Premature formation of nucleolar channel systems indicates advanced endometrial maturation following controlled ovarian hyperstimulation.

STUDY QUESTION: Is there a shift in the timing of nucleolar channel system (NCS) formation following controlled ovarian hyperstimulation (COH)? SUMMARY ANSWER: NCSs appear prematurely following COH compared with natural cycles. WHAT IS KNOWN ALREADY: During natural cycles, NCSs of endometrial epithelial cell (EEC) nuclei are exclusively present during the window of implantation and are uniformly distributed throughout the upper endometrial cavity. STUDY DESIGN, SIZE, DURATION: Prospective two-cohort study. Cohorts I and II each consisted of seven volunteers for the duration of three menstrual study cycles that were separated by at least one wash-out or rest cycle, between December 2008 and May 2012. PARTICIPANTS/MATERIALS, SETTING, METHODS: Participants were recruited from a pool of healthy oocyte donors. Consecutive endometrial biopsies were obtained during the same luteal phase on cycle days (CD) 16, 20 and 26 for Cohort I, and on CD14, 22 and 24 for Cohort II, following random assignment to a natural cycle group, a COH cycle group (using a GnRH antagonist), or a COH cycle group receiving luteal phase hormonal supplementation (COH + S). The day of oocyte retrieval was designated CD14 in COH cycles and the day of the LH surge was designated CD13 in natural cycles. Prevalence of NCSs in the nuclei of EECs was quantified using indirect immunofluorescence with an antibody directed against a subset of related nuclear pore complex proteins that are major constituents of NCSs. Progesterone and estradiol levels were measured on the day of each endometrial biopsy. MAIN RESULTS AND THE ROLE OF CHANCE: The natural cycle group exhibited peak NCS prevalence on CD20 [53.3%; interquartile range (IQR) 28.5-55.8], which rapidly declined on CD22 (11.8%; IQR 6.3-17.6), CD24 (2.5%; IQR 0.0-9.2) and CD26 (0.3%; IQR 0.0-3.5), and no NCSs on CD14 and 16 defining a short NCS window around CD20. In contrast, in COH and COH + S cycles, NCS prevalence was high already on CD16 (40.4%; IQR 22.6-53.4 and 35.6%; IQR 26.4-44.5, respectively; P = 0.001 compared with CD16 of the natural cycle group, Mann-Whitney), whereas no significant difference in NCS prevalence was detected on any of the other five CDs between the three groups (P > 0.05). LIMITATIONS, REASONS FOR CAUTION: The cohort size was small (n = 7) but was offset by the all-or-none presence of NCSs on CD16 in natural versus COH and COH + S cycles and the fact that each subject served as her own control. WIDER IMPLICATIONS OF THE FINDINGS: Premature appearance of NCSs and hence maturation of the endometrium following COH is consistent with previous studies based on histological dating but contradicts studies based on mRNA expression profiling, which reported a lag in endometrial maturation. However, this is the first study of this kind that is based on consecutive endometrial biopsies within the same cycle and that reports such clear-cut differences: no versus robust NCS presence on CD16. Our observation of advanced endometrial maturation following COH may contribute to the reduced implantation rates seen in fresh compared with frozen and donor IVF-embryo transfer cycles. Therefore, the NCS window could serve as a sensitive guide for timing of embryo transfer in frozen and donor cycles. STUDY FUNDING/COMPETING INTEREST(S): The study was supported by the March of Dimes Birth Defects foundation (1-FY09-363 to U.T.M.); Ferring Pharmaceuticals, Parsippany, NJ; East Coast Fertility, Plainview, NY and the CMBG Training Program (T32 GM007491 to M.J.S.). We report no competing interests.

Intranuclear endoplasmic reticulum induced by Nopp140 mimics the nucleolar channel system of human endometrium.

