The functional role of cytochrome b5 reincorporated into hepatic microsomal fractions

Incorporation of detergent-solubilized cytochrome b5 into phenobarbital-induced rabbit liver microsomal fractions decelerates hexobarbital-dependent reduction of ferric cytochrome P-450; this is accompanied by retardation of NADPH utilization and H2O2 formation in the assay media. Integration of manganese-substituted cytochrome b5 into the microsomal preparations fails to affect these parameters. Analysis of the cytochrome P-450 reduction kinetics in the presence of increasing amounts of cytochrome b5 reveals a gradual augmentation of the amplitude of slow-phase electron transfer at the expense of the relative contribution of the fast phase; finally, a slow, apparently monophasic reaction persists. This defect in enzymatic reduction is not due to detergent effects and also does not seem to reflect cytochrome b5-induced perturbation of anchoring of NADPH-cytochrome c(P-450) reductase to cytochrome P-450. Experiments with the highly purified cytochrome P-450 isozyme LM2, in which amino acid residue(s) close to the heme edge had undergone suicidal inactivation through covalent attachment of chloramphenicol metabolite(s) do not exclude the possibility that cytochrome b5 and reductase might compete for a common electron transmission site on the terminal acceptor. Hence, the inhibitory action of cytochrome b5 on the reduction of ferric cytochrome P-450 is tentatively attributed to partial substitution of the former pigment for reductase in direct transport of the first electron to the monooxygenase.     

Comparative studies on the cumene hydroperoxide- and NADPH-supported N-oxidation of 4-chloroaniline by cytochrome P-450.

The present study confirms that cytochrome P-450 can act as a catalyst in the cumene hydroperoxide-supported N-oxidation of 4-chloroaniline. Analogous to the NADPH/O2-driven N-oxidation process, product dissociation is likely to limit the overall rate of cytochrome P-450 cycling also in the peroxidatic pathway. The oxy complexes involved in either metabolic route differ with respect to stability, spectral properties and need for thiolate-mediated resonance stabilization. With the organic hydroperoxide, the metabolic profile is shifted from the preponderant production of N-(4-chlorophenyl)hydroxylamine to the formation of 1-chloro-4-nitrobenzene. This finding suggests that the peroxide-sustained N-oxidation mechanism differs in several ways from that functional in the NADPH/O2-dependent oxenoid reaction. Thus one-electron oxidation, triggered by homolytic cleavage of the oxygen donor, is proposed as the mechanism of peroxidatic transformation of 4-chloroaniline.     

The role of lipid peroxidation in the N-oxidation of 4-chloroaniline.

Irradiation with u.v. light of aerobic aqueous media containing both rabbit liver microsomal fraction and 4-chloroaniline results in N-oxidation of the arylamine. The reaction is severely blocked by exhaustive extraction with organic solvents of the microsomal membranes to remove lipids. Further, scavengers of OH. and O2.-impair the photochemical process. These findings suggest that the observed phenomenon may be closely associated with light-induced lipid peroxidation. Indeed, N-oxidation of 4-chloroaniline is fully preserved when either phospholipid liposomes or dispersed linoleic acid substitute for intact microsomal fraction. Co-oxidation of the amine substrate occurs during iron/ascorbate-promoted lipid peroxidation also, but H2O2 or free OH. radicals do not appear to be involved. Cumene hydroperoxide-sustained rabbit liver microsomal turnover of the amine generates N-oxy product via O2-dependent and -independent pathways; propagation of lipid peroxidation is presumed to govern the former route. Lipid hydroperoxides, either exogenously added to rabbit liver microsomal suspensions or enzymically formed from arachidonic acid in ram seminal-vesicle microsomal preparations, support N-oxidation of 4-chloroaniline. The significance, in arylamine activation, of lipid peroxidation in certain extrahepatic tissues exhibiting but low mono-oxygenase activity is discussed.     

<Emphasis Type="Italic">mab-31</Emphasis> and the TGF-β pathway act in the ray lineage to pattern <Emphasis Type="Italic">C. elegans</Emphasis>male sensory rays

Background  

C. elegans TGF-β-like Sma/Mab signaling pathway regulates both body size and sensory ray patterning. Most of the components in this pathway were initially identified by genetic screens based on the small body phenotype, and many of these mutants display sensory ray patterning defect. At the cellular level, little is known about how and where these components work although ray structural cell has been implicated as one of the targets. Based on the specific ray patterning abnormality, we aim to identify by RNAi approach additional components that function specifically in the ray lineage to elucidate the regulatory role of TGF-β signaling in ray differentiation.     

