Functional expression of a sequence-specific endonuclease encoded by the retrotransposon R2Bm

A fraction of the 28S ribosomal genes in certain insect species is interrupted by the insertion elements R1 and R2. These two elements from the silkworm Bombyx mori (R1Bm and R2Bm) are retrotransposons capable of transposing in a highly sequence-specific manner. We report here the functional expression in E. coli of the entire single open reading frame of R2Bm and show that it encodes a double-stranded endo-nuclease (integrase) that can specifically cleave the 28S gene at the R2 insertion site. The resulting cleavage is a 4 bp staggered 5' overhang. Deletion analysis of the 28S gene revealed that the DNA sequence required for specific cleavage is asymmetric with respect to the actual insertion (cleavage) site, with fewer than 10 bp required at one side and at least 24 bp at the other side of the site. A model is proposed based on these and previous data to account for the sequence-specific integration of the R2 retrotransposon.     

Rational engineering of sequence specificity in R.MwoI restriction endonuclease

R.MwoI is a Type II restriction endonucleases enzyme (REase), which specifically recognizes a palindromic interrupted DNA sequence 5'-GCNNNNNNNGC-3' (where N indicates any nucleotide), and hydrolyzes the phosphodiester bond in the DNA between the 7th and 8th base in both strands. R.MwoI exhibits remote sequence similarity to R.BglI, a REase with known structure, which recognizes an interrupted palindromic target 5'-GCCNNNNNGGC-3'. A homology model of R.MwoI in complex with DNA was constructed and used to predict functionally important amino acid residues that were subsequently targeted by mutagenesis. The model, together with the supporting experimental data, revealed regions important for recognition of the common bases in DNA sequences recognized by R.BglI and R.MwoI. Based on the bioinformatics analysis, we designed substitutions of the S310 residue in R.MwoI to arginine or glutamic acid, which led to enzyme variants with altered sequence selectivity compared with the wild-type enzyme. The S310R variant of R.MwoI preferred the 5'-GCCNNNNNGGC-3' sequence as a target, similarly to R.BglI, whereas the S310E variant preferentially cleaved a subset of the MwoI sites, depending on the identity of the 3rd and 9th nucleotide residues. Our results represent a case study of a REase sequence specificity alteration by a single amino acid substitution, based on a theoretical model in the absence of a crystal structure.     

Substrate specificity of HeLa endonuclease R. A G-specific mammalian endonuclease

We examined the substrate specificity of endonuclease R (endo R) a mammalian endonuclease that cleaves G.C-rich DNA sequences. The best substrates for double-stranded cleavage were homopolymeric stretches of poly(dG).poly(dC). Plasmids which contain other G-rich sequences were also cleaved but at a reduced frequency. These included the telomeric sequences, d(G4T2) and d(G2-6A), which were cleaved at approximately one-third the frequency of d(G)n.d(C)n. The alternating copolymer d(GA) and the terminal sequences of adeno-associated virus d(G1-3T/A) were also cut. Poly(dA).poly(dT) and the alternating copolymer d(GC)n were not detectably cleaved. Although endo R has a nicking activity which converts supercoiled plasmids to nicked circular DNA, the nicking activity is random with respect to plasmid sequences. Specific cleavage of G-rich sequences appears to occur by a concerted double-stranded mechanism. The cleavage pattern within the G-rich runs suggests that cleavage can occur anywhere within the G-rich region. Product ligation experiments indicate that a limited number of cleavage events (1-2) occur/molecule. Inasmuch as the best substrates for endo R are d(G)n.d(C)n and telomeric sequences, we suggest that endo R may directly recognize and cleave DNA that contains G.G base pairing.     

The DNA sequence recognized by the EcoDXX1 restriction endonuclease

EcoDXX1 is a type-I restriction enzyme coded for by the plasmid pDXX1. Like other type-I restriction endonucleases, the enzyme catalyses the modification of susceptible DNA. We have determined the DNA sequence recognised by EcoDXX1 to be: 5'TCANNNNNNNATTC-3' 3'-AGTNNNNNNNTAAG-5' where N can be any nucleotide. This sequence has an overall structure very similar to previously determined type-I sequences.     

