Programmed cell death and heterolysis of larval epithelial cells by macrophage-like cells in the anuran small intestine in vivo and in vitro.

The degenerative processes in the larval small intestine of Xenopus laevis tadpoles during spontaneous metamorphosis and during thyroid hormone-induced metamorphosis in vitro were examined by electron microscopy. Around the beginning of spontaneous metamorphic climax (stages 59-61), both apoptotic bodies derived from larval epithelial cells and intraepithelial macrophage-like cells suddenly increase in number. The macrophage-like cells become rounded and enlarged because of numerous vacuoles containing the apoptotic bodies. Mitotic profiles of the macrophage-like cells, however, are localized in the connective tissue where different developmental stages of macrophage-like cells are present. After stage 62, the intraepithelial macrophage-like cells decrease in number, while large macrophage-like cells which include the apoptotic bodies and retain intact cell membranes and nuclei appear in the lumen. Degenerative changes similar to those during spontaneous metamorphosis described above could be reproduced in vitro. In tissue fragments isolated from the small intestine of stage 57 tadpoles and cultured in the presence of thyroid hormone, the number of intraepithelial macrophage-like cells reaches its maximum around the 3rd day of cultivation when the larval epithelial cells most rapidly decrease in number. These results suggest that the rapid degeneration of larval epithelial cells occurs not only because of apoptosis of the epithelial cells themselves but also from heterolysis by macrophages. The macrophages probably originate in the connective tissue, actively proliferate, migrate into the larval epithelium around the beginning of metamorphic climax, and are finally extruded into the lumen.     

Metamorphosis alters the response to spinal cord transection in Xenopus laevis frogs

A series of studies has examined the response of the spinal cord to lesions made at various stages prior to and after metamorphic climax in the clawed frog Xenopus laevis. Complete transections made between Nieuwkoop and Faber (1956) stages 50 and 62 were followed by gradual recovery of righting and coordinated swimming as animals metamorphosed into juveniles (stage 66). Examination of descending axonal projections using horseradish peroxidase (HRP) showed fibers crossing the lesion site and distributing to the caudal lumbar spinal cord. These fibers could be traced from more rostral spinal segments as well as from brainstem injections of HRP. No evidence for rostrally projecting fibers crossing the lesion was obtained. Juvenile frogs of varying ages failed to demonstrate recovery of coordinated swimming or reconstitution of spinal descending pathways. In an additional series of animals, spinal transections were made within 1 or 2 days of tail resorption to assess whether regenerative capacities extended at all into post-metamorphic stages. No evidence for regeneration was found. Studies of metamorphosing frogs after spinal transections showed that fibers crossed the lesion within 5-12 days of transection, well prior to the end of metamorphic climax; however, in some cases in which metamorphosis seemed arrested, little regeneration was observed. Immunocytochemical studies showed that fibers containing serotonin (5-HT) were included in the population of axons that rapidly crossed the lesion after transection at metamorphic stages. These results are compared to those for lesions of the dorsal columns and other systems in developing and juvenile Xenopus. It is suggested that both metamorphosis-related hormonal changes, and axon substrate pathways, may affect the regenerative response in the Xenopus central nervous system (CNS).     

Synapse formation and modification between distal retinal neurons in larval and juvenile Xenopus

A serial section analysis of photoreceptor synaptic bases was undertaken in the clawed frog Xenopus laevis. The developmental period from tadpole stage 48 through metamorphosis was studied. Horizontal cells contacted rod and cone photoreceptors at ribbon synapses; the number of such contacts per receptor base was constant for rods, but increased for cones as a function of developmental stage. In pre-metamorphic animals bipolar cells contacted receptors only through basal junctions; their number in cone bases increased dramatically during development but was unchanged in rod bases. A densitometric estimation of the cleft width of basal junctions showed that it ranged from 10 to 18 nm, but the junctions could not be divided reliably into the 'wide' and 'narrow' categories reported for other vertebrate species. Near metamorphic climax a new type of ribbon-related bipolar cell junction appeared. Gap junctions between horizontal cells and conventional synapses of horizontal cell onto bipolar cell processes were first seen in mid-larval developmental stages.     

Glomerular development and growth of the renal blood vascular system in Xenopus laevis (Amphibia: Anura: Pipidae) during metamorphic climax.

