DNA sequence recognition by a eukaryotic sequence-specific endonuclease, Endo.SceI, from Saccharomyces cerevisiae

A eukaryotic sequence-specific endonuclease, Endo.SceI, causes sequence-specific double-stranded scission of double-stranded DNA to produce cohesive ends with four bases protruding at the 3' termini. Unlike in the case of restriction enzymes, an asymmetric 26-base pair consensus sequence was found around the cleavage site for Endo.SceI instead of a common sequence. We analyzed the base pairs that interacted with Endo.SceI on the recognition of its cleavage sites. A region comprising -10 through +16 base pairs from the center of the cleavage site was shown to be essential and sufficient for the sequence-specific cutting with Endo.SceI by experiments involving synthesized DNAs. Methylation interference experiments indicate that bases in the region comprising the +7 through +14 base pairs is involved in close contact with Endo.SceI in its recognition of the cleavage site. This +7 through +14-base pair region overlaps the most stringently conserved sequence in the consensus sequence for the cleavage site, suggesting that this region constitutes the core for the recognition by Endo.SceI.     

An endonuclease with multiple cutting sites, Endo.SceI, initiates genetic recombination at its cutting site in yeast mitochondria.

Endo.SceI is a mitochondrial sequence-specific endonuclease which has multiple cutting sites. In order to examine the possible role of Endo.SceI in homologous recombination, we analyzed the mode of recombination upon mating using antibiotic resistance markers on the mitochondrial genome. The segregation of a marker located very close to one of the Endo.SceI cutting sites showed a disparity (polarized segregation, i.e. gene conversion). This gene conversion depended on the presence of the functional Endo.SceI gene. In vivo cutting of mitochondrial DNA upon mating was detected at the cutting site in the antibiotic marker region, which also depended on the Endo.SceI activity. These results suggest that mitochondrial recombination is induced by cleavage of mitochondrial DNA by this sequence-specific endonuclease. This is the first demonstration that a sequence-specific endonuclease with multiple cutting sites induces genetic recombination.     

Stable association of 70-kDa heat shock protein induces latent multisite specificity of a unisite-specific endonuclease in yeast mitochondria.

The multisite-specific endonuclease Endo.SceI of yeast mitochondria is unique among endonucleases because its 50-kDa subunit forms a stable dimer with the mitochondrial 70-kDa heat shock protein (mtHSP70), which otherwise fulfills a chaperone function by binding transiently to unfolded proteins. Here we show that the mtHSP70 subunit confers broader sequence specificity, greater stability, and higher activity on the 50-kDa subunit. The 50-kDa subunit alone displayed weaker activity and highly sequence-specific endonuclease activity. The 50-kDa protein exists as a heterodimer with mtHSP70 in vivo, allowing Endo.SceI to cleave specifically at multiple sites on mitochondrial DNA. Endo.SceI may have evolved from a highly specific endonuclease that gained broader sequence specificity after becoming a stable partner of mtHSP70.     

A maturase-like subunit of the sequence-specific endonuclease endo.SceI from yeast mitochondria

Some yeast strains possess a sequence-specific endonuclease, Endo.SceI, which is a heterodimeric enzyme localized in mitochondria. The larger subunit (75 kDa) of Endo.SceI, encoded by a nuclear gene (ENS1), is transported from the cytosol into the mitochondria. In this study, we determined the partial amino acid sequence of the smaller subunit (50 kDa) of Endo.SceI. The determined sequence matched well the partial sequence deduced from a mitochondrial open reading frame (RF3). The RF3 locus is known to exhibit polymorphism since this reading frame in some yeast strains is supposed to encode a maturase-like protein, whereas in other strains, the frame is interrupted by GC clusters, which thus break the frame. Southern blot analysis of various yeast strains showed that the continuity of RF3 is correlated with the presence of Endo.SceI activity. These data indicate that the continuous RF3 sequence is a functional gene (ENS2) coding for the smaller subunit of Endo.SceI. The results of cytoduction, by which the continuous RF3 sequence was transferred into a yeast strain lacking mitochondrial DNA, confirmed this conclusion. This study suggests the involvement of Endo.SceI in genetic recombination of mitochondrial DNA.     

