Cloning and expression of xP1-L, a new marker gene for larval surface mucous cells of tadpole stomach in Xenopus laevis

The amphibian gastrointestinal tract is remodeled from a larval-type to an adult-type during metamorphosis. In the present study, we examined the products of subtractive hybridization between tadpole and frog stomach cDNAs of Xenopus laevis in order to identify genes expressed specifically in the larval stomach epithelium. A new gene homologous to xP1 was obtained and named xP1-L. In the genome database of Silurana tropicalis, we found a homologue of xP1-L and named it stP1-L. RT-PCR showed that the expression of xP1-L was detected in stage 41/42 tadpoles. In addition, in situ hybridization showed that xP1-L was localized to surface mucous cells of the larval stomach. The H(+)/K(+)-ATPase beta subunit, a marker gene for manicotto gland cells in the tadpole stomach, was also detected at the same time. However, adult marker genes such as xP1 for surface mucous cells and pepsinogen C (PgC) for oxynticopeptic cells were not expressed in the tadpole stages. The expression of xP1-L gradually decreased towards the metamorphic climax and disappeared after stage 61 when larval-type gastric epithelium is replaced by adult-type. We found that xP1-L was never expressed in surface mucous cells of the adult-type stomach, and xP1, instead of xP1-L, was expressed. During T3-induced metamorphosis, xP1-L expression decreased in the same manner as during natural metamorphosis. Thus, xP1-L is a useful marker for larval surface mucous cells in tadpole stomach. This is the first demonstration of a marker gene specific for the surface mucous cells of the larval stomach.     

Differential expression of the TFF-peptides xP1 and xP4 in the gastrointestinal tract of Xenopus laevis

TFF-peptides (formerly P-domain peptides, trefoil factors) represent major secretory products of the mammalian gastrointestinal tract. A molecular cloning approach revealed the existence of two TFF-peptides, xP1 and xP4, also in the stomach of Xenopus laevis. Here, the localization of these two peptides by Western blot analysis as well as immunohistochemistry is presented. xP1 is found predominantly in the surface mucous cells of the stomach, whereas xP4 is mainly localized to a specific population of goblet cells in the esophagus, to mucous neck cells of the stomach, and to closely resembling cells in antral glands. xP4 in the esophagus and in the stomach differ by their N-glycosylation patterns. Compared to mammalian TFF-peptides, xP1 obviously represents the frog homologue of human TFF1 (formerly pS2) and xP4 seems to be the amphibian equivalent of human TFF2 (formerly hSP).     

T3-hydrocortisone synergism on adult-type erythroblast proliferation and T3-mediated apoptosis of larval-type erythroblasts during erythropoietic conversion in Xenopus laevis

 The conversion of an erythropoietic system from larval to adult type in anuran amphibia may possibly come about through cell replacement. The hormonal regulation of apoptosis of larval-type precursor cells and adult-type cell proliferation has yet to be examined in detail. In amphibians, corticoids synergize T₃ action during metamorphosis. In the present study, examination was made of the process of larval-to-adult conversion in the liver erythropoietic site of Xenopus laevis, with special attention to how these metamorphic hormones, T₃ and corticoid, regulate programmed cell death specific for larval erythroblasts and the proliferation of adult cells. Immunohistochemical analysis of liver sections indicates that the number of larval erythroblasts decreased to less than 50% at the early climax stage (stages 59–60) of metamorphosis. Overall liver morphology greatly changed subsequent to the climax stage from the three-lobe to the two-lobe shape. The addition of T₃ (10^-8 M) to premetamorphic tadpoles induced considerable liver morphological change and a 50% decrease in larval-type erythroblasts. These erythroblast decreases seem to take place through the apoptotic process, since double-staining experiments with in situ DNA nick-end labeling (TUNEL) and hemoglobin immunostaining revealed that DNA breakage of nuclei, a well-known feature of apoptosis, occured specifically in larval erythroblasts during prometamorphosis. Hydrocortisone (HC), which modulates T₃ action during metamorphosis, was found not to be a factor in larval cell decrease. But adult erythroblasts increased by 8 times as much through the action of T₃ and 32 times as much by the action of T₃ plus HC, indicating the important action of T₃–HC synergism. It thus follows that the erythropoietic system is converted during metamorphosis effectively by two distinct hormonal mechanisms, T₃–HC synergism on adult erythroblast proliferation and T₃-mediated programmed death of larval precursor cells. Accepted: 14 January 1999     

