Crystal structure and function of C-terminal Sau3AI domain

Sau3AI is a type II restriction enzyme that recognizes the 5'-GATC-3' sequence in double-strand DNA and cleaves at 5' to the G residue. The C-terminal domain of Sau3AI (Sau3AI-C), which contains amino acids from 233 to 489, was crystallized and its structure was solved by using the Multi-wavelength Anomalous Diffraction method. The Sau3AI-C structure at 1.9 A resolution is similar to the structure of MutH, a DNA mismatch repair protein that shares high sequence similarity with the N-terminal Sau3AI domain. The functional analysis shows that Sau3AI-C can bind DNA with one recognition sequence but has no cleavage activity. These results indicate that Sau3AI is a pseudo-dimer belonging to the type IIe restriction enzymes and the Sau3AI-C is the allosteric effector domain that assists DNA binding and cleavage.     

A DNA sequencing strategy

A modification of Lin's systematic DNA sequencing strategy is described. A method based on the religation of compatible cohesive ends generated by Sau3AI and BamHI was developed. The original procedure has been simplified and the yield of transfectant has been greatly improved. After complete digestion with BamHI and limited cleavage with Sau3AI, the single-cut linear DNA does not have to be separated from the supercoil or the open circular DNA on an agarose gel. After ligation, the DNA is digested with the restriction enzyme between the cloning site and BamHI site again. The original intact DNA is linearized, whereas the deleted subclone is not. Therefore the background is decreased to an undetectable level. This DNA sequencing strategy was tested on a 1.4-kb cDNA fragment containing the haptoglobin-related sequences. It is not necessary to purify large amounts of RF DNA (500 ng is enough) to get enough subclones. A set of subclones was produced in 1 day and the yield of plaques was about sixfold higher than that published.     

Alphoid satellite DNA is tightly associated with centromere antigens in human chromosomes throughout the cell cycle

In this study, we have examined a DNA element specific to the centromere domain of human chromosomes. Purified HeLa chromosomes were digested with the restriction enzyme Sau3AI and fractionated by sedimentation through a sucrose gradient. Fractions showing antigenecity to anticentromere (kinetochore) serum obtained from a scleroderma CREST patient were used to construct a DNA library. From this library we found one clone which has specifically hybridized to the centromere domain of metaphase chromosomes using a biotinylated probe DNA and FITC-conjugated avidin. The clone contained a stretch of alphoid DNA dimer. To determine precisely the relative location of the alphoid DNA stretch and the centromere antigen, a method was developed to carry out in situ hybridization of DNA and indirect immunofluorescent staining of antigen on the same cell preparation. Using this method, we have found perfect overlapping of the alphoid DNA sites with the centromere antigen sites in both metaphase chromosomes and nuclei at various stages in the cell cycle. We have also observed this exact correlation at the attachment sites of artificially extended sister chromatids. These results suggest the possibility that alphoid DNA repeats are a key component of kinetochore structure.     

Dynamics of single DNA looping and cleavage by Sau3AI and effect of tension applied to the DNA

Looping and cleavage of single DNA molecules by the two-site restriction endonuclease Sau3AI were measured with optical tweezers. A DNA template containing many recognition sites was used, permitting loop sizes from approximately 10 to 10,000 basepairs. At high enzyme concentration, cleavage events were detected within 5 s and nearly all molecules were cleaved within 5 min. Activity decreased approximately 10-fold as the DNA tension was increased from 0.03 to 0.7 pN. Substituting Ca(2+) for Mg(2+) blocked cleavage, permitting measurement of stable loops. At low tension, the initial rates of cleavage and looping were similar (approximately 0.025 s(-1) at 0.1 pN), suggesting that looping is rate limiting. Short loops formed more rapidly than long loops. The optimum size decreased from approximately 250 to 45 basepairs and the average number of loops (in 1 min) from 4.2 to 0.75 as tension was increased from 0.03 to 0.7 pN. No looping was detected at 5 pN. These findings are in qualitative agreement with recent theoretical predictions considering only DNA mechanics, but we observed weaker suppression with tension and smaller loop sizes. Our results suggest that the span and elasticity of the protein complex, nesting of loops, and protein-induced DNA bending and wrapping play an important role.     

