Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.1.30.2 (endonuclease)
18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The colicin DNase-specific immunity proteins interact with the endonuclease domain of the bacterial toxin colicin E9 with dissociation constants that span the millimolar to femtomolar affinity range. Among the non-cognate interactions Im2 shows the strongest binding toward the E9 DNase domain with a Kd of 10(-8) M, 6 orders of magnitude weaker than that of the cognate immunity protein Im9. Based on a NMR structure of Im9 that shows it to be a 4-helix protein, we have conducted a mutagenic scan in which elements of Im9 secondary structure were substituted into Im2 to precisely delineate regions that define specificity. Eleven chimeras were constructed, and their biological cross-reactivity toward colicins E2 and E9 was evaluated. From this set of mutants seven proteins were purified, and the Kd for their interaction with the E9 DNase domain was measured by a combination of stopped-flow fluorescence and subunit exchange kinetics. Our results show that immunity specificity is dominated by residues on helix II, accounting for 5 orders of magnitude binding specificity relative to Im2, and that packing interactions of helix II with its neighbor helix I and the loop connecting helix III with helix IV play minor roles. The conformational stability of these chimeric proteins was also determined. Proteins displaying an Im9 phenotype were all more stable than the parent Im2 protein, and surprisingly some chimeras were significantly more stable than either Im2 or Im9.
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PMID:Protein-protein interaction specificity of Im9 for the endonuclease toxin colicin E9 defined by homologue-scanning mutagenesis. 926 73

To determine the affinity towards DNA sequences of novel antitumor drugs in comparison with their parental compounds may lead to the design of new analogous drugs with improved antitumor activity. Thus, the affinities of Pt-berenil towards different DNA sites relative to cis-DDP and berenil drugs were analysed using DNase I footprinting and restriction endonuclease analysis. The data show that the Pt-berenil drug inhibits the cutting activity of Hind III enzyme to the same extent as the berenil ligand. In contrast, inhibition by Pt-berenil of the cutting activity of Bam HI enzyme is significantly lower than that of cis-DDP. These results indicate that although the cis-Pt(II) centres of Pt-berenil maintain certain affinity toward G + C regions, which are the main binding sequences of cis-DDP, however, the berenil ligand seems to direct the Pt-berenil molecule towards A + T regions, which are the binding sequences preferred by berenil. In fact, 1H- and 195Pt-NMR spectra of Pt-berenil:nucleoside complexes show that Pt-berenil not only covalently binds to N7 of guanosine but also to N1/N7 of adenosine.
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PMID:The berenil ligand directs the DNA binding of the cytotoxic drug Pt-berenil. 939 76

The endonuclease group of E colicins are a family of bacterial toxins whose cytotoxic activity in a producing host is inactivated by a specific immunity protein. The DNase of colicin E9 can be bound and inhibited by both cognate and noncognate immunity proteins, the dissociation constants for which span a range of 12-orders of magnitude. DNase binding specificity of the immunity proteins is governed primarily by helix II, the sequence of which is variable in this family of proteins. Heteronuclear NMR experiments have identified helix III along with helix II as the likely DNase binding site, although other regions of Im9 also showed perturbations on binding the E9 DNase. In the present work, we have used the NMR experiments as a guide for alanine scanning mutagenesis of Im9. Our data show that helices II and III of Im9 are indeed the DNase binding site and in addition quantitate the relative binding energy associated with each helix. We find that the conserved residues of helix III make the largest relative contribution toward E9 DNase binding. In conjunction with previous studies, the data suggest that specificity in the colicin-immunity system is governed by a dual recognition mechanism in which highly stabilizing interactions emanating from the conserved regions of an immunity protein act as the binding site anchor and these are modulated by interactions from neighboring, nonconserved amino acid residues. This modulation is likely to take the form of both favorable and unfavorable interactions, the balance of which define the specificity of the protein-protein interaction. The generality of such a dual recognition mechanism in other systems is also discussed.
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PMID:Specificity in protein-protein recognition: conserved Im9 residues are the major determinants of stability in the colicin E9 DNase-Im9 complex. 942 68

Two methods for the large scale preparation of uniformly isotope-labeled DNA for NMR studies have been developed. The first method comprises the growth of a suitable plasmid harboring multiple copies of the desired oligonucleotide in a medium based on 15N and 13C nutrients. The second method uses a polymerase chain reaction (PCR)-based approach with 15N- and/or 13C-labeled deoxynucleoside triphosphates. The novelty of our PCR strategy over existing ones is that the primer and template are the identical molecule, resulting in an exponential growth in the length of the double strand that contains tandem repeats of the target DNA sequence. This novel PCR approach, which we have termed ESRA for endonuclease-sensitive repeat amplification, is easy to use, results in high yields, and can be accomplished at low costs. The utility of both methods is demonstrated for the preparation of a double-stranded 21-mer uniformly labeled with 15N and a double-stranded 17-mer DNA uniformly labeled with 15N and 13C.
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PMID:Preparation of uniformly isotope-labeled DNA oligonucleotides for NMR spectroscopy. 944 84

