TGF beta in murine morphogenetic processes: the early embryo and cardiogenesis.

The tissue distribution of TGF beta-1 RNA was examined within whole mouse embryos from implantation to 10.5 days gestational age and, in the developing heart, up to 8 days postpartum. The earliest high level expression of TGF beta-1 RNA is at 7.0 days postcoitum (p.c.) in the cardiac mesoderm. At 8.0 days gestational age, cardiac TGF beta-1 RNA expression is limited to endocardial cells. By 9.5 days p.c., this expression pattern becomes regionalized to those cells that overlie cardiac cushion tissue. High TGF beta-1 RNA levels continue to persist in endothelial cells of the heart valves until approximately one week postpartum. The TGF beta-1 RNA distribution was compared with the extracellular distributions of polypeptides for TGF beta and J1/tenascin. As previously reported, endothelial expression of TGF beta-1 RNA is correlated with mesenchymal expression of TGF beta polypeptide, suggesting a paracrine mode of action for this growth factor in cardiac development. Minor discrepancies in the distributions of TGF beta-1 RNA and the extracellular form of the TGF beta polypeptide suggest that translational or post-translational control of protein levels occurs and/or the possibility that the antibody used may also recognise other members of the TGF beta polypeptide family. A correlation between endothelial TGF beta-1 expression and distribution of J1/tenascin in the mesenchyme gives further support to the proposition that the biological effects of TGF beta-1 may, in part, be mediated by J1/tenascin.     

Expression of transforming growth factor beta 2 RNA during murine embryogenesis

We have studied the temporal and spatial expression of transforming growth factor beta 2 (TGF beta 2) RNA in mouse embryos from 10.5 days post coitum (p.c.) to 3 days post partum (p.p.) by in situ hybridization analysis. TGF beta 2 RNA is expressed in a variety of tissues including bone, cartilage, tendon, gut, blood vessels, skin and fetal placenta, and is in general found in the mesenchymal component of these tissues. The expression of TGF beta 2 RNA changes during development in a manner consistent with a role for the gene product in mediating mesenchymal-epithelial interactions.     

Differential expression of TGF beta 1, beta 2 and beta 3 genes during mouse embryogenesis

We have examined by Northern analysis and in situ hybridisation the expression of TGF beta 1, beta 2 and beta 3 during mouse embryogenesis. TGF beta 1 is expressed predominantly in the mesodermal components of the embryo e.g. the hematopoietic cells of both fetal liver and the hemopoietic islands of the yolk sac, the mesenchymal tissues of several internal organs and in ossifying bone tissues. The strongest TGF beta 2 signals were found in early facial mesenchyme and in some endodermal and ectodermal epithelial cell layers e.g., lung and cochlea epithelia. TGF beta 3 was strongest in prevertebral tissue, in some mesothelia and in lung epithelia. All three isoforms were expressed in bone tissues but showed distinct patterns of expression both spatially and temporally. In the root sheath of the whisker follicle, TGF beta 1, beta 2 and beta 3 were expressed simultaneously. We discuss the implication of these results in regard to known regulatory elements of the TGF beta genes and their receptors.     

Comparison of the biological actions of TGF beta-1 and TGF beta-2: differential activity in endothelial cells

