The absolute frequency of labeled N-6-methyladenosine in HeLa cell messenger RNA decreases with label time

When HeLa cells were labeled with either [³H]adenosine or H₃³²PO₄, the absolute frequency of m⁶A (N-6-methyladenosine) decreased 2 to 2.5-fold between a short and long label. The frequency of caps (m⁷GpppXmpYp) remained constant at a level which suggests that most if not all mRNAs are capped in either a short or a long label. Since the inhibition of heterogeneous nuclear RNA synthesis with either actinomycin D or 5,6-dichloro-I-β-d-ribofuranosyl-benzimidazole halted the labeling of both m⁶A and caps within 10 to 15 minutes and no direct cytoplasmic addition of m⁶A could be detected, m⁶A must be lost faster than caps from the cytoplasmic mRNA. This preferential loss could be due to one or more of the following: (1) a m⁶A demethylase; (2) excision of m⁶A containing sequences followed by splicing of the remaining parts of the mRNA; or (3) a minority of the mRNA with a high frequency of m⁶A leaving the cytoplasmic compartment rapidly, presumably by being degraded.     

Comparison of methylated sequences in messenger RNA and heterogeneous nuclear RNA from mouse L cells

A variety of methylated oligonucleotides were derived from mouse L cell messenger RNA and heterogeneous nuclear RNA by digestion with specific ribonucleases, and the cap-containing oligonucleotides separated from those containing internal m⁶A by chromatography on diborylaminoethyl-cellulose. Cap-containing sequences of the type m⁷GpppX^mpG, m⁷GpppX^mpY^(m)pG, m⁷GpppX^mpY^(m) pNpG and m⁷GpppX^mpY^(m)p(Np)_{> 1}G have distinctive non-random compositions of the 2′-O-methylated constituent X^m; yet sequences of a particular type and composition occur with a remarkably similar frequency in mRNA and hnRNA². For example, approximately 20% of the cap sequences in both hnRNA and mRNA are m⁷Gppp(m⁶)A^mG, whereas less than 1% are m⁷GpppU^mpG. The high degree of similarity in cap sequences is consistent with the previously postulated precursor-product relationship between hnRNA caps and mRNA caps.The composition of the Y position in capped hnRNA molecules was determined to be (29% G, 20% A, 51% Py), which differs considerably from the composition of Y^m in the cap II forms of mRNA (8% G^m, 11% A^m, 81% Py). Given the precursor-product relationship between hnRNA caps and mRNA caps, this result provides strong evidence that only a restricted subclass of mRNA molecules receive the secondary methylation at position Y.In both hnRNA and mRNA the internal m⁶A occurs in well-defined sequences of the type: $\text{-N}{}_1\text{-(}\text{G}\text{A}\text{)-m}{}^6\text{A-C-N}{}_2\text{-}$, the 5′ nearest-neighbor of m⁶A being G in about three-quarters of the molecules and A in about one-quarter of the molecules. The nucleotide N¹ is a purine about 90% of the time and the nucleotide N² is rarely a G. These same sequences are present in large (> 50 S), as well as small (14 S to 50 S) hnRNA. These results raise the possibility that the internal m⁶A, like caps, may be conserved during the processing of large hnRNA into mRNA. Two models based on this idea are discussed.     

Methylation of late adenovirus 2 nuclear and messenger RNA.

Methylation of adenovirus 2 (Ad 2) late RNA was studied. RNA was double-labeled with [³H-methyl]-methionine and [¹⁴C]-uridine 15–20 h postinfection. Nuclear RNA (rRNA) and cytoplasmic RNA (mRNA) was extracted, and fractionated into polyA(+) and (?) molecules using poly(U)-Sepharose. Ad 2 specific RNA was purified by 2 cycles of hybridization to and elution from Ad 2 DNA immobilized on filters. The Ad 2 polyA(+) and (?) nRNA and mRNA fractions had the same ${}^3\text{H}{}^{14}\text{C}$ ratios, and were estimated to contain a minimum of 1.4 methylated nucleotides per 1000 bases. Viral RNA was digested with RNase T₂ and chromatographed on DEAE-Sephadex in 7 M urea at pH 7.6. All four Ad RNA fractions contained methylated constituents consistent with: (1) two classes of methylated “capped” 5′-termini with general structures m⁷ GpppN^mpNp and m⁷ GpppN^mpN^mpNp; (2) internal base methylations; (3) minor amounts of internal ribose 2′-0-methylations. Two classes of 5′-termini have previously been reported for animal cell mRNA, but not for mRNA from a variety of viruses. Internal methylations may be unique to RNA molecules transcribed in the nucleus, since they have not been found in RNA from cytoplasmic viruses. No gross differences were observed in the DEAE-Sephadex elution profiles of the methylated constituents of the four types of Ad 2 RNA. These results suggest that the majority of methylation events occur in the nucleus, and raise the possibility that Ad 2 methylated late nRNA may differ significantly from SV40 late nRNA (Lavi, S., and Shatkin, A.J. (1975) Proc. Natl. Acad. Sci. USA $\text{72}$, 2012–2016).     

