Verapamil hepatic clearance in four preclinical rat models: towards activity-based scaling.

The current study was designed to cross-validate rat liver microsomes (RLM), suspended rat hepatocytes (SRH) and the isolated perfused rat liver (IPRL) model against in vivo pharmacokinetic data, using verapamil as a model drug. Michaelis-Menten constants (Km), for the metabolic disappearance kinetics of verapamil in RLM and SRH (freshly isolated and cryopreserved), were determined and corrected for non-specific binding. The 'unbound' Km determined with RLM (2.8 µM) was divided by the 'unbound' Km determined with fresh and cryopreserved SRH (3.9 µM and 2.1 µM, respectively) to calculate the ratio of intracellular to extracellular unbound concentration (Kpu,u). Kpu,u was significantly different between freshly isolated (0.71) and cryopreserved (1.31) SRH, but intracellular capacity for verapamil metabolism was maintained after cryopreservation (200 vs. 191 µl/min/million cells). Direct comparison of intrinsic clearance values (Clint) in RLM versus SRH, yielded an activity-based scaling factor (SF) of 0.28-0.30 mg microsomal protein/million cells (MPPMC). Merging the IPRL-derived Clint with the MPPMC and SRH data, resulted in scaling factors for MPPGL (80 and 43 mg microsomal protein/g liver) and HPGL (269 and 153 million cells/g liver), respectively. Likewise, the hepatic blood flow (61 ml/min/kg b.wt) was calculated using IPRL Clint and the in vivo Cl. The scaling factors determined here are consistent with previously reported CYP450-content based scaling factors. Overall, the results show that integrated interpretation of data obtained with multiple preclinical tools (i.e. RLM, SRH, IPRL) can contribute to more reliable estimates for scaling factors and ultimately to improved in vivo clearance predictions based on in vitro experimentation.

A mouse model for Zellweger syndrome.

The cerebro-hepato-renal syndrome of Zellweger is a fatal inherited disease caused by deficient import of peroxisomal matrix proteins. The pathogenic mechanisms leading to extreme hypotonia, severe mental retardation and early death are unknown. We generated a Zellweger animal model through inactivation of the murine Pxr1 gene (formally known as Pex5) that encodes the import receptor for most peroxisomal matrix proteins. Pxr1-/- mice lacked morphologically identifiable peroxisomes and exhibited the typical biochemical abnormalities of Zellweger patients. They displayed intrauterine growth retardation, were severely hypotonic at birth and died within 72 hours. Analysis of the neocortex revealed impaired neuronal migration and maturation and extensive apoptotic death of neurons.

Identification of a novel PEX14 mutation in Zellweger syndrome.

BACKGROUND: Peroxisome biogenesis disorders are a clinically and genetically heterogeneous group of very severe autosomal recessive disorders caused by impaired peroxisome biogenesis. The prototype of this group of disorders is the cerebro-hepato-renal syndrome of Zellweger. METHODS AND RESULTS: Here we report a patient with Zellweger syndrome, who presented at the age of 3 months with icterus, dystrophy, axial hypotonia, facial dysmorphy, posterior embryotoxon, and hepatomegaly. Abnormal findings of metabolic screening tests included hyperbilirubinaemia, hypoketotic dicarboxylic aciduria, increased C(26:0) and decreased C(22:0) plasma levels, and strongly reduced plasmalogen concentrations. In fibroblasts, both peroxisomal alpha- and beta-oxidation were impaired. Liver histology revealed bile duct paucity, cholestasis, arterial hyperplasia, very small branches of the vena portae, and parenchymatic destruction. Immunocytochemical analysis of cultured fibroblasts demonstrated that the cells contain peroxisomal remnants lacking apparent matrix protein content and PEX14, a central membrane component of the peroxisomal matrix protein import machinery. Transfection of fibroblasts with a plasmid coding for wild-type PEX14 restored peroxisomal matrix protein import, indicating that the primary genetic defect affecting the patient is indeed linked to PEX14. Mutational analysis of this gene revealed a genomic deletion leading to the deletion of exon 3 from the coding DNA (c.85-?_170+?del) and a concomitant change of the reading frame (p.[Ile29_Lys56del;Gly57GlyfsX2]). CONCLUSIONS: This report represents the second PEX14-deficiency associated with Zellweger syndrome and the first documentation of a PEX14-deficient patient with detailed clinical follow-up and biochemical, morphological, and radiological data.

