Integration host factor (IHF) stimulates binding of the gpNu1 subunit of lambda terminase to cos DNA.

The lambda terminase enzyme binds to the cohesive end sites (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12 bp single-stranded cohesive ends of the mature phage genome. In vitro this endonucleolytic cleavage requires spermidine, magnesium ions, ATP and a host factor. One of the E. coli proteins which can fulfill this latter requirement is Integration Host Factor (IHF). IHF and the gpNu1 subunit of terminase can bind simultaneously to their own specific binding sites at cos. DNase I footprinting experiments suggest that IHF may promote gpNu1 binding. Although no specific gpNu1 binding to the left side of cos can be detected, this DNA segment does play a specific role since a cos fragment that does not include the left side or whose left side is replaced by non-cos sequences, is unable to bind gpNu1 unless either spermidine or IHF is present. Binding studies on the right side of cos using individual or combinations of gpNu1 binding sites I, II and III indicate that binding at sites I and II is not optimal unless site III is present.     

The Nul subunit of bacteriophage lambda terminase binds to specific sites in cos DNA.

The maturation and packaging of bacteriophage lambda DNA are under the control of the multifunctional viral terminase enzyme, which is composed of the protein products of Nu1 and A, the two most leftward genes of the phage chromosome. Terminase binds selectively to the cohesive end site (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12-base single-stranded cohesive ends of the mature phage genome. The purified gpNu1 subunit of terminase forms specific complexes with cos lambda DNA. DNase I footprinting experiments showed that gpNu1 bound to three distinct regions near the extreme left end of the lambda chromosome. These regions coincided with two 16-base-pair sequences (CTGTCGTTTCCTTTCT) that were in inverted orientation, as well as a truncated version of this sequence. Bear et al. (J. Virol. 52:966-972,1984) isolated a mutant phage which contained a CG to TA transition at the 10th position of the rightmost 16-base-pair sequence, and this phage (termed lambda cos 154) exhibits a defect in DNA maturation when it replicates in Escherichia coli which is deficient in integration host factor. Footprinting experiments with cos 154 DNA showed that gpNu1 could not bind to the site which contained the mutation but could protect the other two sites. Since the DNA-packaging specificity of terminase resides in the gpNu1 subunit, these studies suggest that terminase uses these three sites as recognition sequences for specific binding to cos lambda.     

A human DNA-binding protein is methylation-specific and sequence-specific.

A nuclear protein isolated from human placenta, methylated DNA-binding protein (MDBP), binds selectively to DNA enriched in 5-methylcytosine. We now demonstrate that MDBP is a sequence-specific, as well as methylation-specific, DNA-binding protein. From ten restriction fragments of pBR322 DNA methylated with human DNA methyltransferase, one was bound to MDBP very much more strongly than any of the others. For this preferential binding to MDBP, the DNA had to be methylated. By a DNase I protection experiment (DNase I footprinting), a 22-base sequence within this methylated restriction fragment was shown to be specifically protected by MDBP. The sequence-specificity of MDBP coupled with its dependence on DNA methylation suggests that this is one of the proteins which modulates important functions of human DNA methylation in vivo.     

The Nu1 subunit of bacteriophage lambda terminase

The maturation and packaging of bacteriophage lambda DNA are catalyzed by the phage terminase enzyme. Terminase is composed of two protein subunits, gpNu1 and gpA. The holoenzyme is multifunctional in vitro; it binds to and cleaves lambda DNA at the cos site (where cos represents cohesive-end site), packages DNA into lambda proheads, and is also a DNA-dependent ATPase. The genes of the two subunits have been cloned separately into powerful expression vectors which allow for very high levels of protein overproduction. The gpNu1 protein has been purified to homogeneity and has a monomeric molecular weight of 21,200, in close agreement with the Mr of 20,444 expected from its amino acid sequence. Both gel filtration and sedimentation velocity centrifugation indicate that the native gpNu1 protein exists as a Mr greater than 500,000 aggregate. The sequence of the first 20 amino acids and the overall composition both match those predicted by the nucleotide sequence of the Nu1 gene. Purified gpNu1 is able to complement gpA-containing extracts in both lambda DNA packaging and cos cleavage assays. The Nu1 gene amino acid sequence predicts DNA binding by the protein, and gpNu1 does show specific binding to lambda DNA by filter binding assays. Also, as predicted from its sequence, gpNu1 exhibits ATPase activity; but in contrast to the holoenzyme, this activity is DNA-independent.     