Erythropoietin protects red blood cells from TRAIL1-induced cell death during red blood cell transition in Xenopus laevis

In anuran amphibians, larval red blood cells (RBCs) are replaced by adult-type RBCs during metamorphosis. We previously showed that tumor necrosis factor-related apoptosis-inducing ligand 1 (TRAIL1) induces apoptosis in larval-, but not adult-type RBCs in Xenopus laevis. We also found that protein kinase C (PKC) activation is involved in establishing resistance to TRAIL1-induced apoptosis in adult-type RBCs. Here, we investigated whether erythropoietin (EPO), which induces PKC activation in mammalian erythroblasts, is involved in the RBC transition in X. laevis. RT-PCR analysis revealed that epo mRNA was upregulated in the lung, from the metamorphic climax (stage 60) onward. In an RBC culture system, EPO pretreatment significantly attenuated the TRAIL1-induced death of larval- and adult-type RBCs isolated from tadpoles and adults, probably due partly to PKC activation. In samples from froglets undergoing RBC transition, which included both larval- and adult-type RBCs, EPO exhibited a stronger protective effect on the adult-type than the larval-type RBCs. Newly differentiated RBCs isolated from tadpoles treated with a hemolytic reagent were more resistant to TRAIL1-induced cell death than non-treated controls. These results suggest that EPO functions to protect adult-type RBCs from TRAIL1-induced cell death during RBC transition, and that the protective effect might decrease as RBCs age.     

Adult-type pigment cells,which color the ocular sides of flounders at metamorphosis,localize as precursor cells at the proximal parts of the dorsal and anal fins in early larvae

Flounders form left-right asymmetry in body coloration during metamorphosis through differentiation of adult-type melanophores and xanthophores on the ocular side. As the first step in investigating the formation of flounder body coloration asymmetry, in this study, we aimed to determine where the precursors of adult-type chromatophores distribute in larvae before metamorphosis. In Paralichthys olivaceus and Verasper variegatus, GTP cyclohydrolase 2 (gch2), a common marker of melanoblasts and xanthoblasts, was found to be transiently expressed in cells located along the bilateral skeletal muscles at the basal parts of the dorsal and anal fins of premetamorphic larvae. When V. variegatus larvae were fed with a strain of Artemia collected in Brazil, this gch2 expression was abolished and the differentiation of adult-type melanophores was completely inhibited, while the density of larval melanophores was not affected. In a cell trace test in which the cells at the basal part of the dorsal fin were labeled with DiI at the premetamorphic stage, adult-type melanophores labeled with DiI were found in the skin on the ocular side after metamorphosis. These data suggest that, in flounder larvae, adult-type melanophores are distributed at the basal parts of the dorsal and anal fins as unpigmented precursor cells.     

Insulin-like growth factor 1 regulation of proliferation and differentiation of <Emphasis Type="Italic">Xenopus laevis</Emphasis> myogenic cells in vitro

