Cellular titers and subcellular distributions of abundant polyadenylate-containing ribonucleic acid species during early development in the frog Xenopus laevis.

The distribution of cytoplasmic messenger ribonucleic acids (RNAs) in translationally active polysomes and inactive ribonucleoprotein particles changes during early development. Cellular levels and subcellular distributions have been determined for most messenger RNAs, but little is known about how individual sequences change. In this study, we used hybridization techniques with cloned sequences to measure the titers of 23 mitochondrial and non-mitochondrial polyadenylate-containing [poly(A)+]RNA species during early development in the frog Xenopus laevis. These RNA species were some of the most abundant cellular poly(A)+ RNA species in early embryos. The concentrations of most of the non-mitochondrial (cytoplasmic) RNAs remained constant in embryos during the first 10 h of development, although the concentrations of a few species increased. During neurulation, we detected several new poly(A)+ RNA sequences in polysomes, and with one possible exception the accumulation of these sequences was largely the result of new synthesis or de novo polyadenylation and not due to the recruitment of nonpolysomal (free ribonucleoprotein) poly(A)+ RNA. We measured the subcellular distributions of these RNA species in polysomes and free ribonucleoproteins during early development. In gastrulae, non-mitochondrial RNAs were distributed differentially between the two cell fractions; some RNA species were represented more in free ribonucleoproteins, and others were represented less. By the neurula stage this differential distribution in polysomes and free ribonucleoproteins was less pronounced, and we found species almost entirely in polysomes. Some poly(A)+ RNA species transcribed from the mitochondrial genome were localized within the mitochondria and were mapped to discrete fragments of the mitochondrial genome. Much of this poly(A)+ RNA was transcribed from the ribosomal locus. Nonribosomal mitochondrial poly(A)+ RNA species became enriched in polysome-like structures after fertilization, with time courses similar to the time course of mobilization of cytoplasmic poly(A)+ RNA.     

Cell-free translation analysis of messenger RNA in echinoderm and amphibian early development

A wheat germ cell-free translation system has been used to analyze populations of abundant messenger RNA from sea urchin eggs and embryos and from amphibian oocytes and ovaries. We show directly that sea urchin eggs and embryos contain translatable mRNA of three general classes: poly(A)⁺ mRNA, poly(A)^? histone mRNA, and poly(A)^? nonhistone mRNA. Additionally, some histone synthesis appears to be promoted by poly(A)⁺ RNA. Sea urchin eggs seem to contain a higher proportion of prevalent poly(A)^? nonhistone mRNAS than do embryos. Some differences in the proteins encoded by poly(A)⁺ and poly(A)^? RNAs are detectable. Many coding sequences in the egg appear to be represented in both poly(A)⁺ and poly(A)^? RNAs, since the translation products of the two RNA classes exhibit many common bands when run on one-dimensional polyacrylamide gels. However, some of this overlap is probably due to fortuitous comigration of nonidentical proteins. Distinct stage-specific changes in the spectra of prevalent translatable mRNAs of all three classes occur, although many mRNAs are detectable throughout early development. Particularly striking is the presence of an egg poly(A)^? mRNA, encoding a 70,000–80,000 molecular weight protein, which is not detected in morula or later-stage embryos. In amphibian (Xenopus laevis and Triturus viridescens) ovary RNA, the translation assay detects the following three mRNA classes: poly(A)⁺ nonhistone mRNA, poly(A)^? histone mRNA, and poly(A)⁺ histone mRNA. Amphibian ovary RNA appearently lacks an abundant poly(A)^? nonhistone mRNA component of the magnitude detectable in sea urchin eggs. mRNA encoding histone-like proteins is found in the very earliest (small stage 1) oocytes of Xenopus as well as in later stage oocytes. During oogenesis there appear to be no striking qualitative changes in the spectra of prevalent translatable mRNAs which are detected by the cell-free translation assay.     

Rates of synthesis of major classes of RNA in Drosophila embryos.

