Patricia A. Maroney

Evidence that microRNAs are associated with translating messenger RNAs in human cells

MicroRNAs (miRNAs) regulate gene expression post-transcriptionally by binding the 3′ untranslated regions of target mRNAs. We examined the subcellular distribution of three miRNAs in exponentially growing HeLa cells and found that the vast majority are associated with mRNAs in polysomes. Several lines of evidence indicate that most of these mRNAs, including a known miRNA-regulated target (KRAS mRNA), are actively being translated.

Direct detection of small RNAs using splinted ligation

This protocol describes a method for direct labeling and detection of small RNAs present in total RNA by splinted ligation. The assay uses a small RNA-specific bridge oligonucleotide to form base pairs with the small RNA and a 5′-end-radiolabeled ligation oligonucleotide. The captured small RNA is directly labeled by ligation. Detection of the labeled small RNAs is performed by denaturing gel electrophoresis and autoradiography or phosphorimaging. This protocol has been successfully used to study expression of various classes of biological small RNAs from nanogram to microgram amounts of total RNA without an amplification step. It is significantly simpler to perform and more sensitive than either northern blotting or ribonuclease protection assays. Once the oligonucleotides have been synthesized and total RNA has been extracted, the procedure can be completed in 6 h.

New components of the spliced leader RNP required for nematode trans-splicing

Pre-messenger-RNA maturation in nematodes and in several other lower eukaryotic phyla involves spliced leader (SL) addition trans-splicing. In this unusual RNA processing reaction, a short common 5′ exon, the SL, is affixed to the 5′-most exon of multiple pre-mRNAs. The nematode SL is derived from a trans-splicing-specific ∼100-nucleotide RNA (SL RNA) that bears striking similarities to the cis-spliceosomal U small nuclear RNAs U1, U2, U4 and U5 (refs 3, 4); for example, the SL RNA functions only if it is assembled into an Sm small nuclear ribonucleoprotein (snRNP). Here we have purified and characterized the SL RNP and show that it contains two proteins (relative molecular masses 175,000 and 30,000 (Mr 175K and 30K)) in addition to core Sm proteins. Immunodepletion and reconstitution with recombinant proteins demonstrates that both proteins are essential for SL trans-splicing; however, neither protein is required either for conventional cis-splicing or for bimolecular (trans-) splicing of fragmented cis constructs. The Mr 175K and 30K SL RNP proteins are the first factors identified that are involved uniquely in SL trans-splicing. Several lines of evidence indicate that the SL RNP proteins function by participating in a trans-splicing specific network of protein–protein interactions analogous to the U1 snRNP–SF1/BBP–U2AF complex that comprises the cross-intron bridge in cis-splicing.

Functional reconstitution of U6 snRNA in nematode cis- and trans-splicing: U6 can serve as both a branch acceptor and a 5′ exon

Maturation of nuclear pre-mRNAs in nematodes requires both cis- and trans-splicing. Both processing pathways involve analogous two-step phosphotransfer reactions and both are dependent upon the integrity of U6 snRNA. We have developed a functional reconstitution assay to assess the U6 snRNA sequence requirements for cis- and trans-splicing. Branch formation between the splicing substrates and U6 snRNA was observed. The frequency of this event was greatly enhanced when a highly conserved sequence in U6 snRNA was altered by mutation. In cis- and trans-splicing reactions reconstituted with this mutant U6 snRNA the liberated exon of U6 proceeded through the second step of splicing using the appropriate splice acceptor sites. These results demonstrate covalent interactions between a U snRNA required for splicing and a splicing substrate, and they provide evidence for an unexpected degree of catalytic flexibility within the spliceosome.

Transcription of a nematode trans-spliced leader RNA requires internal elements for both initiation and 3' end-formation.