To understand the mechanism of muscle remodeling during Xenopus laevis metamorphosis, we examined the in vitro effect of insulin-like growth factor 1 (IGF-1) on growth and differentiation of three different-fate myogenic cell populations: tadpole tail, tadpole dorsal, and young adult leg muscle. IGF-1 promoted growth and differentiation of both tail and leg myogenic cells only under conditions where these cells could proliferate. Inhibition of cell proliferation by DNA synthesis inhibitor cytosine arabinoside completely canceled the IGF-1’s cell differentiation promotion, suggesting the possibility that IGF-1’s differentiation-promotion effect is an indirect effect via IGF-1’s cell proliferation promotion. IGF-1 promoted differentiation dose dependently with maximum effect at 100–500 ng/ml. RT-PCR analysis revealed the upregulation (11-fold) of ifg1 mRNA expression in developing limbs, suggesting that IGF-1 plays a role in promoting muscle differentiation during limb development. The combined effect of triiodo-l-thyronine (T₃) and IGF-1 was also examined. In adult leg cells, IGF-1 promoted growth and differentiation irrespective of the presence of T₃. In larval tail cells, cell count was 76% lower in the presence of T₃, and IGF-1 did not promote proliferation and differentiation in T₃-containing medium. In larval dorsal cells, cell count was also lower in the presence of T₃, but IGF-1 enhanced proliferation and differentiation in T₃-containing medium. This result is likely due to the presence among dorsal cells of both adult and larval types (1:1). Thus, IGF-1 affects only adult-type myogenic cells in the presence of T₃ and helps accelerate dorsal muscle remodeling during metamorphosis.     

Genomic DNA fragmentation in red blood cells of the bullfrog during metamorphosis

Red blood cells (RBC) of the bullfrog ( Rana catesbeiana ) contain larval-type hemoglobin (Hb) during the larval period. At the beginning of metamorphosis, RBC containing adult-type Hb appear and two types of RBC coexist in the systemic circulation. During the metamorphic climax, RBC with larval-type Hb disappear from the circulation and, simultaneously, RBC containing adult-type Hb begin to circulate. These two types of RBC were separated by Percoll density gradient centrifugation to examine the molecular size of the genomic DNA of each population. DNA fragmentation was detected only in new RBC with adult-type Hb that appeared in the systemic circulation and remained throughout post-metamorphic life. Semiquantification of DNA on agarose gel showed that the degree of DNA fragmentation was highest at the metamorphic climax. As the existence of DNA fragments suggested endonucleolytic cleavage, nuclease activity was examined by an activity gel system and in vitro circular plasmid DNA digestion assays. The latter revealed that both types of RBC possess endonucleolytic activity throughout the pre- and post-metamorphic periods. Assays of endogenous endonucleolytic activities under different divalent ionic conditions suggested that mobilization of intracellular Ca²⁺-Mg²⁺ induces genomic DNA fragmentation in adult-type RBC.     

Detection, isolation and some properties of membrane proteinases from yeast mitochondria

The complete amino-acid sequences of two isocytochromes c (larval- and adult-type cytochromes c) purified from the housefly Musca domestica L. were determined. Their sequences differed at six positions from each other. More than 90% of the total cytochrome c was larval-type during larval stages. The amount of adult-type cytochrome c increased rapidly from 1 day before adult emergence, making the total cytochrome c content increase to approximately 2.5-times as much cytochrome c content as in larvae. Although the major cytochrome c species in flight muscles was adult-type, imaginal disks contained mainly larval-type cytochrome c.     

Loss of reactivity to pan-cadherin antibody in epidermal cells as a marker for metamorphic alteration of Xenopus skin

Pan-cadherin antibodies recognize the conserved C-terminal region of the family of cell-cell adhesion molecules, cadherins, and have a broad spectrum of reactivity to the molecules. In the present study, by immunohistochemistry using an anti-pan cadherin monoclonal antibody (mAb), expression dynamics of cadherins in epidermal tissues were analyzed during metamorphosis of Xenopus laevis. At early stages of development, the anti-pan cadherin mAb detected signals at cell-cell boundaries and in the cytoplasm of both trunk and tail epidermal cells. During metamorphosis, the immunoreactivity decreased in the trunk skin tissue but remained in the tail. At the climax stage, immunoreactivity was observed only in the regressing tail epidermis. The signals disappeared completely from the trunk epidermis, which had already transformed into adult-type tissue. This observation was confirmed by western blot analysis. A specific band was detected in the larval skin, but not in the adult lysate, at approximately 135 kDa in molecular size, corresponding to the molecular mass of cadherins. This different immunoreactivity in larvae and adults was observed in the epidermis of the skin, but not in any other tissues examined, that is, brain, kidney and liver. The immunoreactivity seen in larval epidermal cells was drastically downregulated by thyroid hormone treatment in vitro. These changes of immunoreactivity were specific for the C-terminal region of cadherins, suggesting intracellular alteration of the molecules during metamorphosis, and the anti-pan cadherin mAb can be a marker for larval-type epidermal cells that is applicable to analysis of Xenopus metamorphosis.     

