence of multiple tropoelasting mRNAs and protein isoforms. The present study was designed to examine the developmental expression of a specific tropoelastin mRNA, its encoded isoform, and the fate of that isoform in the extracellular matrix. A chick genomic DNA library was screened with a chick tropoelastin cDNA. Seven unique, overlapping clones spanning 39 kilobases were isolated. A synthetic oligonucleotide complementary to a variable tropoelastin mRNA sequence was used to identify a 1.5-kilobase PstI-BamHI genomic fragment. Nucleotide sequence data revealed that the putative exon was surrounded by intron sequences possessing canonical splice sites at the exon/intron borders. Using both immunologic and molecular probes specific to the tropoelastin isoform and mRNA, quantitative protein and RNA analyses were performed. Results demonstrate that total tropoelastin mRNAs increased significantly during aortic embryogenesis whereas the amount of mRNA containing the variable exon remained relatively constant. The amount of total tropoelastins within the same developmental period reflect the level of total tropoelastin mRNA. The amount of the tropoelastin isoform containing the variable exon essentially mirrored the corresponding mRNA with the exception that a decrease in the isoform at day 15 was not seen in the mRNA level. Immunoelectron micrographs of 13-day chick aortic tissue using both total and isoform-specific antisera showed ultrastructural localization to definable elastic fibers. Antibodies to the variable tropoelastin isoform occurred preferentially at sites where elastic fiber microfibril structures were evident.     

Degradation of tropoelastin by proteases.

A simple assay is described which is capable of detecting single breaks in purified radioactively labeled tropoelastin after incubation with dilute solutions of proteases. Using this assay we show that tropoelastin is rapidly cleaved by a variety of proteases, including leukocyte and pancreatic clastase, at physiologic pH and ionic strength. The results suggest the possibility that degradation of tropoelastin or other related biosynthetic intermediates may play a role in the pathogenesis of emphysema.     

Molecular orientation of tropoelastin is determined by surface hydrophobicity

Tropoelastin is the precursor of the extracellular protein elastin and is utilized in tissue engineering and implant technology by adapting the interface presented by surface-bound tropoelastin. The preferred orientation of the surface bound protein is relevant to biointerface interactions, as the C-terminus of tropoelastin is known to be a binding target for cells. Using recombinant human tropoelastin we monitored the binding of tropoelastin on hydrophilic silica and on silica made hydrophobic by depositing a self-assembled monolayer of octadecyl trichlorosilane. The layered organization of deposited tropoelastin was probed using neutron and X-ray reflectometry under aqueous and dried conditions. In a wet environment, tropoelastin retained a solution-like structure when adsorbed on silica but adopted a brush-like structure when on hydrophobized silica. The orientation of the surface-bound tropoelastin was investigated using cell binding assays and it was found that the C-terminus of tropoelastin faced the bulk solvent when bound to the hydrophobic surface, but a mixture of orientations was adopted when tropoelastin was bound to the hydrophilic surface. Drying the tropoelastin-coated surfaces irreversibly altered these protein structures for both hydrophilic and hydrophobic surfaces.     

Radioimmunological identification of tropoelastin.

Antiserum was prepared in sheep against insoluble elastin isolated from embryonic-chick aortae. In an indirect immunoprecipitation test, the antiserum reacted quantitatively with small amounts of radioactively labelled purified tropoelastin prepared from embryonic-chick aortae. The antiserum did not cross-react with chick procollagen, and the antiserum uas used to identify radioactively labelled tropoelastin secreted by chick aorta cells in suspension culture.     

Exon 26-coded polypeptide: An isolated hydrophobic domain of human tropoelastin able to self-assemble in vitro

Hydrophobic domains of human tropoelastin are able to aggregate in a variegated manner. Some aggregates have typical features of the whole protein while others show peculiar self-assembling profiles. Among these hydrophobic domains, an important role in the self-assembling properties of tropoelastin in vitro could be assigned to the peptide encoded by exon 26 of the human tropoelastin gene, that, although unstructured in solution, has great tendency to self-assemble in an ordered manner. The present report describes the aggregation properties of this hydrophobic domain of human tropoelastin analysed by different ultra-structural approaches. Transmission electron microscopy shows that the peptide is able to form different aggregation entities from short rods to very long and flexible fibers, depending on the temperature and on the incubation time. At a microm scale, very long fibers as well as fractal aggregation patterns were observed. Data show that the isolated domain encoded by exon 26 of the tropoelastin gene is able to aggregate in a manner very similar to the whole tropoelastin protein. The aggregation properties are due to the peculiar sequence of EX26, and not to its amino acid composition, as evidenced by the supramolecular analysis of a scrambled sequence of exon 26-coded domain of human tropoelastin, showing a quite different aggregation patterns. These findings confirm that specific sequences can play a driving role in the aggregation process of tropoelastin molecule, at least in vitro, and indicate exon 26-encoded domain among these sequences.