HOXA13 regulates Aldh1a2 expression in the autopod to facilitate interdigital programmed cell death.

BACKGROUND: Retinoic acid (RA), plays an essential role in the growth and patterning of vertebrate limb. While the developmental processes regulated by RA are well understood, little is known about the transcriptional mechanisms required to precisely control limb RA synthesis. Here, Aldh1a2 functions as the primary enzyme necessary for RA production which regulates forelimb outgrowth and hindlimb digit separation. Because mice lacking HOXA13 exhibit similar defects in digit separation as Aldh1a2 mutants, we hypothesized that HOXA13 regulates Aldh1a2 to facilitate RA-mediated interdigital programmed cell death (IPCD) and digit separation. RESULTS: In this report, we identify Aldh1a2 as a direct target of HOXA13. In absence of HOXA13 function, Aldh1a2 expression, RA signaling, and IPCD are reduced. In the limb, HOXA13 binds a conserved cis-regulatory element in the Aldh1a2 locus that can be regulated by HOXA13 to promote gene expression. Finally, decreased RA signaling and IPCD can be partially rescued in the Hoxa13 mutant hindlimb by maternal RA supplementation. CONCLUSIONS: Defects in IPCD and digit separation in Hoxa13 mutant mice may be caused in part by reduced levels of RA signaling stemming from a loss in the direct regulation of Aldh1a2. These findings provide new insights into the transcriptional regulation of RA signaling necessary for limb morphogenesis.

Retinoic acid signaling regulates embryonic clock hairy2 gene expression in the developing chick limb.

Embryo development proceeds under strict temporal control and an embryonic molecular clock (EC), evidenced by cyclic gene expression, is operating during somite formation and limb development, providing temporal information to precursor cells. In somite precursor cells, EC gene expression and periodicity depends on Retinoic acid (RA) signaling and this morphogen is also essential for limb initiation, outgrowth and patterning. Since the limb EC gene hairy2 is differentially expressed along the proximal-distal axis as growth proceeds, concomitant with changes in flank-derived RA activity in the mesenchyme, we have interrogated the role of RA signaling on limb hairy2 expression regulation. We describe RA as a positive regulator of limb hairy2 expression. Ectopic supplementation of RA induced hairy2 in a short time period, with simultaneous transient activation of Erk/MAPK, Akt/PI3K and Gli3 intracellular pathways. We further found that FGF8, an inducer of Erk/MAPK, Akt/PI3K pathways, was not sufficient for ectopic hairy2 induction. However, joint treatment with both RA and FGF8 induced hairy2, indicating that RA is creating a permissive condition for p-Erk/p-Akt action on hairy2, most likely by enhancing Gli3-A/Gli3-R levels. Finally, we observed an inhibitory action of BMP4 on hairy2 and propose a model whereby RA shapes limb hairy2 expression during limb development, by activating its expression and counteracting the inhibitory action of BMP4 on hairy2. Overall, our work reports a novel role for RA in the regulation of limb clock hairy2 gene expression and elucidates the temporal response of multiple intracellular pathways to RA signaling in limb development.

Visualization of retinoic acid signaling in transgenic axolotls during limb development and regeneration.

Retinoic acid (RA) plays a necessary role in limb development and regeneration, but the precise mechanism by which it acts during these processes is unclear. The role of RA in limb regeneration was first highlighted by the remarkable effect that it has on respecifying the proximodistal axis of the regenerating limb so that serially repeated limbs are produced. To facilitate the study of RA signaling during development and then during regeneration of the same structure we have turned to the axolotl, the master of vertebrate regeneration, and generated transgenic animals that fluorescently report RA signaling in vivo. Characterization of these animals identified an anterior segment of the developing embryo where RA signaling occurs revealing conserved features of the early vertebrate embryo. During limb development RA signaling was present in the developing forelimb bud mesenchyme, but was not detected during hindlimb development. During limb regeneration, RA signaling was surprisingly almost exclusively observed in the apical epithelium suggesting a different role of RA during limb regeneration. After the addition of supplemental RA to regenerating limbs that leads to pattern duplications, the fibroblast stem cells of the blastema responded showing that they are capable of transcriptionally responding to RA. These findings are significant because it means that RA signaling may play a multifunctional role during forelimb development and regeneration and that the fibroblast stem cells that regulate proximodistal limb patterning during regeneration are targets of RA signaling.

