The expression pattern of tomoregulin-1 in urodele limb regeneration and mouse limb development

Tomoregulin-1 (TMEFF1) was first identified as a gene implicated in pituitary secretion in Xenopus laevis. The predicted structure of TMEFF1 is that of a transmembrane protein with a highly conserved cytoplasmic tail, two follistatin domains and one modified EGF domain in its extracellular region. We report the cloning of the newt orthologue, and show that the expression of TMEFF1 is upregulated in the blastema during limb regeneration, and is also expressed in mouse embryonic limb development.

Identification of newt connective tissue growth factor as a target of retinoid regulation in limb blastemal cells

In order to analyse target genes regulated by retinoic acid in urodele limb regeneration, we have used pseudotyped retroviruses to obtain stably transfected newt limb blastemal (progenitor) cells in culture which express chimeric retinoic acid/thyroid hormone receptors delta1 or delta2. After treatment with thyroid hormone to activate the chimeric receptors, we used a polymerase chain reaction (PCR)-based subtraction method to identify target genes which are retinoid regulated. Newt connective tissue growth factor, a secreted protein recognised in several vertebrates, has been identified in this way and found to be expressed in the limb blastema and regulated by retinoic acid. This approach should permit a systematic analysis of retinoid target genes in limb regeneration.

Hedgehog family member is expressed throughout regenerating and developing limbs

Members of the hedgehog family have been shown to play a key role in many developmental processes, including limb patterning and chondrogenesis. We have therefore investigated whether members of this family are also expressed during regeneration of the adult urodele limb and are regulated by retinoic acid (RA), since this derivative induces proximodistal duplications in regenerating limbs, and has been shown to regulate sonic hedgehog (shh) in the developing limbs of birds and mammals. We report here that a newt homologue of Xenopus banded hedgehog, called N-bhh, is uniformly expressed by mesenchymal blastemal cells from the initial stages of regeneration and is up-regulated by RA. In addition, we show that N-bhh is uniformly expressed in the early limb bud of the newt embryo. Since bhh has not been detected in developing limbs of higher vertebrates, its expression in developing and regenerating newt limbs may be related to the regenerative capability of urodeles.

Immortalization of rat embryo fibroblasts by a 3'-untranslated region

We have exploited a cross-species expression screen to search for cellular immortalizing activities. A newt blastemal cDNA expression library was transfected into rat embryo fibroblasts and immortal cell lines were selected. This identified a 1-kb cDNA fragment which has a low representation in the cDNA library and is derived from the 3'-UTR of an alpha-glucosidase-related mRNA. Expression of this sequence in rat embryo fibroblasts has shown that it is active in promoting colony formation and immortalization. It is also able to cooperate with an immortalization-defective deletion mutant of SV40 T antigen, indicating that it can exert its growth-stimulatory activity in the pathway activated by a viral immortalizing oncogene. This is the first example of an immortalizing activity mediated by an RNA sequence, and further analysis of its mechanism should provide new insights into senescence and immortalization.

Newt myotubes reenter the cell cycle by phosphorylation of the retinoblastoma protein

Withdrawal from the cell cycle is an essential aspect of vertebrate muscle differentiation and requires the retinoblastoma (Rb) protein that inhibits expression of genes needed for cell cycle entry. It was shown recently that cultured myotubes derived from the Rb-/- mouse reenter the cell cycle after serum stimulation (Schneider, J.W., W. Gu, L. Zhu, V. Mahdavi, and B. Nadal-Ginard. 1994. Science (Wash. DC). 264:1467-1471). In contrast with other vertebrates, adult urodele amphibians such as the newt can regenerate their limbs, a process involving cell cycle reentry and local reversal of differentiation. Here we show that myotubes formed in culture from newt limb cells are refractory to several growth factors, but they undergo S phase after serum stimulation and accumulate 4N nuclei. This response to serum is inhibited by contact with mononucleate cells. Despite the phenotypic parallel with Rb-/- mouse myotubes, Rb is expressed in the newt myotubes, and its phosphorylation via cyclin-dependent kinase 4/6 is required for cell cycle reentry. Thus, the postmitotic arrest of urodele myotubes, although intact in certain respects, can be undermined by a pathway that is inactive in other vertebrates. This may be important for the regenerative ability of these animals.