Human pex19p binds peroxisomal integral membrane proteins at regions distinct from their sorting sequences.

The molecular machinery underlying peroxisomal membrane biogenesis is not well understood. The observation that cells deficient in the peroxins Pex3p, Pex16p, and Pex19p lack peroxisomal membrane structures suggests that these molecules are involved in the initial stages of peroxisomal membrane formation. Pex19p, a predominantly cytosolic protein that can be farnesylated, binds multiple peroxisomal integral membrane proteins, and it has been suggested that it functions as a soluble receptor for the targeting of peroxisomal membrane proteins (PMPs) to the peroxisome. An alternative view proposes that Pex19p functions as a chaperone at the peroxisomal membrane. Here, we show that the peroxisomal sorting determinants and the Pex19p-binding domains of a number of PMPs are distinct entities. In addition, we extend the list of peroxins with which human Pex19p interacts to include the PMP Pex16p and show that Pex19p's CaaX prenylation motif is an important determinant in the affinity of Pex19p for Pex10p, Pex11pbeta, Pex12p, and Pex13p.

Effect of harvesting methods, growth conditions and growth phase on diacylglycerol levels in cultured human adherent cells.

The cellular mass of sn-1,2-diacylglycerols, which are intracellular second messengers which activate protein kinase C, were quantitatively determined with an enzymatic assay. The method employed to harvest cultured human skin fibroblasts or human epidermal A431 cells prior to extraction of lipid into chloroform/methanol affected diacylglycerol (DAG) levels. Scraping or trypsinization significantly increased DAG levels. A method was devised to allow reliable and reproducible DAG measurements from adherent cells. The addition of methanol prior to scraping was shown to stop cellular metabolism and to permit accurate quantitation. Importantly, this solvent was compatible with cultures grown on plastic. Using this method, growth conditions which could affect DAG levels were investigated. Changes in the osmolality of the culture medium did not affect the DAG levels of A431 cells; exposure of A431 cells to acidic pH or elevated temperature lowered DAG levels. In contrast to fibroblasts, the total DAG levels of A431 cells continued to increase during serum deprivation. The highest DAG levels, normalized to phospholipids, were observed during the exponential growth phase. This ratio dropped when the cultures reached confluency. These experiments also demonstrated that A431 cells possess higher DAG levels than do normal fibroblasts. The function of DAG in cellular regulation is discussed.

Evidence for the importance of iron in the alpha-oxidation of 3-methyl-substituted fatty acids in the intact cell.

Preincubation of isolated rat hepatocytes with desferrioxamine or o-phenanthroline, two iron-specific chelators, strongly suppressed the CO2-production from the alpha-oxidation of 3-methylmargaric acid, whereas the beta-oxidation of 2-methylpalmitic acid, palmitic acid, trihydroxycoprostanic acid and the conversion of formic acid to CO2 were not affected. When, after the initial preincubation with the chelators and prior to the addition of 3-methylmargaric acid, iron-saturated transferrin and Fe3+ were added, a partial restitution of the CO2-production rates was obtained. These facts provide further evidence for the importance of iron in the alpha-oxidation of 3-methyl-substituted fatty acids.

D-aspartate oxidase, a peroxisomal enzyme in liver of rat and man.

By means of subcellular fractionation D-aspartate oxidase was shown to be localized in peroxisomes in rat and human liver. The oxidase from both sources was most active on D-aspartate and N-methyl-D-aspartate. In different rat tissues, the highest enzyme activity was found in kidney, followed by liver and brain. In these tissues, oxidase activities became detectable 1-4 days after birth, reaching adult values after 4 weeks. Analysis of liver samples from patients with Zellweger syndrome, a generalized peroxisomal dysfunction, demonstrated no significant deficiency of this particular oxidase.

Presence of small GTP-binding proteins in the peroxisomal membrane.

