Structural polymorphism of the RecA protein from the thermophilic bacterium Thermus aquaticus.

The Escherichia coli RecA protein has served as a model for understanding protein-catalyzed homologous recombination, both in vitro and in vivo. Although RecA proteins have now been sequenced from over 60 different bacteria, almost all of our structural knowledge about RecA has come from studies of the E. coli protein. We have used electron microscopy and image analysis to examine three different structures formed by the RecA protein from the thermophilic bacterium Thermus aquaticus. This protein has previously been shown to catalyze an in vitro strand exchange reaction at an optimal temperature of about 60 degrees C. We show that the active filament formed by the T. aquaticus RecA on DNA in the presence of a nucleotide cofactor is extremely similar to the filament formed by the E. coli protein, including the extension of DNA to a 5.1-A rise per base pair within this filament. This parameter appears highly conserved through evolution, as it has been observed for the eukaryotic RecA analogs as well. We have also characterized bundles of filaments formed by the T. aquaticus RecA in the absence of both DNA and nucleotide cofactor, as well as hexameric rings of the protein formed under all conditions examined. The bundles display a very large plasticity of mass within the RecA filament, as well as showing a polymorphism in filament-filament contacts that may be important to understanding mutations that affect surface residues on the RecA filament.     

RecA Protein from the extremely radioresistant bacterium Deinococcus radiodurans: expression, purification, and characterization

The RecA protein of Deinococcus radiodurans (RecA(Dr)) is essential for the extreme radiation resistance of this organism. The RecA(Dr) protein has been cloned and expressed in Escherichia coli and purified from this host. In some respects, the RecA(Dr) protein and the E. coli RecA (RecA(Ec)) proteins are close functional homologues. RecA(Dr) forms filaments on single-stranded DNA (ssDNA) that are similar to those formed by the RecA(Ec). The RecA(Dr) protein hydrolyzes ATP and dATP and promotes DNA strand exchange reactions. DNA strand exchange is greatly facilitated by the E. coli SSB protein. As is the case with the E. coli RecA protein, the use of dATP as a cofactor permits more facile displacement of bound SSB protein from ssDNA. However, there are important differences as well. The RecA(Dr) protein promotes ATP- and dATP-dependent reactions with distinctly different pH profiles. Although dATP is hydrolyzed at approximately the same rate at pHs 7.5 and 8.1, dATP supports an efficient DNA strand exchange only at pH 8.1. At both pHs, ATP supports efficient DNA strand exchange through heterologous insertions but dATP does not. Thus, dATP enhances the binding of RecA(Dr) protein to ssDNA and the displacement of ssDNA binding protein, but the hydrolysis of dATP is poorly coupled to DNA strand exchange. The RecA(Dr) protein thus may offer new insights into the role of ATP hydrolysis in the DNA strand exchange reactions promoted by the bacterial RecA proteins. In addition, the RecA(Dr) protein binds much better to duplex DNA than the RecA(Ec) protein, binding preferentially to double-stranded DNA (dsDNA) even when ssDNA is present in the solutions. This may be of significance in the pathways for dsDNA break repair in Deinococcus.     

Differences in Contacts of RNA Polymerases from <Emphasis Type="Italic">Escherichia coli</Emphasis> and <Emphasis Type="Italic">Thermus aquaticus</Emphasis> with <Emphasis Type="Italic">lac</Emphasis>UV5 Promoter Are Determined by Core-Enzyme of RNA Polymerase

The interaction of RNA polymerases from Escherichia coli and Thermus aquaticus with lacUV5 promoter was studied at various temperatures. Using DNA-protein cross-linking induced by formaldehyde, it was demonstrated that each RNA polymerase formed a unique pattern of contacts with DNA in the open promoter complex. In the case of E. coli RNA polymerase, beta and sigma subunits were involved into formation of cross-links with the promoter, whereas in the case of T. aquaticus RNA polymerase its beta subunit formed the cross-links with the promoter. A cross-linking pattern in promoter complexes of a hybrid holoenzyme comprised of the core-enzyme of E. coli and sigma subunit of T. aquaticus was similar to that of the E. coli holoenzyme. This suggests that DNA-protein contacts in the promoter complex are primarily determined by the core-enzyme of RNA polymerase. However, temperature-dependent behavior of contact formation is determined by the sigma subunit. Results of the present study indicate that the method of formaldehyde cross-linking can be employed for elucidation of differences in the structure of promoter complexes of RNA polymerases from various bacteria.     

