Understanding and exploiting nature's chemical arsenal: the past, present and future of calicheamicin research.

The enediyne antitumor antibiotics are appreciated for their novel molecular architecture, their remarkable biological activity and their fascinating mode of action and many have spawned considerable interest as anticancer agents in the pharmaceutical industry. Of equal importance to these astonishing properties, the enediynes also offer a distinct opportunity to study the unparalleled biosyntheses of their unique molecular scaffolds and what promises to be unprecedented modes of self-resistance to highly reactive natural products. Elucidation of these aspects should unveil novel mechanistic enzymology, and may provide access to the rational biosynthetic modification of enediyne structure for new drug leads, the construction of enediyne overproducing strains and eventually lead to an enediyne combinatorial biosynthesis program. This article strives to compile and present the critical research discoveries relevant to the clinically most promising enediyne, calicheamicin, from a historical perspective. Recent progress, particularly in the areas of biosynthesis, self-resistance, bio-engineering analogs and clinical studies are also highlighted.

Role of axial ligands in the reactivity of Mn peroxidase from Phanerochaete chrysosporium.

Site-directed mutagenesis was performed on Mn peroxidase (MnP) from the white-rot fungus Phanerochaete chrysosporium to investigate the role of the axial ligand hydrogen-bonding network on heme reactivity. D242 is hydrogen bonded to the proximal His of MnP; in other peroxidases, this conserved Asp, in turn, is hydrogen bonded to a Trp. In MnP and other fungal peroxidases, the Trp is replaced by a Phe (F190). Both residues are thought to have a direct influence on the electronic environment of the catalytic center. To study only the active mutants at D242 and F190, we used degenerate oligonucleotides allowing us to screen all 19 possible amino acid mutants at these positions. Two mutants at D242 passed our screen, D242E and D242S. Both mutations impaired only the functioning of compound II. The reactions of the ferric enzyme with H(2)O(2) were unaffected by the mutations, as were the reactions of compound I with reducing substrates. The D242S and D242E mutations reduced the first-order rate constant for the reaction of MnP compound II with chelated Mn(2+) from 233 s(-1) (wild type) to 154 s(-1) and 107 s(-1), respectively. Three F190 mutants passed our screen, F190V, F190L, and F190W. Similar to mutants at D242, these mutants largely affected the function of compound II. The F190V mutation increased the first-order rate constant for the reduction of compound II by chelated Mn(2+) to 320 s(-1). The F190L mutation decreased this rate to 137 s(-1). The F190W mutant was not very stable, but at pH 6.0, this mutation decreased the rate of compound II reduction by Mn(2+) from 140 s(-1) in the wild type to 36 s(-1). There was no indication that the F190W mutant was capable of forming a protein-centered Trp cation radical. All the mutations altered the midpoint potential of the Fe(3+)/Fe(2+) couple of the enzyme, as calculated from cyclic voltammagrams of the proteins. The values were shifted from -96 mV in the wild-type enzyme to -123 mV in D242S, -162 mV in D242E, -82 mV in F190L, -173 mV in F190V, and -51 mV in F190W. Collectively, these results demonstrate that D242 and F190 in MnP influence the electronic environment around the heme and that the reactions of compound II are far more sensitive to this influence than the reduction of compound I.

Mutagenesis of the Mn2+-binding site of manganese peroxidase affects oxidation of Mn2+ by both compound I and compound II.

The present study investigates whether compound I and compound II of manganese peroxidase from the white-rot fungus Phanerochaete chrysosporium utilize the same Mn-binding site for catalysis. Manganese peroxidase was expressed from its cDNA in Escherichia coli and refolded from inclusion bodies to yield fully active enzyme. Three mutants of the enzyme were generated by site-directed mutagenesis. Each of the three amino acid residues proposed to be involved in Mn2+ binding, E35, D179, and E39, was mutated. The acidic side chains of E35 and E39 were shortened by one carbon to the acidic group D, and the acidic side chain of D179 was shortened by one carbon to the alkyl group A. These mutants, E35D, D179A, and E39D, were used to determine whether Mn2+ reacts at the same site with both compound I and compound II of manganese peroxidase and to determine whether phenolic substrates for the enzyme react at this site. Our results conclusively demonstrate that E35 and D179 residues are involved not only in Mn2+ binding but also in electron transfer from Mn2+ to the enzyme for both compound I and compound II. In contrast, E39 is not critically important to either process. None of the three residues is involved in reactions with phenolic substrates or with H2O2.

Efficient expression of a Phanerochaete chrysosporium manganese peroxidase gene in Aspergillus oryzae.

A manganese peroxidase gene (mnp1) from Phanerochaete chrysosporium was efficiently expressed in Aspergillus oryzae. Expression was achieved by fusing the mature cDNA of mnp1 with the A. oryzae Taka amylase promoter and secretion signal. The 3' untranslated region of the glucoamylase gene of Aspergillus awamori provided the terminator. The recombinant protein (rMnP) was secreted in an active form, permitting rapid detection and purification. Physical and kinetic properties of rMnP were similar to those of the native protein. The A. oryzae expression system is well suited for both mechanistic and site-directed mutagenesis studies.

Oxidation of 1,2,4,5-tetramethoxybenzene by lignin peroxidase of Phanerochaete chrysosporium.

We have reinvestigated the lignin peroxidase-catalyzed oxidation of 1,2,4,5-tetramethoxybenzene (TMB) by using presteady-state and steady-state kinetic methods. Our presteady-state kinetic results show that the reaction of compound I with TMB obeyed second order kinetics with a rate constant of 1.1 x 10(7) M-1s-1. The reaction of compound II with TMB exhibits a hyperbolic concentration dependence with a Kd of 16 microM and K = 24 s-1. The stoichiometry of TMB oxidation during steady state is two TMB cation radicals formed per H2O2 consumed. These results clearly show that TMB is a good substrate for both compounds I and II of lignin peroxidase.

Expression of fungal Mn peroxidase in E. coli and refolding to yield active enzyme.

The cDNA encoding Mn peroxidase isozyme H4 from Phanerochaete chrysosporium was expressed in Escherichia coli. The portion of the cDNA encoding the enzyme's signal peptide, not found in the processed holoenzyme, was deleted from the cDNA. The polypeptide was produced as inactive inclusion bodies that could be solubilized in 8 M urea and the reducing agent dithiothreitol. Reconstitution of activity was accomplished by diluting the urea concentration to 2M in the presence of hemin, calcium, and oxidized glutathione. All of the additives were required for recovery of activity. The activity of the recombinant enzyme was dependent on both Mn2+ and H2O2.