Characterization of major recognition sequences for a herpes simplex virus type 1 origin-binding protein.

To investigate early initiation events in the replication of herpes simplex virus type 1, we analyzed interactions of proteins from infected cell extracts with the small origin of herpes simplex virus type 1 (oris1). Using the mobility shift assay, we detected two origin-specific binding interactions. We characterized the more prominent interaction on both strands of the DNA duplex with DNase I protection and methylation interference assays. Protein binding protects 17 bases of DNA on each strand from DNase I. These sequences are located at the left end of the central palindrome and are shifted four bases relative to one another. On the basis of the DNase protection pattern, we believe this protein to be related to the origin-binding protein defined by Elias et al. (P. Elias, M.E. O'Donnell, E.S. Mocarski, and I.R. Lehman, Proc. Natl. Acad. Sci. 83:6322-6326, 1986). Our DNase I footprint shows both strong and weak areas of protection. The regions strongly protected from DNase I align with the essential contact residues identified by interference footprinting. Methylation interference defines a small binding domain of 8 base pairs: 5'-GTTCGCAC-3'/3'-CAAGCGTG-5'. This recognition sequence contains two inverted 5'-GT(T/G)CG-3' repeats which share a 2-base overlap; thus, the origin-binding protein probably binds to the inverted repeats as a dimer.     

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.     

Characterizing the DNA contacts and cooperative binding of F plasmid TraM to its cognate sites at oriT

TraM is a DNA binding protein required for conjugative transfer of the self-transmissible IncF group of plasmids, including F, R1, and R100. F TraM binds to three sites in F oriT: two high affinity binding sites, sbmA and sbmB, which are direct repeats of nearly identical sequence involved in the autoregulation of the traM gene; and a lower affinity site, sbmC, an inverted repeat important for transfer, which is situated nearest to the nic site where transfer originates. TraM bound cooperatively to its binding sites at oriT; the presence of sbmA and sbmB increased the affinity for sbmC 10-fold. Bending of oriT DNA by TraM was minimal, suggesting that TraM, a tetramer, was able to loop the DNA when bound to sbmA and sbmB simultaneously. Hydroxyl radical footprinting of DNA of sbmA and sbmC revealed that TraM contacted the DNA within a region previously delineated by DNase I footprinting. TraM protected the CT bases within the sequence CTAG, which occurred at 12-base intervals on the top and bottom strand of sbmA, most consistently with other protected bases. The footprint on sbmC revealed that the predicted inverted repeats were protected by TraM with a pattern that began at the center of the repeats and radiated outward at 11-12 base intervals toward the 5'-ends of either strand. At high protein concentrations, this pattern extended beyond the footprint defined by DNase I, suggesting that the DNA was wrapped around the protein forming a nucleosome-like structure, which could aid in preparing the DNA for transfer.     

The origin binding protein of herpes simplex virus 1 binds cooperatively to the viral origin of replication oris

The origin binding protein (OBP) or herpes simplex virus 1 has been expressed in Escherichia coli and used to study the role of multiple OBP binding sites in the herpes simplex virus #1 origin of replication, oris. Our results showed that the sequence CGTTCGCACTT was required for the binding of OBP to duplex DNA with high affinity. The minimal oris contains three repeats of this sequence or close derivatives thereof. Filter binding experiments have demonstrated that specific binding occurs to two of these repeats, box I and box II. An investigation using the DNase I footprinting technique revealed that the binding of OBP to box I and box II was cooperative and led to the formation of a highly organized complex in which the entire oris sequence was induced. We observed furthermore that the AT-rich sequence of the oris dyad was readily accessible to macromolecules even in the OBP.oris complex. The DNase I cleavage pattern of this sequence was, however, altered radically, indicating that a significant conformational change had occurred. A tentative structural model for the OBP-oris interaction is discussed on the basis of these observations.     

