NotI and SfiI: restriction endonucleases with octanucleotide recognition sequences

Restriction enzymes use a 24 dimensional coding space to recognize 6 base long DNA sequences

Restriction enzymes recognize and bind to specific sequences on invading bacteriophage DNA. Like a key in a lock, these proteins require many contacts to specify the correct DNA sequence. Using information theory we develop an equation that defines the number of independent contacts, which is the dimensionality of the binding. We show that EcoRI, which binds to the sequence GAATTC, functions in 24 dimensions. Information theory represents messages as spheres in high dimensional spaces. Better sphere packing leads to better communications systems. The densest known packing of hyperspheres occurs on the Leech lattice in 24 dimensions. We suggest that the single protein EcoRI molecule employs a Leech lattice in its operation. Optimizing density of sphere packing explains why 6 base restriction enzymes are so common.

Allosteric regulation of DNA cleavage and sequence-specificity through run-on oligomerization

SgrAI is a sequence specific DNA endonuclease that functions through an unusual enzymatic mechanism that is allosterically activated 200- to 500-fold by effector DNA, with a concomitant expansion of its DNA sequence specificity. Using single-particle transmission electron microscopy to reconstruct distinct populations of SgrAI oligomers, we show that in the presence of allosteric, activating DNA, the enzyme forms regular, repeating helical structures characterized by the addition of DNA-binding dimeric SgrAI subunits in a run-on manner. We also present the structure of oligomeric SgrAI at 8.6 Å resolution, demonstrating the conformational state of SgrAI in its activated form. Activated and oligomeric SgrAI displays key protein-protein interactions near the helix axis between its N termini, as well as allosteric protein-DNA interactions that are required for enzymatic activation. The hybrid approach reveals an unusual mechanism of enzyme activation that explains SgrAI's oligomerization and allosteric behavior.

Restriction endonucleases: natural and directed evolution

Type II restriction endonucleases (REs) are highly sequence-specific compared with other classes of nucleases. PD-(D/E)XK nucleases, initially represented by only type II REs, now comprise a large and extremely diverse superfamily of proteins and, although sharing a structurally conserved core, typically display little or no detectable sequence similarity except for the active site motifs. Sequence similarity can only be observed in methylases and few isoschizomers. As a consequence, REs are classified according to combinations of functional properties rather than on the basis of genetic relatedness. New alignment matrices and classification systems based on structural core connectivity and cleavage mechanisms have been developed to characterize new REs and related proteins. REs recognizing more than 300 distinct specificities have been identified in RE database (REBASE: http://rebase.neb.com/cgi-bin/statlist ) but still the need for newer specificities is increasing due to the advancement in molecular biology and applications. The enzymes have undergone constant evolution through structural changes in protein scaffolds which include random mutations, homologous recombinations, insertions, and deletions of coding DNA sequences but rational mutagenesis or directed evolution delivers protein variants with new functions in accordance with defined biochemical or environmental pressures. Redesigning through random mutation, addition or deletion of amino acids, methylation-based selection, synthetic molecules, combining recognition and cleavage domains from different enzymes, or combination with domains of additional functions change the cleavage specificity or substrate preference and stability. There is a growing number of patents awarded for the creation of engineered REs with new and enhanced properties.

Unusual target site disruption by the rare-cutting HNH restriction endonuclease PacI

The crystal structure of the rare-cutting HNH restriction endonuclease PacI in complex with its eight-base-pair target recognition sequence 5'-TTAATTAA-3' has been determined to 1.9 A resolution. The enzyme forms an extended homodimer, with each subunit containing two zinc-bound motifs surrounding a betabetaalpha-metal catalytic site. The latter is unusual in that a tyrosine residue likely initiates strand cleavage. PacI dramatically distorts its target sequence from Watson-Crick duplex DNA base pairing, with every base separated from its original partner. Two bases on each strand are unpaired, four are engaged in noncanonical A:A and T:T base pairs, and the remaining two bases are matched with new Watson-Crick partners. This represents a highly unusual DNA binding mechanism for a restriction endonuclease, and implies that initial recognition of the target site might involve significantly different contacts from those visualized in the DNA-bound cocrystal structures.