Exposure to green tea extract alters the incidence of specific cyclophosphamide-induced malformations.

BACKGROUND: Green tea extract (GTE) has been shown to have antioxidative properties due to its high content of polyphenols and catechin gallates. Previous studies indicated that catechin gallates scavenge free radicals and attenuate the effects of reactive oxygen species. Cyclophosphamide (CP) produces reactive oxidative species, which can have adverse effects on development, causing limb, digit, and cranial abnormalities. The current study was performed to determine if exposure to GTE can decrease teratogenic effects induced by CP in CD-1 mice. METHODS: From gestation days (GD) 6-13, mated CD-1 mice were dosed with 400 or 800 mg/kg/d GTE; 100, 200, 400, or 800 mg/kg/d GTE + CP; CP alone, or the vehicle. GTE was given by gavage. CP (20 mg/kg) was given by intraperitoneal injection on GD 10. Dams were sacrificed on GD 17, and their litters were examined for adverse effects. RESULTS: The highest GTE dose did not effectively attenuate, and in some cases exacerbated the negative effect of CP. GTE alone was also associated with an increased incidence of microblepharia. Conversely, moderate GTE doses (200 and/or 400 mg/kg/d) attenuated the effect of CP on fetal weight and (GTE 200 mg/kg/d) decreased the incidences of certain defects resulting from CP exposure. CONCLUSIONS: Exposure of a developing mammal to moderate doses of GTE can modulate the effects of exposure to CP during development, possibly by affecting biotransformation, while a higher GTE dose tended to exacerbate the developmental toxicity of CP. GTE alone appeared to cause an adverse effect on eyelid development.

Myogenesis in the thoracic limbs of the American lobster.

Newly hatched lobster larvae have biramous thoracic limbs composed of an endopodite, which is used for walking in the adult, and an exopodite used for swimming. Several behavioural and physiological aspects of larval locomotion as well the ontogeny of the neuromuscular system have been examined in developing decapod crustaceans. Nevertheless, the cellular basis of embryonic muscle formation in these animals is poorly understood. Therefore, the present report analyses muscle formation in embryos of the American lobster Homarus americanus Milne Edwards, 1837 (Malacostraca, Eucarida, Decapoda, Homarida) using the monoclonal antibody 016C6 that recognizes an isoform of myosin heavy chain. 016C6 labelling at 25% of embryonic development (E25%) revealed that syncytial muscle precursor cells establish the muscles in the endopodites. During subsequent embryogenesis, these muscle precursors subdivide into several distinct units thereby giving rise to pairs of antagonistic primordial muscles in each of the successive podomeres, the layout of which at E45% already resembles the arrangement in the adult thoracopods. The pattern of primordial muscles was also mapped in the exopodites of thoracic limbs three to eight. Immunohistochemistry against acetylated α-tubulin and against presynaptic vesicle-associated phosphoproteins at E45% demonstrated the existence of characteristic neural tracts within the developing limbs as well as putative neuromuscular synapses in both the embryonic exo- and endopodites. The results are compared to muscle development in other Crustacea.

[Effects of extracts from Patrinia heterophylla on gene expression patterns during morphogenesis of chicken limb buds in vivo].

OBJECTIVE: To study the effects of the extracts from Patrinia heterophylla on gene expression patterns during morphogenesis of chicken limb buds in vivo. METHODS: Implanted a bead into an chicken embryo, which was soaked in the extracts from Patrinia heterophylla. Detected the extracts-induced morphogenesis changes (Myf5, Myod and PCNA). RESULTS: The extracts from Patrinia heterophylla (200 mg/mL) could affect limb bud development, reduce gene expression of MyfS, MyoD and PCNA. CONCLUSION: The extracts from Patrinia heterophylla can inhibit cell differentiation and proliferation.

