The energetics of the interaction of BamHI endonuclease with its recognition site GGATCC.

The interaction of BamHI endonuclease with DNA has been studied crystallographically, but has not been characterized rigorously in solution. The enzyme binds in solution as a homodimer to its recognition site GGATCC. Only six base-pairs are directly recognized, but binding affinity (in the absence of the catalytic cofactor Mg(2+)) increases 5400-fold as oligonucleotide length increases from 10 to 14 bp. Binding is modulated by sequence context outside the recognition site, varying about 30-fold from the bes t (GTG or TAT) to the worst (CGG) flanking triplets. BamHI, EcoRI and EcoRV endonucleases all have different context preferences, suggesting that context affects binding by influencing the free energy levels of the complexes rather than that of the free DNA. Ethylation interference footprinting in the absence of divalent metal shows a localized and symmetrical pattern of phosphate contacts, with strong contacts at NpNpNpGGApTCC. In the presence of Mg(2+), first-order cleavage rate constants are identical in the two GGA half-sites, are the same for the two nicked intermediates and are unaffected by substrate length in the range 10-24 bp. DNA binding is strongly enhanced by mutations D94N, E111A or E113K, by binding of Ca(2+) at the active site, or by deletion of the scissile phosphate GpGATCC, indicating that a cluster of negative charges at the catalytic site contributes at least 3-4 kcal/mol of unfavorable binding free energy. This electrostatic repulsion destabilizes the enzyme-DNA complex and favors metal ion binding and progression to the transition state for cleavage.

Crystallization and preliminary X-ray diffraction analysis of MspI restriction endonuclease in complex with its cognate DNA.

The MspI restriction endonuclease is a type II restriction enzyme. Unlike all other restriction enzymes with known structures, MspI recognizes the palindromic tetranucleotide sequence 5'-C/CGG and cleaves it as indicated by the '/' to produce DNA products with 5' two-base overhangs. Owing to the nature of its cleavage pattern, it is likely that MspI would represent a new structural class of restriction endonucleases. Crystals of the dimeric MspI restriction enzyme bound to a duplex DNA molecule containing the specific recognition sequence have been obtained by vapor-diffusion techniques in the presence of polyethylene glycol as precipitant. The crystals belong to the monoclinic space group P2(1), with unit-cell parameters a = 50.2, b = 131.6, c = 59.3 A, beta = 109.7 degrees. The crystals contain one dimeric complex in the asymmetric unit. A complete native data set has been collected to a resolution of 2.05 A by cryo-crystallographic methods, with an R(merge) of 4.0%.

Crystallization and preliminary diffraction analysis of the HincII restriction endonuclease-DNA complex.

Crystals of the 60 kDa dimeric HincII restriction enzyme bound to a 12 base-pair dyad-symmetric duplex DNA carrying the specific 5'-GTCGAC recognition site have been obtained. Crystals grew by hanging-drop vapor diffusion from solutions containing polyethylene glycol 4000 as precipitating agent. The rod-shaped crystals belong to space group I222 (or I2(1)2(1)2(1)), with unit-cell dimensions a = 66.9, b = 176.7, c = 256.0 A. There are most likely to be two dimeric complexes in the asymmetric unit. A complete native data set has been collected from a high-energy synchrotron source to a resolution of 2.5 A at 100 K, with an R(merge) of 4.8%.

Genetic analysis of the base-specific contacts of BamHI restriction endonuclease.

Here, we investigate the highly specific interaction of the BamHI endonuclease with its cognate recognition sequence GGATCC by determining which amino acid residues can be substituted at the DNA interface while maintaining specificity. Mutational studies, together with the structural determination of the restriction endonuclease BamHI have revealed the amino acid residues which are involved in DNA catalysis and those which play a role in the specific binding of the enzyme to its cognate DNA recognition sequence. Amino acid residues N116, S118, R122, D154 and R155 are involved in DNA sequence recognition and are located in the major groove in close proximity to the nucleotide bases comprising the recognition sequence. Cassette mutagenesis of these amino acids, together with in vivo transcriptional interference selection, was used to identify an array of substitutions which maintain site-specific binding to the cognate GGATCC sequence. This approach has demonstrated the extent of acceptable variation among amino acid residues which are directly involved in site-specific binding. One variant, double mutant N116H, S118G was found to cleave DNA only when the adenine base in the recognition site is methylated.