Interaction between the replication origin and the initiator protein of the filamentous phage f1. Binding occurs in two steps

The replication initiator protein of bacteriophage f1 (gene II protein) binds to the phage origin and forms two complexes that are separable by polyacrylamide gel electrophoresis. Complex I is formed at low gene II protein concentrations, and shows protection from DNase I of about 25 base-pairs (from position +2 to +28 relative to the nicking site) at the center of the minimal origin sequence. Complex II is produced at higher concentrations of the protein, and has about 40 base-pairs (from -7 to +33) protected. On the basis of gel mobility, complex II appears to contain twice the amount of gene II protein as does complex I. The 40 base-pair sequence protected in complex II corresponds to the minimal origin sequence as determined by in-vivo analyses. The central 15 base-pair sequence (from +6 to +20) of the minimal origin consists of two repeats in inverted orientation. This sequence, when cloned into a plasmid, can form complex I, but not complex II. We call this 15 base-pair element the core binding sequence for gene II protein. Methylation interference with the formation of complex I by the wild-type origin indicates that gene II protein contacts six guanine residues located in a symmetric configuration within the core binding sequence. Formation of complex II requires, in addition to the core binding sequence, the adjacent ten base-pair sequence on the right containing a third homologous repeat. A methylation interference experiment performed on complex II indicates that gene II protein interacts homologously with the three repeats. In complex II, gene II protein protects from DNase I digestion not only ten base-pairs on the right but also ten base-pairs on the left of the sequence that is protected in complex I. Footprint analyses of various deletion mutants indicate that the left-most ten base-pairs are protected regardless of their sequence. The site of nicking by gene II protein is located within this region. A model is presented for the binding reaction involving both protein-DNA and protein-protein interactions.     

Human immunoglobulin kappa gene enhancer: chromatin structure analysis at high resolution.

The murine immunoglobulin kappa gene enhancer has previously been found to coincide with a region of altered chromatin structure reflected in a DNase I hypersensitivity site detectable on Southern blots of B-cell DNA. We examined the chromatin structure of the homologous region of human DNA using the high-resolution electroblotting method originally developed for genomic sequence analysis by G. Church and W. Gilbert (Proc. Natl. Acad. Sci. USA 81:1991-1995, 1984). Analysis of DNA isolated from cells treated in vivo with dimethyl sulfate revealed two B-cell-specific sites of enhanced guanine methylation. Both sites are located within perfect inverted repeats theoretically capable of forming cruciform structures; one of these repeats overlaps an enhancer core sequence. No enhancement or protection of guanine methylation was observed within sequences similar to sites of altered methylation previously described in the immunoglobulin heavy-chain enhancer. Treatment of isolated nuclei with DNase I or a variety of restriction endonucleases defined a B-cell-specific approximately 0.25-kilobase region of enhanced nuclease susceptibility similar to that observed in the murine kappa enhancer. The 130-base-pair DNA segment that shows high sequence conservation between human, mouse, and rabbit DNAs lies at the 5' end of the nuclease-susceptible region.     

Saccharomyces cerevisiae RAP1 binds to telomeric sequences with spatial flexibility

A wide divergence has been detected in the telomeric sequences among budding yeast species. Despite their length and homogeneity differences, all these yeast telomeric sequences show a conserved core which closely matches the consensus RAP1-binding sequence. We demonstrate that the RAP1 protein binds this sequence core, without involving the diverged sequences outside the core. In Saccharomyces castellii and Saccharomyces dairensis specific classes of interspersed variant repeats are present. We show here that a RAP1-binding site is formed in these species by connecting two consecutive 8 bp telomeric repeats. DNase I footprint analyses specify the binding site as the 13 bp sequence CTGGGTGTCTGGG. The RAP1 protein also binds the variant repeats, although with a lowered affinity. However, a split footprint is produced when RAP1 binds a variant repeat where the two half-sites of the binding site are separated by an additional 6 nt. This is probably caused by the intervening sequence looping out of the RAP1-DNA complex. We suggest that the bipartite subdomain structure of the RAP1 protein allows it to remodel telomeric chromatin, a feature which may be of great relevance for telomeric chromatin assembly and structure in vivo.     

Binding sites for maize nuclear proteins in the subterminal regions of the transposable elementActivator

Genetic data suggest that transposition of the maize elementActivator (Ac) is modulated by host factors. Using gel retardation and DNase I protection assays we identified maize proteins which bind to seven subterminal sites in both ends ofAc. Four DNase I-protected sites contain a GGTAAA sequence, the other three include either GATAAA or GTTAAA. The specificity of the maize protein binding toAc was verified by using a synthetic fragment containing four GGTAAA motifs as probe and competitor in gel retardation assays. All seven binding sites are located within regions requiredin cis for transposition. A maize protein binding site with the same sequence has previously been identified in the terminal inverted repeats of the maizeMutator element. Thus, the protein, that recognizes this sequence is a good candidate for a regulatory host factor forAc transposition.     

