Half-lives and relative amounts of stored and polysomal ribosomes and poly(A)+ RNA in mouse oocytes

Growing mouse oocytes were labeled in vitro with [³H]uridine and chased for 2 or for 7 days to estimate the relative amounts of RNA appearing in different fractions and to follow their turnover. Oocytes were lysed and thoroughly dispersed in the presence of 1% DOC, and centrifuged on sucrose gradients to separate polysomes from smaller components not engaged in translation. After the short chase, one-third of the labeled ribosomes appeared in EDTA-sensitive polysomes. The proportion of ribosomes in both fractions remained stable during the long chase, demonstrating no net flow from one fraction to the other. When gradient fractions were analyzed by poly(U) Sepharose chromatography, it was found that about 20% of the labeled poly(A)+ RNA appeared in polysomes after the short chase. The half-lives of stored and translated mRNA were followed relative to stable rRNA during the long chase. Stored mRNA was completely stable, but translated mRNA turned over with a $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of about 6 days. Other methods for separating stored from translated components were not successful, including sedimentation of putative large complexes (fibrillar lattices) containing stored components, or chromatography of lysates on oligo(dT)-cellulose. Results presented here combined with our previous results demonstrate that, during meiotic maturation, the percent of labeled stable RNA which is polyadenylated declines from 19 to 10%, suggesting deadenylation or degradation of half of the accumulated maternal mRNA.     

N-6-methyl-adenosine in adenovirus type 2 nuclear RNA is conserved in the formation of messenger RNA

In the biogenesis of adenovirus type 2 messenger RNAs, methylation occurs at the 5′ end (cap) and to internal adenosine residues to yield N⁶-methyl-adenosine (m⁶A) (Sommer et al., 1976; Moss &; Koczot, 1976; Wold et al., 1976). The kinetics of accumulation of ³H from methyl-labeled methionine and ¹⁴C from uridine into Ad-2²-specific RNA was measured late in Ad-2 infection. As reported previously (Nevins &; Darnell, 1978a), the rate of accumulation of [¹⁴C]uridine label in nuclear RNA was approximately four- to fivefold faster than in the cytoplasmic RNA, indicating a conservation of about 20% for the total RNA. The initial rates of [³H]methyl label in m⁶A in nuclear RNA and in the cytoplasmic RNA were approximately equal, suggesting a complete (or nearly complete) conservation of m⁶A.In accord with the accumulation kinetics, the ratio of ³H to ¹⁴C was higher in cytoplasmic RNA than in nuclear RNA that hybridized to equivalent regions of the Ad-2 DNA.A mathematical model was designed to evaluate the accumulation of methyl label in m⁶A, taking into consideration the three major parameters that affect the accumulation curves: equilibration of the S-adenosyl-methionine pool, the nuclear dwell time of sequences destined to be mRNA, and the cytoplasmic stability of mRNA. The half-time ($\text{t}\text{1}\text{2}$) for pool equilibration was determined experimentally to be 22 minutes and the nuclear dwell time and the mean life-time of cytoplasmic mRNA were estimated from ¹⁴C label to be about 30 and 70 minutes, respectively.The model gave an excellent fit to the data when the $\text{t}\text{1}\text{2}$ for pool equilibration time of 24 ± 2 minutes, a nuclear dwell time of 25 ± 10 minutes, and a mean cytoplasmic mRNA life-time of 75 ± 30 minutes were used to evaluate accumulation curves. Even when data from a restricted region of the genome, $\text{40.5–52.6}$, which encodes the main portion of at least five 3′ co-terminal mRNAs whose spliced junction with the tripartite leader sequence varies from $\text{38, 40, 43, 45}$, and $\text{48}$ was analyzed, it appeared that m⁶A was conserved.Finally, m⁶A was found to be added in a brief label (3.5 min) mainly to nuclear molecules that were longer than any cytoplasmic RNA. The conservation of m⁶A and its addition prior to splicing raise the possibility that internal methylations are involved, in the formation of mRNA.     

