Active site labeling of Escherichia coli transcription elongation complexes with 5-[4-azidophenacyl)thio)uridine 5'-triphosphate

Efficient and Accurate Translation Initiation Directed by TISU Involves RPS3 and RPS10e Binding and Differential Eukaryotic Initiation Factor 1A Regulation

Canonical translation initiation involves ribosomal scanning, but short 5' untranslated region (5'UTR) mRNAs are translated in a scanning-independent manner. The extent and mechanism of scanning-independent translation are not fully understood. Here we report that short 5'UTR mRNAs constitute a substantial fraction of the translatome. Short 5'UTR mRNAs are enriched with TISU (translation initiator of short 5'UTR), a 12-nucleotide element directing efficient scanning-independent translation. Comprehensive mutagenesis revealed that each AUG codon-flanking nucleotide of TISU contributes to translational strength, but only a few are important for accuracy. Using site-specific UV cross-linking of ribosomal complexes assembled on TISU mRNA, we demonstrate specific binding of TISU to ribosomal proteins at the E and A sites. We identified RPS3 as the major TISU binding protein in the 48S complex A site. Upon 80S complex formation, RPS3 interaction is weakened and switched to RPS10e (formerly called RPS10). We further demonstrate that TISU is particularly dependent on eukaryotic initiation factor 1A (eIF1A) which interacts with both RPS3 and RPS10e. Our findings suggest that the cap-recruited ribosome specifically binds the TISU nucleotides at the A and E sites in cooperation with eIF1A to promote scanning arrest.

Balanced branching in transcription termination

The theory of stochastic transcription termination based on free-energy competition [von Hippel, P. H. & Yager, T. D. (1992) Science 255, 809-812 and von Hippel, P. H. & Yager, T. D. (1991) Proc. Natl. Acad. Sci. USA 88, 2307-2311] requires two or more reaction rates to be delicately balanced over a wide range of physical conditions. A large body of work on glasses and large molecules suggests that this balancing should be impossible in such a large system in the absence of a new organizing principle of matter. We review the experimental literature of termination and find no evidence for such a principle, but do find many troubling inconsistencies, most notably, anomalous memory effects. These effects suggest that termination has a deterministic component and may conceivably not be stochastic at all. We find that a key experiment by Wilson and von Hippel [Wilson, K. S. & von Hippel, P. H. (1994) J. Mol. Biol. 244, 36-51] thought to demonstrate stochastic termination was an incorrectly analyzed regulatory effect of Mg(2+) binding.

RNA-protein crosslinking to AMP residues at internal positions in RNA with a new photocrosslinking ATP analog

A new photocrosslinking purine analog was synthesized and evaluated as a transcription substrate for Escherichia coli RNA polymerase. This analog, 8-[(4-azidophenacyl)thio]adenosine 5'-triphosphate (8-APAS-ATP) contains an aryl azide photocrosslinking group that is attached to the ATP base via a sulfur-linked arm on the 8 position of the purine ring. This position is not involved in the normal Watson-Crick base pairing needed for specific hybridization. Although 8-APAS-ATP could not replace ATP as a substrate for transcription initiation, once stable elongation complexes were formed, 8-APAS-AMP could be site-specifically incorporated into the RNA, and this transcript could be further elongated, placing the photoreactive analog at internal positions in the RNA. Irradiation of transcription elongation complexes in which the RNA contained the analog exclusively at the 3' end of an RNA 22mer, or a 23mer with the analog 1 nt from the 3' end, produced RNA crosslinks to the RNA polymerase subunits that form the RNA 3' end binding site (beta, beta'). Both 8-APAS-AMP and the related 8-azido-AMP were subjected to conformational modeling as nucleoside monophosphates and in DNA-RNA hybrids. Surprisingly, the lowest energy conformation for 8-APAS-AMP was found to be syn, while that of 8-azido-AMP was anti, suggesting that the conformational properties and transcription substrate properties of 8-azido-ATP should be re-evaluated. Although the azide and linker together are larger in 8-APAS-ATP than in 8-N(3)-ATP, the flexibility of the linker itself allows this analog to adopt several different energetically favorable conformations, making it a good substrate for the RNA polymerase.

