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.     

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.     

Requirement for matrix metalloproteinase stromelysin-3 in cell migration and apoptosis during tissue remodeling in Xenopus laevis

The matrix metalloproteinase (MMP) stromelysin-3 (ST3) was originally discovered as a gene whose expression was associated with human breast cancer carcinomas and with apoptosis during organogenesis and tissue remodeling. It has been shown previously, in our studies as well as those by others, that ST3 mRNA is highly upregulated during apoptotic tissue remodeling during Xenopus laevis metamorphosis. Using a function-blocking antibody against the catalytic domain of Xenopus ST3, we demonstrate here that ST3 protein is specifically expressed in the cells adjacent to the remodeling extracellular matrix (ECM) that lies beneath the apoptotic larval intestinal epithelium in X. laevis in vivo, and during thyroid hormone-induced intestinal remodeling in organ cultures. More importantly, addition of this antibody, but not the preimmune antiserum or unrelated antibodies, to the medium of intestinal organ cultures leads to an inhibition of thyroid hormone-induced ECM remodeling, apoptosis of the larval epithelium, and the invasion of the adult intestinal primodia into the connective tissue, a process critical for adult epithelial morphogenesis. On the other hand, the antibody has little effect on adult epithelial cell proliferation. Furthermore, a known MMP inhibitor can also inhibit epithelial transformation in vitro. These results indicate that ST3 is required for cell fate determination and cell migration during morphogenesis, most likely through ECM remodeling.     

Midkine Promotes Selective Expansion of the Nephrogenic Mesenchyme during Kidney Organogenesis

During kidney development, the growth and development of the stromal and nephrogenic mesenchyme cell populations and the ureteric bud epithelium is tightly coupled through intricate reciprocal signaling mechanisms between these three tissue compartments. Midkine, a target gene activated by retinoid signaling in the metanephros, encodes a secreted polypeptide with mitogenic and anti-apoptotic activities in a wide variety of cell types. Using immmunohistochemical methods we demonstrated that Midkine is found in the uninduced mesenchyme at the earliest stages of metanephric kidney development and only subsequently concentrated in the ureteric bud epithelium and basement membrane. The biological effects of purified recombinant Midkine were analyzed in metanephric organ culture experiments carried out in serum-free defined media. These studies revealed that Midkine selectively promoted the overgrowth of the Pax-2 and N-CAM positive nephrogenic mesenchymal cells, failed to stimulate expansion of the stromal compartment and suppressed branching morphogenesis of the ureteric bud. Midkine suppressed apoptosis and stimulated cellular proliferation of the nephrogenic mesenchymal cells, and was capable of maintaining the viability of isolated mesenchymes cultured in the absence of the ureteric bud. These results suggest that Midkine may regulate the balance of epithelial and stromal progenitor cell populations of the metanephric mesenchyme during renal organogenesis.     

Temporal and spatial expression of an intestinal Na+/PO43− cotransporter correlates with epithelial transformation during thyroid hormone-dependent frog metamorphosis

The amphibian intestine has two morphologically distinct structures during development. Early embryogenesis generates a simple tube-like intestine in the tadpole whereas after thyroid hormone (T₃)-dependent metamorphosis a newly remodeled adult intestine is formed similar to that of higher vertebrates. This change requires a drastic transformation of the epithelial layer. We have isolated a Na⁺/PO₄³⁻ cotransporter gene that may contribute to this transformation. The deduced amino acid sequence of this gene shows a high degree of homology to the mammalian renal NA⁺/PO₄³⁻ cotransporters, which have little or no expression in organs other than the kidney. The frog gene is highly expressed and regulated by T₃ in the intestine with little expression and/or regulation by T₃ in most other organs. Its mRNA is restricted to the differentiated epithelial cells both in tadpoles and postmetamorphic frogs. Interestingly, its expression is low in premetamorphic tadpoles, but up-regulated when metamorphosis is initiated by endogenous T₃. As the larval epithelium undergoes programmed cell death (apoptosis), the mRNA level drops to a minimum. Subsequently, the gene is reactivated at the tip region of the newly formed adult intestinal folds and a crest-trough polarity of expression is established by the end of metamorphosis. This temporal regulation profile is also reproduced when premetamorphic tadpoles are treated with T₃ to induce precocious intestinal remodeling. These results suggest a possible role of the Na⁺/PO₄³⁻ cotransporter during metamorphosis and demonstrate that the adult epithelial cell differentiation pattern is established in the direction of crest-to-trough of the intestinal fold, concurrent with the epithelial morphogenic process. Dev Genet 20:53–66, 1997. © 1997 Wiley-Liss, Inc.     

