Small nuclear U-ribonucleoproteins in Xenopus laevis development. Uncoupled accumulation of the protein and RNA components

The accumulation of protein and RNA components of small nuclear U-ribonucleoprotein particles is non-co-ordinate during oogenesis and early embryogenesis in Xenopus laevis. Northern blot hybridization of a cloned Xenopus U2-RNA gene to oocyte and embryo RNAs demonstrates that the amount of small nuclear U2-RNA per oocyte reaches a plateau early in oogenesis (at the start of yolk deposition); further accumulation is not observed in oogenesis, nor in embryogenesis until the late blastula stage. In contrast, we show by immunoblot analysis that the proteins that bind to small nuclear U-RNAs continue to be accumulated after vitellogenesis begins, reaching maximum amounts only at the end of oocyte development. No further accumulation of these proteins is seen during embryogenesis. The consequences of this non-co-ordinate synthesis of small nuclear RNA and small nuclear RNA-binding proteins are as follows: a 10- to 20-fold excess of the protein components of the small ribonucleoprotein particles over small nuclear RNA exists in large oocytes; the bulk of the protein is cytoplasmic, while the RNA is nuclear. Thus the excess protein in the cytoplasm is uncomplexed with RNA. The imbalance between protein and RNA is not corrected until the late blastula or early gastrula stages of embryogenesis, when a tenfold increase in the amount of small nuclear U2-RNA is detected. Thus the protein, but not the RNA, components of small nuclear U-ribonucleoprotein particles are stockpiled in oocytes for later use in embryonic development. During the course of these studies, we also found that there are tissue-specific differences in the Sm-antigenic proteins of X. laevis.     

NGF promotes copper accumulation required for optimum neurite outgrowth and protein methylation

The role of copper in biological phenomena that involve signal transduction is poorly understood. A well-defined cellular model of neuronal differentiation has been utilized to examine the requirement for copper during nerve growth factor (NGF) signal transduction that results in neurite outgrowth. Experiments demonstrate that NGF increases cellular copper content within 3 days of treatment. Copper chelators reduce the effects of NGF on neurite outgrowth and copper accumulation. The effects of tetraethylene pentamine (TEPA), a copper-specific chelator, are reversible by removal from the culture medium and/or by addition of equimolar copper chloride. Because previous work demonstrated that NGF increases protein methylation in PC12 cells, we examined whether TEPA also inhibits S-adenosylhomocysteine hydrolase (SAHH), an essential copper enzyme involved in all protein methylation reactions. In addition to direct in vitro inhibition of SAHH, we show that TEPA decreases protein arginine methyltransferase 1(PRMT1)-specific enzyme activity in PC12 cells and sympathetic neurons. These data comprise the first biochemical and cellular evidence to address the mechanism of copper involvement in neuronal differentiation.     

The mechanism and regulation of deadenylation: identification and characterization of Xenopus PARN.

In Xenopus oocytes, the deadenylation of a specific class of maternal mRNAs results in their translational repression. Here we report the purification, characterization, and molecular cloning of the Xenopus poly(A) ribonuclease (xPARN). xPARN copurifies with two polypeptides of 62 kDa and 74 kDa, and we provide evidence that the 62-kDa protein is a proteolytic product of the 74-kDa protein. We have isolated the full-length xPARN cDNA, which contains the tripartite exonuclease domain conserved among RNase D family members, a putative RNA recognition motif, and a domain found in minichromosome maintenance proteins. Characterization of the xPARN enzyme shows that it is a poly(A)-specific 3' exonuclease but does not require an A residue at the 3' end. However, the addition of 25 nonadenylate residues at the 3' terminus, or a 3' terminal phosphate is inhibitory. Western analysis shows that xPARN is expressed throughout early development, suggesting that it may participate in the translational silencing and destabilization of maternal mRNAs during both oocyte maturation and embryogenesis. In addition, microinjection experiments demonstrate that xPARN can be activated in the oocyte nucleus in the absence of cytoplasmic components and that nuclear export of deadenylated RNA is impeded. Based on the poly(A) binding activity of xPARN in the absence of catalysis, a model for substrate specificity is proposed.     

