Insights into the regulation of transcription by scanning force microscopy

The scanning force microscope (SFM) is a valuable tool for the structural analysis of complexes between protein(s) and DNA. In recent years the application of scanning force microscopy to the field of transcription regulation has been reported in numerous studies. Using this technique, novel insights could be obtained into the architecture and dynamics of complexes, which are relevant to the transcription process and the mechanisms by which this process is regulated. In this article an overview is given of SFM studies addressing, in particular, topics in the field of transcription in prokaryotic organisms.

Solution structure, hydrodynamics and thermodynamics of the UvrB C-terminal domain

The solution structure, thermodynamic stability and hydrodynamic properties of the 55-residue C-terminal domain of UvrB that interacts with UvrC during excision repair in E. coli have been determined using a combination of high resolution NMR, ultracentrifugation, 15N NMR relaxation, gel permeation, NMR diffusion, circular dichroism and differential scanning calorimetry. The subunit molecular weight is 7,438 kDa., compared with 14.5+/-1.0 kDa. determined by equilibrium sedimentation, indicating a dimeric structure. The structure determined from NMR showed a stable dimer of anti-parallel helical hairpins that associate in an unusual manner, with a small and hydrophobic interface. The Stokes radius of the protein decreases from a high plateau value (ca. 22 A) at protein concentrations greater than 4 microM to about 18 A at concentrations less than 0.1 microM. The concentration and temperature-dependence of the far UV circular dichroism show that the protein is thermally stable (Tm ca. 71.5 degrees C at 36 microM). The simplest model consistent with these data was a dimer dissociating into folded monomers that then unfolds co-operatively. The van't Hoff enthalpy and dissociation constant for both transition was derived by fitting, with deltaH1=23 kJ mol(-1). K1(298)=0.4 microM and deltaH2= 184 kJ mol(-1). This is in good agreement with direct calorimetric analysis of the thermal unfolding of the protein, which gave a calorimetric enthalpy change of 181 kJ mol(-1) and a van't Hoff enthalpy change of 354 kJ mol(-1), confirming the dimer to monomer unfolding. The thermodynamic data can be reconciled with the observed mode of dimerisation. 15N NMR relaxation measurements at 14.1 T and 11.75 T confirmed that the protein behaves as an asymmetric dimer at mM concentrations, with a flexible N-terminal linker for attachment to the remainder of the UvrB protein. The role of dimerisation of this domain in the excision repair mechanism is discussed.

Role of ATP hydrolysis by UvrA and UvrB during nucleotide excision repair

Nucleotide excision repair in eubacteria is a process that repairs DNA damages by the removal of a 12-13-mer oligonucleotide containing the lesion. Recognition and cleavage of the damaged DNA is a multistep ATP-dependent reaction that requires the UvrA, UvrB and UvrC proteins. Both UvrA and UvrB are ATPases, with UvrA having two ATP binding sites which have the characteristic signature of the family of ABC proteins and UvrB having one ATP binding site that is structurally related to that of helicases.

Structural basis for preferential binding of H-NS to curved DNA

The Escherichia coli H-NS protein is a nucleoid-associated protein involved in transcription regulation and DNA compaction. H-NS exerts its role in DNA condensation by non-specific interactions with DNA. With respect to transcription regulation preferential binding sites in the promoter regions of different genes have been reported. In this paper we describe the analysis of H-NS-DNA complexes on a preferred H-NS binding site by atomic force microscopy. On the basis of these data we present a model for the specific recognition of DNA by H-NS as a function of DNA curvature.

Role of the Escherichia coli nucleotide excision repair proteins in DNA replication