Developmentally and regionally regulated participation of epidermal cells in the formation of collagen lamella of anuran tadpole skin

We investigated the cellular mechanism of formation of subepidermal thick bundles of collagen (collagen lamella) during larval development of the bullfrog, Rana catesbeiana, using cDNA of alpha1(I) collagen as a probe. The originally bilayered larval epidermis contains basal skein cells and apical cells, and the collagen lamella is directly attached to the basement membrane. The basal skein cells above the collagen lamella and fibroblasts beneath it intensively expressed the alpha1(I) gene. As the skin developed, suprabasal skein cells ceased expression of the gene. Concomitantly, the fibroblasts started to outwardly migrate, penetrated into the lamella and formed connective tissue between the epidermis and the lamella. These fibroblasts intensively expressed the gene. As the connective tissue developed, the basal skein cells ceased to express the gene and were replaced by larval basal cells that did not express the gene. These dynamic changes took place first in a lateral region of the body skin and proceeded to all other regions except the tail. Isolated cultured skein cells expressed the gene and extracellularly deposited its protein as the type I collagen fibrils. Thus, it is concluded that anuran larval epidermal cells can autonomously and intrinsically synthesize type I collagen.     

Amphibian metamorphosis: An exquisite model for hormonal regulation of postembryonic development in vertebrates

Metamorphosis in invertebrates and vertebrates is an ideal model for studying mechanisms of postembryonic development regulated by external signals. Amphibian metamorphosis shares many similarities with mammalian development in the perinatal period. The precocious induction in vivo and in culture of amphibian metamorphosis by exogenous thyroid hormones and its retardation or inhibition by prolactin, have allowed the analysis of such characteristic features of postembryonic development as morphogenesis, tissue remodelling, gene reprogramming and programmed cell death. Recent studies on metamorphosis have revealed the important role played by such processes as auto- and cross-regulation of hormone receptor genes and by cell death or apoptosis, as in the maturation of the central nervous system, tissue restructuring and organolysis.     

Histo-morphology of the thyroid gland during the larval development of Pleurodema borellii (Anura,Leptodactylidae)

The thyroid gland is essential in anurans, since thyroid hormones (TH) are the main regulators of larval development. Its absence or inactivity interrupts development and precludes metamorphosis. Histological changes are important diagnostic criteria for evaluating thyroid gland activity. However, there is a large larval diversity where the development of the thyroid gland development has not been studied. Pleurodema borellii is an anuran from northwest of Argentina with typical omnivorous pond tadpoles that can be easily raised in captivity. This study explores the histo-morphological changes of the thyroid gland architecture during larval development. Histological parameters indicate peak glandular activity in parallel with the intensity of the metamorphic transformations. These parameters regress towards the end of metamorphosis, indicating low TH release. P. borellii's thyroid gland does not appear to have relevant activity in post-metamorphic juvenile stages. This study is a first step towards understanding endocrine regulation during the development of Pleurodema borellii, and a reference to future studies in this species involving thyroid-dependent processes.     