Beta transforming growth factor (TGF beta) has multiple in vitro biological effects including stimulation or inhibition of proliferation of specific cell types. A second major form of TGF beta, TGF beta-2, has recently been isolated from porcine platelets, from bovine bone matrix, and from several other sources. The two forms of TGF beta are biologically equipotent with the exception that TGF beta-2 was much less active than TGF beta-1 for inhibition of proliferation of a rat pleuripotent hematopoietic stem cell line. During the purification of beta TGF from bone, we obtained two fraction pools that differed in their ability to inhibit 3H-thymidine incorporation into aortic endothelial cells (AEC). We therefore compared highly purified TGF beta-1 and TGF beta-2 isolated from porcine platelets for inhibition of DNA synthesis in mink lung epithelial cells (MvILu), and in AEC, and for stimulation of 3H-thymidine incorporation in calvarial bone cells (CBC) in 3 experiments. TGF beta-1 and TGF beta-2 inhibited cell proliferation in MvILu with no significant differences in the ED50 (31 +/- 8 pg/ml vs 23 +/- 7). TGF beta-2 was much less potent than TGF beta-1 in inhibiting DNA synthesis in AEC (6310 +/- 985 pg/ml vs 101 +/- 34). The reduced specific activity of TGF beta-2 was also observed in adrenal capillary endothelial cells. Both beta-1 and beta-2 stimulated proliferation of CBC (ED50 26 +/- 2 pg/ml vs 10 +/- 4). We also examined the specificity of the MvILu and AEC inhibition assays. Epidermal growth factor (EGF), platelet derived growth factor (PDGF), acidic and basic fibroblast growth factors (FGF), skeletal growth factor (SGF)/insulin-like growth factor-II (IGF-II), and insulin-like growth factor-I (IGF-I) did not inhibit DNA synthesis in either assay system. However, when the growth factors were added to maximal inhibiting concentrations of TGF beta-1, both acidic and basic FGF significantly reduced TGF beta-1 inhibition in AEC. We conclude that (1) inhibition of DNA synthesis in endothelial cells is relatively specific for TGF beta-1, (2) inhibition of DNA synthesis in MvILu is a sensitive and specific assay for generic TGF beta activity but does not distinguish beta-1 from beta-2, (3) the relative inhibition of DNA synthesis in MvILu and AEC may provide a means to quantitatively estimate TGF beta-1 and TGF beta-2, and (4) both TGF beta-1 and TGF beta-2 are potent mitogens for chicken embryonic calvarial bone cells.     

Complementary DNA cloning of the murine transforming growth factor-beta 3 (TGF beta 3) precursor and the comparative expression of TGF beta 3 and TGF beta 1 messenger RNA in murine embryos and adult tissues

Murine transforming growth factor-beta 3 (TGF beta 3) cDNAs were isolated from a TGF beta 2-induced AKR-2B cDNA library. The composite cDNA sequence is 2894 nucleotides long, including 610-nucleotide and 1054-nucleotide 5' and 3' untranslated sequences, respectively. The murine TGF beta 3-coding region is 1230 nucleotides in length and encodes a precursor protein of 410 amino acids, with a 96% peptide sequence identity with the human TGF beta 3 precursor. Examination of TGF beta 1 and TGF beta 3 mRNA levels in adult murine tissues showed that TGF beta 1 mRNA expression is predominant in spleen, lung, and placenta. In contrast, TGF beta 3 RNA was present in substantial amounts in brain, heart, adipose tissue, and testis. TGF beta 3 mRNA is also observed in adult mouse lung and placenta. Both TGF beta 1 and TGF beta 3 RNAs were present in all stages of mouse fetal development studied from 10.5-17.5 days postcoitum, with higher levels observed in the latter stages. The differential expression of these TGF beta genes suggests that the various TGF beta species may have distinct physiological roles in vivo.     

Interactions between retinoids and TGF beta s in mouse morphogenesis.

Using immunocytochemical methods we describe the distribution of different TGF beta isoforms and the effects of excess retinoic acid on their expression during early mouse embryogenesis (8 1/2 - 10 1/2 days of development). In normal embryos at 9 days, intracellular TGF beta 1 is expressed most intensely in neuroepithelium and cardiac myocardium whereas extracellular TGF beta 1 is expressed in mesenchymal cells and in the endocardium of the heart. At later stages, intracellular TGF beta 1 becomes very restricted to the myocardium and to a limited number of head mesenchymal cells; extracellular TGF beta 1 continues to be expressed widely in cells of mesenchymal origin, particularly in head and trunk mesenchyme, and also in endocardium. TGF beta 2 is widely expressed at all stages investigated while TGF beta 3 is not expressed strongly in any tissue at the stages examined. Exposure of early neural plate stage embryos to retinoic acid caused reduced expression of TGF beta 1 and TGF beta 2 proteins but had no effect on TGF beta 3. Intracellular TGF beta 1 expression was reduced in all tissues except in the myocardium, while extracellular TGF beta 1 was specifically reduced in neuroepithelium and cranial neural crest cells at early stages. TGF beta 2 was reduced in all embryonic tissues. The down-regulation of intracellular TGF beta 1 was observed up to 48 hours after initial exposure to retinoic acid while some down-regulation of TGF beta 2 was still seen up to 60 hours after initial exposure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of a cDNA encoding a chicken beta thyroid hormone receptor.