Dual role for Zn2+ in maintaining structural integrity and inducing DNA sequence specificity in a promiscuous endonuclease

We describe two uncommon roles for Zn2+ in enzyme KpnI restriction endonuclease (REase). Among all of the REases studied, KpnI REase is unique in its DNA binding and cleavage characteristics. The enzyme is a poor discriminator of DNA sequences, cleaving DNA in a promiscuous manner in the presence of Mg2+. Unlike most Type II REases, the active site of the enzyme comprises an HNH motif, which can accommodate Mg2+, Mn2+, or Ca2+. Among these metal ions, Mg2+ and Mn2+ induce promiscuous cleavage by the enzyme, whereas Ca2+-bound enzyme exhibits site-specific cleavage. Examination of the sequence of the protein revealed the presence of a zinc finger CCCH motif rarely found in proteins of prokaryotic origin. The zinc binding motif tightly coordinates zinc to provide a rigid structural framework for the enzyme needed for its function. In addition to this structural scaffold, another atom of zinc binds to the active site to induce high fidelity cleavage and suppress the Mg2+- and Mn2+-mediated promiscuous behavior of the enzyme. This is the first demonstration of distinct structural and catalytic roles for zinc in an enzyme, suggesting the distinct origin of KpnI REase.     

Comparative structural analysis of the Erbin PDZ domain and the first PDZ domain of ZO-1. Insights into determinants of PDZ domain specificity

We report a structural comparison of the first PDZ domain of ZO-1 (ZO1-PDZ1) and the PDZ domain of Erbin (Erbin-PDZ). Although the binding profile of Erbin-PDZ is extremely specific ([D/E][T/S]WV(COOH)), that of ZO1-PDZ1 is similar ([R/K/S/T][T/S][W/Y][V/I/L](COOH)) but broadened by increased promiscuity for three of the last four ligand residues. Consequently, the biological function of ZO-1 is also broadened, as it interacts with both tight and adherens junction proteins, whereas Erbin is restricted to adherens junctions. Structural analyses reveal that the differences in specificity can be accounted for by two key differences in primary sequence. A reduction in the size of the hydrophobic residue at the base of the site(0) pocket enables ZO1-PDZ1 to accommodate larger C-terminal residues. A single additional difference alters the specificity of both site(-1) and site(-3). In ZO1-PDZ1, an Asp residue makes favorable interactions with both Tyr(-1) and Lys/Arg(-3). In contrast, Erbin-PDZ contains an Arg at the equivalent position, and this side chain cannot accommodate either Tyr(-1) or Lys/Arg(-3) but, instead, interacts favorably with Glu/Asp(-3). We propose a model for ligand recognition that accounts for interactions extending across the entire binding site but that highlights several key specificity switches within the PDZ domain fold.     

Thermodynamic and structural studies of carbohydrate binding by the agrin-G3 domain

Agrin is a key heparan sulfate proteoglycan involved in the development and maintenance of synaptic junctions between nerves and muscles. Agrin's important functions include clustering acetylcholine receptors on the postsynaptic membranes of muscles and binding to the muscle protein alpha-dystroglycan through its glycan chains. ITC and NMR were used to study the interactions of the C-terminal domain, agrin-G3, with carbohydrates implicated in agrin's functions. Sialic acid caps the glycan chains of alpha-dystroglycan and occurs as a posttranslational modification on the muscle-specific kinase component of the agrin receptor. We found that agrin-G3 binds sialic acid in a Ca2+-dependent manner. ITC data indicate that binding is exothermic and occurs with a 1:1 stoichiometry. NMR chemical shift changes map the sialic acid binding site to the loops that control the domain's acetylcholine receptor clustering activity. By contrast, the glycosaminoglycans heparin and heparan sulfate bind independently of Ca2+. Binding is endothermic, and the binding site spans about 12 saccharide units. The binding site for heparin occupies a similar location but is distinct from that for sialic acid. NMR translational diffusion experiments show that agrin-G3 binds heparin with a 2:1 stoichiometry. Comparisons between the muscle (B0) and neuronal (B8) isoforms of the agrin domain showed very similar Ca2+ and carbohydrate binding properties. Our work identifies agrin-G3 as a functional analogue of the concanavalin A-type lectins, highlights functional similarities between agrin and laminin G domains, and provides mechanistic clues about the roles of carbohydrates in agrin's functions.     

