Crystallographic analysis of triclosan bound to enoyl reductase.

Molecular genetic studies with strains of Escherichia coli resistant to triclosan, an ingredient of many anti-bacterial household goods, have suggested that this compound works by acting as an inhibitor of enoyl reductase (ENR) and thereby blocking lipid biosynthesis. We present structural analyses correlated with inhibition data, on the complexes of E. coli and Brassica napus ENR with triclosan and NAD(+) which reveal how triclosan acts as a site-directed, picomolar inhibitor of the enzyme by mimicking its natural substrate. Elements of both the protein and the nucleotide cofactor play important roles in triclosan recognition, providing an explanation for the factors controlling its tight binding to the enzyme and for the emergence of triclosan resistance.

N-isobutyryl-His-Trp-Ala-Val-D-Ala-His-Leu-NHMe (ICI 216140) a potent in vivo antaconist analogue of bombesin/gastrin releasing peptide (BN/GRP) derived from the C-terminal sequence lacking the final methionine residue.

The GRP receptor mediated growth response in Swiss 3T3 cells has been used to identify BN/GRP antagonists. Analysis of bombesin antagonism by substance P analogues and by truncated GRP analogues revealed that deletion of the C-terminal methionine residue was important for antagonism. Des-Met analogues showing potent antagonist activity in the in vitro 3T3 system (IC50 approximately 2nM) were synthesized. Further structural modification of these peptides led to the identification of (CH3)2CHCO-His-Trp-Ala-Val-D-Ala-His-Leu-NHCH3 (ICI 216140) which reduced bombesin-stimulated rat pancreatic amylase secretion to basal levels when administered subcutaneously at 2.0 mg per kg.

Construction of protein analogues by site-specific condensation of unprotected fragments.

The extreme sensitivity to periodate of 1-amino, 2-hydroxy compounds permits the selective conversion of N-terminal serine and threonine to an aldehydic group. We have used this reaction to construct analogues of human granulocyte colony stimulating factor (G-CSF) by allowing such oxidized peptides to react with others that have had a hydrazide derivative attached to the C-terminus by reversed proteolysis. Two recombinant analogues of G-CSF were used as starting materials. Both had only a single lysine residue (at position 62 and 75, respectively) followed immediately by a serine. Digestion of each analogue by the lysine-specific protease from Achromobacter lyticus gave two fragments, one of which could be N-terminally oxidized and the other converted to the C-terminal hydrazide derivative by reversed proteolysis using the same enzyme. After preliminary studies with model peptides, we first reacted the corresponding peptide pairs together and then, in order to eliminate the 64-74 disulfide loop, fragment 1-62 from the first analogue with fragment 76-174 from the second. Reactions are efficient (up to 80% product based on the oxidized fragment) and take place under very mild conditions. The hydrazone bond can easily be stabilized by reduction with NaBH3CN. This method represents a new, reasonably general route for the construction of large protein chimeras of precisely controlled structure.

Chemo-enzymic backbone engineering of proteins. Site-specific incorporation of synthetic peptides that mimic the 64-74 disulfide loop of granulocyte colony-stimulating factor.

We present the concept of chemo-enzymic backbone engineering of proteins. Recombinant DNA techniques are used to produce appropriate proteins that are enzymically fragmented to give the starting materials. These fragments are modified specifically at their chain termini either enzymically (coupling of a hydrazide to the C terminus) or chemically (periodate oxidation of N-terminal serine to a glyoxylyl function). The modified fragments, which need no side protection whatever, are mixed together and religate themselves spontaneously under mild conditions. The hydrazone bond thus formed can be reduced if desired, which stabilizes the linkage and enhances the flexibility of the local conformation. In this way biologically or chemically derived structures can be incorporated into the protein, and the choice of the chemical ones is free of all of the constraints of the genetic code. We believe that this combined approach gives access to constructions that could not be derived by either recombinant or chemical methods alone. We illustrate the particularity of this concept by the engineered modifications of the 64-74 disulfide loop region of human granulocyte colony-stimulating factor. Analogs constructed include one which, in spite of having a nonpeptide link in its backbone, has full biological activity.

Site-specific religation of G-CSF fragments through a thioether bond.

A new approach is described for linking, through a thioether bond, the C-terminus of one unprotected polypeptide with the N-terminus of another. Homocysteine thiolactone is attached to the C-terminus of one polypeptide by reverse proteolysis and provides through hydroxylamine treatment a free sulfhydryl group. The alpha-amino group of a second polypeptide is selectively iodoacetylated by reaction with iodoacetic anhydride at pH 6.0 or the N-hydroxysuccinimide ester derivative at pH 7.0. Coupling of the two modified fragments occurs in a spontaneous alkylation reaction under mild conditions. After preliminary experiments with small peptides, this approach was extended to large protein fragments derived from recombinant analogs of G-CSF by enzymatic digestion. This approach provides a means of making head-to-tail protein chimeras or introducing noncoded structural elements into a protein.

Characterization of human and rat brain myristoyl-CoA:protein N-myristoyltransferase: evidence for an alternative splice variant of the enzyme.

