Characterization of collagen synthesized by normal and chemically transformed rat liver epithelial cell lines

The characteristics of Ishikawa endometrial cancer cells are modified by substrate topography with cell-like features and the polymer surface

Conventional in vitro culture studies on flat surfaces do not reproduce tissue environments, which have inherent topographical mechanical signals. To understand the impact of these mechanical signals better, we use a cell imprinting technique to replicate cell features onto hard polymer culture surfaces as an alternative platform for investigating biomechanical effects on cells; the high-resolution replication of cells offers the micro- and nanotopography experienced in typical cell–cell interactions. We call this platform a Bioimprint. Cells of an endometrial adenocarcinoma cell line, Ishikawa, were cultured on a bioimprinted substrate, in which Ishikawa cells were replicated on polymethacrylate (pMA) and polystyrene (pST), and compared to cells cultured on flat surfaces. Characteristics of cells, incorporating morphology and cell responses, including expression of adhesion-associated molecules and cell proliferation, were studied. In this project, we fabricated two different topographies for the cells to grow on: a negative imprint that creates cell-shaped hollows and a positive imprint that recreates the raised surface topography of a cell layer. We used two different substrate materials, pMA and pST. We observed that cells on imprinted substrates of both polymers, compared to cells on flat surfaces, exhibited higher expression of β1-integrin, focal adhesion kinase, and cytokeratin-18. Compared to cells on flat surfaces, cells were larger on imprinted pMA and more in number, whereas on pST-imprinted surfaces, cells were smaller and fewer than those on a flat pST surface. This method, which provided substrates in vitro with cell-like features, enabled the study of effects of topographies that are similar to those experienced by cells in vivo. The observations establish that such a physical environment has an effect on cancer cell behavior independent of the characteristics of the substrate. The results support the concept that the physical topography of a cell’s environment may modulate crucial oncological signaling pathways; this suggests the possibility of cancer therapies that target pathways associated with the response to mechanical stimuli.

The Non-coding 3′UTR of CD44 Induces Metastasis by Regulating Extracellular Matrix Functions

The importance of non-coding RNA transcripts in regulating microRNA (miRNA) functions, especially the 3′ untranslated region (UTR), has been revealed in recent years. Genes encoding the extracellular matrix normally produce large mRNA transcripts including the 3′UTR. How these large transcripts affect miRNA functions and how miRNAs modulate the extracellular matrix (ECM) protein expression are largely unknown. Here, we demonstrate that the over-expression of the CD44 3′UTR results in enhanced cell motility, invasion and cell adhesion in human breast carcinoma cell line MDA-MB-231. Furthermore, we found that expression of the CD44 3′UTR enhances metastasis in vivo. We hypothesized that the increased expression of the CD44 3′UTR affected miRNA binding and modulated synthesis of the extracellular matrix. Computational analysis indicated that miRNAs that interact with the CD44 3′UTR also have binding sites in other matrix encoding mRNA 3′UTRs, including collagen type 1α1 (Col1α1) repressed by miR-328 and fibronectin type 1 (FN1) repressed by miR-512-3p, miR-491 and miR-671. Protein analysis demonstrated that expression of CD44, Col1α1, and FN1 were synergistically up-regulated in vitro and in vivo upon transfection of the CD44 3′UTR. The non-coding 3′UTR of CD44 interacts with multiple miRNAs that target extracellular matrix properties and thus can be used to antagonize miRNA activities.

Carcinomas contain a matrix metalloproteinase-resistant isoform of type I collagen exerting selective support to invasion

Collagen fibers affect metastasis in two opposing ways, by supporting invasive cells but also by generating a barrier to invasion. We hypothesized that these functions might be performed by different isoforms of type I collagen. Carcinomas are reported to contain alpha1(I)(3) homotrimers, a type I collagen isoform normally not present in healthy tissues, but the role of the homotrimers in cancer pathophysiology is unclear. In this study, we found that these homotrimers were resistant to all collagenolytic matrix metalloproteinases (MMP). MMPs are massively produced and used by cancer cells and cancer-associated fibroblasts for degrading stromal collagen at the leading edge of tumor invasion. The MMP-resistant homotrimers were produced by all invasive cancer cell lines tested, both in culture and in tumor xenografts, but they were not produced by cancer-associated fibroblasts, thereby comprising a specialized fraction of tumor collagen. We observed the homotrimer fibers to be resistant to pericellular degradation, even upon stimulation of the cells with proinflammatory cytokines. Furthermore, we confirmed an enhanced proliferation and migration of invasive cancer cells on the surface of homotrimeric versus normal (heterotrimeric) type I collagen fibers. In summary, our findings suggest that invasive cancer cells may use homotrimers for building MMP-resistant invasion paths, supporting local proliferation and directed migration of the cells whereas surrounding normal stromal collagens are cleaved. Because the homotrimers are universally secreted by cancer cells and deposited as insoluble, MMP-resistant fibers, they offer an appealing target for cancer diagnostics and therapy.

