Eye factors and lens-forming transformations of outer cornea in Xenopus laevis larvae

Outer cornea of lensectomized Xenopus laevis tadpoles at state 50 (according to Nieuwkoop, P.D. and Faber, J., ('56) Normal Table of Xenopus laevis, Daudin, North-Holland, Amsterdam, pp. 1-243) was removed 3, 7 and 10 days after lensectomy and implanted between the outer and the inner cornea of larvae of the same species at stage 51-52. In these conditions, the implanted outer cornea remained isolated from the retinal factor of the vitreous chamber, although it received the nutritional factors normally reaching the outer cornea. Results show that lens-forming transformation process of the outer cornea is arrested, and lens-forming structures undergo regression at speed which increases with increasing precocity of the stage of lens-forming transformation undergone by the implanted cornea. These data suggest that the process of lens-forming transformation is not a single-step process, but a sequence of interactions extending over a long period of time requiring the continuous presence of the retinal factor in the vitreous chamber until complete differentiation of the lens is achieved.     

Xenopus borealis misidentified as Xenopus mulleri

A species of frogs described in publications from our laboratory between 1971 and 1976 as Xenopus mulleri is in fact Xenopus borealis.     

A partially histocompatible family of Xenopus borealis

Reciprocal skin allografts were made between siblings of three successive generations in a family of Xenopus borealis and mutually tolerant animals were mated. In the F3 generation of one subfamily, 92% of the siblings were histocompatible.     

Tissue interactions and lens-forming competence in the outer cornea of larval Xenopus laevis

After lentectomy through the pupillary hole, the outer cornea of larval Xenopus laevis can undergo transdifferentiation to regenerate a new lens. This process is elicited by inductive factor(s) produced by the neural retina and accumulated into the vitreous chamber. During embryogenesis, the outer cornea develops from the outer layer of the presumptive lens ectoderm (PLE) under the influence of the eye cup and the lens. In this study, we investigated whether the capacity of the outer cornea to regenerate a lens is the result of early inductive signals causing lens-forming bias and lens specification of the PLE, or late inductive signals causing cornea formation or both signals. Fragments of larval epidermis or cornea developed from ectoderm that had undergone only one kind of inductive signals, or both kinds of signals, or none of them, were implanted into the vitreous chamber of host larvae. The regeneration potential and the lens-forming transformations of the implants were tested using an antisense probe for pax6 as an earlier marker of lens formation and a monoclonal antibody anti-lens as a definitive indicator of lens cell differentiation. Results demonstrated that the capacity of the larval outer cornea to regenerate a lens is the result of both early and late inductive signals and that either early inductive signals alone or late inductive signals alone can elicit this capacity.     

Contrasting denaturation maps of Xenopus laevis and Xenopus borealis mitochondrial DNAs.

Denaturation maps of mitochondrial DNAs of Xenopus laevis and Xenopus borealis are radically different from each other. This is in striking contrast to the invariant denaturation patterns previously recognized among mtDNAs of various Drosophila species, particularly, since the two toads may be even more closely related to each other than the Drosophila species.     

Hybrids of Xenopus laevis and Xenopus borealis express proteins from both parents.

Xenopus laevis and X. borealis oocytes were compared by two-dimensional electrophoresis of radioactive proteins. At least one-third of the major newly synthesized proteins differ in their electrophoretic mobility. Protein-coding genes from both parents are expressed in interspecific hybrids, thereby providing useful genetic markers for a variety of embryological studies.     

The nucleotide sequences of 5.8-S ribosomal RNA from Xenopus laevis and Xenopus borealis

1. The nucleotide sequence of 5.8-S rRNA from Xenopus laevis is given; it differs by a C in equilibrium U transition at position 140 from the 5.8-S rRNA of Xenopus borealis. 2. The sequence contains two completely modified and two partially modified residues. 3. Three different 5' nucleotides are found: pU-C-G (0.4) pC-G (0.2) and pG (0.4). 4. The 3' terminus is C not U as in all other 5.8-S sequences so far determined. 5. The X. laevis sequence differs from the mammalian and turtle sequences by five and six residue changes respectively. 6. A ribonuclease-resistant hairpin loop is a principle feature of secondary structure models proposed for this molecule. 7. Sequence heterogeneity may occur at one position at a very low level (approximately 0.01) in X. laevis 5.8-S rRNA, while none was detected in X. borealis or HeLa cell 5.8-S rRNA.     

