Stage-specific keratins in Xenopus laevis embryos and tadpoles: the XK81 gene family.

This report describes the isolation and characterization of genomic and cDNA clones which define a subfamily of type I keratins in Xenopus laevis whose expression is restricted to embryonic and larval stages. The XK81 subfamily, named after the prototype cDNA clone DG81, contains four members arranged in two pairs of closely homologous loci; they were named 81A1, A2, B1, and B2. Genomic clones were obtained representing all of these regions. The A1 gene has been completely sequenced together with approximately 1 kb of flanking sequences at each end; this gene corresponds to the previously reported cDNA clone 8128 (Jonas, E., T. D. Sargent, and I. B. Dawid, 1985, Proc. Natl. Acad. Sci. USA, 82:5413-5417). The B2 gene is represented by a partial cDNA clone, DG118. Upstream sequences and about half of the coding regions have been sequenced for the B1 and B2 genes, whereas the A2 locus has been identified on the basis of hybridization data and could be a gene or pseudogene. Genomic Southern blotting indicates that all members of the subfamily have been isolated. The keratin proteins encoded by the B1 and B2 genes are 96% homologous in the central rod domain, whereas A/B gene homology in this region is 81%. During development mRNAs derived from A and B genes accumulate coordinately during gastrula and neurula stages; in the tadpole, 81A mRNA decays rapidly, whereas 81B mRNA shows a second abundance peak, persists for most of tadpole life, and decays by metamorphosis. RNAs derived from the XK81 keratin subfamily are undetectable in the adult, where different type I keratin genes are expressed.

5-methylcytidylic acid: absence from mitochondrial DNA of frogs and HeLa cells.

The content of 5-methylcytidylic acid in nuclear DNA and mito chondrial DNA of Xenopus laevis and HeLa cells has been determined. Both nuclear DNA's contain 5-methylcytidylic acid. The 5-methylcytidylic acid content of X. laevis DNA is 1.7 mole percent of total nucleotides, and that of HeLc cell DNA is 0.7 mole percent. In neither mitochondrial DNA could any 5-methylcytidylic acid be detected; the limit of sensitivity was judged at below 0.1 mole percent for X. laevis DNA and below 0.05 mole percent for HeLa cell DNA.

Xenopus laevis in developmental and molecular biology.

Xenopus laevis is a prime system for the study of embryogenesis in vertebrates. Both prelocalized information in the egg and inductive interactions between cells contribute to the ordered increase in complexity during development. Embryonic induction, discovered in amphibians, is being studied intensely in Xenopus; recent work suggests a role for growth factors in this process. Contributions of the Xenopus system to the analysis of ribosomal and 5S RNA genes, and the diverse and highly productive applications of the oocyte injection technology, are also summarized.

Differential gene expression in the gastrula of Xenopus laevis.

A modified cloning method designed to produce differential complementary DNA libraries permits the isolation of sequences that are present in the RNA population of any developmental stage or tissue, but are not present or are much less abundant in another stage or tissue. Selective complementary DNA cloning is especially useful when the differentially expressed RNA's are of low to moderate abundance in the cells in which they occur. A class of cytoplasmic polyadenylated RNA's differentially expressed in gastrula embryos of Xenopus laevis (DG RNA's) has been isolated. These DG RNA's occur very rarely or not at all in unfertilized eggs and blastulae, accumulate as the result of transcription before and during gastrulation, and, with some exceptions, decline in abundance as development proceeds. Many of these RNA molecules appear to be translated at the gastrula stage. Thus, DG RNA's may encode proteins that are important in the process of gastrulation.

Vitellogenesis and the vitellogenin gene family.

