Nerve-independent DNA synthesis and mitosis in regenerating hindlimbs of larval Xenopus laevis

Summary Xenopus laevis larvae at stage 52–53 (according to Nieuwkoop and Faber 1956) were subjected to amputation of both limbs at the thigh level as well as to repeated denervations of the right limb. Results obtained in larvae sacrificed during wound healing (1 after amputation), blastema formation (3 days) and blastema growth (5 and 7 days) showed that denervated right limbs have undergone the same histological modifications observed in innervated left limbs and have formed a regeneration blastema consisting of mesenchymal cells with a pattern of DNA synthesis and mitosis very similar to that in presence of nerves. Also, the patterns of cellular density in regenerating right and left limbs were very similar. On the whole, the data here reported show a highly remarkable degree of nerve-independence for regeneration in hindlimbs of larval Xenopus laevis at stage 52–53 and lend some substance to the hypothesis that, in early limbs, there would exist trophic factors capable of replacing those released by nerves, promoting DNA synthesis and mitosis in blastemal cells.Offprint requests to: S. Filoni     

Functional anatomy of the photoreceptor and second-order cell mosaics in the retina of Xenopus laevis

Mosaics of photoreceptors, and horizontal and bipolar cells of the Xenopus laevis retina were studied in whole-mount preparations applying lectin-cytochemical, immunocytochemical and intracellular labeling techniques. The combined density of all photoreceptor types was about 13700/mm2, of which rods represented 53%. Of the cones, the large long-wavelength-sensitive (86% of all cones) and the miniature ultraviolet-wavelength-sensitive (4%) ones could be labeled with peanut agglutinin, whereas the large short-wavelength-sensitive (10%) cones remained unlabeled. There were no significant regional differences in photoreceptor distribution. Bipolar cells were selectively labeled with antibodies against calretinin. Their density was between 4000 and 6000 cells/cm2, with slightly elevated numbers in the superior nasal quadrant. Two types of horizontal cell were injected intracellularly. The luminosity-type cells were more frequent (approximately 1000 cells/mm2) than the chromaticity cells (approximately 450 cells/mm2). The dendritic field size of the latter cell type was threefold bigger than that of the luminosity cells. The coverage factors were estimated to be 3.3 for the luminosity cells and 5.2 for the chromaticity cells. The luminosity cells contacted all photoreceptor types, whereas chromatic horizontal cells received their inputs from the short-wavelength-sensitive cones and from some, but not all, rods. Luminosity cells encounter about 50-60 potential synaptic partners within their dendritic fields, whereas chromatic horizontal cells only about 20. Chromatic horizontal cells form multiple synaptic contacts with the short-wavelength-sensitive cones. The results indicate that the overall photoreceptor to bipolar and bipolar to ganglion cell convergence in Xenopus retina is similar to that in the central retinal specialized regions of mammals, predicting comparable spatial resolutions.     

Differential expression of two cadherins in Xenopus laevis

Using a cadherin fraction from Xenopus tissue culture cells as an immunogen, two monoclonal antibodies were obtained that allowed the characterization of two distinct cadherins in the Xenopus embryo. The two cadherins differ in molecular weight, in their time of appearance during development and in their spatial pattern of expression. One of the antigens was identified as E-cadherin. It appears in the embryonic ectoderm during gastrulation when epidermal differentiation commences and it disappears from the neural plate area upon neural induction. The second antigen could not be allocated to any of the known cadherin subtypes and was termed U-cadherin. It is present in the egg and becomes deposited in newly formed inner cell membranes during cleavage, the outer apical membranes of the embryo remaining devoid of the cadherin throughout development. U-cadherin is found on membranes of all cells up to the late neurula stages. A conspicuous polarized expression of the antigen on the membranes of individual inner cells suggests its participation in the segregation of cell layers and organ anlagen. These findings are discussed in the context of current hypotheses on the role of cadherins in establishing the spatial structure of the embryo.     

