Effects of Breaking Up Prolonged Sitting on Cardiovascular Parameters: A systematic Review

The aim of this systematic review was to analyze the acute and chronic effects of sitting breaks on cardiovascular parameters. PubMed and Web of Science databases were searched by two independent researchers for relevant studies published until February 2020. Acute or chronic studies reporting the effects of sitting breaks or reduction in sitting time on cardiovascular parameters were examined. The eligibility criteria followed PICOS: Population - Humans ≥ 18 years old; Interventions - Sitting break strategies; Comparisons - Uninterrupted sitting; Outcomes - Cardiovascular parameters (blood pressure, heart rate, ambulatory blood pressure, vascular function, pulse-wave velocity, cerebral blood flow and biomarkers); Study design - Randomized controlled trials, non-randomized non-controlled trials and randomized crossover trials. Forty-five studies were included, where 35 investigated the acute and 10 the chronic effects of sitting breaks or reductions in sitting time. Walking was the main acute study strategy, used in different volumes (1 min 30 s to 30 min), intensities (light to vigorous) and frequencies (every 20 min to every 2 h). Acute studies found improvements on cardiovascular parameters, especially blood pressure, flow-mediated dilation, and biomarkers, whereas chronic studies found improvements mostly on blood pressure. Breaking up or reducing sitting time improves cardiovascular parameters, especially with walking.

Blood biomarkers associated with inflammation predict poor prognosis in cerebral venous thrombosis:: a multicenter prospective observational study

BACKGROUND AND PURPOSE

Experimental studies suggest inflammation can contribute to blood barrier disruption and brain injury in cerebral venous thrombosis (CVT). We aimed to determine whether blood biomarkers of inflammation were associated with the evolution of brain lesions, persistent venous occlusion or functional outcome in patients with CVT.

METHODS

Pathophysiology of Venous Infarction-Prediction of Infarction and Recanalization in CVT (PRIORITy-CVT) was a multicenter prospective cohort study of patients with newly diagnosed CVT. Evaluation of neutrophil-to-lymphocyte ratio (NLR) and C-reactive protein (CRP) concentrations in peripheral blood samples was performed at admission in 62 patients. Additional quantification of interleukin (IL)-6 was performed at day 1, 3 and 8 in 35 patients and 22 healthy controls. Standardized magnetic resonance imaging was performed at day 1, 8 and 90. Primary outcomes were early evolution of brain lesion, early recanalization and functional outcome at 90 days.

RESULTS

Interleukin-6 levels were increased in patients with CVT with a peak at baseline. IL-6, NLR and CRP levels were not related with brain lesion outcomes or early recanalization but had a significant association with unfavourable functional outcome at 90 days (IL-6: OR = 1.28, 95% CI: 1.05-1.56, P = 0.046; NLR: OR = 1.39, 95% CI: 1.4-1.87, P = 0.014; CRP: OR = 1.756, 95% CI: 1.010-3.051, P = 0.029). Baseline IL-6 had the best discriminative capacity, with an area under the receiver operating characteristic curve to predict unfavourable functional outcome of 0.74 (P = 0.031).

CONCLUSIONS

Increased baseline levels of NLR, CRP and IL-6 may serve as new predictive markers of worse functional prognosis at 90 days in patients with CVT. No association was found between inflammatory markers and early evolution of brain lesion or venous recanalization.

Phosphorylation of native and heme-modified CYP3A4 by protein kinase C: a mass spectrometric characterization of the phosphorylated peptides

As an initial approach toward the characterization of the phosphorylation of cumene hydroperoxide (CuOOH)-inactivated cytochrome P450 (CYP3A4, the major human liver drug-metabolizing enzyme) and its role in the degradation of the inactivated protein, we have identified one of the major participating cytosolic kinase(s) as rat liver cytosolic protein kinase C (PKC) with the use of specific and general kinase inhibitors. Accordingly, we employed a model phosphorylation system consisting of purified PKC, gamma-S-[(32)P]ATP, and either native or CuOOH-inactivated purified recombinant His(6)-tagged CYP3A4. Lysylendoprotease (Lys)-C digestion of the phosphorylated CuOOH-inactivated CYP3A4(His)(6) followed by HPLC-peptide mapping and mass spectrometric (LC/MS/MS) analyses led to the isolation and the unambiguous identification of two PKC-phosphorylated CYP3A4 peptides: E(258)SRLEDT(p)QK(266) and F(414)LPERFS(p)K(421). Similar analyses of the PKC-phosphorylated native enzyme predominantly yielded E(258)SRLEDT(p)QK(266) as the phosphorylated peptide. Studies are currently in progress to determine whether phosphorylation of any or both of these peptides is required for the Ub-dependent 26S proteasomal degradation of CuOOH-inactivated CYP3A4.

Ubiquitin-dependent 26S proteasomal pathway: a role in the degradation of native human liver CYP3A4 expressed in Saccharomyces cerevisiae?

Cytochrome P450, CYP3A4, is the dominant human liver endoplasmic reticulum (ER) hemoprotein enzyme, responsible for the metabolism of over 60% of clinically relevant drugs. We have previously shown that mechanism-based suicide inactivation of CYP3A4 and its rat liver ER orthologs, CYPs 3A, via heme-modification of their protein moieties, results in their ubiquitin (Ub)-dependent 26S proteasomal degradation (Korsmeyer et al. (1999) Arch. Biochem. Biophys. 365, 31; Wang et al. (1999) Arch. Biochem. Biophys. 365, 45). This is not surprising given that the heme-modified CYP3A proteins are structurally damaged. To determine whether the turnover of the native enzyme similarly recruited this pathway, we heterologously expressed this protein in wild-type Saccharomyces cerevisiae and mutant strains (hrd1Delta, hrd2-1, and hrd3Delta) previously shown to be deficient in the Ub-dependent 26S proteasomal degradation of the polytopic ER protein 3-hydroxy-3-methylglutaryl-CoA reductase (isoform Hmg2p), the rate-limiting enzyme in sterol biosynthesis, as well as in strains deficient in ER-associated Ub-conjugating enzymes, Ubc6p and/or Ubc7p (Hampton et al. (1996) Mol. Biol. Cell 7, 2029; Hampton and Bhakta (1997) Proc. Natl. Acad. Sci. USA 94, 12,944). Our findings reveal that in common with the degradation of Hmg2p, that of native CYP3A4 also requires Hrd2p (a subunit of the 19S cap complex of the 26S proteasome) and Ubc7p, and to a much lesser extent Hrd3p, a component of the ER-associated Ub-ligase complex. In contrast to Hmg2p-degradation, that of native CYP3A4 does not appear to absolutely require Hrd1p, another component of the ER-associated Ub-ligase complex. Furthermore, studies in a S. cerevisiae pep4Delta strain proven to be deficient in the vacuolar degradation of carboxypeptidase Y indicated that CYP3A4 degradation is also largely independent of vacuolar (lysosomal) proteolytic function. The degradation of two other native ER proteins, Sec61p and Sec63p, normal components of the ER translocon, were also examined in parallel and found to be stabilized to some extent in HRD2- and UBC7-deficient strains. Together these findings attest to the remarkable mechanistic diversity in the normal degradation of ER proteins.

Influence of P450 3A4 SRS-2 residues on cooperativity and/or regioselectivity of aflatoxin B(1) oxidation

The major human liver drug-metabolizing cytochrome P450 enzymes P450 3A4 and P450 3A5 share >85% amino acid sequence identity yet exhibit different regioselectivity toward aflatoxin B(1) (AFB(1)) biotransformation [Gillam et al. (1995) Arch. Biochem. Biophys. 317, 74-384]. P450 3A4 prefers AFB1 3alpha-hydroxylation, which detoxifies and subsequently eliminates the hepatotoxin, over AFB1 exo-8,9-oxidation. P450 3A5, on the other hand, is a relatively sluggish 3alpha-hydroxylase and converts AFB(1) predominantly to the genotoxic exo-8,9-epoxide. Using a combination of approaches (sequence alignment, homology modeling and site-directed mutagenesis), we have previously identified several divergent residues in four of the six putative substrate recognition sites (SRSs) of P450 3A4, which when replaced individually with the corresponding amino acid of P450 3A5, resulted in a significant switch of the characteristic P450 3A4 AFB(1) regioselectivity toward that of P450 3A5 [Wang et al. (1998) Biochemistry 37, 12536-12545]. In particular, residues N206 and L210 in SRS-2 were found to be critical for AFB(1) detoxification via 3alpha-hydroxylation, and the corresponding mutants N206S and L210F most closely mimicked P450 3A5, not only in its regioselectivity of AFB(1) metabolism but also in its overall functional capacity. We have now further explored the plausible reasons for such relative inactivity of the SRS-2 mutants by examining N206S and additional mutants (L210A, L211F, L211A, and N206E) and found that the dramatically lowered activities of the N206S mutant are accompanied by a loss of cooperativity of AFB(1) oxidation. Molecular dynamics analyses with an existing P450 3A4 homology model [Szklarz and Halpert (1997) J. Comput. Aided Mol. Des. 11, 265] suggested that N206 (helix F) interacts with E244 (helix G), creating a salt bridge that stabilizes the protein structure and/or defines the active site cavity. To examine this possibility, several E244 mutants (E244A, V, N, S) were tested, of which E244S was the most notable for its relatively greater impairment of P450 3A4-dependent AFB(1) 3alpha-hydroxylation. However, the results with these E244 mutants failed to validate the N206-E244 interaction predicted from these molecular dynamics analyses. Collectively, our findings to date have led us to reconsider our original interpretations and to reexamine them in the light of AFB(1) molecular modeling analyses with a newly refined P450 3A4 homology model. These analyses predicted that F304 in SRS-4 (I-helix) plays a pivotal role in AFB(1) binding at the active site in either orientation leading to 3alpha- or exo-8,9-oxidation. Consistent with this prediction, conversion of F304 to Ala abolished P450 3A4-dependent AFB(1) 3alpha-hydroxylation and exo-8,9-oxidation.