Vitellogenin is synthesized under estrogen control in the liver, extensively modified, transported to the ovary, and there processed to the yolk proteins lipovitellin and phosvitin. In the frog Xenopus laevis there are at least four distinct but related vitellogenin genes. The two genes A1 and A2 have a 95 percent sequence homology in their messenger RNA coding regions, and contain 33 introns that interrupt the coding region (exons) at homologous positions. Sequences and lengths of analogous introns differ, and many introns contain repetitive DNA elements. The introns in these two genes that have apparently arisen by duplication have diverged extensively by events that include deletions, insertions, and probably duplications. Rapid evolutionary change involving rearrangements and the presence of repeated DNA suggests that the bulk of the sequences within introns may not have any specific function.

Mesoderm induction in amphibians: the role of TGF-beta 2-like factors.

Mesoderm induction in the amphibian embryo can be studied by exposing animal region explants (destined to become ectoderm) to appropriate stimuli and assaying the appearance of mesodermal products like alpha-actin messenger RNA. Transforming growth factor beta 2 (TGF-beta 2), but not TGF-beta 1, was active in alpha-actin induction, while addition of fibroblast growth factor had a small synergistic effect. Medium conditioned by Xenopus XTC cells (XTC-CM), known to have powerful mesoderm-inducing activity, was shown to contain TGF-beta-like activity as measured by a radioreceptor binding assay, colony formation in NRK cells, and growth inhibition in CCL64 cells. The activity of XTC-CM in mesoderm induction and in growth inhibition of CCL64 cells was inhibited partially by antibodies to TGF-beta 2 but not by antibodies to TGF-beta 1. Thus, a TGF-beta 2-like molecule may be involved in mesoderm induction.

Critical role of biklf in erythroid cell differentiation in zebrafish.

Hematopoietic cells arise from ventral mesoderm in different vertebrates, but the mechanisms through which various factors contribute to the hematopoietic processes, including erythrogenesis, remain incompletely understood. The Krüppel-like transcription factor Biklf is preferentially expressed in blood islands throughout zebrafish embryogenesis, marking the region of future erythropoiesis [1]. In this paper, we show that expression of biklf is significantly suppressed in the blood-less mutants vampire and m683 in which primitive hematopoiesis is impaired. Knockdown of biklf using morpholino-based antisense oligonucleotides (biklf-MO) led to a potent reduction in the number of circulating blood cells and deficiency in hemoglobin production. Consistently, we found that the expression of beta(e3)globin is strongly suppressed in biklf-MO-injected embryos, while gata1 expression is partly inhibited at the 10-somite stage. In addition, analysis of reporter constructs driven by the GATA1 and beta-globin promoters showed that Biklf can positively regulate both genes. These results indicate that Biklf is required for erythroid cell differentiation in zebrafish.

LIM domains: multiple roles as adapters and functional modifiers in protein interactions.

The LIM domain is a specialized double-zinc finger motif found in a variety of proteins, in association with domains of divergent functions or forming proteins composed primarily of LIM domains. LIM domains interact specifically with other LIM domains and with many different protein domains. LIM domains are thought to function as protein interaction modules, mediating specific contacts between members of functional complexes and modulating the activity of some of the constituent proteins. Nucleic acid binding by LIM domains, while suggested by structural considerations, remains an unproven possibility. LIM-domain proteins can be nuclear, cytoplasmic, or can shuttle between compartments. Several important LIM proteins are associated with the cytoskeleton, having a role in adhesion-plaque and actin-microfilament organization. Among nuclear LIM proteins, the LIM homeodomain proteins form a major subfamily with important functions in cell lineage determination and pattern formation during animal development.

cDNA cloning and developmental expression of fibroblast growth factor receptors from Xenopus laevis.