We have used block substitution mutagenesis and in vitro transcription to define sequence elements important for efficient initiation and 3′ end‐formation of the trans‐spliced leader RNA (SL RNA) of the parasitic nematode Ascaris lumbricoides. These experiments indicate that the SL RNA has an unusual promoter structure containing elements which include the 22 nt trans‐spliced leader exon itself. Efficient transcription is correlated with the binding of a factor to the 22 nt (SL) sequence; mutations within the SL which abolish transcription lead to a loss in binding of this factor. In addition to internal sequences, synthesis of SL RNA in vitro requires an element centered 50 bases upstream of the cap site. Mutations within this element dramatically affect the level of SL RNA synthesis but do not affect accuracy of initiation. Finally, all of the information required for accurate 3′ end‐formation of SL RNA lies within the transcribed region. Thus, the arrangement of sequences necessary for the synthesis of SL RNAs does not resemble that of sequences important for the synthesis of vertebrate U snRNAs despite the similarities between SL RNAs and U snRNAs.

Intramolecular base pairing between the nematode spliced leader and its 5' splice site is not essential for trans-splicing in vitro.

The spliced leader RNAs of both trypanosomes and nematodes can form similar secondary structures where the trans‐splice donor site is involved in intramolecular base pairing with the spliced leader sequence. It has been proposed that this base pairing could serve to activate autonomously the SL RNA splice donor site. Here, we have examined exon requirements for trans‐splicing in a nematode cell free system. Complete disruption of secondary structure interactions at and around the trans‐splice donor site did not affect the ability of the SL RNA to function in trans‐splicing. In addition, the highly conserved 22 nt sequence could be productively replaced by artificial exons ranging in size from 2 to 246 nucleotides. These results reinforce the view that the ‘intron’ portion of the SL RNA functions as an independent Sm snRNP whose role is to deliver exon sequences to the trans‐spliceosome.

The nematode spliced leader RNA participates in trans-splicing as an Sm snRNP

The trans‐spliced leader RNA (SL RNA) of nematodes resembles U snRNAs both in cap structure and in the presence of a consensus Sm binding site. We show here that synthetic SL RNA, synthesized by in vitro transcription, is efficiently used as a spliced leader donor in trans‐splicing reactions catalyzed by a cell free extract prepared from developing embryos of the parasitic nematode, Ascaris lumbricoides. Efficient utilization of synthetic SL RNA requires a functional Sm binding site. Mutations within the Sm binding sequence that prevent immunoprecipitation by Sm antisera and prevent cap trimethylation abolish trans‐splicing. The effect on trans‐splicing is not due to undermethylation of the cap structure.

Unequal distribution of N6-methyladenosine in influenza virus mRNAs.

Influenza virus mRNA is posttranscriptionally methylated at internal adenosine residues to form N6-methyladenosine (m6A). It has been previously shown that there is an average of three m6A residues per influenza virus mRNA (R. M. Krug, M. A. Morgan, and A. J. Shatkin, J. Virol. 20:45-53, 1976). To determine the distribution of m6A in the different influenza virus mRNAs, we purified six of the mRNAs by hybrid selection, digested them with nuclease, and determined their methylation patterns by high-pressure liquid chromatography. The amount of m6A in the different mRNAs varied from one in matrix to eight in hemagglutinin.

Cotranslational microRNA mediated messenger RNA destabilization

MicroRNAs are small (22 nucleotide) regulatory molecules that play important roles in a wide variety of biological processes. These RNAs, which bind to targeted mRNAs via limited base pairing interactions, act to reduce protein production from those mRNAs. Considerable evidence indicates that miRNAs destabilize targeted mRNAs by recruiting enzymes that function in normal mRNA decay and mRNA degradation is widely thought to occur when mRNAs are in a ribosome free state. Nevertheless, when examined, miRNA targeted mRNAs are invariably found to be polysome associated; observations that appear to be at face value incompatible with a simple decay model. Here, we provide evidence that turnover of miRNA-targeted mRNAs occurs while they are being translated. Cotranslational mRNA degradation is initiated by decapping and proceeds 5’ to 3’ behind the last translating ribosome. These results provide an explanation for a long standing mystery in the miRNA field. DOI: http://dx.doi.org/10.7554/eLife.12880.001

Accurate and efficient RNA polymerase III transcription in a cell-free extract prepared from Ascaris suum embryos

High-speed supernatant (S100) extracts derived from homogenized Ascaris suum embryos efficiently transcribe added RNA polymerase III templates including cloned 5S rRNA genes of the filarial parasite Brugia malayi. Several criteria, including two-dimensional RNase T1 oligonucleotide fingerprint analysis, indicate that in vitro transcription is accurately initiated and terminated.