DNA polymerase I (PolI) functions both in nucleotide excision repair (NER) and in the processing of Okazaki fragments that are generated on the lagging strand during DNA replication. Escherichia coli cells completely lacking the PolI enzyme are viable as long as they are grown on minimal medium. Here we show that viability is fully dependent on the presence of functional UvrA, UvrB, and UvrD (helicase II) proteins but does not require UvrC. In contrast, delta polA cells grow even better when the uvrC gene has been deleted. Apparently UvrA, UvrB, and UvrD are needed in a replication backup system that replaces the PolI function, and UvrC interferes with this alternative replication pathway. With specific mutants of UvrC we could show that the inhibitory effect of this protein is related to its catalytic activity that on damaged DNA is responsible for the 3' incision reaction. Specific mutants of UvrA and UvrB were also studied for their capacity to support the PolI-independent replication. Deletion of the UvrC-binding domain of UvrB resulted in a phenotype similar to that caused by deletion of the uvrC gene, showing that the inhibitory incision activity of UvrC is mediated via binding to UvrB. A mutation in the N-terminal zinc finger domain of UvrA does not affect NER in vivo or in vitro. The same mutation, however, does give inviability in combination with the delta polA mutation. Apparently the N-terminal zinc-binding domain of UvrA has specifically evolved for a function outside DNA repair. A model for the function of the UvrA, UvrB, and UvrD proteins in the alternative replication pathway is discussed.

H-NS mediated compaction of DNA visualised by atomic force microscopy

The Escherichia coli H-NS protein is a nucleoid-associated protein involved in gene regulation and DNA compaction. To get more insight into the mechanism of DNA compaction we applied atomic force microscopy (AFM) to study the structure of H-NS-DNA complexes. On circular DNA molecules two different levels of H-NS induced condensation were observed. H-NS induced lateral condensation of large regions of the plasmid. In addition, large globular structures were identified that incorporated a considerable amount of DNA. The formation of these globular structures appeared not to be dependent on any specific sequence. On the basis of the AFM images, a model for global condensation of the chromosomal DNA by H-NS is proposed.

The role of ATP binding and hydrolysis by UvrB during nucleotide excision repair

We have isolated UvrB-DNA complexes by capture of biotinylated damaged DNA substrates on streptavidin-coated magnetic beads. With this method the UvrB-DNA preincision complex remains stable even in the absence of ATP. For the binding of UvrC to the UvrB-DNA complex no cofactor is needed. The subsequent induction of 3' incision does require ATP binding by UvrB but not hydrolysis. This ATP binding induces a conformational change in the DNA, resulting in the appearance of the DNase I-hypersensitive site at the 5' side of the damage. In contrast, the 5' incision is not dependent on ATP binding because it occurs with the same efficiency with ADP. We show with competition experiments that both incision reactions are induced by the binding of the same UvrC molecule. A DNA substrate containing damage close to the 5' end of the damaged strand is specifically bound by UvrB in the absence of UvrA and ATP (Moolenaar, G. F., Monaco, V., van der Marel, G. A., van Boom, J. H., Visse, R., and Goosen, N. (2000) J. Biol. Chem. 275, 8038-8043). To initiate the formation of an active UvrBC-DNA incision complex, however, UvrB first needs to hydrolyze ATP, and subsequently a new ATP molecule must be bound. Implications of these findings for the mechanism of the UvrA-mediated formation of the UvrB-DNA preincision complex will be discussed.

The effect of the DNA flanking the lesion on formation of the UvrB-DNA preincision complex. Mechanism for the UvrA-mediated loading of UvrB onto a DNA damaged site

The UvrB-DNA preincision complex plays a key role in nucleotide excision repair in Escherichia coli. To study the formation of this complex, derivatives of a DNA substrate containing a cholesterol adduct were constructed. Introduction of a single strand nick into either the top or the bottom strand at the 3' side of the adduct stabilized the UvrB-DNA complex, most likely by the release of local stress in the DNA. Removal of both DNA strands up to the 3' incision site still allowed formation of the preincision complex. Similar modifications at the 5' side of the damage, however, gave different results. The introduction of a single strand nick at the 5' incision site completely abolished the UvrA-mediated formation of the UvrB-DNA complex. Deletion of both DNA strands up to the 5' incision site also prevented the UvrA-mediated loading of UvrB onto the damaged site, but UvrB by itself could bind very efficiently. This demonstrates that the UvrB protein is capable of recognizing damage without the matchmaker function of the UvrA protein. Our results also indicate that the UvrA-mediated loading of the UvrB protein is an asymmetric process, which starts at the 5' side of the damage.

