Regulation of RNA synthesis in Neurospora crassa : An analysis of a shift-up

A shift-up transition of growth from acetate to glucose is analyzed in Neurospora crassa. The rates of DNA and of protein accumulations remain at the preshift values for about 2 h, afterwards they increase to the rate characteristic of the new medium. The rate of RNA accumulation increases markedly 30 min after glucose addition initially at a rate greater than that of the new exponential growth which is achieved later on. An increase of the level of ribosomal proteins accompanies the increase of the rRNA content of the shifting cells, and 2–2.5 h after the shift the ribosomal level has reached the value characteristic of the new steady state of growth. The rate of rRNA methylation, which is strictly proportional to rRNA synthesis, remains almost unchanged in the 30 min following the shift; thereafter it increases to values greater than the final rate. It is interesting that the rate of rRNA synthesis is enhanced above the value typical of the new steady state as long as the ribosome level in the cells is below that characteristic of the new steady state, as if a compensatory mechanism were active.     

Small stable RNA of Neurospora crassa.

Summary Small stable RNAs in wild-type Neurospora crassa were investigated by analyzing the cell contents of long term ³²P_i labeled cultures in thin slab polyacrylamide gels. Because of the rigid fungal cell wall and the potency of nucleases the degradation of RNA in opening the cells was rather extensive. Some of these degradation problems were circumvented by using a slime strain of N. crassa which lacks a rigid cell wall. Our findings show that N. crassa. like many other eukaryotes, contains a number of small stable RNA molecules. We also found that the ribosomal RNA, the so called 5.8S, migrates slower on polyacrylamide gels than the 6S RNA of E. coli, which contains 184 nucleotides. The relative migration of the molecules was not changed when the samples were denatured prior to electrophoresis. The mobility of the Neurospora rRNA molecule suggested a chain length of 220 nucleotides. Fingerprinting of a T₁ ribonuclease digest indicated a chain length of 212 nucleotides. Because of the unusually large size of the so-called 5.8S rRNA we found it more appropriate to refer to this molecule as a 7S rRNA. It seems that the N. crassa 7S rRNA is the largest low molecular weight ribosomal RNA studied thus far.     

Ribosomal RNA synthesis during phosphorus starvation in wild type Neurospora and in phosphorus regulatory mutants

Summary When N. crassa is starved for phosphate the rate of synthesis of total RNA, as measured by the incorporation of uridine, rapidly dclines, attaining a value of 2% of the control after 4 h. Synthesis of ribosomal RNA (rRNA), measured by direct hybridization to ribosomal DNA covalently coupled to diazobenzyloxymethyl (DBM) paper, also declines to a value 3%–4% that of the control after 4 h of phosphate starvation. Measurement of rRNA synthesis in regulatory mutant strains expressing phosphorus-family enzymes indicates that two of these mutant strains, pgov ^c12 and nuc-1, respond differently to phosphate starvation from the response in wild-type or the other five mutant strains. The results suggest that the wild-type products of the regulatory loci, pgov ⁺ and nuc-1 ⁺ may have a role in regulating rRNA synthesis as well as phosphorus family enzymes.     

Program of early development in the mammal: Changes in absolute rates of synthesis of ribosomal proteins during oogenesis and early embryogenesis in the mouse

