Particulate DNA polymerase from the cytoplasm of Xenopus laevis oocytes

A DNA polymerase has been partially purified and characterized from Xenopus laevis stage 6 oocytes. The enzyme is present only in the cytoplasm and has been shown to be able to copy Poly(A) x oligo(dT), to be sensitive to N-ethylmaleimide, and to sediment faster than 4 S in high salt glycerol gradient. The enzyme can be extracted from particulate material which has a density in sucrose gradient ranging from 1.200 to 1.225 g/cc. This particulate material is identified by its ability to use Poly(A) x oligo(dT) as template in an exogenous DNA polymerase reaction and by its endogenous DNA synthesizing capacity.     

The N-terminal domain that distinguishes yeast from bacterial RNase III contains a dimerization signal required for efficient double-stranded RNA cleavage

Yeast Rnt1 is a member of the double-stranded RNA (dsRNA)-specific RNase III family identified by conserved dsRNA binding (dsRBD) and nuclease domains. Comparative sequence analyses have revealed an additional N-terminal domain unique to the eukaryotic homologues of RNase III. The deletion of this domain from Rnt1 slowed growth and led to mild accumulation of unprocessed 25S pre-rRNA. In vitro, deletion of the N-terminal domain reduced the rate of RNA cleavage under physiological salt concentration. Size exclusion chromatography and cross-linking assays indicated that the N-terminal domain and the dsRBD self-interact to stabilize the Rnt1 homodimer. In addition, an interaction between the N-terminal domain and the dsRBD was identified by a two-hybrid assay. The results suggest that the eukaryotic N-terminal domain of Rnt1 ensures efficient dsRNA cleavage by mediating the assembly of optimum Rnt1-RNA ribonucleoprotein complex.     

Identification of a 60-kDa phosphoprotein that binds stored messenger RNA of Xenopus oocytes

Rapidly labelled, polyadenylated RNA is contained in three distinct fractions isolated from homogenized amphibian oocytes: (a) in ribonucleoprotein particles that are associated with a fibrillar matrix, the complexes sedimenting at greater than 1500S; (b) in ribonucleoprotein particles that sediment at 20-120S and have the characteristics of stored (maternal) messenger ribonucleoprotein (mRNP) and (c) in polyribosomes that sediment at 120-360S. We have compared the RNA and protein components of the first two of these RNP fractions. The polyadenylated RNA extracted from the two RNP fractions differs in that the RNA from fibril-associated RNP contains a much higher content of repeat sequences than does the RNA from mRNP. In other words, the RNA from fibril-associated RNP is largely unprocessed and may constitute a premessenger state, which for convenience is referred to as premessenger RNP (pre-mRNP). RNA-binding experiments demonstrate that the polypeptide most tightly bound in pre-mRNP is a 54-kDa component (p54), whereas the polypeptide most tightly bound in mRNP is a 60-kDa component (p60). Antibodies raised against p60 are used to show that this polypeptide is a common major component of pre-mRNP and mRNP and that it is also located in oocyte nuclei. However the state of p60 is modified between the premessenger and stored message levels: the polypeptide in mRNP is heavily phosphorylated whereas the equivalent polypeptide in pre-mRNP is completely unphosphorylated. The relative roles of the presence of repeat sequences and phosphorylation of mRNA-associated protein in blocking translation are discussed.     

Phosphorylation of a 60 kDa polypeptide from Xenopus oocytes blocks messenger RNA translation.

The stored mRNP particles of Xenopus oocytes contain protein kinase activity and two major phosphoproteins of 60 kDa (pp60) and 56 kDa (pp56). These proteins can be phospholabelled in the particles either in vivo or in vitro and then isolated by SDS-PAGE. On renaturing pp60 in the presence of globin mRNA, a stable RNA-protein complex is formed. The complex has a uniform density in Cs salt gradients, corresponding to the binding of about 10 protein molecules to each mRNA, probably at the poly(A) sequence. Compared with uncomplexed mRNA, the RNP complex is translated poorly both in vitro and in vivo. Translation of the complex can be regained after treatment with protein phosphatase. It is shown that dephosphorylation destabilizes the binding of protein to RNA, making the mRNA accessible for translation. Studies with native mRNP particles show that their translation also can be enhanced by dephosphorylation.     

Messenger RNA competition in living Xenopus oocytes.

