Biochemical studies of mammalian oogenesis: synthesis and stability of various classes of RNA during growth of the mouse oocyte in vitro

The synthesis of various classes of RNA in mouse oocytes at different stages of growth has been examined after incubating follicles in medium containing radiolabeled uridine. After fractionation on poly(U)-Sepharose of radiolabeled oocyte RNA, of which about 83% is associated with the nucleus after a 5-hr labeling period, revealed that about 40–50% of the radiolabeled RNA behaved as poly(A)-containing RNA. This value remained fairly constant during the period of oocyte growth in which oocyte diameter increased from about 35 to about 55 μm. After a 5-hr labeling, the percentage of radiolabeled poly(A)-containing RNA in either the fully grown dictyate oocyte, metaphase II oocyte, or one-cell embryo was about 20%. After a 5-hr labeling, agarose gel electrophoretic analysis of the radiolabeled species of oocyte RNA obtained after fractionation on poly(U)-Sepharose revealed the presence of a putative ribosomal RNA precursor, ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA and heterodisperse poly(A)-containing RNA. A significant fraction of the radiolabeled RNA species was quite large (>40 S). The ratios of the relative proportions of the radiolabeled ribosomal RNAs and transfer plus 5 S RNA remained essentially constant during oocyte growth. The stability of various classes of RNA was examined by incubating follicles with radiolabeled uridine, washing the follicles free of radioactivity and culturing the follicles under conditions which support oocyte growth in vitro (Eppig, 1977). Under these conditions, total oocyte radiolabeled RNA was quite stable as determined by retention of acid-insoluble radioactive material ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 28}\text{days}$). However, under conditions in which oocytes are viable but do not grow, the half-life of total RNA was about 4.5 days. Poly(A)-containing RNA was also very stable; after 8 days in culture, about 50% of the radiolabeled poly(A)-containing RNA present after 5 hr of labeling was still present. Agarose gel electrophoretic analysis of radiolabeled RNA in oocytes after 4 days of culture and after fractionation on poly(U)-Sepharose revealed the presence of ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA, and heterodisperse poly(A)-containing RNA. At this time, these RNAs are located in the oocyte cytoplasm. In addition, the molecular weight distribution of poly(A)-containing RNA was significantly lower than that after 5 hr of labeling. The ratios of the relative proportions of radiolabeled ribosomal RNAs and transfer plus 5 S RNA were quite similar to those after 5 hr of labeling.     

Biochemical studies of mammalian oogenesis: kinetics of accumulation of total and poly(A)-containing RNA during growth of the mouse oocyte

Kinetics of accumulation of total and poly(A)-containing RNA have been measured during growth of the mouse oocyte. Total RNA from oocytes isolated at discrete stages of growth was determined by two independent microassays. The full-grown oocyte contained about 0.60 ng of RNA. Kinetics of accumulation of total RNA with respect to oocyte volume were biphasic. Small, growing oocytes (about 30 pl) contained about 0.20 ng of RNA/oocyte. The amount of RNA increased in a quasi-linear fashion until oocyte volume was about 160 pl, at which point there was about 0.57 ng of RNA/oocyte. Thus oocytes about 65% of their final volume had accumulated about 95% of the total amount of RNA present in the fully-grown oocyte. The relative amount of poly (A)-containing RNA in oocytes of various size was determined by in situ hybridization of [3H] poly (U) to ovarian sections from juvenile mice of known age, followed by autoradiography. The kinetics of accumulation of poly (A)-containing RNA were similar to those of total RNA; oocytes about 70% of their final volume had accumulated about 95% of the amount of poly (A)-containing RNA present in the fully-grown oocyte. The poly(A)-containing RNA resided predominantly in the cytoplasm and no obvious cytoplasmic localization was observed. Kinetics of accumulation of total RNA, which is mainly ribosomal, and poly (A)-containing RNA were consistent with levels of RNA polymerases I and II measured by others during oocyte growth (Moore and Lintern-Moore, '78). The number of ribosomes that could be made from the amount of rRNA present at various stages of growth was compared to the actual number of ribosomes calculated from a published morphometric study (Garcia et al., '79). Kinetic differences in accumulation between the theoretical and actual number of ribosomes suggested oocyte ribosomes are recruited into cytoplasmic lattice structures. These structures accumulate during oocyte growth and have been postulated to be a ribosomal storage form. In addition, the results from this study are compared to results derived from lower species.     

Polyadenylic acid-containing RNA and its polyadenylic acid sequences newly synthesized in isolated embryonic cells of Xenopus laevis.