Exogenous expression of the characteristic repeat domain of the nucleolar chaperone Nopp140 induces the formation of intranuclear structures, termed R-rings. Here, the R-rings are identified as extensive stacks of membrane cisternae in the otherwise membrane-free nucleus. They consist of bona fide endoplasmic reticulum (ER) containing integral membrane proteins of the smooth and rough ER. Although lacking nuclear pore complexes and lamina, the R-rings derive specifically from the inner nuclear membrane. These findings are consistent with the idea that all transmembrane proteins synthesized in the ER and the outer nuclear membrane can freely diffuse through the pore membrane domain into the inner membrane. Uniquely, the soluble transfected Nopp140 is directly involved in the generation of these membrane stacks as it localizes to the electron dense matrix in which they are embedded. The only well-documented example of intranuclear membrane proliferation is the nucleolar channel system of the postovulation human endometrium. The transient emergence of the nucleolar channel system correlates precisely with the readiness of the endometrium for the implantation of the fertilized egg. The nucleolar channel system exhibits an ultrastructure that is indistinguishable from R-rings, and nuclei of human endometrium harbor Nopp140 and ER marker containing structures. Therefore, the nucleolar channel system appears to be identical to the R-rings, suggesting a role for Nopp140 in human reproduction.

Characterization of the nucleolar gene product, treacle, in Treacher Collins syndrome.

Treacher Collins syndrome (TCS) is an autosomal dominant disorder of craniofacial development caused by mutations in the gene TCOF1. Its gene product, treacle, consists mainly of a central repeat domain, which shows it to be structurally related to the nucleolar phosphoprotein Nopp140. Treacle remains mostly uncharacterized to date. Herein we show that it, like Nopp140, is a highly phosphorylated nucleolar protein. However, treacle fails to colocalize with Nopp140 to Cajal (coiled) bodies. As in the case of Nopp140, casein kinase 2 appears to be responsible for the unusually high degree of phosphorylation as evidenced by its coimmunoprecipitation with treacle. Based on these and other observations, treacle and Nopp140 exhibit distinct but overlapping functions. The majority of TCOF1 mutations in TCS lead to premature termination codons that could affect the cellular levels of the full-length treacle. We demonstrate however, that the cellular amount of treacle varies less than twofold among a collection of primary fibroblasts and lymphoblasts and regardless of whether the cells were derived from TCS patients or healthy individuals. Therefore, cells of TCS patients possess a mechanism to maintain wild-type levels of full-length treacle from a single allele.

Conserved composition of mammalian box H/ACA and box C/D small nucleolar ribonucleoprotein particles and their interaction with the common factor Nopp140.

Small nucleolar ribonucleoprotein particles (snoRNPs) mainly catalyze the modification of rRNA. The two major classes of snoRNPs, box H/ACA and box C/D, function in the pseudouridylation and 2'-O-methylation, respectively, of specific nucleotides. The emerging view based on studies in yeast is that each class of snoRNPs is composed of a unique set of proteins. Here we present a characterization of mammalian snoRNPs. We show that the previously characterized NAP57 is specific for box H/ACA snoRNPs, whereas the newly identified NAP65, the rat homologue of yeast Nop5/58p, is a component of the box C/D class. Using coimmunoprecipitation experiments, we show that the nucleolar and coiled-body protein Nopp140 interacts with both classes of snoRNPs. This interaction is corroborated in vivo by the exclusive depletion of snoRNP proteins from nucleoli in cells transfected with a dominant negative Nopp140 construct. Interestingly, RNA polymerase I transcription is arrested in nucleoli depleted of snoRNPs, raising the possibility of a feedback mechanism between rRNA modification and transcription. Moreover, the Nopp140-snoRNP interaction appears to be conserved in yeast, because depletion of Srp40p, the yeast Nopp140 homologue, in a conditional lethal strain induces the loss of box H/ACA small nucleolar RNAs. We propose that Nopp140 functions as a chaperone of snoRNPs in yeast and vertebrate cells.

Nopp140 functions as a molecular link between the nucleolus and the coiled bodies.