A mutant of BamHI restriction endonuclease which requires N6-methyladenine for cleavage.

Amino acid residues Asn116 and Ser118 of the restriction endonuclease BamHI make several sequence-specific and water-bridged contacts to the DNA bases. An in vivo selection was used to isolate BamHI variants at position 116, 118 and 122 which maintained sequence specificity to GGATCC sites. Here, the variants N116H, N116H/S118G and S118G were purified and characterized. The variants N116H and N116H/S118G were found to have lost their ability to cleave unmethylated GGATCC sequences by more than two orders of magnitude, while maintaining nearly wild-type levels of activity on the N6-methyladenine-containing sequence, GGmATCC. In contrast, wild-type BamHI and variant S118G have only a three- to fourfold lower activity on unmethylated GGATCC sequences compared with GGmATCC sequences. The N116 to H116 mutation has effectively altered the specificity of BamHI from an endonuclease which recognizes and cleaves GGATCC and GGmATC, to an endonuclease which only cleaves GGmATCC. The N116H change of specificity is due to the lowered binding affinity for the unmethylated sequence because of the loss of two asparagine-DNA hydrogen bonds and the introduction of a favorable van der Waals contact between the imidazole group of histidine and the N6-methyl group of adenine.

A mitogen-activated protein kinase pathway is required for mu-opioid receptor desensitization.

The mu-opioid receptor mediates not only the beneficial painkilling effects of opiates like morphine but also the detrimental effects of chronic exposure such as tolerance and dependence. Different studies have linked tolerance to opioid receptor desensitization. Agonist activation of the mu-opioid receptor stimulates a mitogen-activated protein kinase (MAPK) activity, but the functional significance of this pathway remains unclear. We have focused on the MAPK signaling cascade to study mu-opioid receptor desensitization. We report that inhibition of the MAPK pathway blocks desensitization of mu-opioid receptor signaling as well as the loss of receptor density due to internalization. Our results suggest that a feedback signal emanating from the MAPK cascade is required for mu-opioid receptor desensitization.

Structure of the multimodular endonuclease FokI bound to DNA.

FokI is a member of an unusual class of bipartite restriction enzymes that recognize a specific DNA sequence and cleave DNA nonspecifically a short distance away from that sequence. Because of its unusual bipartite nature, FokI has been used to create artificial enzymes with new specificities. We have determined the crystal structure at 2.8A resolution of the complete FokI enzyme bound to DNA. As anticipated, the enzyme contains amino- and carboxy-terminal domains corresponding to the DNA-recognition and cleavage functions, respectively. The recognition domain is made of three smaller subdomains (D1, D2 and D3) which are evolutionarily related to the helix-turn-helix-containing DNA-binding domain of the catabolite gene activator protein CAP. The CAP core has been extensively embellished in the first two subdomains, whereas in the third subdomain it has been co-opted for protein-protein interactions. Surprisingly, the cleavage domain contains only a single catalytic centre, raising the question of how monomeric FokI manages to cleave both DNA strands. Unexpectedly, the cleavage domain is sequestered in a 'piggyback' fashion by the recognition domain. The structure suggests a new mechanism for nuclease activation and provides a framework for the design of chimaeric enzymes with altered specificities.

Human T-cell leukemia virus type 1 Tax releases cell cycle arrest induced by p16INK4a.

