BRD2 and BRD3 genes independently evolved RNA structures to control unproductive splicing

The mammalian BRD2 and BRD3 genes encode structurally related proteins from the bromodomain and extraterminal domain protein family. The expression of BRD2 is regulated by unproductive splicing upon inclusion of exon 3b, which is located in the region encoding a bromodomain. Bioinformatic analysis indicated that BRD2 exon 3b inclusion is controlled by a pair of conserved complementary regions (PCCR) located in the flanking introns. Furthermore, we identified a highly conserved element encoding a cryptic poison exon 5b and a previously unknown PCCR in the intron between exons 5 and 6 of BRD3, however, outside of the homologous bromodomain. Minigene mutagenesis and blockage of RNA structure by antisense oligonucleotides demonstrated that RNA structure controls the rate of inclusion of poison exons. The patterns of BRD2 and BRD3 expression and splicing show downregulation upon inclusion of poison exons, which become skipped in response to transcription elongation slowdown, further confirming a role of PCCRs in unproductive splicing regulation. We conclude that BRD2 and BRD3 independently acquired poison exons and RNA structures to dynamically control unproductive splicing. This study describes a convergent evolution of regulatory unproductive splicing mechanisms in these genes, providing implications for selective modulation of their expression in therapeutic applications.

Survival guide: Escherichia coli in the stationary phase

This review centers on the stationary phase of bacterial culture. The basic processes specific to the stationary phase, as well as the regulatory mechanisms that allow the bacteria to survive in conditions of stress, are described.

Direct localization by cryo-electron microscopy of secondary structural elements in Escherichia coli 23 S rRNA which differ from the corresponding regions in Haloarcula marismortui

Insertions were introduced by a two-step mutagenesis procedure into each of five double-helical regions of Escherichia coli 23 S rRNA, so as to extend the helix concerned by 17 bp. The helices chosen were at sites within the 23 S molecule (h9, h25, h45, h63 and h98) where significant length variations between different species are known to occur. At each of these positions, with the exception of h45, there are also significant differences between the 23 S rRNAs of E. coli and Haloarcula marismortui. Plasmids carrying the insertions were introduced into an E. coli strain lacking all seven rrn operons. In four of the five cases the cells were viable and 50 S subunits could be isolated; only the insertion in h63 was lethal. The modified subunits were examined by cryo-electron microscopy (cryo-EM), with a view to locating extra electron density corresponding to the insertion elements. The results were compared both with the recently determined atomic structure of H. marismortui 23 S rRNA in the 50 S subunit, and with previous 23 S rRNA modelling studies based on cryo-EM reconstructions of E. coli ribosomes. The insertion element in h45 was located by cryo-EM at a position corresponding precisely to that of the equivalent helix in H. marismortui. The insertion in h98 (which is entirely absent in H. marismortui) was similarly located at a position corresponding precisely to that predicted from the E. coli modelling studies. In the region of h9, the difference between the E. coli and H. marismortui secondary structures is ambiguous, and the extra electron density corresponding to the insertion was seen at a location intermediate between the position of the nearest helix in the atomic structure and that in the modelled structure. In the case of h25 (which is about 50 nucleotides longer in H. marismortui), no clear extra cryo-EM density corresponding to the insertion could be observed.

Mutations at position A960 of E. coli 23 S ribosomal RNA influence the structure of 5 S ribosomal RNA and the peptidyltransferase region of 23 S ribosomal RNA

The proximity of loop D of 5 S rRNA to two regions of 23 S rRNA, domain II involved in translocation and domain V involved in peptide bond formation, is known from previous cross-linking experiments. Here, we have used site-directed mutagenesis and chemical probing to further define these contacts and possible sites of communication between 5 S and 23 S rRNA. Three different mutants were constructed at position A960, a highly conserved nucleotide in domain II previously crosslinked to 5 S rRNA, and the mutant rRNAs were expressed from plasmids as homogeneous populations of ribosomes in Escherichia coli deficient in all seven chromosomal copies of the rRNA operon. Mutations A960U, A960G and, particularly, A960C caused structural rearrangements in the loop D of 5 S rRNA and in the peptidyltransferase region of domain V, as well as in the 960 loop itself. These observations support the proposal that loop D of 5 S rRNA participates in signal transmission between the ribosome centers responsible for peptide bond formation and translocation.