Structure--function relationships of rat hepatic tryptophan 2,3-dioxygenase: identification of the putative heme-ligating histidine residues

The liver cytosolic enzyme tryptophan 2,3-dioxygenase (TDO) catalyzes the oxidation of L-tryptophan to formylkynurenine and controls the physiological flux of tryptophan into both the serotonergic and kynureninic pathways. This hemoprotein enzyme is composed of four noncovalently bound subunits of equivalent mass and contains two heme moieties per molecule. Electron paramagnetic resonance analyses have indicated that a histidyl nitrogen is involved in heme ligation [Henry et al., (1976) J. Biol. Chem. 251, 1578], but the identity of the His residue(s) is unknown. In an attempt to characterize the active site of the enzyme we have substituted each of the 12 His residues in the rat TDO subunit with Ala, to determine their relative importance in heme binding. Sequence alignment of the rat liver protein with that of known or putative TDO sequences from other organisms reveals that four of the His residues are conserved in eukaryotes, two of which are also conserved in prokaryotes. Our findings indicate that replacement of the evolutionarily conserved His 76 and 328 residues resulted in a dramatic reduction of TDO activity, whereas that of the eukaryotically conserved His70 resulted in a significant reduction relative to that of the wild-type enzyme. On the other hand, replacement of the other eukaryotically conserved His273 residue, while affecting the relative expression of the enzyme, had little effect on its specific activity. Size-exclusion analyses revealed that the His76Ala and His328Ala mutants retained little or no heme, suggesting that these may be key residues in ligating the prosthetic heme moieties. Whether these His residues are both provided by the same TDO subunit or a different TDO subunit remains to be determined.

Heme: a regulator of rat hepatic tryptophan 2,3-dioxygenase?

The hepatic cytosolic hemoprotein tryptophan 2,3-dioxygenase (TDO) is the rate-limiting enzyme in tryptophan catabolism and thus plays a key role in regulating the physiological flux of tryptophan into relevant metabolic pathways. The TDO protein is induced by corticosteroids such as dexamethasone (DEX) and is stabilized by its prosthetic heme. In rats, acute chemically induced hepatic heme depletion reduces the functional hepatic TDO levels to 25-30% of basal levels within 1 h, and this decrease persists beyond 28 h of heme depletion at which time only 25-30% of the protein is available for heme incorporation. Since this could stem from impaired de novo synthesis and/or instability of the newly synthesized apoTDO protein in the absence of heme, we examined the specific role of heme in these events in a previously validated rat model of acute hepatic heme depletion triggered by the P450 suicide substrate 3, 5-dicarbethoxy 2,6-dimethyl-4-ethyl-1,4-dihydropyridine. We now show that exogenous heme can reverse the functional impairment of the enzyme observed during hepatic heme depletion and fully restore the impaired DEX-mediated induction of the enzyme to normal. Furthermore, through Northern/slot blot analyses coupled with nuclear run-on studies, we now document that this heme regulation of TDO is exerted primarily at the transcriptional level. Immunoblotting analyses also reveal corresponding changes in the TDO protein, thereby establishing that heme is necessary for DEX-inducible TDO mRNA transcription and subsequent translation. Thus, the TDO gene may contain heme-regulatory elements in addition to the reported glucocorticoid-responsive elements. Together, these findings suggest that clinically, hepatic heme deficiency may enhance the tryptophan flux into synthetic (serotonergic) pathways, not only by depriving prosthetic heme for a functionally competent TDO hemoprotein, its primary catabolic enzyme, but also by impairing the de novo synthesis of this enzyme.

Ethynylestradiol-mediated induction of hepatic CYP3A9 in female rats: implication for cyclosporine metabolism

Repeated treatment of female rats with the synthetic estrogen ethynylestradiol (EE(2)) increases the formation of the cyclosporine A (CyA) metabolites AM1c and AM9 by 3-fold, whereas the formation of AM1 and AM4N is not significantly enhanced. The formation of all four CyA metabolites was inhibited by greater than 80% by the CYP3A-selective substrate midazolam or polyclonal anti-rat CYP3A IgGs in liver microsomes of untreated and EE(2)-induced rats. In contrast, anti-rat CYP2C6 IgGs had little effect, indicating the involvement of a CYP3A but not 2C6 in this EE(2)-stimulated CyA metabolism. Semiquantitative reverse-transcriptase polymerase chain reaction was used to determine the mRNA content for four CYP3A genes (CYP3A2, CYP3A9, CYP3A18, and CYP3A23) in livers of control and EE(2)-treated female rats. EE(2) selectively induced CYP3A9 by 3.3-fold whereas the expression of CYP3A18 and CYP3A23 was slightly decreased; neither CYP3A2 mRNA nor CYP3A1 mRNA was detectable in these EE(2)-treated livers. To determine whether rat liver microsomal CYP3A9 was indeed responsible for the EE(2)-stimulated CyA metabolism, a recombinant CYP3A9 was heterologously expressed in Escherichia coli. When functionally reconstituted, this enzyme was active in metabolizing CyA preferentially to its AM9 and AM1c metabolites as compared with CYP3A4. These findings thus support the notion that the increased CyA-metabolizing capacity of EE(2)-treated female rat liver microsomes is due to the induction of the CYP3A9 enzyme.

Cytochrome P450 3A degradation in isolated rat hepatocytes: 26S proteasome inhibitors as probes

Mechanism-based inactivation of liver microsomal cytochromes P450 3A (CYP 3A, P450s 3A) in vivo and/or in vitro, via heme modification of the protein, results in accelerated proteolytic degradation of the enzyme that is preceded by the ubiquitination of the protein, thereby implicating the ubiquitin-ATP-dependent 26S proteasomal system. In this study, this involvement is confirmed with the use of the proteasomal inhibitors aclarubicin and MG-132 as probes, in isolated rat hepatocytes treated with the P450 3A mechanism-based inactivator, 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1, 4-dihydropyridine (DDEP). In addition, the findings reveal that during the course of this proteolysis, the endoplasmic reticulum (ER)-anchored DDEP-inactivated P450 3A is translocated from the ER to the cytosol in a brefeldin A-insensitive manner.

Proteolytic degradation of heme-modified hepatic cytochromes P450: A role for phosphorylation, ubiquitination, and the 26S proteasome?

The resident integral hepatic endoplasmic reticulum (ER) proteins, cytochromes P450 (P450s), turn over in vivo with widely varying half-lives. We and others (Correia et al., Arch. Biochem. Biophys. 297, 228, 1992; and Tierney et al., Arch. Biochem. Biophys. 293, 9, 1992) have previously shown that in intact animals, the hepatic P450s of the 3A and 2E1 subfamilies are first ubiquitinated and then proteolyzed after their drug-induced suicide inactivation. Our findings with intact rat hepatocytes and ER preparations containing native P450s and P450s inactivated via heme modification of the protein have revealed that the proteolytic degradation of heme-modified P450s requires a cytosolic ATP-dependent proteolytic system rather than lysosomal or ER proteases (Correia et al., Arch. Biochem. Biophys. 297, 228, 1992). Using purified cumene hydroperoxide-inactivated P450s (rat liver P450s 2B1 or 3A and/or a recombinant human liver P450 3A4) as models, we now document that these heme-modified enzymes are indeed ubiquitinated and then proteolyzed by the 26S proteasome, but not by its 20S proteolytic core. In addition, our studies indicate that the ubiquitination of these heme-modified P450s is preceded by their phosphorylation. It remains to be determined whether, in common with several other cellular proteins, such P450 phosphorylation is indeed required for their degradation. Nevertheless, these findings suggest that the membrane-anchored P450s are to be included in the growing class of ER proteins that undergo ubiquitin-dependent 26S proteasomal degradation.