A subunit of yeast site-specific endonuclease SceI is a mitochondrial version of the 70-kDa heat shock protein

Endo.SceI of Saccharomyces cerevisiae is a heterodimeric site-specific endonuclease, which is distinguishable from prokaryotic restriction endonucleases in the mode of recognition of its cleavage site. We have used monoclonal antibodies specific to the larger subunit (75 kDa) of Endo.SceI to isolate the gene for the subunit (ENS1) from S. cerevisiae. Unexpectedly, ENS1 was found to encode a 70-kDa heat shock protein-related polypeptide and to be identical to recently cloned SSC1. Subcellular fractionation experiments on yeast cells revealed that the primary target site of the larger subunit is mitochondria, where almost all the Endo.SceI activity is localized. Molecular genetic analysis of ENS1 demonstrated its indispensability for growth and the requirement of a high level of its expression at the sporulation and germination stages. The data suggest that ENS1 plays an important role, especially at these differentiation stages.     

Redox state regulates binding of p53 to sequence-specific DNA, but not to non-specific or mismatched DNA.

Redox modulation of wild-type p53 plays a role in sequence-specific DNA binding in vitro . Reduction produces a DNA-binding form of the protein while oxidation produces a non-DNA-binding form. Primer extension analysis reveals that increasing concentrations of reduced p53 result in enhanced protection of the consensus sequence, while increasing concentrations of oxidized p53 confer minimal protection of the consensus sequence. DNA binding by oxidized p53 is, therefore, not sequence-specific. In contrast, there is no observable difference in the binding of oxidized p53 and reduced p53 to double-stranded non-specific or mismatched DNA in gel mobility shift assays. Both forms of p53 bind equally well, suggesting that redox modulation of p53 does not play a role in its binding to non-specific or mismatched DNA. In view of the in vitro evidence that redox state influences the sequence-specific DNA-binding of p53, we have examined the effect of oxidative stress on the in vivo ability of p53 to bind to and transactivate PG13-CAT, a reporter construct containing multiple copies of the p53 consensus binding site linked to the chloramphenicol acetyltransferase gene. Hydrogen peroxide treatment of cells cotransfected with p53 results in a marked decrease in CAT activity, suggesting that oxidation of p53 decreases the ability of the protein to bind to consensus DNA and transactivate target genes in vivo.     

Subunit structure of a yeast site-specific endodeoxyribonuclease, endo SceI. A study using monoclonal antibodies

Endo SceI is a eucaryotic site-specific endoDNase of 120 kDa that causes double-stranded scission at well-defined sites, but is distinguishable from procaryotic restriction endonucleases by its mode of sequence recognition and lack of related specific DNA modification. In purified preparations of endoSceI, only two polypeptide species of 75 kDa (75-kDa peptide) and 50 kDa (50-kDa peptide) are detected in apparently equal amounts. We prepared mouse monoclonal IgGs that bound specifically to the 75-kDa peptide (but not the 50-kDa peptide) without inhibiting the endoSceI activity. Immunoprecipitation experiments with these IgGs revealed that the 75-kDa peptide and the 50-kDa peptide are physically associated with each other and with the endonucleolytic activity. Full endoSceI activity was recovered by mixing the purified 75-kDa peptide and the partially purified 50-kDa peptide, each of which exhibited little or no endonuclease activity alone. These observations indicate that endoSceI consists of two non-identical subunits of 75 kDa and 50 kDa, and that both subunits are required for full enzyme activity.     

Binding kinetics and footprinting of TaqI endonuclease: effects of metal cofactors on sequence-specific interactions.