Influence of DNA sequence on the positioning of RecA monomers in RecA-DNA cofilaments.

We show that certain DNA sequences have the ability to influence the positioning of RecA monomers in RecA-DNA complexes. A tendency for RecA monomers to be phased was observed in RecA protein complexes with several oligonucleotides containing a recombinational hotspot sequence, the chi-site from Escherichia coli. This influence was observed in both the 5' to 3' and 3' to 5' directions with respect to chi. A 5'-end phosphate group and probably some other features in DNA also influence the phasing of RecA monomers. We conclude that natural DNAs contain a number of features that influence the positioning of RecA monomers. The ability of specific DNA sequences to influence the positioning of RecA monomers demonstrates some specificity in the binding of individual bases at different sites within a RecA monomer and, most likely, reflects the stereochemical non-equivalence of these sites. The possible biological implications of the phasing of RecA monomers in presynaptic DNA-protein cofilaments are discussed.     

Characterization of DNA-binding and strand-exchange stimulation properties of y-RPA, a yeast single-strand-DNA-binding protein.

Single-stranded DNA binding proteins (SSBs) have been isolated from many organisms, including Escherichia coli, Saccharomyces cerevisiae and humans. Characterization of these proteins suggests they are required for DNA replication and are active in homologous recombination. As an initial step towards understanding the role of the eukaryotic SSBs in DNA replication and recombination, we examined the DNA binding and strand exchange stimulation properties of the S. cerevisiae single-strand binding protein y-RPA (yeast replication protein A). y-RPA was found to bind to single-stranded DNA (ssDNA) as a 115,000 M(r) heterotrimer containing 70,000, 36,000 and 14,000 M(r) subunits. It saturated ssDNA at a stoichiometry of one heterotrimer per 90 to 100 nucleotides and binding occurred with high affinity (K omega greater than 10(9) M-1) and co-operativity (omega = 10,000 to 100,000). Electron microscopic analysis revealed that y-RPA binding was highly co-operative and that the ssDNA present in y-RPA-ssDNA complexes was compacted fourfold, arranged into nucleosome-like structures, and was free of secondary structure. y-RPA was also tested for its ability to stimulate the yeast Sepl and E. coli RecA strand-exchange proteins. In an assay that measures the pairing of circular ssDNA with homologous linear duplex DNA, y-RPA stimulated the strand-exchange activity of Sepl approximately threefold and the activity of RecA protein to the same extent as did E. coli SSB. Maximal stimulation of Sepl occurred at a stoichiometry of one y-RPA heterotrimer per 95 nucleotides of ssDNA. y-RPA stimulated RecA and Sepl mediated strand exchange reactions in a manner similar to that observed for the stimulation of RecA by E. coli SSB; in both of these reactions, y-RPA inhibited the aggregation of ssDNA and promoted the co-aggregation of single-stranded and double-stranded linear DNA. These results demonstrate that the E. coli and yeast SSBs display similar DNA-binding properties and support a model in which y-RPA functions as an E. coli SSB-like protein in yeast.     

Visualization of recA protein and its association with DNA: a priming effect of single-strand-binding protein

A stoichiometric interaction of RecA protein with single-stranded DNA promotes homologous pairing of the single strand with duplex DNA and subsequent polar formation of a heteroduplex joint. Escherichia coli single-strand-binding (SSB) protein augments these reactions. Electron microscopic observations suggest structural bases for these interactions. Without triphosphates or DNA, RecA protein forms short linear filaments. With added circular single-stranded DNA, it forms extended circular filaments as well as collapsed and aggregated complexes of protein and DNA. The extended circular filaments are stiff and regular in appearance, contrasting with the convoluted structure formed by SSB protein and single-stranded DNA. Together, these two proteins form mixed filaments, which mostly resemble the extended structures containing RecA protein; moreover, SSB protein accelerates formation of extended filaments more than 50-fold, increasing the yield of these structures at the expense of heterogeneous aggregates. Other observations further define the interactions of RecA protein with partially single-stranded DNA, and the effects of ATP gamma S on the tendency of RecA protein to form polymeric structures even in the absence of DNA.     

