Gossypol inhibits estrogen binding to rat alpha-fetoprotein

We find that gossypol, a male anti-fertility compound, is a reversible competitive inhibitor of estrogen binding to rat alpha-fetoprotein (AFP). The Kd of gossypol for rat AFP is 1.75 microM, which is similar to gossypol's affinity for lactate dehydrogenase isozyme X, the putative site where gossypol exerts its anti-fertility effects. Reacting sodium cyanoborohydride with gossypol reduces its affinity for AFP, showing that intact aldehyde groups on gossypol are important for binding to rat AFP and indicating that gossypol is specifically inter-acting with a nucleophilic site on AFP that influences estrogen binding.     

Molecular dynamics simulations indicate that tyrosineB10 limits motions of distal histidine to regulate CO binding in soybean leghemoglobin

Myoglobin (Mb) uses strong electrostatic interaction in its distal heme pocket to regulate ligand binding. The mechanism of regulation of ligand binding in soybean leghemoglobin a (Lba) has been enigmatic and more so due to the absence of gaseous ligand bound atomic resolution three‐dimensional structure of the plant globin. While the 20‐fold higher oxygen affinity of Lba compared with Mb is required for its dual physiological function, the mechanism by which this high affinity is achieved is only emerging. Extensive mutational analysis combined with kinetic and CO‐FT‐IR spectroscopic investigation led to the hypothesis that Lba depended on weakened electrostatic interaction between distal HisE7 and bound ligand achieved by invoking B10Tyr, which itself hydrogen bonds with HisE7 thus restricting it in a single conformation detrimental to Mb‐like strong electrostatic interaction. Such theory has been re‐assessed here using CO‐Lba in silico model and molecular dynamics simulation. The investigation supports the presence of at least two major conformations of HisE7 in Lba brought about by imidazole ring flip, one of which makes hydrogen bonds effectively with B10Tyr affecting the former's ability to stabilize bound ligand, while the other does not. However, HisE7 in Lba has limited conformational freedom unlike high frequency of imidazole ring flips observed in Mb and in TyrB10Leu mutant of Lba. Thus, it appears that TyrB10 limits the conformational freedom of distal His in Lba, tuning down ligand dissociation rate constant by reducing the strength of hydrogen bonding to bound ligand, which the freedom of distal His of Mb allows. Proteins 2015; 83:1836–1848. © 2015 Wiley Periodicals, Inc.     

Two birds with one stone: genes that encode products targeted to two or more compartments

Eukaryotic cells are divided into multiple membrane-bound compartments, all of which contain proteins. A large subset of these proteins perform functions that are required in more than one compartment. Although in most cases proteins carrying out the same function in different compartments are encoded by different genes, this is not always true. Numerous examples have now been found where a single gene encodes proteins (or RNAs) found in two (or more) cell organelles or membrane systems. Some particularly clear examples come from protein synthesis itself: plant cells contain three protein-synthesizing compartments, the cytosol, the mitochondrial matrix and the plastid stroma. All three compartments thus require tRNAs and aminoacyl-tRNA synthetases. Some mitochondrial tRNAs and their aminoacyl-tRNA synthetases are identical to their cytosolic counterparts and they are encoded by the same genes. Similarly, some mitochondrial and plastid aminoacyl-tRNA synthetases are encoded by the same nuclear genes. The various ways in which differentially targeted products can be generated from single genes is discussed.     