The heparin-binding growth factors constitute a family of homologous polypeptides including basic and acidic fibroblast growth factors (FGFs). These factors participate in a variety of processes, including wound healing, angiogenesis, neuronal survival, and inductive events in the early amphibian embryo. We have isolated three closely related species of cDNA clones for Xenopus FGF receptors. One of these, designated XFGFR-A1, encodes an open reading frame of 814 amino acids. A second class encodes an identical amino acid sequence with the exception of an 88-amino-acid deletion near the 5' end. This species probably arises through alternative splicing. A third class of cDNA corresponding to the shorter form of XFGFR-A1 was isolated and shown to be 95% homologous and is designated XFGFR-A2. Xenopus FGF receptors are similar to FGF receptors from other species in that they contain a transmembrane domain, a tyrosine kinase domain split by a 14-amino-acid insertion, and a unique conserved stretch of eight acidic residues in the extracellular domain. Overexpression of Xenopus FGF receptor protein by transfection of COS1 cells with the corresponding cDNA in a transient expression vector leads to the appearance of new FGF binding sites on transfected cells, consistent with these cDNAs encoding for FGF receptors. RNA gel blot analysis demonstrates that Xenopus FGF receptor mRNA is a maternal message and is expressed throughout early development. When blastula-stage ectoderm is cultured in control amphibian salt solutions, Xenopus FGF receptor mRNA declines to undetectable levels by late neurula stages. However, when cultured in the presence of FGF of XTC mesoderm-inducing factor, Xenopus FGF receptor RNA expression is maintained.

Isolation and characterization of calmodulin genes from Xenopus laevis.

Two cDNAs derived from Xenopus laevis calmodulin mRNA have been cloned. Both cDNAs contain the complete protein-coding region and various lengths of untranslated segments. The two cDNAs encode an identical protein but differ from each other by 5% nucleotide substitutions. The 5' and 3' untranslated regions, to the extent available, are highly homologous between the two cDNAs. The predicted sequence of X. laevis calmodulin is identical to that of vertebrate calmodulins from mammals and chickens and shows one substitution compared with electric eel calmodulin. Genomic DNA sequences homologous to each of the two cDNA clones have been isolated and were shown to account for the major calmodulin-coding DNA sequences in X. laevis. These data suggest that X. laevis carries two active, nonallelic calmodulin genes. Although no complete analysis has been carried out, it appears that the X. laevis calmodulin genes are interrupted by at least four introns. The relative concentrations of calmodulin mRNA have been estimated in different embryonic stages and adult tissues and found to vary by up to a factor of 10. The highest levels of calmodulin mRNA were found in ovaries, testes, and brains. In these three tissues, the two calmodulin genes appear to be expressed at approximately equal levels.

Developmentally regulated cytokeratin gene in Xenopus laevis.

We have determined the sequence of cloned cDNAs derived from a 1,665-nucleotide mRNA which transiently accumulates during Xenopus laevis embryogenesis. Computer analysis of the deduced amino acid sequence revealed that this mRNA encodes a 47-kilodalton type I intermediate filament subunit, i.e., a cytokeratin. As is common to all intermediate filament subunits so far examined, the predicted polypeptide, named XK70, contains N- and C-terminal domains flanking a central alpha-helical rod domain. The overall amino acid homology between XK70 and a human 50-kilodalton type I keratin is 47%; homology within the alpha-helical domain is 57%. The N-terminal domain, which is not completely contained in our cDNAs, is basic, contains 42% serine plus alanine, and includes five copies of a six-amino-acid repeating unit. The C-terminal domain has a high alpha-helical content and contains a region with sequence homology to the C-terminal domains of other type I and type III intermediate filament proteins. We suggest that different keratin filament subtypes may have different functional roles during amphibian oogenesis and embryogenesis.

Retinoid X receptor (RXR) within the RXR-retinoic acid receptor heterodimer binds its ligand and enhances retinoid-dependent gene expression.

Retinoic acid receptor (RAR) and retinoid X receptor (RXR) form heterodimers and regulate retinoid-mediated gene expression. We studied binding of RXR- and RAR-selective ligands to the RXR-RAR heterodimer and subsequent transcription. In limited proteolysis analyses, both RXR and RAR in the heterodimer bound their respective ligands and underwent a conformational change in the presence of a retinoic acid-responsive element. In reporter analyses, the RAR ligand (but not the RXR ligand), when added singly, activated transcription, but coaddition of the two ligands led to synergistic activation of transcription. This activation required the AF-2 domain of both RXR and RAR. Genomic footprinting analysis was performed with P19 embryonal carcinoma cells, in which transcription of the RARbeta gene is induced upon retinoid addition. Paralleling the reporter activation data, only the RAR ligand induced in vivo occupancy of the RARbeta2 promoter when added singly. However, at suboptimal concentrations of RAR ligand, coaddition of the RXR ligand increased the stability of promoter occupancy. Thus, liganded RXR and RAR both participate in transcription. Finally, when these ligands were tested for teratogenic effects on zebra fish and Xenopus embryos, we found that coadministration of the RXR and RAR ligands caused more severe abnormalities in these embryos than either ligand alone, providing biological support for the synergistic action of the two ligands.