DNA looping by two-site restriction endonucleases: heterogeneous probability distributions for loop size and unbinding force

Proteins interacting at multiple sites on DNA via looping play an important role in many fundamental biochemical processes. Restriction endonucleases that must bind at two recognition sites for efficient activity are a useful model system for studying such interactions. Here we used single DNA manipulation to study sixteen known or suspected two-site endonucleases. In eleven cases (BpmI, BsgI, BspMI, Cfr10I, Eco57I, EcoRII, FokI, HpaII, NarI, Sau3AI and SgrAI) we found that substitution of Ca2+ for Mg2+ blocked cleavage and enabled us to observe stable DNA looping. Forced disruption of these loops allowed us to measure the frequency of looping and probability distributions for loop size and unbinding force for each enzyme. In four cases we observed bimodal unbinding force distributions, indicating conformational heterogeneity and/or complex binding energy landscapes. Measured unlooping events ranged in size from 7 to 7500 bp and the most probable size ranged from less than 75 bp to nearly 500 bp, depending on the enzyme. In most cases the size distributions were in much closer agreement with theoretical models that postulate sharp DNA kinking than with classical models of DNA elasticity. Our findings indicate that DNA looping is highly variable depending on the specific protein and does not depend solely on the mechanical properties of DNA.     

Evidence that Escherichia coli virus T1 induces a DNA methyltransferase

DNA of Escherichia coli virus T1 is resistant to MboI cleavage and appears to be heavily methylated. Analysis of methylation by the isoschizomeric restriction enzymes Sau3AI and DpnI revealed that recognition sites for E. coli DNA adenine methylase (dam methylase) are methylated. The same methylation pattern was found for virus T1 DNA grown on an E. coli dam host, indicating a T1-specific DNA methyltransferase.     

DNA sequence recognition by under-methylated analogues of triostin A.

Two new analogues of TANDEM (des-N-tetramethyl triostin A) have been synthesised in an effort to elucidate the molecular basis of DNA nucleotide sequence recognition in this series of compounds. Their binding preferences have been investigated by DNAase I footprinting and differential inhibition of restriction nuclease attack. The presence of a single N-methyl group on only one valine residue (in [N-MeVal4] TANDEM) abolishes the ability to recognise DNA, presumably because this antibiotic analogue has suffered an unfavourable conformational change in the depsipeptide ring. A bis-methylated analogue, [N-MeCys3, N-MeCys7]TANDEM, was found to interact quite strongly with DNA and afforded binding sites, rich in AT residues, identical to those of TANDEM. Footprinting with various DNA fragments of known sequence showed that this analogue recognises sequences containing the dinucleotide TpA, although we cannot exclude the possibility that it binds to ApT as well. [N-MeCys3, N-MeCys7]TANDEM inhibits cutting by RsaI, a restriction enzyme that recognises GTAC but not by Sau3AI which recognises GATC. This provides further supportive evidence that the ligand (and, by extension, TANDEM itself) prefers binding to sequences containing the dinucleotide step TpA.     

A model of structure and action of Sau3AI restriction endonuclease that comprises two MutH-like endonuclease domains within a single polypeptide

Sau3AI is a type II endonuclease that cleaves GATC sequences, producing sticky ends with 4-nucleotide 5'-overhangs. Its activity is inhibited by cytosine C5-methylation within the target sequence. In the N-terminus, Sau3AI exhibits sequence similarity to the GATC-specific single-strand nicking endonuclease MutH implicated in mismatch repair (Ban and Yang, 1998). Sequence analysis of Sau3AI and its homologs reveals that Sau3AI possesses an additional MutH-like domain in the C-terminus. Structure prediction suggests that the C-terminal domain lacks the endonuclease active site but retains all putative DNA-binding elements. As an illustration of these findings, a model of quaternary structure of Sau3AI complexed with the target DNA is presented. These predictions have implications for evolution, structure and function of bacterial DNA repair enzymes and restriction endonucleases.     