The absolute rates of synthesis of specific ribosomal proteins have been determined during growth and meiotic maturation of mouse oocytes, as well as during early embryogenesis in the mouse. These measurements were made possible by the development of a high-resolution twodimensional gel electrophoresis procedure capable of resolving basic proteins with isoelectric points between 9.1 and 10.2. Mouse ribosomal proteins were separated on such gels and observed rates of incorporation of [³⁵S]methionine into each of 12 representative ribosomal proteins were converted into absolute rates of synthesis (femtograms or moles synthesized/hour/oocyte or embryo) by using previously determined values for the absolute rates of total protein synthesis in mouse oocytes and embryos (R. M. Schultz, M. J. LaMarca, and P. M. Wassarman, 1978,Proc. Nat. Acad. Sci. USA,75, 4160;R. M. Schultz, G. E. Letourneau, and P. M. Wassarman, 1979,Develop. Biol.,68, 341–359). Ribosomal proteins were synthesized at all stages of oogenesis and early embryogenesis examined and, while equimolar amounts of ribosomal proteins were found in ribosomes, they were always synthesized in nonequimolar amounts during development. Rates of synthesis of individual ribosomal proteins differed from each other by more than an order of magnitude in some cases. Synthesis of ribosomal proteins accounted for 1.5, 1.5, and 1.1% of total protein synthesis during growth of the oocyte, in the fully grown oocyte, and in the unfertilized egg, respectively. During meiotic maturation of mouse oocytes the absolute rate of synthesis of ribosomal proteins decreased about 40%, from 620 to 370 fg/hr/cell, as compared to a 23% decrease in the rate of total protein synthesis during the same period. On the other hand, during early embryogenesis the absolute rates of synthesis of each of the 12 ribosomal proteins examined increased substantially as compared with those of the unfertilized egg, such that at the eight-cell stage of embryogenesis synthesis of ribosomal proteins (4.17 pg/hr/embryo) accounted for about 8.1% of the total protein synthesis in the embryo. Consequently, while the absolute rate of total protein synthesis increased about 1.5-fold during development from an unfertilized mouse egg to an eight-cell compacted embryo, the absolute rate of ribosomal protein synthesis increased more than 11-fold during the same period. These results seem to reflect the differences reported for the patterns of ribosomal RNA synthesis during early development of mammalian, as compared to nonmammalian, animal species. The results are compared with those obtained using oocytes and embryos fromXenopus laevis.     

Cloning and characterization of the rDNA repeat unit of Podospora anserina

Summary DNA coding for ribosomal RNA in Podospora anserina has been cloned and was found as a tandemly repeated 8.3 kb sequence. The cloned rDNA was characterized by restriction endonuclease mapping. The location of 5.8S, 18S and 28S rRNA coding regions was established by DNA-RNA hybridization and S1 nuclease mapping. The organization of P. anserina rRNA genes is similar to that of Neurospora crassa and Aspergillus nidulans. The rDNA unit does not contain the sequence coding for 5S RNA.     

Decay and synthesis of ribosomal proteins during Dictyostelium discoideum development

Summary Ribosome turnover is a prominent process during cell differentiation in Dictyostelium discoideum. At the end of 24 h of development on filters, the cells contain only 30% of the ribosome content of vegetatively growing cells. We determined the relative rates of synthesis and decay of each of the ribosomal proteins during this period. Approximately 80% of the total vegetative cell ribosomal proteins were degraded during the course of fruiting body construction. Ribosomal RNA and protein degradation apparently occurred coordinately during development. Although all ribosomal proteins decayed during development, some were more stable and a few less stable than the average. In addition, all the ribosomal proteins were synthesized during this period. Most ribosomal proteins were synthesized at the same rate as other cellular proteins, although a number were made at lower or higher rates. It was estimated that about 35% of the ribosomes in developed cells represented those, that were made during cell differentiation. Differential decay and/or synthesis of ribosomal proteins could account for the observed difference in protein content of ribosomes from growing amoebae and late development cells and spores.Paper No. 4 in the series, Studies on Ribosomal Proteins in Dictyostelium discoideum. Paper No. 3 is Ramagopal and Ennis (1982)     

Functional inactivation rates of the messenger RNA molecules coding for the individual ribosomal proteins in Escherichia coli.

Summary The rates of functional decay of messenger RNA coding for total soluble, total ribosomal and individual ribosomal proteins were measured in Escherichia coli strain AS-19, at 30^o. This was accomplished by blocking RNA synthesis with the inhibitor thiolutin and measuring residual protein synthesis at various times thereafter. The data obtained expressed as a decay constant (Hartwell and Magasanik, 1963) show that both total soluble and total ribosomal protein decay with similar rates (K ₂=0.64 and 0.61 respectively) which are slightly faster than the decay rate of -galactosidse (k ₂=0.43) under these conditions. All the individual ribosomal proteins appear to comprise a population of cistrons whose individual mRNA's decay with very similar rates with the possible exception of protein L3, whose mRNA appears consistently to decay very rapidly.Additional data on the stability of the total soluble and total ribosomal proteins during thiolutin treatment (that is, proteins synthesized in the absence of concommitant ribosomal RNA synthesis) fail to demonstrate any marked difference between these two protein populations. Examination of the stability of the individual ribosomal proteins however, reveals that some are degraded up to 35% in 15 min of thiolutin exposure, some to about 15% and some appear to be completely stable. In general, a degree of correlation exists between the stability of a given protein and the observed decay rate of its messenger RNA. This observation may explain in part the spread among the rates of mRNA decay. Nevertheless, we conclude that although degradation is occurring, it is not sufficient to alter the main conclusion that the rates of functional decay of mRNA cistrons coding for the ribosomal proteins are very similar.     