Restriction endonucleases achieve sequence-specific recognition and strand cleavage through the interplay of base, phosphate backbone, and metal cofactor interactions. In this study, we investigate the binding kinetics of TaqI endonuclease using the wild-type enzyme and a binding proficient, catalysis deficient mutant TaqI-D137A both in the absence of a metal cofactor and in the presence of Mg2+ or Ca2+. As demonstrated by gel mobility shift analyses, TaqI endonuclease requires a metal cofactor for achieving high-affinity specific binding to its cognate sequence, TCGA. In the absence of a metal cofactor, the enzyme binds all DNA sequences (TaqI cognate site, star site, and nonspecific site) with essentially equal affinity, thereby exhibiting little discrimination. The dissociation constant of the cognate sequence in the presence of Mg2+ at 60 degrees C is 0. 26 nM, a value comparable to our previously reported Km of 0.5 nM measured under steady-state conditions. The TaqI-TCGA-Mg2+ complex is stable, with a half-life of 21 min at 60 degrees C. The boundary of the protein-DNA interface is approximated to be about 18 bp as determined by DNase I footprinting. Data from this study support the notion that a metal cofactor plays a critical role for achieving sequence-specific discrimination in a subset of nucleases, including TaqI, EcoRV, and others.     

Purification of a eukaryotic site-specific endonuclease, Endo.Sce I, from Saccharomyces cerevisiae and effectors on its specificity and activity

A site-specific endonuclease (Endo.Sce I) which caused double-strand scission of DNA was highly purified from a eukaryote, Saccharomyces cerevisiae IAM4274. The molecular weight of the active form of Endo.Sce I was estimated to be 120,000 and 110,000 by sedimentation analysis on a glycerol density gradient and gel filtration on Ultrogel AcA34, respectively. Analysis of the fractions from the last column chromatography by polyacrylamide gel-electrophoresis in the presence of sodium dodecyl sulfate and by an assay of the endonucleolytic activities suggested that Endo.Sce I consists of two non-identical subunits with molecular weights of 75,000 and 50,000. Unlike restriction endonucleases, Endo.Sce I was active on chromosomal DNA of the cells which produced Endo.Sce I. Single-stranded DNA was not cleaved by Endo.Sce I, but inhibited the endonucleolytic activity of the enzyme on double-stranded DNA. The endonucleolytic activity of Endo.Sce I required the magnesium ions (Mg2+) as a sole cofactor; Mg2+ could not be replaced by Ca2+ or Zn2+. When Mg2+ was replaced by manganese ions (Mn2+), extensively purified Endo.Sce I cleaved double-stranded DNA at many other sites in addition to the sites at which DNA was cleaved in the presence of Mg2+. Experiments indicated that this is not the activation of contaminating endonuclease in the preparation of Endo.Sce I, but the result of relaxation in the site-specificity of cleavage.     

Kinetic sequence discrimination of cationic bis-PNAs upon targeting of double-stranded DNA.

Strand displacement binding kinetics of cationic pseudoisocytosine-containing linked homopyrimidine peptide nucleic acids (bis-PNAs) to fully matched and singly mismatched decapurine targets in double-stranded DNA (dsDNA) are reported. PNA-dsDNA complex formation was monitored by gel mobility shift assay and pseudo-first order kinetics of binding was obeyed in all cases studied. The kinetic specificity of PNA binding to dsDNA, defined as the ratio of the initial rates of binding to matched and mismatched targets, increases with increasing ionic strength, whereas the apparent rate constant for bis-PNA-dsDNA complex formation decreases exponentially. Surprisingly, at very low ionic strength two equally charged bis-PNAs which have the same sequence of nucleobases but different linkers and consequently different locations of three positive charges differ in their specificity of binding by one order of magnitude. Under appropriate experimental conditions the kinetic specificity for bis-PNA targeting of dsDNA is as high as 300. Thus multiply charged cationic bis-PNAs containing pseudoisocytosines (J bases) in the Hoogsteen strand combined with enhanced binding affinity also exhibit very high sequence specificity, thereby making such reagents extremely efficient for sequence-specific targeting of duplex DNA.     

DNA gyrase complex with DNA: determinants for site-specific DNA breakage.

