Spatial and temporal regulation of collagenases—3,—4,and stromelysin —3 implicates distinct functions in apoptosis and tissue remodeling during frog metamorphosis

Matrix metalloproteinases (MMPs) are a family of extracellular proteases capable of degrading various proteinaceous components of the extracellular matrix(ECM).They have been implicated to play important roles in a number of developmental and pathological processes,such as tumor metastasis and inflammation.Relatively few studies have been carried out to investigate the function of MMPs during postembryonic organ-development.Using Xenopus laevis development as a model system,we demonstrate here that three MMPs,stromelysin-3(ST3),collagenases-3(Col3),and Col4,have distinct spatial and temporal expression profiles during metamorphosis as the tadpole transforms into a frog.In situ hybridizations reveal a tight,but distinct,association of individual MMPs with tissue remodeling in the tail and intestine during metamorphosis.In particular,ST3 expression is strongly correlated with apoptosis in both organs as demonstrated by analyses of serial sections with in situ hybridization for ST3 mRNA and TUNEL (terminal deoxyribonucleotidyl transferase-mediated dUTP-biotin nick end labeling)for apoptosis,respectively.On the other hand,Col3 and Col4 are present in regions where extensive connective tissue remodeling take place.These results indicate that ST3 is likely to play a role in ECM-remodeling that facilitate apoptotic tissue remodeling or resorption while Col3 and Col4 appear to participate in connective tissue degradation during development.     

Biochemical and Immunological Characterization of Collagenase in Tissues of Metamorphosing Bullfrog Tadpoles

Tissue inhibitor of metalloproteinases (TIMP, a specific inhibitor of collagenase) was found to inhibit thyroid hormone-induced tail regression, suggesting the important role of collagenase in this process. Collagenase was purified from culture media of back skin of tadpole of bullfrog, Rana catesbeiana . Anti-tadpole collagenase polyclonal antisera were obtained against the purified enzyme. The antibody inhibited the activity of tadpole collagenase. The antisera reacted to tissues of adult bullfrogs, tadpoles of african clawed frog, Xenopus laevis , and adult newts, Cynopus pyrrhogaster , and also reacted to human fibroblast collagenase. Immunoblot analyses suggested that tadpole collagenase lacks the procollagenase which is generally found in mammalian collagenases. Intense immunological stains were observed for the tissues of thyroid hormone-treated tadpoles as compared to those of untreated animals. Thyroid hormone increased amounts of collagenase not only in epidermal layer but also in mesenchymal tissues including fibroblastic cells.     

Activity and expression of Xenopus laevis matrix metalloproteinases: identification of a novel role for the hormone prolactin in regulating collagenolysis in both amphibians and mammals

Prolactin (PRL) has long been implicated in Xenopus metamorphosis as an anti-metamorphic and/or juvenilizing hormone. Numerous studies showed that PRL could prevent effects of either endogenous or exogenous thyroid hormone (TH; T(3)). It has been shown that expression of matrix metalloproteinases (MMPs) is induced by TH during Xenopus metamorphosis. Direct in vivo evidence, however, for such anti-TH effects by PRL with respect to MMPs has not been available for the early phase of Xenopus development or metamorphosis. To understand the functional role of PRL, we investigated effects of PRL on Xenopus collagenase-3 (XCL3) and collagenase-4 (XCL4) expression in a cultured Xenopus laevis cell line, XL-177. Northern blot analysis demonstrated that XCL3 and XCL4 expression were not detected in control or T(3)-treated cells, but were differentially induced by PRL in a dose- and time-dependent fashion. Moreover, treatment with IL-1alpha as well as phorbol myristate acetate (PMA), a protein kinase C (PKC) activator, or H8, a protein kinase A (PKA) inhibitor, augmented PRL-induced collagenase expression, suggesting that multiple protein kinase pathways and cytokines may participate in PRL-induced collagenase expression. Interestingly, XCL3 expression could be induced in XL-177 cells by T(3), but only when co-cultured with prometamorphic Xenopus tadpole tails (stage 54/55), suggesting that the tails secrete a required intermediate signaling molecule(s) for T(3)-induced XCL3 expression. Taken together, these data demonstrate that XCL3 and XCL4 can be differentially induced by PRL and T(3) and further suggest that PRL is a candidate regulator of TH-independent collagenase expression during the organ/tissue remodeling which occurs in Xenopus development.     