Affinity chromatography of RecA protein and RecA nucleoprotein complexes on RecA protein-agarose columns

We have analyzed the nature of RecA protein-RecA protein interactions using an affinity column prepared by coupling RecA protein to an agarose support. When radiolabeled soluble proteins from Escherichia coli are applied to this column, only the labeled RecA protein from the extract was selectively retained and bound tightly to the affinity column. Efficient binding of purified 35S-labeled RecA protein required Mg2+, and high salt did not interfere with the binding of RecA protein to the column. Complete removal of the bound enzyme from the affinity column required treatment with guanidine HCl (5 M) or urea (8 M). These and other properties suggest that hydrophobic interactions contribute significantly to RecA protein subunit recognition in solution. Using a series of truncated RecA proteins synthesized in vitro, we have obtained evidence that at least some of the sequences involved in protein recognition are localized within the first 90 amino-terminal residues of the protein. Based on the observation that RecA proteins from three heterologous bacteria are specifically retained on the E. coli RecA affinity column, it is likely that this binding domain is highly conserved and is required for interaction and association of RecA protein monomers. Stable ternary complexes of RecA protein and single-stranded DNA were formed in the presence of the nonhydrolyzable ATP analog adenosine 5'-O-(thiotriphosphate) and applied to the affinity columns. Most of the complexes formed with M13 DNA could be eluted in high salt, whereas a substantial fraction of those formed with the oligonucleotide (dT)25-30 remained bound in high salt and were quantitatively eluted with guanidine HCl (5 M). The different binding properties of these RecA protein-DNA complexes likely reflect differences in the availability of a hydrophobic surface on RecA protein when it is bound to long polynucleotides compared to short oligonucleotides.     

Insights into thermal resistance of proteins from the intrinsic stability of their α-helices

To investigate the role of α helices in protein thermostability, we compared energy characteristics of α helices from thermophilic and mesophilic proteins belonging to four protein families of known three-dimensional structure, for at least one member of each family. The changes in intrinsic free energy of α-helix formation were estimated using the statistical mechanical theory for describing helix/coil transitions in peptide helices [Munoz, V., Serrano, L. Nature Struc. Biol. 1:399–409, 1994; Munoz, V., Serrano, L. J. Mol. Biol. 245:275–296, 1995; Munoz, V., Serrano, L. J. Mol. Biol. 245:297–308, 1995]. Based on known sequences of mesophilic and thermophilic RecA proteins we found that (1) a high stability of α helices is necessary but is not a sufficient condition for thermostability of RecA proteins, (2) the total helix stability, rather than that of individual helices, is the factor determining protein thermostability, and (3) two facets of intrahelical interactions, the intrinsic helical propensities of amino acids and the side chain–side chain interactions, are the main contributors to protein thermostability. Similar analysis applied to families of L-lactate dehydrogenases, seryl-tRNA synthetases, and aspartate amino transferases led us to conclude that an enhanced total stability of α helices is a general feature of many thermophilic proteins. The magnitude of the observed decrease in intrinsic free energy on α-helix formation of several thermoresistant proteins was found to be sufficient to explain the experimentally determined increase of their thermostability. Free energies of intrahelical interactions of different RecA proteins calculated at three temperatures that are thought to be close to its normal environmental conditions were found to be approximately equal. This indicates that certain flexibility of RecA protein structure is an essential factor for protein function. All RecA proteins analyzed fell into three temperature-dependent classes of similar α-helix stability (ΔG_int = 45.0 ± 2.0 kcal/mol). These classes were consistent with the natural origin of the proteins. Based on the sequences of protein α helices with optimized arrangement of stabilizing interactions, a natural reserve of RecA protein thermoresistance was estimated to be sufficient for conformational stability of the protein at nearly 200°C. Proteins 29:309–320, 1997. © 1997 Wiley-Liss, Inc.     