Identification of the heme-modified peptides from cumene hydroperoxide-inactivated cytochrome P450 3A4

Cumene hydroperoxide-mediated (CuOOH-mediated) inactivation of cytochromes P450 (CYPs) results in destruction of their prosthetic heme to reactive fragments that irreversibly bind to the protein. We have attempted to characterize this process structurally, using purified, 14C-heme labeled, recombinant human liver P450 3A4 as the target of CuOOH-mediated inactivation, and a battery of protein characterization approaches [chemical (CNBr) and proteolytic (lysylendopeptidase-C) digestion, HPLC-peptide mapping, microEdman sequencing, and mass spectrometric analyses]. The heme-peptide adducts isolated after CNBr/lysylendopeptidase-C digestion of the CuOOH-inactivated P450 3A4 pertain to two distinct P450 3A4 active site domains. One of the peptides isolated corresponds to the proximal helix L/Cys-region peptide 429-450 domain and the others to the K-region (peptide 359-386 domain). Although the precise residue(s) targeted remain to be identified, we have narrowed down the region of attack to within a 17 amino acid peptide (429-445) stretch of the 55-amino acid proximal helix L/Cys domain. Furthermore, although the exact structures of the heme-modifying fragments and the nature of the adduction remain to be established conclusively, the incremental masses of approximately 302 and 314 Da detected by electrospray mass spectrometric analyses of the heme-modified peptides are consistent with a dipyrrolic heme fragment comprised of either pyrrole ring A-D or B-C, a known soluble product of peroxidative heme degradation, as a modifying species.

Structure-function relationships of human liver cytochromes P450 3A: aflatoxin B1 metabolism as a probe

Cytochromes P450 3A4 and 3A5, the dominant drug-metabolizing enzymes in the human liver, share >85% primary amino acid sequence identity yet exhibit different regioselectivity toward aflatoxin B1 (AFB1) biotransformation [Gillam et al., (1995) Arch. Biochem. Biophys. 317, 374-384]. P450 3A4 apparently prefers AFB1 3alpha-hydroxylation, which results in detoxification and subsequent elimination of the hepatotoxin, over AFB1 exo-8,9-oxidation. In contrast, P450 3A5 is incapable of appreciable AFB1 3alpha-hydroxylation and converts it predominantly to the exo-8,9-oxide which is genotoxic. To elucidate the structural features that govern the regioselectivity of the human liver 3A enzymes in AFB1 metabolism and bioactivation, a combination of approaches including sequence alignment, homology modeling, and site-directed mutagenesis was employed. Specifically, the switch in AFB1 regioselectivity was examined after individual substitution of the divergent amino acids in each of the six putative substrate recognition sites (SRSs) of P450 3A4 with the corresponding amino acid of P450 3A5. Of the P450 3A4 mutants examined, P107S, F108L, N206S, L210F, V376T, S478D, and L479T mutations resulted in a significant switch of P450 3A4 regioselectivity toward that of P450 3A5. The results confirmed the importance of some of these residues in substrate contact in the active site, with residue N206 (SRS-2) being critical for AFB1 detoxification via 3alpha-hydroxylation. Moreover, the P450 3A4 mutant N206S most closely mimicked P450 3A5, not only in its regioselectivity of AFB1 metabolism but also in its overall functional capacity. Furthermore, the other SRS-2 mutant, L210F, also resembled P450 3A5 in its overall AFB1 metabolism and regioselectivity. These findings reveal that a single P450 3A5 SRS domain (SRS-2) is capable of conferring the P450 3A5 phenotype on P450 3A4. In addition, some of these P450 3A4 mutations that affected AFB1 regioselectivity had little influence on testosterone 6beta-hydroxylation, thereby confirming that each substrate-P450 active site fit is indeed unique.

Cytochrome P450 2C11: Escherichia coli expression, purification, functional characterization, and mechanism-based inactivation of the enzyme

The male-specific P450 enzyme CYP 2C11, whose expression is developmentally and hormonally regulated, is the major steroid 16alpha-hydroxylase of the untreated rat liver. The enzyme metabolizes a host of substrates, including mechanism-based inactivators, such as 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine (DDEP) and spironolactone (SPL). Structural and functional characterization of the specific mode of such inactivation, however, requires sufficient quantities of the fully purified enzyme. Although several laboratories including our own have isolated and purified the enzyme from male rats, the yields are typically low and of the order of 1%. For these reasons, we chose to heterologously express the enzyme in Escherichia coli. The full-length cDNA was excised from the yeast vector pD2M1 and cloned into the plasmid vector pCW after appropriate modifications for optimal expression in E. coli. The enzyme was isolated and purified from E. coli membranes in relatively high yields (approximately 60%) and relatively high specific content (19 nmol/mg protein). The purified recombinant enzyme had spectral and functional characteristics comparable to those reported for the native rat liver enzyme, including mechanism-based inactivation by DDEP and SPL. Studies with 14C-heme-labeled enzyme indicated that the major mode of DDEP inactivation was via heme-N-ethylation. On the other hand, studies with radiolabeled SPL-SH (the proximal inactivating deacetylated metabolite of SPL) revealed that although both [22-14C]SPL-SH and SPL-35SH inactivated the enzyme, only SPL-35SH was found to irreversibly radiolabel the 2C11 protein. The latter findings thus suggest that during mechanism-based inactivation of 2C11, the thiol moiety of SPL-SH is oxidatively activated to a species that attacks the 2C11 protein during or after cleavage from the thiosteroid. Thus, these modes of mechanism-based 2C11 inactivation by DDEP and SPL-SH considerably differ from the corresponding modes of P450 3A inactivation by these agents, wherein heme modification of the protein predominates.

Secobarbital-mediated inactivation of cytochrome P450 2B1 and its active site mutants. Partitioning between heme and protein alkylation and epoxidation

Secobarbital (SB) is a relatively selective mechanism-based inactivator of cytochrome P450 2B1, that partitions between epoxidation and heme and protein modification during its enzyme inactivation. The SB-2B1 heme adduct formed in situ in a functionally reconstituted system has been spectrally documented and structurally characterized as N-(5-(2-hydroxypropyl)-5-(1-methylbutyl)barbituric acid)protoporphyrin IX. The SB-protein modification has been localized to 2B1 peptide 277-323 corresponding to the active site helix I of cytochrome P450 101. The targeting of heme and this active site peptide suggests that the 2B1 active site topology could influence the course of its inactivation. To explore this possibility, the individual SB epoxidation, heme and protein modification, and corresponding molar partition ratios of the wild type and seven structural 2B1 mutants, site-directed at specific substrate recognition sites, and known to influence 2B1 catalysis were examined after Escherichia coli expression. These studies reveal that Thr-302 is critical for SB-mediated heme N-alkylation, whereas Val-367 is a critical determinant of 2B1 protein modification, and Val-363 is important for SB epoxidation. SB docking into a refined 2B1 homology model coupled with molecular dynamics analyses provide a logical rationale for these findings.

Expression of rat liver tryptophan 2,3-dioxygenase in Escherichia coli: structural and functional characterization of the purified enzyme

The hepatic hemoprotein tryptophan 2,3-dioxygenase (TDO) is the key regulatory enzyme that, through irreversible degradation, controls the flux of tryptophan through physiologically relevant pathways. This enzyme is composed of four identical subunits and in its fully assembled tetrameric form requires 2 mol of heme (Fe(+2)-protoporphyrin IX)/mol of protein for functional competence. Using a full-length cDNA for the rat liver TDO subunit (pUC119/TDO) as the template, TDO cDNA was amplified by polymerase chain reaction (PCR) and incorporated into the expression vector pTrc99A after introduction of convenient restriction sites as well as modification of the second codon AGT to GCT to optimize its bacterial expression. DH5 alpha F' strain Escherichia coli cells transfected with this pTrc99A/TDO construct expressed soluble, functionally active, tetrameric TDO protein in high yields. The enzyme was isolated from 30,000g supernatant of cell lysates, purified by ion-exchange chromatography, and its spectral and catalytic properties were assessed in terms of its substrate and prosthetic moiety specificities. In almost all aspects, the bacterially expressed enzyme was found to be identical to that of the rat liver. Heterologous expression of the fully functional enzyme, we trust, will enable future elucidation of its structure-function relationships.