We have isolated and characterized a cDNA encoding a chicken beta homolog of c-erbA, or thyroid hormone receptor (TR). Chicken liver cDNA libraries were screened with a rat TR beta-1 cDNA probe, and several cDNA inserts were isolated and characterized. The sequence of one cDNA predicts a 369-amino-acid open reading frame (ORF), with a protein sequence that possesses 96% identity with that of rat TR beta-1, but only 88% identity with chicken TR alpha. These data indicate that the cDNA likely encodes a beta form of TR that has the expected putative DNA and T3 binding domains. The chicken TR beta (chTR beta) in vitro translated protein binds T3 with high affinity, and binds both the thyroid hormone response element (TRE) from the rat growth hormone gene and the Xenopus vitellogenin A2 gene estrogen response element (ERE), similarly to that of the rat TR beta-1. Northern blot analysis revealed the expression of a 7.0-kb RNA in several tissues including cerebellum, pituitary, kidney, and liver. This chicken liver TR beta cDNA sequence varies in both the 5' and 3' untranslated regions from the chicken kidney TR beta cDNA sequence recently reported (Forrest et al., 1990). The 5' untranslated cDNA sequence divergence occurs near a potential splice site junction of the human TR beta gene, suggesting that this chicken liver cDNA may represent an alternatively spliced RNA product of the chicken TR beta gene.     

Human cells express two differentially spliced forms of topoisomerase II beta mRNA.

Screening of a human B-cell cDNA library with a topoisomerase II beta gene-specific probe revealed the presence of two distinct forms of topoisomerase II beta cDNA. One form (designated topoisomerase II beta-1), representing the majority of the clones, would encode the topoisomerase II beta amino acid sequence reported recently [Jenkins, J.R. et al. (1992) Nucleic Acids Res., 20, 5587-5592]. The second form (designated topoisomerase II beta-2) would encode a protein containing an additional 5 amino acids inserted after Valine-23 of the topoisomerase II beta-1 protein sequence. The topoisomerase II beta-1 and beta-2 mRNAs were both widely expressed in human cell lines and tissues. Topoisomerase II beta-2 mRNA was expressed at a lower level than that of the beta-1 form, but the relative expression of the two forms varied in different cell types. Analysis of genomic DNA clones revealed that the two forms of topoisomerase II beta mRNA arose via differential splicing. These data indicate that in addition to the closely related topoisomerase II alpha and beta isozymes, there are two forms of topoisomerase II beta mRNA widely expressed in human cells.     

Altered responses of regenerating hepatocytes to norepinephrine and transforming growth factor type beta

Norepinephrine (NE), acting through the alpha 1-adrenergic receptor, modules the response of rat hepatocytes in primary culture to transforming growth factor type beta 1 (TGF beta) by increasing the amount of TGF beta required for a given degree of inhibition of epidermal growth factor (EGF)-induced DNA synthesis (Houck et al., J. Cell. Physiol. 135:551-555, 1988). This effect was also found in hepatocytes isolated from regenerating livers but was greatly magnified in cells isolated between 12 and 18 hr after two-thirds partial hepatectomy (PHX). During this period of enhanced sensitivity, NE was equally potent in terms of dose but more efficacious in the regenerating hepatocytes. As it did in control hepatocytes (Cruise et al., Science 227:749-751, 1985), the alpha 1-adrenergic receptor mediated the activity of NE in regenerating hepatocytes. Vasopressin (VP) and angiotensin-II (AG) also antagonized the effect of TGF beta and showed increased activity in regenerating hepatocytes but at only 50% or less of the maximal effect reached by NE. Regenerating hepatocytes isolated 24-72 hr after PHX exhibited decreased sensitivity to inhibition by TGF beta, with a nadir in 48-hr-regenerating cells. These findings suggest that NE may be involved in triggering the early phase of DNA synthesis during liver regeneration, with the subsequent acquisition of innate resistance to TGF beta responsible for continued proliferation at a time when TGF beta mRNA is known to be increasing in the liver (Braun et al., Proc. Natl. Acad. Sci. USA 85:1539-1543, 1988). EGF induced increased DNA and protein synthesis in cultures of control hepatocytes; TGF beta inhibited the EGF-induced DNA synthesis but had no effect on protein synthesis. This may be relevant to the latter stages of liver regeneration, when high levels of TGF beta mRNA are detected in liver and cellular hypertrophy predominates over hyperplasia.     

