Controlling the enzymatic activity of a restriction enzyme by light.

For many applications it would be desirable to be able to control the activity of proteins by using an external signal. In the present study, we have explored the possibility of modulating the activity of a restriction enzyme with light. By cross-linking two suitably located cysteine residues with a bifunctional azobenzene derivative, which can adopt a cis- or trans-configuration when illuminated by UV or blue light, respectively, enzymatic activity can be controlled in a reversible manner. To determine which residues when cross-linked show the largest "photoswitch effect," i.e., difference in activity when illuminated with UV vs. blue light, > 30 variants of a single-chain version of the restriction endonuclease PvuII were produced, modified with azobenzene, and tested for DNA cleavage activity. In general, introducing single cross-links in the enzyme leads to only small effects, whereas with multiple cross-links and additional mutations larger effects are observed. Some of the modified variants, which carry the cross-links close to the catalytic center, can be modulated in their DNA cleavage activity by a factor of up to 16 by illumination with UV (azobenzene in cis) and blue light (azobenzene in trans), respectively. The change in activity is achieved in seconds, is fully reversible, and, in the case analyzed, is due to a change in V(max) rather than K(m).

High-resolution structures of Thermus thermophilus enoyl-acyl carrier protein reductase in the apo form, in complex with NAD+ and in complex with NAD+ and triclosan.

Enoyl-acyl carrier protein reductase (ENR; the product of the fabI gene) is an important enzyme that is involved in the type II fatty-acid-synthesis pathway of bacteria, plants, apicomplexan protozoa and mitochondria. Harmful pathogens such as Mycobacterium tuberculosis and Plasmodium falciparum use the type II fatty-acid-synthesis system, but not mammals or fungi, which contain a type I fatty-acid-synthesis pathway consisting of one or two multifunctional enzymes. For this reason, specific inhibitors of ENR are attractive antibiotic candidates. Triclosan, a broad-range antibacterial agent, binds to ENR, inhibiting fatty-acid synthesis. As humans do not have an ENR enzyme, they are not affected. Here, high-resolution structures of Thermus thermophilus (Tth) ENR in the apo form, bound to NAD(+) and bound to NAD(+) plus triclosan are reported. Differences from and similarities to other known ENR structures are reported; in general, the structures are very similar. The cofactor-binding site is also very similar to those of other ENRs and, as reported for other species, triclosan leads to greater ordering of the loop that covers the cofactor-binding site, which, together with the presence of triclosan itself, presumably provides tight binding of the dinucleotide, preventing cycling of the cofactor. Differences between the structures of Tth ENR and other ENRs are the presence of an additional ß-sheet at the N-terminus and a larger number of salt bridges and side-chain hydrogen bonds. These features may be related to the high thermal stability of Tth ENR.

DNA recognition by the homing endonuclease PI-SceI involves a divalent metal ion cofactor-induced conformational change.

PI-SceI, a homing endonuclease of the LAGLIDADG family, consists of two domains involved in DNA cleavage and protein splicing, respectively. Both domains cooperate in binding the recognition sequence. Comparison of the structures of PI-SceI in the absence and presence of substrate reveals major conformational changes in both the protein and DNA. Notably, in the protein-splicing domain the loop comprising residues 53-70 and adopts a "closed" conformation, thus enabling it to interact with the DNA. We have studied the dynamics of DNA binding and subsequent loop movement by fluorescence techniques. Six amino acids in loop53-70 were individually replaced by cysteine and modified by fluorescein. The interaction of the modified PI-SceI variants with the substrate, unlabeled or labeled with tetramethylrhodamine, was analyzed in equilibrium and stopped-flow experiments. A kinetic scheme was established describing the interaction between PI-SceI and DNA. It is noteworthy that the apparent hinge-flap motion of loop53-70 is only observed in the presence of a divalent metal ion cofactor. Substitution of the major Mg2+-binding ligands in PI-SceI, Asp-218 and Asp-326, by Asn or "nicking" PI-SceI with trypsin at Arg-277, which interferes with formation of an active enzyme.substrate complex, both prevent the conformational change of loop53-70. Deletion of the loop inactivates the enzyme. We conclude that loop53-70 is an important structural element that couples DNA recognition by the splicing domain with DNA cleavage by the catalytic domain and as such "communicates" with the Mg2+ binding sites at the catalytic centers.

Metal-dependent DNA cleavage mechanism of the I-CreI LAGLIDADG homing endonuclease.

The LAGLIDADG homing endonucleases include free-standing homodimers, pseudosymmetric monomers, and related enzyme domains embedded within inteins. DNA-bound structures of homodimeric I-CreI and monomeric I-SceI indicate that three catalytic divalent metal ions are distributed across a pair of overlapping active sites, with one shared metal participating in both strand cleavage reactions. These structures differ in the precise position and binding interactions of the metals. We have studied the metal dependence for the I-CreI homodimer using site-directed mutagenesis of active site residues and assays of binding affinity and cleavage activity. We have also reassessed the binding of a nonactivating metal ion (calcium) in the wild-type enzyme-substrate complex, and determined the DNA-bound structure of two inactive enzyme mutants. The conclusion of these studies is that the catalytic mechanism of symmetric LAGLIDADG homing endonucleases, and probably many of their monomeric cousins, involves a canonical two-metal mechanism in each of two active sites, which are chemically and structurally tethered to one another by a shared metal ion. Failure to occupy the shared metal site, as observed in the presence of calcium or when the metal-binding side chain from the LAGLIDADG motif (Asp 20) is mutated to asparagine, prevents cleavage by the enzyme.