Comparative actions of GABA and acetylcholine on the Xenopus laevis lateral line

The effects of GABA, acetylcholine and carbachol on the spontaneous activity of afferent nerve fibers in the lateral line of Xenopus laevis are characterized. Atropine and bicuculline were also tested on drug- and water motion-evoked activity. GABA (0.019-1.25 mM) suppressed and both acetylcholine (1.25-80 microM) and carbachol (1.25-40 microM) increased spontaneous activity. These actions were blocked by bicuculline (100 microM) and atropine (4 microM) respectively. Atropine (20 microM) and bicuculline (100 microM) had no effect on water motion-evoked activity. The results characterize actions of GABA and acetylcholine not previously described and provide evidence that does not support the hypothesis that GABA or acetylcholine are the afferent transmitter.     

Developmental expression of a neurofilament-M and two vimentin-like genes in Xenopus laevis

A hamster vimentin cDNA probe has been used to isolate and characterize three Xenopus laevis intermediate filament genes, named XIF1, XIF3 and XIF6. Of these, XIF6 shows 89% homology at the amino acid level to a portion of porcine neurofilament-M. XIF6 is transcribed solely in nervous tissue of embryos, commencing at the late neural tube stage. Expression is totally dependent on an interaction between mesoderm and ectoderm during gastrulation and can be used as a marker of neural induction. XIF1 shows 94% homology and XIF3 83% homology to hamster vimentin at the amino acid level over a region of the protein. Although XIF1 and XIF3 show more homology to vimentin than to any other intermediate filament gene, they have distinct temporal and spatial patterns of expression. XIF1 expression most resembles that of vimentin in higher vertebrates, being expressed in embryonic myotome and nerve cord, whilst XIF3 is unusual in that its expression is restricted predominantly to the head in tailbud embryos.     

Comparison by electrophoresis of proteins characteristic of the lateral line and skin of Xenopus laevis

In experiments aimed at determining acousticolateralis marker proteins, fractions of lateral-line organs and skin of Xenopus laevis were analyzed by one- and two-dimensional polyacrylamide-gel electrophoresis. A protein fraction of approximately 44K mol. wt (K = 1000 daltons) and isoelectric pH 6.3, consisting of at least two components, was enhanced in lateral-line neuromast tissue (containing hair cells) and was decreased in tactile organs and skin (lacking hair cells). This "neuromast-marker-protein" fraction had a mol. wt close to that of actin but was shown to be different from actin. Two other major proteins, at mol. wts 16 and 28K, were present in gels of skin and absent in gels of lateral-line tissue. These proteins were shown to be due to secretion of the amphibian granular glands and were designated "negative marker proteins".     

Localization of two IQGAPs in cultured cells and early embryos of Xenopus laevis

Mammalian IQGAP1 is considered to modulate organization of the actin cytoskeleton under regulation of signaling proteins Cdc42 or Rac and calmodulin [Bashour et al., 1997: J Cell Biol 137:1555-1566; Hart et al., 1996: EMBO J 15:2997-3005] and also to be involved in cadherin-based cell adhesion [Kuroda et al., 1998: Science 281:832-835]. However, its function in the cell has not been clear. In order to clarify the function of IQGAP, we investigated IQGAP in Xenopus laevis cells. We isolated two Xenopus cDNAs encoding homologues of mammalian IQGAP, XIQGAP1, and XIQGAP2, which show high homology with human IQGAP1 and IQGAP2, respectively. Immunofluorescent localization of XIQGAPs in Xenopus tissue cultured cells (XTC cells) and in developing embryos was examined. In XTC cells, XIQGAP1 was colocalized with F-actin at cell-to-cell contact sites, membrane ruffles in lamellipodia, and filopodia. During development of embryos, XIQGAP1 was concentrated in the borders of all embryonic cells. An intense staining for XIQGAP1 was found in regions undergoing active morphogenetic movements, such as the blastopore lip of gastrulae, and the neural plate, the notochord, and the somite of neurulae. These results suggest that XIQGAP1 is involved in both cell-to-cell adhesion and cell migration during Xenopus embryogenesis and in cultured cells. On the other hand, the localization of XIQGAP2 in XTC cells was distinct from that of XIQGAP1 although it was also seen in lamellipodia, filopodia, and borders between cells. In addition to these regions, strong nuclear staining was observed in both XTC cells and embryonic cells.     