Differential expression of genes encoding TGFs beta 1, beta 2, and beta 3 during murine palate formation.

Transforming growth factor beta 1 (TGF beta 1) has been shown to have multiple effects on primary cultures of palate-derived cell types. We report the analysis, by in situ hybridization, of RNA expression for three different TGF beta isoforms (TGF beta 1, beta 2, and beta 3) during murine embryonic palate development. Differential expression of the three TGF beta genes is seen in the palatal shelves in mesenchymal and epithelial cells known to be involved in the morphogenesis of this organ. Taken together, these results suggest that the TGF beta s act as endogenous factors involved in the formation of the mammalian palate.     

Differential expression of TGF beta isoforms in murine palatogenesis

We have studied the expression of genes encoding transforming growth factors (TGFs) beta 1, beta 2 and beta 3 during development of the secondary palate in the mouse from 11.5 to 15.5 days postcoitum using in situ hybridisation. The RNA detected at the earliest developmental stage is TGF beta 3, which is localised in the epithelial component of the vertical palatal shelf. This expression continues in the horizontal palatal shelf, predominantly in the medial edge epithelium, and is lost as the epithelial seam disrupts, soon after palatal shelf fusion. TGF beta 1 RNA is expressed with the same epithelial pattern as TGF beta 3, but is not detectable until the horizontal palatal shelf stage. TGF beta 2 RNA is localised to the palatal mesenchyme underlying the medial edge epithelia in the horizontal shelves and in the early postfusion palate. The temporal and spatial distribution of TGF beta 1, beta 2 and beta 3 RNAs in the developing palate, together with a knowledge of in vitro TGF beta biological activities, suggests an important role for TGF beta isoforms in this developmental process.     

Effect of transforming growth factor beta on proliferation of L6 and embryonic porcine myogenic cells

We have examined the effect of Transforming Growth Factor (TGF) beta on proliferation of L6 and embryonic porcine myogenic cells. Proliferation of L6 cells was suppressed by both TGF beta-1 and TGF beta-2 in a dose-dependent manner. Half-maximal suppression of proliferation occurred at .036 ng TGF beta-1/ml and .06 ng TGF beta-2/ml. Maximal inhibition (60% suppression of proliferation for TGF beta-1 and 52% for TGF beta-2) occurred between .1 and .3 ng/ml for each growth factor. Suppression of proliferation was completely abolished in the presence of an anti-TGF beta antibody that inhibited the biological activity of TGF beta-1 and TGF beta-2. When we evaluated the effect of TGF beta-1 on proliferation of embryonic porcine myogenic cells we obtained results which were very similar to those obtained for L6 cells. Insulin-like growth factor (IGF)-I stimulated proliferation of L6 cells in a dose-dependent manner in serum-free, defined medium. However as little as .02 ng TGF beta-1/ml detectably suppressed this stimulation and .3 ng TGF beta-1/ml caused a 60% reduction in cell number in cultures treated with 30 ng IGF-l/ml. Thus TGF beta-1 significantly suppressed IGF-I-stimulated proliferation of L6 cells.     