Molecular cloning, expression, purification, and characterization of fructose-1,6-bisphosphate aldolase from Thermus aquaticus

Fructose-1,6-bisphosphate aldolase from the thermophilic eubacteria, Thermus aquaticus YT-1, was cloned and sequenced. Nucleotide-sequence analysis revealed an open reading frame coding for a 33-kDa protein of 305 amino acids having amino acid sequence typical of thermophilic adaptation. Multiple sequence alignment classifies the enzyme as a class II B aldolase that shares similarity with aldolases from other extremophiles: Thermotoga maritima, Aquifex aeolicus, and Helicobacter pylori (49--54% identity, 76--81% homology). Taq FBP aldolase was overexpressed under tac promoter control in Escherichia coli and purified to homogeneity using heat treatment followed by two chromatographic steps. Yields of 40--50 mg of monodisperse protein were obtained per liter of culture. The quaternary structure is that of a homotetramer stabilized by an apparent 21-amino-acid insertion sequence. The recombinant protein is thermostable for at least 45 min at 80 degrees C with little residual activity below 60 degrees C. Kinetic characterization at 70 degrees C, the optimal growth temperature for T. aquaticus, indicates extreme negative subunit cooperativity (h = 0.32) with a limiting K(m) of 305 microM. The maximal specific activity (V(max)) is 46 U/mg at 70 degrees C.     

Purification and characterization of the single-stranded DNA binding protein from Streptococcus pneumoniae

The Escherichia coli single-stranded DNA binding (SSB) protein is a non-sequence-specific DNA binding protein that functions as an accessory factor for the RecA protein-promoted three-strand exchange reaction. An open reading frame encoding a protein similar in size and sequence to the E. coli SSB protein has been identified in the Streptococcus pneumoniae genome. The open reading frame has been cloned, an overexpression system has been developed, and the protein has been purified to greater than 99% homogeneity. The purified protein binds to ssDNA in a manner similar to that of the E. coli SSB protein. The protein also stimulates the S. pneumoniae RecA protein and E. coli RecA protein-promoted strand exchange reactions to an extent similar to that observed with the E. coli SSB protein. These results indicate that the protein is the S. pneumoniae analog of the E. coli SSB protein. The availability of highly-purified S. pneumoniae SSB protein will facilitate the study of the molecular mechanisms of RecA protein-mediated transformational recombination in S. pneumoniae.     

Structure and mechanism of Escherichia coli RecA ATPase

RecA protein catalyses an ATP-dependent DNA strand-exchange reaction that is the central step in the repair of dsDNA breaks by homologous recombination. Although much is known about the structure of RecA protein itself, we do not at present have a detailed picture of how RecA binds to ssDNA and dsDNA substrates, and how these interactions are controlled by the binding and hydrolysis of the ATP cofactor. Recent studies from electron microscopy and X-ray crystallography have revealed important ATP-mediated conformational changes that occur within the protein, providing new insights into how RecA catalyses DNA strand-exchange. A unifying theme is emerging for RecA and related ATPase enzymes in which the binding of ATP at a subunit interface results in large conformational changes that are coupled to interactions with the substrates in such a way as to promote the desired reactions.     

Dissecting DNA-protein and protein-protein interactions involved in bacterial transcriptional regulation by a sensitive protein array method combining a near-infrared fluorescence detection

The protein array methodology is used to study DNA-protein and protein-protein interactions governing gene expression from the Bacillus stearothermophilus PargCo promoter-operator region. Using probes labelled with near-infrared fluorescence dyes with exitation characteristics close to 700 or 800 nm, it is possible to detect signals from proteins (purified or non-purified in Escherichia coli cell extracts) immobilised on a nitrocellulose membrane with a high sensitivity (almost 12 amol of a spotted protein for protein-DNA interactions). Protein array data are confirmed by other methods indicating that molecular interactions of the order 10(-7) M can be monitored with the proposed protein array approach. We show that the PargCo region is a target for binding at least three types of regulatory proteins, ArgR repressors from thermophilic bacteria, the E. coli RNA polymerase alpha subunit and cyclic AMP binding protein CRP. We also demonstrate that the high strength of the PargC promoter is related to an upstream element that binds to the E. coli RNA polymerase alpha subunit.     

