DNA cleavage reactions by type II restriction enzymes that require two copies of their recognition sites.

Several type II restriction endonucleases interact with two copies of their target sequence before they cleave DNA. Three such enzymes, NgoMIV, Cfr10I and NaeI, were tested on plasmids with one or two copies of their recognition sites, and on catenanes containing two interlinked rings of DNA with one site in each ring. The enzymes showed distinct patterns of behaviour. NgoMIV and NaeI cleaved the plasmid with two sites faster than that with one site and the catenanes at an intermediate rate, while Cfr10I gave similar steady-state rates on all three substrates. Both Cfr10I and NgoMIV converted the majority of the substrates with two sites directly to the products cut at both sites, while NaeI cleaved just one site at a time. All three enzymes thus synapse two DNA sites through three-dimensional space before cleaving DNA. With Cfr10I and NgoMIV, both sites are cleaved in one turnover, in a manner consistent with their tetrameric structures, while the cleavage of a single site by NaeI indicates that the second site acts not as a substrate but as an activator, as reported previously. The complexes spanning two sites have longer lifetimes on catenanes with one site in each ring than on circular DNA with two sites, which indicates that the catenanes have more freedom for site juxtaposition than plasmids with sites in cis.

Analysis of DNA looping interactions by type II restriction enzymes that require two copies of their recognition sites.

Before cleaving DNA substrates with two recognition sites, the Cfr10I, NgoMIV, NaeI and SfiI restriction endonucleases bridge the two sites through 3D space, looping out the intervening DNA. To characterise their looping interactions, the enzymes were added to plasmids with two recognition sites interspersed with two res sites for site-specific recombination by Tn21 resolvase, in buffers that contained either EDTA or CaCl2 so as to preclude DNA cleavage by the endonuclease; the extent to which the res sites were sequestered into separate loops was evaluated from the degree of inhibition of resolvase. With Cfr10I, a looped complex was detected in the presence but not in the absence of Ca(2+); it had a lifetime of about 90 seconds. Neither NgoMIV nor NaeI gave looped complexes of sufficient stability to be detected by this method. In contrast, SfiI with Ca(2+) produced a looped complex that survived for more than seven hours, whereas its looping interaction in EDTA lasts for about four minutes. When resolvase was added to a SfiI binding reaction in EDTA followed immediately by CaCl2, the looped DNA was blocked from recombination while the unlooped DNA underwent recombination. By measuring the distribution between looped and unlooped DNA at various SfiI concentrations, and by fitting the data to a model for DNA binding by a tetrameric protein to two sites in cis, an equilibrium constant for the looping interaction was determined. The equilibrium constant was essentially independent of the length of DNA between the SfiI sites.

Specificity from the synapsis of DNA elements by the Sfi I endonuclease.

The synapsis of DNA sites is a prerequisite for the reactions of many proteins that act at specific DNA sequences. The requirement for synapsis was investigated by analysing the reactions of Sfi I, a tetrameric restriction enzyme that cleaves DNA only after interacting with two recognition sites. In the presence of Mg2+, oligonucleotide duplexes with the cognate recognition sequence were cleaved rapidly, with cooperative kinetics, while non-cognate duplexes were not cleaved. In the absence of Mg2+, the primary complex formed by Sfi I with cognate DNA contained two duplexes synapsed by the tetramer: a secondary complex containing one duplex was seen only at elevated Sfi I concentrations. In contrast, the principal complex with non-cognate DNA contained one duplex bound to Sfi I. Pairs of non-cognate duplexes, or one cognate and one non-cognate duplex, generally failed to form synaptic complexes. On adding Mg2+to complexes with cognate DNA, cleavage occurred much more rapidly in the synaptic complex than in the secondary complex. DNA synapsis thus acts to enhance the specificity of Sfi I for its recognition sequence, by demanding two cognate sites for a catalytically active complex and by excluding non-cognate sites from the synaptic complex.