Inductive interactions in the spatial and temporal restriction of lens-forming potential in embryonic ectoderm of Xenopus laevis

The process of lens cell determination in amphibians is currently viewed as one involving a series of inductive interactions. On the basis of previous investigations, these interactions are thought to begin during gastrulation when the presumptive foregut endoderm and then the heart mesoderm come into contact with the presumptive lens ectoderm. This earlier period of induction is followed by the later interaction of the optic vesicle with the lens-forming ectoderm. Transplantation experiments were performed to determine the relative significance of the early and later periods of induction in the process of lens cell determination in the anuran Xenopus laevis. Various ectodermal tissues were transplanted either into the lens-forming region of open neural plate stage host embryos or over the newly formed optic vesicle of later neurula stage embryos. All transplanted tissues were labeled with the intracellular marker horseradish peroxidase to assess the exact origins of any induced lens structures. The results indicate that all nonneural ectodermal tissues have some lens-forming potential early during gastrulation; however, this potential is restricted to the lens-forming region, and perhaps nearby regions, later in development during the time of neurulation. Furthermore, the results show that the optic vesicle is not a substantial inductor of the lens in tissues that have not been previously exposed to the earlier series of inductive interactions that take place during gastrulation and neurulation. Since the optic vesicle does not appear to be a sufficient inductor of the lens, these earlier inductive interactions are, therefore, essential in the process of lens cell determination in Xenopus. These earlier inductive interactions lead to a steady increase in what may be called a lens-forming bias in the presumptive lens ectoderm during this period of development. The eventual loss in the ability of nonlens ventral ectoderm to respond to these lens inductors is presumably the result of other determinative processes that occur in this tissue.     

Histone gene number and organisation in Xenopus: Xenopus borealis has a homogeneous major cluster

Using a Xenopus laevis H4 cDNA clone as a probe we have determined that the numbers of H4 histone genes in Xenopus laevis and Xenopus borealis are approximately the same. These numbers are dependent on the hybridization stringency and we measure about 90 H4 genes per haploid genome after a 60 degrees C wash in 3 X SSC. Using histone probes from both Xenopus and sea urchin we have studied the genomic organization of histone genes in these two species. In all of the X.borealis individuals analyzed about 70% of the histone genes were present in a very homogeneous major cluster. These genes are present in the order H1, H2B, H2A, H4 and H3, and the minimum length of the repeated unit is 16kb. In contrast, the histone gene clusters in X.laevis showed considerable sequence variation. However two major cluster types with different gene orders seem to be present in most individuals. The differences in histone gene organization seen in species of Xenopus suggest that even in closely related vertebrates the major histone gene clusters are quite fluid structures in evolutionary terms.     

A unique sound production mechanism in the pipid anuran Xenopus borealis

The totally aquatic pipid frog Xenopus borealis produces long trains of click-like sound at high sound pressure levels (> 105 dB SPL) underwater at night. While X. borealis retains an essentially terrestrial respiratory tract, the larynx is highly modified in two ways. First, the cricoid cartilage is greatly expanded posteriorly to form a large 'box'. Portions of this cricoid box are composed of an unusual elastic cartilage. Second, portions of the arytenoid cartilages are elaborated into calcified rods with disc-like enlargements at their posterior ends. These discs are the only freely moveable components within the larynx–there are no vocal cords. Artificial stimulation of a pair of muscles controlling the discs and discrete lesions that impair their movement demonstrate that motion of the discs is both necessary and sufficient for click production. Unlike all other anurans, X borealis does not use a moving air column in sound production. A possible mechanism of click production involves two steps: (1) at first, the discs are held tighdy apposed in the midline by fluid adhesive forces, and contraction of bipennate muscles is isometric; (2) when the muscle tension exceeds the adhesive force, the discs separate with very high acceleration leaving a vacuum between them. Air rushing into the space at high speed (an implosion) produces the click. The cricoid box shapes the frequency spectrum of the clicks, and opening the box broadens the power spectrum. The power spectrum of clicks produced by males after breathing helium is unchanged.     

