Structural determinants of adenophostin A activity at inositol trisphosphate receptors.

Adenophostin A is the most potent known agonist of inositol 1,4,5-trisphosphate (InsP(3)) receptors. Ca(2+) release from permeabilized hepatocytes was 9.9 +/- 1.6-fold more sensitive to adenophostin A (EC(50), 14.7 +/- 2.4 nM) than to InsP(3) (145 +/- 10 nM), consistent with the greater affinity of adenophostin A for hepatic InsP(3) receptors (K(d) = 0.48 +/- 0.06 and 3.09 +/- 0.33 nM, respectively). Here, we systematically modify the structures of the glucose, ribose, and adenine moieties of adenophostin A and use Ca(2+) release and binding assays to define their contributions to high-affinity binding. Progressive trimming of the adenine of adenophostin A reduced potency, but it fell below that of InsP(3) only after complete removal of the adenine. Even after substantial modifications of the adenine (to uracil or even unrelated aromatic rings, retaining the beta-orientation), the analogs were more potent than InsP(3). The only analog with an alpha-ribosyl linkage had massively decreased potency. The 2'-phosphate on the ribose ring of adenophostin A was essential and optimally active when present on a five-membered ring in a position stereochemically equivalent to its location in adenophostin A. Xylo-adenophostin, where xylose replaces the glucose ring of adenophostin A, was only slightly less potent than adenophostin A, whereas manno-adenophostin (mannose replacing glucose) had similar potency to InsP(3). These results are consistent with the relatively minor role of the 3-hydroxyl of InsP(3) (the equivalent is absent from xylo-adenophostin) and greater role of the equatorial 6-hydroxyl (the equivalent is axial in manno-adenophostin). This is the first comprehensive analysis of all the key structural elements of adenophostin A, and it provides a working model for the design of related high-affinity ligands of InsP(3) receptors.

Selective recognition of inositol phosphates by subtypes of the inositol trisphosphate receptor.

Synthetic analogues of inositol trisphosphate (IP(3)), all of which included structures equivalent to the 4,5-bisphosphate of (1,4,5)IP(3), were used to probe the recognition properties of rat full-length type 1, 2 and 3 IP(3) receptors expressed in insect Spodoptera frugiperda 9 cells. Using equilibrium competition binding with [(3)H](1,4,5)IP(3) in Ca(2+)-free cytosol-like medium, the relative affinities of the receptor subtypes for (1,4,5)IP(3) were type 3 (K(d)=11+/-2 nM)>type 2 (K(d)=17+/-2 nM)>type 1 (K(d)=24+/-4 nM). (1,4,5)IP(3) binding was reversibly stimulated by increased pH, but the subtypes differed in their sensitivity to pH (type 1>type 2>type 3). For all three subtypes, the equatorial 6-hydroxy group of (1,4,5)IP(3) was essential for high-affinity binding, the equatorial 3-hydroxy group significantly improved affinity, and the axial 2-hydroxy group was insignificant; a 1-phosphate (or in its absence, a 2-phosphate) improved binding affinity. The subtypes differed in the extents to which they tolerated inversion of the 3-hydroxy group of (1,4,5)IP(3) (type 1>type 2>type 3), and this probably accounts for the selectivity of (1,4,6)IP(3) for type 1 receptors. They also differed in their tolerance of inversion, removal or substitution (by phosphate) of the 2-hydroxy group (types 2 and 3>type 1), hence the selectivity of (1,2,4,5)IP(4) for type 2 and 3 receptors. Removal of the 3-hydroxy group or its replacement by fluorine or CH(2)OH was best tolerated by type 3 receptors, and accounts for the selectivity of 3-deoxy(1,4,5)IP(3) for type 3 receptors. Our results provide the first systematic analysis of the recognition properties of IP(3) receptor subtypes and have identified the 2- and 3-positions of (1,4,5)IP(3) as key determinants of subtype selectivity.

Bis-methionine ligation to heme iron in mutants of cytochrome b562. 1. Spectroscopic and electrochemical characterization of the electronic properties.

We have generated mutants of cytochrome b562 in which the histidine ligand to the heme iron (His102) has been replaced by a methionine. The resulting proteins can have bis-methionine coordination to the heme iron, but the stability of this arrangement is dependent on oxidation state and solution pH. We have used optical, MCD, and EPR spectroscopies to study the nature of the heme coordination environment under a variety of conditions. Optical spectra of the reduced state of the single variant, H102M, are consistent with bis-methionine ligation. In its oxidized state, this protein is high-spin under all conditions studied, and the spectroscopic properties are consistent with only one of the methionine ligands being coordinated. We cannot identify what, if anything, provides the other axial ligand. A double variant, R98C/H102M (in which the heme is covalently attached to the protein through a c-type thioether linkage), is also bis-methionine coordinated in the ferrous state, but has significantly different properties in the oxidized state. With a pKa of 7.1 at 20 degrees C, the protein converts from a low-spin, 6-coordinate heme protein at low pH, to a high-spin species, similar to the high-spin species observed for the single variant. Our spectroscopic data prove that the low-spin species is bis-methionine coordinated. The reduction potential of this bis-methionine species has been measured using direct electrochemical techniques and is +440 mV at pH 4.8. The electrochemistry of these proteins is complicated by coupled coordination-state changes. Proof that the ferrous state is bis-methionine coordinated is provided by NMR results presented in the following paper.

Conversion of cytochrome b562 to c-type cytochromes.

Cytochrome b562 from the periplasm of Escherichia coli is the only member of a family of cytochromes sharing the 4-alpha-helical bundle structural motif that does not have a covalently bound heme. We have introduced cysteine residues into the amino acid sequence of cytochrome b562 in positions homologous to those found in the other members of the family, generating the ubiquitous heme-binding peptide (-C-X-Y-C-H-) found in virtually all c-type cytochromes. The resulting single-cysteine-containing mutants, R98C and Y101C, together with the double mutant combining both of these mutations have been expressed into the periplasm of E. coli. The apo- and holoprotein products of each mutation have been isolated, and all the mutants produce multiple species with covalently attached heme. Results from ion exchange chromatograph, optical spectroscopy, SDS gel electrophoresis, and electrospray mass spectrometry identified those species that appear to be cytochrome b562 holoprotein with thioether covalent linkages to the heme as the only difference in chemical composition between them and the wild-type protein. Results from 1H-NMR experiments prove the existence of the expected c-type covalent bonds in each of these proteins and show that the structure of the heme pocket is not significantly perturbed by the covalent modification(s). These proteins all have perturbed optical spectra, compared with those of the wild-type protein, that are consistent with the modifications but are still characteristic of six-coordinate, low-spin cytochromes with Met-His ligation to the heme iron in both oxidation states.