Nascent RNA in transcription complexes interacts with CspE, a small protein in E. coli implicated in chromatin condensation

Proteins in a partially fractionated Escherichia coli extract that interact with the nascent RNA in active transcription complexes from several promoters were detected using the photocrosslinking ribonucleotide analogs 5-(azidophenacyl)thio-UTP or 5-(azidophenacyl)thio-CTP as transcription substrates. Upon irradiation of ternary transcription complexes, several extract proteins were crosslinked to the RNA. Most notably, a small protein was crosslinked to the RNA in complexes on seven of nine templates tested. This protein was purified and sequenced and found to match a hypothetical protein, MsmC/CspE, recently shown to be involved in chromatin partitioning. CspE has 69% amino acid sequence identity with the major cold shock protein in E. coli, CspA, which has been shown to bind to a DNA sequence designated the Y box, with the sequence 5'-ATTGG. Of the nine templates tested, CspE was found to be most heavily crosslinked to RNA from the lambda PR' promoter, which is modified by the Q antiterminator protein. CspE was very heavily crosslinked to RNA only ten nucleotides long in initial ternary complexes on this promoter, but not to this same RNA after it had been released from the transcription complex. However, even when present from the start of transcription, CspE did not crosslink to the RNA 82 nucleotides long in elongation complexes from this same promoter. Despite the loss of interaction with the RNA after polymerase had left the promoter, CspE inhibited Q-mediated transcriptional antitermination from PR' in vitro almost 200 nucleotides downstream from the promoter, presumably by interaction with the Y box DNA upstream from PR', which overlaps with the binding site for the Q. A potential role for CspE and transcription in chromosome condensation and nucleoid structure is discussed.

Synthesis and characterization of a new 5-thiol-protected deoxyuridine phosphoramidite for site-specific modification of DNA

A new nucleotide analogue was developed for site-specific incorporation of a reactive thiol group into DNA. This creates a unique site for the post-synthetic modification of that nucleotide with a variety of molecular tags, such as photo-cross-linkers and fluorescent or spin-label moieties. 5'-O-(4,4'-Dimethoxytrityl)-5-[S-(2,4-dinitrophenyl)thio]-2'-deoxyuridin e 3'-O-(2-cyanoethyl N,N'-diisopropylphosphoramidite) was synthesized and incorporated at internal positions in several oligonucleotides using automated DNA synthesis and standard phosphoramidite chemistry. The coupling yield of the analogue was comparable to the coupling yield for a standard phosphoramidite, and no significant differences were observed in the overall yields of the dinitrophenyl-labeled oligonucleotides compared to the corresponding unmodified oligonucleotides. Characterization of the dinitrophenyl-modified oligonucleotides included enzymatic degradation, HPLC chromatography, and gel electrophoresis. Deprotection of the mercaptan group with beta-mercaptoethanol yielded an oligonucleotide containing 5-mercaptodeoxyuridine which was then selectively modified, without purification, by reaction with 5-(iodoacetamido)fluorescein. Incorporation of the dinitrophenyl-modified oligonucleotide into double-stranded DNA was achieved using the polymerase chain reaction. CHaracterization of the dinitrophenyl-labeled product by immunodetection with anti-dinitrophenyl antibodies confirmed the stability of the protecting group to the thermocycling and thus established the use of this thiol-protected mercaptodeoxyuridine phosphoramidite for preparation of site-specifically modified DNA.

Termination-altering amino acid substitutions in the beta' subunit of Escherichia coli RNA polymerase identify regions involved in RNA chain elongation

To identify regions of the largest subunit of RNA polymerase that are potentially involved in transcript elongation and termination, we have characterized amino acid substitutions in the beta' subunit of Escherichia coli RNA polymerase that alter expression of reporter genes preceded by terminators in vivo. Termination-altering substitutions occurred in discrete segments of beta', designated 2, 3a, 3b, 4a, 4b, 4c, and 5, many of which are highly conserved in eukaryotic homologs of beta'. Region 2 substitutions (residues 311-386) are tightly clustered around a short sequence that is similar to a portion of the DNA-binding cleft in E. coli DNA polymerase I. Region 3b (residues 718-798) corresponds to the segment of the largest subunit of RNA polymerase II in which amanitin-resistance substitutions occur. Region 4a substitutions (residues 933-936) occur in a segment thought to contact the transcript 3' end. Region 5 substitutions (residues 1308-1356) are tightly clustered in conserved region H near the carboxyl terminus of beta'. A representative set of mutant RNA polymerases were purified and revealed unexpected variation in percent termination at six different rho-independent terminators. Based on the location and properties of these substitutions, we suggest a hypothesis for the relationship of subunits in the transcription complex.