Purification and characterization of the RecA protein from Streptococcus pneumoniae

Streptococcus pneumoniae is a naturally transformable bacterium that is able to take up single-stranded DNA from its environment and incorporate the exogenous DNA into its genome. This process, known as transformational recombination, is dependent upon the presence of the recA gene, which encodes an ATP-dependent DNA recombinase whose sequence is 60% identical to that of the RecA protein from Escherichia coli. We have developed an overexpression system for the S. pneumoniae RecA protein and have purified the protein to greater than 99% homogeneity. The S. pneumoniae RecA protein has ssDNA-dependent NTP hydrolysis and NTP-dependent DNA strand exchange activities that are generally similar to those of the E. coli RecA protein. In addition to its role as a DNA recombinase, the E. coli RecA protein also acts as a coprotease, which facilitates the cleavage and inactivation of the E. coli LexA repressor during the SOS response to DNA damage. Interestingly, the S. pneumoniae RecA protein is also able to promote the cleavage of the E. coli LexA protein, even though a protein analogous to the LexA protein does not appear to be present in S. pneumoniae.     

Role of RecA in DNA damage repair in Deinococcus radiodurans

It has been shown previously that the RecA protein of Deinococcus radiodurans plays a unique role in the repair of DNA damage in this highly DNA damage-resistant organism. Despite the high level of amino-acid identity, previous work has shown that Escherichia coli RecA does not complement D. radiodurans RecA mutants, further suggesting the uniqueness of D. radiodurans RecA. The work presented here shows that E. coli RecA does in fact provide partial complementation to a D. radiodurans RecA null mutant, suggesting that the RecA protein from D. radiodurans may not be as unique as believed previously.     

Difference FTIR studies reveal nitrogen-containing amino acid side chains are involved in the allosteric regulation of RecA

The Escherichia coli RecA protein performs the DNA strand-exchange reaction utilized in both genetic recombination and DNA repair. The binding of nucleotides triggers conformational changes throughout the protein resulting in the RecA-ATP (high DNA affinity) and RecA-ADP (low DNA affinity) structures. Difference infrared spectroscopy has allowed us to study protein structural changes in RecA that occur after binding ADP or ATP. Experiments were performed on control and uniformly (15)N-labeled RecA in an effort to assign vibrational changes to protein structures and study the molecular changes associated with the allosteric regulation of RecA. Comparison of RecA-ATP and RecA-ADP data indicates that the protein adopts unique secondary structures in each form and altered N-H stretching vibrations in the RecA-ADP structure not observed in the RecA-ATP data. Numerous vibrations throughout the 1700-1300 cm(-)(1) region are influenced by isotopic substitution and imply that many nitrogen-containing side chains are altered after ADP binds to RecA. The RecA-ATP data contain unique vibrations that are not observed in the RecA-ADP data and may be associated with Gln, Lys, Arg, or Asn. Model compound studies on control and (15)N-labeled glutamine and lysine provide additional evidence that supports the tentative assignments of vibrations observed in our difference spectra. In addition, we provide evidence that nitrogen-containing amino acids are important in locking in the low-DNA affinity, more compact conformation of the protein and that some of these interactions may not be present in a more extended, flexible RecA-ATP conformation.     

Situational repair of replication forks: roles of RecG and RecA proteins

Replication forks often stall or collapse when they encounter a DNA lesion. Fork regression is part of several major paths to the repair of stalled forks, allowing nonmutagenic bypass of the lesion. We have shown previously that Escherichia coli RecA protein can promote extensive regression of a forked DNA substrate that mimics a possible structure of a replication fork stalled at a leading strand lesion. Using electron microscopy and gel electrophoresis, we demonstrate that another protein, E. coli RecG helicase, promotes extensive fork regression in the same system. The RecG-catalyzed fork regression is very efficient and faster than the RecA-promoted reaction (up to 240 bp s(-1)), despite very limited processivity of the RecG protein. The reaction is dependent upon ATP hydrolysis and is stimulated by single-stranded binding protein. The RecA- and RecG-promoted reactions are not synergistic. In fact, RecG functions poorly under the conditions optimal for the RecA reaction, and vice versa. When both RecA and RecG proteins are incubated with the DNA substrate, high RecG concentrations inhibit the RecA protein-promoted fork regression. The very different reaction profiles may reflect a situational application of these proteins to the rescue of stalled replication forks in vivo.     