We have been successful in labeling to high specific activity (3 × 10⁵ dpm/μg) the RNA synthesized by large numbers of Drosophila embryos. Embryos of various developmental stages were rendered permeable with octane and labeled with [³H]uridine for 1 hr. At each stage the total dpm incorporated into RNA and the specific activity of the UTP pool were measured and used to calculate the absolute rate of RNA synthesis per embryo. This rate increases during embryonic development, from 1 pmole UTP/hr at 2 hr after oviposition to 6 pmoles UTP/hr at 15 hr. The rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNAs were determined by analyzing the fractionated RNAs from each stage by sucrose gradient sedimentation. There is a significant activation of nuclear RNA synthesis at the blastoderm stage (approximately 2 hr after oviposition). After blastoderm, the rates of synthesis of nuclear and cytoplasmic poly(A)^? and poly(A)⁺ RNA per embryo increase continuously; the rate of synthesis of each of these classes per nucleus, however, remains fairly constant. After making corrections for turnover during the labeling period, we find that the rates of synthesis of the major classes of RNA per nucleus at the gastrula stage are: cytoplasmic poly(A)⁺ RNA, 0.06 fg/nucleus-min; hnRNA, 0.86 fg/nucleus-min; and ribosomal RNA, 0.46 fg/nucleus-min. These rates are compared to rates of RNA synthesis in sea urchin embryos.     

Identification and characterization of the poly(A)-binding proteins from the sea urchin: a quantitative analysis.

Poly(A)-binding proteins (PABPs) are the best characterized messenger RNA-binding proteins of eucaryotic cells and have been identified in diverse organisms such as mammals and yeasts. The in vitro poly(A)-binding properties of these proteins have been studied intensively; however, little is known about their function in cells. In this report, we show that sea urchin eggs have two molecular weight forms of PABP (molecular weights of 66,000 and 80,000). Each of these has at least five posttranslationally modified forms. Both sea urchin PABPs are found in approximately 1:1 ratios in both cytoplasmic and nuclear fractions of embryonic cells. Quantification in eggs and embryos revealed that sea urchin PABPs are surprisingly abundant, composing about 0.6% of total cellular protein. This is 50 times more than required to bind all the poly(A) in the egg based on the binding stoichiometry of 1 PABP per 27 adenosine residues. We found that density gradient centrifugation strips PABP from poly(A) and therefore underestimates the amount of PABP complexed to poly(A)+ RNA in cell homogenates. However, large-pore gel filtration chromatography could be used to separate intact poly(A)-PABP complexes from free PABP. Using the gel filtration method, we found that the threefold increase in poly(A) content of the egg after fertilization is paralleled by an approximate fivefold increase in the amount of bound PABP. Furthermore, both translated and nontranslated poly(A)+ RNAs appear to be complexed to PABP. As expected from the observation that PABPs are so abundant, greater than 95% of the PABP of the cell is uncomplexed protein.     

Isolation and sequence analysis of sea urchin (Lytechinus pictus) histone H4 messenger RNA

Histone messenger RNAs isolated from early blastula stage Lytechinus pictus sea urchin embryos have been separated into discrete RNA bands on polyacrylamide gels. The most rapidly migrating of these molecules, the putative histone H4 mRNA, has been digested with T₁ ribonuclease to generate oligonucleotides for nucleotide sequence analysis. Many of these sequences are colinear with the highly conserved amino acid sequence of histone H4 protein as determined for both cows and peas.Histone H4 messenger RNA hybridizes in conditions of DNA excess to sea urchin DNA which is repeated approximately 470-fold. Despite this level of repetition the nucleotide sequence of the H4 messenger RNA reflects little evolutionary divergence within the H4 genes of L. pictus as judged by the stoichiometric yield of T₁ oligonucleotides and the hybridization and thermal stability of histone H4 mRNA-DNA hybrids.     