A monomeric mutant of restriction endonuclease EcoRI nicks DNA without sequence specificity

We have mutated the monomer-monomer interface of the restriction endonuclease EcoRI in order to destabilize the homodimer and to stabilize heterodimers. Mutations of Leu158 to charged amino acid residues result in strong destabilization of the dimer. The largest effect was detected for the L158D mutant which is monomeric even at higher concentrations. It unspecifically degrades DNA by cleaving both single strands independently every 15 nucleotides on the average. Although cleavage is reproducible, it is not determined by nucleotide sequence but by general properties like conformation or deformability as has been found for other unspecific nucleases. Mutations of Ile230, which is in direct contact with Leu158 of the other subunit, cause structural changes with the loss of about ten percent alpha-helix content, but interfere only marginally with homodimerization and double strand cleavage. Again the mutation to aspartate shows the strongest effects. Mixtures of single mutants, one containing aspartate at one of the two positions and the other lysine at the corresponding position, form heterodimers. These are mainly stabilized compared to the homodimers by re-establishment of the wild-type hydrophobic interaction at the not mutated residues while an interaction of aspartate and lysine seems energetically unfavorable in this structural context.     

The sequence specificity domain of cytosine-C5 methylases.

Prokaryotic DNA[cytosine-C5]methyltransferases (m5C-methylases) share a common architectural arrangement of ten conserved sequence motifs. A series of eleven hybrids have been constructed between the HpaII (recognition sequence: Cm5CGG) and HhaI (recognition sequence: Gm5CGC) DNA-methylases. The hybrids were over-expressed in E.coli and their in vivo methylation phenotypes investigated. Six were inactive by our assay while five of them retained partial methylation activity and full specificity. In all five cases the specificity matched that of the parent methylase which contributed the so-called variable region, located between conserved motifs VIII and IX. This was the only sequence held in common between the active hybrids and for the first time provides unequivocal evidence that the specificity determinants of the mono-specific m5C-methylases are located within the variable region. Correlation of the hybrid methylase structure with the efficiency of methylation suggests that conserved motif IX may interact with the variable region whereas motif X most probably interacts with the N-terminal half of the molecule.     

Characterization of C- and N-terminal domains of Aquifex aeolicus MutL endonuclease: N-terminal domain stimulates the endonuclease activity of C-terminal domain in a zinc-dependent manner

DNA MMR (mismatch repair) is an excision repair system that removes mismatched bases generated primarily by failure of the 3'-5' proofreading activity associated with replicative DNA polymerases. MutL proteins homologous to human PMS2 are the endonucleases that introduce the entry point of the excision reaction. Deficiency in PMS2 function is one of the major etiologies of hereditary non-polyposis colorectal cancers in humans. Although recent studies revealed that the CTD (C-terminal domain) of MutL harbours weak endonuclease activity, the regulatory mechanism of this activity remains unknown. In this paper, we characterize in detail the CTD and NTD (N-terminal domain) of aqMutL (Aquifex aeolicus MutL). On the one hand, CTD existed as a dimer in solution and showed weak DNA-binding and Mn2+-dependent endonuclease activities. On the other hand, NTD was monomeric and exhibited a relatively strong DNA-binding activity. It was also clarified that NTD promotes the endonuclease activity of CTD. NTD-mediated activation of CTD was abolished by depletion of the zinc-ion from the reaction mixture or by the substitution of the zinc-binding cysteine residue in CTD with an alanine. On the basis of these results, we propose a model for the intramolecular regulatory mechanism of MutL endonuclease activity.     

Protein engineering of the colony-stimulating factor-1 receptor kinase domain for structural studies

A parallel approach to designing crystallization constructs for the c-FMS kinase domain was implemented, resulting in proteins suitable for structural studies. Sequence alignment and limited proteolysis were used to identify and eliminate unstructured and surface-exposed domains. A small library of chimeras was prepared in which the kinase insert domain of FMS was replaced with the kinase insert domain of previously crystallized receptor-tyrosine kinases. Characterization of the newly generated FMS constructs by enzymology and thermoshift assays demonstrated similar activities and compound binding to the FMS full-length cytoplasmic domain. Two chimeras were evaluated for crystallization in the presence and absence of a variety of ligands resulting in crystal structures, and leading to a successful structure-based drug design project for this important inflammation target.     