Procollagen Alpha 1 Type I: A Potential Aide in Histopathological Grading of Glioma

Collagen type I production has been shown to play a role in malignant transformation. We examined procollagen type I expression in brain tumors and with histopathological grading. Expression levels of procollagen alpha 1 type 1 were determined in 5 glioma cell lines by RT-PCR, Northern, and Western blot analysis. In addition, 41 primary brain tumors and 2 metastatic lung cancers to the brain were examined by PCR. Of the 5 glioma cell line analyzed, 3 (glioma 1, SW-1783 and U-118) expressed procollagen alpha 1 type I and were sensitive to vitamin D3 (VD3). In contrast, 2 of the cell lines (U-373 and T-98G) lacked procollagen alpha 1 type 1 expression. In patients' samples, 14 of 15 anaplastic and low grade gliomas expressed procollagen alpha 1 type I, and 12 of the 14 expressed high levels. In contrast, only 12 of 21 high grade gliomas from patients expressed procollagen alpha 1 type1 and among these, only 4 of the 12 expressed high levels. Thus, there is an inversed correlation between procollagen alpha 1 type 1 expression and histopathological grading (R2=- 0.56, p=0.0005). Our data suggest that procollagen alpha 1 type I expression occurs more commonly in intermediate and low grade gliomas and may assist in histopathological grading.

Collagen alpha1(I) gene (COL1A1) is repressed by RFX family

Collagen type I is composed of three polypeptide chains transcribed from two separate genes (COL1A1 and COL1A2) with different promoters requiring coordinate regulation. Our recent publications, centering on COL1A2 regulation, demonstrate that methylation in the first exon of COL1A2 at a regulatory factor for X box (RFX) site (at -1 to +20) occurs in human cancer cells and correlates with increased RFX1 binding and decreased collagen transcription (Sengupta, P. K., Erhlich, M., and Smith, B. D. (1999) J. Biol. Chem. 274, 36649-36655; Sengupta, S., Smith, E. M., Kim, K., Murnane, M. J., and Smith, B. D. (2003) Cancer Res. 63, 1789-1797). In normal cells, RFX5 complex along with major histocompatibility class II transactivator (CIITA) is induced by interferon-gamma to occupy this site and repress collagen transcription (Xu, Y., Wang, L., Buttice, G., Sengupta, P. K., and Smith, B. D. (2004) J. Biol. Chem. 279, 41319-41332). In this paper, we demonstrate that COL1A1 has an RFX consensus binding site surrounding the transcription start site (-11 to +10) that contains three methylation sites rather than one in the COL1A2 gene RFX binding site. RFX1 interacts weakly with the unmethylated COL1A1 site, and binds with higher affinity to the methylated site. RFX1 represses the unmethylated COL1A1 less efficiently than COL1A2. COL1A1 promoter activity is sensitive to DNA methylation and the COL1A1 gene is methylated in human cancer cells with coordinately decreased collagen expression. The DNA methylation inhibitor, 5-aza-2'-deoxycytidine (aza-dC) increases collagen gene expression with time in human cancer cells. On the other hand, RFX5 interacts with both collagen type I genes with a similar binding affinity and represses both promoters equally in transient transfections. Two dominant negative forms of RFX5 activate both collagen genes coordinately. Finally, CIITA RNA interference experiments indicate that CIITA induction is required for interferon gamma-mediated repression of both collagen type I genes.

Independent Downstream Gene Expression Profiles in the Presence of Estrogen Receptor α or β1

The two known forms of estrogen receptor (ER), alpha and beta, exhibit differences in structure, affinity for certain ligands, and tissue distribution, suggesting differential roles. It is of interest from several perspectives to determine whether the two receptors elicit similar or differing responses within the same cell type in the presence of the same ligand. To evaluate roles of ER, we have examined responses to estrogen in a rat embryonic fibroblast cell line model, normally naive to ER, engineered to stably express ERalpha or ERbeta. Rat1+ERalpha, Rat1+ERbeta, and precursor Rat1 cell lines were treated with estradiol-17beta (E(2); 1 nM) or an ethanol vehicle for 24 h. Total RNA was extracted, and cDNA generated and subjected to suppression subtractive hybridization (SSH), followed by differential screening using dot blot hybridization. In the presence of ERalpha, products were identified that represent classic responses to E(2), including markers for cell proliferation. In the presence of ERbeta, an alternate transcription profile was observed, including upregulation of pro-alpha-2(I) collagen. These data support a model in which ERalpha and ERbeta regulate unique subsets of downstream genes within a given cell type.

A methylation-responsive MDBP/RFX site is in the first exon of the collagen alpha2(I) promoter

DNA methylation inhibits transcription driven by the collagen alpha2(I) promoter and the 5' end of the gene in transient transfection and in vitro transcription assays. DNA-binding proteins in a unique family of ubiquitously expressed proteins, methylated DNA-binding protein (MDBP)/regulatory factor for X box (RFX), form specific complexes with a sequence overlapping the transcription start site of the collagen alpha2(I) gene. Complex formation increased when the CpG site at +7 base pairs from the transcription start site was methylated. The identity of the protein was demonstrated by co-migration and cross-competition for a characteristic slowly migrating doublet complex formed on MDBP/RFX recognition sequences and the collagen sequences by band shift assays. A RFX1-specific antibody supershifted the collagen DNA-protein complexes. Furthermore, in vitro translated RFX1 protein formed a specific complex with the collagen sequence that was also supershifted with the RFX1 antibody. MDBP/RFX displayed a higher affinity binding to the collagen sequence if the CpG at +7 was mutated in a manner similar to TpG. This same mutation within reporter constructs inhibited transcription in transfection and in vitro transcription assay. These results support the hypothesis that DNA methylation-induced inactivation of collagen alpha2(I) gene transcription is mediated, in part, by increased binding of MDBP/RFX to the first exon in response to methylation in this region.