Characterization of a Max:DNA complex by cross-linking to photoactive oligonucleotides

The structure of the Max:DNA complex was investigated by cross-linking Max to a series of photoactive oligonucleotides. A single photoactive aryl azide was introduced into oligonucleotides at defined positions downstream from the specific CACGTG binding site. Purified Max homodimers bound to and were cross-linked to oligonucleotides containing a photoactive group either 2, 5, 8, or 11 bp downstream from the binding site. Further analysis revealed that an amino-terminal chymotryptic peptide of Max was cross-linked to the oligonucleotide containing a photoactive probe 11 bp downstream from the specific binding site. This result is consistent with the recent crystal structure of the Max:DNA complex (Ferré-D'Amaré et al., 1993) and further suggests that amino acid residues near the amino-terminus of Max are in close proximity to a region of DNA that is separated from the core binding site by one turn of the double helix.

NusA changes the conformation of Escherichia coli RNA polymerase at the binding site for the 3' end of the nascent RNA

A conformational change in Escherichia coli RNA polymerase induced by NusA was detected by utilizing photocrosslinking. A change in the binding site for the 3' end of the RNA occurred, and NusA increased interactions of the RNA with the beta subunit of the polymerase. NusA was not contacted by the 3' end of the RNA.

Wheat germ and yeast RNA polymerase II: photoaffinity labeling by 4-thiouracil 5'-monophosphate positioned uniquely at the 3' end of an enzyme-bound [32P]-containing transcript

A stable ternary transcription complex was formed with either wheat germ or yeast RNA polymerase II using a ribotrinucleotide primer (GpCpG) to initiate transcription on a short synthetic single-strand DNA template. The template was designed to limit the incorporation of a photoprobe S4-UMP (4-thio-UMP) to a unique position at the 3' terminus of the transcript. The resulting stable ternary transcription complex was photolyzed to cross-link the bound transcript ([32P]-labeled by the incorporation of [alpha-32P]CMP) with the protein domain at or near the active site. Separation of the protein components by electrophoresis in polyacrylamide gel containing SDS and analysis by autoradiography and silver staining revealed that for either enzyme only the largest subunit was [32P] labeled.

Structural analysis of ternary complexes of Escherichia coli RNA polymerase. Individual complexes halted along different transcription units have distinct and unexpected biochemical properties

Ternary complexes containing RNA polymerase, DNA and nascent RNA are intermediates in all RNA syntheses and are the targets of cellular factors that regulate RNA chain elongation and termination. Hence, elucidation of the structure and properties of these complexes is essential for understanding the catalytic and regulatory properties of the enzyme. We have described methods to prepare ternary complexes halted at defined positions along the DNA template, using specific dinucleotides to prime chain initiation along with limited subsets of the NTP substrates. Study of these static, halted complexes may provide information about the structure and properties of the transient elongation intermediates involved in transcription, although there is no necessary direct relationship between the two. Using specific halted complexes as precursors, we have walked the RNA polymerase along its template, producing defined ternary complexes at unique sites along two different transcription units. These complexes differ significantly from one another in many biochemical properties, in dramatic contrast to the properties expected from models that postulate a monotonous structure for elongation intermediates. These differences include variations in complex mobility during electrophoresis in non-denaturing polyacrylamide gels, in thermal stability and in stability to dissociation. Some halted complexes lose the ability to resume elongation when presented with the missing substrates. These "dead end" complexes must represent metastable structures in which elongation is blocked, and demonstrate clearly that not all halted complexes can be considered true intermediates in elongation. Other halted complexes rapidly cleave the nascent RNA seven nucleotides from the 3' terminus, in an unexpected and unusual biochemical reaction. These differences in properties among complexes bearing transcripts that differ by only one or a few nucleotides suggest that they have distinct structures. These differences must be due, at least in part, to differences in the template sequence and the length of the transcript. The results raise important questions as to the actual mechanism of transcription elongation, and suggest that it is a much more complex process than previously assumed.

