Cell to Cell Adhesion Systems in Xenopus laevis, the South African Clawed Frog I. Detection of Ca2+ Dependent and Independent Adhesion Systems in Adult and Embryonic Cells. (cell-cell adhesion/Xenopus laevis embryos/frog cell lines/monoclonal antibody/cadherin)

Towards gene banking amphibian maternal germ lines: short-term incubation, cryoprotectant tolerance and cryopreservation of embryonic cells of the frog, Limnodynastes peronii

Gene banking is arguably the best method available to prevent the loss of genetic diversity caused by declines in wild populations, when the causes of decline cannot be halted or reversed. For one of the most impacted vertebrate groups, the amphibians, gene banking technologies have advanced considerably, and gametes from the male line can be banked successfully for many species. However, cryopreserving the female germ line remains challenging, with attempts at cryopreserving oocytes unsuccessful due to their large size and yolk content. One possible solution is to target cryopreservation of early embryos that contain the maternal germ line, but consist of smaller cells. Here, we investigate the short term incubation, cryoprotectant tolerance, and cryopreservation of dissociated early embryonic cells from gastrulae and neurulae of the Striped Marsh Frog, Limnodynastes peronii. Embryos were dissociated and cells were incubated for up to 24 hours in various media. Viability of both gastrula and neurula cells remained high (means up to 40-60%) over 24 hours of incubation in all media, although viability was maintained at a higher level in Ca(2+)-free Simplified Amphibian Ringer; low speed centrifugation did not reduce cell viability. Tolerance of dissociated embryonic cells was tested for two cryoprotectants, glycerol and dimethyl sulphoxide; dissociated cells of both gastrulae and neurulae were highly tolerant to both-indeed, cell viability over 24 hours was higher in media containing low-to-medium concentrations than in equivalent cryoprotectant-free media. Viability over 24 hours was lower in concentrations of cryoprotectant higher than 10%. Live cells were recovered following cryopreservation of both gastrula and neurula cells, but only at low rates. Optimal cryodiluents were identified for gastrula and neurula cells. This is the first report of a slow cooling protocol for cryopreservation of amphibian embryonic cells, and sets future research directions for cryopreserving amphibian maternal germ lines.

Ca2+ signaling and early embryonic patterning during the Blastula and Gastrula Periods of Zebrafish and Xenopus development

It has been proposed that Ca(2+) signaling, in the form of pulses, waves and steady gradients, may play a crucial role in key pattern forming events during early vertebrate development [L.F. Jaffe, Organization of early development by calcium patterns, BioEssays 21 (1999) 657-667; M.J. Berridge, P. Lipp, M.D. Bootman, The versatility and universality of calcium signaling, Nat. Rev. Mol. Cell Biol. 1 (2000) 11-21; S.E. Webb, A.L. Miller, Calcium signalling during embryonic development, Nat. Rev. Mol. Cell Biol. 4 (2003) 539-551]. With reference to the embryos of zebrafish (Danio rerio) and the frog, Xenopus laevis, we review the Ca(2+) signals reported during the Blastula and Gastrula Periods. This developmental window encompasses the major pattern forming events of epiboly, involution, and convergent extension, which result in the establishment of the basic germ layers and body axes [C.B. Kimmel, W.W. Ballard, S.R. Kimmel, B. Ullmann, T.F. Schilling, Stages of embryonic development of the zebrafish, Dev. Dyn. 203 (1995) 253-310]. Data will be presented to support the suggestion that propagating waves (both long and short range) of Ca(2+) release, followed by sequestration, may play a crucial role in: (1) Coordinating cell movements during these pattern forming events and (2) Contributing to the establishment of the basic embryonic axes, as well as (3) Helping to define the morphological boundaries of specific tissue domains and embryonic structures, including future organ anlagen [E. Gilland, A.L. Miller, E. Karplus, R. Baker, S.E. Webb, Imaging of multicellular large-scale rhythmic calcium waves during zebrafish gastrulation, Proc. Natl. Acad. Sci. USA 96 (1999) 157-161; J.B. Wallingford, A.J. Ewald, R.M. Harland, S.E. Fraser, Calcium signaling during convergent extension in Xenopus, Curr. Biol. 11 (2001) 652-661]. The various potential targets of these Ca(2+) transients will also be discussed, as well as how they might integrate with other known pattern forming pathways known to modulate early developmental events (such as the Wnt/Ca(2+)pathway; [T.A. Westfall, B. Hjertos, D.C. Slusarski, Requirement for intracellular calcium modulation in zebrafish dorsal-ventral patterning, Dev. Biol. 259 (2003) 380-391]).