The 1723 element: a long, homogeneous, highly repeated DNA unit interspersed in the genome of Xenopus laevis.

We describe a highly repeated DNA element in the Xenopus laevis genome. This sequence, named the 1723 element, was first identified among sequences that are transcribed during embryonic development. The element is present in about 8500 copies per haploid genome, which together accounts for about 2.4% of the genome. Most copies of the element have highly conserved restriction maps, and are interspersed in the genome. The copies range in size from 6000 to 10,000 base-pairs due to an expandable region that contains variable numbers of a tandemly repeating 183 to 204 base-pair unit. The element is framed by an imperfect 18 base-pair inverted sequence, and inverted repeats of 180 to 185 base-pairs are nearby. Sequence analysis of DNA adjacent to three cloned elements shows that the elements are flanked by 8 base-pair direct repeats. These and other properties of 1723 suggest that it may be transposable.

A family of oligo-adenylate-terminated transposable sequences in Drosophila melanogaster.

Five members of the F family of transposable elements in Drosophila melanogaster have been characterized. Together with earlier work, these experiments lead to the following conclusions. There are about 50 copies of F elements in the genome located at about 25 euchromatic sites and in the chromocenter. Three of the cloned F elements have a length of 4.7 X 10(3) bases, the other two are truncated at their left ends by 0.4 X 10(3) and 1.3 X 10(3) bases, the other two are truncated at their left ends by 0.4 X 10(3) and 1.3 X 10(3) bases. The shortest F element has been found in a recently arisen revertant of the white ivory mutation. All F elements terminate at their right ends in a stretch of 12 to 30 A residues. A polyadenylation signal (A-A-T-A-A-A) precedes this terminus. Analysis of homologous DNA regions derived from two different strains of D. melanogaster containing F elements (filled sites) or lacking F elements (empty sites) showed that F insertions lead to the generation of target site duplications of 8 to 13 base-pairs. The five target sites analyzed differ in sequence but show a low level of homology. F elements do not contain internal repeats and, in particular, they lack the terminal redundancy characteristic of many other transposable elements. We compare F elements with other oligo(A)-terminated sequences, specifically the Alu sequences and processed pseudogenes of mammals. The presence of an oligo(A) stretch and of a polyadenylation signal raises the possibility that F elements transpose by a mechanism that involves transcription and reverse transcription followed by reinsertion into the genome.

The use of hybrid somatic cells as an approach to mitochondrial genetics in animals.

We have studied the fate of parental mitochondrial DNA (mtDNA) in hybrid somatic cells derived by Sendai virus-induced fusion of human cells and mouse or rat cells. Many hybrid cell strains were obtained which contained sequences from both human and rodent mtDNA after 40 to 60 population doublings. Some strains were subcloned and cultured further for up to 150 doublings; a large fraction of these strains contained both parental mtDNA sequences at that time. The relation between human and rodent mtDNA sequences was tested in some of the hybrid cell strains. In a high fraction of strains tested the human and rodent mtDNA sequences were linked to each other by what are most likely covalent bonds. This linkage may be described as "recombination" of mtDNA sequences from two different animals.

Zebrafish mab21l2 is specifically expressed in the presumptive eye and tectum from early somitogenesis onwards.

