Evidence for differential regulation of two classes of poly(A) RNA inBlastocladiella emersonii zoospores

The poly(A) RNA in zoospores ofBlastocladiella emersonii contains RNA synthesized during the growth phase (GP poly(A) RNA) and late sporulation (LS poly(A) RNA). LS poly(A) RNA synthesized during the final 30 minutes of sporulation is bound exclusively to polyribosomes which comprise approximately 50% of the total zoospore ribosome population. In contrast, GP poly(A) RNA is bound to zoospore monoribosomes. During the final 30 minutes of sporulation, GP poly(A) RNA which is bound to polyribosomes makes a transition to monoribosomes. Zoospore monoribosomes and RNA extracted from zoospore monoribosomes are inactivein vitro while both zoospore polyribosomes and RNA extracted from zoospore polyribosomes stimulate protein synthesis in the wheat germin vitro system. Sedimentation of poly(A) RNA from zoospore monoribosomes on dimethyl sulfoxide gradients revealed that the GP poly(A) RNA was of sufficiently high molecular weight to code for average-sized proteins. These denaturing gradients failed to activate the zoospore monoribosome RNA. The results suggest that the inability to translate zoospore monoribosomesin vitro is due to some property or modification of the zoospore monoribosome poly(A) RNA. Zoospore monoribosomes bound to poly(A) RNA contain an average of two tRNA molecules while zoospore polyribosomes have an average of less than one tRNA bound. This suggests the two classes of ribosomes are blocked at different steps in the elongation process.     

The polyadenylated RNA of zoospores and growth phase cells of the aquatic fungus,Blastocladiella

The stored poly(A) + RNA from zoospores of the aquatic fungus Blastocladiella emersonii represents 2.5% of the total RNA and has a model MW of 425,000 daltons and an average poly(A) isostich of 32 bases. The poly(A) + RNA also represents 2.5% of the total RNA from early growth phase cells and has a modal MW of 360,000 daltons and an average poly(A) isostich of 38 bases. The poly(A) + RNA from spores and 2-hr plants contains a structure resistant to RNases T₁, T₂, and A, which can be labeled with ³²PO₄ and which will bind to DBAE-cellulose. These characteristics strongly suggest that both the zoospore poly(A) + RNA and the 2-hr cell poly(A) + RNA are capped at the 5′ end; and, hence, it is unlikely that capping is involved in the control of protein synthesis during germination.Approximately 80% of the poly(A) + RNA of the spore is located in the membrane-enclosed ribosomal nuclear cap, and more than 90% of the poly(A) + RNA within the cap is found in the 80S monoribosome and heavier fractions.Synthesis of new poly(A) + RNA occurs very early during zoospore germination, and the labeled poly(A) + RNA rapidly enters the newly organized polysomes. The labeling data for early germination also suggest that cytoplasmic polyadenylation occurs.     

Gene expression during development of Blastocladiella emersonii

To evaluate gene expression during sporulation and early development of the aquatic fungus Blastocladiella emersonii, the nucleotide sequence complexity of the polysomal RNA has been measured at different stages. To assess the effect of medium composition on gene expression, similar experiments were completed during early development in a range of simple to complex media. The polysomal RNA sequence complexity was measured by hybridization with single-copy tracer DNA and with a complex class-enriched cDNA fraction copied from the stored zoospore poly(A⁺)RNA. Forty-four to eighty-six percent (8.2 × 10⁶ to 16 × 10⁶ nucleotides) of the single-copy DNA sequence complexity was found on polysomes, depending upon the stage examined or the medium used, compared to 42.5% (8 × 10⁶ nucleotides) in the stored RNA pool of zoospores. The highest levels of complexity occurred during the two periods of active differentiation, sporulation and germination. During starvation-induced sporulation, and average of 82% of the total asymmetrically transcribed complexity was expressed; half of this complexity was lost prior to the completion of zoospore differentiation and was missing from the zoospore-stored RNA pool. During the first 30 min of zoospore germination the level of sequence complexity increased by 46 to 66% over the zoospore level, depending upon the medium used. The polysomal RNA complexity then decreased by a nearly equal amount between 30 and 60 min when the cells entered the growth phase. An inverse relationship was found between the richness of the medium and the level of sequence complexity found on polysomes. The data indicate that sequences representative of most of the zoospore-stored poly(A+)RNA were expressed at all other stages and maintained by turnover and resynthesis. In addition, significant numbers of new sequences were also expressed, particularly during stages of active differentiation. Cells that germinated and completed early development in an inorganic starvation medium showed a marked loss of the middle and high abundance classes of poly(A⁺)RNA and slight enrichment for the low abundance class.     