Methylation in the initiation region of the first exon suppresses collagen pro-alpha2(I) gene transcription

Our previous studies demonstrated that the collagen alpha2(I) gene is hypermethylated in the promoter/first exon region after chemical transformation and the alpha2(I) promoter/first exon is sensitive to methylation in transfection studies. In this paper, we demonstrate that a minimum collagen promoter containing the preinitiation region (-41 to +54) driving luciferase reporter gene was inactivated by DNA methylation as judged by transfection assays. All the methylation sites within the preinitiation region were located in the first exon, not in the promoter. Methylation of the promoter construct inhibited transcription as determined by an in vitro assay, only if proteins were extracted from nuclei using 500 mM NaCl. Gel mobility shift analysis suggested that methylation within the first exon decreased the formation of the largest preinitiation complex while increasing the formation of faster migrating protein-DNA complexes. Competition gel mobility shift analysis indicated that the faster migrating protein-DNA complex could be competed by a smaller initiator probe which did not contain TATA binding region. A protein-DNA complex with increased affinity to methylated sequences was detected using the initiator probe, which contained two methylation sites and no TATA sequence (-25 to 30) suggesting that a separate repressor complex binds to the methylated sequences. Mutations at the methylation sites (+7, +23) in the first exon also increased the protein-DNA complex formation in gel shift analysis and inhibited collagen alpha2(I) transcription as judged by transient transfection and in vitro transcription assays. Therefore, these methylation sites in the preinitiation region are important for transcription of alpha2(I) gene and the protein responsible for the repression of transcription is extractable using high salt nuclear extracts.

Relationships between translation of pro alpha1(I) and pro alpha2(I) mRNAs during synthesis of the type I procollagen heterotrimer

Final assembly of the procollagen I heterotrimeric molecule is initiated by interactions between the carboxyl propeptide domains of completed, or nearly completed nascent pro alpha chains. These interactions register the chains for triple helix folding. Prior to these events, however, the appropriate nascent chains must be brought within the same compartments of the endoplasmic reticulum (ER). We hypothesize that the co-localization of the synthesis of the nascent pro alpha1(I) and pro alpha2(I) chains results from an interaction between their translational complexes during chain synthesis. This has been investigated by studying the polyribosomal loading of the pro alpha-chain messages during in vitro translation in the presence and absence of microsomal membranes, and in cells which have the ability to synthesize the pro alpha1 homotrimer or the normal heterotrimer. Recombinant human pro alpha1(I) and pro alpha2(I) cDNAs were inserted into plasmids and then transcribed in vitro. The resulting RNAs were translated separately and in mixture in a cell-free rabbit reticulocyte lysate +/- canine pancreatic microsomes. Cycloheximide (100 mu g/ml) was added and the polysomes were collected and fractionated on a 15-50% sucrose gradient. The RNA was extracted from each fraction and the level of each chain message was determined by RT-PCR. Polysomes from K16 (heterotrimer-producing), W8 (pro alpha1(I) homotrimer), and A2' (heterotrimer + homotrimer) cells were similarly analyzed. Translations of the pro alpha1(I) and pro alpha2(I) messages proceeded independently in the cell-free, membrane-free systems, but were coordinately altered in the presence of membrane. The cell-free + membrane translation systems mimicked the behavior of the comparable cell polysome mRNA loading distributions. These data all suggest that there is an interaction between the pro alpha chain translational complexes at the ER membrane surface which temporally and spatially localize the nascent chains for efficient heteromeric selection and folding.

Nicotine regulates collagen gene expression, collagenase activity, and DNA synthesis in cultured cardiac fibroblasts

Cardiac fibroblasts that reside in the interstitium are the cellular origin of collagen and other proteins of the extracellular matrix in the heart. We have previously shown that in vitro gene expression, proliferation and even phenotypic features of cardiac fibroblasts are subject to regulation by biological factors such as hormones, growth factors and neurotransmitters. The influence of nicotine, the active ingredient of tobacco, on risk factors for cardiac diseases is well known. In vivo adverse effects of nicotine are as the result of its direct and indirect effects. The cellular and molecular mechanisms of direct effects of nicotine in the heart are widely unknown. The objective of this study was to investigate if nicotine has direct influence on cardiac fibroblasts. To this end, we studied the effects of nicotine on cultured cardiac fibroblasts. Northern hybridization analysis of RNA extracted from cardiac fibroblasts, enzymography of conditioned medium of cardiac fibroblasts and [3H]-thymidine incorporation into DNA of cardiac fibroblasts were used to examine the effects of nicotine on collagen gene expression, collagenase activity and DNA synthesis respectively. Treatment of cardiac fibroblasts with nicotine (10 micrograms/ml) led to a 31% (P < 0.05) decrease in the abundance of mRNA for pro alpha 1(I) but not pro alpha 2(I) collagen compared with control untreated cells. Nicotine treatment of cardiac fibroblasts also led to decreased collagenase activity (62%, P < 0.001) in the conditioned medium of those cells in culture. Studies with [3H]-thymidine incorporation into DNA of cardiac fibroblasts showed a nicotine-induced decrease (39%, P < 0.001) in DNA synthesis in those cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of the neomycin-resistance (neo) gene induces alterations in gene expression and metabolism

The amino 3'-glycosyl phosphotransferase (neo) gene is the selectable marker most widely used in stable transfection or infection protocols. Because the neo gene product has phosphotransferase activity, it might modify the phosphorylation state when introduced in mammalian cells. NIH-3T3 fibroblast cells expressing the neo gene, after either infection with retroviral vectors or transfection with plasmids, showed a 50% reduction in both fructose 2,6-bisphosphate (Fru 2,6-P2) concentration and lactate production compared with control NIH-3T3 cells, indicating that these neo-expressing cells are less glycolytic. In addition, a marked decrease in the levels of mRNA for the procollagen 1 alpha and fibronectin genes was also observed in neo-expressing NIH-3T3 cells. This decrease was concomitant with an increase in the mRNA concentration of the endogenous c-myc gene. FTO-2B rat hepatoma cells also showed modifications in gene expression when the neo gene was introduced by stable transfection or infection. In these cells an increase in both P-enolpyruvate carboxykinase (PEPCK) and tyrosine aminotransferase (TAT) mRNA was observed. These results suggest that neo gene expression may induce changes in the cells, which should be considered when neo-selected cells are used to deliver specific genes in different therapy approaches and in embryo manipulation.