Receptor isoform specificity in a cellular response to retinoic acid

The effects of retinoic acid on cell proliferation, differentiation and patterning are thought to be mediated by the various retinoic acid receptors. Different receptor types are encoded by distinct genes (alpha, beta, and gamma), whereas various isoforms within each type are encoded by splicing variants resulting from the use of alternative promoters. The only region that differs between isoforms is the N-terminal A region containing a transcriptional activating domain. It has been proposed that these alternative A regions confer distinct activities on the receptors, thus allowing each to mediate specific effects of retinoic acid, but it has been difficult to demonstrate such isoform specificity as most cells express a number of different retinoic acid receptors. In an attempt to test whether different isoforms can mediate distinct biological effects we are focusing on retinoic-acid-dependent growth inhibition of newt limb cells. We have constructed chimaeric receptors in which the retinoic acid binding domain of each of five newt retinoic acid receptors has been replaced with a thyroid hormone (T3) binding domain. These constructs were introduced individually into cells whose growth rate was then measured in the presence of T3. The chimaeric alpha 1 receptor mediated T3-dependent inhibition of proliferation that was comparable to that given by retinoic acid, whereas the alpha 2 isoform had no activity in this assay, nor did the delta 1A, delta 1B and Delta 2 receptors. When the A region was deleted from the alpha 1 chimaera it remained a potent T3-dependent transcriptional activator, but no longer mediated T3-dependent growth inhibition. In contrast, when the A region of alpha 1 was transferred to a delta chimaeric receptor, the resulting molecule was fully active in T3-dependent growth inhibition. This is the first direct evidence for isoform specificity in a biological response to retinoic acid, and demonstrates that the specificity of this response is confined to the A region.

Expression and activity of the newt Msx-1 gene in relation to limb regeneration

The Msx-1 homeobox gene is expressed in various contexts during vertebrate development, including the progress zone of the avian and mouse limb bud. Expression of mouse Msx-1 in a cultured myogenic cell line conferred a transformed phenotype and inhibited fusion into myotubes. It has been proposed that Msx-1 expression is required to maintain certain cells in a proliferating and undifferentiated state and may be associated with the ability to regenerate limbs. Urodele amphibians such as the newt regenerate their limbs by formation of a growth zone or blastema, and we have isolated and sequenced newt Msx-1 (NvMsx-1) from a limb blastemal cDNA library. NvMsx-1 expression was detectable in RNA preparations from both limb and tail and their regeneration blastemas, although cultured cells established from limb blastemal mesenchyme gave negative results. When either COS cells or cultured newt blastemal cells were cotransfected with an expression vector for NvMsx-1 and reporter plasmids containing multiple homeobox protein binding sites, NvMsx-1 repressed reporter expression. If NvMsx-1 was expressed together with a marker enzyme in cultured newt blastemal cells, no significant difference in DNA synthesis was observed relative to control transfectants. When myogenic mononucleate cells were transfected with NvMsx-1 and subsequently exposed to low serum to promote fusion, the fraction of Msx-1 positive cells in myotubes was comparable to a control transfected population analysed in the same culture. These results indicate that although Msx-1 expression could be important for limb regeneration, it does not exert a cell-autonomous effect on proliferation or myogenic differentiation of cultured blastemal cells.

Delta retinoic acid receptor isoform delta 1 is distinguished by its exceptional N-terminal sequence and abundance in the limb regeneration blastema

In amphibian limb regeneration memory for position in the proximal-distal axis can be respecified by retinoic acid. The favoured candidates to mediate this effect are the retinoic acid receptors (RARs) and of the RARs identified in the regeneration blastema, the delta receptor is the most abundant. The presence in blastemal mesenchyme of at least two delta receptor isoforms, delta 1 and delta 2, alternatively spliced at the A-B junction, was demonstrated in expression studies and by PCR cloning. The delta 1 receptor is abundant in regenerative structures such as the limb and tail, whereas the delta 2 and alpha receptors show a more uniform pattern of expression across adult newt tissues. Full-length cloning of the delta 1 receptor established the presence of an unusually long open reading frame and N-terminal sequence that appears unique among vertebrate retinoic acid receptors. Transient transfection of expression constructs into COS cells followed by Western blotting confirmed the existence of at least three potential initiation sites for delta 1 translation. The possibility that delta 1 RAR expression may specify positional memory directly was tested in RNase protection experiments. delta 1 receptor message is increased on amputation, but does not exhibit a pronounced differential distribution along the proximal-distal axis in normal and regenerating limbs, nor does it show a persistent alteration in expression levels following a dose of retinoic acid sufficient to respecify position. The possibility that the morphogenetic effects of RA may be mediated through receptor interactions is raised by the finding that single mesenchymal blastemal cells in culture can express multiple RAR subtypes (delta 1 and alpha) and isoforms (delta 1 and delta 2).

