GreA and GreB proteins revive backtracked RNA polymerase in vivo by promoting transcript trimming.

The GreA and GreB proteins of Escherichia coli show a multitude of effects on transcription elongation in vitro, yet their physiological functions are poorly understood. Here, we investigated whether and how these factors influence lateral oscillations of RNA polymerase (RNAP) in vivo, observed at a protein readblock. When RNAP is stalled within an (ATC/TAG)(n) sequence, it appears to oscillate between an upstream and a downstream position on the template, 3 bp apart, with concomitant trimming of the transcript 3' terminus and its re-synthesis. Using a set of mutant E.coli strains, we show that the presence of GreA or GreB in the cell is essential to induce this trimming. We show further that in contrast to a ternary complex that is stabilized at the downstream position, the oscillating complex relies heavily on the GreA/GreB-induced 'cleavage-and-restart' process to become catalytically competent. Clearly, by promoting transcript shortening and re-alignment of the catalytic register, the Gre factors function in vivo to rescue RNAP from being arrested at template positions where the lateral stability of the ternary complex is impaired.

In vivo evidence for back and forth oscillations of the transcription elongation complex.

We have used a combination of DNA and RNA footprinting experiments to analyze the structural rearrangements experienced by a transcription elongation complex that was halted in vivo by a protein readblock. We show that the complex readblocked within an (ATC/TAG)(n) sequence is in a dynamic equilibrium between upstream- and downstream- translocated conformers. By increasing the strength of the putative RNA-DNA hybrid, the ternary complex is readily trapped in the downstream-translocated conformation, where the melted DNA region is limited to 8 bp. The shift of the equilibrium towards the downstream location is also achieved by introducing within the 5' end of the message an RNA sequence that can pair with a segment of the transcript in the vicinity of the halted ternary complex. Our results demonstrate that within certain template DNA sequences, the back and forth oscillations of the ternary complex actually occur in a multipolymerase system and inside the cell. Furthermore, the cis-acting effect of the upstream RNA sequence underscores an important phenomenon in gene regulation where a transcript may regulate its own elongation.

Preferential binding of the archaebacterial histone-like MC1 protein to negatively supercoiled DNA minicircles.

The interaction of the archaebacterial MC1 protein with 207 bp negatively supercoiled DNA minicircles has been examined by gel retardation assays and compared to that observed with the relaxed DNA minicircle. MC1 binding induces a drastic DNA conformational change of each minicircle, leading to an increase of the electrophoretic mobility of the DNA. A slight increase in salt concentration enhances the amount of bound MC1, and high NaCl concentrations are required to dissociate the complexes. Furthermore, the salt effect on binding depends on the supercoiling state of the DNA. The dissociation rates decrease with increasing linking difference of the minicircles relative to their relaxed configuration to reach a maximum at -2 turns. In addition, differences between the topoisomers are also observed in terms of stoichiometry of the strongest complexes. So with the -2 topoisomer the complex with two MC1 molecules is the most stable, while with the -1 and -3 topoisomers, the strongest ones are those with one MC1 molecule per DNA ring.

Conformational changes of DNA minicircles upon the binding of the archaebacterial histone-like protein MC1.

Binding of the archaebacterial histone-like protein MC1 to DNA minicircles has been examined by gel retardation and electron microscopy. MC1 preferentially binds to a 207-base pair relaxed DNA minicircle as compared with the linear fragment. Random binding is observed at very low ionic strength, and a slight increase in salt concentration highly favors the formation of a complex that corresponds to the binding of two MC1 molecules per DNA ring. Measurements of dissociation rates show that this complex is remarkably stable, and electron microscopy reveals that it is characterized by two diametrically opposed kinks. These results are discussed in regard to the mechanisms by which MC1 affects DNA structure.

Fluorescence study on the non-specific binding of cyclic-AMP receptor protein to DNA: effect of pH.

The binding of the cyclic-AMP receptor protein (CRP) of Escherichia coli to a non-specific DNA fragment of 46 base pairs has been studied using fluorescence spectroscopy. The equilibrium binding constant was found to be several orders of magnitude lower than in the specific binding to a DNA fragment of the same size. The salt dependence of the equilibrium binding constant indicates that the CRP makes an identical number (8) of ion pairs to this non-specific DNA fragment in the presence and absence of cAMP. This number is larger than that previously found in the specific binding process. The effect of pH on the non-specific binding was investigated. The number of ion pairs does not vary between pH 6 and 8. From the variation of the binding constant with pH it was deduced that two histidines are involved in the binding in the absence of cAMP. These are most probably the histidines 199 of each subunit. In the presence of cAMP, only one histidine participates in the binding process, indicating an asymmetric interaction between the two subunits of the CRP and the DNA.