Thermolabile in vivo DNA-binding activity associated with a protein encoded by mutants of herpes simplex virus type 1.

The major DNA-binding protein encoded by several temperature-sensitive mutants of herpes simplex virus type 1 was thermolabile for binding to intracellular viral DNA. The ability of DNase I to release this protein from isolated nuclei was used as a measure of the amount of protein bound to viral DNA. This assay was based upon our previous observation that the fraction of herpesviral DNA-binding protein which can be eluted from nuclei with DNase I represents proteins associated with progeny viral DNA (D. M. Knipe and A. E. Spang, J. Virol. 43:314-324, 1982). In this study, we found that several temperature-sensitive mutants encoded proteins which rapidly chased from a DNase I-sensitive to a DNase I-resistant nuclear form upon shift to the nonpermissive temperature. We interpret this change in DNase I sensitivity to represent the denaturation of the DNA-binding site at the nonpermissive temperature and the association with the nuclear framework via a second site on the protein. The DNA-binding activity measured by the DNase I sensitivity assay represents an important function of the protein in viral replication because three of five mutants tested were thermolabile for this activity. A fourth mutant encoded a protein which did not associate with the nucleus at the nonpermissive temperature and therefore would not be available for DNA binding in the nucleus. We also present supportive evidence for the binding of the wild-type protein to intracellular viral DNA by showing that a monoclonal antibody coprecipitated virus-specific DNA sequences with the major DNA-binding protein.     

Purification and characterization of the Ner repressor of bacteriophage Mu

The Ner protein of bacteriophage Mu acts as a lambda cro-like negative regulator of the phage's early (transposase) operon. Using the band retardation assay to monitor ner-operator-specific DNA-binding activity, the 8 kDa Ner protein was purified to homogeneity. DNase I footprinting revealed that the purified protein bound and protected a specific DNA operator that contains two 12 bp sites with the consensus sequence 5'-ANPyTAPuCTAAGT-3', separated by a 6 bp spacer region. Moreover, regions corresponding to a turn of the DNA helix flanking these 12 bp repeats are also protected by Ner. Unlike the functionally similar lambda cro protein, gel filtration experiments show that the native molecular mass of Mu Ner to be approx. 8 kDa. These results, plus the pattern of DNase I protection, suggest that the protein may bind as a monomer to each of its specific DNA substrates.     

Novel method for identifying sequence-specific DNA-binding proteins.

We developed a general method for the enrichment and identification of sequence-specific DNA-binding proteins. A well-characterized protein-DNA interaction is used to isolate from crude cellular extracts or fractions thereof proteins which bind to specific DNA sequences; the method is based solely on this binding property of the proteins. The DNA sequence of interest, cloned adjacent to the lac operator DNA segment is incubated with a lac repressor-beta-galactosidase fusion protein which retains full operator and inducer binding properties. The DNA fragment bound to the lac repressor-beta-galactosidase fusion protein is precipitated by the addition of affinity-purified anti-beta-galactosidase immobilized on beads. This forms an affinity matrix for any proteins which might interact specifically with the DNA sequence cloned adjacent to the lac operator. When incubated with cellular extracts in the presence of excess competitor DNA, any protein(s) which specifically binds to the cloned DNA sequence of interest can be cleanly precipitated. When isopropyl-beta-D-thiogalactopyranoside is added, the lac repressor releases the bound DNA, and thus the protein-DNA complex consisting of the specific restriction fragment and any specific binding protein(s) is released, permitting the identification of the protein by standard biochemical techniques. We demonstrate the utility of this method with the lambda repressor, another well-characterized DNA-binding protein, as a model. In addition, with crude preparations of the yeast mitochondrial RNA polymerase, we identified a 70,000-molecular-weight peptide which binds specifically to the promoter region of the yeast mitochondrial 14S rRNA gene.     