Structures of the rare-cutting restriction endonuclease NotI reveal a unique metal binding fold involved in DNA binding

The structure of the rare-cutting restriction endonuclease NotI, which recognizes the 8 bp target 5'-GCGGCCGC-3', has been solved with and without bound DNA. Because of its specificity (recognizing a site that occurs once per 65 kb), NotI is used to generate large genomic fragments and to map DNA methylation status. NotI contains a unique metal binding fold, found in a variety of putative endonucleases, occupied by an iron atom coordinated within a tetrahedral Cys4 motif. This domain positions nearby protein elements for DNA recognition, and serves a structural role. While recognition of the central six base pairs of the target is accomplished via a saturated hydrogen bond network typical of restriction enzymes, the most peripheral base pairs are engaged in a single direct contact in the major groove, reflecting reduced pressure to recognize those positions. NotI may represent an evolutionary intermediate between mobile endonucleases (which recognize longer target sites) and canonical restriction endonucleases.

A unique type II restriction endonuclease FspAI, that recognizes the octanucleotide sequence 5'-RTGC/GCAY-3'

A new type II restriction endonuclease designated FspAI has been partially purified from a Flexibacter species Tv-m21K. FspAI recognizes the octanucleotide sequence 5'-RTGC/GCAY-3' and cleaves it in the center generating blunt-ended DNA fragments.

CpG-specific common commitment in caspase-dependent and -independent cell deaths

Cell death in mammals seems to have caspase-dependent and -independent pathways unlike that in Caenorhabditis elegans where CED-3 protease activation is the central command. A recent suggestion to define apoptosis as the caspase-dependent or caspase-committed cell death form and leave cell death committed by other pathways as just cell death was meant to categorize the apparent divergence in mammalian cell death pathways. However, we show CpG oligonucleotides (ODN) blocking caspase-dependent fas(CD95) ligand-mediated apoptosis as well as caspase-independent etoposide-mediated apoptosis and etoposide-zVAD-mediated necrosis. CpG specificity was demonstrated by reversing the CpG motif or replacing it with a methylated motif (mCpG) which failed to inhibit. CpG ODN blocked CpG-specific DNA cleavage by rare-cutting NotI restriction, which produced a megabase cleavage pattern similar to that in the fasL and etoposide cell death inductions. CpG ODN inhibition was similar to that by CpG-specific SssI methylase. A common CpG-specific commitment point preceding caspase-dependent and -independent cell death pathways was suggested. CpG-specific modulation is a key epigenetic mechanism in genomic imprinting, resisting nuclease restriction, and patterning of chromatin conformations. It is now shown to have a powerful effect modulating cell death.

Reactions of type II restriction endonucleases with 8-base pair recognition sites

Type II restriction endonucleases usually recognize 4-6-base pair (bp) sites on DNA and cleave each site in a separate reaction. A few type II endonucleases have 8-bp recognition sites, but these seem unsuited for restriction, since their sites are rare on most DNA. Moreover, only one endonuclease that recognizes a target containing 8 bp has been examined to date, and this enzyme, SfiI, needs two copies of this site for its DNA cleavage reaction. In this study, several endonucleases with 8-bp sites were tested on plasmids that have either one or two copies of the relevant sequence to determine if they also need two sites. SgfI, SrfI, FseI, PacI, PmeI, Sse8781I, and SdaI all acted through equal and independent reactions at each site. AscI cleaved the DNA with one site at the same rate as that with two sites but acted processively on the latter. In contrast, SgrAI showed a marked preference for the plasmid with two sites and cleaved both sites on this DNA in a concerted manner, like SfiI. Endonucleases that require two copies of an 8-bp sequence may be widespread in nature, where, despite this seemingly inappropriate requirement, they may function in DNA restriction.

The Cfr10I restriction enzyme is functional as a tetramer

It is thought that most of the type II restriction endonucleases interact with DNA as homodimers. Cfr10I is a typical type II restriction enzyme that recognises the 5'-Pu decreases CCGGPy sequence and cleaves it as indicated by the arrow. Gel-filtration and analytical ultracentrifugation data presented here indicate that Cfr10I is a homotetramer in isolation. The only SfiI restriction enzyme that recognises the long interrupted recognition sequence 5'-GGCCNNNNNGGCC has been previously reported to operate as a tetramer however, its structure is unknown. Analysis of Cfr10I crystals revealed that a single molecule in the asymmetric unit is repeated by D2 symmetry to form a tetramer. To determine whether the packing of the Cfr10I in the crystal reflects the quaternary structure of the protein in solution, the tryptophan W220 residue located at the putative dimer-dimer interface was mutated to alanine, and the structural and functional consequences of the substitution were analysed. Equilibrium sedimentation experiments revealed that, in contrast to the wild-type Cfr10I, the W220A mutant exists in solution predominantly as a dimer. In addition, the tetramer seems to be a catalytically important form of Cfr10I, since the DNA cleavage activity of the W220A mutant is < 0.1% of that of the wild-type enzyme. Further, analysis of plasmid DNA cleavage suggests that the Cfr10I tetramer is able to interact with two copies of the recognition sequence, located on the same DNA molecule. Indeed, electron microscopy studies demonstrated that two distant recognition sites are brought together through the DNA looping induced by the simultaneous binding of the Cfr10I tetramer to both sites. These data are consistent with the tetramer being a functionally important form of Cfr10I.