When calf lens crystallin mRNA and rabbit globin mRNA are competing for factors limiting protein synthesis in living Xenopus oocytes, no mRNA species is preferentially selected for translation. Differences in the intrinsic translational efficiency of the mRNA species exist, but the relative efficiencies are the same at high and low mRNA concentrations. mRNAs already being translated, in particular endogenous oocyte mRNAs, are less sensitive to competitive inhibition by injected mRNAs. As injected mRNAs gradually become incorporated into the protein-synthesizing machinery of the oocyte, they acquire the same status as the oocyte's own active mRNAs. Exogenous mRNAs this become endogenous mRNAs. These results, together with previous estmates of the translational efficiency of injected heterologous mRNA species, are compatible with the assumption that a large proportion of the endogenous mRNAs is not competing for the translational apparatus of the oocyte and, therefore, probably is present in the temporarily inactivated form.     

RNA sorting in Xenopus oocytes and embryos.

Cytoplasmic localization of mRNA molecules has emerged as a powerful mechanism for generating spatially restricted gene expression. This process is an important contributor to cell polarity in both somatic cells and oocytes, and can provide the basis for patterning during embryonic development. In vertebrates, this phenomenon is perhaps best documented in the frog, Xenopus laevis, where polarity along the animal-vegetal axis coincides with the localization of numerous mRNA molecules. Research over the last several years has made exciting progress toward understanding the molecular mechanisms underlying cytoplasmic mRNA localization.     

A synthetic histone pre-mRNA-U7 small nuclear RNA chimera undergoing cis cleavage in the cytoplasm of Xenopus oocytes.

The 3' processing of histone pre-mRNAs is a nuclear event in which the U7 small nuclear ribonucleoprotein (snRNP) participates as an essential trans-acting factor. We have constructed a chimeric histone-U7 RNA that when injected into the cytoplasm of Xenopus laevis oocytes assembles into a snRNP-like particle and becomes cleaved at the correct site(s). RNP assembly is a prerequisite for cleavage, but, since neither the RNA nor the RNP appreciably enter the nucleus, cleavage occurs mostly, if not exclusively, in the cytoplasm. Consistent with this, cleavage also occurs in enucleated oocytes or in oocytes which have been depleted of U7 snRNPs. Thus all necessary components for cleavage must be present in the oocyte cytoplasm. The novel cleavage occurs in cis, involving only a single molecule of chimeric RNA with its associated proteins. This reaction is equally dependent upon base pairing interactions between histone spacer sequences and the 5'-end of the U7 moiety as the natural in trans reaction. These results imply that U7 is the only snRNP required for histone RNA processing. Moreover, the chimeric RNA is expected to be useful for further studies of the cleavage and assembly mechanisms of U7 snRNP.     

Evidence that XR family interspersed RNA may regulate translation in Xenopus oocytes

It has been shown that about two thirds of Xenopus oocyte or sea urchin egg cytoplasmic poly(A)⁺ RNA contains interspersed repetitive sequences. The functional significance of this interspersed RNA has remained unknown. Here the function of a subfamily of interspersed RNA (XR family; McGrew and Richter, 1989: Dev Biol 134:267–270) in Xenopus oocytes was studied. We found that the elimination of T7 XR (one of the two complementary strands of the XR repeat) interspersed RNA by complementary oligodeoxynucleotides significantly inhibited protein synthesis. On the other hand, the injection of in vitro synthesized T7 XR RNA stimulated translation. Moreover, the insertion of the T7 XR RNA sequence into globin mRNA repressed the translation of the globin mRNA. In order to explain these results, we analyzed interactions between the XR interspersed RNA and oocyte proteins. We found that the major XR RNA binding proteins were p56 and p60, which could be the known mRNA “masking” proteins that bind mRNA and inhibit translation. Further, a 42 kD protein has been identified that appears to bind T7 XR RNA relatively specifically, although it interacts with mRNA with a lower affinity. Based on all of these data, we have proposed that interspersed RNA may be involved in regulating translation by competing with mRNA to interact with certain proteins that can regulate translation. © 1995 Wiley-Liss, Inc.     

Segregation of mitochondria in the cytoplasm of Xenopus vitellogenic oocytes

In actively growing vitellogenic oocytes of Xenopus laevis mitochondria segregate into 2 populations. One stays around the nucleus, actively replicates mitochondrial DNA (mtDNA), and builds up most of the stock of the mitochondria in the full-grown oocyte. The other moves toward the vegetal pole and stops replicating mtDNA early in vitellogenesis. Organelles of this population are components of the germ plasm of the cell.     

