Saulius Grazulis

Structure of the tetrameric restriction endonuclease NgoMIV in complex with cleaved DNA.

The crystal structure of the NgoMIV restriction endonuclease in complex with cleaved DNA has been determined at 1.6 Å resolution. The crystallographic asymmetric unit contains a protein tetramer and two DNA molecules cleaved at their recognition sites. This is the first structure of a tetrameric restriction enzyme–DNA complex. In the tetramer, two primary dimers are arranged back to back with two oligonucleotides bound in clefts on opposite sides of the tetramer. The DNA molecules retain a B-type conformation and have an enclosed angle between their helical axes of 60°. Sequence-specific interactions occur in both the major and minor grooves. Two Mg2+ ions are located close to the cleaved phosphate at the active site of NgoMIV. Biochemical experiments show that interactions between the recognition sites within the tetramer greatly increase DNA cleavage efficiency.

Crystal structure of Citrobacter freundii restriction endonuclease Cfr10I at 2.15 A resolution.

The X-ray crystal structure of Citrobacter freundii restriction endonuclease Cfr10I has been determined at a resolution of 2.15 A by multiple isomorphous replacement methods and refined to an R-factor of 19.64%. The structure of Cfr10I represents the first structure of a restriction endonuclease recognizing a degenerated nucleotide sequence. Structural comparison of Cfr10I with previously solved structures of other restriction enzymes suggests that recognition of specific sequence occurs through contacts in the major and the minor grooves of DNA. The arrangement of the putative active site residues shows some striking differences from previously described restriction endonucleases and supports a two-metal-ion mechanism of catalysis.

Time-resolved fluorescence of 2-aminopurine as a probe of base flipping in M.HhaI–DNA complexes

DNA base flipping is an important mechanism in molecular enzymology, but its study is limited by the lack of an accessible and reliable diagnostic technique. A series of crystalline complexes of a DNA methyltransferase, M.HhaI, and its cognate DNA, in which a fluorescent nucleobase analogue, 2-aminopurine (AP), occupies defined positions with respect the target flipped base, have been prepared and their structures determined at higher than 2 Å resolution. From time-resolved fluorescence measurements of these single crystals, we have established that the fluorescence decay function of AP shows a pronounced, characteristic response to base flipping: the loss of the very short (∼100 ps) decay component and the large increase in the amplitude of the long (∼10 ns) component. When AP is positioned at sites other than the target site, this response is not seen. Most significantly, we have shown that the same clear response is apparent when M.HhaI complexes with DNA in solution, giving an unambiguous signal of base flipping. Analysis of the AP fluorescence decay function reveals conformational heterogeneity in the DNA–enzyme complexes that cannot be discerned from the present X-ray structures.

Crystal structure of MunI restriction endonuclease in complex with cognate DNA at 1.7 A resolution.

The MunI restriction enzyme recognizes the palindromic hexanucleotide sequence C/AATTG (the ‘/’ indicates the cleavage site). The crystal structure of its active site mutant D83A bound to cognate DNA has been determined at 1.7 Å resolution. Base‐specific contacts between MunI and DNA occur exclusively in the major groove. While DNA‐binding sites of most other restriction enzymes are comprised of discontinuous sequence segments, MunI combines all residues involved in the base‐specific contacts within one short stretch (residues R115–R121) located at the N‐terminal region of the 3104 helix. The outer CG base pair of the recognition sequence is recognized solely by R115 through hydrogen bonds made by backbone and side chain atoms to both bases. The mechanism of recognition of the central AATT nucleotides by MunI is similar to that of EcoRI, which recognizes the G/AATTC sequence. The local conformation of AATT deviates from the typical B‐DNA form and is remarkably similar to EcoRI–DNA. It appears to be essential for specific hydrogen bonding and recognition by MunI and EcoRI.