Direct evidence that all three histidine residues coordinate to Cu(II) in amyloid-beta1-16

We provide direct evidence that all three histidine residues in amyloid-beta 1-16 (Abeta 1-16) coordinate to Cu(II). In our approach, we generate Abeta 1-16 analogues, in each of which a selected histidine residue is isotopically enriched with (15)N. Pulsed electron spin resonance (ESR) experiments such as electron spin echo envelope modulation (ESEEM) and hyperfine sublevel correlation (HYSCORE) spectroscopy clearly show that all three histidine imidazole rings at positions 6, 13 and 14 in Abeta 1-16 bind to Cu(II). The method employed here does not require either chemical side chain modification or amino acid residue replacement, each of which is traditionally used to determine whether an amino acid residue in a protein binds to a metal ion. We find that the histidine coordination in the Abeta 1-16 peptide is independent of the Cu(II)-to-peptide ratio, which is in contrast to the Abeta 1-40 peptide. The ESR results also suggest tight binding between the histidine residues and the Cu(II) ion, which is likely the reason for the high binding affinity of the Abeta peptide for Cu(II).     

Diethyl pyrocarbonate, a histidine selective reagent, inhibits estrogen binding to receptor protein in rat uterus cytosol

We find that at pH 6.1 diethyl pyrocarbonate inhibits estrogen binding to its receptor protein in rat uterus. Hydroxylamine partially reverses this inhibition and estrogen partially protects its receptor protein from this inhibition. We suggest that the estrogen receptor protein in rat uterus contains a nucleophilic site that either overlaps or is near the estrogen binding site. Based on the pH of inhibition reaction, the receptor concentration in the experiment, and the partial reversal of the inhibition by hydroxylamine, we suggest that this site contains a histidine residue or possibly an unusually reactive tyrosine residue that is important for estrogen binding.     

Analysis of 3D models of octopus estrogen receptor with estradiol: evidence for steric clashes that prevent estrogen binding

Relatives of the vertebrate estrogen receptor (ER) are found in Aplysia californica, Octopus vulgaris, Thais clavigera, and Marisa cornuarietis. Unlike vertebrate ERs, invertebrate ERs are constitutively active and do not bind estradiol. To investigate the molecular basis of the absence of estrogen binding, we constructed a 3D model of the putative steroid-binding domain on octopus ER. Our 3D model indicates that binding of estradiol to octopus ER is prevented by steric clashes between estradiol and amino acids in the steroid-binding pocket. In this respect, octopus ER resembles vertebrate estrogen-related receptors (ERR), which have a ligand-binding pocket that cannot accommodate estradiol. Like ERR, octopus ER also may have the activation function 2 domain (AF2) in a configuration that can bind to coactivators in the absence of estrogens, which would explain constitutive activity of octopus ER.     

Resonance Raman evidence that distal histidine protonation removes the steric hindrance to upright binding of carbon monoxide by myoglobin

The resonance Raman band assigned to Fe--CO stretching in the sperm whale myoglobin CO adduct shifts from 507 cm-1 at neutral pH to 488 cm-1 at low pH, in concert with a shift of the C-O stretching infrared band from 1947 to 1967 cm-1 (Fuchsman & Appleby, 1979), while the 575-cm-1 Fe-C-O bending RR band loses intensity. The pKa that characterizes these changes is approximately 4.4. The vibrational frequencies at low pH are well modeled by the protein-free CO, imidazole adduct of protoheme in a nonpolar solvent while those at high pH are modeled by the adduct of a heme with a covalent strap (Yu et al., 1983) which inhibits upright CO binding. It is inferred that the Fe-C-O unit changes from a tilted to an upright geometry when the distal histidine is protonated, because its side chain swings out of the heme pocket due to electrostatic repulsion with a nearby arginine residue. A different protonation step (pKa = 5.7), which has been shown to modulate the CO rebinding kinetics (Doster et al., 1982) as well as the optical spectrum (Fuchsman & Appleby, 1979), is suggested to involve a global structure change associated with protonation of histidine residues distant from the heme.     