Microcorrosion casts of the renal vascular system of tadpoles of the Clawed Frog, Xenopus laevis, were observed by scanning electron microscopy. Glomerular differentiation was studied qualitatively and quantitatively during developmental stages 56-66 (metamorphic climax). The general structure of the renal vascular system corresponds to the pattern commonly found in anurans; however, the arterial supply has conspicuous connecting vessels that supply groups of glomeruli. In the dorsal part of the kidney, qualitative differentiation of glomerular structures precedes quantitative growth. The ventral part of the kidney has larger, well-developed renal corpuscles of nearly adult appearance. Four developmental stages of glomerulogenesis are distinguished morphologically and their glomerular and vascular growth is analyzed.     

Immunologic reactivity to TNP-Ficoll during development and ageing in Xenopus laevis, the South African clawed toad

The immunological response of Xenopus laevis to haptenated Ficoll was examined throughout development. The capacity to respond to TNP-Ficoll originated with the first appearance (at stage 48, 8 days post-fertilisation) of mature thymic lymphocytes, and preceded the ability to respond to heterologous erythrocytes. During premetamorphosis the response increased, while during prometamorphosis , particularly at stages 57-58, there was a marked reduction. The response recovered during the metamorphic climax and immature adult stages, increasing further at the onset of sexual maturity. The reduced response during prometamorphosis parallels the reported reduction in other thymus-dependent responses.     

Neurotrophin receptors and enteric neuronal development during metamorphosis in the amphibian<Emphasis Type="Italic"> Xenopus laevis</Emphasis>

During metamorphosis, the frog intestine goes through a dramatic shortening with extensive apoptosis and regeneration in the epithelial layer and connective tissue. Our aim was to study changes in the enteric nervous system represented by one inhibitory (vasoactive intestinal polypeptide; VIP) and one excitatory (substance P, neurokinin A; SP/NKA) nerve population and concomitant changes in neurotrophin receptor occurrence during this development in the gut of Xenopus laevis adults and tadpoles at different stages of metamorphosis (NF stages 57–66). Sections were incubated with antibodies against the neurotrophin Trk receptors and p75^NTR, and the neurotransmitters VIP and SP/NKA. Trk-immunoreactive nerves increased dramatically but transiently in number during early metamorphic climax. Nerves immunoreactive for p75^NTR were present throughout the gut, decreased in number in the middle intestine during climax, and increased in the large intestine during late metamorphosis. The percentage of VIP-immunoreactive nerves did not change during metamorphosis. SP/NKA-immunoreactive nerves were first apparent at NF stages 61–62 in the middle intestine and increased in the stomach and large intestine during metamorphosis. Endocrine cells expressing SP/NKA increased in number in stomach, proximal, and middle intestine during metamorphic climax. Thus, neurotrophin receptors are expressed transiently in neurons of the enteric nervous system during metamorphosis in Xenopus laevis and SP/NKA innervation is more abundant in the intestine of the postmetamorphic frog than in the tadpole.This study was supported by grants from the Swedish Research Council to S. Holmgren     

Cloning of a cDNA for Xenopus prolactin receptor and its metamorphic expression profile

A pituitary hormone, prolactin (PRL) shows various effects on cellular metabolism in amphibians, such as stimulation of larval tissue growth and inhibition of metamorphic changes. All these effects are mediated by its cell surface receptor. However, lack of information on PRL receptor (PRL-R) gene expression has made the physiological importance of the PRL/PRL-R system obscure in amphibian metamorphosis. Hence, a Xenopus PRL-R cDNA was cloned, its structure was characterized, and specific binding of PRL to Xenopus PRL-R expressed in COS-7 cells was confirmed. In adult tissues, high level expression was found in the lung, heart, brain, thymus and skin, and low level in the oviduct, kidney and spinal cord. The developmental expression pattern showed that PRL-R messenger ribonucleic acid (mRNA) was expressed in the brain and tail from premetamorphosis and the level increased toward late metamorphosis, suggesting that PRL may inhibit the metamorphic changes in those organs. The level of brain PRL-R mRNA reached a peak just at the start of the metamorphic climax stages and then decreased, whereas in the tail, mRNA expression peaked at late metamorphosis. In the kidney, mRNA expression increased and reached a maximum level at the end of metamorphosis. The results obtained were discussed in relation to metamorphosis.     