The human T-cell leukemia virus type 1 (HTLV-1) Tax oncoprotein causes cellular transformation by deregulating important cellular processes such as DNA repair, transcription, signal transduction, proliferation, and growth. Although it is clear that normal cell cycle control is deregulated during HTLV-1-induced cellular transformation, the effects of Tax on cell cycle control are not well understood. Flow cytometric analyses of human T cells indicate that cell cycle arrest in late G1, at or before the G1/S restriction point, by p16INK4a is relieved by Tax. Furthermore, Tax-dependent stimulation of 5-bromo-2'-deoxyuridine incorporation and transcriptional activation is inhibited by p16INK4a. This result suggests that p16INK4a is able to block Tax-dependent stimulation of DNA synthesis and cell cycle progression into S phase. In vitro binding assays with recombinant glutathione S-transferase fusion proteins and [35S]methionine-labeled proteins indicate that Tax binds specifically with p16INK4a but not with either p21cip1 or p27kip1. Furthermore, sequential immunoprecipitation assays with specific antisera and [35S]methionine-labeled cell lysates subsequent to coexpression with Tax and p16INK4a indicate that the two proteins form complexes in vivo. Immunocomplex kinase assays with cyclin-dependent kinase 4 antiserum indicate that Tax blocks the inhibition of cdk4 kinase activity by p16INK4a. This study identifies p16INK4a as a novel cellular target for Tax and suggests that the inactivation of p16INK4a function is a mechanism of cell cycle deregulation by Tax.

Crystallization and preliminary X-ray analysis of restriction endonuclease FokI bound to DNA.

FokI is a type IIs restriction endonuclease which recognizes an asymmetric DNA sequence and cleaves DNA a short distance away from the sequence. The enzyme is bipartite in nature with its DNA recognition and cleavage functions located on distinct domains. We report here cocrystals of the complete FokI enzyme (579 amino acids) bound to a 20-bp DNA fragment containing its recognition sequence. The complex is amongst the largest protein-DNA complexes to be crystallized, and required macroseeding techniques for optimal crystal growth. The cocrystals diffract to at least 2.8 A in resolution and belong to space group P2(1) with unit cell dimensions of a=67.9 A, b=119.8 A, c=69.1 A, beta = 96.6 degrees. Using specific amino acid analysis we show that asymmetric unit contains a single FokI molecule bound to the 20-bp DNA fragment. This paper reports the first cocrystals of a type IIs restriction endonuclease.

Structure of Bam HI endonuclease bound to DNA: partial folding and unfolding on DNA binding.

The crystal structure of restriction endonuclease Bam HI complexed to DNA has been determined at 2.2 angstrom resolution. The DNA binds in the cleft and retains a B-DNA type of conformation. The enzyme, however, undergoes a series of conformational changes, including rotation of subunits and folding of disordered regions. The most striking conformational change is the unraveling of carboxyl-terminal alpha helices to form partially disordered "arms." The arm from one subunit fits into the minor groove while the arm from the symmetry related subunit follows the DNA sugar-phosphate backbone. Recognition of DNA base pairs occurs primarily in the major groove, with a few interactions occurring in the minor groove. Tightly bound water molecules play an equally important role as side chain and main chain atoms in the recognition of base pairs. The complex also provides new insights into the mechanism by which the enzyme catalyzes the hydrolysis of DNA phosphodiester groups.

Cloning, analysis and expression of the HindIII R-M-encoding genes.

The genes encoding the HindIII restriction endonuclease (R.HindIII ENase) and methyltransferase (M.HindIII MTase) from Haemophilus influenzae Rd were cloned and expressed in Escherichia coli and their nucleotide (nt) sequences were determined. The genes are transcribed in the same orientation, with the ENase-encoding gene (hindIIIR) preceding the MTase-encoding gene (hindIIIM). The two genes overlap by several nt. The ENase is predicted to be 300 amino acids (aa) in length (34,950 Da); the MTase is predicted to be 309 aa (35,550 Da). The HindIII ENase and MTase activities increased approx. 20-fold when the genes were brought under the control of an inducible lambda pL promoter. Highly purified HindIII ENase and MTase proteins were prepared and their N-terminal aa sequences determined. In H. influenzae Rd, the HindIII R-M genes are located between the holC and valS genes; they are not closely linked to the HindII R-M genes.