Highly purified peroxisomal membranes stripped from their peripheral membrane proteins and only minimally contaminated with other membranes, contained three GTP-binding proteins of 29, 27 and 25 kDa, respectively. Bound radioactive GTP was displaced by unlabelled GTP, GTP analogs and GDP but not by GMP or other nucleotides. GTP binding was markedly decreased by trypsin treatment of intact purified peroxisomes; it increased 2-3-fold after pretreatment of the animals with a peroxisome proliferator. We conclude that the peroxisomal membrane contains small GTP-binding proteins that are exposed to the cytosol and that are firmly anchored in the membrane. We speculate that these proteins are involved in peroxisome multiplication by fission or budding during peroxisome biogenesis and proliferation.

2-methylacyl racemase: a coupled assay based on the use of pristanoyl-CoA oxidase/peroxidase and reinvestigation of its subcellular distribution in rat and human liver.

Because of the 2S-methyl-stereospecificity of the acyl-CoA oxidases acting on the CoA esters of 2-methyl-branched fatty carboxylates such as pristanic acid and the side chain of trihydroxycoprostanic acid (Van Veldhoven P.P., Croes K., Asselberghs S., Herdewijn P. and Mannaerts G.P. (1996) FEBS Lett. 388, 80-84), naturally occurring 2R-pristanic acid and 25R- (corresponding to 2R in the side chain) trihydroxycoprostanic acid, after activation to their CoA-esters, need to be racemized to the S-isomers before they can be degraded by peroxisomal beta-oxidation. A coupled assay to measure 2-methyl-acyl racemases was developed by using purified rat pristanoyl-CoA oxidase. Upon incubation of rat and human liver homogenates with 2R-methyl-pentadecanoyl-CoA, the formed 2S-methyl isomer was desaturated by an excess of added oxidase and the concomitant production of hydrogen peroxide was monitored by means of peroxidase in the presence of a suitable hydrogen donor. Application of this assay to subcellular fractions of rat liver revealed the presence of racemase activity not only in mitochondria, as described by Schmitz W., Albers C., Fingerhut R. and Conzelmann E. (Eur. J. Biochem. (1995) 231, 815-822), but also in peroxisomes and cytosol. A similar distribution was seen in human liver. In rat the highest activities were found in liver, followed by Harderian gland, kidney and intestinal mucosa.

Human long chain, very long chain and medium chain acyl-CoA dehydrogenases are specific for the S-enantiomer of 2- methylpentadecanoyl-CoA.

The acyl-CoA dehydrogenases are a family of mitochondrial flavoenzymes involved in fatty acid and branched chain amino-acid metabolism. Long chain acyl-CoA dehydrogenase (LCAD) and short/branched chain acyl-CoA dehydrogenase (SBCAD) have been shown to have activity towards 2-methyl branched chain acyl-CoA substrates of varying chain lengths. In humans, long chain 2-branched chain fatty acids such as pristanic acid are largely thought to be metabolized in peroxisomes through desaturation of their CoA esters by branched chain acyl-CoA oxidase, but LCAD is also capable of utilizing 2-methyldecanoyl- and 2-methylpalmitoyl-CoA as substrate [1]. Since the acyl-CoA oxidase reaction is specific for the S-enantiomer of the branched chain substrates, we investigated the stereo specificity of mitochondrial LCAD. Purified LCAD had a specific activity of 390 and 340 mU/mg of purified LCAD protein using palmitoyl-CoA and S-2-methylpentadecanoyl-CoA, respectively, as substrate. No activity was measurable with R-2-methylpentadecanoyl-CoA. Purified medium chain acyl-CoA dehydrogenase (MCAD) could also utilize S-2-methylpentadecanoyl-CoA as a substrate, but not R-2-methylpentadecanoyl-CoA. These results indicate that LCAD and MCAD are specific for the S-enantiomers of methylbranched chain substrates. Crude mitochondrial extracts showed no activity when dehydrogenating activity was measured with R/S-2-methylpalmitoyl-CoA or S-2-methylpentadecanoyl-CoA after inactivation of the extract with antibodies to very long chain acyl-CoA dehydrogenase and MCAD, suggesting that this substrate is not useful in identifyig clinical deficiencies of LCAD.