Timing of initiation of polyadenylation of preformed RNA in sea urchin and Urechis caupo zygotes

An increase in the synthesis of polyadenylic acid, following fertilization, was examined in sea urchin, Strongylocentrotus purpuratus, and the marine worm Urechis caupo embryos. It was found that in both organisms there is a large increase in the incorporation of [³H]adenosine into the poly(A) region, of poly(A)-containing RNA, in the phase preceding the 2-cell stage. In sea urchin this rise was localized to the G₂ period. Similar findings were made in Urechis indicating that polyadenylation of RNA may be a common postfertilization event in many developing organisms.     

Messenger ribonucleoprotein particles in developing sea urchin embryos

Messenger RNA entering polysomes during early development of the sea urchin embryo consists of both oogenetic and newly transcribed sequences. Newly transcribed mRNA enters polysomes rapidly while oogenetic mRNA enters polysomes from a pool of stable, nontranslatable messenger ribonucleoprotein particles (mRNPs) derived from the unfertilized egg. Protein content may relate to differences in the regulation of newly transcribed and oogenetic mRNAs. Oogenetic poly(A)⁺ mRNA was found to be present in both polysomal and subpolysomal fractions of cleavage stage and early blastula stage embryos. This mRNA was found to be present in subpolysomal mRNPs with a density of 1.45 g/cm³ in Cs₂SO₄. Poly(A)⁺ mRNPs released from polysomes of embryos cultured in the presence of actinomycin D sedimented in a broad peak centered at 55 S and contained RNA of 21 S. The density of these particles was sensitive to the method of release; puromycin-released mRNPs had a density of 1.45 g/cm³, while EDTA caused a shift in density to 1.55 g/cm³, indicating a partial loss of protein. The results with newly synthesized mRNAs contrast sharply. Newly transcribed mRNA in subpolysomal mRNPs had a density of 1.55–1.66 g/cm³, a density approaching that of deproteinized RNA. Messenger RNA released from polysomes either by EDTA or puromycin was examined to determine the possible existence of polysomal mRNPs. When [³H]uridine-labeled mRNA was released from late cleavage stage embryo polysomes by either technique, and centrifuged on sucrose gradients, two broad peaks were found. One peak centered at 30 S contained 21 S mRNA while the other at 15 S contained 9 S histone mRNA. When these fractions were fixed with formaldehyde, they banded on Cs₂SO₄ gradients at a density of 1.60–1.66 g/cm³, very similar to that of pure RNA. We conclude that the newly transcribed mRNA may be present in stable mRNPs containing up to 10% protein in either subpolysomal or polysomal fractions. These mRNPs are clearly distinguishable from the protein-rich mRNPs containing oogenetic mRNAs.     

Mitochondrial regulation in sea urchins. III. Rapid degradation of mitochondrial RNA in association with a failure to form mitochondrial polyribosomes in eggs activated with ionophore A 23187.

Most of the biochemical changes which have been examined in eggs of sea urchins, following activation with ionophore A-23187, parallel those events which have been observed to occur after fertilization. However, the results reported here indicate that mitochondrial polyribosomes fail to form after ionophore activation of either nucleate or anucleate fragments of eggs of the sea urchin. The results also demonstrate that ionophore activation does not impair the ability of eggs to generate ATP within the subsequent 2.5 h and thus the absence of mitochondrial protein synthesis appears not to be responsible for the failure of ionophore activated eggs to divide. Studies of the rates of uptake and incorporation of [³H]uridine into nucleic acid within ionophore activated anucleate fragments suggest that the rates of synthesis and degradation for both messenger and ribosomal “like” RNAs reach equilibrium within 5 min after the addition of isotope to the cultures, demonstrating that the half-lives of newly synthesized mitochondrial RNAs may be relatively brief in the absence of polyribosome formation. These results support and extend the conclusion of Lambowitz et al. [42] which suggests that ribosomal proteins may be important for stabilization of at least one of the mitochondrial ribosomal RNAs.