Interaction of the Gifsy-1 Xis protein with the Gifsy-1 attP sequence

The Gifsy-1 phage integrates site specifically into the Salmonella chromosome via an integrase-mediated site-specific recombination mechanism. Initial genetic analysis suggests that Gifsy-1 integrase-mediated excision of the Gifsy-1 phage is influenced by proteins encoded by both the Gifsy-1 and the Gifsy-2 phages. Our studies show that the Gifsy-1 Xis protein regulates the directionality of integrase-mediated excision of the Gifsy-1 phage. Electrophoretic mobility shift assays, DNase I footprinting, dimethyl sulfate (DMS) interference assays, and DMS protection assays were used to identify a 31-base-pair sequence in the attP region to which the Gifsy-1 protein binds. The results suggest that this recombination directionality factor binds in vitro to three imperfect direct repeats, spaced 10 base pairs apart, in a sequential and cooperative manner in the absence of other phage-encoded proteins. Our studies suggest that, while the Gifsy-1 Xis does not require additional factors for specific and high-affinity binding, it may form a microfilament on DNA similar to that described for the phage lambda Xis protein.     

The A.T-DNA-binding domain of mammalian high mobility group I chromosomal proteins. A novel peptide motif for recognizing DNA structure.

We have determined the domains of the mammalian high mobility group (HMG)I chromosomal proteins necessary and sufficient for binding to the narrow minor groove of stretches of A.T-rich DNA. Three highly conserved regions within each of the known HMG-I proteins is closely related to the consensus sequence T-P-K-R-P-R-G-R-P-K-K. A synthetic oligopeptide corresponding to this consensus "binding domain" (BD) sequence specifically binds to substrate DNA in a manner similar to the intact HMG-I proteins. Molecular Corey-Pauling-Koltun model building and computer simulations employing energy minimization programs to predict structure suggest that the consensus BD peptide has a secondary structure similar to the antitumor and antiviral drugs netropsin and distamycin and to the dye Hoechst 33258. In vitro these ligands, which also preferentially bind to A.T-rich DNA, have been demonstrated to effectively compete with both the BD peptide and the HMG-I proteins for DNA binding. The BD peptide also contains novel structural features such as a predicted Asx bend or "hook" at its amino-terminal end and laterally projecting cationic Arg/Lys side chains or "bristles" which may contribute to the binding properties of the HMG-I proteins. The predicted BD peptide structure, which we refer to as the "A.T-hook," represents a previously undescribed DNA-binding motif capable of binding to the minor groove of stretches of A.T base pairs.     

Systematic method for the detection of potential lambda Cro-like DNA-binding regions in proteins

We have developed and tested a systematic method for the location and statistical evaluation of potential DNA-binding regions of the lambda Cro type in protein sequences. Using this approach to examine proteins expected to contain such regions, we have been able to compile a statistically homogeneous master set of 37 lambda Cro-like DNA-binding domains. Examination of a protein database revealed other prokaryotic proteins that are similar to this lambda Cro-like group. There are also many DNA-binding proteins that are not found to be significantly similar to the lambda Cro group, consistent with previous suggestions that different types of protein sequence may be able to achieve a similar mode of binding and that there exist other modes of sequence-specific DNA-binding. A useful feature of the method is that it can be applied without a computer.     

HU and IHF, two homologous histone-like proteins of Escherichia coli, form different protein-DNA complexes with short DNA fragments.

Using the gel retardation technique we have studied the protein-DNA complexes formed between HU--the major histone-like protein of Escherichia coli--and short DNA fragments. We show that several HU heterodimers bind DNA in a regularly spaced fashion with each heterodimer occupying about 9 base pairs. The alpha 2 and beta 2 HU homodimers form the same structure as the alpha beta heterodimer on double stranded DNA. However when compared to the heterodimer, they bind single stranded DNA with higher affinity. We also show that HU and the Integration Host Factor of E. coli (IHF) form different structures with the same DNA fragments. Moreover, HU seems to enhance the DNA-binding capacity of IHF to a DNA fragment which does not contain its consensus sequence.     