Mammary epithelial cell: influence of extracellular matrix composition and organization during development and tumorigenesis

Stromal-epithelial interactions regulate mammary gland development and are critical for the maintenance of tissue homeostasis. The extracellular matrix, which is a proteinaceous component of the stroma, regulates mammary epithelial growth, survival, migration and differentiation through a repertoire of transmembrane receptors, of which integrins are the best characterized. Integrins modulate cell fate by reciprocally transducing biochemical and biophysical cues between the cell and the extracellular matrix, facilitating processes such as embryonic branching morphogenesis and lactation in the mammary gland. During breast development and cancer progression, the extracellular matrix is dynamically altered such that its composition, turnover, processing and orientation change dramatically. These modifications influence mammary epithelial cell shape, and modulate growth factor and hormonal responses to regulate processes including branching morphogenesis and alveolar differentiation. Malignant transformation of the breast is also associated with significant matrix remodeling and a progressive stiffening of the stroma that can enhance mammary epithelial cell growth, perturb breast tissue organization, and promote cell invasion and survival. In this review, we discuss the role of stromal-epithelial interactions in normal and malignant mammary epithelial cell behavior. We specifically focus on how dynamic modulation of the biochemical and biophysical properties of the extracellular matrix elicit a dialogue with the mammary epithelium through transmembrane integrin receptors to influence tissue morphogenesis, homeostasis and malignant transformation.     

Larval-to-adult conversion of a myogenic system in the frog, Xenopus laevis, by larval-type myoblast-specific control of cell division, cell differentiation, and programmed cell death by triiodo-L-thyronine

For the clarification of larval-to-adult muscle conversion, the authors established primary culture methods for adult- and larval-type myoblasts in the frog, Xenopus laevis, and examined the hormonal response in each case. The cell types were enzymatically dissociated from adult frog leg and tadpole tail muscles, respectively. The cells became attached to culture plates, proliferated, and fused with each other to form multinucleated myotubes within one week. Five significant differences between the two cell types were noted. (1) Adult cells showed greater proliferation activity than larval cells, the former increasing 5.5-fold over 6 days while the latter increase only 2.5-fold. (2) Differentiation (fusion) of larval type myoblasts started earlier. Cell fusion began on day 2 or 3 in larval cells and on day 4 in adult cells. (3) The metamorphic hormone, triiodo-L-thyronine (T3) decreased larval cell numbers to 56% of that of control-cultures on day 7 but had no effect on adult cell number. DNA synthetic activity (3H-thymidine incorporation) in larval cells decreased under T3 (10(-8) M) to 45% of the control level on day 7. (4) Differentiation of adult myoblasts into myotubes was promoted by T3, whereas that of larval cells diminished by half. (5) Myotube death was induced by T3 specifically in larval but not in adult cultures. In addition to the myotube death, double staining with TUNEL (in situ DNA nick end labeling) and anti-desmin antibody indicated that T3 induces myoblast (desmin+ cell) death specifically in larval but not in adult cells. It is thus evident that the conversion of a larval-type myogenic system during metamorphosis becomes possible through nearly totally specific control of cell division, cell differentiation, and programmed cell death at a precursor cell level by T3.     

Warmer winters reduce frog fecundity and shift breeding phenology,which consequently alters larval development and metamorphic timing

One widely documented phenological response to climate change is the earlier occurrence of spring‐breeding events. While such climate change‐driven shifts in phenology are common, their consequences for individuals and populations have rarely been investigated. I addressed this gap in our knowledge by using a multi‐year observational study of six wood frog (Rana sylvatica) populations near the southern edge of their range. I tested first if winter temperature or precipitation affected the date of breeding and female fecundity, and second if timing of breeding affected subsequent larval development rate, mass at metamorphosis, date of metamorphosis, and survival. Warmer winters were associated with earlier breeding but reduced female fecundity. Winter precipitation did not affect breeding date, but was positively associated with female fecundity. There was no association between earlier breeding and larval survival or mass at metamorphosis, but earlier breeding was associated with delayed larval development. The delay in larval development was explained through a counterintuitive correlation between breeding date and temperature during larval development. Warmer winters led to earlier breeding, which in turn was associated with cooler post‐breeding temperatures that slowed larval development. The delay in larval development did not fully compensate for the earlier breeding, such that for every 2 days earlier that breeding took place, the average date of metamorphosis was 1 day earlier. Other studies have found that earlier metamorphosis is associated with increased postmetamorphic growth and survival, suggesting that earlier breeding has beneficial effects on wood frog populations.     