Nucleotide flips determine the specificity of the Ecl18kI restriction endonuclease

Restricion endonuclease Ecl18kI is specific for the sequence /CCNGG and cleaves it before the outer C to generate 5 nt 5′‐overhangs. It has been suggested that Ecl18kI is evolutionarily related to NgoMIV, a 6‐bp cutter that cleaves the sequence G/CCGGC and leaves 4 nt 5′‐overhangs. Here, we report the crystal structure of the Ecl18kI–DNA complex at 1.7 Å resolution and compare it with the known structure of the NgoMIV–DNA complex. We find that Ecl18kI flips both central nucleotides within the CCNGG sequence and buries the extruded bases in pockets within the protein. Nucleotide flipping disrupts Watson–Crick base pairing, induces a kink in the DNA and shifts the DNA register by 1 bp, making the distances between scissile phosphates in the Ecl18kI and NgoMIV cocrystal structures nearly identical. Therefore, the two enzymes can use a conserved DNA recognition module, yet recognize different sequences, and form superimposable dimers, yet generate different cleavage patterns. Hence, Ecl18kI is the first example of a restriction endonuclease that flips nucleotides to achieve specificity for its recognition site.

Structural mechanisms for the 5′-CCWGG sequence recognition by the N- and C-terminal domains of EcoRII

EcoRII restriction endonuclease is specific for the 5′-CCWGG sequence (W stands for A or T); however, it shows no activity on a single recognition site. To activate cleavage it requires binding of an additional target site as an allosteric effector. EcoRII dimer consists of three structural units: a central catalytic core, made from two copies of the C-terminal domain (EcoRII-C), and two N-terminal effector DNA binding domains (EcoRII-N). Here, we report DNA-bound EcoRII-N and EcoRII-C structures, which show that EcoRII combines two radically different structural mechanisms to interact with the effector and substrate DNA. The catalytic EcoRII-C dimer flips out the central T:A base pair and makes symmetric interactions with the CC:GG half-sites. The EcoRII-N effector domain monomer binds to the target site asymmetrically in a single defined orientation which is determined by specific hydrogen bonding and van der Waals interactions with the central T:A pair in the major groove. The EcoRII-N mode of the target site recognition is shared by the large class of higher plant transcription factors of the B3 superfamily.

4-[N-(Substituted 4-pyrimidinyl)amino]benzenesulfonamides as inhibitors of carbonic anhydrase isozymes I, II, VII, and XIII

A series of 4-[N-(substituted 4-pyrimidinyl)amino]benzenesulfonamides were designed and synthesised. Their binding potencies as inhibitors of selected recombinant human carbonic anhydrase (hCA) isozymes I, II, VII, and XIII were measured using isothermal titration calorimetry and the thermal shift assay. To determine the structural features of inhibitor binding, the crystal structures of several compounds in complex with hCA II were determined. Several compounds exhibited selectivity towards isozymes I, II, and XIII, and some were potent inhibitors of hCA VII.

A novel free-mounting system for protein crystals: transformation and improvement of diffraction power by accurately controlled humidity changes

The large size and the irregular shape of the protein molecules mean that protein crystals are characterized by very slight lattice forces. They have high solvent content in the region of 30 to 70% or even as much as 90%. Consequently, protein crystals are often unstable, poorly ordered and restricted to characteristic crystal sizes between some μm to 1 mm. One effort revealing suitable crystals is to exchange the crystal solution via diffusion. A novel device for capillary-free mounting of protein crystals is described. A controlled stream of air allows an accurate adjustment of the humidity at the crystal. The crystal is held on the tip of a micropipette. With a video system (CCD-camera), the two-dimensional shadow projections of crystals are recorded for optical analysis. Instead of the micropipette, a standard loop can also be used. Experiments and results for different crystal systems demonstrate the application of this method, also in combination with shock-freezing, to improve crystal order. Working with oxygen-free gases offers the possibility of crystal measurements under anaerobic conditions. Furthermore, the controlled application of arbitrary volatile substances with the gas stream is practicable. The control of the environment of the protein crystal in combination with accurate optical and X-ray measurements on the crystal system offers enormous possibilities for fine-tuned crystal engineering. s8b.m3.p4.la Spherically averaged phased translation function and its applications to search of molecules and fragments in the macromolecular electron density maps. A. Vagin1 and M. Isupov2, 1Department of Chemistry, University of York, Heslington, York YO1 5DD, UK; alexei@ysbl.york.ac.uk, 2School of Chemistry, University of Exeter, Stocker Road, Exeter, EX4 4QD, UK.