Sigma subunit of Escherichia coli RNA polymerase loses contacts with the 3' end of the nascent RNA after synthesis of a tetranucleotide

We have used photocrosslinking to analyze the contacts between the 3' end of the RNA and Escherichia coli RNA polymerase during the early steps of RNA synthesis using the nucleotide analog 8-azido-ATP (8-N3-ATP). The crosslinking group on 8-N3-ATP contacts the beta, beta' and sigma subunits when the analog is bound to the holoenzyme. We show here that 8-N3-ATP is a substrate for E. coli RNA polymerase and acts as an RNA chain terminator when incorporated into the 3' end of nascent RNA. 8-N3-AMP was incorporated uniquely at the 3' end of tri-, tetra- and pentanucleotides synthesized from a poly[d(A-T)] template and at the 3' end of pentanucleotides from two promoters (lambda PR' and E. coli rrnB P1). The oligonucleotides were covalently attached to the RNA polymerase by irradiation of transcription complexes with ultraviolet light. All RNAs labeled the beta and beta' subunits, but sigma was contacted only by the trinucleotide and tetranucleotide on poly[d(A-T)]. Sigma is still present in transcription complexes containing the pentanucleotide on poly[d(A-T)], despite the lack of labeling. Neither pentanucleotide from the authentic promoters contacted sigma. We conclude that as holoenzyme moves downstream, either two separate conformational changes occur, after synthesis of the trinucleotide and tetranucleotide, which result in movement of sigma away from the nucleotide binding site or, alternatively, sigma remains fixed relative to the DNA while the domain on core polymerase forming the nucleotide binding site moves downstream.

RNA-protein interactions in a Nus A-containing Escherichia coli transcription complex paused at an RNA hairpin

We have isolated Escherichia coli transcription complexes, paused in the presence and absence of Nus A, which contain RNA substituted at every UMP residue with a photocrosslinking nucleotide analog. The pause site is immediately downstream from an RNA stem-loop structure, and although pausing occurs in the absence of Nus A, it is substantially enhanced in the presence of Nus A. We have analyzed the secondary structure of this RNA and show that the analog does not interfere with the formation of the normal stem-loop structures. Additionally, the analog substrate does not alter transcriptional pausing, in the presence or absence of Nus A, indicating that Nus A recognition of the transcription complex is not affected by the presence of the crosslinking groups in the RNA. Ribonuclease digestion of the RNA in paused complexes identifies two accessible regions, two nucleotides in the loop and one near the base of the upstream side of the stem-loop. Cleavage at one loop nucleotide is enhanced by Nus A, while the nucleotide near the base of the stem-loop is partially protected. Upon irradiation of the transcription complex, Nus A is not photoaffinity labeled by the RNA, even at a high molar ration to RNA polymerase (250:1). Both the beta and beta' subunits are labeled, however, indicating that the putative stem-loop binding domain on the core polymerase involves both subunits. Because the nucleotide protected from ribonuclease by Nus A is very near two analogs, yet Nus A is not crosslinked to the RNA, it is unlikely that Nus A could be protecting this position through direct contact. Furthermore, analog is substituted at positions in both the loop and at several positions in the stem, and again, no crosslinking to Nus A is observed. We conclude that enhancement of pausing by Nus A probably does not require direct interaction with the bases in the RNA stem-loop.

Protein-DNA cross-linking demonstrates stepwise ATP-dependent assembly of T4 DNA polymerase and its accessory proteins on the primer-template

T4 DNA polymerase, the 44/62 and 45 polymerase accessory proteins, and 32 single-stranded DNA-binding protein catalyze ATP-dependent DNA synthesis. Using DNA primers with cross-linkable residues at specific positions, we obtained structural data that reveal how these proteins assemble on the primer-template. With the nonhydrolyzable ATP analog ATP gamma S, assembly of the 44/62 and 45 proteins on the primer requires 32 protein but not polymerase. ATP hydrolysis changes the position and intensity of cross-linking to each of the accessory proteins and allows cross-linking of polymerase. Our data indicate that the initial binding of the three accessory proteins and ATP to a 32 protein-covered primer-template is followed by ATP hydrolysis, binding of polymerase, and movement of the accessory proteins to yield a complex capable of processive DNA synthesis.