Binding sites for maize nuclear proteins in the subterminal regions of the transposable elementActivator

Genetic data suggest that transposition of the maize elementActivator (Ac) is modulated by host factors. Using gel retardation and DNase I protection assays we identified maize proteins which bind to seven subterminal sites in both ends ofAc. Four DNase I-protected sites contain a GGTAAA sequence, the other three include either GATAAA or GTTAAA. The specificity of the maize protein binding toAc was verified by using a synthetic fragment containing four GGTAAA motifs as probe and competitor in gel retardation assays. All seven binding sites are located within regions requiredin cis for transposition. A maize protein binding site with the same sequence has previously been identified in the terminal inverted repeats of the maizeMutator element. Thus, the protein, that recognizes this sequence is a good candidate for a regulatory host factor forAc transposition.     

NS3 protease of Langat tick-borne flavivirus cleaves serine protease substrates

A DNA fragment of 163 bp containing 11 GGA repeats formed two-end positioned mononucleosomes as efficiently as that of CTG repeats. However, the rotational positioning of the GGA fragment was weak because clear DNase I cleavage patterns with 10-base periodicity were not seen near the center of the GGA fragment but were detected in the entire region of the CTG fragment. Incubation of the GGA mononucleosomes with the same fragment provided the DNA-DNA complex, which had been shown by using naked DNA fragments. DNase I digestion of the complex exhibited protection in the GGA repeats and in flanking sequences of about 30 bp at both sides, suggesting that both the repeat and flanking regions were involved in the association. Interestingly, histone H1, which enhanced DNA-DNA association on naked DNA, did not affect the complex formation on mononucleosomes. These results imply that GGA microsatellites in genomes could associate with one another at multiple sites and that the association may play a role in functional organization of higher order chromatin architecture.     

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 nuclear targeting coiled-coil protein of <Emphasis Type="Italic">Helicobacter pylori</Emphasis> showing Ca<Superscript>2+</Superscript>-independent,Mg<Superscript>2+</Superscript>-dependent DNase I activity

HP0059, an uncharacterized gene of Helicobacter pylori, encodes a 284-aa-long protein containing a nuclear localization sequence (NLS) and multiple leucine-rich heptad repeats. Effects of HP0059 proteins in human stomach cells were assessed by incubation of recombinant HP0059 proteins with the AGS human gastric carcinoma cell line. Wild-type HP0059 proteins showed cytotoxicity in AGS cells in a concentration-dependent manner, whereas NLS mutant protein showed no effect, suggesting that the cytotoxicity is attributed to host nuclear localization. AGS cells transfected with pEGFP-HP0059 plasmid showed strong GFP signal merged to the chromosomal DNA region. The chromosome was fragmented into multiple distinct dots merged with the GFP signal after 12 h of incubation. The chromosome fragmentation was further explored by incubation of AGS chromosomal DNA with recombinant HP0059 proteins, which leaded to complete degradation of the chromosomal DNA. HP0059 protein also degraded circular plasmid DNA without consensus, being an indication of DNase I activity. The DNase was activated by MgCl₂, but not by CaCl₂. The activity was completely blocked by EDTA. The optimal pH and temperature for DNase activity were 7.0–8.0 and 55°C, respectively. These results indicate that HP0059 possesses a novel DNase I activity along with a role in the genomic instability of human gastric cells, which may result in the transformation of gastric cells.     

DNase I cleavage of adenoviral nucleoprotein.

Cleavage products resulting from DNase I treatment of adenoviral nucleoprotein were examined by gel electrophoresis, Southern blotting and hybridization to cloned restriction fragments derived from various regions of the viral genome. DNase I produced specific double-stranded cleavages in DNA of purified adenoviral cores and in DNA of intranuclear viral chromatin at early and late times of infection. At least some of these sites were also cleaved by DNase I in purified viral DNA, showing that sequence specificity of DNase I cleavage may contribute to the observation of specific double-stranded DNase I cleavage sites in adenoviral nucleoprotein. In addition, sites were observed which were specific either for cores or for intranuclear chromatin. In contrast to many cellular genes which have been characterized, there was no obvious relationship between DNase I cleavage sites and other features of the viral genome such as promoters or polyadenylation sites.     

Molecular evolution of shark and other vertebrate DNases I.