Newly synthesized polyriboadenylic acid [poly(A)]-containing RNA and its poly(A) sequences were isolated and characterized in Xenopus embryonic cells. Upon sedimentation analysis, the poly(A)-containing RNA labeled for 30 min showed a very heterogeneous size distribution ranging from 9 to >40 S. After 5 hr of labeling, the profile became much less heterogeneous and the main component was distributed in the 9–28 S region. The average molecular weight of 6.5–7.0 × 10⁵ daltons was calculated for the 5-hr labeled RNA. This poly(A)-containing RNA, comprising about 10% of the total labeled RNA, was metabolically stable and accumulated linearly for 5 hr. Gel electrophoresis of the RNA revealed the presence of little or no free poly(A) sequences. Most of the poly(A) sequences, which were isolated from 30-min labeled poly(A)-containing RNA migrated as a single discrete component approximately 150 nucleotides long. In contrast, they were slightly smaller (130 nucleotides long) and more heterogeneous, when obtained from the poly(A)-containing RNA labeled for 5 hr. From these results, it may be likely that the embryonic poly(A)-containing RNA is similar in size to the steady-state population of the poly(A)-containing RNA reported to occur in vitellogenic oocytes and cultured kidney cells of the same species.     

A simple method for electrophoretic selection and fractionation of poly(A)-containing RNA and poly(A).

A simple procedure, useful for quantitative and qualitative assays of poly(A)-containing RNA and poly(A), as well as for preparative purposes, is described. Glass-fiber filters with immobilized poly(U), a well-known technique for absorption of poly(A)-containing RNA, is combined with electrophoresis in a gel slab of agarose. In front of each of the two troughs in a gel slab, glass-fiber filters are inserted, one of which is impregnated with poly(U). Two identical RNA samples, e.g., split samples of total RNA from salivary glands of Chironomus tentans, are applied to the troughs and are moved electrophoretically across two different filters. The electrophoresis is conducted under conditions which promote the formation of duplexes between absorbed poly(U) and moving poly(A). While the passage of RNA chains across the control filter may take place essentially freely, RNA molecules that contain poly(A) hybridize with poly(U) fixed in the glass-fiber filter and become trapped there. The difference between resulting gel profiles [pattern of the total RNA minus the pattern of RNA not containing poly(A)] yields the electrophoretic distribution of poly(A)-containing RNA. In addition, poly(A)-containing RNA can be eluted from the poly(U) filter with formamide and subjected to electrophoresis without a subsequent precipitation in ethanol. No measurable quantities of ribosomal RNA or tRNA are retained on the poly(U) glass-fiber filters. The hybridization technique enables a quantitative retention of poly(A) molecules representing a wide range of chain lengths.     

Differential accumulation of two size classes of poly(A) associated with messenger RNA during oogenesis in Xenopus laevis

The RNA of full-grown oocytes of Xenopus laevis contains two distinct size classes of poly(A), designated poly(A)_S and poly(A)_L, which contain 15–30 (mean = 20) and 40–80 (mean = 61) A residues, respectively. Both poly(A)_L and poly(A)_S are associated with RNA which is heterogeneous in size. The two classes of poly(A)⁺ RNA can be separated by affinity chromatography: Only poly(A)_L⁺ RNA binds to oligo(dT)-cellulose under appropriate conditions, but up to 50% of the poly(A)_S⁺ RNA can be isolated from the void fraction by binding to poly(U)-Sepharose. Both classes of poly(A)⁺ RNA are active as messenger RNA in an in vitro system and yield identical patterns of in vitro protein products. Previtellogenic oocytes contain almost exclusively poly(A)_L, which accumulates up to vitellogenesis but remains almost constant in amount (molecules/oocyte) during vitellogenesis and in the full-grown oocyte. Poly(A)_S accumulates (molecules/oocyte) from early vitellogenesis up to the full-grown oocyte. The total number of poly(A)⁺ RNA molecules per oocyte increases throughout oogenesis from 2 × 10¹⁰/previtellogenic oocyte [80–90% poly(A)_L] to 20 × 10¹⁰/full-grown oocyte (25–40% poly(A)_L). It is argued that poly(A)_S is protected from degradation in the oocyte, thus stabilizing the “maternal” poly(A)⁺ mRNA.     

Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

A transient accumulation of poly(A)-containing RNA in the tapetum of Hyoscyamus niger during microsporogenesis

The distribution of poly(A)-containing RNA in the tapetal cells of Hyoscyamus niger during microsporogenesis was followed by in situ hybridization with [³H]poly(U) as a probe. Although no poly(A)-containing RNA accumulated in the premeiotic tapetum, [³H]poly(U) binding sites were detected in the tapetum as meiosis was completed in the microsporocytes. Accumulation of poly(A)-containing RNA in the tapetal cells reached a peak before the first haploid mitosis in the pollen grains. With the onset of tapetal senescence at the late uninucleate stage of the pollen grain, [³H]poly(U) binding sites gradually decreased and they completely disappeared in the tapetum at the binucleate pollen stage. The significance of the results is discussed, particularly with regard to the possible role of tapetum in the synthesis of informational macromolecules during microsporogenesis.     

Degradation of maternal poly(A)-containing RNA during early embryogenesis of an insect (Smittia spec., chironomidae,diptera)

Summary Eggs of the chironomid midgeSmittia spec. were shown to contain maternal rRNA, tRNA and poly(A)-containing RNA. The ribonucleoprotein spectrum consisted of monosomes, ribosomal subunits, and subribosomal particles, whereas polysomes could be detected only in small amounts. Poly(A)-containing RNA was found in different regions of the RNP spectrum, mainly between 15 S and 60 S. After labelling maternal RNA by feeding tritiated uridine to the larvae, the radioactivity associated with poly(A)-containing RNA accounted for about 4% of the label in the total RNA extracted from newly deposited eggs. About half of the radioactivity in the poly(A)-containing RNA was lost between egg deposition and an advanced blastoderm stage. The loss was accompanied by both a decrease in the size of the poly(A)-containing RNA molecules and a shift of poly(A)-containing RNP particles to less dense regions in sucrose gradients. Comparison with poly(A)-containing RNA synthesized by the embryo indicates that the reduction in size of maternal poly(A)-containing RNA is not artifactual but reflects its degradation after the formation of blastoderm.     

5'-terminal structures of poly(A)+ cytoplasmic messenger RNA and of poly(A)+ and poly(A)- heterogeneous nuclear RNA of cells of the dipteran Drosophila melanogaster.

Structures at the 5′ terminus of poly (A)-containing cytoplasmic RNA and heterogeneous nuclear RNA containing and lacking poly(A) have been examined in RNA extracted from both normal and heat-shocked Drosophila cells. ³²P-labeled RNA was digested with ribonucleases T₂, T₁ and A and the products fractionated by a fingerprinting procedure which separates both unblocked 5′ phosphorylated termini and the blocked, methylated, “capped” termini, known to be present in the messenger RNA of most eukaryotes.Approximately 80% of the 5′-terminal structures recovered from digests of poly(A)-containing Drosophila mRNA are cap structures of the general form m⁷G^5′ppp^5′X(m)pY(m)pZp. With respect to the extent of ribose methylation and the base distribution, the 5′-terminal sequences of Drosophila capped mRNA appear to be intermediate between those of unicellular eukaryotes and those of mammals. Drosophila is the first organism known in which type 0 (no ribose methylations), type 1 (one ribose methylation), and type 2 (two ribose methylations) caps are all present. In contrast to mammalian cells, the caps of Drosophila never contain the doubly methylated nucleoside N⁶,2′-O-dimethyladenosine. Both purines and pyrimidines can be found as the penultimate nucleoside of Drosophila caps and there is a wide variety of X-Y base combinations. The relative frequencies of these different base combinations, and the extent of ribose methylation, vary with the duration of labeling. The large majority of poly(A)-containing cytoplasmic RNA molecules from heat-shocked Drosophila cells are also capped, but these caps are unusual in having almost exclusively purines as the penultimate X base.Greater than 75% of the 5′ termini of heterogeneous nuclear RNA (hnRNA) containing poly(A) and greater than 50% of the termini of hnRNA lacking poly (A) are also capped. Triphosphorylated nucleotides, common as the 5′ nucleotides of mammalian hnRNA, are rare in the poly(A)-containing hnRNA of Drosophila. The frequency of the various type 0 and type 1 cap sequences of cytoplasmic and nuclear poly (A)-containing RNA are almost identical. The caps of hnRNA lacking poly(A) are also quite similar to those of poly-adenylated hnRNA, but are somewhat lower in their content of penultimate pyrimidine nucleosides, suggesting that these two populations of molecules are not identical.     