DNA gyrase catalyses DNA supercoiling by making a transient double-stranded DNA break within its 120-150 bp binding site on DNA. Addition of the inhibitor oxolinic acid to the reaction followed by detergent traps a covalent enzyme-DNA intermediate inducing sequence-specific DNA cleavage and revealing potential sites of gyrase action on DNA. We have used site-directed mutagenesis to examine the interaction of Escherichia coli gyrase with its major cleavage site in plasmid pBR322. Point mutations have been identified within a short region encompassing the site of DNA scission that reduce or abolish gyrase cleavage in vitro. Mapping of gyrase cleavage sites in vivo reveals that the pBR322 site has the same structure as seen in vitro and is similarly sensitive to specific point changes. The mutagenesis results demonstrate conclusively that a major determinant for gyrase cleavage resides at the break site itself and agree broadly with consensus sequence studies. The gyrase cleavage sequence alone is not a good substrate, however, and requires one or other arm of flanking DNA for efficient DNA breakage. These results are discussed in relation to the mechanism and structure of the gyrase complex.     

A Non-Sequence-Specific DNA Binding Mode of RAG1 Is Inhibited by RAG2

RAG1 and RAG2 proteins catalyze site-specific DNA cleavage reactions in V(D)J recombination, a process that assembles antigen receptor genes from component gene segments during lymphocyte development. The first step towards the DNA cleavage reaction is the sequence-specific association of the RAG proteins with the conserved recombination signal sequence (RSS), which flanks each gene segment in the antigen receptor loci. Questions remain as to the contribution of each RAG protein to recognition of the RSS. For example, while RAG1 alone is capable of recognizing the conserved elements of the RSS, it is not clear if or how RAG2 may enhance sequence-specific associations with the RSS. To shed light on this issue, we examined the association of RAG1, with and without RAG2, with consensus RSS versus non-RSS substrates using fluorescence anisotropy and gel mobility shift assays. The results indicate that while RAG1 can recognize the RSS, the sequence-specific interaction under physiological conditions is masked by a high-affinity non-sequence-specific DNA binding mode. Significantly, addition of RAG2 effectively suppressed the association of RAG1 with non-sequence-specific DNA, resulting in a large differential in binding affinity for the RSS versus the non-RSS sites. We conclude that this represents a major means by which RAG2 contributes to the initial recognition of the RSS and that, therefore, association of RAG1 with RAG2 is required for effective interactions with the RSS in developing lymphocytes.     

Mechanisms of specific and nonspecific binding of architectural proteins in prokaryotic gene regulation

IHF and HU are small basic proteins of eubacteria that bind as homodimers to double-stranded DNA and bend the duplex to promote architectures required for gene regulation. These architectural proteins share a common alpha/beta fold but exhibit different nucleic acid binding surfaces and distinct functional roles. With respect to DNA-binding specificity, for example, IHF is sequence specific, while HU is not. We have employed Raman difference spectroscopy and gel mobility assays to characterize the molecular mechanisms underlying such differences in DNA recognition. Parallel studies of solution complexes of IHF and HU with the same DNA nonadecamer (5' --> 3' sequence: TC TAAGTAGTTGATTCATA, where the phage lambda H1 consensus sequence of IHF is underlined) show the following. (i) The structure of the targeted DNA site is altered much more dramatically by IHF than by HU binding. (ii) In the IHF complex, the structural perturbations encompass both the sugar-phosphate backbone and the bases of the consensus sequence, whereas only the DNA backbone is altered by HU binding. (iii) In the presence of excess protein, complexes of order higher than 1 dimer per duplex are detected for HU:DNA, though not for IHF:DNA. The results differentiate structural motifs of IHF:DNA and HU:DNA solution complexes, provide Raman signatures of prokaryotic sequence-specific and nonspecific recognition, and suggest that the architectural role of HU may involve the capability to recruit additional binding partners to even relatively short DNA sequences.     