Topological Biosynthesis of Phosphatidylcholine in Brain Microsomes

The sidedness of the biosynthesis of phosphatidylcholine and its transbilayer movement in brain microsomes were investigated. Microsomes were labelled in vitro or in vivo either through Kennedy's pathway or by the base-exchange reaction. The vesicles were treated with phospholipase C under conditions where only the phospholipids present in the external leaflet were hydrolyzed. The incubation of microsomes with CDP-[14C]choline or [14C]choline showed that most of the newly synthesized phosphatidylcholine molecules were localized in the external leaflet. With time a few molecules were transferred into the inner leaflet. When phosphatidylcholine was labelled in vivo by intraventricular injection of [3H]choline the specific activities of the phosphatidylcholine in the outer leaflet were higher than those in the inner leaflet after short times of labelling but became similar after long times of labelling. The results suggest that in brain microsomes the synthesis of phosphatidylcholine through Kennedy's pathway or by the base-exchange reaction takes place on the external leaflet which corresponds to the cytoplasmic one in situ. The transfer of these molecules from the outer leaflet to the inner one is a slow process and the mechanisms that control the transbilayer movement of the phosphatidylcholine seem to be independent of those that control their biosynthesis.     

Detection of G Proteins in Purified Bovine Brain Myelin

Following a previous report on detection of muscarinic receptors in myelin with the implied presence of G proteins, we now demonstrate by more direct means the presence of such proteins and their quantification. Using [35S]guanosine 5'-O-(3-thiotriphosphate) ([35S]GTP gamma S) as the binding ligand, purified myelin from bovine brain was found to contain approximately half the binding activity of whole white matter (138 +/- 9 vs. 271 +/- 18 pmol/mg of protein). Scatchard analysis of saturation binding data revealed two slopes, a result suggesting at least two binding populations. This binding was inhibited by GTP and its analog but not by 5'-adenylylimidodiphosphate [App(NH)p], GMP, or UTP. Following sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) of myelin proteins and blotting on nitrocellulose, [alpha-32P]GTP bound to three bands in the 21-27-kDa range in a manner inhibited by GTP and GTP gamma S but not App(NH)p. ADP-ribosylation of myelin with [32P]NAD+ and cholera toxin labeled a protein of 43 kDa, whereas reaction with pertussis toxin labeled two components of 40 kDa. Cholate extract of myelin subjected to chromatography on a column of phenyl-Sepharose gave at least three major peaks of [35S]GTP gamma S binding activity. SDS-PAGE and immunoblot analyses of peak I indicated the presence of Go alpha, Gi alpha, and Gs alpha. Further fractionation of peak II by diethyl-aminoethyl-Sephacel chromatography gave one [35S]GTP gamma S binding peak with the low-molecular-mass (21-27 kDa) proteins and a second showing two major protein bands of 36 and 40 kDa on SDS-PAGE.(ABSTRACT TRUNCATED AT 250 WORDS)     

Influence of N,N-dimethylaniline on the association of phenobarbital-induced cytochrome P-450 and NADPH-cytochrome c(P-450) reductase in a reconstituted rabbit liver microsomal enzyme system

N,N-Dimethylaniline when added to reaction mixtures provokes deviation from Michaelis-Menten law of the interaction kinetics of NADPH-cytochrome c(P-450) reductase (NADPH:ferrihaemoprotein oxidoreductase, EC 1.6.2.4) with highly purified phenobarbital-induced rabbit liver microsomal cytochrome P-450 (P-450LM2). This phenomenon is not associated with the low-to-high spin transition in the iron-coordination sphere of the haemoprotein, as elicited by the arylamine. Substrate-triggered departure from linearity of the kinetics is abolished by inclusion into the assay media of p-chloromercuribenzoate, hinting at a vital role in the process of thiols. Similarly, the parabolic progress curve (nH = 1.7) is transformed to a straight line (nH = 1.01) when the N-terminal reductase-binding domain in the P-450LM2 molecule is selectively blocked through covalent attachment of fluorescein isothiocyanate (FITC); such a modification does not alter the affinity of the haemoprotein for the amine substrate. Steady-state fluorescence polarization measurements reveal that N,N-dimethylaniline perturbs the motional properties of the fluorophore-bearing reductase-binding region, suggesting the induction of a conformational change. Summarizing these results, the data possibly indicate N,N-dimethylaniline-induced cooperativity in the association of reductase with P-450LM2.     