Inteins are protein splicing elements that mediate their excision from precursor proteins and the joining of the flanking protein sequences (exteins). In this study, protein splicing was controlled by splitting precursor proteins within the Psp Pol-1 intein and expressing the resultant fragments in separate hosts. Reconstitution of an active intein was achieved by in vitro assembly of precursor fragments. Both splicing and intein endonuclease activity were restored. Complementary fragments from two of the three fragmentation positions tested were able to splice in vitro. Fragments resulting in redundant overlaps of intein sequences or containing affinity tags at the fragmentation sites were able to splice. Fragment pairs resulting in a gap in the intein sequence failed to splice or cleave. However, similar deletions in unfragmented precursors also failed to splice or cleave. Single splice junction cleavage was not observed with single fragments. In vitro splicing of intein fragments under native conditions was achieved using mini exteins. Trans-splicing allows differential modification of defined regions of a protein prior to extein ligation, generating partially labeled proteins for NMR analysis or enabling the study of the effects of any type of protein modification on a limited region of a protein.
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PMID:Control of protein splicing by intein fragment reassembly. 946 70

We report the first detailed comparison of two immunity proteins which, in conjunction with recent protein engineering data, begins to explain how these structurally similar proteins are able to bind and inhibit the endonuclease domain of colicin E9 (E9 DNase) with affinities that differ by 12 orders of magnitude. In the present work, we have determined the X-ray structure of the Escherichia coli colicin E7 immunity protein Im7 to 2.0 A resolution by molecular replacement, using as a trial model the recently determined NMR solution structure of Im9. Whereas the two proteins adopt similar four-helix structures, subtle structural differences, in particular involving a conserved tyrosine residue critical for E9 DNase binding, and the identity of key residues in the specificity helix, lie at the heart of their markedly different ability to bind the E9 DNase. Two other crystal structures were reported recently for Im7; in one, Im7 was a monomer and was very similar to the structure reported here, whereas in the other it was a dimer to which functional significance was assigned. Since this previous work suggested that Im7 could exist either as a monomer or a dimer, we used analytical ultracentrifugation to investigate this question further. Under a variety of solution conditions, we found that Im7 only ever exists in solution as a monomer, even up to protein concentrations of 15 mg/ml, casting doubt on the functional significance of the crystallographically observed dimer. This work provides a structural framework with which we can understand immunity-protein specificity, and in addition we believe it to be the first successfully refined crystal structure solved by molecular replacement using an NMR trial model with less than 100% sequence identity.
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PMID:A structural comparison of the colicin immunity proteins Im7 and Im9 gives new insights into the molecular determinants of immunity-protein specificity. 963 78

The immunity protein Im2 can bind and inhibit the noncognate endonuclease domain of the bacterial toxin colicin E9 with a Kd of 19 nM, 6 orders of magnitude weaker than that of the cognate immunity protein Im9 with which it shares 68% sequence identity. Previous work from our laboratory has shown that the specificity differences of these four-helix immunity proteins is due almost entirely to helix II which is largely variable in sequence in the immunity protein family. From alanine scanning mutagenesis of Im9 in conjunction with high-field NMR data, a dual recognition model for colicin-immunity protein specificity has been proposed whereby the conserved residues of helix III of the immunity protein act as the anchor of the endonuclease binding site while the variable residues of helix II control the specificity of the protein-protein interaction. In this work, we identify three residues (at positions 33, 34, and 38) in helix II which define the specificity differences of Im2 and Im9 for colicin E9 and, using alanine mutagenesis of the putative endonuclease binding surface of Im2, compare the distribution of binding energies for conserved and nonconserved sites in both immunity proteins. This comparison highlights the conserved residues of both Im2 and Im9 as the major determinants of E9 DNase binding energy. Conversely, the nonconserved, specificity-determining residues only contribute to the E9 DNase binding energy in the cognate Im9 protein, while in the noncognate immunity protein Im2, they either destabilize the complex or do not contribute to the binding energy. This comparative alanine scan of two immunity proteins therefore supports the dual recognition mechanism of selectivity in colicin-immunity protein interactions and provides a basis for understanding specificity in other protein-protein interaction systems involving structurally conserved protein families.
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PMID:Dual recognition and the role of specificity-determining residues in colicin E9 DNase-immunity protein interactions. 971 99