Metabolism of polyadenylic acid sequences during germination of blastocladiella emersoni: Zoospores.

The metabolism of the poly(A) sequences isolated from Blastocladiella emersonii was followed during the first hour of germination. Poly (A) sequences synthesized during the first 30 min of germination do not undergo detectable changes in size. During the first 45 min of germination, poly(A) sequences synthesized during zoosporogenesis decrease in size to the extent that there is essentially no size overlap between poly(A) fragments which were present in the zoospore and newly synthesized poly(A) sequences. The results presented indicate that during germination, polyadenylation occurs in RNA molecules which were present in the zoospore but lacked poly(A) sequences. No detectable size differences were observed between poly(A) sequences added to newly synthesized RNA compared to those added to the nonpolyadenylated RNA present in the zoospore during germination. Cycloheximide did not prevent the observed decrease in size of the poly(A) sequences during germination.     

Studies on the nature and role of polyadenylated RNA in spore development of Bacillus subtilis

Summary cDNA probes synthesized on poly(A)RNAs isolated from sporulating cells of Bacillus subtilis were used for hybridization studies with RNAs derived from cells at different stages of growth and sporulation. It was shown that these cDNAs hybridized only to RNA from sporulating cells. No hybridization was observed if total RNA isolated from vegetative cells or from stationary phase cells of a zero stage asporogenic mutant was used. The hybridization studies also indicate that at each sporulation stage different poly(A)RNA species are synthesized. Furthermore, the hybridization kinetics have clearly demonstrated the existence of three distinct abundance classes of poly(A)RNA similar to those observed in eukaryotic cells. BamHI endonuclease restriction fragments of B. subtilis DNA that were found to hybridize to labeled poly(A)RNA were ligated to the pHV33 vector and hybrid clones that hybridized efficiently to poly(A)RNA were selected. Among these, three have been found to carry the spoOB gene.These results strongly suggest that the appearance of poly(A)RNA can be correlated to the expression of spore genes.     

Onset of ribosome degradation during cessation of growth in BHK-21/C13 cells.

When BHK-21/C13 cells growing exponentially in 10% serum are transferred to a medium containing only 0.25% serum, cell growth is decreased. After initial changes in RNA synthesis and degradation, protein content of the cultures reaches a plateau and eventually DNA synthesis is arrested. rRNA is relatively stable in exponentially growing cells. Immediately after 'step-down' rRNA degradation commences, but poly(A)-containing RNA does not appear to be degraded any faster than in control cells. Reutilization of RNA precursors has been independently measured and amounts to less than 1%/h for rRNA, insufficient to influence the conclusion that rRNA degradation begins almost immediately after 'step-down'. The degree of reutilization of uridine is much greater for poly(A)-containing RNA than for poly(A)-free RNA.     

Protein synthesis and breakdown in the mother-cell and forespore compartments during spore morphogenesis in Bacillus megaterium

Recently developed techniques for isolating forespores from bacilli at all stages of spore morphogenesis have been exploited to investigate the contribution of each of the two compartments of the sporulating cell to the overall pattern of protein synthesis and degradation during sporulation in Bacillus megaterium. These studies have shown: (1) that protein synthesis continues in both compartments throughout spore morphogenesis; (2) that the degradation of proteins made at all times during vegetative growth and sporulation is confined to the mother-cell compartment; (3) that proteins synthesized in the mother-cell compartment during sporulation are subsequently degraded more rapidly than proteins synthesized during vegetative growth. This rate of degradation increases the later the proteins are synthesized in the sporulation sequence. Mature spores were disrupted, and the percentage of the total protein in soluble and particulate fractions was determined. Pulse-labelling experiments were performed to investigate the extent to which the proteins of these two fractions are newly synthesized during sporulation. These data were used to calculate the extent of capture of vegetative cell protein at the time of formation of the forespore septum. The value obtained is consistent with evidence from electron micrographs and supports a model for the origin of spore protein in which there is no protein turnover in the developing forespore.     