Programmed cell death during amphibian metamorphosis

The death of different types of cells occurs in regressing or remodeling organs to transform from a tadpole to a frog in both temporally and spatially regulated manners during amphibian metamorphosis. This morphological change is drastic and visible with the naked eye. This review summarizes our current understanding of the basic mechanism of the cell death during the metamorphosis. It focuses in particular on the tail resorption and the remodeling of intestine and skin where programmed cell death is executed by thyroid hormone-signaling through the cell-autonomous response (suicide) and the degradation of the extracellular matrix (murder).     

Expression of the fibroblast activation protein during mouse embryo development

Human Fibroblast Activation Protein (FAP), a member of the serine prolyl oligopeptidase family, is a type II cell surface glycoprotein that acts as a dual-specificity dipeptidyl-peptidase (DPP) and collagenase in vitro. Its restricted expression pattern in embryonic mesenchyme, in wound healing and in reactive stromal fibroblasts of epithelial cancers, has suggested a role for the FAP protease in extracellular matrix degradation or growth factor activation in sites of tissue remodeling. The FAP homologue in Xenopus laevis has been reported to be induced in the thyroid hormone-induced tail resorption program during tadpole metamorphosis supporting a role for FAP in tissue remodeling processes during embryonic development. However, Fap-deficient mice show no overt developmental defects and are viable. To study the expression of FAP during mouse embryogenesis, a second Fap-deficient mouse strain expressing beta-Galactosidase under the control of the Fap promoter was generated by homologous recombination (Fap-/- lacZ mice). FAP deficiency was confirmed by the absence of FAP-specific dipeptidyl-peptidase activity in detergent-soluble extracts isolated from 17.5 d.p.c. Fap-/- lacZ embryos. We report that Fap-/- lacZ mice express beta-Galactosidase at regions of active tissue remodeling during embryogenesis including somites and perichondrial mesenchyme from cartilage primordia.     

Spatial and temporal expression pattern of a novel gene in the frog Xenopus laevis: correlations with adult intestinal epithelial differentiation during metamorphosis

We report the cloning of a novel gene (ID14) and its expression pattern in tadpoles and adults of Xenopus laevis. ID14 encodes a 315-amino acid protein that has a signal peptide and a nidogen domain. Even though several genes have a nidogen domain, ID14 is not the homolog of any known gene. ID14 is a late thyroid hormone (TH)-regulated gene in the tadpole intestine, and its expression in the intestine does not begin until the climax of metamorphosis, correlating with adult intestinal epithelial differentiation. In contrast, ID14 is expressed in tadpole skin and tail and is not regulated by TH. In situ hybridization revealed that this putative extracellular matrix protein is expressed in the epithelia of the tadpole skin and tail and in the intestinal epithelium after metamorphosis. In the adult, ID14 is found predominantly in the intestine with weak expression in the stomach, lung, and testis. Its exclusive expression in the adult intestinal epithelial cells makes it a useful marker for developmental studies and may give insights into cell/cell interactions in intestinal metamorphosis and adult intestinal stem cell maintenance.     

Amphibian organ remodeling during metamorphosis: insight into thyroid hormone-induced apoptosis

During amphibian metamorphosis, the animal body dramatically remodels to adapt from the aquatic to the terrestrial life. Cell death of larval organs/tissues occurs massively in balance with proliferation of adult organs/tissues, to ensure survival of the individuals. Thus, amphibian metamorphosis provides a unique and valuable opportunity to study regulatory mechanisms of cell death. The advantage of this animal model is the absolute dependence of amphibian metamorphosis on thyroid hormone (TH). Since the 1990s, a number of TH response genes have been identified in several organs of Xenopus laevis tadpoles such as the tail and the intestine by subtractive hybridization and more recently by cDNA microarrays. Their expression and functional analyses, which are still ongoing, have shed light on molecular mechanisms of TH‐induced cell death during amphibian metamorphosis. In this review, I survey the recent progress of research in this field, focusing on the X. laevis intestine where apoptotic process is well characterized at the cellular level and can be easily manipulated in vitro. A growing body of evidence indicates that apoptosis during the intestinal remodeling occurs not only via a cell‐autonomous pathway but also via cell–cell and/or cell–extracellular matrix (ECM) interactions. Especially, stromelysin‐3, a matrix metalloproteinase, has been shown to alter cell–ECM interactions by cleaving a laminin receptor and induce apoptosis in the larval intestinal epithelium. Here, I emphasize the importance of TH‐induced multiple apoptotic pathways for massive and well‐organized apoptosis in the amphibian organs and discuss their conservation in the mammalian organs.     