The T-box transcription factor Tbx15 is required for skeletal development.

During early limb development several signaling centers coordinate limb bud outgrowth as well as patterning. Members of the T-box gene family of transcriptional regulators are crucial players in these processes by activating and interpreting these signaling pathways. Here, we show that Tbx15, a member of this gene family, is expressed during limb development, first in the mesenchyme of the early limb bud, then during early endochondral bone development in prehypertrophic chondrocytes of cartilaginous templates. Expression is also found in mesenchymal precursor cells and prehypertrophic chondrocytes, respectively, during development of skeletal elements of the vertebral column and the head. Analysis of Tbx15 null mutant mice indicates a role of Tbx15 in the development of skeletal elements throughout the body. Mutants display a general reduction of bone size and changes of bone shape. In the forelimb skeleton, the scapula lacks the central region of the blade. Cartilaginous templates are already reduced in size and show a transient delay in ossification in mutant embryos. Mutants show a significantly reduced proliferation of prehypertrophic chondrocytes as well as of mesenchymal precursor cells. These data suggest that Tbx15 plays an important role in the development of the skeleton of the limb, vertebral column and head by controlling the number of mesenchymal precursor cells and chondrocytes.

The Polycomb Ezh2 methyltransferase regulates muscle gene expression and skeletal muscle differentiation.

The Ezh2 protein endows the Polycomb PRC2 and PRC3 complexes with histone lysine methyltransferase (HKMT) activity that is associated with transcriptional repression. We report that Ezh2 expression was developmentally regulated in the myotome compartment of mouse somites and that its down-regulation coincided with activation of muscle gene expression and differentiation of satellite-cell-derived myoblasts. Increased Ezh2 expression inhibited muscle differentiation, and this property was conferred by its SET domain, required for the HKMT activity. In undifferentiated myoblasts, endogenous Ezh2 was associated with the transcriptional regulator YY1. Both Ezh2 and YY1 were detected, with the deacetylase HDAC1, at genomic regions of silent muscle-specific genes. Their presence correlated with methylation of K27 of histone H3. YY1 was required for Ezh2 binding because RNA interference of YY1 abrogated chromatin recruitment of Ezh2 and prevented H3-K27 methylation. Upon gene activation, Ezh2, HDAC1, and YY1 dissociated from muscle loci, H3-K27 became hypomethylated and MyoD and SRF were recruited to the chromatin. These findings suggest the existence of a two-step activation mechanism whereby removal of H3-K27 methylation, conferred by an active Ezh2-containing protein complex, followed by recruitment of positive transcriptional regulators at discrete genomic loci are required to promote muscle gene expression and cell differentiation.

Sp8 and Sp9, two closely related buttonhead-like transcription factors, regulate Fgf8 expression and limb outgrowth in vertebrate embryos.

Initiation and maintenance of signaling centers is a key issue during embryonic development. The apical ectodermal ridge, a specialized epithelial structure and source of Fgf8, is a pivotal signaling center for limb outgrowth. We show that two closely related buttonhead-like zinc-finger transcription factors, Sp8 and Sp9, are expressed in the AER, and regulate Fgf8 expression and limb outgrowth. Embryological and genetic analyses have revealed that Sp8 and Sp9 are ectodermal targets of Fgf10 signaling from the mesenchyme. We also found that Wnt/beta-catenin signaling positively regulates Sp8, but not Sp9. Overexpression functional analyses in chick unveiled their role as positive regulators of Fgf8 expression. Moreover, a dominant-negative approach in chick and knockdown analysis with morpholinos in zebrafish revealed their requirement for Fgf8 expression and limb outgrowth, and further indicate that they have a coordinated action on Fgf8 expression. Our study demonstrates that Sp8 and Sp9, via Fgf8, are involved in mediating the actions of Fgf10 and Wnt/beta-catenin signaling during vertebrate limb outgrowth.