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.     

Spatio-temporal expression profile of stem cell-associated gene LGR5 in the intestine during thyroid hormone-dependent metamorphosis in Xenopus laevis

Background

The intestinal epithelium undergoes constant self-renewal throughout adult life across vertebrates. This is accomplished through the proliferation and subsequent differentiation of the adult stem cells. This self-renewal system is established in the so-called postembryonic developmental period in mammals when endogenous thyroid hormone (T3) levels are high.

Methodology/Principal Findings

The T3-dependent metamorphosis in anurans like Xenopus laevis resembles the mammalian postembryonic development and offers a unique opportunity to study how the adult stem cells are developed. The tadpole intestine is predominantly a monolayer of larval epithelial cells. During metamorphosis, the larval epithelial cells undergo apoptosis and, concurrently, adult epithelial stem/progenitor cells develop de novo, rapidly proliferate, and then differentiate to establish a trough-crest axis of the epithelial fold, resembling the crypt-villus axis in the adult mammalian intestine. The leucine-rich repeat-containing G protein-coupled receptor 5 (LGR5) is a well-established stem cell marker in the adult mouse intestinal crypt. Here we have cloned and analyzed the spatiotemporal expression profile of LGR5 gene during frog metamorphosis. We show that the two duplicated LGR5 genes in Xenopus laevis and the LGR5 gene in Xenopus tropicalis are highly homologous to the LGR5 in other vertebrates. The expression of LGR5 is induced in the limb, tail, and intestine by T3 during metamorphosis. More importantly, LGR5 mRNA is localized to the developing adult epithelial stem cells of the intestine.

Conclusions/Significance

These results suggest that LGR5-expressing cells are the stem/progenitor cells of the adult intestine and that LGR5 plays a role in the development and/or maintenance of the adult intestinal stem cells during postembryonic development in vertebrates.     

Differential expression of two cathepsin Es during metamorphosis-associated remodeling of the larval to adult type epithelium in Xenopus stomach

Cathepsin E (CE) was purified from the foregut of Xenopus laevis tadpoles as a mature dimeric form. The purified enzyme was a typical CE among aspartic proteinases with respect to pH dependence of proteolytic activity, susceptibility to pepstatin, and having N-linked high-mannose type oligosaccharide chains. We isolated two cDNAs for the CE (CE1 and CE2) from adult stomach. The amino acid sequence of the N-terminal region of the purified CE coincided with the corresponding sequence predicted from CE1. Northern blot analysis and in situ hybridization were performed. The CE1 mRNA was highly expressed in surface mucous cells and gland cells constituting the larval epithelium of the foregut of pro-metamorphic tadpoles. As metamorphosis began and progressed, CE1 mRNA drastically decreased in amount, and subsequently both CE1 and CE2 mRNAs gradually increased. The increase in CE2 mRNA was detected shortly after the increase in CE1 mRNA. The decrease in CE1 expression correlated with degeneration of the larval type epithelium, while the increases in both CE1 and CE2 expression correlated with formation of the adult type epithelium. Thus, cathepsin E gene expression was differentially regulated during metamorphosis-associated remodeling of the larval to adult type epithelium in stomach.     