Rapid inhibition by cycloheximide of rat hepatic nuclear free and engaged poly(A) polymerase activities

This paper reports the effect of cycloheximide on the activity of rat hepatic nuclear poly(A) polymerase. Three hours after cycloheximide treatment (3 mg/100 g body weight), total rat hepatic nuclear poly (A) polymerase activity was decreased to 50% of the normal level. This conclusion was reached when the enzyme activity was measured either in the whole nuclei $\text{in vitro}$ or with partly purified enzyme preparations. When examined at different times after a single injection of cycloheximide, it was observed that poly(A) polymerase activity decayed biphasically with an initial rapid decay phase reaching a minimum at one hour $\text{(}\text{t}\text{1}\text{2}\text{= 0.8}\text{hrs}\text{)}$, followed by a stable phase thereafter. These results have been interpreted to mean that poly(A) polymerase consists of either a mixture of two structurally distinct populations of enzymes with a different turnover rate, or of a single type of enzyme with a protein factor which is rapidly turning over and which is required for maximal enzyme activity.     

5' Cap methylation of homologous poly A(+) RNA by a RNA (guanine-7) methyltransferase from Neurospora crassa.

RNA (guanine-7) methyltransferase, partially purified from $\text{N.}\text{crassa}$ mycelia, catalyzed the transfer of the methyl group from S-adenosylmethionine to the 5′ terminus of both $\text{N.}\text{crassa}$ poly A(+) RNA and reovirus unmethylated mRNA. RNase T₂ digestion of the $\text{in}\text{vitro}$ methylated poly A(+) RNA from $\text{N.}\text{crassa}$ yielded the “cap” structures m ⁷G(5′)pppAp and m ⁷G(5′)pppGp in a ratio of 2:1 respectively. RNase T₂ digestion of the $\text{in}\text{vitro}$ methylated reovirus mRNA yielded m ⁷G(5′)pppGp exclusively. The absence of mRNA 2′-0-methyltransferase activity in the enzyme preparation is consistent with the absence of 2′-0-methylation in $\text{N.}\text{crassa}$ mRNA [Seidel, B. L. and Somberg, E. W. (1978) Arch. Biochem. Biophys. $\text{187}$, 108–112]. This is the first isolation of an eucaryotic, cellular RNA (guanine-7) methyltransferase that has been shown to methylate homologous substrate.     

Cloning of a cDNA complementary to rat preputial gland β-glucuronidase mRNA

Messenger RNA was isolated from rat preputial glands by guanidine HCl extraction, ethanol and salt precipitation, followed by chromatography on oligo(dT) cellulose. Double-stranded cDNA was synthesized from the mRNA and inserted into the Pst 1 site of the plasmid pBR322 by the poly(dG)·poly(dC) tailing and annealing procedure. The hybrid plasmids were used to transform $\text{E. coli}$ HB101. Recombinant clones were screened for those containing cDNA inserts complementary to β-glucuronidase mRNA by a hybridization-selection procedure. One clone, containing an insert of about 1.2 kilobases, hybridized to preputial gland mRNA which, when translated $\text{in vitro}$, gave a product that migrated with the β-glucuronidase subunit on polyacrylamide gels.     

Destabilization of the secondary structure of RNA by ribosomal protein S1 from escherichia coli

S1 is an acidic protein associated with the 3′ end of 16S RNA; it is indispensable for ribosomal binding of natural mRNA. We find that S1 unfolds single stranded stacked or helical polynucleotides (poly rA, poly rC, poly rU). It prevents the formation of poly (rA + rU) and poly (rI + rC) duplexes at 10–25 mM NaCl but not at 50–100 mM NaCl. Partial, salt reversible denaturation is also seen with coliphage MS2 RNA, $\text{E. coli}$ rRNA and tRNA. Generally, only duplex structures with a Tm greater than about 55° are formed in the presence of S1. The protein unfolds single stranded DNA but not poly d(A·T).     

Cytosine-rich messenger RNA from carrot root discs

The total poly A⁺ RNA from aerated carrot root discs was further fractionated into a cytosine-rich mRNA fraction by oligo (dG) cellulose chromatography. C-rich mRNA was purified at least 10-fold by this procedure and, when translated in wheat germ lysates, codes for 57 and 53 Kdalton peptides. Translation in double label amino acid mixtures indicates that C-rich mRNA codes for proline-rich peptides which may be precursors to the hydroxyproline-rich glycoprotein synthesized $\text{in}\text{vivo}$ by this tissue.     