Modulation of restriction enzyme-induced damage by chemicals that interfere with cellular responses to DNA damage: a cytogenetic and pulsed-field gel analysis

The electroporation of restriction enzymes into mammalian cells results in DNA double-strand breaks that can lead to chromosome aberrations. Four chemicals known to interfere with cellular responses to DNA damage were investigated for their effects on chromosome aberrations induced by AluI and Sau3AI; in addition, the number of DNA double-strand breaks at various times after enzyme treatment was determined by pulsed-field gel electrophoresis (PFGE). The poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide (3AB) dramatically increased the yield of exchanges and deletions and caused a small but transitory increase in the yield of double-strand breaks induced by the enzymes. 1-beta-D-Arabinofuranosylcytosine, which can inhibit DNA repair either by direct action on DNA polymerases alpha and delta or by incorporation into DNA, potentiated aberration induction but to a lesser extent than 3AB and did not affect the amount of DNA double-strand breakage. Aphidicolin, which inhibits polymerases alpha and delta, had no effect on AluI-induced aberrations but did increase the aberration yield induced by Sau3AI. The postreplication repair inhibitor caffeine had no effect on aberration yields induced by either enzyme. Neither aphidicolin nor caffeine modulated the amount of DNA double-strand breakage as measured by PFGE. These data implicate poly(ADP-ribosyl)ation and polymerases alpha and delta as important components of the cellular processes required for the normal repair of DNA double-strand breaks with blunt or cohesive ends. Comparison of these data with the effect of inhibitors on the frequency of X-ray-induced aberrations leads us to the conclusion that X-ray-induced aberrations can result from the misjoining or nonrejoining of double-strand breaks, particularly breaks with cohesive ends, but that this process accounts for only a portion of the induced aberrations.     

Efficient simplified cosmid cloning: construction and characterization of cosmid vectors that carry the two cohesive end sites of lambda phages arrayed in tandem

We constructed a series of cosmid vectors that carry the two cohesive end sites (cos) of lambda phage, arrayed in tandem, which enabled us to clone fragments of genomic DNA of up to 50 kb without a vector background. An equimolar mixture of the left and right vector arms of equal length was prepared from the vector DNA, simply by treating the DNA sequentially with three enzymes, restriction enzyme PvuII, alkaline phosphatase, and restriction enzyme BamHI (or BglII), without purification by agarose gel electrophoresis. After phenol extraction and ethanol precipitation, the equimolar mixture of the vector arms, which carried a single cos oriented from left to right, was directly ligated with insert DNA without further manipulation. We established conditions for cosmid cloning, using two kinds of DNA fragment of 40-50 kb, prepared from mouse L cell genomic DNA, as insert DNAs, namely, three cloned BamHI fragments and Sau3AI fragments, size-selected on a sucrose density gradient. The most important parameters affecting the cloning efficiency were the quality of the insert DNA and the molar ratio of the insert and vector arms. We achieved cloning efficiencies of 3.6 X 10(6)-1.3 X 10(7) colony forming units (cfu)/micrograms of insert DNA and 1.7 X 10(5)-1.0 X 10(6) cfu/micrograms of insert DNA, using the cloned BamHI fragments and the Sau3AI fragments, respectively. We examined more than 5000 clones and found that they all contained insert DNA.     

Enhanced Transformation Efficiency of Recalcitrant Bacillus cereus and Bacillus weihenstephanensis Isolates upon In Vitro Methylation of Plasmid DNA

Digestion patterns of chromosomal DNAs of Bacillus cereus and Bacillus weihenstephanensis strains suggest that Sau3AI-type restriction modification systems are widely present among the isolates tested. In vitro methylation of plasmid DNA was used to enhance poor plasmid transfer upon electroporation to recalcitrant strains that carry Sau3AI restriction barriers.     

Chromosomal location by in situ hybridization of the human Sau3A family of DNA repeats

Summary The Sau3A family is a human, clustered, highly repetitive, GC-rich DNA family. In situ hybridization studies with a plasmid carrying a Sau3A monomer as a probe have shown that Sau3A sequences are preferentially concentrated in the heterochromatic regions of human acrocentric chromosomes (D and G groups, both in pericentromeric regions and in cytological satellites) and in pericentromeric heterochromatin of chromosome 1. The same chromosomal locations were observed by using as probes two recombinant phages which carry Sau3A-positive genomic sectors. The two sectors differfor the relative proportions of monomer and multiples of Sau3A repeats, which show different extents of homology to the cloned monomer, and for the presence, in one of the two, of a samll amount of an unrelated repeat (alphoid DNA). The similarity of the results obtained with the three probes suggests that heterogeneous Sau3A repeats share the same chromosomal localizations and that the two analyzed genomic sectors may not contain significant amounts of repetitive DNAs other than the Sau3A family. A comparison between the chromosomal locations of Sau3A and EcoRI families of repeats has confirmed that each family is characterized by specific chromosomal locations and that single heterochromatic regions may contain both.     