Human flap endonuclease-1 (FEN-1) is a member of the structure-specific endonuclease family and is essential in DNA replication and repair. FEN-1 has specific endonuclease activity for repairing nicked double-stranded DNA substrates that have the 5'-end of the nick expanded into a single-stranded tail, and it is involved in processing Okazaki fragments during DNA replication. Magnesium is a cofactor required for nuclease activity. We used small-angle x-ray scattering to obtain global structural information pertinent to nuclease activity from FEN-1, the D181A mutant, the wild-type FEN-1. 34-mer DNA flap complex, and the D181A.34-mer DNA flap complex. The D181A mutant, which has Asp-181 replaced by Ala, selectively binds to the flap structure, but has lost its cleaving activity. Asp-181 is thought to be involved in Mg2+ binding at the active site (Shen, B., Nolan, J. P., Sklar, L. A., and Park, M. S. (1996) J. Biol. Chem. 271, 9173-9176). Our data indicate that FEN-1 and the D181A mutant each have a radius of gyration of approximately 26 A, and the effect of Mg2+ on the scattering from the proteins alone is insignificant. The 34-mer DNA fragment was constructed such that it readily forms a 5'-flap structure. The formation of the flap conformation of the DNA substrate was evident by both the extrapolated Io scattering and radius of gyration and was supported by NMR spectrum and nuclease assays. In the absence of magnesium, the FEN-1.34-mer DNA flap complex has an Rg value of approximately 34 A, whereas the D181A.34-mer DNA flap complex self-associates, suggesting that a significant protein conformational change occurs by addition of the flap DNA substrate and that Asp-181 is crucial for proper binding of the protein to the DNA substrate. A time course change in the scattering profiles arising from magnesium activation of the FEN-1.34-mer DNA flap complex is consistent with the protein completely releasing the DNA substrate after cleavage.
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PMID:Structural changes measured by X-ray scattering from human flap endonuclease-1 complexed with Mg2+ and flap DNA substrate. 988 Apr 91

We have correlated the structural perturbations caused by DNA mismatches with the enzymatic data of the interaction of the restriction endonuclease EcoRI with DNA. Oligonucleotides d(CGAGAATTCTCA5GAXAATTCT) (X = G, A, T) and d(CGCGAATTYGCGT4CGCXAATTCGCG) (Y = C, X = G, T and Y = A, X = T) containing single mismatches within the EcoRI recognition site were characterized by NMR spectroscopy and by their EcoRI substrate properties. UV melting and gel electrophoresis studies confirm that the oligonucleotides form hairpin structures. The presence of either a CT or a CA mismatch results in markedly lower Tm and van't Hoff enthalpies compared with the fully base paired control. NMR imino proton spectra of these hairpins demonstrate that the perturbation caused by the two mispairs or a noncanonical AT pair is localized and limited to one or two base pairs on either side of the perturbation. The DNA hairpin structures containing single mismatches, and to a lesser extent also sequences with a single noncanonical base pair, are substrates for the restriction endonuclease. In addition to the strand scission at the nonperturbed GpA phosphodiester bond some cleavage is observed at the mismatched position. The interactions of the CA and CT mismatched hairpin with the enzyme are characterized by binding constants that are only 33 and 57 times lower, respectively, than that for the canonical sequence, corresponding to 8-10 kJ x mol(-1) less favorable free binding energy. This, taken together with the NMR data, indicates that the CA and CT mismatches have only small effects on the EcoRI recognition of the DNA substrate. We conclude that two out of the three hydrogen bonds that characterize the interaction of EcoRI with the CG base pair in the canonical sequence can still be formed for either the CT or CA mismatched recognition site.
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PMID:NMR spectroscopic and enzymatic studies of DNA hairpins containing mismatches in the EcoRI recognition site. 992 8

The activities of restriction enzymes are important examples of Mg(II)-dependent hydrolysis of DNA. While a number of crystallographic studies of enzyme-DNA complexes have also involved metal ions, there have been no solution studies exploring the relationship between enzyme conformation and metal-ion binding in restriction enzymes. Using PvuII restriction endonuclease as a model system, we have successfully developed biosynthetic fluorination and NMR spectroscopy as a solution probe of restriction-enzyme conformation. The utility of this method is demonstrated with a study of metal-ion binding by PvuII endonuclease. Replacement of 74% (+/- 10%) of the Tyr residues in PvuII endonuclease by 3-fluorotyrosine produces an enzyme with Mg(II)-supported specific activity and sequence specificity that is indistinguishable from that of the native enzyme. Mn(II) supports residual activity of both the native and fluorinated enzymes; Ca(II) does not support activity in either enzyme, a result consistent with previous studies. 1H- and 19F-NMR spectroscopic studies reveal that while Mg(II) does not alter the enzyme conformation, the paramagnetic Mn(II) produces both short-range spectral broadening and longer range changes in chemical shift. Most interestingly, Ca(II) binding perturbs a larger number of different resonances than Mn(II). Coupled with earlier mutagenesis studies that place Ca(II) in the active site [Nastri, H. G., Evans, P.D., Walker, I.H. & Riggs, P.D. (1997) J. Biol. Chem. 272, 25761-25767], these data suggest that the enzyme makes conformational adjustments to accommodate the distinct geometric preferences of Ca(II) and may play a role in the inability of this metal ion to support activity in restriction enzymes.
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PMID:Effects of divalent metal ions on the activity and conformation of native and 3-fluorotyrosine-PvuII endonucleases. 1010 58


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