Identification of the heme adduct and an active site peptide modified during mechanism-based inactivation of rat liver cytochrome P450 2B1 by secobarbital

The olefinic barbiturate secobarbital (SB) is a sedative hypnotic known to be a relatively selective mechanism-based inactivator of rat liver cytochrome P450 2B1. Previous studies have demonstrated that such inactivation results in prosthetic heme destruction and irreversible drug-induced protein modification, events most likely triggered by P450 2B1-dependent oxidative activation of the olefinic pi-bond. However, the precise structure of the SB-modified heme and/or the protein site targeted for attack remained to be elucidated. We have now isolated the SB-heme adduct from P450 2B1 inactivated by [14C]SB in a functionally reconstituted system and structurally characterized it by electronic absorption spectroscopy and tandem collision-induced dissociation (CID), matrix-assisted laser desorption ionization on time of flight (MALDI-TOF), and liquid secondary ion mass spectrometry in the positive mode (+ LSIMS) as the N-(5-(2-hydroxypropyl)-5-(1-methylbutyl)barbituric acid)protoporphyrin IX adduct. The [14C]SB-modified 2B1 protein has also been isolated from similar inactivation systems and subjected to lysyl endopeptidase C (Lys-C) digestion and HPLC-peptide mapping. A [14C]SB-modified 2B1 peptide was thus isolated, purified, electrotransferred onto a poly-(vinylidene) membrane, and identified by micro Edman degradation of its first N-terminal 17 residues (S277NH(H)TEFH(H)ENLMISLL293) as the Lys-C peptide domain comprised of amino acids 277-323. This peptide thus includes the peptide domain corresponding to the distal helix I of P450 101, a region highly conserved through evolution, and which is known not only to flank the heme moiety but also to intimately contact the substrates. This finding thus suggests that SB-induced protein modification of P450 2B1 also occurs at the active site and, together with heme N-alkylation, contributes to the SB-induced mechanism-based inactivation of P450 2B1.

Microsomal cytochrome P450-mediated liver and brain anandamide metabolism

Anandamide (AN) is an arachidonic acid congener, found in the brain, that binds to the cannabinoid receptor and elicits cannabinoid-like pharmacological activity. Cytochromes P450 (P450s) are known to oxidize arachidonic acid to a wide variety of metabolites, yielding many physiologically potent compounds. To determine if AN could be similarly oxidized by P450s, its metabolism by mouse liver and brain microsomes was examined. Mouse hepatic microsomal incubation of AN with NADPH resulted in the generation of at least 20 metabolites, determined after HPLC separation by increased UV-absorbance at 205 nm. Pretreatment of mice with various P450 inducers resulted in increased hepatic microsomal formation of several AN metabolites, with dexamethasone being the most effective inducer. Phenobarbital pretreatment resulted in a metabolic profile similar to that observed after dexamethasone pretreatment, whereas 3-methylcholanthrene pretreatment selectively increased the formation of several other metabolites. Clofibrate pretreatment had no effect on hepatic AN metabolism. Polyclonal antibodies prepared against mouse hepatic P450 3A inhibited the formation of several AN metabolites by hepatic microsomes from untreated mice as well as the formation of those metabolites found to be increased after dexamethasone pretreatment. AN metabolism by brain microsomes resulted in the formation of two NADPH- and protein-dependent metabolites. Hepatic P450 3A antibody partially inhibited the formation of only one of these metabolites. Thus, P450 3A is a major contributor to AN metabolism in the liver but not in the brain. The physiological consequences of P450-mediated AN metabolism remain to be determined.

Interactions of peroxyquinols with cytochromes P450 2B1, 3A1, and 3A5: influence of the apoprotein on heterolytic versus homolytic O-O bond cleavage

In studies of the mechanisms involved in oxygen activation by cytochromes P450 (P450s), organic hydroperoxides are frequently used to model the putative peroxyferrous complex formed immediately prior to oxygen-oxygen bond cleavage during the reaction cycle of this monooxygenase. Heterolysis of the O-O bond by ferric P450 generates the catalytically competent oxo-ferryl intermediate analogous to peroxidase Compound I, and homolysis produces the Compound II analog capable only of one-electron oxidations. As P450s have been shown to catalyze both modes of O-O bond scission, the present investigation was focused on the influence of the apoprotein on the relative contributions of these competing processes. Liver microsomes from rats treated with the P450-inducing agents phenobarbital, beta-naphthoflavone, and dexamethasone, as well as purified P450s 2B1, 3A1, and 3A5 were incubated with 2,6-di-tert-butyl-4-hydroperoxy-4-methyl-2, 5-cyclohexadienone (BHTOOH). Ratios of heterolysis to homolysis were determined by analyzing the products derived from this hydroperoxide. The data demonstrate that BHTOOH is cleaved with a ratio of approximately 1.0 with all of the liver microsomal or purified P450s investigated, except with liver microsomes from dexamethasone-treated rats or with P450s 3A1 and 3A5. In these cases, heterolysis predominated over homolysis by factors of 2.5 to 4.0. On the other hand, microsomes rich in P450 2B1 catalyzed predominantly heterolysis with analogs of BHTOOH containing smaller alkyl substituents. The data are consistent with a requirement for solvent access to the peroxyferrous complex and general acid catalysis of heterolytic O-O bond cleavage by water.

[Drug-addicted mothers]

Drug addiction in Portuguese women has greatly increased recently and affects women of child-bearing age. The lack of scientific knowledge of the influence of drug addiction on pregnancy led us to create a model to approach the problem. With that purpose, a Clinic for Pregnant Drug Addicts was opened in the Alfredo da Costa Maternity Hospital in 1989, intended to set up a special permanent team to provide personalized pre-natal care. This clinic should be considered an integral part of multi-disciplinary action covering obstetrics, pediatrics, anesthesiology, nursing, clinical psychology and social assistance. The evolution of 164 pregnant women was monitored from October 1989 to December 1992, urine and amniotic fluid was analysed in 51 women. Due to the difficulty in applying standard criteria to the pregnancies observed, three levels of pre-natal care for the aforementioned 51 pregnant women, who are the object of this study, are proposed. The pre-natal observation of 164 pregnant drug addicts revealed that 74% were aged from 20 to 29 years, 49% had completed compulsory education, 59% were unemployed, 61% were unmarried and 82% had not planned their baby and had attended their first pre-natal clinic in the 19th week of pregnancy. The women's partners were drug addicts in 80% of cases. Their toxicological history revealed that 29% of them began taking drugs between the ages of 11 and 15, cannabis-based products being the first drug in 67% and opium-based in 28% of cases.(ABSTRACT TRUNCATED AT 250 WORDS)

Cobaltous chloride-mediated induction of rat hepatic tryptophan 2,3-dioxygenase: implications for the use of the enzyme to probe the hepatic free heme pool

Subcutaneous administration of CoCl2, a well recognized inhibitor of hepatic heme synthesis, to rats results in the functional stimulation of total (holo- + apo) tryptophan 2,3 dioxygenase (TDO), a hemoprotein and the key rate-limiting enzyme in the oxidative metabolism of tryptophan to formylkynurenine. Because basal holo-TDO activity is not altered, TDO stimulation appears to be entirely due to CoCl2-mediated increase of its apoprotein. This apoTDO increase was blocked by conventional inhibitors of protein synthesis (actinomycin D, cycloheximide), thereby revealing that such CoCL2-mediated apoprotein increase truly reflected TDO induction. To determine whether the CoCl2-mediated TDO induction involved the action of its natural physiological inducers (glucocorticoids) or was due to direct CoCl2-regulation of the TDO gene, rats were adrenalectomized before CoCl2 administration. In adrenalectomized rats, CoCl2 failed to induce TDO, but induction was completely restored on administration of the glucocorticoid hydrocortisone, but not of adrenaline. These findings reveal that CoCl2-mediated TDO induction is indirect and entails glucocorticoid participation. In addition, because CoCl2 lowered the % heme saturation of TDO [= 100(holo TDO activity/total (apo+holo) TDO activity] largely by increasing the apoTDO protein levels rather than by affecting the basal holo-TDO levels (as expected from its inhibition of heme synthesis), these findings question the widely accepted use of the relative intrahepatic % heme saturation of TDO as a reporter of the hepatic "free" heme pool.

pH-dependent one- and two-electron oxidation of 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine catalyzed by horseradish peroxidase

The porphyrinogenic agent 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine (DDEP) is known to inactivate hepatic cytochrome P450 (P450) enzymes 2C11, 2C6, and 3A1 [Correia et al. (1987) Arch. Biochem. Biophys. 258, 436-451] by different mechanisms. The inactivation of P450 2C11 and 2C6 appears to be due to the ethylation of the heme in the active sites of the enzymes [Augusto et al. (1982) J. Biol. Chem. 257, 11288-11295], whereas the inactivation of P450 3A1 appears to involve the covalent binding of the heme to the apoprotein [Correia et al. (1987)]. Moreover, we have found that DDEP inactivates horseradish peroxidase (HRP) pretreated with hydrogen peroxide. In this system, DDEP was oxidized predominately to 3,5-dicarbethoxy-2,6-dimethyl-4-ethylpyridine (EDP) under weakly acidic conditions and predominately to 3,5-dicarbethoxy-2,6-dimethylpyridine (DP) under basic conditions. The loss of heme and the formation of altered heme products were also pH-dependent and were correlated with the formation of DP and the inactivation of HRP. Thus the inactivation of HRP appears to depend on the formation of an ethyl radical, which presumably reacts with the heme in the active site of the enzyme. Similar product ratios were obtained for the oxidation of DDEP by K3Fe(CN)6, indicating that product ratios of DP over EDP are mainly determined by the pH of buffer. These results, in addition to semiemperical calculations (AM1) for the oxidation of DDEP in the gas phase, are consistent with the idea that the inhibitor undergoes a single-electron oxidation to form the DDEP radical cation, the fate of which depends on the environment of the active site of the enzyme. The proposed formation of a radical cation by the abstraction of an electron from nitrogen is consistent with the finding of low intramolecular isotope effects of the metabolism of 3,5-dicarbethoxy-2,6-dimethyl-[4-2H,4-1H]-1,4-dihydropyridine by P450 2C11 and 3A4. Under basic or aprotic conditions, the radical dissociates to form DP and the ethyl radical, which reacts with the heme, thereby inactivating the enzyme. Under acidic or polar conditions, the radical undergoes an additional one-electron oxidation to form EDP.(ABSTRACT TRUNCATED AT 400 WORDS)