Dynamic changes in the response of cells to positive hedgehog signaling during mouse limb patterning.

In the vertebrate limb, the posteriorly located zone of polarizing activity (ZPA) regulates digit identity through the morphogen Sonic Hedgehog (Shh). By genetically marking Shh-responding cells in mice, we have addressed whether the cumulative influence of positive Shh signaling over time and space reflects a linear gradient of Shh responsiveness and whether Shh could play additional roles in limb patterning. Our results show that all posterior limb mesenchyme cells, as well as the ectoderm, respond to Shh from the ZPA and become the bone, muscle, and skin of the posterior limb. Further, the readout of Shh activator function integrated over time and space does not display a stable and linear gradient along the A-P axis, as in a classical morphogen view. Finally, by fate mapping Shh-responding cells in Gli2 and Gli3 mutant limbs, we demonstrate that a specific level of positive Hh signaling is not required to specify digit identities.

Effects of zinc on bone development in mouse embryo in vitro.

OBJECTIVE: This study was designed to explore the effects of zinc on bone development. METHODS: Forelimbs of mice with 16 d gestation were cultured by a rotating device. RESULTS: Contents of OC and (45)Ca and activities of AKP in the bone tissues cultured at zinc-deficiency media and at media with 120 micro mol/L of Zn(2+) decreased significantly. Synthesis of OC, absorption of calcium and activities of AKP in the bone tissues cultures at media with 45 and 70 micro mol/L of Zn(2+) increased significantly. Radiograph of bone tissues showed that length of long bone cultured at zinc-deficiency media and at media with 120 micro mol/L of Zn(2+) shortened and their density reduced, and those cultured at media with 45 and 70 micro mol/L of zinc increased, as compared with self-control bone. Histological analysis showed the death of bone cells and loss of stroma in the bone tissues cultured at media with 120 micro mol/L of Zn(2+), and active proliferation and differentiation of bone cells, and secretion and synthesis of osteoid increased in the bone tissues cultured at media with 45 and 70 micro mol/L of zinc. CONCLUSIONS: Adequate supplementation of zinc could promote formation and development of bone tissues and deficiency or excess of zinc could alter their growth and development and normal metabolism.

YY1 activates Msx2 gene independent of bone morphogenetic protein signaling.

Msx2 is a homeobox gene expressed in multiple embryonic tissues which functions as a key mediator of numerous developmental processes. YY1 is a bi-functional zinc finger protein that serves as a repressor or activator to a variety of promoters. The role of YY1 during embryogenesis remains unknown. In this study, we report that Msx2 is regulated by YY1 through protein-DNA interactions. During embryogenesis, the expression pattern of YY1 was observed to overlap in part with that of Msx2. Most notably, during first branchial arch and limb development, both YY1 and Msx2 were highly expressed, and their patterns were complementary. To test the hypothesis that YY1 regulates Msx2 gene expression, P19 embryonal cells were used in a number of expression and binding assays. We discovered that, in these cells, YY1 activated endogenous Msx2 gene expression as well as Msx2 promoter-luciferase fusion gene activity. These biological activities were dependent on both the DNA binding and activation domains of YY1. In addition, YY1 bound specifically to three YY1 binding sites on the proximal promoter of Msx2 that accounted for this transactivation. Mutations introduced to these sites reduced the level of YY1 transactivation. As bone morphogenetic protein type 4 (BMP4) regulates Msx2 expression in embryonic tissues and in P19 cells, we further tested whether YY1 is the mediator of this BMP4 activity. BMP4 did not induce the expression of YY1 in early mouse mandibular explants, nor in P19 cells, suggesting that YY1 is not a required mediator of the BMP4 pathway in these tissues at this developmental stage. Taken together, these findings suggest that YY1 functions as an activator for the Msx2 gene, and that this regulation, which is independent of the BMP4 pathway, may be required during early mouse craniofacial and limb morphogenesis.