Type I collagen formation in rat type II alveolar cells immortalised by viral gene products

BACKGROUND

Alveolar type II (T2) cells synthesise matrix proteins such as type IV collagen and fibronectin. In contrast, a fetal rat T2 cell line has been shown to synthesise type I and III collagen as well as type IV collagen. To study regulation of collagen production in T2 cells, neonatal T2 cells immortalised by adenoviral 12SE1A gene transfer were used. It was previously reported that this immortalised cell line (E1A-T2) retains epithelial features such as tight junctions and cytokeratins but also expresses mesenchymal features such as vimentin.

METHODS

Collagen production was examined in E1A-T2 and primary neonatal T2 cells using polyacrylamide gel electrophoresis. Electron microscopy was used to examine collagen deposition in E1A-T2 cell culture. To define the mechanism by which alpha 1(I) type I collagen gene expression was activated in E1A-T2 cells, a deletional analysis of alpha 1(I) promoter constructs linked to the bacterial chloramphenicol acetyltransferase gene was performed.

RESULTS

E1A-T2 cells produced large amounts of type I collagen with a predominance of alpha 1(I) homotrimers; alpha 2(I) peptides were detected only in the cell layer. In contrast, primary neonatal rat T2 cell cultures produced a trace amount of type I collagen. Production of alpha 1(I) peptide chains (per microgram DNA) in E1A-T2 cell cultures was 30 times higher than that observed in primary neonatal T2 cell cultures. Electron microscopy showed deposition of type I collagen fibrils in the extracellular matrix of E1A-T2 cell cultures. Transfection studies suggested at least two cis-acting elements which mediate increased alpha 1(I) gene expression in E1A-T2 cells.

CONCLUSIONS

These studies indicate that the E1A-T2 cell line may be useful for studying type I collagen gene regulation in alveolar T2 cells. These findings also raise the possibility that viral activation of type I collagen genes in alveolar epithelium may be involved in certain forms of pulmonary fibrosis.

Expression of alpha 2 type I collagen in W8 cells increases cell adhesion and decreases colony formation in soft agar

A chemically transformed cell line, W8, produces alpha 1(I) homotrimers with no alpha 2(I) chains whereas the parent cell line, K16, produces heterotrimers. When W8 cells were transfected with plasmid constructs containing the full length human alpha 2(I) cDNA driven by viral promoters, the cells expressed alpha 2(I) collagen chains forming varying amounts of heterotrimers. Previously, we have shown that K16 and W8 cells have different growth characteristics (Smith, B.D. et al., Cancer Research 43: 4275-4282, 1983) including population doubling, saturation density, cell adhesion and colony formation in soft agar. These parameters were tested for each transfected cell line in order to determine if the alpha 2(I) expression and heterotrimer formation alters cell characteristics. The cells expressing alpha 2(I) forming heterotrimers needed higher concentrations of trypsin or longer time periods to lift from the plate suggesting a role for alpha 2(I) in cell adhesion. The W8 cells formed colonies in soft agar exhibiting anchorage independent growth. However, W8 cells expressing alpha 2(I) chains formed less colonies in soft agar than W8 cells or W8 cells transfected with a neomycin resistant gene indicating that the alpha 2(I) producing cells were less anchorage independent than W8 cells. Population doubling time, morphology and saturation densities were similar to W8 cells with small alterations towards an epithelial morphology. These results demonstrated that alpha 2(I) within heterotrimer is important for cell adhesion and anchorage independent growth.

Electron and fluorescence microscopic investigations on composition and structure of the epithelial basement membrane of the human inferior nasal concha

Light and electron microscopic as well as immunohistochemical investigations were performed on the basement membrane (BM) of the nasal mucosa from the inferior nasal conchae of 20 patients, aged 15-50 years. Two of the patients served as controls. Clinical disorders requiring the turbinectomies were hyperplastic nasal inferior conchae (17 patients) and immobile cilia syndrome (1 patient). In all cases light microscopy demonstrated a 10-15 microns thick homogeneous BM underneath an intact epithelium. Electron microscopic findings revealed a typical subepithelial basal lamina (BL). The remaining parts of the BM consisted of single, isolated 25-mm-thick collagenous fibrils. Only a few cells and small unmyelinated nerves occurred in this layer. Immunohistochemical investigations showed BL components (collagen type IV, laminin, nidogen and heparan sulfate proteoglycan) directly underneath the epithelium. Collagen types I, III, V, and VI could also be demonstrated immunohistochemically in the remaining parts of the BM. Collagen type VII was allocated to the anchor filaments beneath the BL. This special BM is presumed to contribute to mechanical stabilization of the epithelium. The significance of the BL and the subepithelial connective tissue for the behavior of the epithelium--e.g. direction of differentiation--are discussed.