Locomotion in Amphibian Larvae (or "Why Aren't Tadpoles Built Like Fishes?")

SYNOPSIS. A variety of morphological features that affect locomotiondistinguish larvae of the three living amphibian orders fromfishes and their larvae. The oddest amphibian larvae are anurantadpoles. With their globose bodies, concealed forelimbs, abruptlycompressed and terminally tapered tails, tadpoles not only differradically from fishes but they—unlike caecilians or salamanders—alsodiffer radically from their adults. Tadpoles typically haveless axial musculature and much simpler myotomes than fishes.Surprisingly, in terms of mechanical (propeller) efficiencyand maximum sprint speeds, tadpoles still perform as well asmany teleosts of comparable sizes. From a consideration of hydromechanics,no amphibian larvae appear to be designed for sustained swimmingat high speeds. High maneuverability, rather than sustainablespeed, are important for amphibian larval survival.Two key featuresof tadpoles are the absence of caudal vertebrae and unexposedpectoral appendages. With only a notochord to serve as a skeleton,the tadpole tail is extremely flexible. Because of this exceptionalflexibility, tadpoles can fold their tails up against the bodyand turn rapidly with virtually no displacement of their centerof mass. Caudal flexibility can be regulated by muscle activityin the tadpole to effect turning. Lateral appendages are notneeded for this movement and are free to develop directly intotheir adult morphology; the anterior ones develop under coverof an opercular fold where they do not contribute to drag. Acase is presented, based on the ecology of metamorphosis, thatanuran transformation should be as brief as possible. With nobone to resorb, metamorphosis of the anuran caudal appendagecan, indeed, be very rapid.The basic kinematics of constantvelocity straightforward swimming for tadpoles and salamanderlarvae is reviewed, as well as the kinematics and electromyographyof starting, stopping, and turning in tadpoles. An attempt ismade to relate swimming kinematics to the characteristic morphologiesof amphibian larvae. Swimming speed in Rana, Bufo and Aynbystomalarvae, which swim only intermittently, is modulated by changingtail beat frequency. However, Xenopus, which swims constantlyby sculling with its tail, regulates swimming speed (at lowto intermediate velocities) by varying the length of the propulsivewave in its tail. Xenopus and Rana differ in the morphologyof their notochord, spinal cord, spinal nerves, and spinal motorpool distribution within the spinal cord. These differencesmay underlie the different way these larvae regulate swimming.They may also reflect their phylogenetic history.     

Actin Degradation in the Metamorphosing Bullfrog Tadpole Tail

Degradation of tail muscle proteins was investigated during metamorphosis of Rana catesbeiana , tadpole. Regressing tail muscle contained actomyosin which was comparable to that of non-regressing tail muscle in its physico-chemical character, althouth the actomyosin content of the former tissue decreased as compared to the latter. However, when muscle proteins were extracted in the SDS-containing medium (TSM) and analyzed by SDS-polyacrylamide gel electrophoresis, we found that the protein band corresponding to actin disappeared completely during the late climax stage of metamorphosis. Detailed studies on this phenomenon showed that the apparent absence of actin on SDS-polyacrylamide gel electrophoresis was dependent upon the metamorphic stages of the tadpoles investigated. When TSM extract from the premetamorphic tadpole tail muscles which contained actin was incubated with the same extract from tadpoles of the climax stage, actin derived from premetamorphic tadpole disappeared on gel electrophoresis, indicating that tail muscle tissues of the climax stages contain the actin-degrading enzyme. Characterization of the enzyme was performed with a crude extract using actin prepared from rabbit thigh muscle as a substrate. Actin degrading activity showed incubation time- and temperature-dependency and the activity decreased gradually when the extract was preheated at increasing temperatures with the complete inactivation at 100°C. The major degradation products of actin hydrolysis by the enzyme had a Mr=28,000 and 14,000 which indicated the enzyme splits actin at a specific point. The activity had an optimum pH of 7.5 and was inhibited by leupeptin and iodoacetate and required the presence of a thiol reagent.     