The environment of 5S rRNA in the ribosome: cross-links to the GTPase-associated area of 23S rRNA

Two photoreactive diazirine derivatives of uridine were used to study contacts between 5S rRNA and 23 rRNA in situ in Escherichia coli ribosomes. 2'-Amino-2'-deoxy-uridine or 5-methyleneaminouridine were introduced into 5S rRNA by T7 transcription. After incorporation of these uridine analogues into the transcript their amino groups were modified with 4-[3-(trifluoromethyl)-3 H -diazirin-3-yl]benzyl isothiocyanate or the N -hydroxysuccinimide ester of 4-[3-(trifluoromethyl)-3 H -diazirin-3-yl]benzoic acid respectively. 5S rRNA carrying the photoreactive diazirine groups (referred to as the 2'-aminoribose derivative and the 5-methyleneamino derivative respectively) was reconstituted into 50S subunits or 70S ribosomes. After mild UV irradiation cross-links formed to 23S rRNA were analysed by standard procedures. All of the observed cross-links involved residue U89 of the 5S rRNA. Three nucleotides of 23S rRNA were cross-linked to this residue with the 5-methyleneamino derivative, namely U958, G1022 and G1138. With the 2'-aminoribose derivative a single cross-link was found, to U958. The significance of these cross-links for our understanding of the structure and function of 5S rRNA and its environment in the ribosome are discussed.

Loop IV of 5S ribosomal RNA has contacts both to domain II and to domain V of the 23S RNA

An analogue of 5S rRNA, containing a random distribution of thiouridine residues in place of normal uridine, was prepared by T7 transcription from a suitable DNA template. The modified RNA molecule was reconstituted into 50S or 70S ribosomes, and the thiouridine residues were activated by irradiation at 350 nm. Crosslinks generated between the 5S and 23S RNA were analyzed by our standard procedures. Two crosslink sites were identified, one to residue A-960 at the loop-end of helix 39 in Domain II, and the other to C-2475 at the loop-end of helix 89 in Domain V of the 23S RNA. Both crosslinks involved residue U-89 of the 5S RNA, that in Domain V corresponding to the principal crosslink found in a previously published series of experiments. The relative intensities of the two crosslink sites were found to be highly dependent on individual preparations of 50S ribosomal proteins and 23S RNA. The results are discussed in terms of the three-dimensional folding and dynamics of the 23S RNA within the 50S subunit.

Contacts between 16S ribosomal RNA and mRNA, within the spacer region separating the AUG initiator codon and the Shine-Dalgarno sequence; a site-directed cross-linking study

mRNA analogues containing several 4-thiouridine (thio-U) residues at selected positions were prepared by T7-transcription. The spacer region between the Shine-Dalgarno sequence and the AUG codon consisted of four or eight bases with a single thio-U at a variable position; alternatively, cro-mRNA analogues were used carrying the thio-U substituted spacer sequence UUGU. The mRNAs were bound to E. coli ribosomes, and--after irradiation--the sites of cross-linking to 16S RNA were analysed. Three cross-links to the 16S RNA from the spacer region were observed, namely to positions 665, 1360, and a site close to nucleotide 1530. The cross-links were formed in different amounts in the presence or absence of tRNA(fMet), and were observed from thio-U residues located at various positions within the spacer sequence, although in the presence of tRNA they were in general stronger from positions close to the Shine-Dalgarno end of the spacer. The cross-linking behaviour in this upstream area of the mRNA is thus rather different in character from the previously published pattern in the downstream area. From considerations of structural conservation in small subunit RNA, we propose that both the upstream and downstream cross-links to 16S RNA reflect a universal mRNA path through the ribosome.

Stem-loop IV of 5S rRNA lies close to the peptidyltransferase center

A DNA fragment containing the Escherichia coli 5S rDNA sequence linked to a T7 promoter was prepared by PCR from an M13 clone carrying the 5S-complementary sequence. The DNA was transcribed with T7 polymerase using a mixture of [alpha-32P]UTP and 4-thio-UTP, yielding a transcript in which approximately 18% of the uridine residues were randomly replaced by thiouridine. This modified 5S RNA could be reconstituted efficiently into 50S ribosomal subunits or 70S functional complexes. The reconstituted particles were irradiated at wavelengths above 300 nm, and the crosslinked ribosomal components were identified. A crosslink in high yield was reproducibly observed between the modified 5S RNA and 23S RNA, involving residue U-89 of the 5S RNA (at the loop end of helix IV) linked to nucleotide 2477 of the 23S RNA in the loop end of helix 89, immediately adjacent to the peptidyltransferase "ring." On the basis of this result, and in combination with earlier immunoelectron microscopic data, we propose a model for the orientation of the 5S RNA in the 50S subunit.