Induction and genetic regulation of mouse hepatic cytochrome P450 by cannabidiol

Cannabidiol (CBD) has been shown to be a selective inactivator of cytochromes P450 (P450s) 2C and 3A in the mouse and, like many P450 inactivators, it can also induce P450s after repeated administration. The inductive effects of CBD on mouse hepatic P450s 2B, 3A, and 2C were determined using cDNA probes, polyclonal antibodies, and specific functional markers. P450 2B10 mRNA was increased markedly after repeated CBD administration and correlated well with increased P450 2B immunoquantified content and functional activity. On the other hand, although the 2-fold increase in P450 3A mRNA detected after repeated CBD administration was consistent with the increased immunoquantified P450 3A protein content, the lack of an observable increase in P450 3A-specific functional activity suggested subsequent inactivation of the induced P450 3A. Repeated CBD treatment increased P450 2C mRNA content 2-fold, but did not increase either the P450 2C immunoquantified content or its functional activity. The effect of CBD treatment on the ability of tetrahydrocannabinol (THC) to induce P450 2B was also determined. A THC dose that did not induce P450 2B significantly was administered alone or in combination with a CBD dose that markedly inactivated P450s 2C- and 3A but submaximally increased P450 2B functional activity. The combination of THC and CBD did not increase P450 2B-catalyzed activity significantly over that observed after CBD treatment alone. Thus, prior CBD-mediated P450 inactivation does not appear to increase the ability of THC to induce P450 2B. To further characterize the relationship between P450 inactivation and induction, several structurally diverse CBD analogs with varying P450 inactivating potentials were tested for their ability to induce P450 2B. At least one CBD analog that is an effective P450 inactivator failed to induce P450 2B, while at least one CBD analog that is incapable of inactivating P450 was found to be a very good P450 2B inducer. It therefore appears that inherent structural features of the CBD molecule rather than its ability to inactivate P450 determine P450 2B inducibility. The complex effects of CBD treatment on P450 inactivation and induction have the potential to influence the pharmacological action of many clinically important drugs known to be metabolized by these various P450s. The mechanism of CBD-mediated P450 induction remains to be elucidated but does not appear to be related to CBD-mediated P450 inactivation.

Selective inhibitors of cytochromes P450

The balance between detoxification and bioactivation of a compound in a particular species or organ is highly dependent on the relative amounts and activities of the different forms of cytochrome P450 (P450) that are expressed. Therefore, knowledge of the catalytic specificities and regulation of individual P450 forms is of paramount importance in predicting and/or rationalizing species, strain, and individual differences in xenobiotic metabolism as well as metabolic interactions between compounds, both endogenous and exogenous. The emergence in recent years of a battery of isoform-selective chemical inhibitors that can be used in vitro and in vivo in experimental animals and humans has greatly facilitated the identification of individual cytochromes P450 responsible for specific bioactivation and detoxification reactions. Many of these inhibitors are mechanism-based and owe their selectivity to metabolism by the target enzyme. Such compounds have also proven valuable as probes of the catalytic mechanism of cytochromes P450, for identifying amino acid residues of importance for the various functions of the enzyme, for assessing the physiological roles of P450-derived oxidation products of endogenous compounds, in chemical-induced models of acute hepatic porphyria, and for studying protein turnover. The identification of isoform-selective, nontoxic inhibitors of individual human cytochromes P450 raises the real possibility of modulation of human drug metabolism for therapeutic purposes.

The effect of cannabidiol on mouse hepatic microsomal cytochrome P450-dependent anandamide metabolism

Anandamide (arachidonylethanolamide) has been identified as a brain constituent that selectively binds to the cannabinoid receptor and possesses cannabimimetic activity. Cytochromes P450 catalyze the oxidation of arachidonic acid to several metabolites possessing very potent pharmacological activity. We examined whether P450 would also metabolize anandamide, and whether cannabidiol (a cannabinoid which inactivates several P450s) would affect this metabolism. Mouse hepatic P450s were found to metabolize anandamide to at least 10 different metabolites, four of which were characterized by mass spectrometry. Cannabidiol selectively inhibited the formation of two of these four anandamide metabolites. The significance of anandamide metabolism remains to be explored.

Cyclosporine metabolism by rat liver microsomes. Evidence for involvement of enzyme(s) other than cytochromes P-450 3A

Cyclosporine (CyA) metabolism was investigated in liver microsomes obtained from untreated male and female Sprague-Dawley rats, and rats pretreated with ethinyl estradiol (EE), dexamethasone (DX), and phenobarbital (PB). Total hepatic microsomal cytochrome P-450 content of DX- and PB-treated male and female rats was significantly higher than that of their respective control or EE-treated rats. However, CyA metabolism was significantly increased, by all drug pretreatments, both in male and female rats. EE increased (2-5 fold) the formation of AM9 (a hydroxylated metabolite) and AM1c (a cyclized-hydroxylated product) over the CyA concentration range tested (0.2-42 microM). DX and PB significantly increased (2- to 20-fold) all detected metabolites (AM1, another hydroxylated metabolite; AM9; AM4N, an N-demethylated product; and AM1c), especially at high substrate concentrations (above 1.25 microM). Immunoblot analyses revealed that the microsomal P-450 3A2 content was decreased in EE-treated male rats, but markedly induced in those treated with either DX or PB. P-450 3A1 was undetectable in untreated and EE-treated female rats, but greatly induced in DX-treated male and female rats. Examination of P-450 3A activity, using 6 beta-hydroxytestosterone formation as a probe, confirmed the immunoblot results. These studies suggest that enzyme(s), other than P-450s 3A1 and 3A2 also play a significant role in CyA metabolism.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of cannabidiol-mediated cytochrome P450 inactivation

Cannibidiol (CBD) has been shown to impair hepatic drug metabolism in several animal species and to markedly inhibit mouse hepatic microsomal delta 1-tetrahydrocannabinol (THC) metabolism by inactivating specific cytochrome P450s (P450) belonging to the 2C and 3A subfamilies. Elucidation of the mechanism of CBD-mediated P450 inhibition would be clinically very important for predicting its effect on metabolism of THC and the many other clinically important drugs known to be metabolized by P450s 2C and 3A. CBD-mediated inactivation of mouse hepatic microsomal P450s did not decrease hepatic microsomal heme content. However, [14C]CBD was found covalently bound to microsomal protein in an approximately equimolar ratio to P450 loss. Immunoprecipitation of microsomal protein with antibodies raised against either P450 2C or 3A revealed that approximately equal amounts of [14C]-CBD were bound to each of these P450s after CBD-mediated inactivation. Furthermore, this specific P450 binding was equivalent to P450 loss and accounted for nearly all of the microsomal [14C]CBD irreversible binding. Although > 80% of the enzyme activities attributed to P450s 2C and 3A were inactivated by CBD at the anticonvulsant dose of 120 mg/kg, P450 2C was approximately 3-fold more sensitive than P450 3A at the lower CBD doses tested. CBD analogs were synthesized in order to elucidate the chemical pathways for CBD-mediated P450 inactivation in vivo. Oxidations at allylic carbon positions or saturation of either the exocyclic double bond or both double bonds of the terpene moiety did not markedly affect the inhibitory properties of the analogs. Methylation of both phenolic groups of the resorcinol moiety completely blocked the P450-inhibitory properties of this analog, revealing the involvement of a free hydroxyl group in the inactivation process. Rotation of the resorcinol moiety in abnormal-CBD did not impair the inhibitory properties of the analog, suggesting that the position of the hydroxyl group relative to the terpene ring is unimportant. Further studies are required to fully understand the chemical basis of CBD-mediated P450 inactivation.