MHC class I antigens as surface markers of adult erythrocytes during the metamorphosis of Xenopus

An alloantiserum produced against Xenopus MHC class I antigens has been used to distinguish different erythrocyte populations at metamorphosis. By analysis using a fluorescence-activated cell sorter (FACS) analyzer, tadpole (stage 55) and adult erythrocytes have distinct volume differences and tadpole cells have no MHC antigens on the cell surface. Both tadpole and adult erythrocytes express a "mature erythrocyte" antigen marker, recognized by its monoclonal antibody (F1F6). During metamorphosis, immature erythrocytes, at various stages of differentiation, which express adult levels of cell-surface MHC antigens by 12 days after tail resorption, are found in the bloodstream. These immature cells are biosynthetically active, produce adult hemoglobin, and mature by 60 days after the completion of metamorphosis. Percoll gradient-density fractionation has shown that all of the cells in the new erythrocyte series express adult levels of MHC antigens but there is only a gradual increase in the amount of "mature erythrocyte" antigen. Tadpole erythrocytes, which are biosynthetically active during larval stages, produce small amounts of surface MHC antigens before the metamorphic climax and then become metabolically inactive. They are completely cleared from the circulation by 60 days after metamorphosis. Erythrocytes from tadpoles arrested in their development for long periods of time express intermediate levels of MHC antigens, suggesting a "leaky" expression of these molecules in the tadpole cells. The most abundant erythrocyte cell-surface proteins from tadpoles and adults, as judged by two-dimensional gel electrophoresis, are very different.     

Thyroid hormone receptor subtype specificity for hormone-dependent neurogenesis in Xenopus laevis

Thyroid hormone (T₃) influences cell proliferation, death and differentiation during development of the central nervous system (CNS). Hormone action is mediated by T₃ receptors (TR) of which there are two subtypes, TRα and TRβ. Specific roles for TR subtypes in CNS development are poorly understood. We analyzed involvement of TRα and TRβ in neural cell proliferation during metamorphosis of Xenopus laevis. Cell proliferation in the ventricular/subventricular neurogenic zones of the tadpole brain increased dramatically during metamorphosis. This increase was dependent on T₃ until mid-prometamorphosis, after which cell proliferation decreased and became refractory to T₃. Using double labeling fluorescent histochemistry with confocal microscopy we found TRα expressed throughout the tadpole brain, with strongest expression in proliferating cells. By contrast, TRβ was expressed predominantly outside of neurogenic zones. To corroborate the histochemical results we transfected living tadpole brain with a Xenopus TRβ promoter-EGFP plasmid and found that most EGFP expressing cells were not dividing. Lastly, treatment with the TRα selective agonist CO23 increased brain cell proliferation; whereas, treatment with the TRβ-selective agonists GC1 or GC24 did not. Our findings support the view that T₃ acts to induce cell proliferation in the tadpole brain predominantly, if not exclusively, via TRα.     

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     

Induction of metamorphosis by thyroid hormone in anuran small intestine cultured organotypically in vitro

Summary We have developed an organ culture system of the anuran small intestine to reproduce in vitro the transition from larval to adult epithelial form which occurs during spontaneous metamorphosis. Tubular fragments isolated from the small intestine ofXenopus laevis tadpoles were slit open and placed on membrane filters in culture dishes. In 60% Leibovitz 15 medium supplemented with 10% charcoal-treated serum, the explants were maintained in good condition for at least 10 days without any morphologic changes. Addition of triiodothyronine (T₃) at a concentration higher than 10⁻⁹ M to the medium could induce cell death of larval epithelial cells, but T₃ alone was not sufficient for proliferation and differentiation of adult epithelial cells. When insulin (5 μg/ml) and cortisol (0.5 μg/ml) besides T₃ were added, the adult cells proliferated and differentiated just as during spontaneous metamorphosis. On Day 5 of cultivation, the adult cells rapidly proliferated to form typical islets, whereas the larval ones rapidly degenerated. At the same time, the connective tissue beneath the epithelium suddenly increased in cell density. These changes correspond to those occurring at the onset of metamorphic climax. By Day 10, the adult cells differentiated into a simple columnar epithelium which possessed the brush border and showed the adult-type lectin-binding pattern. Therefore, the larval epithelium of the small intestine responded to the hormones and transformed into the adult one. This organ culture system may be useful for clarifying the mechanism of the epithelial transition from larval to adult type during metamorphosis.