Comparison of the stability and substrate specificity of purified peroxisomal 3-oxoacyl-CoA thiolases A and B from rat liver.

The specific activities and substrate specificities of 3-oxoacyl-CoA thiolase A (thiolase A) purified from normal rat liver peroxisomes and 3-oxoacyl-CoA thiolase B (thiolase B) isolated from livers of rats treated with the peroxisome proliferator clofibrate were virtually identical. The enzymes could be distinguished by their N-terminal amino acid sequences, their isoelectric points and their stability, the latter being higher for thiolase A. Contrary to thiolase B, which showed a marked cold lability in the presence of KCl by dissociating into monomers with poor activity, thiolase A retained its full activity and its homodimeric structure under these conditions.

Subcellular study of sphingoid base phosphorylation in rat tissues: evidence for multiple sphingosine kinases.

The enzymatic phosphorylation of sphingoid bases was analysed in rat tissues, using D-erythro-[4,5-(3)H]sphinganine as substrate. After optimisation of the assay, taking care to block sphingosine-phosphate lyase and sphingosine phosphatase, highest ATP-dependent kinase activities were present in testis, followed by kidney, and intestinal mucosa. Approximately two thirds of the kidney activity were membrane bound, the remaining being cytosolic. Classical cell fractionation studies of kidney and liver did not allow to identify unequivocally the subcellular site of the membrane bound kinase. Separation of a particulate fraction from kidney homogenates by Percoll gradient and sucrose density gradient centrifugation revealed that kinase activities are associated with vesicles derived from the endoplasmic reticulum and the plasma membrane. Based on indirect data, such as the effect of detergents and divalent ions, the cytosolic and both membrane bound activities appear to reside in different proteins. N,N-Dimethylsphingenine was inhibitory to all three different kinases, which were mainly active towards the D-erythro isomers of sphingenine and sphinganine.

Metabolism of dolichol, dolichoic acid and nordolichoic acid in cultured cells.

The uptake and metabolism of [1-(14)C]-labelled dolichol, dolichoic acid and nordolichoic acid were investigated in MDCK and HepG2 cells. Each of the three isoprenoids, bound to human serum albumin, was taken up effectively. None of the compounds was broken down in HepG2 cells, although these converted dolichol into fatty acid esters. In MDCK cells dolichoic acid gave rise to the formation of [14C]CO2 and radiolabelled formic acid, indicating that dolichoic acid can be broken down by alpha-oxidation. Dolichoic acid was also converted to a mixture of polar compounds, possibly polyols. MDCK cells generated radiolabelled CO2 from nordolichoic acid, presumably through beta-oxidation, although we could not find any labelled propionic acid. No oxidative breakdown of dolichol was found, apparently due to the lack of or very low conversion to dolichoic acid.

The human peroxisomal multifunctional protein involved in bile acid synthesis: activity measurement, deficiency in Zellweger syndrome and chromosome mapping.

The dehydrogenation of 24R,25R-varanoyl-CoA, the physiological intermediate formed during the peroxisomal breakdown of the bile acid intermediate trihydroxycoprostanic acid, was studied in human liver. The reaction appeared to be catalyzed by two different enzymes. A first one, present in the cytosol, did not discriminate between the four possible varanoyl-CoA isomers and did not require the CoA moiety. The second enzymic activity was associated with peroxisomes and acted only on the 24R,25R-isomer, in which the 24-hydroxy group possesses the D-configuration. The D-specific dehydrogenase is part of a 79 kDa protein which represents the human counterpart of a recently discovered second multifunctional protein in rat liver peroxisomes, named multifunctional protein 2 (MFP-2). Human MFP-2, like its rat counterpart, is also responsible for the formation (by hydratation) of 24R,25R-varanoyl-CoA. A deficiency of MFP-2 in Zellweger liver could be demonstrated immunologically by using antibodies against the rat enzyme and enzymically -- after removal of the cytosol -- by using 24R,25R-varanoyl-CoA. The gene coding for MFP-2 was mapped to chromosome 5q2.3.

Human sphingosine-1-phosphate lyase: cDNA cloning, functional expression studies and mapping to chromosome 10q22(1).