Catalytic sites for 3' and 5' incision of Escherichia coli nucleotide excision repair are both located in UvrC

Nucleotide excision repair in Escherichia coli is a multistep process in which DNA damage is removed by incision of the DNA on both sides of the damage, followed by removal of the oligonucleotide containing the lesion. The two incision reactions take place in a complex of damaged DNA with UvrB and UvrC. It has been shown (Lin, J. -J., and Sancar, A. (1992) J. Biol. Chem. 267, 17688-17692) that the catalytic site for incision on the 5' side of the damage is located in the UvrC protein. Here we show that the catalytic site for incision on the 3' side is in this protein as well, because substitution R42A abolishes 3' incision, whereas formation of the UvrBC-DNA complex and the 5' incision reaction are unaffected. Arg(42) is part of a region that is homologous to the catalytic domain of the homing endonuclease I-TevI. We propose that the UvrC protein consists of two functional parts, with the N-terminal half for the 3' incision reaction and the C-terminal half containing all the determinants for the 5' incision reaction.

Crystal structure of Escherichia coli UvrB C-terminal domain, and a model for UvrB-uvrC interaction

A crystal structure of the C-terminal domain of Escherichia coli UvrB (UvrB') has been solved to 3.0 A resolution. The domain adopts a helix-loop-helix fold which is stabilised by the packing of hydrophobic side-chains between helices. From the UvrB' fold, a model for a domain of UvrC (UvrC') that has high sequence homology with UvrB' has been made. In the crystal, a dimerisation of UvrB domains is seen involving specific hydrophobic and salt bridge interactions between residues in and close to the loop region of the domain. It is proposed that a homologous mode of interaction may occur between UvrB and UvrC. This interaction is likely to be flexible, potentially spanning > 50 A.

Synthesis and biological evaluation of modified DNA fragments for the study of nucleotide excision repair in E. coli

Three new cholesterol-containing phosphoramidites where synthesized and used in automated synthesis of modified DNA fragments. These cholesterol lesions are good substrates for the E. coli UvrABC endonuclease. In vitro they are incised from damaged DNA with higher efficiency in respect with the cholesterol lesions previously published.

NMR assignments and secondary structure of the UvrC binding domain of UvrB

The 55 residue C-terminal domain of UvrB that interacts with UvrC during excision repair in Escherichia coli has been expressed and purified as a (His)6 fusion construct. The fragment forms a stable folded domain in solution. Heteronuclear NMR experiments were used to obtain extensive 15N, 13C and 1H NMR assignments. NOESY and chemical shift data showed that the protein comprises two helices from residues 630 to 648 and from 652 to 670. 15N relaxation data also show that the first 11 and last three residues are unstructured. The effective rotational correlation time within the structured region is not consistent with a monomer. This oligomerisation may be relevant to the mode of dimerisation of UvrB with the homologous domain of UvrC.

Characterization of the Escherichia coli damage-independent UvrBC endonuclease activity

Incision of damaged DNA templates by UvrBC in Escherichia coli depends on UvrA, which loads UvrB on the site of the damage. A 50-base pair 3' prenicked DNA substrate containing a cholesterol lesion is incised by UvrABC at two positions 5' to the lesion, the first incision at the eighth and the second at the 15th phosphodiester bond. Analysis of a 5' prenicked cholesterol substrate revealed that the second 5' incision is efficiently produced by UvrBC independent of UvrA. This UvrBC incision was also found on the same substrate without a lesion and, with an even higher efficiency, on a DNA substrate containing a 5' single strand overhang. Incision occurred in the presence of ATP or ADP but not in the absence of cofactor. We could show an interaction between UvrB and UvrC in solution and subsequent binding of this complex to the substrate with a 5' single strand overhang. Analysis of mutant UvrB and UvrC proteins revealed that the damage-independent nuclease activity requires the protein-protein interaction domains, which are exclusively needed for the 3' incision on damaged substrates. However, the UvrBC incision uses the catalytic site in UvrC which makes the 5' incision on damaged DNA substrates.