Synthesis of Ribosomal Ribonucleic Acid During Sporulation of Bacillus subtilis

The incorporation of radioactive uracil into 50s and 30s ribosomal subunits and ribosomal ribonucleic acid (rRNA) was studied during the growth cycle of different sporogenic and asporogenic strains of Bacillus subtilis. It was found that partially synchronized cultures of the strains examined incorporated labeled uracil into the two ribosomal subunit species and rRNA during sporulation and during the stationary phase of the asporogenic strains. Kinetic studies have shown that, compared to vegetative cells, the percentage of uracil incorporated into the ribosomal subunits of cells taken 30 min after the end of exponential growth was decreased by about 25 to 35%. This decrease, however, appeared to be a general characteristic of stationary-phase cells and seems to depend on the nature of the sporulation medium and to some extent on the nature of the strain but not on the sp(+) or sp(-) phenotype of the strain. Moreover, by use of actinomycin D it was shown that the labeled uracil incorporated, in the presence of the drug, during the sporulation period was located in the ribosomal subunits (stable RNA). Based on these results, we concluded that during sporulation ribosomal genes are transcribed and consequently rRNA continues to be synthesized, although to a lesser extent than during vegetative growth. These results are discussed in the light of those obtained by Hussey et al.     

Mobilization of newly synthesized RNAs into polysomes inXenopus laevis embryos

Summary The mobilization of newly synthesized 18S and 28S rRNAs, 4S RNA and poly(A)⁺ RNA into polysomes was studied in isolated cells ofXenopus laevis embryos between cleavage and neurula stages. Throughout these stages, 4S RNA and poly(A)⁺ RNA were mobilized immediately following their appearance in the cytoplasm. 18S rRNA however, stayed in the ribosomal subunit fraction for about 30 min until the 28S rRNA appeared, when the two rRNAs were mobilized together at an equimolar ratio. This mobilization, at a 1:1 molar ratio, appeared to be realized at initiation monome formation. Thus, the efficiency of the mobilization of two newly synthesized rRNAs, shortly after their arrival at the cytoplasm, differed considerably but difference disappeared once steady state was reached.The contribution of newly synthesized 18S and 28S rRNAs to polysomes remains small throughout early development. around 3% of newly synthesized 4S RNA is polysomal which is the same distribution observed for unlabeled 4S RNA. Less than 10% of the newly synthesized cytoplasmic poly(A)⁺ RNA was mobilized into polysomes during cleavage, but in later stages the proportion increased to around 20%–25%. These results show that newly synthesized RNAs are utilized for protein synthesis at characteristic rates soon after they are synthesized during early embryonic development. On the basis of the data presented here and elsewhere we discuss quantitative aspects of the utilization of newly synthesized and maternal RNAs during early embryogenesis.     

Poly(A)+ RNA metabolism during oogenesis in Xenopus laevis.