Cumene hydroperoxide-mediated inactivation of cytochrome P450 2B1. Identification of an active site heme-modified peptide

Cumene hydroperoxide (CuOOH)-mediated inactivation of cytochromes P450 (P450) results in the degradation of their prosthetic heme to products that alkylate the apoprotein. Indirect approaches suggest that this alkylation occurs at the active site. in order to identify the specific apoprotein site(s) alkylated, purified 3H- or 14C-heme-labeled P450 2B1 was incubated with CuOOH and subjected to lysyl endopeptidase-C digestion. Two major peaks (L1 and L2) containing 3H- or 14C-labeled peptides were detected by reverse-phase high pressure liquid chromatography of the digest. L1 contained the highest specific radioactivity and after Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis yielded 3 peptide bands (M(r) approximately 3,500 (P1), 5,000 (P2), and 7,000 (P3)). Although all 3 bands were found radiolabeled, the yield of P1 was higher than that of P2 or P3. Amino acid sequence analysis of the first 13 N-terminal residues of P1 revealed the sequence RICLGEGIARNEL, corresponding to residues 434-446 of the reported 2B1 sequence. A species with the molecular mass of 3771 +/- 1 Da was detected in preliminary electrospray mass spectrometric analysis of L1. Since the theoretical average mass of the predicted peptide (residues 434-466) is 3721.99 Da, the additional 49 +/- 1 Da are considered to be contributed by the alkylating heme fragment. This alkylated 2B1 sequence contains not only Cys436, the conserved residue that provides the SH ligand for heme, but also other highly conserved residues, and therefore corresponds to the heme-sandwiching helix L of P450cam. To our knowledge, this is the first report to localize CuOOH-induced heme alkylation of 2B1 to its active site.

Matrix-assisted laser desorption mass spectrometry of cytochromes P450

Matrix-assisted laser desorption ionization on a time-of-flight (MALDI/TOF) mass spectrometer provides a rapid and accurate method for molecular weight determination of hydrophobic cytochrome P450 proteins (P450s). A mass accuracy of 0.075% was achieved by analysis of dialyzed P450 2B1 using bovine serum albumin (BSA) as an internal standard. The measured mass of cytochrome P450 2B2 with MALDI/TOF resulted in an average molecular weight which was higher than reported values. Immobilization procedures proved extremely effective on samples containing high concentrations of phosphate buffers.

Degradation of rat liver cytochromes P450 3A after their inactivation by 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine: characterization of the proteolytic system

The suicide substrate 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4- dihydropyridine (DDEP) inactivates rat liver cytochrome P450 (P450) 3A isozymes through prosthetic heme alkylation of the apoprotein in a mechanism-based fashion, which marks them for rapid proteolysis. In this article, through the use of epitope-specific monoclonal antibodies, we show that both 3A1 and 3A2 isozymes are targeted for proteolysis. Furthermore, using intact rats, isolated rat hepatocytes, and rat liver subcellular fractions supplemented with ATP and MgCl2, as well as various proteolytic inhibitors as probes, we now report that the hepatic cytosolic ubiquitin-dependent proteolytic system rather than hepatic lysosomes is involved in the rapid degradation of DDEP-induced heme alkylated P450s 3A.

Differential apoprotein loss of rat liver cytochromes P450 after their inactivation by 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine: a case for distinct proteolytic mechanisms?

Suicide inactivation of hepatic cytochrome P450 (P450) enzymes 2C11, 2C6, and 3A1/A2 by 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine (DDEP) in intact rats results in prosthetic heme destruction, albeit by apparently distinct mechanisms. Such heme destruction is now shown to be associated with the loss of immunochemically detectable apoprotein of P450s 2C11 and 3A but with little of that of P450 2C6, in spite of their comparable DDEP-mediated functional inactivation. The loss of a approximately 50-kDa hepatic microsomal protein band along with the immunoreactive P450 3A loss strengthens the concept that such an in vivo loss indeed reflects proteolysis of the DDEP-inactivated P450. Furthermore, this propensity of DDEP-inactivated P450s 3A for proteolysis appears to correlate with the relative degree of prosthetic heme alkylation of their apoprotein rather than their functional inactivation per se. Thus, rapid degradation of apoP450s 3A was seen after DDEP treatment, which promoted extensive irreversible heme binding to apoP450s 3A, but not after exposure to allylisopropylacetamide (AIA), which inactivates these isozymes comparably, but induced minimal apoP450 3A heme alkylation. In addition, differences were observed in the relative sensitivities of proteolysis of DDEP-inactivated P450s 2C11 and 3A to hemin, which largely prevented the DDEP-induced proteolytic loss of P450 2C11 but apparently failed to prevent the loss of DDEP-inactivated P450s 3A, when coadministered with DDEP. This differential hemin sensitivity of the proteolysis of DDEP-inactivated P450 2C11, coupled with the observation that immunochemically detectable P450 2C11 loss occurs after its inactivation by both AIA and DDEP, provides compelling support for the existence of distinct proteolytic pathways for individual suicidally inactivated P450s.

Specifically designed thiosteroids as active-site-directed probes for functional dissection of rat liver cytochrome P450 3A isozymes

Testosterone (T) 6 beta-hydroxylase (6 beta-OHase) is a well-recognized functional marker of rat liver cytochrome P450 3A (P450 3A) isozymes. Pretreatment of rats with inducers or specific or nonspecific inhibitors of P450 3A isozymes is associated not only with stimulation or inhibition of hepatic microsomal T 6 beta-OHase activity but also with parallel changes in the corresponding T 2 beta-, 15 beta-, and 18-OHase activities and T 4,6-diene formation. At the time these studies were conducted, no fully functionally active rat hepatic P450 3A isozymes had been isolated. To determine whether each of these activities was due to a single P450 3A isozyme, or whether multiple isozymes contributed to these activities, we specifically synthesized two thiotestosterone (6 beta- and 2 beta-SHT) analogues as potential mechanism-based inactivators of rat liver T 6 beta- and 2 beta-OHases. In addition, to assess their relative stereoselectivity, 2 alpha-SHT was also included as a control. Our studies revealed that although all three thiosteroids were excellent suicide substrates of P450 3A isozymes, they inactivated these T OHases differentially. Such differential inactivation and determination of the kinetic parameters of inactivation allowed the functional classification of rat hepatic P450 3A isozymes into at least two and possibly three categories: (i) forms (catalyzing 4,6-diene and 6 beta-OHT formation but with characteristically low 6 beta/2 beta-OHase ratios) highly susceptible to inactivation by SHTs; (ii) forms (catalyzing T 6 beta-, 2 beta-, 15 beta-, and 18-hydroxylations with high 6 beta-/2 beta-OHase ratios) moderately susceptible to the SHTs; and (iii) forms somewhat resistant to inactivation, at least at the SHT concentrations tested. Although no specific T OHase could be ascribed to a single P450 3A isozyme, it appears that each of these P450s catalyzed such T regiohydroxylations, albeit at considerably different extents. Furthermore, our studies also revealed that 2 alpha-SHT preferentially inactivated P450 3A forms but surprisingly failed to inactivate rat hepatic P450 2C11, thereby confirming the rather high substrate promiscuity of the P450 3A family of isozymes.

Formation of glutathionyl-spironolactone disulfide by rat liver cytochromes P450 or hog liver flavin-containing monooxygenases: a functional probe of two-electron oxidations of the thiosteroid?

We have previously reported that the diuretic thiosteroid spironolactone (SPL) inactivates rat liver microsomal cytochromes P450 [P450 (P450 3A and P450 2C11)] in a in a mechanism-based fashion, and we have identified two polar SPL metabolites (SPL-sulfinic acid and -sulfonic acid), formed in a partition ratio of approximately 20:1 in such rat liver microsomal incubations [Decker et al. (1989) Biochemistry 28, 5128-5136]. We proposed at the time that these metabolites were most likely derived from further enzymatic (or nonenzymatic) oxidations of the one-electron oxidation product [SPL-thiyl radical (SPL-S.)] and/or the two-electron-oxidized species [SPL-sulfenic acid (SPL-SOH)]. In those studies, glutathione (GSH) was found to attenuate both SPL-mediated P450 loss as well as polar metabolite formation by approximately 40%. We have now reexamined this in greater detail and report that it is due to GSH trapping of an electrophilic oxidized SPL species to form an adduct that we have isolated and unambiguously characterized by mass spectral analyses as the glutathionyl-SPL adduct (SPL-SSG). Moreover, we have found not only that rat liver microsomal formation of this adduct is enhanced at pH 9.0, the pH optimum for flavin-containing monooxygenase (FMO), but also that such adduct formation was indeed efficiently catalyzed by purified hog liver FMO. Because FMO oxidations of thiols are thought to entail a two-electron process to form the corresponding sulfenic acids, we infer that such a SPL-SSG adduct most likely reflects FMO-catalyzed oxidation of SPL to SPL-SOH, which on leaving the FMO active site is then trapped by GSH.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of the major hepatic cannabinoid hydroxylase in the mouse: a possible member of the cytochrome P-450IIC subfamily

Acute cannabidiol treatment of mice inactivated hepatic microsomal cytochrome P-450IIIA (P-450IIIA) and markedly inhibited in vitro cannabinoid metabolism. Antibodies raised against purified P-450IIIA inhibited the microsomal formation of quantitatively minor cannabinoid metabolites but had no effect on the major metabolites. Cannabinoid hydroxylation to the major metabolites was used as a functional probe to isolate and purify a P-450 (termed P-450THC) from hepatic microsomes of untreated mice. The purified protein had an apparent molecular weight of 47,000 and a specific content of 15.4 nmol/mg and exhibited an absorbance maximum at 452 nm for the reduced carbon monoxide complex. NH2-terminal sequence analysis of the first 16 residues of P-450THC suggests that it is a member of the P-450IIC subfamily, because its sequence is 85 and 69% identical to published sequences of rat hepatic P-450IIC7 and P-450IIC6, respectively. P-450THC exhibited high activity for cannabinoid hydroxylation and specifically produced 6 alpha- and 7-hydroxy-delta 1-tetrahydrocannabinol, as well as 6 alpha-, 7-, and 4"-hydroxycannabidiol. Unlike anti-P-450IIIA antibody, antibody raised against purified P-450THC markedly inhibited the microsomal formation of all major cannabinoid metabolites. Similar immunoinhibition studies also revealed the existence of orthologs of mouse P-450THC and P-450IIIA in human liver microsomes. Thus, cannabidiol treatment of mice resulted in the inactivation of at least two constitutive P-450 isozymes, which together account for the majority of the detected cannabinoid metabolites.