Purification and characterization of the DNA-binding protein DnrI, a transcriptional factor of daunorubicin biosynthesis in Streptomyces peucetius

The DnrI protein, essential for the biosynthesis of daunorubicin in Streptomyces peucetius , was purified almost to homogeneity from dnrI expression strains of Escherichia coli and S. peucetius through several steps of chromatography. The proteins purified from both organisms had identical chromatographic and electrophoretic behaviour. Purified His-tagged or native DnrI was used to conduct DNA-binding assays by gel mobility-shift analysis, and the results showed no significant difference in the DNA-binding activity of native or His-tagged proteins. DnrI binds specifically to DNA segments containing the intergenic regions separating the putative dnrG–dpsABCD and dpsEF operons, and the dnrC gene and dnrDKPSQ operon. DNase I footprinting assays indicated that the DNA-binding sites for DnrI extended from upstream of the −10 to −35 regions of the dnrG or dpsE promoters to include about 65 bp of the dnrG – dpsE intergenic region and about 80 bp of the dnrC – dnrD intergenic region. Both binding sites contain imperfect inverted repeat sequences of 6–10 bp with a 5'-TCGAG-3' consensus sequence that was present in 4 out of 10 other promoter regions in the cluster of daunorubicin biosynthesis genes.     

High Resolution Structural Studies of Cro Repressor Protein and Implications for DNA Recognition

Abstract

Cro repressor is a small dimeric protein that binds to specific sites on the DNA of bacteriophage λ. The structure of Cro has been determined and suggests that the protein binds to its sequence-specific sites with a pair of two-fold related α-helices of the protein located within successive major grooves of the DNA.

From the known three-dimensional structure of the repressor, model building and energy refinement have been used to develop a detailed model for the presumed complex between Cro and DNA. Recognition of specific DNA binding sites appears to occur via multiple hydrogen bonds between amino acid side chains of the protein and base pair atoms exposed within the major groove of DNA. The Cro:DNA model is consistent with the calculated electrostatic potential energy surface of the protein.

From a series of amino acid sequence and gene sequence comparisons, it appears that a number of other DNA-binding proteins have an α-helical DNA-binding region similar to that seen in Cro. The apparent sequence homology includes not only DNA-binding proteins from different bacteriophages, but also gene-regulatory proteins from bacteria and yeast. It has also been found that the conformations of part of the presumed DNA-binding regions of Cro repressor, λ repressor and CAP gene activator proteins are strikingly similar. Taken together, these results strongly suggest that a two-helical structural unit occurs in the DNA-binding region of many proteins that regulate gene expression. However, the results to date do not suggest that there is a simple one-to-one recognition code between amino acids and bases.

Crystals have been obtained of complexes of Cro with six-base-pair and nine-basepair DNA oligomers, and X-ray analysis of these co-crystals is in progress.     

Identification and purification of DBF-A, a double-stranded DNA-binding protein from Saccharomyces cerevisiae.

Using oligonucleotide affinity chromatography with DNase I footprinting as an assay we have looked for proteins that interact with sequence elements within the yeast origin of replication, autonomously replicating sequence 1 (ARS1). In this work we describe a protein that binds with high affinity to DNA but displays only moderate sequence specificity. It is eluted at 0.7 M salt from an ARS1 oligonucleotide column. Footprinting analysis on ARS1 at a high protein concentration revealed at least three sites of protection flanking element A and its repeats. Element A itself is rendered hypersensitive to DNase I digestion upon protein binding. This pattern is also observed for the H4 and HMR-E ARSs, suggesting that the protein alters the DNA conformation at element A and its repeats. The affinity-purified fraction is also capable of supercoiling a relaxed, covalently closed plasmid in the presence of topoisomerase. Highly purified preparations of the protein are enriched in an 18-kDa polypeptide which can be renatured from a denaturing gel and shown to bind ARS1 DNA. We have designated this protein DBF-A, DNA-binding factor A.     