Coiled bodies are small nuclear organelles that are highly enriched in small nuclear RNAs, and that have long been thought to be associated with the nucleolus. Here we use mutational analysis, transient transfections, and the yeast two-hybrid system to show that the nucleolar phosphoprotein Nopp140 functions as a molecular link between the two prominent nuclear organelles. Exogenous Nopp140 accumulated in the nucleolus rapidly, but only after a lag phase in coiled bodies, suggesting a pathway between the two organelles. The expression of partial Nopp140 constructs exerted dominant negative effects on the endogenous Nopp140 by chasing it and other antigens that were common to both organelles out of the nucleolus. The alternating positively and negatively charged repeat domain of Nopp140 was required for targeting to both organelles. In addition, partial Nopp140 constructs caused formation of novel structures in the nucleoplasm and, in the case of the conserved carboxy terminus, led to the dispersal of coiled bodies. As a final link, we identified the coiled body-specific protein p80 coilin in a yeast two-hybrid screen with Nopp140. The interaction of the two proteins was confirmed by coimmunoprecipitation. Taken together, Nopp140 appeared to shuttle between the nucleolus and the coiled bodies, and to chaperone the transport of other molecules.

A class of nonribosomal nucleolar components is located in chromosome periphery and in nucleolus-derived foci during anaphase and telophase.

. The subcellular location of several nonribosomal nucleolar proteins was examined at various stages of mitosis in synchronized mammalian cell lines including HeLa, 3T3, COS-7 and HIV-1 Rev-expressing CMT3 cells. Nucleolar proteins B23, fibrillarin, nucleolin and p52 as well as U3 snoRNA were located partially in the peripheral regions of chromosomes from prometaphase to early telophase. However, these proteins were also found in large cytoplasmic particles, 1-2 microm in diameter, termed nucleolus-derived foci (NDF). The NDF reached maximum numbers (as many as 100 per cell) during mid- to late anaphase, after which their number declined to a few or none during late telophase. The decline in the number of NDF approximately coincided with the appearance of prenucleolar bodies and reforming nucleoli. The HIV-1 Rev protein and a mutant Rev protein defective in its nuclear export signal were also found in the NDF. The mutant Rev protein precisely followed the pattern of localization of the above nucleolar proteins, whereas the wild-type Rev did not enter nuclei until G1 phase. The nucleolar shuttling phosphoprotein Nopp140 did not follow the above pattern of localization during mitosis: it dispersed in the cytoplasm from prometaphase through early telophase and was not found in the NDF. Although the NDF and mitotic coiled bodies disappeared from the cytoplasm at approximately the same time during mitosis, protein B23 was not found in mitotic coiled bodies, nor was p80 coilin present in the NDF. These results suggest that a class of proteins involved in preribosomal RNA processing associate with chromosome periphery and with NDF as part of a system to conserve and deliver preexisting components to reforming nucleoli during mitosis.

Specific interaction between casein kinase 2 and the nucleolar protein Nopp140.

Casein kinase 2 (CK2) is a multifunctional second messenger-independent protein serine/threonine kinase that phosphorylates many different proteins. To understand the function and regulation of this enzyme, biochemical methods were used to search for CK2-interacting proteins. Using immobilized glutathione S-transferase fusion proteins of CK2, the nucleolar protein Nopp140 was identified as a CK2-associated protein. It was found that Nopp140 binds primarily to the CK2 regulatory subunit, beta. The possible in vivo association of Nopp140 with CK2 was also suggested from a coimmunoprecipitation experiment in which Nopp140 was detected in immunoprecipitates of CK2 prepared from cell extracts. Further studies using an overlay technique with radiolabeled CK2 as a probe revealed a direct CK2-Nopp140 interaction. Using deletion mutants of CK2beta subunits, the binding region of the CK2beta subunit to Nopp140 has been mapped. It was found that the NH2-terminal 20 amino acids of CK2beta are involved. Since Nopp140 has been identified as a nuclear localization sequence-binding protein and has been shown to shuttle between the cytoplasm and the nucleus, the finding of a CK2-Nopp140 interaction could shed light on our understanding of the function and regulation of CK2 and Nopp140.