Pattern and morphogenesis of presumptive superficial mesoderm in two closely related species, Xenopus laevis and Xenopus tropicalis

The mesoderm, comprising the tissues that come to lie entirely in the deep layer, originates in both the superficial epithelial and the deep mesenchymal layers of the early amphibian embryo. Here, we characterize the mechanisms by which the superficial component of the presumptive mesoderm ingresses into the underlying deep mesenchymal layer in Xenopus tropicalis and extend our previous findings for Xenopus laevis. Fate mapping the superficial epithelium of pregastrula stage embryos demonstrates ingression of surface cells into both paraxial and axial mesoderm (including hypochord), in similar patterns and amounts in both species. Superficial presumptive notochord lies medially, flanked by presumptive hypochord and both overlie the deep region of the presumptive notochord. These tissues are flanked laterally by superficial presumptive somitic mesoderm, the anterior tip of which also appears to overlay the presumptive deep notochord. Time-lapse recordings show that presumptive somitic and notochordal cells move out of the roof of the gastrocoel and into the deep region during neurulation, whereas hypochordal cells ingress after neurulation. Scanning electron microscopy at the stage and position where ingression occurs suggests that superficial presumptive somitic cells in X. laevis ingress into the deep region as bottle cells whereas those in X. tropicalis ingress by "relamination" (e.g., [Dev. Biol. 174 (1996) 92]). In both species, the superficially derived presumptive somitic cells come to lie in the medial region of the presumptive somites during neurulation. By the early tailbud stages, these cells lie at the horizontal myoseptum of the somites. The morphogenic pathway of these cells strongly resembles that of the primary slow muscle pioneer cells of the zebrafish. We present a revised fate map of Xenopus, and we discuss the conservation of superficial mesoderm within amphibians and across the chordates and its implications for the role of this tissue in patterning the mesoderm.     

Micronuclei and chromosome aberrations in Xenopus laevis spermatocytes and spermatids exposed to adriamycin and colcemid

Cultured testes and spermatocytes from the frog Xenopus laevis have been incubated (40-42 h) with adriamycin or colcemid followed by quantitation of chromosome aberrations in secondary spermatocytes and quantitation of micronuclei in secondary spermatocytes, early round spermatids, and round spermatids with acrosomal vacuoles (AV) at 18-162 h of culture. Micronucleus frequencies were consistently higher in secondary spermatocytes relative to round spermatids after exposure to either adriamycin or colcemid due to a higher rate of micronucleus formation during meiosis I compared to meiosis II. Also, some of the micronuclei formed during meiosis I did not survive meiosis II to form micronucleated spermatids. Micronucleus formation occurred in 3-7% of secondary spermatocytes with detectable chromosome aberrations, depending upon drug treatment. Thus, the ratio of micronuclei to total chromosome aberrations in secondary spermatocytes was always higher in colcemid-treated cells compared to adriamycin-treated cells following 18- and 42-h treatment periods. Adriamycin induced significant increases in micronuclei in both secondary spermatocytes and spermatids after 162 h of culture, the time for initial pachytene stages to develop into secondary spermatocytes and spermatids. The data show that cultured testes and spermatocytes from Xenopus may be used to quantify specific meiotic chromosome aberrations induced by both clastogens and spindle poisons using either a rapid secondary spermatocyte micronucleus assay or meiotic chromosome analysis.     

African clawed toads (Xenopus laevis) sense the distance of lateral line stimuli

Sighted African clawed toads use their lateral lines to detect stimulus distance, although accuracy and precision are poorer than for stimulus direction. Single surface wave trains elicited discrete turns and/or swims towards the wave origin. Most responses were brief, ending with the toad stationary (70 % overall; 54–86 % individual toads) or pausing before turning away (11 %; 1–24 %). Lunges or capturing movements with the arms (13 %; 10–22 %) also indicated where toads expected to find prey. Overall, 94 % (88–100 %) of oriented responses had well-defined endpoints. Swim distance—measured as means, medians, and upper and lower quartiles—and the number of bilateral leg kicks increased with stimulus distance. Swim distance also depended upon stimulus angle due to features of turning. Most responses (81 %; 62–92 %) ended short of the wave origin. Regression slopes were 0.45 ± 0.04 mm/mm for stimulus distances up to 85 mm (ca. 2–3x body lengths), 0.16 ± 0.07 mm/mm for distances of 85–130 mm, and non-significant for larger distances to 220 mm. Slopes were steeper for responses that included lunges or capture movements. In only 15 % (3–26 %) of responses were both turn direction and swim distance sufficiently accurate for the toad to sweep through the wave origin.     