Random screening for tissue specific genes in zebrafish by in situ hybridization led us to isolate a gene which showed highly restricted expression in the developing eyes and midbrain at somitogenesis stages. This gene was very similar to mouse and human mab21l2. The characteristic expression pattern of mab21l2 facilitates a detailed description of the morphogenesis of the eyes and midbrain in the zebrafish. In the eye field, mab21l2 expression illustrates the transformation of the eye field to form two separate eyes in the anterior neural plate. Mab21l2 staining in the cyclopic mutants, cyc and oep, exhibited incomplete splitting of the eye primodium. In the midbrain, mab21l2 is expressed in the tectum, and its expression follows the expansion of the tectal region. In mutants affecting the mid-hindbrain boundary (MHB), mab21l2 expression is affected differentially. In the noi/pax2.1 mutant, mab21l2 is down-regulated and the size of the tectum remains small, whereas in the ace/fgf8 mutant, mab21l2 expression persists although the shape of the tectum is altered.

Expression of the Krüppel-like zinc finger gene biklf during zebrafish development.

The zebrafish biklf gene encodes a novel Krüppel-like transcription factor containing three contiguous zinc fingers at the C-terminus. Expression of biklf is detected from the shield stage onward in the developing prechordal plate, and as a 'baseball seam'-like lateral stripe beginning at the end of gastrulation. The latter expression domain is suppressed in the swirl mutant in which bmp2b is disrupted. At the 5-somite stage the lateral expression domain separates into two distinct stripes, one in the ectoderm, the other in blood islands in the lateral plate mesoderm. Blood island staining of biklf continues through somitogenesis as the most prominent area of biklf expression.

Cloning and expression of noz1, a zebrafish zinc finger gene related to Drosophila nocA.

We report the isolation of noz1, a novel zebrafish zinc finger gene which displays sequence similarity to Drosophila nocA. noz1 transcripts are detected at the shield stage within the germ ring and excluded from the most dorsal region. By the end of gastrulation, noz1 is expressed in the presumptive hindbrain and spinal cord as well as in the forming tailbud. During somitogenesis noz1 shows a dynamic expression in the midbrain-hindbrain boundary, hindbrain and spinal cord. This results, at 24 hpf, in a graded expression with the highest level in rhombomeres 2 and 3, and the lowest in the spinal cord. Expression analysis in swirl and chordino mutants as well as in retinoic acid treated embryos indicate that noz1 is activated by BMP antagonists and neural posteriorizing signals.

Transforming growth factor-beta5 expression during early development of Xenopus laevis.

Members of the transforming growth factor-beta (TGF-beta) superfamily play various roles during development in both vertebrates and invertebrates. Two isoforms, TGF-beta2 and -beta5, have been isolated from Xenopus laevis. We describe here the localization of TGF-beta5 mRNA in early embryos of X. laevis, assessed by whole-mount in situ hybridization. The first detectable expression of TGF-beta5 was seen in the stage 14 embryo at the posterior tip of notochord, which continued to later stages, accompanied by the expression in bilateral regions of posterior wall in the tail region next to the notochord. At later stages, transient expression was seen in the cement gland (around stage 21) and in the somites (stages 24-27). In addition, expression was present in the branchial arches (stage 29-36) and olfactory placodes (stage 36).

Expression of LIM-domain binding protein (ldb) genes during zebrafish embryogenesis.

LIM homeodomain proteins are developmental regulators whose functions depend on synergism with LIM domain binding proteins (Ldb proteins). We have isolated four members of the ldb gene family from the zebrafish, Danio rerio. Ldb1, Ldb2 and Ldb3 share 95%, 73% and 62% amino acid identity with mouse Ldb1, respectively. In overlay assays, Ldb proteins bind LIM homeodomain proteins and LMO1, but not zyxin or MLP. Whole mount in situ hybridization showed that zebrafish ldb1 is expressed ubiquitously from gastrulation onward. Ldb2 is ubiquitous at gastrulation, and later is found in many but not all tissues, especially the anterior central nervous system (CNS) and vasculature. Ldb3 mRNA was expressed primarily in the anterior CNS.