In this study, we have measured the synthesis and turnover of oligo(dT)cellulose-bound RNA [poly(A)⁺ RNA] in Xenopus laevis oocytes at the maximal lampbrush chromosome stage (stage 3) and at the completion of oocyte growth (stage 6). Oocytes at both stages are shown to be active in the synthesis of poly(A)⁺ RNA. In stage 6 oocytes, the mean rate of synthesis of stable poly(A)⁺ RNA is 15% the instantaneous rate of synthesis, while the mean half-life of the unstable component is 1.6 hr. In contrast, the instantaneous rate of synthesis in stage 3 oocytes is about one-third that seen in stage 6, and most of it is devoted to the production of unstable species with an average half-life of 5 hr. Studies on the nuclear versus the cytoplasmic distribution of the newly synthesized poly(A)⁺ RNA demonstrated that by the end of a 12-hr labeling period for stage 3 oocytes and a 24-hr labeling period for stage 6 oocytes, approximately half of the material was cytoplasmic. This cytoplasmic material had the same electrophoretic mobility as bulk poly(A)⁺ RNA. Similarly, as with bulk poly(A)⁺ RNA, little, if any, of the newly synthesized material was found to be polysomal. Also, poly(A) labeling studies indicated that the newly synthesized poly(A)⁺ RNA was associated with the synthesis of poly(A) of the same length as that appearing on bulk poly(A)⁺ RNA. Studies on the content of bulk oligo(dT)cellulose-bound RNA indicated that about 86 ng is present in both stage 3 and stage 6 oocytes. The continual synthesis of poly(A)⁺ RNA throughout oogenesis in the absence of its accumulation led to the conclusion that it must be turning over. These data are discussed in relation to the hypothesis that bulk levels of poly(A)⁺ RNA are maintained by continually changing rates of synthesis and degradation.     

Correlation among turnover of nucleic acids,ribonuclease activity and sporulation ability of Saccharomyces cerevisiae

The turnover of nucleic acids and changes in ribonuclease activity during sporulation of Saccharomyces cerevisiae were studied. In the sporulating strains, 37–58% of vegetatively synthesized RNA were degraded during the sporulation process. The degree of degradation of vegetative RNA was proportional to the sporulation ability. In the non-sporulating strains, the degradation of vegetative RNA was less than 28% in the sporulation medium. Accompanied by the degradation of vegetative RNA, a ribonuclease activity increased several times during sporulation. We have found a close relation among the sporulation rate, the degree of the degradation of vegetative RNA and the increase in ribonuclease activity in the sporulation medium, using cells of which sporulation ability was repressed by changing the age or carbon source in various degrees.     

Lipid turnover during morphogenesis in the water mold Blastocladiella emersonii

The lipid content of $\text{Blastocladiella emersonii}$ zoospores is 5 pg/cell or about 13% of dry weight. Within the first few minutes of germination 60–70% of total zoospore lipid is lost, with neutral lipid, glycolipid and phospholipid fractions decreasing to about the same extent. These changes in lipid content precede the breakdown during germination of the complex and extensive membrane system of zoospores. During growth, which immediately follows germination, net phospholipid synthesis resumes so that total lipid is maintained at 6% of dry weight, but net synthesis of neutral and glycolipid does not begin until induction of sporulation. During sporulation the phospholipid level decreases so that the distribution of lipid among the three fractions approaches that found in zoospores. These changes in lipid content suggest that zoospore membranes containing neutral and glycolipids are synthesized $\text{de novo}$ during spore formation.     

Turnover of chloroplast and cytoplasmic ribosomes during gametogenesis in Chlamydomonas reinhardi

A number of novel observations on ribosomal metabolism were made during gametic differentiation of Chlamydomonas reinhardi. Throughout the gametogenic process the amount of chloroplast and cytoplasmic ribosomes decreased steadily. The kinetics and extent of such decreases were different for each of the two ribosomal species. Comparable rRNA degradation accompanied this ribosome degradation. Concurrent with the substantial ribosome degradation was the synthesis of rRNA, ribosomal proteins and the assembly of new chloroplast and cytoplasmic ribosomes throughout gametogenesis. The newly synthesized chloroplast ribosomes exhibited distinctively faster turnover than their cytoplasmic counterpart. Cytoplasmic ribosomes, pulse-labeled in early gametogenic stages, retained label until differentiation was nearly complete even though a net decrease in the level of cytoplasmic ribosomes continued, indicating that the newly synthesized cytoplasmic ribosomes were preferentially retained during differentiation. Hence the regulation of ribosome metabolism during gametogenesis contrasts with the conservation of ribosomes obtained during vegetative growth of C. reinhardi and other organisms. This unique pattern of ribosome metabolism suggests that new ribosome synthesis is necessary during gametogenesis and that some specific structural or functional difference relating to the development stage of the life cycle might exist between degraded and newly synthesized ribosomes.     

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.