Transforming growth factor beta and the cell surface in tumor progression

Type 1 transforming growth beta (TGF-beta 1) is a multifunctional regulator of cellular differentiation, motility and growth. It is capable of inhibiting or stimulating these processes depending on cell type, cell density, culture conditions and TGF-beta 1 concentration. TGF-beta 1 regulates growth, in part, by inducing the expression and secretion of various types of collagen, which participate in the control of cell adhesion and migration, as well as growth. TGF-beta 1 also regulates cell growth by controlling the response to epidermal growth factor (EGF) and other growth factors, in ways that can either decrease or increase their growth-promoting effects. Alterations in both negative and positive growth responses to TGF-beta 1 play important roles in tumor progression. Loss of sensitivity to growth inhibition by TGF-beta 1 can occur as a result of decreased expression of collagen. Acquisition of sensitivity to growth stimulation, and autocrine transformation by TGF-beta 1, are associated with aberrant EGF receptor regulation. Aberrant growth factor receptor regulation by TGF-beta 1 may be mediated by a protein kinase C (PKC)-dependent pathway which inhibits degradation of growth factor receptor/ligand complexes. The evidence reviewed is consistent with a minimal two-step mechanism for autocrine transformation, which involves production of growth factor and enhanced cellular response as a result of aberrant membrane traffic. Defects in membrane traffic regulation may provide an explanation for common alterations in tumor cell response to both multiple growth inhibitors and growth stimulators, and may also suggest novel approaches to cancer chemotherapy.

Parallel regulation of procollagen I and colligin, a collagen-binding protein and a member of the serine protease inhibitor family

A potential regulatory linkage between the biosynthesis of colligin, a collagen-binding protein of the ER, and procollagen I was examined under a variety of experimental conditions. Cell lines which did not produce a significant amount of procollagen I mRNA also lacked the capacity to produce colligin mRNA. Anchorage-dependent cell lines like L6 myoblasts and normal rat kidney fibroblasts produced both colligin and procollagen I mRNA, but the level of both was concurrently reduced considerably in their ras-transformed counterparts. Similarly, during the differentiation of L6 myoblasts, levels of both colligin and procollagen declined together. Treatment of myoblasts by dexamethasone or EGF led to a decrease in the steady-state levels of procollagen I mRNA, and this was, again, accompanied by a decrease in colligin mRNA synthesis. On the other hand, when the rate of procollagen I synthesis was stimulated by treatment of myoblasts with TGF beta, it led to the concurrent augmentation of both the mRNA and protein levels of colligin. A linkage between the regulation of synthesis of procollagen I and colligin thus seems to exist. The only exception to this generalization is provided by the heat induction behavior of the two proteins. Treatment of myoblasts for a very short period leads to an increase in the synthesis of both the mRNA and protein levels of colligin. This, however, is not accompanied by a change in the mRNA levels of procollagen I. These studies establish that colligin and procollagen are generally tightly co-regulated except after heat shock, suggesting an important functional linkage.

DNA methylation inhibits transcription of procollagen alpha 2(I) promoters

Our previous studies have demonstrated that a 2-[N-(acetoxyacetyl)amino]fluorene-transformed rat epithelial-like cell line, W8, contains a transcriptionally inactive alpha 2(I) gene with a hypermethylated promoter/first-exon region. We have cloned the rat promoter/first-exon region (-211 to +207) from W8 cells and their parent cell line, K16, which expresses alpha 2(I) collagen. There were no sequence differences between the clones from the two cell lines, indicating that a mutation was not responsible for transcriptional inhibition. The alpha 2(I) rat promoters were cloned upstream of the chloramphenicol acetyltransferase gene. Both constructs were equally active in both cell lines, suggesting that trans-activating factors for alpha 2(I) transcription are present in W8 cells. Finally, methylation of plasmids at all CpG sites with SssI methylase completely inhibited transcription using alpha 2(I) promoters, but methylation did not inhibit simian-virus-40 promoter-driven transcription. Certain methylation sites partially inhibit promoter activity. An HhaI methylation site inhibited transcriptional activity of the alpha 2(I) promoter 8-fold, whereas methylation at the HpaII site in the rat alpha 2(I) promoter did not decrease transcriptional activity. This provides further evidence that methylation at specific sites in the collagen alpha 2(I) promoter is responsible for the inactivation of transcription in W8 cells.

Immunohistochemical localization of collagenous components in healthy periodontal tissues of the rat and marmoset (Callithrix jacchus). I. Distribution of collagen types I and III

The distribution of collagen types I and III was demonstrated in healthy periodontal tissues of the rat and marmoset using immunofluorescent localization after decalcification of the maxillae and mandiblae in 0.2 N HCl. An intense fluorescence in the alveolar bone and cementum matrix, as well as in the soft periodontal tissue, was demonstrated with anti-collagen type I antibodies. In the gingival connective tissue and in the periodontal ligament thick fibers of collagen type I could be observed. The fluorescent reaction in the rat periodontal ligament was not strong in comparison to the marmoset periodontal ligament. Sharpey's fibers, inserting into the cementum and alveolar bone, were also stained. On the other hand, collagen type III could not be demonstrated in the hard periodontal tissues, but could be in the bone marrow stroma and the incremental lines as well as around the Sharpey's fibers of the cementum, in accordance to previous studies. In the gingival connective tissue a strong staining was evident, especially near the basement membrane. The periodontal ligament showed an intense fluorescence that was, in some areas, continuous with Sharpey's fibers inserting into the cementum. The distribution of collagen types I and III was demonstrated with immunohistochemical techniques in the rat and marmoset periodontium. These results provide necessary information on healthy tissues that will be required for future studies on the effects of pathological, reparative and regenerative processes.

Methylation of the alpha 2(I) collagen gene in chemically transformed rat liver epithelial cells

W8 cells, 2-N-(acetoxyacetyl)aminofluorene-transformed rat liver epithelial-like cells, secrete no alpha 2(I) collagen chains. This paper reports the first demonstration of DNA methylation in the promoter-5' region of an alpha 2(I) collagen gene which occurs in W8 cells. Since inhibition of methylation by azacytidine induces transcription of the alpha 2(I) gene, DNA methylation of W8 alpha 2(I) promoter-5' region could contribute to altered collagen production in these cells.