Translational control of the expression of the β subunit gene of E., coli RNA polymerase

Using the plasmid pNF1337 as template, a mRNA preparation has been obtained that directs the $\text{in}\text{,}\text{vitro}$ synthesis of fMet-Val, the N-terminal dipeptide of the β subunit of RNA polymerase. RNA polymerase holoenzyme specifically inhibits the mRNA-directed synthesis of fMet-Val showing that the autoregulation by RNA polymerase of β,β′ synthesis is at the level of translation. L factor ($\text{nusA}$ gene product) stimulates the synthesis of fMet-Val from a DNA template but not from mRNA. Rifampicin has no effect on the mRNA-directed synthesis of fMet-Val or the ability of RNA polymerase to inhibit fMet-Val synthesis.     

The early synthesis and possible function of a 0.5 X 10(6) Mr RNA after transfer of dark-grown Spirodela plants to light.

A 0.5 × 10⁶$\text{M}$_r RNA found in plastids of the aquatic angiosperm $\text{Spirodela}$, is synthesized at a much higher rate than any other rapidly labeling RNA species about $\text{3–3}\text{1}\text{2}$ h after dark-grown plants are transferred to light. The pulse labeling kinetics of the 0.5 × 10⁶$\text{M}$_r RNA after transfer to light, argue against its involvement in the biogenesis of plant rRNAs. Although poly(A) RNA is found in $\text{Spirodela}$, poly(A) sequences are not detected in the 0.5 × 10⁶$\text{M}$_r RNA; yet a sucrose gradient fraction which includes RNA of this $\text{M}$_r stimulates amino acid incorporation by an $\text{E. coli}$ cell free extract more than other RNA fractions. The possible involvement of the 0.5 × 10⁶$\text{M}$_r RNA as a chloroplast messenger is discussed.     

A template independent, rifampicin sensitive poly (A).poly (U) synthesizing activity present in Bacillus subtilis.

A template independent poly (A)·poly (U) synthesizing activity has been isolated from $\text{Bacillus subtilis}$. This activity is eluted from a DNA-cellulose column along with DNA-dependent RNA polymerase. The column fractions which exhibit this activity contain RNA polymerase holoenzyme plus a polypeptide which is slightly larger than sigma factor; pure RNA polymerase holoenzyme did not synthesize poly (A)·poly (U). The activity was dependent on the presence of ATP, UTP, and Mn⁺⁺ (Mg⁺⁺ could not substitute), and was inhibited by rifampicin, streptolydigin, and Cibacron Blue. The incorporation of nucleotides was not linear with time, but appeared after a lag period. The results suggest that a modified form of DNA-dependent RNA polymerase analogous to $\text{Escherichia coli}$ holoenzyme II is catalyzing the synthesis of poly (A)·poly (U).     

Cyclopenta(f)isoquinoline derivatives designed to bind specifically to native deoxyribonucleic acid. 3. Interaction of 6-carbamylmethyl-8-methyl-7H-cyclopenta(f)isoquinolin-3(2H)-one with deoxyribonucleic acids and polydeoxyribonucleotides

By the use of space-filling models, a novel compound, 6-carbamylmethyl-8-methyl-7$\text{H}$-cyclopenta[f]isoquinolin-3(2$\text{H}$)-one ($\text{1}$) was devised which would be expected to hydrogen bond specifically to GC pairs in the major groove of the double helix such that (i) the amino group of the cytosine molecule donates a hydrogen bond to the C-3 carbonyl of the isoquinoline moiety and (ii) the amide proton of the side chain donates a hydrogen bond to the N-7 of guanine. From difference spectra studies it was found that $\text{1}$ binds to native calf thymus DNA better than to denatured DNA; $\text{1}$ inhibited RNA synthesis by a DNA-dependent RNA polymerase; and equilibrium dialysis experiments revealed that $\text{1}$ binds to poly(dG).poly(dC), whereas no such binding to poly(dA).poly(dT) was observed.