Thyroid hormone directly induces hepatocyte competence for estrogen-dependent vitellogenin synthesis during the metamorphosis of Xenopus laevis

Hepatocytes competent for estrogen-dependent vitellogenin synthesis appeared and increased in number in the liver at the metamorphic climax of Xenopus laevis (A. Kawahara, S. Kohara, Y. Sugimoto, and M. Amano, 1987, Dev. Biol. 122, 139-145). The present study was conducted to determine whether cells competent for vitellogenin synthesis could be induced by thyroid hormone in a primary culture of larval hepatocytes. The thyroid hormone, triiodothyronine (T3), directly induced the competent cells in a primary culture of premetamorphic larval hepatocytes in a dose- and duration-dependent manner. The competency acquired in response to T3 persisted after removal of the hormone. Aphidicholin, an inhibitor of DNA synthesis, failed to block this induction, suggesting the presence of a "precursor cell fraction." This cell fraction in the hepatocyte population increased with the progress of metamorphosis. The thyroid hormone is thus considered the cause of competent cell formation at metamorphic climax.     

Morphologic changes of the basal lamina in the small intestine of Xenopus laevis during metamorphosis

Further investigations of the epithelial and mesothelial basal lamina of the duodenum of Xenopus laevis during metamorphosis were performed by means of scanning electron microscopy (SEM) and histochemical techniques using polyethyleneimine (PEI) to demonstrate anionic sites as well as light- and transmission-electron-microscopic methods involving morphometric analysis. The basal lamina of the duodenal epithelial cells was smooth, and it was occasionally curved along the processes of the epithelial cells (stages 56-59). The basal lamina became thicker by folding, and the thickness of the folded basal lamina exceeded 1 micron (stages 60-62). Subsequently, the folded basal lamina disappeared gradually and became almost smooth again and consisted of only one layer (stages 63-66). After removing the epithelium by boric acid, SEM revealed that the small ridges of the basal lamina protruded like a mesh-work into the luminal side, and the luminal surface of the basal lamina became smooth at later stages of the metamorphic climax. The electron-dense granules of PEI-positive material were localized at both sides of the lamina densa at regular intervals (80-100 nm). The basal lamina of the mesothelial cells was almost smooth at stages 56-59 and started to show occasional slight folding. This folding became continuous and deeper (stages 60-62). The folded mesothelial basal lamina disappeared except for the cell-associated basal lamina and became smooth again at later stages of the metamorphic climax (stages 63-66). These morphologic changes of the basal lamina observed in the epithelium and mesothelium may be induced by common factors. We suggest that physical changes in the small intestine involving the shortening and narrowing should be a main factor to cause these changes in the basal lamina. Furthermore, morphometric analysis proposed that the basal lamina becomes more complex by adding newly synthesized basal lamina material, especially in the epithelium.     

Plasticity of the duration of metamorphosis in the African clawed toad

In organisms with complex life cycles, such as amphibians, selection is thought to have minimized the duration of metamorphosis, because this is the stage at which predation risk is presumed to be highest. Consequently, metamorphic duration is often assumed to show little if any environmentally induced plasticity, because the elevation in the extrinsic mortality risk associated with prolonging metamorphosis is presumed to have selected for a duration as short as is compatible with normal development. We examined the extent to which metamorphic duration in the anuran amphibian Xenopus laevis was sensitive to environmental temperature. Metamorphic duration was influenced by body size, but independent of this effect, it was strongly influenced by environmental temperature: the duration at 18 °C was more than double that at 24 and 30 °C. We also compared the vulnerability of larval, metamorphosing and post metamorphic Xenopus to predators by measuring their burst swimming speeds. Burst swim speed increased through development and while we found no evidence that it was reduced during metamorphosis, it did increase sharply on completion of metamorphosis. We therefore found no evidence of a substantial increase in vulnerability to predators during metamorphosis compared with larval stages, and hence the slowing of metamorphosis in response to temperature may not be as costly as has been assumed.     