Contribution of the active site histidine residues of ribonuclease A to nucleic acid binding

His12 and His119 are critical for catalysis of RNA cleavage by ribonuclease A (RNase A). Substitution of either residue with an alanine decreases the value of k(cat)/K(M) by more than 10(4)-fold. His12 and His119 are proximal to the scissile phosphoryl group of an RNA substrate in enzyme-substrate complexes. Here, the role of these active site histidines in RNA binding was investigated by monitoring the effect of mutagenesis and pH on the stability of enzyme-nucleic acid complexes. X-ray diffraction analysis of the H12A and H119A variants at a resolution of 1.7 and 1.8 A, respectively, shows that the amino acid substitutions do not perturb the overall structure of the variants. Isothermal titration calorimetric studies on the complexation of wild-type RNase A and the variants with 3'-UMP at pH 6.0 show that His12 and His119 contribute 1.4 and 1.1 kcal/mol to complex stability, respectively. Determination of the stability of the complex of wild-type RNase A and 6-carboxyfluorescein approximately d(AUAA) at varying pHs by fluorescence anisotropy shows that the stability increases by 2.4 kcal/mol as the pH decreases from 8.0 to 4.0. At pH 4.0, replacing His12 with an alanine residue decreases the stability of the complex with 6-carboxyfluorescein approximately d(AUAA) by 2.3 kcal/mol. Together, these structural and thermodynamic data provide the first thorough analysis of the contribution of histidine residues to nucleic acid binding.     

Further characterization of estrogen binding to rat testis cytosol

Binding of estradiol (E2), estriol (E3), RU16117, and moxestrol to testis cytosol from adult male rats was investigated. High-affinity binding sites were identified in the 8-9S region of sucrose density gradients; a second, high-capacity binding component in the 4S region was probably due to contamination with serum. Thermodynamic properties of the testicular estrogen binding site were quite similar to those of the uterine receptor. E2 had the highest affinity for testicular cytosol binding sites (Ka: E2 much greater than moxestrol greater than E3 greater than RU16117). Comparison of association rate (E2 greater than E3 greater than moxestrol = RU16117) and dissociation rate constants (E3 = RU16117 greater than E2 much greater than moxestrol) as well as studies in vivo revealed moxestrol as a long-acting and RU16117 as a short-acting compound. This difference may be useful for evaluation of the mediation of estrogen effects in the rat testis.     

Sensitizer-mediated photooxidation of histidine residues: evidence for the formation of reactive side-chain peroxides

Exposure of proteins to visible light in the presence of a sensitizer results in the oxidation of Met, Trp, Tyr, Cys, and His side chains. These reactions are only partially understood, particularly with His. In this study, the oxidation of free His, His derivatives, and His-containing peptides has been examined using visible light and a range of sensitizers. It is shown that photooxidation gives rise to unstable peroxides, in a light-, illumination time-, and sensitizer-dependent manner. The yield of these materials is increased when reactions are carried out in solutions prepared with D2O, which prolongs the lifetime of 1O2, and decreased in the presence of the potent 1O2 scavenger azide, consistent with the involvement of this excited state. These peroxides have half-lives of hours, though the rate of decomposition is enhanced by elevated temperatures, reductants, and metal ions. Reducing metal ions catalyze the formation of radicals, which have been detected by EPR spin trapping. Structural analysis of His photo-products using NMR spectroscopy has provided evidence for the formation of oxygenated and cyclized compounds (e.g., 6a-hydroxy-2-oxo-octahydro-pyrollo[2,3-d]imidazole-5-carboxylic acid) and cross-linked materials. The latter materials may be partly responsible for the high yield of aggregated materials detected on photooxidation of His-containing proteins.     

The presence of histidine residues at or near the C1q binding site of rabbit immunoglobulin G

Treatment of covalently crosslinked rabbit IgG oligomers with diethylpyrocarbonate resulted in the loss of their C1q binding activity. The inactivation was a first-order process with respect to time in the range 0-8 min, and modifier concentration from 0 to 2.39 mM. Hydroxylamine treatment of diethylpyrocarbonate-treated IgG oligomers led to 80% recovery of their C1q binding activity. Diethylpyrocarbonate treatment of IgG oligomers had little effect on their absorbance at 278 nm, but led to an increase in their absorbance at 242 nm. The apparent pKa of the modified residues was 6.91 +/- 0.12. These data are consistent with diethylpyrocarbonate modification of histidine residues leading to loss of C1q binding activity in rabbit IgG oligomers. Modification of four histidine residues per IgG molecule was associated with the loss of C1q binding activity. Thus, there may be two histidine residues at or near the C1q binding sites in the CH2 domains of rabbit IgG.     