Crystallization and preliminary X-ray analysis of restriction endonuclease BamHI-DNA complex.

Restriction endonuclease BamHI from Bacillus amyloliquefaciens has been co-crystallized with a 12 bp DNA fragment that encompasses its recognition site. The co-crystals diffract to at least 1.95 A resolution and belong to space group P2(1)2(1)2(1). The unit cell parameters are a = 108.8 A, b = 81.9 A, c = 68.8 A, consistent with one complex in the crystallographic asymmetric unit. The direction of the DNA appears to be along the b axis. In order to achieve end to end stacking of DNA, the complex must lie on the screw axis along b. A self-rotation function has determined the directions of the non-crystallographic 2-fold axes.

Structure of restriction endonuclease bamhi phased at 1.95 A resolution by MAD analysis.

BACKGROUND: Type II restriction endonucleases recognize DNA sequences that vary between four to eight base pairs, and require only Mg2+ as a cofactor to catalyze the hydrolysis of DNA. Their protein sequences display a surprising lack of similarity, and no recurring structural motif analogous to the helix-turn-helix or the zinc finger of transcription factors, has yet been discovered. RESULTS: We have determined the crystal structure of restriction endonuclease BamHI at 1.95 A resolution. The structure was solved by combining phase information derived from multi-wavelength X-ray data by algebraic and maximum likelihood methods. The BamHI subunit consists of a central beta-sheet with alpha-helices on both sides. The dimer configuration reveals a large cleft which could accommodate B-form DNA. Mutants of the enzyme that are deficient in cleavage are located at or near the putative DNA-binding cleft. BamHI and endonuclease EcoRI share a common core motif (CCM) consisting of five beta-strands and two helices. It remains to be determined if other restriction enzymes also contain the CCM. CONCLUSIONS: The structure of BamHI provides the first clear evidence that there may be substantial structural homology amongst restriction enzymes, even though it is undetectable at the sequence level.

Structure of restriction endonuclease BamHI and its relationship to EcoRI.

Type II restriction endonucleases are characterized by the remarkable specificity with which they cleave specific DNA sequences. Surprisingly, their protein sequences are in most cases unrelated, and no recurring structural motif has yet been identified. We have determined the structure of restriction endonuclease BamHI at 1.95 A resolution. BamHI shows striking resemblance to the structure of endonuclease EcoRI (refs 3, 4), despite the lack of sequence similarity between them. We also observe some curious differences between the two structures, and propose an evolutionary scheme that may explain them. The active site of BamHI is structurally similar to the active sites of EcoRI and EcoRV (ref. 5), but the mechanism by which BamHI activates a water molecule for nucleophilic attack may be different.

Direct selection of binding proficient/catalytic deficient variants of BamHI endonuclease.

Variants of BamHI endonuclease in which the glutamate 113 residue has been changed to lysine or the aspartate 94 to asparagine were shown to behave as repressor molecules in vivo. This was demonstrated by placing a BamHI recognition sequence, GGATCC, positioned as an operator sequence in an antisense promoter for the aadA gene (spectinomycin resistance). Repression of this promoter relieved the inhibition of expression of spectinomycin resistance. This system was then used to select new binding proficient/cleavage deficient BamHI variants. The BamHI endonuclease gene was mutagenized either by exposure to hydroxylamine or by PCR. The mutagenized DNA was reintroduced into E. coli carrying the aadA gene construct, and transformants that conferred spectinomycin resistance were selected. Twenty Spr transformants were sequenced. Thirteen of these were newly isolated variants of the previously identified D94 and E113 residues which are known to be involved in catalysis. The remaining seven variants were all located at residue 111 and the glutamate 111 residue was shown to be involved with catalysis.

Overexpression, purification and crystallization of BamHI endonuclease.

