Remodeling of insulin producing β-cells during Xenopus laevis metamorphosis

Insulin-producing β-cells are present as single cells or in small clusters distributed throughout the pancreas of the Xenopus laevis tadpole. During metamorphic climax when the exocrine pancreas dedifferentiates to progenitor cells, the β-cells undergo two changes. Insulin mRNA is down regulated at the beginning of metamorphic climax (NF62) and reexpressed again near the end of climax. Secondly, the β-cells aggregate to form islets. During climax the increase in insulin cluster size is not caused by cell proliferation or by acinar-to-β-cell transdifferentiation, but rather is due to the aggregation of pre-existing β-cells. The total number of β-cells does not change during the 8 days of climax. Thyroid hormone (TH) induction of premetamorphic tadpoles causes an increase in islet size while prolonged treatment of tadpoles with the goitrogen methimazole inhibits this increase. Expression of a dominant negative form of the thyroid hormone receptor (TRDN) driven by the elastase promoter not only protects the exocrine pancreas of a transgenic tadpole from TH-induced dedifferentiation but also prevents aggregation of β-cells at climax. These transgenic tadpoles do however undergo normal loss and resynthesis of insulin mRNA at the same stage as controls. In contrast transgenic tadpoles with the same TRDN transgene driven by an insulin promoter do not undergo down regulation of insulin mRNA, but do aggregate β-cells to form islets like controls. These results demonstrate that TH controls the remodeling of β-cells through cell-cell interaction with dedifferentiating acinar cells and a cell autonomous program that temporarily shuts off the insulin gene.     

Gene switching at Xenopus laevis metamorphosis

During the climax of amphibian metamorphosis many tadpole organs remodel. The different remodeling strategies are controlled by thyroid hormone (TH). The liver, skin, and tail fibroblasts shut off tadpole genes and activate frog genes in the same cell without DNA replication. We refer to this as “gene switching”. In contrast, the exocrine pancreas and the intestinal epithelium dedifferentiate to a progenitor state and then redifferentiate to the adult cell type. Tadpole and adult globin are not present in the same cell. Switching from red cells containing tadpole-specific globin to those with frog globin in the liver occurs at a progenitor cell stage of development and is preceded by DNA replication. Red cell switching is the only one of these remodeling strategies that resembles a stem cell mechanism.     

Changing a limb muscle growth program into a resorption program

Transgenic Xenopus laevis tadpoles that express a dominant negative form of the thyroid hormone receptor (TRDN) controlled by the cardiac actin muscle promoter (pCar) develop with very little limb muscle. Under the control of the tetracycline system the transgene can be induced at will by adding doxycycline to the rearing water. Pre-existing limb muscle fibers begins to disintegrate within 2 days after up-regulation of the TRDN transgene. The muscle cells do not die even after weeks of transgene exposure when the myofibrils have degenerated completely and the tadpole is nearing death. A microarray analysis after 2 weeks of exposure to the transgene identified 24 muscle genes whose expression was altered in such a way that they might cause the muscle phenotype. These candidate genes are normally activated in growing limb muscle but they are repressed by the TRDN transgene. Several of these genes have been implicated in mammalian myopathies. However, the expression of only one of these genes, calsequestrin, is down-regulated in 1 day and therefore might initiate the degeneration. Calsequestrin is one of several affected genes that encode proteins involved in calcium sequestration, transport and utilization in muscle suggesting that uncontrolled calcium influx into the growing limb muscle fibers causes rhabdomyolysis. Many of the same genes that are down-regulated in the tail at the peak of metamorphic climax just before it is resorbed are suppressed in the transgenic limb muscle in effect turning the limb growth program into a tail resorption program.     

Expression and regulation of miR-1, -133a, -206a, and MRFs by thyroid hormone during larval development in Paralichthys olivaceus

MiR-1, miR-133a, and miR-206a have been identified as muscle-specific miRNAs. They play multiple crucial roles in the regulation of muscle development. Here, we show that these miRNAs were differentially expressed during the larval development of flounder, and specifically expressed in skeletal muscle and heart in adult tissues/organs. The expression levels of these miRNAs were significantly changed by thyroid hormone (TH) or thiourea (TU) treatment during metamorphosis from 17 dph (days post hatching) to 42 dph. In addition, the expression levels of MyoD and Myf5 mRNAs markedly increased at 14 dph (pre-metamorphosis) compared to metamorphic stages, and their expression levels are far above the myogenin during larval development. Moreover, these MRFs (myogenic regulatory factors) expression were directly or indirectly regulated by thyroid hormone or thiourea during metamorphosis. All the results suggest that miRNAs and MRFs might be involved in signaling pathway of TH or TU-mediated flounder metamorphosis.     