Changes in albumin, alpha-fetoprotein and collagen gene transcription in CCl4-induced hepatic fibrosis

In efforts to understand mechanisms of liver dysfunction in cirrhosis, transcription of specific genes important to liver function has been measured in the rat model of CCl4-induced hepatic fibrosis. The relative transcription rates of albumin, alpha-fetoprotein and pro-alpha 1-collagen genes were studied during development of fibrosis and after fibrosis was established. During the initial phase of CCl4 administration, there was a decrease in albumin transcription associated with increased alpha-fetoprotein transcription, indicative of active liver regeneration. However, later during development of fibrosis, the response pattern of these genes was different, as albumin gene transcription was normal or increased and alpha-fetoprotein gene transcription was no longer increased. Three weeks after completion of CCl4 treatment (fully established cirrhosis), albumin genes responded normally or hypernormally to an acute regenerative stimulus, but the alpha-fetoprotein gene was again not measurably responsive. Pro-alpha 1-collagen gene transcription increased during the entire fibrogenic process and remained elevated after cirrhosis was established. These studies suggest that a switch from albumin to alpha-fetoprotein gene transcription can serve as a marker of liver regenerative capacity, and that this process is altered during and after development of hepatic fibrosis. The fibrogenic process is also associated with elevated transcription of collagen genes.

Synthesis of type III collagen by cultured kidney epithelial cells

Studies have been performed to evaluate both the relative amounts and molecular forms of the collagens synthesized by an established line of cultured rat kidney epithelial (clone NRK52E) cells. The collagens secreted into the culture medium and extracted from the cell layers of cultured NRK52E cells were isolated after limited pepsin digestion and differential salt fractionation. Greater than 95% of the collagenous proteins synthesized by NRK52E cells were found to be associated with the cells and not secreted. Polyacrylamide gel electrophoresis under denaturing conditions of the NRK52E cell collagens indicated the presence of components exhibiting properties corresponding to those of the chains present in types I, III, IV and V collagen. Analysis of each fraction by carboxymethyl-trisacryl chromatography revealed that approximately two-thirds of the total collagen synthesized by NRK52E cells was type III. Of the remaining collagen types I, IV and V molecules represented 20%, 4% and 10% respectively, of the total produced. Essentially all of the type I collagen produced by NRK52E cells was recovered as the type I-trimer, whereas the type V molecules synthesized by NRK52E cells had the molecular compositions of [alpha 1(V)]2 alpha 2(V) and alpha 1(V)alpha 2(V)alpha 3(V). These data establish the relative proportions and molecular forms of the collagens synthesized by cultured NRK52E cells. Furthermore, these findings suggest that NRK52E cells may be a useful in vitro model for investigating the regulation of changes in collagen biosynthesis occurring under situations of renal epithelial cell injury.

Dynamics of collagen accumulation and activity of collagen-degrading enzymes in the liver of rats with carbon tetrachloride-induced hepatic fibrosis

Liver fibrosis in rats was induced by repeated subcutaneous injections of carbon tetrachloride. Total collagen, soluble and insoluble collagen fractions as well as type I and type III collagen content in the liver were subsequently measured over a 3-18 week period. Liver collagen was found to increase exponentially during this time. Insoluble collagen accumulated more rapidly than soluble forms, and the accumulation of type III collagen was relatively greater than type I collagen. Changes in specific liver enzymes were also observed. Collagenase, collagenolytic cathepsin and collagen peptidase activities all increased. Levels of collagen-degrading enzymes increased rapidly during the first weeks of fibrosis-induction, and were followed by a more gradual increase during the remainder of the study.

Development of molecular hybridization technology to evaluate albumin and procollagen mRNA content in baboons and man

We have developed the methodology for evaluating the effects of pathophysiological conditions on the molecular mechanisms of hepatic protein synthesis and fibrogenesis in baboons and man. Total RNA was extracted from percutaneous liver biopsies of five baboons who were chronically fed an ethanol-rich liquid diet, their pair-fed controls and from humans with a variety of liver abnormalities. Chronic alcohol administration in baboons with liver fibrosis and normal serum albumin levels increased in vitro protein synthesis as measured by [35S]methionine incorporation, albumin mRNA content and Type I procollagen mRNA content. There was no difference in the beta-actin (a constitutive protein) mRNA content. In humans, serum albumin levels correlated with albumin mRNA content as indicated by the intensity of dot blot hybridization and Type I procollagen mRNA levels correlated with the activity of liver fibrosis. The use of RNA-DNA hybridization to investigate procollagen mRNA from human biopsies appears to be a valuable tool for evaluating the potential for collagen synthesis and the future course of liver disease. Besides the use of RNA-DNA hybridization, we describe other methodologies which are useful in delineating the levels of gene expression responsible for hepatic mRNA regulation in normal liver and disease states in man. The use of molecular techniques to evaluate human liver disease provides an opportunity to develop clinically relevant information while at the same time offering the additional advantage of providing fundamental knowledge about fibrogenesis.