Selective inactivation of mouse liver cytochrome P-450IIIA by cannabidiol

Cannabidiol (CBD) inhibits hepatic drug metabolism in mice, particularly those activities known to be catalyzed by the cytochrome P-450IIIA (P-450IIIA) subfamily. CBD treatment (120 mg/kg) inhibited more than 75% of hepatic 6 beta-testosterone hydroxylase and erythromycin N-demethylase activities (functional markers of P-450IIIA) after 2 hr. An isozyme of the P-450IIIA subfamily (Mr 49,960) was purified to apparent homogeneity from hepatic microsomes of untreated mice and was found to catalyze testosterone hydroxylation at the 2 beta-, 6 beta-, and 15 beta-positions exclusively. Incubation of this isozyme with CBD in a reconstituted system resulted in a time- and concentration-dependent inactivation, with almost complete loss of P-450 chromophore and corresponding increase in P-420 content. NH2-terminal sequence analysis of the isozyme revealed an 86% similarity to the corresponding sequence of rat P-450IIIA2, a constitutive P-450 isozyme in the male rat liver. Pretreatment of mice with dexamethasone markedly (6-fold) increased the steroid-inducible P-450IIIA-dependent activities 6 beta-testosterone hydroxylation and erythromycin N-demethylation. CBD treatment of dexamethasone-pretreated animals failed to inhibit these activities, indicating that the steroid-inducible P-450IIIA was refractory to CBD-mediated inactivation. 3-Methylcholanthrene-inducible P-450IA and phenobarbital-inducible P-450IIB also appear to be refractory to CBD-mediated inactivation. On the other hand, erythromycin N-demethylase activity increased 4-fold after phenobarbital pretreatment and, as in untreated animals, was comparably inhibited by CBD, demonstrating its susceptibility to this drug. Thus, CBD appears to inactivate the P-450IIIA isozymes that are constitutively present in hepatic microsomes of untreated mice and/or inducible by phenobarbital pretreatment but not those that are steroid inducible.

Inactivation of rat hepatic cytochrome P-450 isozymes by 3,5-dicarbethoxy- 2,6-dimethyl-4-ethyl-1,4-dihydropyridine

We have reported [Correia et al. (1987) Arch. Biochem. Biophys. 258, 436-443] that administration of 3,5-dicarbethoxy-4-ethyl-2,6-dimethyl-1,4-dihydropyridine (DDEP) to untreated, phenobarbital (PB) pretreated, or dexamethasone (DEX) pretreated rats results in relatively selective inactivation of cytochrome P-450 (P-450) isozymes h (CYP2C11), k (CYP2C6), and p (CYP3A). Such inactivation involves destruction of P-450 prosthetic heme predominantly by N-ethylation in untreated and PB-pretreated rats, whereas in DEX-pretreated rats, it also appears to be associated with prosthetic heme alkylation of the apocytochrome presumably at the active site. The cause for this differential course of DDEP-mediated P-450 heme destruction is unclear. Since this process is absolutely dependent on NADPH-mediated DDEP metabolism and can be reproduced in vitro, in search of mechanistic clues, we have examined DDEP metabolism by liver microsomes from the three rat sources as well as by isolated purified rat liver P-450h and P-450k. HPLC analyses of microsomal incubations of DDEP with NADPH, in the presence of an esterase inhibitor, revealed the presence of two major products: deethylated pyridine (DP) and 4-ethylpyridine (4-EDP) with product ratios (DP/4-EDP) of 1.4, 1.4, and 0.7 for reactions catalyzed by liver microsomes from untreated, PB-pretreated, and DEX-pretreated rats, respectively. The corresponding mean product ratios for P-450h- and P-450k-catalyzed reactions were 4.2 and 5.5, respectively. On the other hand, partition ratios (DP formed/P-450 destroyed) ranged from 12.0, 10.5, and 4.8, respectively, for incubations of liver microsomes from untreated, PB-pretreated, and DEX-pretreated rats to 9.5 and 28.9 for purified P-450h- and P-450k-catalyzed reactions, respectively. However, DP formation in all these microsomal systems was comparable, and although 4-EDP formation was greatly stimulated by DEX pretreatment, it does not appear to be a destructive pathway. In view of this, our findings reported herein suggest that the active site environment of P-450's h, k, and p apparently determines not only the pattern of DDEP metabolism but also the differential course of prosthetic heme destruction.

Purification and characterization of a mouse liver cytochrome P-450 induced by cannabidiol

A cytochrome P-450 isozyme (Mr = 51,600) was purified to apparent homogeneity from hepatic microsomes of mice pretreated with cannabidiol (CBD), a major constituent of marijuana. The isozyme exhibited high pentoxyresorufin O-dealkylase, hexobarbital hydroxylase, and 16 alpha- and 16 beta-testosterone hydroxylase activities and formed a Fe+2-metyrapone complex, properties characteristic of the major hepatic cytochrome P-450s previously purified from phenobarbital (PB)-pretreated animals. In addition, the CBD-induced cytochrome P-450 was immunoreactive with an antibody raised against the major rat hepatic PB-inducible cytochrome P-450 and exhibited an NH2-terminal amino acid sequence greater than 90% homologous with that of the PB-inducible rat liver isozyme. Because of the many similarities between the CBD-induced isozyme and certain other isozymes previously purified from PB-pretreated animals, a cytochrome P-450 isozyme was purified from PB-pretreated mice by a chromatographic procedure similar to that employed for purification of the CBD-induced isozyme. The PB-inducible isozyme was indistinguishable from the CBD-inducible cytochrome P-450 on the bases of apparent molecular weight, absorption spectra, NH2-terminal amino acid sequence, peptide mapping, immunoreactivity, and catalytic activity. Although the CBD- and PB-inducible P-450 isozymes appear to be qualitatively very similar, PB appears to be a quantitatively better inducer of the isozyme. Thus, CBD exposure results in the induction of an isozyme that is refractory to CBD-mediated inactivation, thereby apparently altering the cytochrome P-450 isozymal composition of mouse hepatic microsomes.

Effect of cannabidiol on cytochrome P-450 isozymes

Cannabidiol (CBD) has been shown to inhibit mouse hepatic mixed-function oxidations of several drugs after acute treatment, whereas repetitive treatment resulted in the restoration of drug-metabolizing capabilities. We have found that acute CBD treatment modestly decreased cytochrome P-450 content but markedly decreased hexobarbital hydroxylase, erythromycin N-demethylase, and 6 beta-testosterone hydroxylase activities. Repetitive CBD treatment, on the other hand, resulted in the restoration of cytochrome P-450 content as well as hexobarbital hydroxylase and erythromycin N-demethylase activities. However, after such repeated treatments a fresh dose of CBD can once again inactivate erythromycin N-demethylase activity but not hexobarbital hydroxylase activity. The resistance of hexobarbital hydroxylase to re-inactivation by CBD was paralleled by stimulation of pentoxyresorufin O-dealkylase activity and the appearance of a 50 kD protein that was immunoreactive to an antibody raised against rat hepatic cytochrome P-450b. CBD metabolism in vitro by microsomes prepared from such CBD-"induced" animals, resulted in a pattern of metabolites different from that observed from comparable incubations with liver microsomes from either untreated or phenobarbital-treated animals. Thus, it appears that CBD initially inactivates at least one cytochrome P-450 isozyme, but after repetitive CBD treatment, an isozyme is induced that is resistant to further re-inactivation by CBD. This isozyme appears to be immunochemically similar to, but somewhat functionally distinct from, the isozyme induced by phenobarbital treatment in mice.