A small nuclear precursor of messenger RNA in the cellular slime mold Dictyostelium discoideum

Previous work (Firtel et al., 1972) showed that messenger RNA from the cellular slime mold Dictyostelium discoideum, like that from mammalian cells, contains a sequence of about 100 adenylic acid residues at the 3′ end. We show here that Dictyostelium nuclei, labeled under a variety of conditions, do not contain material analogous to the large nuclear heterogeneous RNA found in mammalian cells. Rather, the majority of pulse-labeled nuclear RNA that is not a precursor of ribosomal RNA does contain at least one sequence of polyadenylic acid; this RNA, with an average molecular weight of 500,000, appears to be only 20% larger than cytoplasmic messenger RNA.Pulse-labeling experiments show that the nuclear poly(A)-containing RNA is a material precursor of messenger RNA. Whereas previous work showed that over 90% of messenger RNA sequences are transcribed from non-reiterated DNA, we show here that about 25% of nuclear poly (A)-containing RNA is transcribed from reiterated DNA sequences and only 75% from single-copy DNA. We present evidence that a large fraction of the nuclear poly(A)-containing RNA contains, at the 5′ end, a sequence of about 300 nucleotides that is transcribed from repetitive DNA, and which is lost before transport of messenger RNA into the cytoplasm.Based on these and other results, we present a model of arrangement of repetitive and single-copy DNA sequences in the Dictyostelium chromosome.     

Comparison of cytoplasmic and nuclear poly(A)-containing RNA sequences in Xenopus liver cells.

Poly(A)-containing RNAs from cytoplasm and nuclei of adult Xenopus liver cells are compared. After denaturation of the RNA by dimethysulfoxide the average molecule of nuclear poly(A)-containing RNA has a sedimentation value of 28 S whereas the cytoplasmic poly(A)-containing RNA sediments slightly ahead of 18 S. To compare the complexity of cytoplasmic and nuclear poly(A)-containing RNA, complementary DNA (cDNA) transcribed on either cytoplasmic or nuclear RNA is hybridized to the RNA used as a template. The hybridization kinetics suggest a higher complexity of the nuclear RNA compared to the cytoplasmic fraction. Direct evidence of a higher complexity of nuclear poly(A)-containing RNA is shown by the fact that 30% of the nuclear cDNA fails to hybridize with cytoplasmic poly(A)-containing RNA. An attempt to isolate a specific probe for this nucleus-restricted poly(A)-containing RNA reveals that more than 10(4) different nuclear RNA sequences adjacent to the poly(A) do not get into the cytoplasm. We conclude that a poly(A) on a nuclear RNA does not ensure the transport of the adjacent sequence to the cytoplasm.     

Identification and genetic localization of mRNAs from ovarian follicle cells of Drosophila melanogaster.

RNA synthesis in ovarian follicles of Drosophila melanogaster was studied by methods which eliminate experimentally induced alterations in gene expression. Gel electrophoresis of follicular RNA, labeled after injection of precursors into females, revealed qualitative and quantitative differences in synthesis during the course of oogenesis. A highly heterogeneous group of poly(A)-containing RNAs is produced during much of the course of follicular development. However, post-vitellogenic stages synthesize a small number of stage-specific poly(A)-containing RNAs. During this period, RNA synthesis is known to take place primarily in the follicle cells, which are engaged in the production of the endochorion and exochorion. Two intense bands of nonmitochondrial poly(A)⁺ RNA are labeled between stage 11 and early stage 13. The synthesis of a more heterogeneous group of very small poly(A)-containing RNAs characterizes the last part of oogenesis, stages 13 and 14. Evidence is presented to show that these RNAs are specifically localized in the follicle cells of the egg chamber. We propose that they represent mRNAs for chorion proteins. In situ hybridization of preparations of late stage poly(A)-containing RNA to salivary gland chromosomes revealed two major sites of complementarity, 7E11 and 12E, as well as several minor sites. Experiments in which RNAs were separated on gels prior to hybridization in situ suggested that both the major stage 12-specific RNA bands contained molecules which were complementary to DNA in the 7E11 region. It is particularly interesting that this site is within a small chromosomal interval known to contain the gene ocelliless. Females homozygous for ocelliless have been shown to produce structurally abnormal chorions (Johnson and King, 1974).     

RNA synthesis in whole cells and protoplasts of centaurea: a comparison

Protoplasts enzymically isolated from suspension cultures of Centaurea cyanus L. incorporate radioactive precursors into RNA with kinetics similar to that of whole cells. There are differences, however, in several other aspects of RNA metabolism. The proportion of total RNA that contains poly(A) sequences (25 to 30%) is similar in both freshly isolated protoplasts and whole cells after a 20-minute pulse with [³H]adenosine. After a 4-hour pulse, however, poly(A)-containing RNA makes up 30% of the total RNA in protoplasts whereas it drops to 8% in whole cells. There appears to be a faulty processing of ribosomal precursor into the mature ribosomal species, as the precursor seems to accumulate to higher levels relative to the mature 18S and 25S rRNAs in protoplasts as compared to whole cells. Additional differences are seen in the size distributions of poly(A)-containing RNA, although the length of the poly(A) segment is similar in both protoplasts and whole cells. Within 24 hours protoplasts appear to have resumed a pattern of RNA synthesis similar to that of whole cells.     