Comparison of the rat nucleolar protein nopp140 with its yeast homolog SRP40. Differential phosphorylation in vertebrates and yeast.

Rat Nopp140, a nonribosomal protein of the nucleolus and coiled bodies, was characterized as one of the most highly phosphorylated proteins in the cell. Based on its subcellular location, its nuclear localization signal binding capacity, and its shuttling between the nucleolus and the cytoplasm, Nopp140 was proposed to function as a chaperone in ribosome biogenesis. This study shows that casein kinase II phosphorylates Nopp140 to its unusual high degree and identifies the yeast SRP40 gene product as immunologically and structurally related to rat Nopp140. SRP40 encodes an acidic (pI = 3. 9), serine-rich (49%) protein of 41 kDa whose carboxyl terminus exhibits 59% sequence identity to that of Nopp140. SRP40 localizes to the yeast nucleolus and is required at a specific cellular concentration for optimal growth as indicated by the negative effect on cell growth of both overexpression and deletion of its gene. Like Nopp140, SRP40 is phosphorylated by casein kinase II, but to a much lesser extent. While the parallels between these two proteins suggest that SRP40 is the bona fide yeast Nopp140 homolog, their disparities reflect the differences in nucleolar dynamics and regulation of ribosome biogenesis between yeast and vertebrates.

NAP57, a mammalian nucleolar protein with a putative homolog in yeast and bacteria.

We report the identification and molecular characterization of a novel nucleolar protein of rat liver. As shown by coimmunoprecipitation this protein is associated with a previously identified nucleolar protein, Nopp140, in an apparently stoichiometric complex and has therefore been termed NAP57 (Nopp140-associated protein of 57 kD). Immunofluorescence and immunogold electron microscopy with NAP57 specific antibodies show colocalization with Nopp140 to the dense fibrillar component of the nucleolus, to coiled bodies, and to the nucleoplasm. Immunogold staining in the nucleoplasm is occasionally seen in the form of curvilinear tracks between the nucleolus and the nuclear envelope, similar to those previously reported for Nopp140. These data suggest that Nopp140 and NAP57 are indeed associated with each other in these nuclear structures. The cDNA deduced primary structure of NAP57 shows a protein of a calculated molecular mass of 52,070 that contains a putative nuclear localization signal near its amino and carboxy terminus and a hydrophobic amino acid repeat motif extending across 84 residues. Like Nopp140, NAP57 lacks any of the known consensus sequences for RNA binding which are characteristic for many nucleolar proteins. Data bank searches revealed that NAP57 is a highly conserved protein. A putative yeast (S. cerevisiae) homolog is 71% identical. Most strikingly, there also appears to be a smaller prokaryotic (E. coli and B. subtilis) homolog that is nearly 50% identical to NAP57. This indicates that NAP57 and its putative homologs might serve a highly conserved function in both pro- and eukaryotes such as chaperoning of ribosomal proteins and/or of preribosome assembly.

Nopp140 shuttles on tracks between nucleolus and cytoplasm.

Nopp140 is a nucleolar phosphoprotein of 140 kd that we originally identified and purified as a nuclear localization signal (NLS)-binding protein. Molecular characterization revealed a 10-fold repeated motif of highly conserved acidic serine clusters that contain an abundance of phosphorylation consensus sites for casein kinase II (CK II). Indeed, Nopp140 is one of the most phosphorylated proteins in the cell, and NLS binding was dependent on phosphorylation. Nopp140 was shown to shuttle between the nucleolus and the cytoplasm. Shuttling is likely to proceed on tracks that were revealed by immunoelectron microscopy. These tracks extend from the dense fibrillar component of the nucleolus across the nucleoplasm to some nuclear pore complexes. We suggest that Nopp140 functions as a chaperone for import into and/or export from the nucleolus.

A nuclear localization signal binding protein in the nucleolus.