Specific binding of cyclic-AMP receptor protein to DNA. Effect of the sequence and of the introduction of a nick in the binding site.

The binding of Escherichia coli Cyclic AMP Receptor Protein (CRP) to several DNA fragments of about 45 base pairs, bearing the natural lactose or galactose sites, as well as several synthetic related sites, was investigated using fluorescence spectroscopy and gel retardation experiments. The salt dependence of the equilibrium binding constant indicates that CRP makes an identical number of ion pairs with the lac, lacL8 and gal sites although the binding constants are drastically different. However increasing the symmetry of the gal site leads to an increase of the number of ion pairs between the protein and the DNA. A single strand nick was introduced at the centre of a symmetrized gal site and this reduces the binding energy of CRP by about 0.6 Kcal. These results are discussed with respect to the bending constraints imposed on the DNA by the binding of CRP. The results are in agreement with the recently published crystal structure of the CRP complexed with DNA [Schutz, S.C., Shields, G.C. and Steitz, T.A., Science 253, 1001-1007 (1991)] showing that the 90 degrees bending of the DNA in the complex results from two kinks.

Oligodeoxynucleotides covalently linked to intercalating agents: a new class of gene regulatory substances.

Oligodeoxynucleotides have been covalently linked to a 9-aminoacridine derivative via their 3'-phosphate group. Specific complexes are formed with the complementary sequence of the oligonucleotide. The stability is strongly increased due to intercalation of the acridine derivative. Absorption, fluorescence, nuclear magnetic resonance and circular dichroism have been used to characterize complex formation. The stability of the complexes depends on the length of the linker between the acridine derivative and the 3'-phosphate group of the oligonucleotide. Oligonucleotides covalently linked to an intercalating agent can be used to selectively control gene expression. Transcription initiation can be blocked when such an oligonucleotide binds to the transcribed strand in the open complex formed by E. coli RNA polymerase with the bla promoter. With some oligonucleotides, non-specific effects on transcription can be detected, most probably due to binding of the modified oligonucleotide to RNA polymerase. Translation of the messenger RNA from gene 32 of phage T4 can be prevented by using an oligonucleotide complementary to the sequence upstream from the Shine-Dalgarno sequence. Inhibition of translation does not occur in the absence of the intercalating agent covalently linked to the oligonucleotide nor with oligonucleotides which do not have a target sequence on the mRNA.

Nucleic acid-binding molecules with high affinity and base sequence specificity: intercalating agents covalently linked to oligodeoxynucleotides.

Oligodeoxyribonucleotides covalently linked to an intercalating agent via a polymethylene linker were synthesized. Oligothymidylates attached to an acridine dye (Acr) through the 3'-phosphate group [(Tp)n(CH2) mAcr ] specifically interact with the complementary sequence. The interaction is strongly stabilized by the intercalating agent. By using absorption and fluorescence spectroscopies, it is shown that complex formation between (Tp)n(CH2) mAcr and poly(rA) involves the formation of n A X T base pairs, where n is the number of thymines in the oligonucleotide. The acridine ring intercalates between A X T base pairs. Fluorescence excitation spectra reveal the existence of two environments for the acridine ring, whose relative contributions depend on the linker length (m). The binding of (Tp)4(CH2) mAcr to poly(rA) is analyzed in terms of site binding and cooperative interactions between oligonucleotides along the polynucleotide lattice. Thermodynamic parameters show that the covalent attachment of the acridine ring strongly stabilizes the binding of the oligonucleotide to its complementary sequence. The stabilization depends on the linker length; the compound with m = 5 gives a more stable complex than that with m = 3. These results open the way to the synthesis of a family of molecules exhibiting both high-affinity and high-specificity for a nucleic acid base sequence.

Oligodeoxynucleotides covalently linked to intercalating dyes as base sequence-specific ligands. Influence of dye attachment site.