The C-terminal region of the Escherichia coli UvrC protein, which is homologous to the C-terminal region of the human ERCC1 protein, is involved in DNA binding and 5'-incision

The incisions in the DNA at the 3'- and 5'-side of a DNA damage during nucleotide excision repair in Escherichia coli occur in a complex consisting of damaged DNA, UvrB and UvrC. The exact requirements for the two incision events, however, are different. It has previously been shown that the 3'-incision requires the interaction between the C-terminal domain of UvrB and a homologous region in UvrC. This interaction, however, is dispensable for the 5'-incision. Here we show that the C-terminal domain of the UvrC protein is essential for the 5'-incision, whereas this domain can be deleted without affecting the 3'-incision. The C-terminal domain of UvrC is homologous with the C-terminal part of the ERCC1 protein which, in a complex with XPF, is responsible for the 5'-incision reaction in human nucleotide excision repair. Both in the UvrC and the ERCC1 domain a Helix-hairpin-Helix (HhH) motif can be indicated, albeit at different positions. Such a motif also has been found in a large variety of DNA binding proteins and it has been suggested to form a structure involved in non-sequence-specific DNA binding. In contrast to the full length UvrC protein, a truncated UvrC protein (UvrC554) lacking the entire ERCC1 homology including the HhH motif no longer binds to ssDNA. Analysis of protein-DNA complexes using bandshift experiments showed that this putative DNA binding domain of UvrC is required for stabilisation of the UvrBC-DNA complex after the 3'-incision has taken place. We propose that after the initial 3'-incision the HhH motif recognises a specific DNA structure, thereby positioning the catalytic site for the subsequent 5'-incision reaction.

Function of the homologous regions of the Escherichia coli DNA excision repair proteins UvrB and UvrC in stabilization of the UvrBC-DNA complex and in 3'-incision

The nicking of damaged DNA during the nucleotide excision repair reaction in E. coli, is the result of a multi-step process involving three enzymes, UvrA, UvrB and UvrC. The UvrB protein is loaded on the site of the damage by UvrA, forming a stable UvrB-DNA complex. This complex is recognized by UvrC and in the resulting UvrBC-DNA complex dual incision takes place, first on the 3'-side and next on the 5'-side of the damaged nucleotide. A domain in the C-terminal part of UvrB has been identified to be essential for formation of the specific UvrBC-DNA complex that induces the 3'-incision [1]. The N-terminal half of UvrC contains a region that is homologous to this C-terminal domain of UvrB. Using site-directed mutagenesis of a conserved phenylalanine in the homologous regions of UvrB and UvrC two mutants were constructed, UvrB(F652L) and UvrC(F223L). Both proteins were tested in vitro using a DNA substrate with a defined cisplatin lesion. The protein-DNA and protein-protein interactions were studied using bandshift assays and DNAse I footprinting. We show that both domains are important for the binding of UvrC to the UvrB-DNA complex.

The integration host factor-DNA complex upstream of the early promoter of bacteriophage Mu is functionally symmetric

Inversion of the ihf site in the promoter region of the early promoter of bacteriophage Mu did not influence the integration host factor (IHF)-mediated functions. IHF bound to this inverted site could counteract H-NS-mediated repression, directly activate transcription, and support lytic growth of bacteriophage Mu. This implies that the IHF heterodimer and its asymmetrical binding site form a functionally symmetrical complex.

Function of the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase in basal expression and integration host factor-mediated activation of the early promoter of bacteriophage Mu

Integration host factor (IHF) can activate transcription from the early promoter (Pe) of bacteriophage Mu both directly and indirectly. Indirect activation occurs through alleviation of H-NS-mediated repression of the Pe promoter (P. Van Ulsen, M. Hillebrand, L. Zulianello, P. Van de Putte, and N. Goosen, Mol. Microbiol. 21:567-578, 1996). The direct activation involves the C-terminal domain of the alpha subunit (alphaCTD) of RNA polymerase. We investigated which residues in the alphaCTD are important for IHF-mediated activation of the Pe promoter. Initial in vivo screening, using a set of substitution mutants derived from an alanine scan (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996; H. Tang, K. Severinov, A. Goldfarb, D. Fenyo, B. Chait, and R. H. Ebright, Genes Dev. 8:3058-3067, 1994), indicated that the residues, which are required for transcription activation by the UP element of the rrnB P1 promoter (T. Gaal, W. Ross, E. E. Blatter, T. Tang, X. Jia, V. V. Krishnan, N. Assa-Munt, R. Ebright, and R. L. Gourse, Genes Dev. 10:16-26, 1996), are also important for Pe expression in the presence of IHF. Two of the RNA polymerase mutants, alphaR265A and alphaG296A, that affected Pe expression most in vivo were subsequently tested in in vitro transcription experiments. Mutant RNA polymerase with alphaR265A showed no IHF-mediated activation and a severely reduced basal level of transcription from the Pe promoter. Mutant RNA polymerase with alphaG296A resulted in a slightly reduced transcription from the Pe promoter in the absence of IHF but could still be activated by IHF. These results indicate that interaction of the alphaCTD with DNA is involved not only in the IHF-mediated activation of Pe transcription but also in maintaining the basal level of transcription from this promoter. Mutational analysis of the upstream region of the Pe promoter identified a sequence, positioned from -39 to -51 with respect to the transcription start site, that is important for basal Pe expression, presumably through binding of the alphaCTD. The role of the alphaCTD in IHF-mediated stimulation of transcription from the Pe promoter is discussed.