Identification and expression pattern of a second isoform of the newt alpha retinoic acid receptor

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Identification of a novel retinoic acid receptor in regenerative tissues of the newt

In urodele amphibians, the progenitor cells that regenerate amputated limbs (known as the blastema) normally replace only the missing structures. After systemic delivery of retinoic acid (RA), more proximal structures are also formed, indicating that RA can control position specification in the proximal-distal axis of the regenerating limb. According to dose and experimental context, retinoids can also re-specify the anteroposterior axis of the limb, induce deletions of skeletal elements, or block re-growth completely. To study the molecular basis of these morphogenetic effects, we screened complementary DNA libraries of newt regenerative tissues (limbs and tails) for hormone nuclear receptors activated by RA. Two functional retinoic acid receptors (RARs) were identified, one of which is the newt homologue of the human alpha-receptor (RAR alpha). The second receptor, called RAR delta, is novel. Sequence analysis suggests that the composite newt RAR previously reported is chimaeric, consisting of 5'RAR-beta-like and 3' RAR delta clones. We conclude that multiple RARs are expressed during limb regeneration in amphibians and suggest that receptor heterogeneity may underlie the different effects of retinoids on limb morphogenesis.

Position dependent expression of a homeobox gene transcript in relation to amphibian limb regeneration

Adult urodele amphibians such as the newt Notophthalmus viridescens are capable of regenerating their limbs and tail by formation of a blastema, a growth zone of mesenchymal progenitor cells. In an attempt to identify genes implicated in specification of the regenerate, we screened a newt forelimb blastema cDNA library with homeobox probes, and isolated and sequenced clones that identify a 1.8 kb polyadenylated transcript containing a homeobox. The transcript is derived from a single gene called NvHbox 1, the newt homologue of XIHbox 1 (Xenopus), HHO.c8 (human) and Hox-6.1 (mouse). The cDNA for the 1.8 kb transcript has two exons as determined by isolation and partial sequencing of a genomic clone. The expression of the transcript shows several interesting features in relation to limb regeneration: (i) Hybridization of Northern blots of poly(A)+ RNA from limb and tail and their respective blastemas shows that the transcript in limb tissues has exons 1 and 2, whereas a 1.8 kb transcript in tail tissues has only exon 2. (ii) The transcript is expressed in limbs of adult newt but not of adult Xenopus, raising the possibility that this contributes to an explanation of the loss of regenerative ability with maturation in adult anurans. (iii) The transcript is expressed at a higher level in a proximal (mid-humerus) blastema than in a distal one (mid-radius). When distal blastemas were proximalized by treatment with retinoic acid, no change in the level of the transcript was detected by Northern analysis at a single time point after amputation.(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence for dedifferentiation and metaplasia in amphibian limb regeneration from inheritance of DNA methylation

Amphibian limb regeneration is a process in which it has been suggested that cells of one differentiated type may dedifferentiate and give rise to cells of another type in the regenerate. We have used two tissue-specific hypomethylations in the newt cardioskeletal myosin heavy chain gene as lineage markers to follow the fate of cells during limb regeneration. Analysis of genomic DNA from different muscle cell populations allowed the assignment of one marker to the muscle (Hypo A) lineage and the other, more tentatively, to the ‘connective tissue’ (Hypo B) component of muscle. The contribution to regenerated limb cartilage and limb blastemal tissue by cells carrying these markers was estimated by quantitative analysis of Southern blot hybridizations using DNA from regenerate tissues. The results are consistent with a contribution of cells from both muscle and connective tissue lineages to cartilage in regenerated limbs. In addition, removal of the humerus at the time of amputation (eliminating any contribution from pre-existing cartilage), has provided evidence for an increased representation of cells carrying the connective tissue marker in regenerate cartilage but did not affect the representation of cells carrying the muscle cell marker.

Structure and expression of a newt cardio-skeletal myosin gene. Implications for the C value paradox

As part of our studies on the fate of the muscle lineage during amphibian limb regeneration, we have isolated genomic and cDNA sequences from a myosin heavy chain in the newt (Notophthalmus viridescens). Notwithstanding the technical problems inherent in analysing the large newt genome, genomic and cDNA sequences have been isolated and subjected to analysis by restriction mapping. Northern hybridization, Southern hybridization and DNA sequencing. We believe these to be the first single copy newt gene sequences to have been subjected to this type of analysis. The newt gene sequences showed a striking difference from mammalian myosins in both the estimated sizes of the gene and its intervening sequences; these being much larger than in the mammalian models, it is speculated that this could contribute to the exceptional size of the newt genome. By contrast, the coding sequences displayed very high levels of sequence homology to mammalian myosins. In particular, the amino acid sequence of the newt myosin was found to have greatest homology with rat and human myosin isotypes having a similar cardio-skeletal muscle expression pattern. Despite a long evolutionary separation, newt and mammalian cardio-skeletal myosins have remained more similar to each other than have the human or rat cardiac forms to skeletal myosins within their own respective species.