Conversion of red blood cells (RBCs) from the larval to the adult type during metamorphosis in Xenopus: specific removal of mature larval-type RBCs by apoptosis

The conversion of hemoglobins (Hbs) and red blood cells (RBCs) from the larval to the adult type was monitored during normal metamorphosis in Xenopus laevis, and in artificially induced metamorphosis-arrested and precociously metamorphosed animals by means of SDS-PAGE, Hb immunohistochemistry, and double-staining with in situ DNA nick-end labeling (TUNEL) for detection of apoptosis and Hb immunostain. During normal metamorphosis, larval RBCs gradually decreased and, conversely, adult RBCs increased in number. However, in metamorphosis-arrested tadpoles, the larval-adult conversion of RBCs did not occur within 4 weeks, but did rather within 6 months after the controls metamorphosed. In order to identify possible mechanisms for the specific removal of larval RBCs from circulation in metamorphosing and metamorphosed animals, double-staining experiments with TUNEL and Hb immunostain were carried out. During metamorphic climax, many larval RBCs expressed TUNEL-positive reactions in the spleen, suggesting that the larval RBCs were specifically removed from the spleen during metamorphosis. When the larval RBCs were transferred to the circulatory system of histocompatible control adults, they survived for a long time, and no transferred RBCs showed TUNEL-positive reactions. In contrast, larval RBCs transferred to histocompatible adults that had been treated with T3 were reduced in number in the circulatory system of the recipients. Double-staining experiments demonstrated that the transferred larval RBCs underwent apoptosis in the spleen and liver of the adult recipients treated with T3, indicating that the mature larval-type RBCs were specifically removed from metamorphosing animals by apoptotic cell death under the influence of THs.     

Thyroxine-binding proteins in liver and tail of Rana catebeiana undergoing metamorphosis.

Presence of a thyroxine-binding protein was demonstrated in vivo in cell sap of tail and liver of metamorphosing Rana catesbeiana tadpoles. Thyroxine-binding protein was not present in tail of prematamorphic tadpoles while it appeared during progressing metamorphosis roughly coinciding with the beginning of tail resorption. Susceptibility to pronase indicates that this thyroxine-binding macromolecule is protein in nature. Thyroxine-binding in liver was already present during premetamorphic stages and increased further during metamorphosis. A further difference between tail and liver thyroxine-binding protein was evidenced by molecular sieve chromatography on Sephadex G-200 indicating a molecular weight of thyroxine-binding protein in the tail of 60 000 as opposed to 42 000 for liver. Scatchard analysis of tail cell sap of tadpoles in metamorphic climax revealed a high affinity thyroxing binding site (Kd of 2 - 10(-10) M) of low capacity (1.7 pmol per mg protein) while tadpoles in premetamorphic stage had a thyroxine-binding site of lower affinity (9 - 10(-10) M) and higher capacity (4.8 pmol per mg protein). Thus affinity of thyroxine binding is 4-fold in metamorphic climax and appears to reflect the appearance of thyroxine binding observed in vivo.     

A change of the hepatocyte population is responsible for the progressive increase of vitellogenin synthetic capacity at and after metamorphosis of Xenopus laevis

Synthesis of the egg yolk precursor protein, vitellogenin, can be induced in adult, but not in larval, amphibian hepatocytes by estrogen treatment. The transition process for this inducibility of hepatocytes during development of Xenopus laevis was examined, using primary cultures of hepatocytes. This was found to occur at about the metamorphic climax of stage 62, although the level of vitellogenin production was very limited at this stage. This low level seemed due neither to insufficient estradiol-17 beta nor to high estrogen-degrading activity. The level of synthesis gradually increased following metamorphosis. Immunohistochemical analysis showed that fewer than 5% of the hepatocytes at stage 62 could be stained with antivitellogenin antibody and that the stained cell fraction subsequently increased gradually for several months after metamorphosis. These findings indicate that adult-type cells capable of synthesizing vitellogenin appear at metamorphosis and then expand their population in the liver during postmetamorphic maturation.     

The decrease in plasma melatonin at metamorphic climax in Rana catesbeiana (bullfrog) tadpoles is induced by thyroxine.