Developmental expression of chick twist and its regulation during limb patterning.

We have isolated a chick Twist gene (cTwist) and examined its expression pattern during development by whole mount in situ hybridization. In early embryos, cTwist transcripts are found in the developing somites, lateral plate mesoderm, limb mesenchyme, branchial arches and head mesenchyme. At later stages, cTwist expression is found in the sclerotome and dermatome, limb bud mesenchyme, interdigital regions, and distal mesenchyme of the maxillary and mandibular processes. In the developing feathers, cTwist is expressed in the mesenchyme of the buds and becomes restricted to the proximal region of the feather filaments. Additionally, we report that the expression of cTwistin the limb mesenchyme is regulated by the AER, FGFs, RA and SHH. The FGFs secreted by the AER seem to have a critical role in maintaining cTwist expression. SHH is also able to maintain cTwist expression but only in the presence of the AER. Overall, our results provide new evidence that reinforce the existence of an interplay between the cTwist and FGF signalling pathways.

Expression of the receptor tyrosine kinase gene EphB3 during early stages of chick embryo development.

The expression pattern of the receptor tyrosine kinase gene EphB3 was examined during the early stages of chick embryogenesis, and is described in this report. In the gastrula, EphB3 is expressed in epiblast cells adjacent to and entering the anterior portion of the primitive streak; expression is extinguished once cells have ingressed. At headfold stages, EphB3 is strongly transcribed in the floor of the foregut and in anterior lateral endoderm, and is expressed in the subjacent cardiogenic mesoderm. EphB3 is transiently expressed in the lateral ectoderm, neural tube, and neural crest during these stages. Later neural expression is localized to the mesencephalon. In the somitic mesoderm, EphB3 is initially expressed in the sclerotome, but later is expressed predominantly in the dermatome. Prominent expression is also detected in the developing heart, liver, posterior ventral limb bud mesenchyme, pharyngeal arches, and head mesenchyme.

The role of Alx-4 in the establishment of anteroposterior polarity during vertebrate limb development.

We have determined that Strong's Luxoid (lstJ) [corrected] mice have a 16 bp deletion in the homeobox region of the Alx-4 gene. This deletion, which leads to a frame shift and a truncation of the Alx-4 protein, could cause the polydactyly phenotype observed in lstJ [corrected] mice. We have cloned the chick homologue of Alx-4 and investigated its expression during limb outgrowth. Chick Alx-4 displays an expression pattern complementary to that of shh, a mediator of polarizing activity in the limb bud. Local application of Sonic hedgehog (Shh) and Fibroblast Growth Factor (FGF), in addition to ectodermal apical ridge removal experiments suggest the existence of a negative feedback loop between Alx-4 and Shh during limb outgrowth. Analysis of polydactylous mutants indicate that the interaction between Alx-4 and Shh is independent of Gli3, a negative regulator of Shh in the limb. Our data suggest the existence of a negative feedback loop between Alx-4 and Shh during vertebrate limb outgrowth.

Hedgehog family member is expressed throughout regenerating and developing limbs.

Members of the hedgehog family have been shown to play a key role in many developmental processes, including limb patterning and chondrogenesis. We have therefore investigated whether members of this family are also expressed during regeneration of the adult urodele limb and are regulated by retinoic acid (RA), since this derivative induces proximodistal duplications in regenerating limbs, and has been shown to regulate sonic hedgehog (shh) in the developing limbs of birds and mammals. We report here that a newt homologue of Xenopus banded hedgehog, called N-bhh, is uniformly expressed by mesenchymal blastemal cells from the initial stages of regeneration and is up-regulated by RA. In addition, we show that N-bhh is uniformly expressed in the early limb bud of the newt embryo. Since bhh has not been detected in developing limbs of higher vertebrates, its expression in developing and regenerating newt limbs may be related to the regenerative capability of urodeles.

p260/270 expressed in embryonic abdominal leg cells of Bombyx mori can transfer palmitate to peptides.