We used functional wild-type and mutant synthetic nuclear localization signal peptides of SV-40 T antigen cross-linked to human serum albumin (peptide conjugates) to assay their binding to proteins of rat liver nuclei on Western blots. Proteins of 140 and 55 kD (p140 and p55) were exclusively recognized by wild-type peptide conjugates. Free wild-type peptides competed for the wild-type peptide conjugate binding to p140 and p55 whereas free mutant peptides, which differed by a single amino acid from the wild type, competed less efficiently. The two proteins were extractable from nuclei by either low or high ionic strength buffers. We purified p140 and raised polyclonal antibodies in chicken against the protein excised from polyacrylamide gels. The anti-p140 antibodies were monospecific as judged by their reactivity with a single nuclear protein band of 140 kD on Western blots of subcellular fractions of whole cells. Indirect immunofluorescence microscopy on fixed and permeabilized Buffalo rat liver (BRL) cells with anti-p140 antibodies exhibited a distinct punctate nucleolar staining. Rhodamine-labeled wild-type peptide conjugates also bound to nucleoli in a similar pattern on fixed and permeabilized BRL cells. Based on biochemical characterization, p140 is a novel nucleolar protein. It is possible that p140 shuttles between the nucleolus and the cytoplasm and functions as a nuclear import carrier.

Genetic polymorphism of human cytochrome P-450 (S)-mephenytoin 4-hydroxylase. Studies with human autoantibodies suggest a functionally altered cytochrome P-450 isozyme as cause of the genetic deficiency.

The metabolism of the anticonvulsant mephenytoin is subject to a genetic polymorphism. In 2-5% of Caucasians and 18-23% of Japanese subjects a specific cytochrome P-450 isozyme, P-450 meph, is functionally deficient or missing. We have accumulated evidence that autoimmune antibodies observed in sera of patients with tienilic acid induced hepatitis (anti-liver kidney microsome 2 or anti-LKM2 antibodies) specifically recognize the cytochrome P-450 involved in the mephenytoin hydroxylation polymorphism. This is demonstrated by immunoinhibition and immunoprecipitation of microsomal (S)-mephenytoin 4-hydroxylation activity and by the recognition by anti-LKM2 antibodies of a single protein band on immunoblots of human liver microsomes after sodium dodecyl sulfate-polyacrylamide gel electrophoresis or isoelectric focusing. The cytochrome P-450 recognized by anti-LKM2 antibodies was immunopurified from microsomes derived from livers of extensive (EM) or poor metabolizers (PM) of (S)-mephenytoin. Comparison of the EM-type cytochrome P-450 to that isolated from PM livers revealed no difference in regard to immuno-cross-reactivity, molecular weight, isoelectric point, relative content in microsomes, two-dimensional tryptic peptide maps, one-dimensional peptide maps with three proteases, amino acid composition, and amino-terminal protein sequence. Finally, the same protein was precipitated from microsomes prepared from the liver biopsy of a subject phenotyped in vivo as a poor metabolizer of mephenytoin. These data strongly suggest that the mephenytoin hydroxylation deficiency is caused by a minor structural change leading to a functionally altered cytochrome P-450 isozyme.

Mephenytoin-type polymorphism of drug oxidation: purification and characterization of a human liver cytochrome P-450 isozyme catalyzing microsomal mephenytoin hydroxylation.

A genetic polymorphism causing deficient metabolism of the anticonvulsant drug mephenytoin occurs in 5% of the Caucasian and 23% of the Japanese population. By monitoring the activities of the two major oxidative pathways of mephenytoin metabolism in the column eluates, we have purified from human livers a cytochrome P-450 isozyme, P-450 meph, which exclusively and stereoselectively catalyzes the 4-hydroxylation of (S)-mephenytoin, the major pathway affected by the polymorphism, whereas P-450 meph was virtually devoid of catalytic activity for N-demethylation of mephenytoin, the pathway remaining unaffected by the genetic deficiency. P-450 meph had an apparent Mr of 55 000 and a lambda max in the reduced CO-binding spectrum of 450 nm. Polyclonal rabbit antibodies against purified human P-450 meph almost completely inhibited the 4-hydroxylation of mephenytoin but had little effect on N-demethylation in human liver microsomes. In microsomes of liver biopsies of two subjects characterized in vivo as 'poor metabolizers' of mephenytoin, immunocrossreactive and immunoinhibitable material was observed with similar or identical properties to those of P-450 meph. There was no difference in the extent of the immunochemical reaction between microsomes of in vivo phenotyped poor metabolizers and extensive metabolizers of mephenytoin. These data suggest that P-450 meph is the target of the genetic deficiency and support the concept that a functionally altered variant form of P-450 meph causes this polymorphism.