Integration host factor alleviates the H-NS-mediated repression of the early promoter of bacteriophage Mu

Integration host factor (IHF), which is a histone-like protein, has been shown to positively regulate transcription in two different ways. It can either help the formation of a complex between a transcription factor and RNA polymerase or it can itself activate RNA polymerase without the involvement of other transcription factors. In this study, we present a third mechanism for IHF-stimulated gene expression, by counteracting the repression by another histone-like protein, H-NS. The early (Pe) promoter of bacteriophage Mu is specifically inhibited by H-NS, both in vivo and in vitro. For this inhibition, H-NS binds to a large DNA region overlapping the Pe promoter. Binding of IHF to a binding site just upstream of Pe alleviates the H-NS-mediated repression of transcription. This same ihf site is also involved in the direct activation of Pe by IHF. In contrast to the direct activation by IHF, however, the alleviating effect of IHF appears not to be dependent on the relevant position of the ihf site on the DNA helix, and it also does not require the presence of the C-terminal domain of the alpha subunit of RNA polymerase. Footprint analysis shows that binding of IHF to the ihf site destabilizes the interaction of H-NS with the DNA, not only in the IHF-binding region but also in the DNA regions flanking the ihf site. These results suggest that IHF disrupts a higher-order nucleoprotein complex that is formed by H-NS and the DNA.

The C-terminal region of the UvrB protein of Escherichia coli contains an important determinant for UvrC binding to the preincision complex but not the catalytic site for 3'-incision

The UvrABC endonuclease from Escherichia coli repairs damage in the DNA by dual incision of the damaged strand on both sides of the lesion. The incisions are in an ordered fashion, first on the 3'-side and next on the 5'-side of the damage, and they are the result of binding of UvrC to the UvrB-DNA preincision complex. In this paper, we show that at least the C-terminal 24 amino acids of UvrB are involved in interaction with UvrC and that this binding is important for the 3'-incision. The C-terminal region of UvrB, which shows homology with a domain of the UvrC protein, is part of a region that is predicted to be able to form a coiled-coil. We therefore propose that UvrB and UvrC interact through the formation of such a structure. The C-terminal region of UvrB only interacts with UvrC when present in the preincision complex, indicating that the conformational change in UvrB accompanying the formation of this complex exposes the UvrC binding domain. Binding of UvrC to the C-terminal region of UvrB is not important for the 5'-incision, suggesting that for this incision a different interaction of UvrC with the UvrB-DNA complex is required. Truncated UvrB mutants that lack up to 99 amino acids from the C terminus still give rise to significant incision (1-2%), indicating that this C-terminal region of UvrB does not participate in the formation of the active site for 3'-incision. This region, however, contains the residue (Glu-640) that was proposed to be involved in 3'-catalysis, since a mutation of the residue (E640A) fails to promote 3'-incision (Lin, J.J., Phillips, A.M., Hearst, J.E., and Sancar, A. (1992) J. Biol. Chem. 267, 17693-17700). We have isolated a mutant UvrB with the same E640A substitution, but this protein shows normal UvrC binding and incision in vitro and also results in normal survival after UV irradiation in vivo. As a consequence of these results, it is still an open question as to whether the catalytic site for 3'-incision is located in UvrB, in UvrC, or is formed by both proteins.