Melatonin decreases in the plasma of Rana catesbeiana (bullfrog) tadpoles at the climax of metamorphosis when the thyroxine (T(4)) level peaks. Since melatonin inhibited thyroid function in vitro, it would be of interest to determine if the decline in plasma melatonin permits greater thyroid hormone secretion, or if the increasing levels of T(4) cause the climactic decrease in plasma melatonin. The reciprocal effects of administering T(4) or melatonin just prior to metamorphic climax were examined in tadpoles kept at 22 degrees C on an 18L:6D cycle. If melatonin functions as a thyroid antagonist at later metamorphic stages, administration of melatonin should decrease plasma T(4), whereas if T(4) causes the decline in plasma melatonin, T(4) treatment of tadpoles prior to climax should induce the climactic melatonin decrease prematurely. Once daily injection of 40 microg melatonin for 5 days at 19.30 h had no effect on metamorphic progress, or on plasma T(4) or melatonin levels, except for a transient rise in melatonin just after the injection. Immersion in 2.2x10(-4) M melatonin for 6 days accelerated metamorphosis and decreased plasma melatonin, but had no effect on plasma T(4). Administration of T(4) by injection of 0.2 microg, or immersion in a 6.3x10(-8) M solution accelerated metamorphosis more than melatonin immersion, raised plasma T(4) to climax levels, and induced a decrease in plasma melatonin. We conclude that rapid clearance of exogenous melatonin from the circulation in these experiments did not allow it to affect plasma T(4), and that there is clear evidence that the rise in T(4) induces the climax decrease in plasma melatonin. The finding that immersion in a high level of melatonin can lower plasma melatonin and accelerate metamorphosis, whereas a single daily injection does not, provides an explanation for some of the contradictory reports in the literature concerning melatonin's effect on tadpole metamorphic progress.     

Characterization of metamorphic changes in anuran larval epidermis using lectins as probes

The skin of an adult frog of Xenopus laevis was characterized by the reactivity of 20 lectins. The lectins were classified into six groups in their binding to the epidermal cells: Lycopersicon esculentum lectin (LEL)-type which was positive for all epidermal cells; Pisum sativum agglutinin (PSA)-type for stratum germinativum; succinylated wheat germ agglutinin (sWGA)-type for strata spinosum, granulosum and corneum; Dolichos biflorus agglutinin (DBA)-type for strata germinativum and spinosum; peanut agglutinin (PNA)-type for stratum spinosum; and Ulex europaeus agglutinin (UEA-I)-type for strata granulosum and corneum. PSA and sWGA were utilized as markers of mitotically active germinative cells and the differentiated cells of the epidermis, respectively, to describe the metamorphic conversion of larval epidermal cells to adult type. PSA stained all epidermal cells of tadpoles before metamorphic climax. At the end of metamorphosis, PSA-positive cells were restricted to cells in the basal layer of body epidermis while all the tail epidermis remained PSA-positive. The other cell marker, sWGA, only stained apical cells in tadpole epidermis. During the metamorphic climax, sWGA-positive cells appeared in the cells beneath the stratum corneum of the body region, but not in the tail region. The present study demonstrates that PSA and sWGA are useful to investigate metamorphic changes in tadpole epidermal cells.     

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.     

Ontogenic emergence and localization of larval skin antigen molecule recognized by adult T cells of Xenopus laevis: Regulation by thyroid hormone during metamorphosis

Results from previous studies using an inbred strain of Xenopus laevis have led to the proposition that metamorphosis includes the events by which the newly differentiating adult immune system, including T lymphocytes, recognizes and eliminates larval skin cells as 'non-self'. More recently, a larval antigen targeted by adult T cells was identified as a 59 kDa protein with a specific peptide sequence. Using antisera directed against the larval antigen and the peptide, immunohistochemistry and western blotting were done to examine expression of the 59 kDa larval antigen in the skin during larval and metamorphic periods. There was no expression before Nieuwkoop and Faber stage 53. Expression was first seen at the beginning of metamorphic stage 54, when hind limbs appear, and increased thereafter, in apical and skein cells of both trunk and tail regions. In the trunk region, expression started to decrease at stage 58, until it completely disappeared at stage 62 (metamorphic climax). In the tail skin, however, expression persisted throughout the metamorphic stages. Treatment of larvae with thyroid hormone (TH) resulted in repression of expression of the 59 kDa molecule in a dose-dependent manner. Downregulation occurred earlier in the trunk than in the tail skin. These results suggest involvement in metamorphic events of an immunological mechanism: differential expression of the larval antigen in the trunk and tail skin cells due to their differing concentration of TH results in the tail, but not the trunk skin, being selectively attacked by the newly differentiating adult-type immune system.