Cloning and expression studies of cDNA for a novel Xenopus cadherin (XmN-cadherin), expressed maternally and later neural-specifically in embryogenesis

From a Xenopus tailbud cDNA library, we obtained the cDNA for a novel cadherin which was named as XmN-cadherin (Xenopus maternally expressed neural cadherin). The cDNA consisted of 3690 bp and encoded 922 amino acid residues. XmN-cadherin preserved five extracellular cadherin motifs, a single transmembrane domain, and a cytoplasmic domain, and was closely related by its sequence to R- and N-cadherin. In the adult frog, XmN-cadherin mRNA was detected strongly in ovary, testis, brain, eye, and kidney, and weakly in stomach, and intestine. In the egg, the mRNA occurred as a maternal mRNA at a relatively high level, and its level became very low by the neurula stage, then increased steadily thereafter. Dissection experiments with 8-cell stage and neurula stage embryos revealed that the maternally inherited mRNA was relatively uniformly distributed within the embryo. By a sharp contrast, whole mount in situ hybridization revealed that the zygotically expressed mRNA occurred almost exclusively in neural tissues such as brain, the anterior part of spinal cord, and the optic and otic vesicles. Thus, XmN-cadherin appears to have at least triple functions; it probably contributes in early embryos to cell-type non-specific cell adhesion, but in post-neurula embryos may be responsible for the development and/or maintenance of anterior neural tissues, and may be used in adult frog for the development and/or maintenance of neural, endodermal and reproductive organs.

Teratogenesis induced by short- and long-term exposure of Xenopus laevis progeny to lead

Short-term (96-h) tests on Xenopus laevis embryos are advocated for rapid screening of teratogens, as an alternative to the use of mammals. The objective of the present investigation was to determine whether extending the short-term tests beyond 96 h would detect the teratogenicity of chemicals that would otherwise be missed by the short-term tests. Lead teratogenicity was examined in Xenopus, using lead concentrations of 0.02, 0.05, 0.1, 0.5, 1.0, and 3.0 mg/L, which bracket the U.S. Environmental Protection Agency (EPA) maximum allowable concentration of 0.05 mg/L in water. Short-term exposure times were 72 or 96 h, starting on d 1, 2, or 3 postfertilization, while long-term exposure covered d 1 through metamorphosis. Short-term exposure resulted in neural tube defects (when exposure included d 1 and/or d 2) and tail curvatures, but only at the higher lead concentrations (1 and 3 mg/L). Lower lead concentrations produced no malformations upon short-term exposure, and this corresponded with the absence of tissue lead uptake. On the other hand, long-term exposure to lead (> 3 wk) resulted in the delayed appearance of lordoscoliosis at low lead concentrations (0.02-0.1 mg/L). The delayed appearance of lordoscoliosis corresponded roughly with the attainment of stable lead tissue levels, and this malformation persisted after metamorphosis. Thus, short-term observation tests alone may fail to detect the teratogenicity of low concentrations of environmental chemicals, and may result in the setting of inappropriately liberal exposure standards.

Molecular cloning of cDNA for XTCAD-1, a novel Xenopus cadherin, and its expression in adult tissues and embryos of Xenopus laevis

We have isolated from a Xenopus tailbud cDNA library a novel cadherin cDNA, denoted as XTCAD-1, which contained an open reading frame including the entire coding region. XTCAD-1 codes for 714 amino acids (molecular mass: 96 kDa), which include five characteristic extracellular cadherin motifs, a single putative transmembrane domain, and a cytoplasmic domain. In each domain, XTCAD-1 shared extensive homologies with other cadherins, and was related to EP-, E-, and P-cadherins more closely than to N- and M-cadherins. In adult Xenopus, XTCAD-1 mRNA was strongly expressed in intestine/stomach, kidney and skin, which are respectively derived from endoderm, mesoderm, and ectoderm. In Xenopus embryogenesis, expression of XTCAD-1 mRNA was first detected at blastula stage, and the level of the expression increased gradually during gastrula stage, reached a peak at tailbud stage and then decreased slightly at tadpole stage. These results suggest that in Xenopus laevis XTCAD-1 plays an important role in the maintenance of adult tissues that contain epithelial cells abundantly and also in morphogenesis in early embryonic development.

Xenopus cadherins: the maternal pool comprises distinguishable members of the family

Three maternal cadherins have been reported to occur in the pregastrula Xenopus embryo. EP- and XB-cadherin are distinguished by their distinct cDNA sequences. U-cadherin has been characterized by its reaction with a specific monoclonal antibody (mAb 6D5). Thus far, lack of specific probes that discriminate between these molecules has prevented their identification as distinct cadherins. We now demonstrate by means of RNase protection assays that both EP- and XB-cadherin mRNAs are present in oocytes and mature eggs. By use of the Xenopus cadherin proteins expressed in mammalian cell lines, we find that mAb 6D5 crossreacts with XB-cadherin, but not with EP-cadherin. The major fraction of the maternal cadherins does not contain the 6D5 epitope and probably represents EP-cadherin. A minor fraction carries the 6D5 epitope indicative for the XB- and U-type of cadherins. We have termed this fraction XB/U-cadherin. The function of maternal cadherins was examined by in vitro cell adhesion assays. A newly developed antiserum with a broad specificity for various Xenopus cadherins efficiently blocks all calcium dependent cell adhesion in the early embryo. We conclude that the maternal cadherins play a central role in interblastomere adhesion in the early embryo and comprise at least two discrete cadherin forms, EP- and XB/U-cadherin.