Oxidative stress, tissue remodeling and regression during amphibian metamorphosis

Anuran metamorphosis is characterized by rapid and drastic changes in the body form and function under the influence of thyroid hormones. We evaluated the involvement of reactive oxygen species and antioxidant defenses during intestinal remodeling and tail regression of tadpoles of Xenopus laevis. Oxidative stress resulting from depletion in catalase and reduced glutathione, and simultaneous increase in lipid peroxidation during intestinal remodeling as well as tail regression are probably responsible for cell death and differentiation in these organs. Gene expression data for superoxide dismutase and catalase supports this contention. A dramatic increase in another antioxidant, ascorbic acid content of both these organs during metamorphic climax indicates its multifactor role such as collagen synthesis in intestine and controlled tail regression. These findings suggest that the cellular environment in the intestine and tail becomes progressively more oxidizing during its remodeling and regression respectively.     

Spatial and temporal expression profiles suggest the involvement of gelatinase A and membrane type 1 matrix metalloproteinase in amphibian metamorphosis

The matrix metalloproteinases (MMPs) are a family of proteases capable of degrading various components of the extracellular matrix (ECM). Among them, the membrane type MMP–1 (MT1–MMP) has been shown to participate in the activation of MMP gelatinase A (GelA), suggesting that they may function together in development and pathogenesis. Here, we have investigated the spatiotemporal expression profiles of Xenopus laevis MT1–MMP and GelA genes during thyroid-hormone-dependent metamorphosis. We have focused our studies on two organs: (1) the intestine, which undergoes first the degeneration of the tadpole epithelium through apoptosis and then the development of adult epithelium and other tissues, and (2) the tail, which completely resorbs through programmed cell death. We show that both MT1–MMP and GelA are upregulated in the intestine and tail when both organs undergo metamorphosis. Within the organs, MT1–MMP and GelA are coexpressed in the connective tissues during both natural and thyroid-hormone-induced metamorphosis. In addition, MT1–MMP (but not GelA) is also expressed in the longitudinal muscle cells of the metamorphosing intestine. These results suggest that MT1–MMP and GelA function together in the ECM degradation or remodeling associated with metamorphosis and that MT1–MMP has additional GelA–independent roles in the development of adult longitudinal muscle in the intestine. This research was supported by the Intramural Research Program of the National Institute of Child Health and Human Development, NIH. T. Hasebe and H. Matsuda were supported in part by JSPS (NIH) fellowships.     

Carbamylation differentially alters type I collagen sensitivity to various collagenases.

Carbamylation is a post-translational modification due to nonenzymatic binding of cyanate, a by-product of urea, on free amino groups of proteins. Post-translational modifications are known to induce alterations in structural and functional properties of proteins, thus disturbing protein-protein or cell-protein interactions. We report the impact of carbamylation on type I collagen sensitivity to enzymatic proteolysis. Type I collagen was extracted from rat tail tendons and carbamylated by incubation with 0.1 M potassium cyanate at 37 degrees C for 2, 6 or 24 h. Degradation assays revealed that carbamylated collagen exhibited a greater resistance to collagenases (i.e. bacterial collagenase, matrix metalloproteinase(MMP)-1, MMP-8 and MMP-13), together with an increased sensitivity to MMP-2. Evaluation of collagen triple helix conformation by polarimetry indicated that local destabilizations of triple helix structure related to carbamylation could be responsible for the observed differences in sensitivity. These results confirm the crucial role of triple helix integrity in the degradation of type I collagen by MMPs, and support the deleterious impact of post-translational modifications in vivo by altering the balanced remodeling of collagen within connective tissue.     

Tissue sensitivity to thyroid hormone in athyroid Xenopus laevis larvae

Tadpoles that spontaneously arrest development and remain as larvae occur occasionally in Xenopus laevis populations. These non-metamorphosing tadpoles continue to grow, and they develop into grossly deformed giant individuals which come as close as any anurans to being truly neotenic. Giant X. laevis tadpoles that fail to metamorphose lack thyroid glands. In this study, the hypothesis that the tissues of these tadpoles nevertheless remain thyroid hormone sensitive was tested, by exposing isolated tadpole tail tips to exogenous thyroid hormone in tissue culture. The tail tips from giant tadpoles significantly shrank in response to the thyroid hormone treatment, showing that their tissue was still capable of metamorphosis. However, the amount of shrinkage was less than that observed in tail tissue from normal tadpoles. It was hypothesized that complete induction of metamorphosis may not be possible in the giant tadpoles due to a disproportionate growth and development of tissues and organs.     