Oxidative metabolism of spironolactone: evidence for the involvement of electrophilic thiosteroid species in drug-mediated destruction of rat hepatic cytochrome P450

In a preliminary paper [Decker et al. (1986) Biochem. Biophys. Res. Commun. 136, 1162] we have shown that the antimineralocorticoid spironolactone (SPL) preferentially inactivates dexamethasone (DEX) inducible rat hepatic cytochrome P450p isozymes in a suicidal manner. These findings are now confirmed, and the kinetic characteristics of such a process are detailed. In an effort to elucidate the mechanism of SPL-mediated inactivation of cytochrome P450, we have examined the metabolism of SPL in vitro. Incubation of [14C]SPL and NADPH with liver microsomes prepared from DEX-pretreated rats results in the formation of several polar metabolites separable by HPLC with UV detection. This process is found to be dependent on NADPH, O2, SPL, and enzyme concentration, as well as temperature. Furthermore, metabolite formation was significantly attenuated by P450 inhibitors CO and n-octylamine. Mass spectral analysis (thermospray LC/MS, FAB/MS, and FAB/MS/MS) of the two most prominent polar metabolites indicated that these compounds had molecular weights that corresponded to the sulfinic and sulfonic acid derivatives of deacetyl-SPL (SPL-SH). These findings document the formation of previously unreported polar metabolites of SPL by rat liver microsomes enriched in cytochrome P450p and implicate a role for this isozyme in the oxidation of the thiol moiety of deacetyl-SPL. The detection of such metabolites also implicates a catalytic trajectory that includes the thiyl radical and/or sulfenic acid species as a plausible protagonist in drug-mediated inactivation of cytochrome P450p.

Secobarbital-mediated inactivation of rat liver cytochrome P-450b: a mechanistic reappraisal

Administration of the allylbarbiturate secobarbital (SB) to phenobarbital-pretreated rats is known to result in structural and functional loss of hepatic cytochrome P-450 and generation of N-alkylated prosthetic heme derivatives. Isozyme-selective functional markers have led us to confirm P-450b as the isozyme selectively inactivated by the drug. In contrast to its inactivation by allylisopropylacetamide, such SB-inactivated P-450b is not amenable to structural and functional repair by exogenous heme, for reasons that remain unclear. In an effort to gain some insight, we have explored various possible mechanisms. In the course of these studies with rat liver microsomes enriched in P-450b as well as isolated purified P-450b, we have found that, along with prosthetic heme alkylation, a significant fraction of the hemoprotein also undergoes drug-mediated alkylation of the apocytochrome, presumably at the active site. Accordingly, an equimolar ratio of irreversibly bound drug to functionally inactive residual P-450b chromophore is observed after incubation of the purified isozyme with SB and NADPH. Thus, P-450b-mediated oxidative metabolism of SB appears to partition not only between prosthetic heme alkylation and epoxidation but apoprotein alkylation as well.

Role of gastrin/pentagastrin in regulation of intestinal cytochrome P-450

1. In the absence of intraluminal inducers, low "basal" levels of cytochrome P-450 and its dependent MFO activities are detected in the rat intestinal mucosa, and may be regulated by endogenous hormones. 2. Rats were nutritionally maintained by either short term (48 hr) intravenous glucose infusion or chronic (8 days) intravenous hyperalimentation, and were treated with various doses of pentagastrin in the infusate. 3. Regardless of the dose (6-90 micrograms/kg/hr) or duration of infusion (2-8 days), pentagastrin had no effect on small intestinal cytochrome P-450, its dependent MFO activity, or the activity of delta-aminolevulinic acid synthetase. 4. The intestinal trophic peptide hormone, gastrin, apparently does not regulate the cytochrome P-450-dependent MFO system of the small intestine.

Drug-induced modulations of hepatic heme metabolism. Neurological consequences

Administration of the porphyrinogenic agent DDEP to PB-pretreated rats results in acute hepatic heme depletion, which is a characteristic of acute hepatic porphyria. Such acute heme depletion is associated with impaired hepatic tryptophan degradation and enhanced serotonergic tone in the CNS. We showed that intestinal motility in these rats is also significantly decreased, indicating that the serotonergic tone of the enteric nervous system may also be enhanced. In addition, the marked hepatic accumulation of glucogenic precursors, observed in parallel, indicates that the elevated tryptophan levels may also block hepatic glucogenesis. The clinical implications of these findings to acute heme-deficient states, such as the acute hepatic porphyrias, was discussed.

Degradation of rat hepatic cytochrome P-450 heme by 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine to irreversibly bound protein adducts

Administration of 3,5-dicarbethoxy-2,6-dimethyl-4-ethyl-1,4-dihydropyridine (DDEP) (a structural analog of the dihydropyridine Ca2+ antagonists) to untreated, phenobarbital-, or dexamethasone-pretreated rats results in time-dependent losses of hepatic cytochrome P-450 content. Functional markers for various cytochrome P-450 isozymes have permitted the identification of P-450h, P-450 PB-1/k, and P-450p as the isozymes inactivated preferentially by the drug. DDEP-mediated cytochrome P-450 destruction may be reproduced in vitro, is most prominent after pretreatment of rats with dexamethasone, pregnenolone 16 alpha-carbonitrile or phenobarbital, and is blocked by triacetyloleandomycin. These findings together with the observation that DDEP markedly inactivates hepatic 2 beta- and 6 beta-testosterone hydroxylase and erythromycin N-demethylase tend to indict the steroid-inducible P-450p isozyme as a key protagonist in this event. The precise mechanism of such DDEP-mediated P-450p heme destruction is unclear, but involves prosthetic heme alkylation of the apocytochrome at its active site in what appears to be a novel mechanism-based "suicide" inactivation. Such inactivation appears to involve fragmentation of the heme to reactive metabolites that irreversibly bind to the protein, but the chemical structure of the heme-protein adducts is yet to be established. Intriguingly, such DDEP-mediated P-450p destruction in vivo also results in accelerated loss of immunochemically detectable apocytochrome P-450p. It remains to be determined whether or not this loss is due to enhanced proteolysis triggered by the structural modification of the apocytochrome.

Inactivation of multiple hepatic cytochrome P-450 isozymes in rats by allylisopropylacetamide: mechanistic implications

In vivo administration of the porphyrogenic agent allylisopropylacetamide (AIA) to phenobarbital-pretreated rats results in marked loss of hepatic cytochrome P-450 content. Using isozyme-selective functional markers, we now show that such loss reflects inactivation of several phenobarbital-inducible and constitutive isozymes. Some of the isozymes (P-450a,b,h and PB-1) are largely reparable by reconstitution with exogenous hemin, indicating that after AIA-mediated loss of their prosthetic heme, their apoprotein moieties are essentially intact and functionally reconstitutable with hemin. On the other hand, after AIA-mediated inactivation, isozymes such as cytochrome P-450p remain refractory to such repair. The cause for such intractability remains somewhat elusive since AIA-mediated alkylation of the apocytochrome, proteolytic loss of the hemoprotein, or even irreversible binding of prosthetic heme catabolites to the apocytochrome does not appear to be responsible.

Fractionation and purification of hepatic microsomal cytochrome P-450 isoenzymes from phenobarbital-pretreated rats by h.p.l.c. A convenient tool for screening of isoenzymes inactivated by allylisopropylacetamide

A procedure incorporating the salient features of ion-exchange column chromatography with ion-exchange h.p.l.c. is described for the fractionation and purification to homogeneity of several membrane-bound rat hepatic phenobarbital (PB)-inducible cytochrome P-450 isoenzymes, including the major PB-inducible species. The resolving power of this technique makes it a highly promising tool for the isolation and purification of closely related cytochrome P-450 isoenzymes. In addition, it may also be used for screening of individual isoenzymes either selectively induced or repressed by a variety of endobiotics or xenobiotics. Accordingly, we have exploited this particular feature to identify not only the PB-inducible cytochrome P-450 isoenzymes destroyed in vivo by allylisopropylacetamide, a suicide inactivator of cytochrome P-450, but also to distinguish those that are reparable by exogenous haemin from those that are irreparably damaged.

Incorporation of haemoglobin haem into the rat hepatic haemoproteins tryptophan pyrrolase and cytochrome P-450

After its administration to intact rats, haemoglobin haem was incorporated into hepatic tryptophan pyrrolase as shown by the marked increase in functional constitution of this enzyme. Incorporation of haemoglobin haem into cytochrome P-450 was demonstrated in intact rats and in the isolated rat liver perfused with haemoglobin-free medium. In both systems, haemoglobin haem restored cytochrome P-450 content and its dependent mixed-function-oxidase activity after substrate-induced destruction of the cytochrome P-450 haem moiety. Further confirmation that haemoglobin haem could be incorporated prosthetically into cytochrome P-450 was achieved by administration of [3H]haemoglobin to rats and subsequent isolation and characterization of radiolabelled substrate-alkylated products of cytochrome P-450 haem. Our findings indicate that, although hepatic uptake of parenteral haemoglobin is slower than that of haem, it appears to serve as an effective haem donor to the intrahepatic 'free' haem pool. Thus parenteral haemoglobin may warrant consideration as a therapeutic alternative to haem in the acute hepatic porphyrias.