Early larval development and metamorphosis in the summer flounder: changes in per cent whole-body water content and effects of altered thyroid status

At the end of premetamorphosis, summer flounder Paralichthys dentatus larvae had 84·1% whole-body water content (WBW), which decreased to the lowest levels (8·5%) at the start of metamorphic climax (MC). During mid- and late MC, %WBW was slightly higher (82·1%) then returned to the lowest levels at the juvenile stage. In fish treated with thyroxine (T₄-Na salt, 100 ng ml⁻¹) beginning at premetamophosis, %WBW never differed from controls of the same age throughout metamorphosis, despite an earlier start of metamorphic climax and transitional settling behaviour. This suggests that thyroid hormones do not mediate the drop in %WBW which accompanies natural metamorphosis. Thiourea (TU, 30 μg ml⁻¹) treatment of fish over the same period induced a developmental stasis in early MC which was accompanied by initially higher %WBW than controls at 33 days post-hatch, followed by a progressive decrease to abnormally low %WBW by 42 and 45 days post-hatch. Since concurrent treatment with TU+T₄ rescued the fish from both the TU-induced developmental stasis and abnormally low %WBW, these findings suggest that thyroid hormones, or thyroid hormone-mediated developmental progression, are necessary for regulating %WBW.     

One of the duplicated matrix metalloproteinase-9 genes is expressed in regressing tail during anuran metamorphosis

The drastic morphological changes of the tadpole are induced during the climax of anuran metamorphosis, when the concentration of endogenous thyroid hormone is maximal. The tadpole tail, which is twice as long as the body, shortens rapidly and disappears completely in several days. We isolated a cDNA clone, designated as Xl MMP-9TH, similar to the previously reported Xenopus laevis MMP-9 gene, and showed that their Xenopus tropicalis counterparts are located tandemly about 9 kb apart from each other in the genome. The Xenopus MMP-9TH gene was expressed in the regressing tail and gills and the remodeling intestine and central nervous system, and induced in thyroid hormone-treated tail-derived myoblastic cultured cells, while MMP-9 mRNA was detected in embryos. Three thyroid hormone response elements in the distal promoter and the first intron were involved in the upregulation of the Xl MMP-9TH gene by thyroid hormone in transient expression assays, and their relative positions are conserved between X. laevis and X. tropicalis promoters. These data strongly suggest that the MMP-9 gene was duplicated, and differentiated into two genes, one of which was specialized in a common ancestor of X. laevis and X. tropicalis to be expressed in degenerating and remodeling organs as a response to thyroid hormone during metamorphosis.     

Metamorphosis-associated and region-specific expression of calbindin gene in the posterior intestinal epithelium of Xenopus laevis larva

The present study used a molecular approach toward understanding the mechanism of hormone- and region-dependent remodeling of the small intestine during metamorphosis of Xenopus laevis . A protein spot was noticed on a two-dimensional polyacrylamide gel as a protein whose expression was metamorphic stage- and region-dependent. The protein was identified as the Xenopus homolog (Xcalbindin) of chick calbindin D_28k. Xcalbindin expression in the intestine was restricted to absorptive cells in the posterior part, being detectable at stages 49–61, not detectable at stages 62–63, detectable again at stages 64–66, and finally becoming undetectable in the adult. During spontaneous metamorphosis, the level of Xcalbindin mRNA was significantly increased between stages 57 and 58, dramatically reduced at stage 59, and the mRNA was undetectable from stages 60–63, after which it was weakly re-expressed until the end of metamorphosis. Such up- and down-regulation of Xcalbindin mRNA was induced precociously by exogenous thyroid hormone. These results indicated that Xcalbindin is a specific marker of the differentiated absorptive cells of the intestine. Immunohistochemistry with specific antibodies against Xcalbindin demonstrated that precursor cells of adult intestinal epithelial cells expressed Xcalbindin. Considering these results, the origin of adult intestinal epithelial cells was discussed.     