The type II restriction endonuclease BamHI has been expressed in E. coli, producing 100-fold more enzyme than the wild type Bacillus amyloliquefaciens H strain. This high yield has facilitated purification to homogeneity of large amounts of the enzyme, along with its crystallization in a form which diffracts to at least 1.9 A in X-ray analysis.

Poliovirus RNA synthesis in vitro: structural elements and antibody inhibition.

The poliovirus RNA polymerase complex has been analyzed by immunoautoradiography using antibody probes derived from purified replicase (P3) region viral polypeptides. Antibody preparations made against the polio RNA polymerase, P3-4b, detected a previously unreported cellular protein that copurifies with the RNA polymerase. An IgG fraction purified from rabbit antiserum to polypeptide P3-2, a precursor of the RNA polymerase, specifically inhibits poliovirus RNA synthesis in vitro. We have also immunoprecipitated a 60,000-dalton protein (P3-4a) with antiserum to protein P3-4b and have determined the precise genomic map position of this protein by automated Edman degradation. Protein P3-4a originates by cleavage of the RNA polymerase precursor at a glutamine-glycine amino acid pair not previously reported to be a viral cleavage site.

Identification of a poliovirus neutralization epitope through use of neutralizing antiserum raised against a purified viral structural protein.

VP4, one of the poliovirus structural proteins, was purified and used to prepare rabbit anti-VP4 serum. In addition to the anti-VP4 activity, this serum was also found to contain significant anti-VP3 and antivirion activities. The serum also effectively neutralized viral infectivity. The ease with which nonneutralizable variants were obtained indicated that neutralization was due to an antibody population which bound to a single virion epitope. Antigen saturation and immunoprecipitation experiments demonstrated that antibody to this epitope was also responsible for the serum's antivirion and anti-VP3 activities, as well as for a part of the anti-VP4 activity. The identification of a neutralization epitope most probably present on VP3, which cross-reacts with a site on denatured VP4, is the first report of such an epitope on a poliovirus structural protein other than VP1.

Identification of the initiation site of poliovirus polyprotein synthesis.

The complete nucleotide sequence of poliovirus RNA has a long open reading frame capable of encoding the precursor polyprotein NCVP00. The first AUG codon in this reading frame is located 743 nucleotides from the 5' end of the RNA and is preceded by eight AUG codons in all three reading frames. Because all proteins that map at the amino terminus of the polyprotein (P1-1a, VP0, and VP4) are blocked at their amino termini and previous studies of ribosome binding have been inconclusive, direct identification of the initiation site of protein synthesis was difficult. We separated and identified all of the tryptic peptides of capsid protein VP4 and correlated these peptides with the amino acid sequence predicted to follow the AUG codon at nucleotide 743. Our data indicate that VP4 begins with a blocked glycine that is encoded immediately after the AUG codon at nucleotide 743. An S1 nuclease analysis of poliovirus mRNA failed to reveal a splice in the 5' region. We concluded that synthesis of the poliovirus polyprotein is initiated at nucleotide 743, the first AUG codon in the long open reading frame.

A membrane-associated precursor to poliovirus VPg identified by immunoprecipitation with antibodies directed against a synthetic heptapeptide.

A synthetic heptapeptide corresponding to the C-terminal sequence of the poliovirus genome protein (VPg) has been linked to bovine serum albumin and used to raise antibodies in rabbits. These antibodies precipitate not only VPg but also at least two more virus-specific polypeptides. The smaller polypeptide, denoted P3-9 (12,000 daltons), has been mapped by Edman degradation and by fragmentation with cyanogen bromide and determined to be the N-terminal cleavage product of polypeptide P3-1b, a precursor to the RNa polymerase. P3-9 contains the sequence of the basic protein VPg (22 amino acids) at its C terminus. As predicted by the known RNA sequence of poliovirus, P3-9 also contains a hydrophobic region of 22 amino acids preceding VPg, an observation suggesting that P3-9 may be membrane-associated. This was confirmed by fractionation of infected cells in the presence or absence of detergent. We speculate that P3-9 may be the donor of VPg to RNA chains in the membrane-bound RNa replication complex.