Biological activity and receptor binding of human prointerleukin-1 beta and subpeptides

We report here that the human interleukin-1 beta precursor (proIL-1 beta) protein as well as several interleukin-1 beta (IL-1 beta) subpeptides bind cellular receptors specifically and exhibit biological activity by stimulating proliferation of helper T-cells. IL-1 beta polypeptides have been synthesized by in vitro translation of mRNAs transcribed from plasmid vectors containing the bacteriophage SP6 promoter joined to the complete IL-1 beta cDNA or to deletion constructs. The quantity of IL-1 beta in vitro translation products was increased significantly by replacing the cognate IL-1 beta untranslated leader sequence with a 37-nucleotide plant viral untranslated leader. Translation of chimeric mRNAs followed by direct bioactivity assay demonstrated that mature IL-1 beta-(117-269), proIL-1 beta-(1-269), and peptide IL-1-(71-269) were all biologically active. Specific binding to cellular receptors was observed with these three IL-1 beta molecules; moreover, several peptides with minimal biological activity also bound receptor specifically. The biological activity and receptor binding properties of the IL-1 beta proteins reported here contrast with those described by Mosley et al. (Mosley, B., Urdal, D. L., Prickett, K. S., Larsen, A., Cosman, D., Conlon, P. J., Gillis, S., and Dower, S. K. (1987) J. Biol. Chem. 262, 2941-2944; Mosley, B., Dower, S. K., Gillis, S., and Cosman, D. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 4572-4576), who reported that proIL-1 beta-(1-269) had no biological activity and does not bind receptor. Our results indicate that proIL-1 beta is active at a relatively high concentration, and analysis of the proIL-1 beta-(1-269) and IL-1-(71-269) bioactivity data suggests a possible relationship with membrane-bound IL-1.     

Localization of transforming growth factor beta receptor II interacting protein-1 in bone and teeth: implications in matrix mineralization

Transforming growth factor beta receptor II (TGFβR-II) interacting protein 1 (TRIP-1) is a WD-40 protein that binds to the cytoplasmic domain of the TGF-β type II receptor in a kinase-dependent manner. To investigate the role of TRIP-1 in mineralized tissues, we examined its pattern of expression in cartilage, bone, and teeth and analyzed the relationship between TRIP-1 overexpression and mineralized matrix formation. Results demonstrate that TRIP-1 was predominantly expressed by osteoblasts, odontoblasts, and chondrocytes in these tissues. Interestingly, TRIP-1 was also localized in the extracellular matrix of bone and at the mineralization front in dentin, suggesting that TRIP-1 is secreted by nonclassical secretory mechanisms, as it is devoid of a signal peptide. In vitro nucleation studies demonstrate a role for TRIP-1 in nucleating calcium phosphate polymorphs. Overexpression of TRIP-1 favored osteoblast differentiation of undifferentiated mesenchymal cells with an increase in mineralized matrix formation. These data indicate an unexpected role for TRIP-1 during development of bone, teeth, and cartilage.     

Structural analysis of multiple bovine P-450(11 beta) genes and their promoter activities

A bovine genomic library was constructed using a cosmid vector, pHC79, and bovine DNA partially digested by EcoRI. Bovine P-450(11 beta) cDNA, pcP-450(11 beta)-2 [Morohashi et al. (1987) J. Biochem. 102,559-568], was used as a probe for screening the genomic library. Ten clones carrying P-450(11 beta) genomic DNA were isolated from 8 x 10(4) colonies and classified into five groups (CB11 beta-1, CB11 beta-3, CB11 beta-7, CB11 beta-20, and CB11 beta-21) according to differences in the restriction endonuclease sites. Nucleotide sequences of amino acid coding regions of the five clones were determined by the dideoxy sequencing method using synthetic nucleotides corresponding to various parts of the cDNA as primers. The nucleotide sequences revealed that three clones, CB11 beta-1, CB11 beta-3, and CB11 beta-21, were pseudogenes. Amino acid sequences coded by the other two clones, CB11 beta-7 and CB11 beta-20, were identical with that coded by a previously described cDNA, pcP-450(11 beta)-3 [Kirita et al. (1988) J. Biochem. 104, 683-686]. The promoter regions of the five clones were introduced in front of chloramphenicol acetyltransferase (CAT) gene of pSV00CAT and used to examine P-450(11 beta) gene regulation in cultured cells. The five recombinant plasmids showed cAMP-responsive CAT activities in Y-1 cells, a cell strain derived from adrenal tumor. The induction rates of the recombinant plasmids carrying the promoters of normal genes, CB11 beta-7 and -20, were larger than those of pseudogenes, CB11 beta-1, -3, and -21. CAT activities expressed by the promoter regions of the normal genes in the presence or absence of cAMP in Y-1 cells were almost equal to that by the promoter region of human P-450(SCC) gene. Though the promoter of the P-450(SCC) gene also showed cAMP-responsive CAT activity in I-10 cells, a cell strain derived from Leyding cell tumor, P-450(11 beta) gene promoter did not express the activity in I-10 cells.     