The size of poly(A)-containing RNAs in Drosophila melanogaster embryos

The size range of poly(A)-containing RNA from Drosophila melanogaster embryos has been estimated by hybridization with ³H-labeled poly(U) and subsequent fractionation on sucrose gradients. The median size of nuclear poly(A)-containing RNA is about 30 S (6000 nucleotides), and the median size of cytoplasmic poly(A)-containing RNA is about 17 S (1800 nucleotides). The relationship of these sizes to messenger RNA needed to code for protein and to the length of DNA contained in a chromomere is discussed.Research grant support was provided by NIH (6M35558; HD-00266) and NSF (GB-30600).     

The synthesis of polyadenylic acid-containing ribonucleic acid by isolated mitochondria from Ehrlich ascites cells.

The synthesis of poly(A)-containing RNA by isolated mitochondria from Ehrlich ascites cells was studied. Isolated mitochondria incorporate [3H]AMP or [3H]UTP into an RNA species that adsorbs on oligo (dT)-cellulose columns or Millipore filters. Hydrolysis of the poly(A)-containing RNA with pancreatic and T1 ribonucleases released a poly(A) sequence that had an electrophoretic mobility slightly faster than 4SE. In comparison, ascites-cell cytosolic poly(A)-containing RNA had a poly(A) tail that had an electrophoretic mobility of about 7SE. Sensitivity of the incorporation of [3H]AMP into poly(A)-containing RNA to ethidium bromide and to atractyloside and lack of sensitivity to immobilized ribonuclease added to the mitochondria after incubation indicated that the site of incorporation was mitochondrial. The poly(A)-containing RNA sedimented with a peak of about 18S, with much material of higher s value. After denaturation at 70 degrees C for 5 min the poly(A)-containing RNA separated into two components of 12S and 16S on a 5-20% (w/v) sucrose density gradient at 4 degrees C, or at 4 degrees and 25 degrees C in the presence of formaldehyde. Poly(A)-containing RNA synthesized in the presence of ethidium bromide sedimented at 5-10S in a 15-33% (w/v) sucrose density gradient at 24 degrees C. The poly(A) tail of this RNA was smaller than that synthesized in the absence of ethidium bromide. The size of the poly(A)-containing RNA (approx. 1300 nucleotides) is about the length necessary for that of mRNA species for the products of mitochondrial protein synthesis observed by ourselves and others.     

RNA metabolism and membrane-bound polysomes in relation to globulin biosynthesis in cotyledons of developing field beans (Vicia faba L.).

In cotyledon cells of developing field beans the RNA content per cell does not change in the second half of developmental period 2, whereas globulin biosynthesis continues. The constant RNA content per cell results from an equilibrium between RNA synthesis and degradation. All types of RNA are synthesized until the end of globulin biosynthesis, but poly(A)-containing RNA was preferentially labelled during maximum globulin formation. During stage 2 of seed development of poly(A)-containing RNA fraction represents a discrete peak in the 12--18-S region on agarose gels and corresponds to the peak of poly(A)-containing RNA isolated from polysomes. alpha-Amanitin inhibits selectively the labelling of poly(A)-containing RNA and concomitantly globulin formation. Translation of total poly(A)-containing RNA, free and membrane-bound polysomes in a cell-free wheat germs demonstrates that the globulins are preferentially produced on membrane-bound polysomes and that poly(A)-containing RNA includes the mRNA for both vicilin and legumin.     

Comparison of poly(A)-containing RNAs in different cell types of the lower eukaryote Schizophyllum commune

Poly(A)-containing RNAs were isolated from morphologically different cells of the fungus Schizophyllum commune. Using mRNA markers the number-average length of poly(A)-containing RNA in total RNA and in purified poly(A)-containing RNA was estimated as 1100 nucleotides. Number-average length of poly(A)-tracts was 33 nucleotides. 2.5% of total RNA is poly(A)-containing RNA and probably up to 7.5% are non-polyadenylated polydisperse RNA sequences. Saturation hybridization of poly(A)-containing RNA to gap-translated [3H]DNA resulted in 16% of the reactive single-copy DNA to become S1 nuclease resistant. It was found that purified poly(A)-containing RNA represented the entire RNA complexity, i.e. 10 000 different RNA sequences in S. commune. RNA sequences isolated from morphologically different mycelia and from fruiting and non-fruiting mycelia were identical for at least 90%.