Thyroid hormone alleviates demyelination induced by cuprizone through its role in remyelination during the remission period

Multiple sclerosis (MS) is a disease induced by demyelination in the central nervous system, and the remission period of MS is crucial for remyelination. In addition, abnormal levels of thyroid hormone (TH) have been identified in MS. However, in the clinic, insufficient attention has been paid to the role of TH in the remission period. Indeed, TH not only functions in the development of the brain but also affects myelination. Therefore, it is necessary to observe the effect of TH on remyelination during this period. A model of demyelination induced by cuprizone (CPZ) was used to observe the function of TH in remyelination during the remission period of MS. Through weighing and behavioral tests, we found that TH improved the physical symptoms of mice impaired by CPZ. Supplementation of TH led to the repair of myelin as detected by immunohistochemistry and western blot. In addition, a sufficient TH supply resulted in an increase in myelinated axons without affecting myelin thickness and g ratio in the corpus callosum, as detected by electron microscopy. Double immunostaining with myelin basic protein and neurofilament 200 (NF200) showed that the CPZ-induced impairment of axons was alleviated by TH. Conversely, insufficient TH induced by 6-propyl-2-thiouracil resulted in the enlargement of mitochondria. Furthermore, we found that an adequate supply of TH promoted the proliferation and differentiation of oligodendrocyte lineage cells by immunofluorescence, which was beneficial to remyelination. Further, we found that TH reduced the number of astrocytes without affecting microglia. Conclusively, it was shown that TH alleviated demyelination induced by CPZ by promoting the development of oligodendrocyte lineage cells and remyelination. The critical time for remyelination is the remission period of MS. TH plays a significant role in alleviating demyelination during the remission period in the clinical treatment of MS.     

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.     

Cells Derived from the Coelomic Epithelium Contribute to Multiple Gastrointestinal Tissues in Mouse Embryos

Gut mesodermal tissues originate from the splanchnopleural mesenchyme. However, the embryonic gastrointestinal coelomic epithelium gives rise to mesenchymal cells, whose significance and fate are little known. Our aim was to investigate the contribution of coelomic epithelium-derived cells to the intestinal development. We have used the transgenic mouse model mWt1/IRES/GFP-Cre (Wt1^cre) crossed with the Rosa26R-EYFP reporter mouse. In the gastrointestinal duct Wt1, the Wilms’ tumor suppressor gene, is specific and dynamically expressed in the coelomic epithelium. In the embryos obtained from the crossbreeding, the Wt1-expressing cell lineage produces the yellow fluorescent protein (YFP) allowing for colocalization with differentiation markers through confocal microscopy and flow cytometry. Wt1^cre-YFP cells were very abundant throughout the intestine during midgestation, declining in neonates. Wt1^cre-YFP cells were also transiently observed within the mucosa, being apparently released into the intestinal lumen. YFP was detected in cells contributing to intestinal vascularization (endothelium, pericytes and smooth muscle), visceral musculature (circular, longitudinal and submucosal) as well as in Cajal and Cajal-like interstitial cells. Wt1^cre-YFP mesenchymal cells expressed FGF9, a critical growth factor for intestinal development, as well as PDGFRα, mainly within developing villi. Thus, a cell population derived from the coelomic epithelium incorporates to the gut mesenchyme and contribute to a variety of intestinal tissues, probably playing also a signaling role. Our results support the origin of interstitial cells of Cajal and visceral circular muscle from a common progenitor expressing anoctamin-1 and SMCα-actin. Coelomic-derived cells contribute to the differentiation of at least a part of the interstitial cells of Cajal.     

Fetal endoderm primarily holds the temporal and positional information required for mammalian intestinal development

In rodents, the intestinal tract progressively acquires a functional regionalization during postnatal development. Using lactase-phlorizin hydrolase as a marker, we have analyzed in a xenograft model the ontogenic potencies of fetal rat intestinal segments taken prior to endoderm cytodifferentiation. Segments from the presumptive proximal jejunum and distal ileum grafted in nude mice developed correct spatial and temporal patterns of lactase protein and mRNA expression, which reproduced the normal pre- and post-weaning conditions. Segments from the fetal colon showed a faint lactase immunostaining 8-10 d after transplantation in chick embryos but not in mice; it is consistent with the transient expression of this enzyme in the colon of rat neonates. Heterotopic cross-associations comprising endoderm and mesenchyme from the presumptive proximal jejunum and distal ileum developed as xenografts in nude mice, and they exhibited lactase mRNA and protein expression patterns that were typical of the origin of the endodermal moiety. Endoderm from the distal ileum also expressed a normal lactase pattern when it was associated to fetal skin fibroblasts, while the fibroblasts differentiated into muscle layers containing alpha-smooth- muscle actin. Noteworthy, associations comprising colon endoderm and small intestinal mesenchyme showed a typical small intestinal morphology and expressed the digestive enzyme sucrase-isomaltase normally absent in the colon. However, in heterologous associations comprising lung or stomach endoderm and small intestinal mesenchyme, the epithelial compartment expressed markers in accordance to their tissue of origin but neither intestinal lactase nor sucrase-isomaltase. A thick intestinal muscle coat in which cells expressed alpha-smooth- muscle actin surrounded the grafts. The results demonstrate that: (a) the temporal and positional information needed for intestinal ontogeny up to the post-weaning stage results from an intrinsic program that is fixed in mammalian fetuses prior to endoderm cytodifferentiation; (b) this temporal and positional information is primarily carried by the endodermal moiety which is also able to change the fate of heterologous mesodermal cells to form intestinal mesenchyme; and (c) the small intestinal mesenchyme in turn may deliver instructive information as shown in association with colonic endoderm; yet this effect is not obvious with nonintestinal endoderms.     