Lens formation from cornea implanted into amputated hindlimbs of Xenopus laevis larvae requires innervation or proliferating cell populations in the stump

The capacity of amputated early and late limbs of larval Xenopus laevis to promote lens-forming transformations of corneal implants in the absence of a limb regeneration blastema has been tested by implanting outer cornea fragments from donor larvae at stage 48 (according to Nieuwkoop and Faber 1956), into limb stumps of larvae at stage 52 and 57. Blastema formation has been prevented either by covering the amputation surface with the skin or by reconnecting the amputated part to the limb stump. Results show that stage 52 non-regenerating limbs could promote lens formation from corneal implants not only when innervated but also when denervated. A similar result was observed in stage 57 limbs where blastema formation was prevented by reconnecting the amputated part to the stump. In this case, relevant tissue dedifferentiation was observed in the boundary region between the stump and the autografted part of the limb. However, stage 57 limbs, where blastema formation was prevented by covering the amputation surface with skin, could promote lens formation from the outer cornea only when innervated. In this case, no relevant dedifferentiation of the stump tissues was observed. These results indicate that blastema formation is not a prerequisite for lens-forming transformations of corneal fragments implanted into amputated hindlimbs of larval X. laevis and that lens formation can be promoted by factors delivered by the nerve fibres or produced by populations of undifferentiated or dedifferentiated limb cells.     

Lipids of Xenopus laevis Spermatozoa

Xenopus laevis sperm lipid composition has been studied. The cholesterol content of Xenopus spermatozoa is 194 μ/mg DNA. Their content of glycolipids and phospholipids (measured as inorganic phosphorus) is respectively 40 and 27 μ/mg DNA. The phospholipid pattern is quite homogeneous and all the principal molecular species are present. In all the examined samples, a glycolipid with low mobility, not yet structurally identified, is present. Finally, using as a probe filipin, we have observed cholesterol distribution on the Xenopus sperm plasma membrane by freeze-fracture. In agreement with the chemical data here presented, Xenopus spermatozoa are heavily labelled by filipin. The filipin-cholesterol complexes seem to be distributed on the entire sperm plasma membrane and appear as protuberances on the P face, suggesting that most of the cholesterol reside in the inner leaflet of the membrane.     

Lens formation from the cornea following implantation into hindlimbs of larval Xenopus laevis: the influence of limb innervation and extent of differentiation

Corneal fragments of larval Xenopus laevis at stage 48 (according to Nieuwkoop and Faber, '56), were implanted into sham denervated unamputated hindlimbs, denervated unamputated hindlimbs, amputated and sham denervated hindlimbs, and amputated and denervated hindlimbs of larvae at stages 52 and 57. The results show that unamputated limbs at stage 52, either innervated or denervated, manifest a weak capacity to promote the first lens-forming transformations of the outer cornea. This capacity is absent in both limb types at stage 57. After amputation, limbs of both early and late stages form a regenerative blastema and support lens formation from the outer cornea. Denervation of early stage limbs has no appreciable effect on blastema formation and lens-forming transformation of corneal implants. However, denervation of late stage limbs inhibits both processes. These results indicate that the limb tissues of the early stage limbs contain non-neural inductive factors at a low level and that after limb amputation and blastema formation the level of these factors becomes high enough to promote lens formation from implanted cornea, even after denervation. In contrast, the limb tissues of late stage limbs do not contain a suitable level of non-neural inductive factors.     

Differential expression of two skeletal muscle beta-tropomyosin mRNAs during Xenopus laevis development

A cDNA clone for a Xenopus laevis skeletal muscle beta-tropomyosin (beta-TMad) isoform was isolated from an adult skeletal muscle cDNA library. Sequence analysis revealed that this clone corresponded to a second beta-tropomyosin mRNA distinct from the one that was previously characterized (beta-TMemb). The two skeletal beta-TM mRNAs originate from distinct genes and are differentially expressed during development. Beta-TMemb mRNA is expressed only in the somites of the early embryo while beta-TMad mRNA is expressed in pre-metamorphic tadpoles and adult skeletal muscles. We have isolated the promoter region of the beta-TMemb gene and shown that a DNA construct containing 2.9 kb of promoter region is properly expressed after injection in the embryo.