The molecular mechanisms of two common polymorphisms of drug oxidation--evidence for functional changes in cytochrome P-450 isozymes catalysing bufuralol and mephenytoin oxidation.

Using the stereospecific metabolism of (+)- and (-)-bufuralol and (+)- and (-)-metoprolol as model reactions, we have characterized the enzymic deficiency of the debrisoquine/sparteine-type polymorphism by comparing kinetic data of subjects in vivo with their microsomal activities in vitro and with reconstituted activities of cytochrome P-450 isozymes purified from human liver. The metabolism of bufuralol in liver microsomes of in vivo phenotyped 'poor metabolizers' of debrisoquine and/or sparteine is characterized by a marked increase in Km, a decrease in Vmax and a virtual loss of the stereoselectivity of the reaction. These parameters apparently allow the 'phenotyping' of microsomes in vitro. A structural model of the active site of a cytochrome P-450 for stereospecific metabolism of bufuralol and other polymorphically metabolized substrates was constructed. Two cytochrome P-450 isozymes, P-450 buf I and P-450 buf II, both with MW 50,000 Da, were purified from human liver on the basis of their ability to metabolize bufuralol to 1'-hydroxy-bufuralol. However, P-450 buf I metabolized bufuralol in a highly stereoselective fashion ((-)/(+) ratio 0.16) as compared to P-450 buf II (ratio 0.99) and had a markedly lower Km for bufuralol. Moreover, bufuralol 1'-hydroxylation by P-450 buf I was uniquely characterized by its extreme sensitivity to inhibition by quinidine. Antibodies against P-450 buf I and P-450 buf II inhibited bufuralol metabolism in microsomes and with the reconstituted enzymes. Immunochemical studies with these antibodies with microsomes and translations in vitro of RNA from livers of extensive and poor metabolizers showed no evidence for a decrease in the recognized protein or its mRNA. Because the antibodies do not discriminate between P-450 buf I and P-450 buf II, both a decreased content of P-450 buf I or its functional alteration could explain the polymorphic metabolism in microsomes. The genetically defective stereospecific metabolism of mephenytoin was determined in liver microsomes of extensive and poor metabolizers of mephenytoin phenotyped in vivo. Microsomes of poor metabolizers were characterized by an increased Km and a decreased Vmax for S-mephenytoin hydroxylation as compared to extensive metabolizers and a loss of stereospecificity for the hydroxylation of S-versus R-mephenytoin. A cytochrome P-450 with high activity for mephenytoin 4-hydroxylation was purified from human liver. Immunochemical studies with inhibitory antibodies against this isozyme suggest the presence in poor-metabolizer microsomes of a functionally altered enzyme.

Assay of mephenytoin metabolism in human liver microsomes by high-performance liquid chromatography.