Sse8387I, a useful eight base cutter for mammalian genome analysis (influence of methylation on the activity of Sse8387I)

To develop restriction enzymes that are useful for genome analysis, we previously performed screening and isolated Sse8387I from Streptomyces sp. strain 8387. Sse8387I is a restriction enzyme that recognizes 5'-CCTGCA/GG-3' and cleaves DNA at the site shown by the diagonal (Nucleic Acid Res., 18, 5637-5640). The present study evaluated the effects of methylation that is important when Sse8387I is used for genome analysis. Sse8387I lost cleavage activity after methylation of adenine or methylation of cytosine at any site in the recognition sequence. However, the recognition sequence of Sse8387I contains no CG sequence, which is the mammalian methylation sequence. In addition, we evaluated the effects of methylation of CG at sites other than the recognition sequence. The cleavage activity of Sse8387I was maintained even when CG sequences were present immediately before or after, or near the recognition sequence, and cytosine was methylated. These results suggest that CG methylation does not affect the cleavage activity of Sse8387I. Therefore, Sse8387I seems to be very useful for mammalian genome analysis.

SgfI, a new type-II restriction endonuclease that recognizes the octanucleotide sequence 5'-GCGAT/CGC-3'

A new restriction endonuclease (ENase), SgfI, has been isolated from the bacterium Streptomyces sp. SgfI recognizes the 8-bp palindrome 5'-GCGATCGC-3' and cleaves double-stranded DNA after the T in this sequence, producing a two-base 3' overhang compatible with PvuI termini. SgfI is a rare-cutting ENase and should be useful for megabase mapping experiments.

SrfI, a new type-II restriction endonuclease that recognizes the octanucleotide sequence, [sequence: see text]

A new restriction endonuclease, SrfI has been isolated from an unidentified species of Streptomyces. SrfI recognizes the 8-bp palindrome, 5'-GCCCGGGC and cleaves double-stranded DNA after the third C in the sequence, producing blunt ends. SrfI is a rare-cutting enzyme and should therefore be useful for megabase mapping.

Use of high coverage reference libraries of Drosophila melanogaster for relational data analysis. A step towards mapping and sequencing of the genome

Three differently made, primary Drosophila cosmid libraries of 16-fold genome coverage have been generated. Also, a jumping library has been created by a new method that takes advantage of methylation differences between genomic DNA and vector. Thirdly, two cDNA libraries have been picked. All these libraries have been arrayed on high-density in situ filters, each containing 9216 clones. As a reference system, such filters are distributed and identified clones are provided. Single-copy probes have identified on average 1.4 cosmids per genome equivalent. Together with cytogenetically mapped yeast artificial chromosomes, the libraries are also being used for physically mapping the genome, mainly by oligonucleotide fingerprinting and pool hybridizations. cDNA clones are further examined by a partial sequencing analysis by oligomer hybridization.

Sse8387I, a new type-II restriction endonuclease that recognizes the octanucleotide sequence 5'-CCTGCAGG-3'

A type II restriction endonuclease designated Sse8387I was partially purified from Streptomyces sp. 8387. This enzyme cleaved adenovirus 2 DNA at three sites, lambda phage DNA at five sites, and pUC18 and M13mp18 RF DNA at one site each, but did not cleave the DNAs from pBR322, SV40, or phi X174. Sse8387I recognized the octanucleotide sequence 5'-CCTGCA decreases GG-3', cleaving where shown by the arrow. Sse8387I is the first restriction endonuclease to be reported that recognizes an octanucleotide sequence consisting of all four nucleotides, G, A, T, and C. The frequency of occurrence of Sse8387I sites within sequenced regions of primate genomes was 2.4 times that of NotI sites.