Participation of the flank regions of the integration host factor protein in the specificity and stability of DNA binding

The heterodimeric integration host factor (IHF) protein is a site-specific DNA-binding protein from Escherichia coli that strongly bends the DNA. It has been proposed (Yang, C., and Nash, H.A. (1989) Cell 57, 869-880; Granston, A. E., and Nash, H. A. (1993) J. Mol. Biol 234, 45-59; Lee, E. C., Hales, L. M., Gumport, R. I., and Gardner, J. F. (1992) EMBO J. 11, 305-313) that the wrapping of the DNA around the protein is stabilized through interactions between the flanks of the protein and the DNA. In order to elucidate which domains of the IHF protein are involved in these interactions, we have constructed mutant proteins in which the C-terminal part of one of the subunits has been deleted. We observed that the C-terminal alpha 3 helix of HimD is involved in the stability of DNA binding, but not in the specificity. In contrast the corresponding alpha 3 helix of HimA is essential for the sequence specificity, since an IHF mutant lacking this domain only binds to the DNA in a non-specific way. The possible role of the two C-terminal alpha-helical structures in complex formation will be discussed. We also examined the properties of an IHF mutant that has an amino acid substitution between beta sheets beta 1 and beta 2 of the HimD subunit (R46H). The occupancy of the ihf site by the mutant and wild type proteins differ in the 3' part of the ihf site and as a result the bend introduced in the DNA by the mutant protein is less pronounced. We propose that the arginine 46 in the HimD subunit is in vicinity of the TTR region of the consensus and that through contacts within the minor groove the DNA bend introduced by IHF is stabilized.

The regulation of transcription initiation by integration host factor

Integration host factor (IHF) of Escherichia coli is an asymmetric histone-like protein that binds and bends the DNA at specific sequences. IHF functions as an accessory factor in a wide variety of processes including replication, site-specific recombination and transcription. In many of these processes IHF was shown to act as an architectural element which helps the formation of nucleo-protein complexes by bending of the DNA at specific sites. This MicroReview shows how such a structural role of IHF can influence the initiation of transcription. In addition, it summarizes the evidence indicating that IHF can stimulate transcription via a direct interaction with RNA polymerase and explores the possibility that the asymmetry of the IHF protein might reflect such an interaction.

Gin invertase of bacteriophage Mu is a dimer in solution, with the domain for dimerization in the N-terminal part of the protein

The Gin protein of bacteriophage Mu mediates recombination between two inverted repeat sequences. Gin binds as a dimer to each of these recombination sites. We show that Gin is a dimer in solution also, and that the dimerization is probably stabilized by hydrophobic interactions between the subunits. The subunits of the dimer could efficiently be cross-linked with the 4-A cross-linker diepoxybutane. Spontaneous oxidation of Cys(24) and/or Cys(27) also resulted in intersubunit cross-linking. One or both cysteine residues are located at the interface of the Gin dimer, which maps the dimerization domain in the N-terminal part of the protein. Binding of the disulfide-bonded dimers of Gin to a recombination site was strongly reduced, suggesting that the subunits need to reorient in order to form a stable protein-DNA complex. In the protein-DNA complex, however, oxidation of cysteine residues still seems to be possible, indicating that the N-terminal parts of two Gin subunits are also in close proximity when bound to DNA.

Effects of N-terminal deletions of the Escherichia coli protein Fis on growth rate, tRNA(2Ser) expression and cell morphology

The Escherichia coli Fis protein is known to be involved in a variety of processes, including the activation of stable RNA operons. In this paper we study the ability of a set of N-terminal Fis deletion mutants to stimulate transcription of the tRNA(2Ser) gene. The results indicate that the domain of the Fis protein containing residues 1-26 is not required for transcription activation. The Fis mutants that are still active in transcription stimulation can also complement the reduced growth rates of Fis- cells, suggesting that the same activating domain is involved in this phenomenon. In addition, we show that in fast growing cultures in the absence of an active Fis protein, minicells are formed. These minicells seem to arise from septum formation near the cell poles. Suppression of minicell formation by Fis also does not require the presence of the N-terminal domain of the protein.