The metabolism of mephenytoin to its two major metabolites, 4-OH-mephenytoin (4-OH-M) and 5-phenyl-5-ethylhydantoin (nirvanol) was studied in human liver microsomes by a reversed phase HPLC assay. Because of preferential hydroxylation of S-mephenytoin in vivo, microsomes (5-300 micrograms protein) were incubated separately with S- and R-mephenytoin. After addition of phenobarbital as internal standard, the incubation mixture was extracted with dichloromethane. The residue remaining after evaporation was dissolved in water and injected on a 60 X 4.6-mm reversed-phase column (5 mu-C-18). Elution with acetonitrile/methanol/sodium perchlorate (20 mM, pH 2.5) led to almost baseline separation of mephenytoin, metabolites, and phenobarbital. Quantitation was performed by uv-absorption at 204 nm by the internal standard method. Propylene glycol was found to be the best solvent for mephenytoin, but inhibited the reaction noncompetitively. 4-OH-M and nirvanol could be detected at concentrations in the incubation mixture as low as 40 and 80 nM, respectively. The rates of metabolite formation were linear with time and protein concentration. The reaction was found to be substrate stereoselective. At substrate concentrations below 0.5 mM S-mephenytoin was preferentially hydroxylated to 4-OH-M, while R-mephenytoin was preferentially demethylated to nirvanol at all substrate concentrations tested (25-1600 microM). These data provide a mechanistic explanation for the stereospecific pharmacokinetics in vivo. The dependence of both metabolic relations on NADPH and the inhibition by CO suggest that they are mediated by cytochrome P-450-type monooxygenases.(ABSTRACT TRUNCATED AT 250 WORDS)

Mephenytoin hydroxylation polymorphism: characterization of the enzymatic deficiency in liver microsomes of poor metabolizers phenotyped in vivo.

The rate of 4-hydroxylation and of N-demethylation of S- and R-mephenytoin was determined in liver microsomes of 13 extensive (EM) and two poor (PM) metabolizers of mephenytoin. Detailed kinetic studies were performed in microsomes of eight EMs and the two PMs. Microsomal mephenytoin metabolism in PMs was characterized by an increased Km (150.6 and 180.6 vs. a mean [+/- SD] 37.8 +/- 9.6 mumol/L S-mephenytoin in 8 EMs), a decreased maximum rate of metabolism for S-mephenytoin hydroxylation (0.76 and 0.69 vs 4.85 +/- 1.65 nmol 4-hydroxymephenytoin per milligram protein per hour), and loss of stereoselectivity for the hydroxylation of the R- and S-enantiomers of mephenytoin (R/S ratio: 1.10 and 0.76 vs. 0.11 +/- 0.04 in 13 EMs). The formation of 4-OH-mephenytoin from R-mephenytoin and the demethylation reaction remained unaffected. These results support our hypothesis that the mephenytoin polymorphism is caused by a partial or complete absence or inactivity of a cytochrome P-450 isozyme with high affinity for S-mephenytoin.

Kinetics of oxygen and carbon monoxide binding to liver fluke (Dicrocoelium dendriticum) hemoglobin. An extreme case?

The kinetics of oxygen and carbon monoxide binding to the monomeric liver fluke (Dicrocoelium dendriticum) hemoglobin have been studied. The ligand association rates are approximately 1 X 10(8) and approximately 3 X 10(8) M-1 s-1, respectively, for CO and O2 and show no pH dependence. On the contrary the ligand dissociation rates decrease by lowering the pH below 7, the pK of the transition being around 5.5. These findings, together with spectroscopic properties of the protein, are discussed in relation to the fact that, in this hemoglobin, the distal histidine is replaced by a glycine.

Electron paramagnetic resonance properties of liver fluke (Dicrocoelium dendriticum) nitrosyl hemoglobin.

The electron paramagnetic resonance properties of the nitric oxide derivative of liver fluke (Dicrocoelium dendriticum) hemoglobin (DD-Hb) have been investigated in the pH range from 4.8 to 7.8. In the neutral and alkaline regions the spectra have a rhombic shape, with gx = 2.09, gy = 1.99 and gz = 2.009, and a triplet hyperfine structure of 2.2 mT, due to the nitrogen of the bound NO molecule, in the center resonance. No superhyperfine lines in the gz region, related to the interaction of the iron with the proximal histidine, are detected, suggesting a large distance between the metal and the N epsilon of the imidazole. By lowering the pH the EPR spectrum undergoes a reversible change showing a 3-line pattern in the high-field region. Such a spectrum is fully formed at pH 4.8 and is interpreted in terms of a dissociation of the proximal histidine from the heme iron.