SgrAI, a novel class-II restriction endonuclease from Streptomyces griseus recognizing the octanucleotide sequence 5'-CR/CCGGYG-3' [corrected]

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McrI: a novel class-II restriction endonuclease from Micrococcus cryophilus recognizing 5'-CGRY/CG-3'

A new class-II restriction endonuclease, McrI, with a novel sequence specificity as isolated from the Gram-positive eubacterium Micrococcus cryophilus. McrI recognizes the palindromic hexanucleotide sequence. [sequence: see text] The novel enzyme in the presence of Mg2(+)-ions cleaves specifically both strands as indicated by the arrows. The staggered cuts generate 3'-protruding ends with single-stranded 5'-RY-3' dinucleotide extensions. The McrI recognition sequence was deduced from mapping data on DNAs of bacteriophages theta X174RF and M13mp18RF characterized by one and four cleavage sites, respectively. The cut positions within both strands of the recognition sequence were determined in sequencing experiments by analyzing hydrolysis of phosphodiester bonds within a polylinker region of M13mp18RF DNA containing an additional McrI recognition site including treatment with T4 DNA polymerase. The novel enzyme may be a useful tool for cloning experiments by completion of the enzymes EclXI (5'-C/GGCCG-3'), NotI (5'-GC/GGCCGC-3'), PvuI (5'-CGAT/CG-3') as well as EaeI (5'-Y/GGCCR-3') and XhoII (5'-Y/GATCR-3') characterized by partly identical sequence specificities.

FseI, a new type II restriction endonuclease that recognizes the octanucleotide sequence 5' GGCCGGCC 3'

A Type II restriction endonuclease, designated FseI, has been partially purified from a Frankia species (NRRL 18528). This enzyme cleaves Adenovirus 2 DNA at three sites, but does not cleave the DNAs from bacteriophages lambda, T7, and phi X174, the animal virus SV40, pUC18 and pBR322. FseI recognizes the octanucleotide sequence 5' GGCCGG decreases CC 3' and cleaves as indicated by the arrow. The frequency of occurrence of FseI sites within sequenced regions of the human genome is similar to that for NotI sites.

Cleavage at the twelve-base-pair sequence 5'-TCTAGATCTAGA-3' using M.Xbal (TCTAGm6A) methylation and DpnI (Gm6A/TC) cleavage

The DNA methylase M.Xbal was isolated from an E. coli recombinant clone. We deduce that the enzyme methylates at the sequence 5'-TCTAGm6A-3'. In combination with the methylation-dependent restriction endonuclease, DpnI (5'-Gm6A/TC-3'), DNA cleavage occurs at the sequence 5'-TCTAGA/TCTAGA-3'. This twelve-base-pair site should occur once every 16,000,000 base pairs in a random sequence of DNA. The exceptional rarity of the M.XbaI/DpnI sequence makes it an ideal candidate for transpositional integration of a unique cleavage site into bacterial genomes. Retrotransposition into mammalian genomes is also an attractive possibility.

A cassette with seven unique restriction sites, including octanucleotide sequences: extension of multiple-cloning-site plasmids

A 27-bp synthetic DNA cassette was constructed which contains the restriction sites of the two rare-cutter enzymes NotI and SfiI and, in an overlapping arrangement, those of five enzymes with 6-bp recognition sequences: ApaI, BalI, NdeI, SacII, XmaIII. The protruding termini of the fragment allow its insertion into any EcoRI-cut DNA creating a new EcoRI site at one side of the cassette only. This fragment was integrated into the pUC18-like multiple-cloning-site (MCS) plasmids pTZ18R and pTZ19R, producing a set of vectors which carry seven additional unique restriction sites (giving a total of 17) within their MCS. They still provide the capabilities of simple recombinant selection by blue/white coloured colonies, creation of single-stranded DNA in the presence of a helper phage, and in vitro transcription of cloned DNA using T7 RNA-polymerase. Plasmids with two copies of the DNA cassette inserted into their MCS were also constructed. Beside the advantages they provide in some cloning procedures, these latter plasmids, which carry a tandem repeat, are valuable sources of related 27-bp fragments, with features similar to the original but with different cloning termini.

Construction of a Not I restriction map of the fission yeast Schizosaccharomyces pombe genome

Pulsed field gel electrophoresis and large DNA technology were used to construct a Not I restriction map of the entire genome of the fission yeast Schizosaccharomyces pombe. There are 14 detectable Not I sites in S. pombe 972h: 9 sites on chromosome I and 5 sites on chromosome II, while no Not I sites were found on chromosome III. The 17 fragments (including intact chromosome III) generated by Not I digestion were resolved by PFG electrophoresis. These fragments ranged in size from 4.5 kb to approximately 3.5 Mb. Various strategies were applied in determining, efficiently, the order of the fragments on the chromosomes. The genomic size measured by adding all the fragments together is about 14 Mb and the sizes of the three chromosomes are I, 5.7 Mb, II, 4.6 to 4.7 Mb, and III, 3.5 Mb. These are generally somewhat smaller than estimated previously.