Use of Hybrids between Xenopus laevis and Xenopus borealis in Chimera Formation: Dorsalization of Ventral Cells

The combination of Xenopus borealis and X. laevis provides an excellent cell marking system. The potential availability of this system for chimera formation has also been suggested. However, eggs and early embryos of these species differ in size and the fusion of blastomeres of different sizez results in some disturbance in arrangement of blastomeres of a chimera. This disturbance was avoided by use of embryos from X. laevis eggs fertilized with X. borealis sperm, instead of X. borealis embryos. The cells of these hybrids could also be distinguished from the cells of X. laevis.
The fate of animal ventral cells placed in the dorsal region was followed by making a chimera by fusing a right lateral half of an 8-cell X. laevis embryo with that of an 8-cell hybrid embryo. The animal ventral cells in the "dorsal" region were found to become "dorsalized", giving rise to a lateral half of dorsal axial structures. This observation explains a previous finding that the replacement of dorsal cells by ventral ones had no effect on embryogenesis in a composite embryo.     

DNaseI-hypersensitive sites at promoter-like sequences in the spacer of Xenopus laevis and Xenopus borealis ribosomal DNA.

We have detected a DNAseI hypersensitive site in the ribosomal DNA spacer of Xenopus laevis and Xenopus borealis. The site is present in blood and embryonic nuclei of each species. In interspecies hybrids, however, the site is absent in unexpressed borealis rDNA, but is present normally in expressed laevis rDNA. Hypersensitive sites are located well upstream (over lkb) of the pre-ribosomal RNA promoter. Sequencing of the hypersensitive region in borealis rDNA, however, shows extensive homology with the promoter sequence, and with the hypersensitive region in X. laevis. Of two promoter-like duplications in each spacer, only the most upstream copy is associated with hypersensitivity to DNAaseI. Unlike DNAaseI, Endo R. MspI digests the rDNA of laevis blood nuclei at a domain extending downstream from the hypersensitive site to near the 40S promoter. Since the organisation of conserved sequence elements within this "proximal domain" is similar in three Xenopus species whose spacers have otherwise evolved rapidly, we conclude that this domain plays an important role in rDNA function.     

Mechanical properties of muscles from Xenopus borealis following maintenance in organ culture

The mechanical properties of sartorii muscles from the toad Xenopus borealis were studied in organ cultures lasting up to 26 days. Isometric twitch and tetanic tensions diminished in force reaching half their initial values after 15 days in culture. In contrast, twitch time to peak time to half relaxation, twitch-tetanus ratio and muscle weight-body weight ratio, were unchanged. Maximum isotonic shortening velocity (Vmax) declined, with a half time similar to that of the isometric force. The fall in isometric tension is probably due to a breakdown of activation in some fibres. The change in Vmax could be due to a loss of functional sarcomeres in series with the tendons.     

The organisation and expression of histone genes from Xenopus borealis.

We have isolated genomic clones from Xenopus borealis representing 3 different types of histone gene cluster. We show that the major type (H1, H2B, H2A, H4, H3), present at about 60-70 copies per haploid genome (1), is tandemly reiterated with a repeat length of 15 kb. In situ hybridization to mitotic chromosomes shows that the majority of histone genes in Xenopus borealis are at one locus. This locus is on the long arm of one of the small sub-metacentric chromosomes. A minor cluster type with the gene order H1, H3, H4, H2A is present at about 10-15 copies. The genome also contains rare or unique cluster types present at less than 5 copies having other types of organisation. An isolate of this type had the gene order H1, H4, H2B, H2A, H1 (no H3 cloned). Microinjection of all of the clones into Xenopus laevis oocyte nuclei shows that most of the genes present are functional or potentially functional and a number of variant histone proteins have been observed. S1 mapping experiments confirm that the genes of the major cluster are expressed in all tissues and at all developmental stages examined.