We purified pancreatic deoxyribonuclease I (DNase I) from the shark Heterodontus japonicus using three-step column chromatography. Although its enzymatic properties resembled those of other vertebrate DNases I, shark DNase I was unique in being a basic protein. Full-length cDNAs encoding the DNases I of two shark species, H. japonicus and Triakis scyllia, were constructed from their total pancreatic RNAs using RACE. Nucleotide sequence analyses revealed two structural alterations unique to shark enzymes: substitution of two Cys residues at positions 101 and 104 (which are well conserved in all other vertebrate DNases I) and insertion of an additional Thr or Asn residue into an essential Ca(2+)-binding site. Site-directed mutagenesis of shark DNase I indicated that both of these alterations reduced the stability of the enzyme. When the signal sequence region of human DNase I (which has a high alpha-helical structure content) was replaced with its amphibian, fish and shark counterparts (which have low alpha-helical structure contents), the activity expressed by the chimeric mutant constructs in transfected mammalian cells was approximately half that of the wild-type enzyme. In contrast, substitution of the human signal sequence region into the amphibian, fish and shark enzymes produced higher activity compared with the wild-types. The vertebrate DNase I family may have acquired high stability and effective expression of the enzyme protein through structural alterations in both the mature protein and its signal sequence regions during molecular evolution.     

A distant evolutionary relationship between bacterial sphingomyelinase and mammalian DNase I.

The three-dimensional structure of bacterial sphingomyelinase (SMase) was predicted using a protein fold recognition method; the search of a library of known structures showed that the SMase sequence is highly compatible with the mammalian DNase I structure, which suggested that SMase adopts a structure similar to that of DNase I. The amino acid sequence alignment based on the prediction revealed that, despite the lack of overall sequence similarity (less than 10% identity), those residues of DNase I that are involved in the hydrolysis of the phosphodiester bond, including two histidine residues (His 134 and His 252) of the active center, are conserved in SMase. In addition, a conserved pentapeptide sequence motif was found, which includes two catalytically critical residues, Asp 251 and His 252. A sequence database search showed that the motif is highly specific to mammalian DNase I and bacterial SMase. The functional roles of SMase residues identified by the sequence comparison were consistent with the results from mutant studies. Two Bacillus cereus SMase mutants (H134A and H252A) were constructed by site-directed mutagenesis. They completely abolished their catalytic activity. A model for the SMase-sphingomyelin complex structure was built to investigate how the SMase specifically recognizes its substrate. The model suggested that a set of residues conserved among bacterial SMases, including Trp 28 and Phe 55, might be important in the substrate recognition. The predicted structural similarity and the conservation of the functionally important residues strongly suggest a distant evolutionary relationship between bacterial SMase and mammalian DNase I. These two phosphodiesterases must have acquired the specificity for different substrates in the course of evolution.     

Identification of the replication terminator protein binding sites in the terminus region of the Bacillus subtilis chromosome and stoichiometry of the binding

DNase I footprinting of the interaction between the replication terminator protein (RTP) of Bacillus subtilis and the inverted repeat region (IRR) at the chromosome terminus, to which it binds to block the clockwise replication fork, showed that two major regions of 41 base pairs (bp) were protected from cleavage. These regions corresponded approximately to the imperfect inverted repeats (IRI and IRII) identified previously. Band retardation analyses of the interaction between RTP and portions of the IRR established that each inverted repeat (IRI or IRII) contained two RTP binding sites. By sedimentation equilibrium in the ultracentrifuge, RTP was found to exist as a dimer of 29 kDa at neutral pH and concentrations above 0.2 g/l. Quantitative studies of the RTP-IRR interaction using [3H]RTP and [32P]IRR showed that the fully saturated complex contained eight RTP monomers per IRR. It is concluded that a dimer of RTP binds to each of the four sites in IRR. The apparent dissociation constant for the interaction was estimated (in the presence of 50% glycerol) to be 1.2 x 10(-11) M (dimer of RTP). Glycerol was found to have a marked effect on the affinity of RTP for the IRR and on the relative amounts of the interaction complexes formed; in the absence of glycerol the dissociation constant was approximately 50-fold higher and there was pronounced co-operative binding of RTP dimers to adjacent sites in each inverted repeat. Examination of the DNA sequence in IRI and IRII identified two 8 bp direct repeats in each. The regions protected from DNase I cleavage in each inverted repeat and the protection afforded by a core sequence spanning just one of the 8 bp direct repeats were consistent with each 8 bp repeat representing a recognition sequence for the RTP dimer. A model describing the binding of RTP to the IRR is presented.