Three-strand exchange by the Escherichia coli RecA protein using ITP as a nucleotide cofactor: mechanistic parallels with the ATP-dependent reaction of the RecA protein from Streptococcus pneumoniae

The RecA protein from Escherichia coli promotes an ATP-dependent three-strand exchange reaction between a circular single-stranded DNA (ssDNA) and a homologous linear double-stranded (dsDNA). We have now found that under certain conditions, the RecA protein is also able to promote the three-strand exchange reaction using the structurally related nucleoside triphosphate, ITP, as the nucleotide cofactor. However, although both reactions are stimulated by single-stranded DNA-binding (SSB) protein, the ITP-dependent reaction differs from the ATP-dependent reaction in that it is observed only at low SSB protein concentrations, whereas the ATP-dependent reaction proceeds efficiently even at high SSB protein concentrations. Moreover, the circular ssDNA-dependent ITP hydrolysis activity of the RecA protein is strongly inhibited by SSB protein (suggesting that SSB protein displaces RecA protein from ssDNA when ITP is present), whereas the ATP hydrolysis activity is uninhibited even at high SSB protein concentrations (because RecA protein is resistant to displacement by SSB protein when ATP is present). These results suggest that SSB protein does not stimulate the ITP-dependent strand exchange reaction presynaptically (by facilitating the binding of RecA protein to the circular ssDNA substrate) but may act postsynaptically (by binding to the displaced strand that is generated when the circular ssDNA invades the linear dsDNA substrate). Interestingly, the mechanistic characteristics of the ITP-dependent strand exchange reaction of the E. coli RecA protein are similar to those of the ATP-dependent strand exchange reaction of the RecA protein from Streptococcus pneumoniae. These findings are discussed in terms of the relationship between the dynamic state of the RecA-ssDNA filament and the mechanism of the SSB protein-stimulated three-strand exchange reaction.     

Interaction of RecA protein with acidic phospholipids inhibits DNA-binding activity of RecA.

The RecA protein of Escherichia coli binds specifically to acidic phospholipids such as cardiolipin and phosphatidylglycerol. This binding appears to be affected by the presence of divalent cations such as Ca2+ and Mg2+. The interaction leads to the inhibition of RecA binding to at least two different conformations of DNA, single-stranded DNA and left-handed Z-DNA, thus suggesting that the phospholipids interact at the DNA-binding site of the RecA protein. Inclusion of a nucleotide cofactor [adenosine 5'-O-(gamma-thiotriphosphate)] in the reactions did not prevent the inhibition of DNA-binding activities of RecA protein by the phospholipids. The interaction of RecA protein with cardiolipin and phosphatidylglycerol, which represent two of the three major phospholipids of the E. coli membrane, may be physiologically important, as it provides a possible mechanism for the RecA-membrane association during the SOS response. These observations raise the possibility that the Z-DNA-binding activity of RecA protein is merely a manifestation of its phospholipid-binding property.     

An enhanced thermostability in thermophilic 5-S ribonucleic acids under physiological salt conditions.

The secondary structure of 5-S rRNAs of Thermus aquaticus (an extreme thermophile), Bacillus stearothermophilus (a moderate thermophile) and Escherichia coli (a mesophile) was compared using thermal denaturation techniques under varying ionic conditions. At a low ionic strength (10 mM K+), the Tm of T. aquaticus 5-S RNA differed by only 1 degrees C from that of E. coli RNA and the molecule was fully denatured well below the optimum growth temperature of the thermophile. The internal Na+, K+ and Mg2+ concentrations of T. aquaticus cells were determined to be 91 mM, 130 mM and 59 mM, respectively. Under these salt conditions, T. aquaticus 5-S RNA was significantly more stable than E. coli RNA and the 5-S RNA from B. stearothermophilus was intermediate as is its optimum growth temperature. The results suggest that the thermostability of macromolecules from thermophilic organisms may be specially dependent on the internal salt concentration. Furthermore, under these salt conditions, most of the secondary structure of the RNA remained stable at the optimum growth temperatures suggesting that ribosomal RNAs of thermophilic organisms contribute more to the thermostability of the ribosome than previously thought.