Genes and mechanisms involved in early embryonic development in Xenopus laevis

Our laboratory is studying genes involved in the regulation of the balance between cell growth and differentiation during embryonic development in Xenopus. We have analyzed the developmental expression of the proto-oncogenes c-myc, and KiRas 2B, the proliferating cell nuclear antigen (PCNA), and the tumor suppressor gene p53. These genes, usually expressed during cell proliferation, are expressed in the oocyte in large quantities, but the majority of their maternal RNAs are degraded by the gastrula stage. The expression of c-myc and the localization of the protein indicate that c-myc has the characteristics expected for a gene involved in the regulation of the mid-blastula transition, when zygotic expression is turned on in the embryo. Its expression during late development or during regeneration indicates that it enables the cells to remain competent for cycling during organogenesis. In vitro systems that reproduce the principal cellular functions during early development are used as model systems to understand the mechanisms involved in early embryogenesis.     

A Xenopus protein related to hnRNP I has a role in cytoplasmic RNA localization.

Cytoplasmic localization of mRNA molecules is a powerful mechanism for generating cell polarity. In vertebrates, one paradigm is localization of Vg1 RNA within the Xenopus oocyte, a process directed by recognition of a localization element within the Vg1 3' UTR. We show that specific base changes within the localization element abolish both localization in vivo and binding in vitro by a single protein, VgRBP60. VgRBP60 is homologous to a human hnRNP protein, hnRNP I, and combined immunolocalization and in situ hybridization demonstrate striking colocalization of hnRNP I and Vg1 RNA within the vegetal cytoplasm of the Xenopus oocyte. These results implicate a novel role in cytoplasmic RNA transport for this family of nuclear RNA-binding proteins.     

Oocytes and embryos of Xenopus laevis express two different isoforms of germ cell nuclear factor (GCNF,NR6A1)

The germ cell nuclear factor (GCNF) is a nuclear orphan receptor and a putative regulator of the pluripotent state of cells. Although it was first described in mouse germ cells, GCNF is also expressed in mouse and Xenopus embryos. By means of 5'RACE we have identified a novel isoform of Xenopus laevis GCNF that is predominantly expressed in germ cells, whereas both the oocyte and embryonic forms are expressed during Xenopus embryogenesis. EST database search revealed that the homologues of both isoforms are also transcribed in Xenopus tropicalis.     

Morphological changes and hypomethylation of DNA in transgenic tobacco expressing antisense RNA of the S-adenosyl-l-homocysteine hydrolase gene

S-adenosyl-l-homocysteine hydrolase (SAHH) is a key enzyme in the regulation of intracellular methylation reactions. To investigate the role of SAHH in methylation reactions and morphogenesis in planta, we have made transgenic plants expressing antisense RNA of tobacco SAHH. The transgenic plants displayed distinct morphological changes including a floral homeotic change. We hypothesized that the changes were caused by increased levels of cytokinin. In those transgenic plants, we observed that a repetitive DNA sequence appeared less methylated than controls. We speculated that altered gene expressions by the hypomethylation of DNA might be involved in the changes.     

Changes in bicoid mRNA anchoring highlight conserved mechanisms during the oocyte-to-embryo transition

Intracellular mRNA localization directs protein synthesis to particular subcellular domains to establish embryonic polarity in a variety of organisms. In Drosophila, bicoid (bcd) mRNA is prelocalized at the oocyte anterior. After fertilization, translation of this RNA produces a Bcd protein gradient that determines anterior cell fates [1] and [2]. Analysis of bcd mRNA during late stages of oogenesis suggested a model for steady-state bcd localization by continual active transport [3]. However, this mechanism cannot explain maintenance of bcd localization throughout the end of oogenesis, when microtubules disassemble in preparation for embryogenesis [4] and [5], or retention of bcd at the anterior in mature oocytes, which can remain dormant for weeks before fertilization [6]. Here, we elucidate the path and mechanism of sustained bcd mRNA transport by direct observation of bcd RNA particle translocation in living oocytes. We show that bcd mRNA shifts from continuous active transport to stable actin-dependent anchoring at the end of oogenesis. Egg activation triggers bcd release from the anterior cortex for proper deployment in the embryo, probably through reorganization of the actin cytoskeleton. These findings uncover a surprising parallel between flies and frogs, as cortically tethered Xenopus Vg1 mRNA undergoes a similar redistribution during oocyte maturation [7]. Our results thus highlight a conserved mechanism for regulating mRNA anchoring and redeployment during the oocyte-to-embryo transition.     