Site-directed cross-linking of mRNA analogues to 16S ribosomal RNA; a complete scan of cross-links from all positions between '+1' and '+16' on the mRNA, downstream from the decoding site

mRNA analogues containing 4-thiouridine residues at selected sites were used to extend our analysis of photo-induced cross-links between mRNA and 16S RNA to cover the entire downstream range between positions +1 and +16 on the mRNA (position +1 is the 5'-base of the P-site codon). No tRNA-dependent cross-links were observed from positions +1, +2, +3 or +5. Position +4 on the mRNA was cross-linked in a tRNA-dependent manner to 16S RNA at a site between nucleotides ca 1402-1415 (most probably to the modified residue 1402), and this was absolutely specific for the +4 position. Similarly, the previously observed cross-link to nucleotide 1052 was absolutely specific for the +6 position. The previously observed cross-links from +7 to nucleotide 1395 and from +11 to 532 were however seen to a lesser extent with certain types of mRNA sequence from neighbouring positions (+6 to +10, and +10 to +13, respectively); no tRNA-dependent cross-links to other sites on 16S RNA were found from these positions, and no cross-linking was seen from positions +14 to +16. In each case the effect of a second cognate tRNA (at the ribosomal A-site) on the level of cross-linking was studied, and the specificity of each cross-link was confirmed by translocation experiments with elongation factor G, using appropriate mRNA analogues.

Three widely separated positions in the 16S RNA lie in or close to the ribosomal decoding region; a site-directed cross-linking study with mRNA analogues

Synthetic mRNA analogues were prepared by T7 transcription, each containing several thio-uridine residues at selected positions. After binding to the ribosome in the presence of cognate tRNA, the thio-U residues were activated by UV irradiation and the resulting sites of cross-linking to 16S RNA analysed. Three distinct cross-links were consistently observed: (i) from position '+6' of the mRNA (the 3'-base of the A-site codon) to base 1052 of 16S RNA; (ii) from position '+7' of the mRNA to base 1395; and (iii) from '+11' to base 532. Individual yields of the cross-links were strongly dependent on the particular mRNA sequence in each case. The '+11/532' and '+6/1052' cross-links were always entirely tRNA-dependent, whereas the '+7/1395' cross-link was observed at lower intensity in the absence of tRNA. In the presence of a second (A-site bound) tRNA the +6/1052 cross-link was markedly reduced. A cross-link to the 1050 region was again observed when a message carrying a thio-U at position '+9' was translocated on the ribosome so as to bring the thio-U to position +6. Taken together, the data are incompatible with some current models both for the three-dimensional arrangement of 16S RNA and for the orientation of the tRNA-mRNA complex in the ribosome.

The location of mRNA in the ribosomal 30S initiation complex; site-directed cross-linking of mRNA analogues carrying several photo-reactive labels simultaneously on either side of the AUG start codon

Messenger RNA molecules 30-35 bases long, with sequences related to the 5'-region of cro-mRNA from lambda-phage, were prepared by T7 transcription from synthetic DNA templates. Each mRNA contained five or six internal uridine residues, which were transcribed using a mixture of UTP and thio-UTP. Initiation complexes were formed with Escherichia coli 30S ribosomes in the presence or absence of tRNA(fMet), and cross-linking of the thio-U residues was induced by UV irradiation at wavelengths greater than 300 nm. The cross-linked ribosomal proteins were identified immunologically, and cross-linked regions of the 16S RNA were isolated by excision with ribonuclease H and suitable deoxyoligonucleotides. In both cases, the particular thio-U residue involved in the cross-link was identified by ribonuclease T1 fingerprinting of the (radioactive) mRNA in the isolated cross-linked complex. The principal results were that, at thio-U positions upstream of the AUG codon, specific cross-linking occurred to protein S7 and to the 3'-terminus of the 16S RNA, in agreement with similar experiments using 70S ribosomes. Less specific cross-linking was observed to proteins S1, S18 and S21 at various positions within the mRNA. Six bases downstream from the AUG codon, a tRNA-dependent cross-link was found to position approximately 1050 of the 16S RNA, but--in contrast to similar experiments with 70S ribosomes--no cross-linking was found to the 1390-1400 region.