Identification of Ca2(+)-dependent cell adhesion molecules in Xenopus by the use of interspecies homology

Ca2(+)-dependent cell adhesion molecules (CAMs) are transmembrane glycoproteins structurally and functionally related in mammalian and avian species. This suggests that Ca2(+)-dependent CAMs consist of an evolutionary conserved gene family. Antibodies or cDNA probes specific either to the extracellular part or the cytoplasmic domain of uvomorulin were compared for their ability to detect corresponding molecules in Xenopus. Only antibodies directed against the evolutionary highly conserved cytoplasmic domain afforded a clear membrane staining on sections of Xenopus embryos or on cultured Xenopus epithelial cells. However, these antibodies recognized different polypeptides of 156, 140 and 128 kDa in immunoblots prepared from cell lysates of epithelial, neural, muscle and embryonic tissues. In concordance with the antibody analysis, signals in Northern hybridizations were only obtained when the cDNA probe encoding the cytoplasmic domain of uvomorulin was used. Here again, this cDNA probe revealed different mRNA species of 4.3, 4.1, 3.8 and 3.2 kb in the studied cell types. These results provide further direct evidence that the Ca2(+)-dependent CAMs are evolutionary conserved. The variety of polypeptides and transcripts observed in Xenopus indicates that several members of this gene family were detected by the use of probes specific to conserved sequences. More important, with this approach we also identified members of this gene family in the early stages of Xenopus development. Since these proteins were present in mature eggs but not in oocytes, we assume a maternal store of Ca2(+)-dependent CAM RNAs whose translation might be initiated during egg maturation.

Immunological evidence for the presence in sea urchin embryos of a cell adhesion protein similar to mouse uvomorulin (E-cadherin)

A tryptic fragment (88 kDa), obtained from external digestion of sea urchin embryos carried out in the presence of calcium, shows immunological cross-reactivity with polyclonal and monoclonal antibodies (DECMA-1) against mouse teratocarcinoma uvomorulin. Fab fragments obtained from anti-mouse terato-carcinoma uvomorulin mono- and polyclonal antibodies, and from polyclonal antibodies against the partially purified 88-kDa tryptic fragment, decompact early sea urchin embryos and block reaggregation of dissociated sea urchin blastula cells. These data indicate the presence of an uvomorulin-like protein in sea urchin embryos and suggest an important role for this protein in embryonic development.

Cell to cell adhesion systems in Xenopus laevis, the South African clawed toad. II: Monoclonal antibody against a novel Ca2+-dependent cell-cell adhesion glycoprotein on amphibian cells

We isolated a mouse monoclonal antibody that disrupts Ca2+-dependent cell-cell adhesion of amphibian (Xenopus laevis) cells. When added to culture medium, the monoclonal antibody completely disrupted cell-cell adhesion of amphibian cells in monolayer culture and specifically inhibited Ca2+-dependent cell-cell adhesion of dissociated cells in reaggregation experiments. The monoclonal antibody recognized a 140 kDa cell surface glycoprotein antigenically different from the previously reported Ca2+-dependent cell-cell adhesion molecules (cadherins).

Factors involved in the formation and stabilization of cell aggregates obtained from amphibian embryonic explants

The effect of factors influencing the formation and stability of animal and vegetal aggregates from Xenopus laevis and Ambystoma mexicanum was examined in the light and scanning electron microscopes. At extreme values of pH the surface coat covering the vegetal aggregates is dissolved and dissociation may take place. Animal aggregates are more resistant. At high tonicities vegetal aggregates may be dissociated, and in the animal aggregates the epidermal differentiation is suppressed. In the absence of Ca2+ the vegetal aggregates are dissociated, but the animal aggregates are not affected. The results obtained with the inhibitor selenate and from incorporation experiments indicate that sulfated glycosaminoglycans are involved in the formation of aggregates in both species. Corresponding observations with tunicamycin suggest that even glycoproteins may play a role in aggregate formation, particularly in the vegetal aggregates.

Studies on cellular adhesion of Xenopus laevis melanophores: modulation of cell-cell and cell-substratum adhesion in vitro by endogenous Xenopus galactoside-binding lectin

We have investigated cell-cell and cell-substratum adhesion of Xenopus laevis neural crest cells at various stages of melanophore differentiation. Single-cell suspensions were obtained by trypsinization and aggregated in a cell-cell adhesion assay. Unpigmented cells did not adhere while the rate of adhesion of melanophores correlated with the degree of melanization. Melanophore cell-cell adhesion decreased significantly in the presence of beta-galactosidase, which suggests that cell-surface galactose is involved. Beta-galactoside-binding lectin has been isolated and purified from embryos at the stage of neural crest migration. When added to aggregating cells smaller, looser clusters formed compared to controls. When lectin was added to cells in stationary culture to test cell-substratum adhesion, melanophores spread more smoothly and formed more regular spacing patterns. These results suggest that this lectin can modulate receptors used in cell-cell and cell-substratum adhesion of melanophores.