Using 5'-rapid amplification of cDNA ends, we have identified an extended 5'-end of mRNA coding for human myristoyl-CoA:protein N-myristoyltransferase (NMT). PCR using primers based on this new 5'-sequence and reverse primers within the currently accepted coding sequence of the enzyme resulted in the identification of a novel splice variant of NMT. In vitro translation of these cDNAs resulted in the production of proteins with apparent molecular masses of 63 kDa and 48 kDa. Immunoprecipitation of NMT from human cell lines and immunoblotting of a range of rat tissues has identified proteins with molecular masses corresponding to those derived from these cDNAs, and provided evidence that their relative abundance differs among tissues. Our results provide evidence that this enzyme exists in different forms resulting from alternative splicing of the mRNA.

Functionally important conserved amino-acids in interferon-alpha 2 identified with analogues produced from synthetic genes.

A gene was chemically synthesised and expressed in Escherichia coli to produce [Ala30,32,33]IFN-alpha 2, an analogue of human alpha 2-interferon (IFN-alpha 2) which is devoid of activity on human cells. Eight additional analogues provided single changes in IFN-alpha 2 at each of these three conserved positions. No one residue is essential for activity, but both antiviral and anti-proliferative activity are particularly sensitive to changes in the side-chain of Arg33.

Crystal structure of the anti-fungal target N-myristoyl transferase.

N-myristoyl transferase (NMT) catalyzes the transfer of the fatty acid myristate from myristoyl-CoA to the N-terminal glycine of substrate proteins, and is found only in eukaryotic cells. The enzyme in this study is the 451 amino acid protein produced by Candida albicans, a yeast responsible for the majority of systemic infections in immuno-compromised humans. NMT activity is essential for vegetative growth, and the structure was determined in order to assist in the discovery of a selective inhibitor of NMT which could be developed as an anti-fungal drug. NMT has no sequence homology with other protein sequences and has a novel alpha/beta fold which shows internal two-fold symmetry, which may be a result of gene duplication. On one face of the protein there is a long, curved, relatively uncharged groove, at the center of which is a deep pocket. The pocket floor is negatively charged due to the vicinity of the C-terminal carboxylate and a nearby conserved glutamic acid residue, which separates the pocket from a cavity. These observations, considered alongside the positions of residues whose mutation affects substrate binding and activity, suggest that the groove and pocket are the sites of substrate binding and the floor of the pocket is the catalytic center.

Chemical synthesis of a human interferon-alpha 2 gene and its expression in Escherichia coli.

A 511-base pair DNA fragment encoding human interferon-alpha 2 has been chemically synthesised and expressed from a lac UV5 and a synthetic trp promoter in Escherichia coli. The synthesis involved preparation of 68 oligodeoxyribonucleotides and their enzymic ligation. The product expressed from the trp promoter system had high antiviral activity and displayed biological effects similar to those of Namalwa interferon on natural killer cell activity and in a Daudi cell growth inhibition assay. E.coli minicells containing plasmid DNA with the synthetic IFN-alpha 2 gene under trp promoter control produce a protein with the same electrophoretic mobility as a sample of authentic IFN-alpha 2. The protein from E.coli cross-reacts with the monoclonal antibody NK-2 and was readily purified, close to homogeneity, by immunoadsorption chromatography on NK-2 sepharose.

Kinetic and structural characteristics of the inhibition of enoyl (acyl carrier protein) reductase by triclosan.

Triclosan is used widely as an antibacterial agent in dermatological products, mouthwashes, and toothpastes. Recent studies imply that antibacterial activity results from binding to enoyl (acyl carrier protein) reductase (EACPR, EC 1.3.1.9). We first recognized the ability of triclosan to inhibit EACPR from Escherichia coli in a high throughput screen where the enzyme and test compound were preincubated with NAD(+), which is a product of the reaction. The concentration of triclosan required for 50% inhibition approximates to 50% of the enzyme concentration, indicating that the free compound is depleted by binding to EACPR. With no preincubation or added NAD(+), the degree of inhibition by 150 nM triclosan increases gradually over several minutes. The onset of inhibition is more rapid when NAD(+) is added. Gel filtration and mass spectrometry show that inhibition by triclosan is reversible. Steady-state assays were designed to avoid depletion of free inhibitor and changes in the degree of inhibition. The results suggest that triclosan binds to E-NAD(+) complex, with a dissociation constant around 20-40 pM. Triclosan follows competitive kinetics with respect to NADH, giving an inhibition constant of 38 pM at zero NADH and saturating NAD(+). Uncompetitive kinetics are observed when NAD(+) is varied, giving an inhibition constant of 22 pM at saturating NAD(+). By following regain of catalytic activity after dilution of EACPR that had been preincubated with triclosan and NAD(+), the rate constant for dissociation of the inhibitor (k(off)) is measured as 1.9 x 10(-4) s(-1). The association rate constant (k(on)) is estimated as 2.6 x 10(7) s(-1) M(-1) by monitoring the onset of inhibition during assays started by addition of EACPR. As expected, the ratio k(off)/k(on) = 7.1 pM is similar to the inhibition constants from the steady-state studies. The crystal structure of E. coli EACPR in a complex with coenzyme and triclosan has been determined at 1.9 A resolution, showing that this compound binds in a similar site to the diazaborine inhibitors. The high affinity of triclosan appears to be due to structural similarity to a tightly bound intermediate in catalysis.