Site-directed mutagenesis of Klebsiella aerogenes urease: identification of histidine residues that appear to function in nickel ligation, substrate binding, and catalysis.

Comparison of six urease sequences revealed the presence of 10 conserved histidine residues (H96 in the gamma subunit, H39 and H41 in beta, and H134, H136, H219, H246, H312, H320, and H321 in the alpha subunit of the Klebsiella aerogenes enzyme). Each of these residues in K. aerogenes urease was substituted with alanine by site-directed mutagenesis, and the mutant proteins were purified and characterized in order to identify essential histidine residues and assign their roles. The gamma H96A, beta H39A, beta H41A, alpha H312A, and alpha H321A mutant proteins possess activities and nickel contents similar to wild-type enzyme, suggesting that these residues are not essential for substrate binding, catalysis, or metal binding. In contrast, the alpha H134A, alpha H136A, and alpha H246A proteins exhibit no detectable activity and possess 53%, 6%, and 21% of the nickel content of wild-type enzyme. These results are consistent with alpha H134, alpha H136, and alpha H246 functioning as nickel ligands. The alpha H219A protein is active and has nickel (approximately 1.9% and approximately 80%, respectively, when compared to wild-type protein) but exhibits a very high Km value (1,100 +/- 40 mM compared to 2.3 +/- 0.2 mM for the wild-type enzyme). These results are compatible with alpha H219 having some role in facilitating substrate binding. Finally, the alpha H320A protein (Km = 8.3 +/- 0.2 mM) only displays approximately 0.003% of the wild-type enzyme activity, despite having a normal nickel content.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the two histidine residues responsible for the inhibition by malonyl-CoA in peroxisomal carnitine octanoyltransferase from rat liver

Carnitine octanoyltransferase (COT), an enzyme that facilitates the transport of medium chain fatty acids through peroxisomal membranes, is inhibited by malonyl-CoA. cDNAs encoding full-length wild-type COT and one double mutant variant from rat peroxisomal COT were expressed in Saccharomyces cerevisiae. Both expressed forms were expressed similarly in quantitative terms and exhibited full enzyme activity. The wild-type-expressed COT was inhibited by malonyl-CoA like the liver enzyme. The activity of the enzyme encoded by the double mutant H131A/H340A was completely insensitive to malonyl-CoA in the range assayed (2-200 microM). These results indicate that the two histidine residues, H131 and H340, are the sites responsible for inhibition by malonyl-CoA. Another mutant variant, H327A, abolishes the enzyme activity, from which it is concluded that it plays an important role in catalysis.     

Peptides that regulate food intake: effect of peptide histidine isoleucine on consummatory behavior in rats

Peptide histidine isoleucine (PHI) and VIP are derived from the same precursor. While central VIP decreases food intake, potential effects of PHI on feeding have not been studied. In the current study, we found that PHI administered intracerebroventricularly (ICV) or into the hypothalamic paraventricular nucleus (PVN) or central nucleus of the amygdala (CeA) decreased food consumption in overnight-deprived rats. The magnitude of an anorexigenic response to PHI differed depending on the injection route: ICV-infused peptide evoked the most potent effect. We determined that that only PVN- and CeA-injected PHI did not have aversive consequences. In addition, we infused anorexigenic doses of PHI via the same routes and assessed Fos immunoreactivity of PVN oxytocin (OT) and vasopressin (VP) neurons using double immunohistochemistry. OT and VP are thought to promote feeding termination. PHI increased the percentage of Fos-positive OT neurons regardless of the injection route. PVN- and ICV-infused PHI induced activation of VP cells. We conclude that central PHI has an inhibitory influence on food intake in rats. The PVN, with OT and VP neurons, and CeA may be involved in the mediation of anorexigenic effects of PHI.     