A group of repetitive human DNA families that is characterized by extrachromosomal oligomers and restriction-fragment length polymorphism

We have recently reported a novel human repetitive DNA (Sau3A family) that exists both in the chromosomes and in the extrachromosomal fraction. Several more clones that hybridized with the Sau3A family were isolated from the extrachromosomal fraction of HeLa cells. Use of these clones as probes has revealed that at least four different types of oligomeric forms of DNA are present in the extrachromosomal fraction. The oligomers consist of one, two, five or 12 subunits of basic 170 base-pair unit DNA, or superimposed forms of two of them. Nucleotide sequencing of these clones indicated that the clones have 70 to 90% sequence homology with human alphoid satellite DNA. These DNA sequences are present also in the chromosomes, as tandemly repeated DNA sequences, and exhibit a considerable degree of restriction-fragment length polymorphism. These results, taken together with the previous findings on Sau3A family DNA, suggest that there is a group of recombination-prone repetitive DNA families in human chromosomes.     

Type II restriction endonucleases cleave single-stranded DNAs in general.

Restriction endonucleases (13 out of 18 species used for the test) were certified to cleave single-stranded(ss)DNA. Such enzymes as AvaII, HaeII, DdeI, AluI, Sau3AI, AccII,TthHB8I and HapII were newly reported to cleave ssDNA. A model to account for the cleavage of ssDNA by restriction enzymes was proposed with supportive data. The essential part of the model was that restriction enzymes preferentially cleave transiently formed secondary structures (called canonical structures) in ssDNA composed of two recognition sequences with two fold rotational symmetry. This means that a restriction enzyme can cleave ssDNAs in general so far as the DNAs have the sequences of restriction sites for the enzyme, and that the rate of cleavage depends on the stabilities of canonical structures.     

The double-length tyrosyl-tRNA synthetase from the eukaryote Leishmania major forms an intrinsically asymmetric pseudo-dimer

The single tyrosyl-tRNA synthetase (TyrRS) gene in trypanosomatid genomes codes for a protein that is twice the length of TyrRS from virtually all other organisms. Each half of the double-length TyrRS contains a catalytic domain and an anticodon-binding domain; however, the two halves retain only 17% sequence identity to each other. The structural and functional consequences of this duplication and divergence are unclear. TyrRS normally forms a homodimer in which the active site of one monomer pairs with the anticodon-binding domain from the other. However, crystal structures of Leishmania major TyrRS show that, instead, the two halves of a single molecule form a pseudo-dimer resembling the canonical TyrRS dimer. Curiously, the C-terminal copy of the catalytic domain has lost the catalytically important HIGH and KMSKS motifs characteristic of class I aminoacyl-tRNA synthetases. Thus, the pseudo-dimer contains only one functional active site (contributed by the N-terminal half) and only one functional anticodon recognition site (contributed by the C-terminal half). Despite biochemical evidence for negative cooperativity between the two active sites of the usual TyrRS homodimer, previous structures have captured a crystallographically-imposed symmetric state. As the L. major TyrRS pseudo-dimer is inherently asymmetric, conformational variations observed near the active site may be relevant to understanding how the state of a single active site is communicated across the dimer interface. Furthermore, substantial differences between trypanosomal TyrRS and human homologs are promising for the design of inhibitors that selectively target the parasite enzyme.     

Cooperative DNA Binding and Protein/DNA Fiber Formation Increases the Activity of the Dnmt3a DNA Methyltransferase