Cytoplasmic protein methylation is essential for neural crest migration

As they initiate migration in vertebrate embryos, neural crest cells are enriched for methylation cycle enzymes, including S-adenosylhomocysteine hydrolase (SAHH), the only known enzyme to hydrolyze the feedback inhibitor of trans-methylation reactions. The importance of methylation in neural crest migration is unknown. Here, we show that SAHH is required for emigration of polarized neural crest cells, indicating that methylation is essential for neural crest migration. Although nuclear histone methylation regulates neural crest gene expression, SAHH and lysine-methylated proteins are abundant in the cytoplasm of migratory neural crest cells. Proteomic profiling of cytoplasmic, lysine-methylated proteins from migratory neural crest cells identified 182 proteins, several of which are cytoskeleton related. A methylation-resistant form of one of these proteins, the actin-binding protein elongation factor 1 alpha 1 (EF1α1), blocks neural crest migration. Altogether, these data reveal a novel and essential role for post-translational nonhistone protein methylation during neural crest migration and define a previously unknown requirement for EF1α1 methylation in migration.     

Quantitation and subcellular localization of proliferating cell nuclear antigen (PCNA/cyclin) in oocytes and eggs of Xenopus laevis

Proliferating cell nuclear antigen (PCNA/cyclin) is a 36-kDa polypeptide present in the nuclei of mitotically active cells. It is known to be involved in DNA replication through an association with DNA polymerase delta. We examined the total content as well as the subcellular distribution of PCNA in the oocyte and the egg of Xenopus laevis by employing immunocytological staining and immunoblot analysis. While oocytes are not capable of replicating chromosomes, PCNA is abundant in the nucleus (about 65 ng per nucleus). The oocyte cytoplasm, on the other hand, does not contain a significant quantity of this protein. The amount of total PCNA does not change appreciably during oocyte maturation and the subsequent stages of egg cleavage. Thus, PCNA belongs to a class of proteins which are stockpiled during oogenesis in order to be utilized later for early embryogenesis.     

Quantitation and subcellular localization of proliferating cell nuclear antigen (PCNA/cyclin) in oocytes and eggs of Xenopus laevis

Proliferating cell nuclear antigen (PCNA/cyclin) is a 36-kDa polypeptide present in the nuclei of mitotically active cells. It is known to be involved in DNA replication through an association with DNA polymerase δ. We examined the total content as well as the subcellular distribution of PCNA in the oocyte and the egg of Xenopus laevis by employing immunocytological staining and immunoblot analysis. While oocytes are not capable of replicating chromosomes, PCNA is abundant in the nucleus (about 65 ng per nucleus). The oocyte cytoplasm, on the other hand, does not contain a significant quantity of this protein. The amount of total PCNA does not change appreciably during oocyte maturation and the subsequent stages of egg cleavage. Thus, PCNA belongs to a class of proteins which are stockpiled during oogenesis in order to be utilized later for early embryogenesis.     

Disruption of the dynamic sub-cellular localization of the Xenopus tumorhead protein causes embryonic lethality at the early gastrula transition

Abstract The Xenopus laevis tumorhead (TH) protein, a positive regulator of cell proliferation during embryogenesis, shuttles from the cell periphery into the nucleus during embryogenesis. In these studies, we performed a detailed analysis of TH's subcellular localization pattern to characterize its dynamic behavior. We found that TH exhibits distinct patterns of localization in different germ layers. At the blastula stage, TH is present in the apical cell periphery of prospective mesodermal and ectodermal cells. At the gastrula stage, TH is distributed throughout the entire cytoplasm of prospective mesodermal and ectodermal cells, whereas it shows nuclear localization in presumptive endodermal cells. TH moves into the nucleus of mesodermal and ectodermal cells during the neurula and early tailbud stages. To understand if TH is regulated by changes in its subcellular localization, we used a TH mutant containing signals for farnesylation and palmitoylation to tether the protein to the plasma membrane. Ubiquitous overexpression of this mutant causes embryonic lethality at the early gastrula transition. Further examination using TUNEL assays indicated that wild-type TH overexpression induces apoptosis during gastrulation, and that this effect is exacerbated by the overexpression of the membrane-bound TH mutant. Taken together, our results suggest that changes in the sub-cellular localization of the TH protein are important for its function because blocking the nuclear translocation of overexpressed TH increases apoptosis and causes embryos to die. Our data also suggest that TH plays a role outside the nucleus when it is present at the cell periphery.