Two Transitions of Haemoglobin Expression in Xenopus: from Embryonic to Larval and from Larval to Adult

Abstract. Electrophoretic analyses of haemoglobin and globin phenotypes in families of Xenopus borealis and Xenopus l. laevis revealed two developmental haemoglobin transitions during ontogeny. The first transition occurs at the developmental stage when tadpoles begin to feed. It is characterized by the decline of embryonic-specific globins in favour of novel, tadpole-specific globins ( X. borealis ) correlated to changes in the haemoglobin pattern. We suppose that this switch results from the replacement of a primitive, ventral blood island-dependent erythrocyte population by tadpole erythrocytes from other erythropoietic sites. Several other globin chains and haemoglobins are present in both young tadpoles and throughout larval life. The second, well-known transition occurs during metamorphosis, where all tadpole haemoglobins are replaced by adult haemoglobins composed of entirely different globin chains.     

Cloning and thyroid hormone regulation of albumin mRNA in Rana catesbeiana tadpole liver.

Thyroid hormones are responsible for the specific biochemical and structural changes that occur during amphibian metamorphosis. In this study we screened a series of cDNAs from a library constructed from T4-treated premetamorphic tadpole liver poly(A)+ RNA in order to identify a clone that could be used to study the influence of T3 on liver-specific gene expression during Rana catesbeiana metamorphosis. The cDNA from one clone exhibited a greater degree of hybridization to liver RNA from thyroid hormone-treated tadpoles than untreated tadpoles and no hybridization to RNA from tail fins of tadpoles of either group. On Northern blots, the mRNA to which the cDNA hybridized was 2.3 kilobases in size. The pattern of hybridization to genomic DNA digested by various restriction enzymes was consistent with the presence of a single gene. Using slot blot analysis we found that the mRNA levels first rose above basal levels only after 5 days of immersion of tadpoles in 12.5 micrograms/liter T3. The mRNA levels increased approximately 10-fold after 7 and 9 days of treatment. Frog livers had mRNA levels that were intermediate between those in untreated tadpoles and tadpoles immersed in T3 for 7 days. Sequence analysis revealed a significant degree of homology to serum albumin and alpha-fetoprotein. While it is known that serum albumin levels rise dramatically during metamorphosis in Rana species, presumably playing a critical role in maintaining water and electrolyte balance during the animals' terrestrial phase, the molecular basis of the induction has not been fully explained.     

Tissue- and gene-specific recruitment of steroid receptor coactivator-3 by thyroid hormone receptor during development

Numerous coactivators that bind nuclear hormone receptors have been isolated and characterized in vitro. Relatively few studies have addressed the developmental roles of these cofactors in vivo. By using the total dependence of amphibian metamorphosis on thyroid hormone (T3) as a model, we have investigated the role of steroid receptor coactivator 3 (SRC3) in gene activation by thyroid hormone receptor (TR) in vivo. First, expression analysis showed that SRC3 was expressed in all tadpole organs analyzed. In addition, during natural as well as T3-induced metamorphosis, SRC3 was up-regulated in both the tail and intestine, two organs that undergo extensive transformations during metamorphosis and the focus of the current study. We then performed chromatin immunoprecipitation assays to investigate whether SRC3 is recruited to endogenous T3 target genes in vivo in developing tadpoles. Surprisingly, we found that SRC3 was recruited in a gene- and tissue-dependent manner to target genes by TR, both upon T3 treatment of premetamorphic tadpoles and during natural metamorphosis. In particular, in the tail, SRC3 was not recruited in a T3-dependent manner to the target TRbetaA promoter, suggesting either no recruitment or constitutive association. Finally, by using transgenic tadpoles expressing a dominant negative SRC3 (F-dnSRC3), we demonstrated that F-dnSRC3 was recruited in a T3-dependent manner in both the intestine and tail, blocking the recruitment of endogenous coactivators and histone acetylation. These results suggest that SRC3 is utilized in a gene- and tissue-specific manner by TR during development.     

The life span of red blood cells in the amphibian larvae, Rana catesbeiana

Nearly one hundred amphibian tadpoles were made anemic by phenylhydrazine injection. During the recovery period radioactive thymidine was incorporated into the DNA of the nucleated amphibian red blood cells. Over the next 135 days blood was drawn and smears of circulating red blood cells were prepared. The blood smears from each tadpole were autoradiographed and percentage of labeled nuclei (PLN) determined. The average life span of tadpole red blood cells was calculated from the change in PLN, and is about 100 days. It is concluded that during the transition from tadpole to frog, the tadpole red blood cell life span must be drastically shortened to account for the hemoglobin transition observed during amphibian metamorphosis.