Differential affinity and cooperativity functions of the amino-terminal 70 residues of lambda integrase

The site-specific recombinase (Int) of bacteriophage lambda is a heterobivalent DNA-binding protein that binds two different classes of DNA-binding sites within its recombination target sites. The several functions of Int are apportioned between a large carboxy-terminal domain that cleaves and ligates DNA at each of its four "core-type" DNA-binding sites and a small amino-terminal domain, whose primary function is binding to each of its five "arm-type" DNA sites, which are distant from the core region. Int bridges between the two classes of binding sites are facilitated by accessory DNA-bending proteins that along with Int comprise higher-order recombinogenic complexes. We show here that although the 64 amino-terminal residues of Int bind efficiently to a single arm site, this protein cannot form doubly bound complexes on adjacent arm sites. However, 1-70 Int does show the same cooperative binding to adjacent arm sites as the full length protein. We also found that 1-70 Int specifies cooperative interactions with the accessory protein Xis when the two are bound to their adjacent cognate sites P2 and X1, respectively. To complement the finding that these two amino-terminal domain functions (along with arm DNA binding) are all specified by residues 1-70, we determined that Thr75 is the first residue of the minimal carboxy-terminal domain, thereby identifying a specific interdomain linker region. We have measured the affinity constants for Int binding to each of the five arm sites and the cooperativity factors for Int binding to the two pairs of adjacent arm sites, and we have identified several DNA structural features that contribute to the observed patterns of Int binding to arm sites. Taken together, the results highlight several interesting features of arm DNA binding that invite speculation about additional levels of complexity in the regulation of lambda site-specific recombination.     

Bacteriophage lambda gpNu1 and Escherichia coli IHF proteins cooperatively bind and bend viral DNA: implications for the assembly of a genome-packaging motor

Terminase enzymes are common to both prokaryotic and eukaryotic double-stranded DNA viruses and are responsible for packaging viral DNA into the confines of an empty procapsid shell. In all known cases, the holoenzymes are heteroligomers composed of a large subunit that possesses the catalytic activities required for genome packaging and a small subunit that is responsible for specific recognition of viral DNA. In bacteriophage lambda, the DNA recognition protein is gpNu1. The gpNu1 subunit interacts with multiple recognition elements within cos, the packaging initiation site in viral DNA, to site-specifically assemble the packaging machinery. Motor assembly is modulated by the Escherichia coli integration host factor protein (IHF), which binds to a consensus sequence also located within cos. On the basis of a variety of biochemical data and the recently solved NMR structure of the DNA binding domain of gpNu1, we proposed a novel DNA binding mode that predicts significant bending of duplex DNA by gpNu1 (de Beer et al. (2002) Mol. Cell 9, 981-991). We further proposed that gpNu1 and IHF cooperatively bind and bend viral DNA to regulate the assembly of the packaging motor. Here, we characterize cooperative gpNu1 and IHF binding to the cos site in lambda DNA using a quantitative electrophoretic mobility shift (EMS) assay. These studies provide direct experimental support for the long presumed cooperative assembly of gpNu1 and IHF at the cos sequence of lambda DNA. Further, circular permutation experiments demonstrate that the viral and host proteins each introduce a strong bend in cos-containing DNA, but not nonspecific DNA substrates. Thus, specific recognition of viral DNA by the packaging apparatus is mediated by both DNA sequence information and by structural alteration of the duplex. The relevance of these results with respect to the assembly of a viral DNA-packaging motor is discussed.     

Determination of DNA-binding parameters for the Bacillus subtilis histone-like HBsu protein through introduction of fluorophores by site-directed mutagenesis of a synthetic gene.

A synthetic gene encoding the histone-like DNA-binding protein HBsu from Bacillus subtilis has been expressed in Escherichia coli. Yields of the purified protein are at least 20 mg/l culture medium. The recombinant HBsu protein is chromatographically, immunologically and functionally identical with the authentic wild-type protein. N-terminal sequencing of the purified protein confirms the fidelity of expression of the synthetic gene in E. coli. Site-directed mutagenesis of the synthetic gene was employed to replace several amino acid residues of HBsu protein with tryptophan to facilitate the determination of DNA-binding parameters by fluorescence spectroscopy. According to gel-retardation experiments, the mutant protein [Phe47----Trp]HBsu shows identical DNA binding to wild-type HBsu protein. Analysis of fluorescence binding data reveals that [Phe47----Trp]HBsu binds double-stranded DNA with a dissociation constant in the micromolar range. Computer-assisted fit of binding models to the experimental data renders positive cooperativity of binding unlikely. A dimer of [Phe47----Trp]HBsu appears to contact three or four base pairs of DNA. These results are in partial disagreement with earlier measurements on closely homologous proteins which tended to show cooperative binding and a longer DNA contact region.