Pools of oligonucleotide conjugates consisting of 10-400 different molecular species were synthesized. The conjugates contained a varying number of ethylene glycol units attached to 3'-terminal, 5'-terminal and internal positions of the oligonucleotides. Conjugate synthesis was performed by phosphoramidite solid phase chemistry using suitably protected polyethylene glycol phosphoramidites and PEG-derivatized solid supports containing polydisperse PEGs of various molecular weight ranges. The pools were analyzed and fractionated by chromatographic and electrophoretic techniques, and the composition of isolated conjugates was revealed by matrix-assisted laser desorption/ionization mass spectrometry. The number and attachment sites of coupled ethylene glycol units greatly influence the hydrophobicity of the conjugates, as well as their electrophoretic mobilities. Conjugation had little effect on the hybridization behavior of oligonucleotide conjugates with unmodified complementary oligonucleotide strands. Melting temperatures were between 67 and 73 degrees C, depending on the size and number of coupled PEG chains, compared to 68 degrees C for the unmodified duplex. Conjugates with PEG coupled to both 3'- and 5'-terminal positions showed a more than 10-fold increase in exonuclease stability.
The present study deals with the binding and cleavage by EcoRII endonuclease of concatemer DNA duplexes containing EcoRII recognition sites (formula; see text) in which dT is replaced by dU or 5-bromodeoxyuridine, or 5'-terminal dC in the dT-containing strand is methylated at position 5. The enzyme molecule is found to interact with the methyl group of the dT residue of the DNA recognition site and to be at least in proximity to the H5 atom of the 5'-terminal dC residue in dT-containing strand of this site. Modification of any of these positions exerts an equal effects on the cleavage of both DNA strands. Endonuclease EcoRII was found to bind the substrate specifically. At the same time modification of the bases in recognized sequence may result in the formation of unproductive, though stable, enzyme-substrate complexes.
Some DNA species are resistant towards the restriction endonuclease EcoRII despite the presence of unmodified recognition sites. We show that 14 base-pair oligonucleotide duplexes containing the EcoRII recognition site 5'-CC(A/T)GG are cleaved by this enzyme and are able to stimulate EcoRII cleavage of such resistant DNA molecules (e.g. DNA of bacterial virus T3). A direct correlation between the concentration of oligonucleotide duplex molecules and the degree of EcoRII digestion of the primarily resistant DNA is observed. This indicates a stoichiometric rather than a catalytic mode of enzyme activation. An excess of DNA devoid of EcoRII sites ('non-site' DNA, e.g. MvaI-digested T7 DNA) does not interfere with the activity of EcoRII.
The restriction endonuclease EcoRII is unable to cleave DNA molecules when recognition sites are very far apart. The enzyme, however can be activated in the presence of DNA molecules with a high frequency of EcoRII sites or by oligonucleotides containing recognition sites: Addition of the activator molecules stimulates cleavage of the refractory substrate. We now show that endonucleolysis of the stimulator molecules is not a necessary prerequisite of enzyme activation. A total EcoRII digest of pBR322 DNA or oligonucleotide duplexes with simulated EcoRII ends (containing the 5' phosphate group), as well as oligonucleotide duplexes containing modified bases within the EcoRII site, making them resistant to cleavage, are all capable of enzyme activation. For activation EcoRII requires the interaction with at least two recognition sites. The two sites may be on the same DNA molecule, on different oligonucleotide duplexes, or on one DNA molecule and one oligonucleotide duplex. The efficiency of functional intramolecular cooperation decreases with increasing distance between the sites. Intermolecular site interaction is inversely related to the size of the stimulator oligonucleotide duplex. The data are in agreement with a model whereby EcoRII simultaneously interacts with two recognition sites in the active complex, but cleavage of the site serving as an allosteric activator is not necessary.
The interaction of MvaI restriction endonuclease with 14-membered deoxyribonucleotide duplexes containing modifications within the recognition site (CCA/TGG) has been studied. Substitution of m'dC for the internal dC residue, as well as substitution of fl'dU or rU for dT did not influence the initial rate of hydrolysis (vo) of modified strands, whereas the hydrolysis of unmodified strands was inhibited in some cases. Furthermore, the substitution of a pyrophosphate bond for a scissile phosphodiester bond in one strand completely inhibited digestion in this strand without any decrease of the rate of hydrolysis of the unmodified strand. In contrast to EcoRII endonuclease, which recognizes the same DNA sequence, in the case of MvaI endonuclease substrate recognition is possible in a wide range of conformational, electronic and hydrophobic alterations within the recognition site.
Oligonucleotides containing 2-aminopurine (2-AP) in place of G or A in the recognition site of EcoRII (CCT/AGG) or SsoII (CCNGG) restriction endonucleases have been synthesized in order to investigate the specific interaction of DNA with these enzymes. Physicochemical properties (CD spectra and melting behaviour) have shown that DNA duplexes containing 2-aminopurine exist largely in a stable B-like form. 2-Aminopurine base paired with cytidine, however, essentially influences the helix structure. The presence of a 2-AP-C mismatch strongly reduces the stability of the duplexes in comparison with the natural double strand, indicated by a biphasic melting behaviour. SsoII restriction endonuclease recognizes and cleaves the modified substrate with a 2-AP-T mismatch in the centre of the recognition site, but it does not cleave the duplexes containing 2-aminopurine in place of inner and outer G, or both. EcoRII restriction endonuclease does not cleave duplexes containing 2-aminopurine at all. The two-substrate mechanism of EcoRII-DNA interaction, however, allows hydrolysis of the duplex containing 2-aminopurine in place of adenine in the presence of the canonical substrate.
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