Synthesis of proteins and RNA of the 60S ribosomal subunit in HeLa cells recovering from valine deprivation

The synthesis of ribosomes in HeLa cells was studied during recovery from a 20-hour deprivation for valine. The rates of incorporation of labeled precursors into ribosomal pre-RNA, processed rRNA, total cellular proteins, and proteins of the 60S ribosomal subunit returned to normal or nearly normal levels immediately after restoration of valine to the medium. Specific proteins of the 60S ribosomal subunit, whose apparent net synthesis is reduced more than that of the other proteins of the 60S ribosomal subunit during valine deprivation, were no longer undersynthesized after valine was restored. This rapid recovery suggests that the apparent decrease in the net rate of synthesis of these ribosomal proteins during valine deprivation is effected at the translational or post-translational level. No evidence of significant synchrony in any particular stage of the cell cycle was observed after a 20-hr valine deprivation. Key words: 60S ribosomal subunit; HeLa, cells; valine deprivation.     

Magnification of rRNA gene number in a Neurospora crassa strain with a partial deletion of the nucleolus organizer

Some progeny from crosses between the Neurospora crassa translocation strain T(IL VL)OY321 and normal sequence N. crassa strains are duplication strains with a partial deletion of the nucleolus organizer. Despite the deletion, these progeny are viable and produce a functional nucleolus. Quantification of rRNA gene number in these deletion progeny demonstrated a significant loss of rRNA genes, down to 60% of the parental wild-type level. Initially, all of these reduced nucleolus organizer (RNO) strains demonstrated a reduction in the rate of mycelial elongation in growth tubes. After several vegetative growth cycles some progeny reverted to the normal growth phenotype, and also showed an increase in the number of rRNA genes to approximately that of the wild type.     

Stimulation of ribosomal RNA synthesis during hypertrophic growth of cultured heart cells by phorbol ester

Primary cultures of neonatal cardiac myocytes were used to determine the effects of tumor-promoting phorbol esters on ribosomal RNA (rRNA) synthesis during myocyte growth. Treatment of myocytes with phorbol-12,13-dibutyrate (PDBu) increased protein accumulation by 25% and RNA content by 20%. Rates of rRNA synthesis were measured to assess the mechanism by which rRNA accumulated during myocyte growth. Rates of rRNA synthesis were determined from the incorporation of [³H]uridine into UMP of purified rRNA and the specific radioactivity of the cellular UTP pool. After 24h of PDBu treatment, cellular rates of 18S and 28S rRNA synthesis were accelerated by 67% and 64%, respectively. The increased rate of rRNA synthesis accounted for the net increase in myocyte rRNA content after PDBu treatment.     

DNA replication in synchronized cultured mammalian cells : VI. The temporal replication of ribosomal cistrons in synchronized cell lines

The time of synthesis of ribosomal genes was studied in a haploid (Rana pipiens), and a pseudodiploid (Chinese hamster) cell line. R. pipiens cells were synchronized by amethopterin block. Chinese hamster cells were synchronized by isoleucine starvation followed by hydroxyurea treatment. DNA replicated during three or four selected intervals of the S period was separated from the remainder of the DNA by bromodeoxyuridine density labeling. Purified bromodeoxyuridine substituted DNA was annealed with radioactive-labeled 28S ribosomal RNA (rRNA) to determine when, during different intervals of S, the nuclear DNA homologous to rRNA was replicated. In the R. pipiens and Chinese hamster cell lines, the percent of nuclear DNA homologous to 28S rRNA is highest in the DNA replicated during the first half of the S period.     