New molecules with high and specific affinity for nucleic acid base sequences have been synthesized. They involve an oligodeoxynucleotide covalently attached to an intercalating dye. Visible absorption spectroscopy and fluorescence have been used to investigate the binding of poly(rA) to octadeoxythymidylates substituted by a 9-aminoacridine derivative in different positions along the oligonucleotide chain. The 9-amino group of the acridine dye was linked through a polymethylene bridge to the 3'-phosphate, the 5'-phosphate, the fourth internucleotidic phosphate or to both the 3'- and 5'-phosphates. Different interactions of the acridine dye were exhibited by these different substituted oligodeoxynucleotides when they bind to poly(rA). The interaction was shown to be specific for adenine-containing polynucleotides. The stability of these complexes was compared with that of oligodeoxynucleotides substituted by an alkyl group on the 3'-phosphate. The increase in stability due to the presence of the intercalating dye has been determined from the comparison of melting temperatures. These results are discussed with respect to the strategy of synthesis of a new class of molecules with high affinity and high specificity for nucleic acid base sequences.

[Inhibition of the 3' to 5' exonuclease activity of the DNA polymerase I of Escherichia coli by deoxyribonucleotides]. / Inhibition de l'activité exonucléase 3' à 5' de la DNA polymérase I d'Escherichia coli par les désoxyribonucléotides.

The 3' à 5' exonuclease activity of E. coli DNA-polymerase I is inhibited by nucleotides and deoxynucleotides at concentrations (< 1 mM) where polymerase activity is not affected. This inhibitory effect depends on the nature of the excised deoxynucleotide, excision of purines being much less inhibited than that of pyrimidines. It does not depend on the purine or pyrimidine nature of the inhibitor.

Binding of a tryptophan-containing peptide (lysyltryptophyllysine) to deoxyribonucleic acid modified by 2-(N-acetoxyacetylamino)fluorene.

The binding of the tripeptide Lys-Trp-Lys to DNA modified by reaction with the chemical carcinogen 2-(N-acetoxyacetylamino)fluorene (AAAF) has been investigated by fluorescence spectroscopy. A quenching of tryptophan fluorescence was observed which increased when the degree of base substitution by AAAF increased. Similar results were obtained with the 7-iodo derivative of AAAF (AAAIF). Two hypotheses are discussed which could account for the experimental results: (1) stacking interactions of the tryptophyl residue of the peptide with nucleic acid bases in locally unpaired regions in the vicinity of modified bases; (2) energy transfer from the tryptophyl residue of the peptide to acetylaminofluorene bound to guanine bases without direct interaction of this residue with nucleic acid bases (outside binding). The results obtained with denatured DNA in the absence and the presence of chemical modifications by AAAF or AAAIF allow us to conclude that energy transfer contributes to fluorescence quenching in the case of AAIF but not in that of AAF. Stacking interactions are therefore responsible for fluorescence quenching of Lys-Trp-Lys when bound to AAF-modified DNA. In the case of DNA-AAIF, fluorescence quenching is due both to energy transfer and to stacking of the tryptophan ring with bases inside the helix. These results are discussed in relation to what is already known in terms of local structure and with respect to the role that could be played by aromatic residues of proteins in the recognition of chemically damaged DNA.

The role of tyrosine in the association of proteins and nucleic acids. Specific recognition of single-stranded nucleic acids by tyrosine-containing peptides.

Oligopeptides containing tyrosyl, lysyl, and alanyl residues bind to polynucleotides and nucleic acids as shown by proton magnetic resonance, fluorescence spectroscopy, and difference absorption spectroscopy. Proton magnetic resonance data indicate that stacking of tyrosyl residues with nucleic acid bases takes place only in single-stranded structures (such as poly(A) or denatured DNA). Stacking interactions lead to a quenching of tyrosine fluorescence. However, the tyrosyl fluorescence of the peptides is quenched in their complexes with both single-stranded and double-stranded nucleic acids. A comparison of the behavior of homologous peptides containing Tyr, methoxytyrosine, and Phe leads to the conclusion that hydrogen bonding of tyrosine with bases or phosphates is not involved in the investigated complexes. An energy transfer mechanism from tyrosine to nucleic acid bases is proposed to account for fluorescence quenching in oligopeptide complexes with double-stranded DNAs. Due to the specificity of its stacking interaction for single-stranded nucleic acid structures, tyrosine might be involved through such interactions in the selective recognition of single strands by proteins.