Sphingosine-1-phosphate lyase catalyzes the last step in sphingolipid breakdown, the cleavage of phosphorylated sphingoid bases such as sphingenine-1-phosphate. The latter lipid is not only a catabolite, but can influence as an inter- and/or intracellular second messenger many cellular processes. To allow for the diagnosis of human disorders that might be linked to a deficient lyase, the human sphingosine-1-phosphate lyase cDNA was cloned. The obtained cDNA encoded a protein of 568 amino acids with a calculated molecular mass of 63492 Da. Hydropathy plots revealed the presence of one membrane span near the amino-terminal which is however not required for enzyme activity since recombinant poly-His-tagged lyase, lacking this membrane span, was functionally active. Site-directed mutagenesis disclosed the importance of the cysteine residues 218 and 317 for the cleavage reaction. Northern analysis showed the presence of rare large-sized mRNAs of 6.7, 5.8 and 4 kb and the highest expression in liver. By fluorescent in situ hybridization, the gene was mapped to chromosome 10q22.

The 80 kDa cytosolic protein that binds the C-terminal part of rat acyl-CoA oxidase is not a peroxisomal import receptor but a prolyl-endopeptidase.

In an attempt to identify putative peroxisomal import receptors, we investigated the cross-linking of a radioiodinated peptide consisting of the 13 last amino acids of acyl-CoA oxidase and comprising the carboxy-terminal SKL-peroxisomal targeting motive, to proteins present in different subcellular fractions from rat liver. The radiolabeled peptide could be cross-linked to an 80 kDa protein present in the cytosol but not to proteins present in other subcellular fractions including highly purified peroxisomes. Binding was reversible, saturable and dependent on the presence of Mg2+ and ATP or GTP but hydrolysis of the nucleotides was not required. Binding was abolished by pretreatment of the cytosol--but not of the peptide--with N-ethylmaleimide. Binding was not specific for peptides containing the carboxy-terminal SKL-motive, since binding was competed for by the SKL-peptide from which the SKL-motive had been deleted, by the SKL-peptide with reversed sequence and by the SV40 T-antigen nuclear localisation signal peptide, but not by other peptides tested. The 80 kDa binding protein cross-reacted with a monoclonal antibody against hsp90. Purification and internal peptide sequencing of the binding protein revealed its identity as prolyl-endopeptidase. In retrospect, we realized that the SKL-peptide and all competing peptides contained a proline residue, which was not present in the non-competing peptides. In recent experiments in yeast McNew et al. (McNew, J.A., Sykes, K. and Goodman, J.M. (1993) Mol. Biol. Cell 4, 223-232) cross-linked a peroxisomal targeting peptide to a 20 kDa cytosolic protein that was identified as proline isomerase despite the fact that the peptide did not contain proline. The experiments by McNew et al. in yeast and our experiments in the rat suggest that the (peroxisomal) targeting sequence cross-linking approach may not be suited for the identification of (peroxisomal) import receptors.

Characterisation of human peroxisomal 2,4-dienoyl-CoA reductase.

Based on the primary structure of the rat peroxisomal 2,4-dienoyl-CoA reductase (M. Fransen, P.P. Van Veldhoven, S. Subramani, Biochem. J. 340 (1999) 561-568), the cDNA of the human counterpart was cloned. It contained an open reading frame of 878 bases encoding a protein of 291 amino acids (calculated molecular mass 30778 Da), being 83% identical to the rat reductase. The gene, encompassing nine exons, is located at chromosome 16p13. Bacterially expressed poly(His)-tagged reductase was active not only towards short and medium chain 2,4-dienoyl-CoAs, but also towards 2,4,7,10,13,16,19-docosaheptaenoyl-CoA. Hence, the reductase does not seem to constitute a rate limiting step in the peroxisomal degradation of docosahexaenoic acid. The reduction of docosaheptaenoyl-CoA, however, was severely decreased in the presence of albumin.

Do sphingoid bases interact with the peroxisome proliferator activated receptor alpha (PPAR-alpha)?