Essential factors in the kinetic analysis of RNA synthesis in HeLa cells

Further evidence of mRNA in HeLa cells with a half-life two hours or less is given. A kinetic model of RNA synthesis in HeLa cells is described in which equilibration of label occurs first into the acid soluble pool (evidence is given that this pool feeds RNA synthesis) and thence in nuclear and cytoplasmic molecules. The measured accumulation of label in nuclear and cytoplasmic poly(A) is examined with the model and parameters were found which are consistent with the quantitative transfer of nuclear poly(A) to the cytoplasm. The strengths and limitations of the model are discussed.     

Altered restriction of nuclear RNA during incubation in vitro

Nuclei were isolated from rat liver and incubated $\text{in}\text{vitro}$ in two commonly employed RNA transport assays. Released [¹⁴C] RNA was isolated and hybridized with filter-bound DNA in the presence of competing cytoplasmic RNA. A significant portion of RNA which was transported to either medium was not represented in cytoplasmic RNA. These results indicate that the restriction of some sequences to the nucleus $\text{in}\text{vivo}$ is not maintained $\text{in}\text{vitro}$.     

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.     

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.     

Studies of odd bases in yeast mitochondrial tRNA: II. Characterization of rare nucleosides

The nucleoside composition of tRNA from highly purified yeast mitochondria shows the presence of T, ψ, hU, m¹G, m²G, m₂²G, I and t⁶A whereas neither m⁷G, m⁵C, m³C, m¹A, i⁶A and Y nor O′-methylated nucleosides (which are common in yeast cytoplasmic tRNA) were found. The G+C content is very low (35%). The overall methylation content is 2.7% which is about half the content of yeast cytoplasmic tRNA but similar to that of $\text{E. coli}$ tRNA. Some rare nucleosides however which are found in $\text{E. coli}$ (s⁴U, acp³U, m²A, m⁶A, ms²i⁶A, Q) were not found in yeast mitochondrial tRNA.     

The methylation of adenovirus-specific nuclear and cytoplasmic RNA.

Each poly(A) containing cytoplasmic AD-2 MRNA contains at its 5' terminus the general structure m7 GpppN1 pN2p or m7 GpppN1mpN2mpNp as well as an average of 4 m6A and 0.5-1 m5C residues per molecule. Almost all of the N1m residues are adenine derivatives including Am, m6Am and probably m26,6Am. The N2m is mostly Cm but small amounts of the other three methylated bases are also present. All the methylated constitutents of mRNA are distant from the 3' terminal poly(A). The amount of m6A appears to be greater in larger mRNA than in smaller mRNA. Nuclear Ad-2 specific RNA also contains caps, m6A, and m5C with about twice as much m6A relative to caps as cytoplasmic mRNA. The similarity of Ad-2 nuclear and mRNA to HeLa hnRNA and mRNA suggests that adenovirus mRNA production is a good model for eukaryotic mRNA production.     

Competition between bacteriophage f2 RNA and bacteriophage T4 messenger RNA

In an $\text{Escherichia coli}$ cell-free protein synthesis assay, mRNA isolated from cells late after infection by phage T4 out-competes bacteriophage f2 RNA. Addition of a saturating or subsaturating amount of T4 mRNA inhibits translation of f2 RNA, while even an excess of f2 RNA has no effect on translation of T4 mRNA. Peptide mapping of reaction products labeled with formyl-[³⁵S]-methionyl-tRNA was used to quantitate f2 and T4 protein products synthesized in the same reaction. We suggest that messenger RNA competition might be one mechanism by which T4 superinfection of cells infected with phage f2 blocks translation of f2 RNA and possibly host mRNA.     

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.     

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.     

RNA metabolsim during vegetative growth and morphogenesis of the cellular slime mold Dictyostelium discoideum

During vegetative growth of the cellular slime mold Dictyostelium discoideum, RNA is rapidly labeled by radioactive precursor and both the 25 S and the 17 S ribosomal RNA species appear in the cytoplasm 6–7 min after the onset of labeling. Thirty minutes after further incorporation of radioactive RNA precursors has been blocked, less than 10% of the label in RNA is associated with the nuclear fraction. After aggregation of the slime mold amoebae, RNA appears in the cytoplasm at a reduced rate, the small ribosomal subunit appearing in the cytoplasmic fraction more slowly than the larger ribosomal subunit. Some labeled RNA remains in the nuclei of developing cells long after the incorporation of ³H-uridine is blocked.