Single rRNA Helices Bind Independently to the Protein‐Conducting Channel SecYEG

Ribosomes tightly interact with protein‐conducting channels in the plasma membrane of bacteria (SecYEG) and in the endoplasmic reticulum of eukaryotes (Sec61 complex). This interaction is mediated by multiple junctions and is highly conserved during evolution. Although it is well known that both ribosomal proteins and ribosomal RNA (rRNA) are involved in the ribosome–channel interaction, detailed analyses on how these components contribute to this binding are lacking. Here, we demonstrate that the evolutionary conservation of ribosome binding is solely mediated by rRNA. Moreover, we show that in vitro transcribed 23 S rRNA binds with similar characteristics to protein translocation channels as native 23 S rRNA or 50 S ribosomal subunits. This indicates that base modifications, which exist in native rRNA, do not crucially influence the binding. In two of the ribosome‐channel junctions (c1 and c2), exclusively rRNA helices are involved. Using in vitro transcribed rRNA mutants, we now provide evidence that large parts of the rRNA can be deleted without altering its binding properties, as long as the rRNA helices of the c1 and c2 junctions remain intact. We demonstrate that the connection sites c1 and c2 generate high‐affinity binding sites that act independently of each other. This could explain why membrane‐bound ribosomes have an extremely low off‐rate .     

Synthesis and conservation of ribosomal proteins during compensatory renal hypertrophy.

The rate of synthesis of ribosomal proteins was investigated as an index of the rate of production of ribosomes in mouse kidney during the first few days after contralateral nephrectomy. Compensatory renal hypertrophy was not associated with a major increase in the synthetic rate of ribosomal proteins and rRNA. Instead, the ratio of the rate of ribosomal-protein synthesis to that of total protein synthesis remained nearly constant. The conformation of glutaraldehyde-fixed ribosomes and ribosomal subunits was unchanged. During the early stages of compensatory renal hypertrophy the accretion of rRNA is due largely to conservation of ribosomes that would otherwise have been degraded.     

Changes in rate of RNA synthesis and ribosomal gene number during oogenesis of Drosophila melanogaster.

A new method for separating Drosophila egg chambers into different developmental classes (Jacobs-Lorena and Crippa, 1977) made it possible to study changes in the rate of ribosomal RNA (rRNA), 5S RNA, and tRNA synthesis and the changes in ribosomal gene number during oogenesis. Synthesis of RNA was measured by [³H]uridine incorporation in vivo and subsequent analysis on sucrose gradients or gel electrophoresis. Specific radioactivity of nucleotide pools has also been determined. Ribosomal gene number has been measured by hybridization of egg chamber DNA to rRNA of high specific radioactivity. Our findings led us to conclude that in Drosophila melanogaster: (i) rRNA, 5S RNA, and tRNA are synthesized in all stages of oogenesis. (ii) In every stage, rRNA is the main RNA species synthesized. (iii) The rate of rRNA, 5S RNA, and tRNA synthesis increases greatly during oogenesis and is paralleled by a similar increase in ribosomal gene number resulting from the polyploidization of the nurse cell nuclei.     

Starved Tetrahymena Synthesize and Maintain an Excess of 5s rRNA in Their Cytoplasm1

We have measured the rate of accumulation of newly synthesized 5s ribosomal RNA (5s rRNA) in Tetrahymena thermophila cells in early log phase growth and in cells that had been starved in a dilute salt solution. From these measurements we have determined the rates of synthesis and levels of accumulation of 5s rRNA relative to 5.8s rRNA in these two different cell populations. In growing cells 5s rRNA is transcribed and accumulated in a 1:1 molar ratio when compared with 5.8s rRNA. In contrast, in starved cells, 5s rRNA is produced at a rate which is about 15% higher than that seen for 5.8s rRNA. This excess 5s rRNA accumulates in the cytoplasm in a non-ribosomal form and is maintained in the cell as long as the cell remains in a starved condition. The role this excess 5s rRNA may play in the control of 5s rRNA gene expression is discussed.