In a search for possible endogenous ligands of nuclear receptors that are activated by peroxisome proliferators (PPARs), a solid phase binding assay was developed employing recombinant mouse PPAR-alpha, containing a myc-epitope, a histidine repeat and a kinase A domain. After in vitro labelling with 32P-gamma-ATP, the binding of purified 32P-PPAR-alpha to a panel of different natural and synthetic lipids, immobilized on silica layers, was evaluated. Autoradiographs of the silica layers revealed binding to two main classes of lipophilic compounds. A first class comprised (poly)unsaturated fatty acids. Compounds belonging to a second class were characterized by the presence of an overall positive charge such as long chain amines, sphingoid bases (sphingenine), and lysoglycosphingolipids (psychosine). PPAR-alpha did not bind to N-acylated sphingoid bases (ceramides) or to sphingenine phosphorylated at the primary hydroxy group (sphingenine-1-phosphate). The binding of PPAR-alpha to sphingoid bases might be of interest given the role of PPAR-alpha and sphingolipids in various cellular processes.

The neuronal migration defect in mice with Zellweger syndrome (Pex5 knockout) is not caused by the inactivity of peroxisomal beta-oxidation.

The purpose of this study was to investigate whether deficient peroxisomal beta-oxidation is causally involved in the neuronal migration defect observed in Pex5 knockout mice. These mice are models for Zellweger syndrome, a peroxisome biogenesis disorder. Neocortical development was evaluated in mice carrying a partial or complete defect of peroxisomal beta-oxidation at the level of the second enzyme of the pathway, namely, the hydratase-dehydrogenase multifunctional/bifunctional enzymes MFP1/L-PBE and MFP2/D-PBE. In contrast to patients with multifunctional protein 2 deficiency who present with neocortical dysgenesis, impairment of neuronal migration was not observed in the single MFP2 or in the double MFP1/MFP2 knockout mice. At birth, the double knockout pups displayed variable growth retardation and about one half of them were severely hypotonic, whereas the single MFP2 knockout animals were all normal in the perinatal period. These results indicate that in the mouse, defective peroxisomal beta-oxidation does not cause neuronal migration defects by itself. This does not exclude that the inactivity of this metabolic pathway contributes to the brain pathology in mice and patients with complete absence of functional peroxisomes.

Androgens markedly stimulate the accumulation of neutral lipids in the human prostatic adenocarcinoma cell line LNCaP.

Microscopic evaluation of LNCaP cells stained with the lipophilic dye Oil red O revealed that androgens induce a marked stimulation of lipid droplet accumulation. As determined by quantitative analysis of the Oil red O extracted from the stained cells, stimulatory effects of the synthetic androgen R1881 became apparent at concentrations as low as 10(-11) M. Maximal induction (15-fold) was reached at 10(-8) M. Increases were observed 2 days after hormone addition and were maximal 1 day later. Accumulation of lipid droplets was also induced by mibolerone (another synthetic androgen) and by the natural androgens testosterone and dihydrotestosterone. In agreement with the aberrant ligand specificity of the mutated androgen receptor in LNCaP cells, stimulation of lipid accumulation was also apparent after treatment with progesterone and estradiol. Cortisol and the synthetic glucocorticoid dexamethasone were ineffective. The androgen antagonist Casodex (bicalutamide) abolished the stimulatory effect of R1881, further supporting the involvement of the androgen receptor. In agreement with this conclusion, no changes in lipid accumulation were observed after androgen treatment of the androgen receptor-negative prostate tumor lines PC-3 and DU-145. To investigate the nature of the lipids affected by androgens, lipid extracts were analyzed by TLC, complemented with enzymatic lipid analyses. Androgens were shown to have major effects on the content of triglycerides and cholesterol esters (33- and 7-fold stimulation, respectively), the two main classes of lipids stained by Oil red O. Phospholipid and cholesterol contents were increased by a factor of 2. Incorporation studies with [2-14C]acetate revealed that androgens caused a major stimulation of 2-14C incorporation into triglycerides and cholesterol esters (11- and 13-fold, respectively), suggesting that androgens act at least in part at the level of lipid synthesis. Taken together, these findings indicate that androgens, besides affecting proliferation and protein secretion, also markedly stimulate the production and accumulation of neutral lipids, revealing a novel interesting aspect of androgen regulation of LNCaP cells.