Pisum sativum endonuclease. Studies on substrate specificity and possible use as a biochemical tool

An endonuclease purified from germinating pea (Pisum sativum) seeds has been shown to catalyze the hydrolysis of heat-denatured single-stranded DNA. Since P. sativum endonuclease shows appreciable activity in the presence of DNA destabilizing agents and, unlike many similar endonucleases, significant activity at neutral pH, it is a potentially valuable tool for studies of the secondary structure of nucleic acids. The residual hydrolysis of duplex DNA is directed towards partially denatured, A,T-rich areas in native DNA. The rate of hydrolysis of deoxypolynucleotides was in the order poly(dT) greater than denatured DNA greater than poly(dA) greater than poly(dA-dT) = native DNA. Neither poly(dC), poly(dG) nor poly(dC).poly(dG) were attacked by the enzyme. Supercoiled, covalently closed circular phage PM2 form I DNA is converted to singly hit nicked circular form II and doubly hit linear from III duplexes. Prolonged treatment with enzyme does not further cleave the linear form III DNA. Addition of increasing concentrations of NaCl in the incubation mixture suppresses the conversion of form I to form II, but not the conversion of form II to form III, which is enhanced with the increasing ionic strength. The enzymatically relaxed circular form, I degree, obtained by unwinding of supercoiled DNA with a DNA-relaxing protein, is resistant to the action of the enzyme. Molecules with intermediate superhelix densities do not serve as substrates. The sites of cleavage of P. sativum endonuclease in PM2 DNA occur within regions that are readily denaturable in a topologically constrained superhelical molecule.     

Acquisition of endonuclease specificity during evolution of L1 retrotransposon

L1 is the most proliferative autonomous retroelement that comprises about 20% of mammalian genomes. Why L1s have proliferated so extensively in mammalian genomes is an important yet unsolved question. L1 copies are amplified via retrotransposition, in which the DNA cleavage specificity by the L1-encoded endonuclease (EN) primarily dictates sites of insertion. Whereas mammalian L1s show target preference for 5'-TTAAAA-3', other L1-like elements exhibit various degrees of target specificity. To gain insights on diversification of the EN specificity during L1 evolution, ENs of zebrafish L1 elements were analyzed here. We revealed that they form 3 discrete clades, M, F, and Tx1, which is in stark contrast to a single L1 clade in mammalian species. Interestingly, zebrafish clade M elements cluster as a sister group of mammalian L1s and show target-site preference for 5'-TTAAAA-3'. In contrast, elements of the clade F, the immediate outgroup of the clade M, show little specificity. We identified certain clade-specific amino acid residues in EN, many of which are located in the cleft that recognizes the substrate, suggesting that these amino acid alterations have generated 2 types of ENs with different substrate specificities. The distribution pattern of the 3 clades suggests a possibility that the acquisition of target specificity by the L1 ENs improved the L1 fitness under the circumstances in mammalian hosts.     

Crystallization and preliminary structural studies of the ncd motor domain

The motor domain of the kinesin homolog ncd has been crystallized in the presence of MgATP by the vapor diffusion method using polyethylene glycol as the precipitant. The crystals belong to the orthorhombic space group I222 with unit cell dimensions a = 127.1 Å, b = 122.3 Å, c = 68.0 Å, and there is one ncd molecule per asymmetric unit. The crystals diffract X-ray to at least 2.3 Å and are appropriate for high-resolution structure determination. © 1995 Wiley-Liss, Inc.     

A DNA sequence cleaved by restriction endonuclease R.EcoRI in only one strand.

Restriction endonuclease EcoRI cuts both strands of the DNA sequence

generating two separate frayed ends (Hedgpeth et al., 1972). Here it is shown that under standard digestion conditions, the enzyme also attacks the sequence

but cuts only one strand. The resulting nick is an efficient initiation point for DNA synthesis by Escherichia coli DNA polymerase I, allowing the selective labelling of one strand of the DNA duplex.In buffers of low molarity and high pH (8.5), EcoRI cleaves sequences with the form

(Polisky et al., 1975). Thus it seems that under both sets of conditions the enzyme recognises the four-base-pair core sequence

and that its ability to cleave different adjacent phosphodiester bonds varies with pH and ionic strength.     

Relaxed specificity of the EcoRV restriction endonuclease

The EcoRV restriction endonuclease normally shows a high specificity for its recognition site on DNA, GATATC. In standard reactions, it cleaves DNA at this site several orders of magnitude more readily than at any alternative sequence. But in the presence of dimethyl sulphoxide and at high pH, the EcoRV enzyme cleaves DNA at several sites that differ from its recognition site by one nucleotide. Of the 18 (3 X 6) possible sequences that differ from GATATC by one base, all were cleaved readily except for the following 4 sites: TATATC, CATATC, GATATA and GATATG. However, two of the sites that could be cleaved by EcoRV in the presence of dimethyl sulphoxide, GAGATC and GATCTC, were only cleaved on DNA that lacked dam methylation: both contain the sequence GATC, the recognition site for the dam methylase of Escherichia coli.