High throughput screening to investigate the interaction of stem cells with their extracellular microenvironment

Stem cells in vivo are housed within a functional microenvironment termed the “stem cell niche.” As the niche components can modulate stem cell behaviors like proliferation, migration and differentiation, evaluating these components would be important to determine the most optimal platform for their maintenance or differentiation. In this review, we have discussed methods and technologies that have aided in the development of high throughput screening assays for stem cell research, including enabling technologies such as the well-established multiwell/microwell plates and robotic spotting, and emerging technologies like microfluidics, micro-contact printing and lithography. We also discuss the studies that utilized high throughput screening platform to investigate stem cell response to extracellular matrix, topography, biomaterials and stiffness gradients in the stem cell niche. The combination of the aforementioned techniques could lay the foundation for new perspectives in further development of high throughput technology and stem cell research.     

Variation of clonal, mesquite-associated rhizobial and bradyrhizobial populations from surface and deep soils by symbiotic gene region restriction fragment length polymorphism and plasmid profile analysis

Genetic characteristics of 14 Rhizobium and 9 Bradyrhizobium mesquite (Prosopis glandulosa)-nodulating strains isolated from surface (0- to 0.5-m) and deep (4- to 6-m) rooting zones were determined in order to examine the hypothesis that surface- and deep-soil symbiont populations were related but had become genetically distinct during adaptation to contrasting soil conditions. To examine genetic diversity, Southern blots of PstI-digested genomic DNA were sequentially hybridized with the nodDABC region of Rhizobium meliloti, the Klebsiella pneumoniae nifHDK region encoding nitrogenase structural genes, and the chromosome-localized ndvB region of R. meliloti. Plasmid profile and host plant nodulation assays were also made. Isolates from mesquite nodulated beans and cowpeas but not alfalfa, clover, or soybeans. Mesquite was nodulated by diverse species of symbionts (R. meliloti, Rhizobium leguminosarum bv. phaseoli, and Parasponia bradyrhizobia). There were no differences within the groups of mesquite-associated rhizobia or bradyrhizobia in cross-inoculation response. The ndvB hybridization results showed the greatest genetic diversity among rhizobial strains. The pattern of ndvB-hybridizing fragments suggested that surface and deep strains were clonally related, but groups of related strains from each soil depth could be distinguished. Less variation was found with nifHDK and nodDABC probes. Large plasmids (>1,500 kb) were observed in all rhizobia and some bradyrhizobia. Profiles of plasmids of less than 1,000 kb were related to the soil depth and the genus of the symbiont. We suggest that interacting selection pressures for symbiotic competence and free-living survival, coupled with soil conditions that restrict genetic exchange between surface and deep-soil populations, led to the observed patterns of genetic diversity.     

The role of hemoglobin in the N-oxidation of 4-chloroaniline

Rabbit hemoglobin effects reduced pyridine nucleotide-dependent N-oxidation of 4-chloroaniline in the presence of NADPH-cytochrome c (P-450) reductase (EC 1.6.2.4). The reaction is blocked by the addition of CO, superoxide dismutase (EC 1.15.1.1) and catalase (EC 1.11.1.6). The apparent Km value for the amine is 5.9 mM. The substrate interacts with hemoglobin in a non-cooperative manner; highly purified alpha- and beta-subunits mediate amine oxidation with kinetic constants close to those of the intact tetramer. Metabolism of 4-chloroaniline is associated with the formation of a 421 nm absorbing spectral complex, which might represent a ferryl species or a product adduct. Rapid reaction measurements suggests that either transfer of the second electron or product dissociation limits the overall rate of hemoglobin cycling. Erythrocyte reductases, such as 'NADPH-methemoglobin reductase' or soluble NADH-cytochrome b5 reductase (EC 1.6.2.2), also sustain amine oxidation in the presence of an appropriate electron carrier. Similarly, intact rabbit erythrocytes generate low amounts of N-oxy product when incubated with the parent amine. These findings support the notion that the red blood cell might be a site of bioactivation of aromatic amines, some of which, after being N-oxidized, become potent mutagens and carcinogens.