Latent forms of transforming growth factor-beta (TGF beta) derived from bone cultures: identification of a naturally occurring 100-kDa complex with similarity to recombinant latent TGF beta

Transforming growth factor-beta (TGF beta) is produced by most tissues, including bone, as a complex that is biologically inert. Release of TGF beta homodimer from this latent complex is necessary for TGF beta to exert effects on target cells. Thus, the nature of the latent complex and the mechanisms responsible for TGF beta release are the key to understanding TGF beta actions. We have found that murine calvarial bone cultures secrete multiple latent forms of TGF beta. Using analytical chromatography and Western blot analysis, we have compared bone latent TGF beta with the previously characterized latent complex present in platelets and with simian TGF beta precursor, which is stably expressed in a latent form by Chinese hamster ovarian (CHO) cells. A major component of the bone material appears to be a latent complex of 100 kDa, consisting of mature TGF beta (25-kDa homodimer). Like the recombinant TGF beta precursor, it elutes from a Mono-Q fast pressure liquid chromatography anion exchange column at 0.2 M NaCl and shows a very similar banding pattern on Western blots. Thus, this bone complex closely resembles recombinant TGF beta precursor expressed in a latent form by CHO cells and differs from the naturally occurring platelet complex, which has an additional 135-kDa binding protein that is bound through disulfide bonds to the precursor proregion. Western blot analysis also indicates that, like CHO cells, which express recombinant TGF beta precursor, but unlike other cell types, the bone cultures secrete detectable amounts of uncleaved TGF beta precursor. The bone calvarial culture is the first example of a naturally occurring system that expresses the 100-kDa latent TGF beta complex.     

Occurrence of poly-N-acetyllactosamine synthesis in Sf-9 cells upon transfection of individual human beta-1,4-galactosyltransferase I, II, III, IV, V and VI cDNAs

Lectin blot analysis of membrane glycoprotein samples from Sf-9 cells upon transfection of individual human beta-1,4-galactosyltransferase (beta-1,4-GalT) I, II, III, IV, V et VI cDNAs showed that the endogenous N-linked oligosaccharides are galactosylated (Guo et al., Glycobiology (2001), in press). Further analysis revealed that membrane glycoprotein samples from all the gene-transfected cells are also reactive to Lycopersicon esculentum agglutinin (LEA) et Datura stramonium agglutinin (DSA), both of which bind to oligosaccharides with poly-N-acetyllactosamine chains while no lectin reactive protein bands are detected when blots are pretreated with a mixture of diplococcal beta-1,4-galactosidase et jack bean beta-N-acetylhexosaminidase or N-glycanase. Analysis of endo-beta-galactosidase-digestion products revealed the presence of the Gal1-->GlcNAc1-->Gal and/or GlcNAc1-->Gal structures in the gene-transfected cells. When the homogenates of the gene-transfected cells were used as enzyme sources towards oligosaccharides with the GlcNAc beta 1-->(3Gal beta 1-->4GlcNAc)(1-3) structures, human recombinant beta-1,4-GalTs I et II galactosylated these oligosaccharides more effectively than other beta-1,4-GalTs. These results indicate that beta-1,4-GalTs I-VI can synthesize poly-N-acetyllactosamine chains with beta-1,3-N-acetylglucosaminyltransferase.