Phenotypic differences in subclones and long-term cultures of clonally derived rat bone cell lines

Previous studies with clonally derived populations of cells have shown that cells released from embryonic rat calvaria by enzymatic digestion are heterogeneous with respect to their hormone responsiveness, morphology, and production of matrix components [Aubin JE et al; J. Cell Biol 92:452, 1982]. Several of these clonal populations have been used to study the effects of long-term culture and inter- and intraclonal cell heterogeneity. During continuous subculture, marked changes in collagen synthesis were observed in two clonal populations. Both of these clones were originally responsive to parathyroid hormone (PTH) and synthesized primarily type I collagen with small amounts of type III and V collagens, although one clone (RCJ 3.2) had a fibroblastic morphology whereas the second clone (RCB 2.2) displayed a more polygonal shape. Following routine subculture over 3 yr, clone RCB 2.2 was found to synthesize exclusively alpha 1(I)-trimer and not other interstitial collagens. When the same cells were maintained at confluence for 1-2 wk, however, they also synthesized type III collagen. Whereas RCJ 3.2 did not show such dramatic changes in collagen synthesis after long-term subculture, two subclones derived from RCJ 3.2 were found to synthesize almost exclusively either type III collagen (RCJ 3.2.4.1) or type V collagen (RCJ 3.2.4.4). Immunocytochemical staining indicated that both subpopulations also produced type IV collagen, laminin, and basement membrane proteoglycan, proteins that are typically synthesized by epithelial cells. The differences in collagen expression by the various clonal cell populations were accompanied by qualitative and quantitative differences in other secreted proteins and differences in cell morphology. The results demonstrate both the inter- and intraclonal heterogeneity of connective tissue cells and their diverse potentiality with respect to extracellular matrix synthesis.

Early cellular events in pulmonary fibrosis

In this review we have surveyed recent investigations of early cellular events in pulmonary fibrosis both in animal models and in human diseases. Analysis of the interactions of the numerous cell types in the lung following injury is an almost overwhelmingly complex enterprise. In the animal models experimental design has a profound effect on results, making it difficult to compare studies when species, fibrogenic agent, dose, route of exposure, schedule of administration, time course, and analytical methods may not be equivalent. In human diseases we are rarely able to obtain data at precisely the same time point in the course of the disease even among patients in the same study, and possible confounding variables present are legion. Transcending these difficulties for the moment, can we draw any conclusions from our current knowledge of early cellular interactions in pulmonary fibrosis? What is striking is not that there are so many agents that can potentially induce pulmonary fibrosis, but that the lung has such capabilities for recovery. Although the major effector cells may all initially participate in damaging the lung and initiating fibrosis, there is evidence that they may also have the capacity to participate in subsequent repair. Macrophages may initially recruit fibroblasts and stimulate them to proliferate, only to suppress them subsequently. Macrophage production of prostaglandins can lead to suppression of macrophage, neutrophil and lymphocyte responses, thus attenuating tissue injury and the development of fibrosis. Neutrophils may initially release toxic metabolites and enzymes that damage parenchyma. However, there is evidence that they may later play a role in attenuating fibrosis, perhaps through collagenase secretion, or through as yet unknown mechanisms. Lymphocytes may initially participate in a number of damaging ways by secreting chemoattractants for other cells and participating in destructive autoimmune processes. However, there is evidence that subpopulations of T cells may dramatically shift during the course of fibrosis, leading to attenuation of the process. It may thus be useful to consider irreversible pulmonary fibrosis as the end result of a process in which the balance of normal injury/repair mechanisms is disrupted. There is clearly no single "fibrogenic event." Rather, there seem to be a number of places where disruption of balance/repair processes may begin. In diseases of unknown etiology such as sarcoidosis or IPF, loss of control may occur at the genetic level, leading to the destructive alveolitis that is the apparent precursor of fibrosis.(ABSTRACT TRUNCATED AT 400 WORDS)

Localization of type III procollagen aminopeptide antigenicity in hepatocytes from cirrhotic human liver

Immunolocalization of type III procollagen (pro III) in normal and cirrhotic human liver was studied using rabbit antiserum specific for bovine type III procollagen aminopeptide. The material examined was deparaffinized, trypsin-treated hepatic tissue sections from 28 autopsy cases, including 19 cirrhotic and 9 normal liver donors. Immunostaining, performed by the unlabeled peroxidase-antiperoxidase antibody technique demonstrated that extracellular matrices corresponding to perisinusoidal reticulin, collagen in periportal areas, and blood vessel walls were the common sites of pro III antigenicity in both normal and cirrhotic liver. Moreover, in the cirrhotic liver, the fibrous septa of pseudolobules, and cytoplasm of hepatocytes and sinusoidal cells were positive when stained for pro III peptide. The differential counts of pro III positive cells in cirrhotic liver, however, revealed that the average ratio of these hepatocytes to sinusoidal cells was 25 to 1, indicating complete dominance of hepatocytes with respect to stainability for pro III peptide compared to sinusoidal cells. In hepatocellular carcinomas coexisting with cirrhosis, neoplastic cells also displayed pro III antigenicity. These data suggest that hepatocytes of cirrhotic liver and hepatocellular carcinoma cells play a significant role in type III collagen synthesis in vivo.

Changes in collagen and albumin mRNA in liver tissue of mice infected with Schistosoma mansoni as determined by in situ hybridization

We have employed in situ hybridization to evaluate the molecular mechanisms responsible for hypoalbuminemia and increased liver collagen content in murine schistosomiasis. Results were compared using a simplified method of hybridizing isolated hepatocytes from Schistosoma mansoni-infected and normal mouse liver with mouse albumin (pmalb-2) and chick pro-alpha 2(l) collagen (pCg45) probes. Whereas hepatocytes from infected mice showed significantly less albumin mRNA than hepatocytes from control, there were more grains of procollagen mRNA in hepatocytes from infected as compared with control liver. Hybridization of infected liver tissue sections with the collagen probe showed more grains per field in granulomas than in liver regions, whereas with the albumin probe there was more hybridization in liver tissue than in granulomas. These results suggest that in murine schistosomiasis a reduction in albumin mRNA sequence content may be associated with decreased albumin synthesis and ultimately leads to hypoalbuminemia. In addition, although the granuloma seems to be the primary source of type I collagen synthesis, hepatocytes are also capable of synthesizing collagen, especially under fibrogenic stimulation.