Analysis of p53 "latency" and "activation" by fluorescence correlation spectroscopy. Evidence for different modes of high affinity DNA binding

The concept that the tumor suppressor p53 is a latent DNA-binding protein that must become activated for sequence-specific DNA binding recently has been challenged, although the "activation" phenomenon has been well established in in vitro DNA binding assays. Using electrophoretic mobility shift assays and fluorescence correlation spectroscopy, we analyzed the binding of "latent" and "activated" p53 to double-stranded DNA oligonucleotides containing or not containing a p53 consensus binding site (DNAspec or DNAunspec, respectively). In the absence of competitor DNA, latent p53 bound DNAspec and DNAunspec with high affinity in a sequence-independent manner. Activation of p53 by the addition of the C-terminal antibody PAb421 significantly decreased the binding affinity for DNAunspec and concomitantly increased the binding affinity for DNAspec. The net result of this dual effect is a significant difference in the affinity of activated p53 for DNAspec and DNAunspec, which explains the activation of p53. High affinity nonspecific DNA binding of latent p53 required both the p53 core domain and the p53 C terminus, whereas high affinity sequence-specific DNA binding of activated p53 was mediated by the p53 core domain alone. The data suggest that high affinity nonspecific DNA binding of latent and high affinity sequence-specific binding of activated p53 to double-stranded DNA differ in their requirement for the C terminus and involve different structural features of the core domain. Because high affinity nonspecific DNA binding of latent p53 is restricted to wild type p53, we propose that it relates to its tumor suppressor functions.     

DNA topoisomerase III from the hyperthermophilic archaeon Sulfolobus solfataricus with specific DNA cleavage activity

We report the production, purification, and characterization of a type IA DNA topoisomerase, previously designated topoisomerase I, from the hyperthermophilic archaeon Sulfolobus solfataricus. The protein was capable of relaxing negatively supercoiled DNA at 75 degrees C in the presence of Mg2+. Mutation of the putative active site Tyr318 to Phe318 led to the inactivation of the protein. The S. solfataricus enzyme cleaved oligonucleotides in a sequence-specific fashion. The cleavage occurred only in the presence of a divalent cation, preferably Mg2+. The cofactor requirement of the enzyme was partially satisfied by Cu2+, Co2+, Mn2+, Ca2+, or Ni2+. It appears that the enzyme is active with a broader spectrum of metal cofactors in DNA cleavage than in DNA relaxation (Mg2+ and Ca2+). The enzyme-catalyzed oligonucleotide cleavage required at least 7 bases upstream and 2 bases downstream of the cleavage site. Analysis of cleavage by the S. solfataricus enzyme on a set of oligonucleotides revealed a consensus cleavage sequence of the enzyme: 5'-G(A/T)CA(T)AG(T)G(A)X / XX-3'. This sequence bears more resemblance to the preferred cleavage sites of topoisomerases III than to those of topoisomerases I. Based on these data and sequence analysis, we designate the enzyme S. solfataricus topoisomerase III.     

A new class of site-specific endodeoxyribonucleases. Endo.Sce I isolated from a eukaryote, Saccharomyces cerevisiae

We had found that yeasts had intracellular endodeoxyribonucleases that cut phage DNA into a set of double-stranded fragments with discrete chain lengths. We purified one of them to apparent homogeneity from Saccharomyces cerevisiae and designated it Endo.Sce I. Sequence analysis around 5 cleavage sites in plasmid DNA and phage DNA revealed that Endo.Sce I cuts a defined phosphodiester bond in each strand of double helix at the cleavage sites and produces free cohesive ends consisting of 4 nucleotides protruding at 3'-termini. However, unlike in the case of prokaryotic type II-restriction endonucleases, (i) Endo.Sce I seems to consist of two nonidentical subunits, (ii) no common palindrome or consensus sequence including more than 5 base pairs is detected at or near these cleavage sites, and (iii) Endo.Sce I can cut the DNA isolated from the cells that produced Endo.Sce I. All of the 5 cleavage sites are included in inverted repeats, but these inverted repeats are variable in size, nucleotide sequence, and distance between repeating units. An inverted repeat itself is not a structure recognized by Endo.Sce I. This study shows that Endo.Sce I is the first example of eukaryotic site-specific endonuclease and has properties, as described above, which distinguish it from prokaryotic restriction endonucleases.