The Dnmt3a DNA methyltransferase has been shown to bind cooperatively to DNA and to form large multimeric protein/DNA fibers. However, it has also been reported to methylate DNA in a processive manner, a property that is incompatible with protein/DNA fiber formation. We show here that the DNA methylation rate of Dnmt3a increases more than linearly with increasing enzyme concentration on a long DNA substrate, but not on a short 30-mer oligonucleotide substrate. We also show that addition of a catalytically inactive Dnmt3a mutant, which carries an amino acid exchange in the catalytic center, increases the DNA methylation rate by wild type Dnmt3a on the long substrate but not on the short one. In agreement with this finding, preincubation experiments indicate that stable protein/DNA fibers are formed on the long, but not on the short substrate. In addition, methylation experiments with substrates containing one or two CpG sites did not provide evidence for a processive mechanism over a wide range of enzyme concentrations. These data clearly indicate that Dnmt3a binds to DNA in a cooperative reaction and that the formation of stable protein/DNA fibers increases the DNA methylation rate. Fiber formation occurs at low μm concentrations of Dnmt3a, which are in the range of Dnmt3a concentrations in the nucleus of embryonic stem cells. Understanding the mechanism of Dnmt3a is of vital importance because Dnmt3a is a hotspot of somatic cancer mutations one of which has been implicated in changing Dnmt3a processivity.     

Induction of chromosome damage by restriction enzymes during mitosis.

Once electroporated into the nucleus of eukaryotic cells, restriction enzymes will bind at specific DNA sequences and cleave DNA to make double-strand breaks. These induced breaks can lead to chromosome aberrations and consequently offer one approach to determining the mechanism(s) of aberration formation. Because the higher-order structure of DNA in eukaryotic cells might influence the ability of restriction enzymes to locate their recognition sequence, bind, and cleave DNA, we have investigated whether enzymes will cut DNA during metaphase when the chromosomes are most condensed. Chinese hamster ovary cells synchronized in mitosis and treated with either AluI or Sau3AI showed few chromosome aberrations when held in mitosis for 1, 2, or 3 h after enzyme treatment. However, some disruption of chromosome morphology was seen, especially after exposure to Sau3AI. When cells were allowed to complete one cell cycle after enzyme treatment in the preceding mitosis, there was extensive chromosome damage, with the most abundant type of lesion being the interstitial deletion. It appears that restriction enzymes will cleave the highly condensed DNA in mitotic cells but that decondensation, DNA replication, and recondensation are required before the aberrations are manifested.     

A restriction endonuclease from Staphylococcus aureus.

A specific endonuclease, Sau 3AI, has been partially purified from Staphylococcus aureus strain 3A by DEAE-cellulose chromatography. The enzyme cleaves adenovirus type 5 DNA many times, SV40 DNA eight times but does not cleave double-stranded phi X174 DNA. It recognizes the sequence (see article) and cleaves as indicated by the arrows. Evidence is presented that this enzyme plays a role in the biological restriction-modification system of Staphylococcus aureus strain 3A.     

Subunit assembly for DNA cleavage by restriction endonuclease SgrAI

The SgrAI endonuclease usually cleaves DNA with two recognition sites more rapidly than DNA with one site, often converting the former directly to the products cut at both sites. In this respect, SgrAI acts like the tetrameric restriction enzymes that bind two copies of their target sites before cleaving both sites concertedly. However, by analytical ultracentrifugation, SgrAI is a dimer in solution though it aggregates to high molecular mass species when bound to its specific DNA sequence. Its reaction kinetics indicate that it uses different mechanisms to cleave DNA with one and with two SgrAI sites. It cleaves the one-site DNA in the style of a dimeric restriction enzyme acting at an individual site, mediating neither interactions in trans, as seen with the tetrameric enzymes, nor subunit associations, as seen with the monomeric enzymes. In contrast, its optimal reaction on DNA with two sites involves an association of protein subunits: two dimers bound to sites in cis may associate to form a tetramer that has enhanced activity, which then cleaves both sites concurrently. The mode of action of SgrAI differs from all restriction enzymes characterised previously, so this study extends the range of mechanisms known for restriction endonucleases.     

玉米单染色体的分离和体外扩增

建立了玉米单染色体的分离及体外扩增的方法。取95％乙醇固定后经果胶酶和纤维酶酶解的根尖制备染色体标本,用自制的微细玻璃针在倒置显微镜下挑取目的染色体。染色体DNA经Sau3A酶切后与人工合成的Sau3A连接接头连接,经两次PCR扩增获得足以用于构建单染色体DNA文库的扩增产物。片段大小为0．3～5kb,多数为0．5～3．5kb．与前人研究方法相比,所需底物量少（只需1条染色体）,扩增片段大,为植物中小型染色体分离、体外扩增进而进行单染色体DNA文库构建奠定了基础。