Mechanism of proton transfer inhibition by Cd(2+) binding to bacterial reaction centers: determination of the pK(A) of functionally important histidine residues

The bacterial photosynthetic reaction center (RC) uses light energy to catalyze the reduction of a bound quinone molecule Q(B) to quinol Q(B)H(2). In RCs from Rhodobacter sphaeroides the protons involved in this process come from the cytoplasm and travel through pathways that involve His-H126 and His-H128 located near the proton entry point. In this study, we measured the pH dependence from 4.5 to 8.5 of the binding of the proton transfer inhibitor Cd(2+), which ligates to these surface His in the RC and inhibits proton-coupled electron transfer. At pH <6, the negative slope of the logarithm of the dissociation constant, K(D), versus pH approaches 2, indicating that, upon binding of Cd(2+), two protons are displaced; i.e., the binding is electrostatically compensated. At pH >7, K(D) becomes essentially independent of pH. A theoretical fit to the data over the entire pH range required two protons with pK(A) values of 6.8 and 6.3 (+/-0.5). To assess the contribution of His-H126 and His-H128 to the observed pH dependence, K(D) was measured in mutant RCs that lack the imidazole group of His-H126 or His-H128 (His --> Ala). In both mutant RCs, K(D) was approximately pH independent, showing that Cd(2+) does not displace protons upon binding in the mutant RCs, in contrast to the native RC in which His-H126 and His-H128 are the predominant contributors to the observed pH dependence of K(D). Thus, Cd(2+) inhibits RC function by binding to functionally important histidines.     

Structural analysis of peptides capable of binding to more than one Ia antigen

The Ia binding regions were analyzed for three unrelated peptide Ag (sperm whale myoglobin 106-118, influenza hemagglutinin 130-142, and lambda repressor protein 12-26) for which binding to more than one Ia molecule has previously been demonstrated. By determining the binding profile of three separate series of truncated synthetic peptides, it was found that in all three cases the different Ia reactivities mapped to largely overlapping regions of the peptides; although, for two of the peptides, the regions involved in binding the different Ia specificities were distinct. Moreover, subtle differences were found to dramatically influence some, but not other, Ia reactivities. Using a large panel of synthetic peptides it was found that a significant correlation exists between the capacity of peptides to interact with different alleles of the same molecule (i.e., IAd and IAk), but no correlation was found with the capacity of peptides to interact with different isotypes within the same haplotype (i.e., IAd and IEd). These data suggest that different alleles of the same MHC molecule may actually recognize closely related structures, whereas different isotypes may recognize unrelated, albeit non-mutually exclusive, structures on an Ag molecule.     

Dissecting the ribosomal inhibition mechanisms of edeine and pactamycin: the universally conserved residues G693 and C795 regulate P-site RNA binding

The crystal structures of the universal translation-initiation inhibitors edeine and pactamycin bound to ribosomal 30S subunit have revealed that edeine induces base pairing of G693:C795, residues that constitute the pactamycin binding site. Here, we show that base pair formation by addition of edeine inhibits tRNA binding to the P site by preventing codon-anticodon interaction and that addition of pactamycin, which rebreaks the base pair, can relieve this inhibition. In addition, edeine induces translational misreading in the A site, at levels comparable to those induced by the classic misreading antibiotic streptomycin. Binding of pactamycin between residues G693 and C795 strongly inhibits translocation with a surprising tRNA specificity but has no effect on translation initiation, suggesting that reclassification of this antibiotic is necessary. Collectively, these results suggest that the universally conserved G693:C795 residues regulate tRNA binding at the P site of the ribosome and influence translocation efficiency.