The plasma membrane of Xenopus laevis oocytes contains voltage-dependent anion-selective porin channels

Recent patch-clamp studies have shown that anti-porin antibodies, applied to the external side of excised plasma membrane patches of mammalian astrocytes, close chloride channels that are thought to be engaged in cell volume regulation. Frog oocytes are often used to study this basic cell function. Here we document the localisation of endogenous porin voltage-dependent anion-selective channels in Xenopus laevis oocyte plasma membranes. In confocal laser microscopy images a disjunctive pattern of fluorescing spots appear about 10 microm apart. Labelling was prevented by preabsorption of the antibodies with synthetic peptides comprising the epitope of the antigen. Immuno-gold marking of oocyte surfaces followed by silver enhancement of the gold particles lead to a plasma membrane labelling corresponding to that obtained by the confocal laser approach. The data suggests the presence of voltage-dependent, anion-selective channels in oocyte plasma membranes. This data should be borne in mind when frog oocytes are used to study the characteristics of endogenous or heterologously expressed ion channels or regulatory proteins.     

Superkiller yeast strain contains additional species of double-stranded RNA

A superkiller yeast strain, T158C, was found to contain four new species of ds RNA designated P3, P4, P5, and P6. The new components were found to have molecular weights of 880,000 daltons, 620,000 daltons, 500,000 daltons, and 330,000 daltons, respectively. The new species were shown to be double-stranded RNA by their resistance to pancreatic RNAse (E.C.3.1.4.22) in high salt and their sensitivity in low salt. Curing of the killer character by growth at high temperature resulted in the loss of P3–6 as well as M ds RNA. Since T158C is a superkiller, these new molecules may play an important role in the expression of the killer character.     

Teleost Fh14-3-3a protein protects Xenopus oocytes from hyperosmolality

We have previously cloned and characterized a novel 14-3-3 gene from the euryhaline telost Fundulus heteroclitus, Fh14-3-3a (Kültz et al., 2001). The corresponding gene product is osmoregulated and most highly expressed in gill epithelium of this fish. In the present study we have expressed Fh14-3-3a cRNA in Xenopus laevis oocytes and investigated the survival and electrophysiological parameters of Xenopus oocytes in isosmotic and various hyperosmotic media. Xenopus oocytes expressing Fh14-3-3a show no mortality after a 16 hour exposure to hyperosmolality in the form of elevating medium K(+), Na(+), polyethylene glycol, or sorbitol concentrations up to 444 mosmol/kg. In contrast, 16 hours of the same hyperosmolality caused 100% mortality in control Xenopus oocytes injected with water. As a result of hyperosmolality the Xenopus oocyte membrane potential decreased between 10 and 70% in oocytes expressing Fh14-3-3a whereas it was completely abolished in control oocytes. We report that one potential cause for the osmoprotective effect of Fh14-3-3a on Xenopus oocytes could be its inhibition of an endogenous chloride current. Hyperosmotic urea was not as harmful to Xenopus oocytes as hypertonicity and maybe acting through a different mechanism. Coexpression of Fh14-3-3a with a human calcium channel in Xenopus oocytes did not affect the electrophysiological properties of this exogenous channel. Thus, the osmoprotective effect of Fh14-3-3a may prove a valuable tool for the characterization of exogenous ion channels in Xenopus oocytes exposed to hyperosmotic conditions.     

Translation of biologically active messenger RNA from human placenta in Xenopus oocytes.

Polysomal RNA was extracted from human term placenta and total poly(A)-containing RNA purified by affinity chromatography on oligo(dT)-cellulose. Poly(A)-containing RNA constituted approximately 1.2% of the total polysomal RNA and 8% of this purified preparation was able to anneal with [3H]poly(U). When injected into Xenopus oocytes, this poly(A)-rich RNA directed the synthesis of a polypeptide which is immunoprecipitable with a specific antiserum to human placental lactogen. The identity of authentic human placental lactogen and the immunoreactive polypeptide synthesized in the oocytes is suggested by their identical behaviour in dodecylsulfate gel electrophoresis and by the formation of identical cyanogen bromide peptides. No precursor of human placental lactogen can be detected in the oocytes. The messenger RNA for human placental lactogen is very stable in oocytes; it is translated efficiently for a period of at least 7 days.     

An RNA molecule copurifies with RNase P activity from Xenopus laevis oocytes.

Utilizing a procedure for the purification of RNase P from Xenopus laevis germinal vesicle (GV) extracts, according to which the contamination by a large, cytoplasmic, cylindrical structure (1) is avoided, we demonstrate that the X.laevis enzyme, like the HeLa RNase P, is precipitated by anti-Th antibodies and an RNA molecule (XL RNA), 320 nucleotides long, copurifies with the activity. The sequence of XL RNA is 60% homologous to HeLa H1 RNA, therefore the two molecules seem related.