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.     

Cell-cell and cell-ECM interactions in epithelial apoptosis and cell renewal during frog intestinal development

Amphibian intestinal remodeling during metamorphosis is a developmental system that is entirely controlled by thyroid hormone. It transforms a simple tubular organ into a complex multiply folded frog intestine similar to that in higher vertebrates. This process involves the degeneration of the larval epithelium through programmed cell death (apoptosis) and concurrent proliferation and differentiation of adult cell types. Earlier morphological and cellular studies have provided strong evidence implicating the importance of cell-cell and cell-ECM (extracellular matrix) interactions in this process. The recent molecular characterization of the genes that are regulated by thyroid hormone has begun to reveal some molecular clues underlying such interactions. In particular, theXenopus putative morphogen hedgehog appears to be involved in regulating/mediating cell-cell interactions during adult epithelial proliferation, differentiation, and/or intestinal morphogenesis. On the other hand, several matrix metalloproteinases (MMPs) may be involved in remodeling the ECM. Of special interest is stromelysin-3, whose spatial and temporal expression profile during intestinal metamorphosis implicates a role in ECM remodeling, which in turn facilitates cell fate determination, i.e., apoptosis vs proliferation and differentiation. Understanding the mechanisms of action for those extracellular molecules will present a future challenge in developmental research.     

Thyroidal regulation of different isoforms of NaKATPase in the primary cultures of neurons derived from fetal rat brain

The developmental profile of the different isoforms of NaKATPase have been investigated using primary cultures of isolated neurons initiated from 17 day old fetal rat brain. Northern blot analysis showed that the expression of three alpha isoforms (alpha(1), alpha(2) and alpha(3)) and two beta isoforms (beta(1) and beta(2)) increased progressively and reached a peak between 12 to 16 days of culture. Comparison of the mRNA levels of these isoforms in the cells maintained in thyroid hormone deficient (TH def) and thyroid hormone supplemented (TH sup) media for 6-12 days, revealed for the first time that in the neurons three alpha and two beta isoforms of NaKATPase are sensitive to TH. Furthermore immunocytochemical staining of these cells with isoform specific NaKATPase antibodies showed that the uniform distribution of alpha(2), alpha(3) and beta(2) isoforms in the neuronal processes require the presence of TH. These results establish neurons as the target cells for the regulation of NaKATPase by TH in the developing brain.     

Smooth muscle actin expression during rat gut development and induction in fetal skin fibroblastic cells associated with intestinal embryonic epithelium

Abstract. Cytodifferentiation of smooth muscle cells has been analyzed immunocytochemically during rat intestinal development and in chimaeric intestines by using monoclonal antibodies reacting specifically with smooth muscle actin species ( CGA7 [10] and anti-α SM-1 [40]). As development proceeds, the various intestinal muscle layers differentiate in the following order: (1) cells expressing smooth muscle actin appear within the mesenchyme of the 15-day fetal rat intestine, in the circular muscle-forming area, the differentiation of cells in the presumptive longitudinal muscle layer starting with a 48-h delay; (2) smooth muscle fibers appear within the connective tissue core of the villi shortly after birth, in parallel with a progressive formation of the muscularis mucosae, which becomes clear-cut only in the course of the 2nd week after birth; (3) a distinct cell layer in the innermost part of the circular muscle layer arises during the perinatal period. Thereafter, the fluorescence pattern remains unchanged until the adult stage. Chimaeric intestines were constructed by the association of 14-day fetal intestinal epithelium and cultured fetal rat or human skin fibroblasts. These fibroblastic cells did not express actin at the time at which they were associated. The immunocytochemical analysis of smooth muscle actin in the hybrid intestines, which had developed as intracoelomic grafts for 12 days, revealed that the skin fibroblastic cells had been induced by the intestinal epithelial cells to differentiate into smooth muscle cells. Such a result was also obtained with allantoic endoderm. It was not obvious in cocultures of intestinal epithelium with skin fibroblastic cells. However, when intestinal epithelial cells were cocultured with intestinal mesenchymal cells, actin expression was stimulated in the latter cell population.