During the study on the mechanisms of abdominal leg development in the silkworm Bombyx mori, we found that a high molecular mass protein (p260/270) was expressed specifically in abdominal leg cells during early embryonic stages and disappeared by a late embryonic stage. p260/270 consists of two polypeptides with molecular masses of 260 and 270 kDa. We have established a purification procedure for p260/270 and have raised an antibody against p260/270. Immunoblot analysis of the ECa/ECa (additional crescent) and EN/EN (new additional crescent) mutants, which lack the Bombyx abdominal-A gene and therefore do not express abdominal legs, demonstrated that the two mutants lacked p260/270. Therefore, we speculate that the expression of p260/270 may be regulated by the Bombyx abdominal-A gene. cDNA cloning and sequencing demonstrated that p260 and p270 have structures similar to that of rat fatty-acid synthase, which synthesizes palmitate. Most of the enzymatic domains for palmitate synthesis were well conserved in the amino acid sequences of p260 and p270, while the thioesterase domains of p260 and p270 were less homologous to that of rat fatty-acid synthase. Purified p260/270 can transfer palmitate to cysteine residues of synthetic peptides in vitro. We propose that p260/270 may be involved in protein palmitoylation and may function in abdominal leg development.

The receptor tyrosine kinase, Cek8, is transiently expressed on subtypes of motoneurons in the spinal cord during development.

Receptor tyrosine kinases (RTKs) play important roles in cellular proliferation, differentiation, and survival. We performed reverse transcriptase-polymerase chain reactions (RT-PCR) from enriched embryonic day 5 (E5) chick motoneurons by panning to identify RTKs involved in the early development of motoneuron. In situ hybridization revealed that Cek8, a member of the eph family, was specifically expressed on motoneurons at the brachial and lumbar segments of the spinal cord which innervate limb muscles, and disappeared after the naturally occurring cell death period (E6-E11). Immunohistochemistry using an anti-Cek8 monoclonal antibody showed the localization of Cek8 protein at the cell bodies and axonal fibers of motoneurons and muscles. The unique expression of Cek8 suggests its involvement in cellular survival or cell-cell interactions for specific subpopulations of developing motoneurons.

Differential effects of retinoic acid and a retinoid antagonist on the spatial distribution of the homeoprotein Hoxb-7 in vertebrate embryos.

An antibody raised against the recombinant Xenopus laevis Hoxb-7 protein (López and Carrasco [1992] Mech. Dev. 36:153-164) recognizes the 30 kDa translation product of the Hoxb-7 gene in X. laevis and the cognate nuclear protein in chicken embryos. The X. laevis Hoxb-7 protein was expressed maternally and zygotically. Treatment of X. laevis and chicken embryos with either all-trans retinoic acid (RA) or the retinoid antagonist Ro 41-5253 (Ro; Apfel et al. [1992] Proc. Natl. Acad. Sci. U.S.A. 89:7129-7133) during early development induced malformations of the neural tube and complementary changes in the expression domain of the homeoprotein Hoxb-7. Treatment of X. laevis embryos with retinoic acid during gastrulation induced an anterior shift of the Hoxb-7 expression domain and was correlated with an enlargement of rhombomere r7. In addition to a reduction in rhombomere numbers and of forebrain size, various malformations involving all three germ layers were observed. Treatment of X. laevis embryos with the antagonist Ro before or during gastrulation caused a progressive reduction of the Hoxb-7 domain and also dose-dependent malformations of all three germ layers. RA or Ro treatment of chicken embryos from the beginning of gastrulation caused changes of the Hoxb-7 expression domain very similar to those observed in X. laevis. In particular, either a dose-dependent loss of the Hoxb-7 protein in the neural tube or an ectopic expression in the forebrain region was observed. The results of this study indicate that endogenous retinoids regulate the spatial expression of homeobox-containing genes in vertebrates.