Molecular mechanisms for thyroid hormone-induced remodeling in the amphibian digestive tract: a model for studying organ regeneration

During amphibian metamorphosis the digestive tract is extensively remodeled under the control of epithelial-connective tissue interactions. At the cellular level, larval epithelial cells undergo apoptosis, while a small number of stem cells appear, actively proliferate, and then differentiate to form adult epithelium that is analogous to its mammalian counterpart. Therefore the amphibian digestive tract is a unique model system for the study of postembryonic organ regeneration. As amphibian intestinal remodeling can be triggered by thyroid hormone (TH), the molecular mechanisms involved can be studied from the perspective of examining the expression cascade of TH response genes. A number of these genes have been isolated from the intestine of Xenopus laevis. Recent progress in the functional analysis of this cascade has shed light on key molecules in intestinal remodeling such as matrix metalloproteinase-11, sonic hedgehog, and bone morphogenetic protein-4. These genes are also thought to play key roles in organogenesis and/or homeostasis in both chick and mammalian digestive tract, suggesting the existence of conserved mechanisms underlying such events in terrestrial vertebrates. In this article, we review our recent findings in this field, focusing on the development of adult epithelium in the X. laevis intestine.     

Distinct expression profiles of transcriptional coactivators for thyroid hormone receptors during Xenopus laevis metamorphosis

The biological effects of thyroid hormone (T3) are mediated by the thyroid hormone receptor (TR). Amphibian metamorphosis is one of the most dramatic processes that are dependent on T3. T3 regulates a series of orchestrated developmental changes, which ultimately result in the conversion of an aquatic herbivorous tadpole to a terrestrial carnivorous frog. T3 is presumed to bind to TRs, which in turn recruit coactivators, leading to gene activation. The best-studied coactivators belong to the p160 or SRC family. Members of this family include SRC1/ NCoA-1, SRC2/TIF2/GRIP1, and SRC3/pCIP/ACTR/AIB-l/RAC-3/TRAM-1. These SRCs interact directly with liganded TR and function as adapter molecules to recruit other coactivators such as p300/CBP. Here, we studied the expression patterns of these coactivators during various stages of development. Amongst the coactivators cloned in Xenopus laevis, SRC3 was found to be dramatically upregulated during natural and T3-induced metamorphosis, and SRC2 and p300 are express     

Cell-cell interactions during remodeling of the intestine at metamorphosis in Xenopus laevis

Amphibian metamorphosis is accompanied by extensive intestinal remodeling. This process, mediated by thyroid hormone (TH) and its nuclear receptors, affects every cell type. Gut remodeling in Xenopus laevis involves epithelial and mesenchymal proliferation, smooth muscle thickening, neuronal aggregation, formation of intestinal folds, and shortening of its length by 75%. Transgenic tadpoles expressing a dominant negative TH receptor (TRDN) controlled by epithelial-, fibroblast-, and muscle-specific gene promoters were studied. TRDN expression in the epithelium caused abnormal development of virtually all cell types, with froglet guts displaying reduced intestinal folds, thin muscle and mesenchyme, absence of neurons, and reduced cell proliferation. TRDN expression in fibroblasts caused abnormal epithelia and mesenchyme development, and expression in muscle produced fewer enteric neurons and a reduced inter-muscular space. Gut shortening was inhibited only when TRDN was expressed in fibroblasts. Gut remodeling results from both cell-autonomous and cell-cell interactions.