Use of in situ hybridization to identify collagen and albumin mRNAs in isolated mouse hepatocytes

We present a simple and improved method for in situ localization of albumin and collagen mRNAs in isolated mouse hepatocytes. The cells were isolated by collagenase perfusion, mincing, and differential centrifugation. Nick-translated 3H-labeled mouse albumin cDNA (pmalb-2) and chicken pro-alpha 2(I) collagen cDNA (pCg45) probes were then hybridized with the cells in silane-treated microcentrifuge tubes. The cells were transferred and fixed to a microscope slide and hybridization was evaluated semiquantitatively by counting exposure of grains in autoradiographic emulsion placed over the cells. With this method of in situ hybridization, all hepatocytes appear to have significant, but highly variable, amounts of albumin mRNA. In addition, type I procollagen mRNA appears to be present at low abundance in hepatocytes. These results indicate that in situ hybridization can effectively demonstrate the presence of specific low- or high-abundance mRNAs in isolated well-differentiated eukaryotic cells.

Loss of type I procollagen gene expression in SV40-transformed human fibroblasts is accompanied by hypermethylation of these genes

Transformation of human lung fibroblasts (WI-38) by Simian Virus 40 (SV40) resulted in a decline of 25-30% in the amount of secreted collagen. The collagen produced by the transformed fibroblasts contained no type I collagen (i.e. alpha 1(I) and alpha 2 chains), which was the major collagen component produced by untransformed fibroblasts. Measurement of the procollagen mRNA levels by dot hybridization with nick-translated procollagen-cDNA clones showed that the absence of type I collagen was due to the absence of alpha 1(I) and alpha 2 procollagen mRNAs. This result was confirmed by hybridization of cDNA to total RNA with southern blots of the procollagen clones. To clarify the mechanism by which type I procollagen gene transcription is abolished in transformed cells, the methylation patterns of the alpha 1(I) and alpha 2 procollagen genes in normal and SV40-transformed fibroblasts were compared, using the chicken alpha 1(I) and alpha 2 procollagen-cDNA clones as probes. Methylated sites were detected by means of the restriction endonuclease isoschizomers HpaII and MspI. Methylation of the procollagen alpha 1(I) and alpha 2 genes was increased in the SV40-transformed fibroblasts, concurrently with the loss of type I collagen synthesis. DNA methylation may thus contribute to altered regulation of gene expression upon cell transformation.

Kinetics of reduction of the intersubunit disulfides of the carboxyl propeptide of type I procollagen

The carboxyl propeptide produced by proteolysis during maturation of type I procollagen to collagen was purified to homogeneity from the medium of cultured chick embryo calvaria by a new method. The propeptide was identified as such by its amino acid composition and migration pattern through sodium dodecyl sulfate-polyacrylamide gels in the absence and presence of dithiothreitol. Reduction of the intersubunit disulfides, which covalently join the two C1 and one C2 polypeptides of the carboxyl propeptide, was studied by incubating the propeptide in the presence of dithiothreitol for various times under nondenaturing conditions at pH 8.2. The reduction process was characterized by the appearance of disulfide-linked dimers. The appearance of dimers correlated with the disappearance of the carboxyl propeptide. Monomers, retaining intrasubunit disulfides, appeared concomitant with dimer formation. Reduction of the intersubunit disulfides of the dimers followed; intrasubunit disulfides were retained. The rate of the first process, trimer to dimer plus monomer, was an order of magnitude larger than the rate for the second process, dimer to monomers. The dimeric intermediates were composed of approximately equivalent amounts of (C1)2 and (C1, C2). The kinetics of formation and reduction of (C1)2 and (C1, C2) could not be differentiated by the techniques used. The relative amounts of intermediates found were not those expected if quasi-equivalent intersubunit disulfides were reduced in a random fashion. A possible model for reduction of the intersubunit disulfides of the propeptide has been proposed, and implications for the intersubunit polypeptide surface contacts have been discussed.

Multiple collagen gene expression with type III predominance in rat mucosal keratinocytes

Collagen synthesis in serially propagated cultures of rat mucosal keratinocytes (line RTK-I) was investigated. Analysis of biosynthetically labeled cell and media proteins retrieved after limited pepsin digestion revealed seven or eight collagen chains originating from four distinct collagens (types I, III, IV, V). Type III collagen was identified as the predominant species based on its electrophoretic and chromatographic behavior in the reduced and unreduced states, on the peptide pattern generated by limited cleavage with CNBr and with trypsin, and on the immunofluorescent detection of intracellular, collagen type III-reactive material. Evidence for the synthesis of two type IV collagen chains (155 k and 160 k after limited pepsin digestion) was provided by immunofluorescent and electrophoretic studies. Type V collagen was revealed by immunofluorescence, and two, possibly three, component chains were resolved in native type V collagen isolated from the harvest medium. Type I collagen, identified by comigration with authentic carriers, was a constant but quantitatively variable synthetic product. This study provides evidence that keratinocytes produce collagens normally found in mesenchymal matrices (type I and III) in addition to collagens characteristic of basement membranes (type IV) and of pericellular structures (type V). These findings reveal a hitherto unrecognized complexity and heterogeneity of the collagens synthesized by a highly differentiated epithelial cell type.