Cytochrome P450-dependent renal arachidonic acid metabolism in desoxycorticosterone acetate-salt hypertensive mice.

Cytochrome P450 (P450)-dependent arachidonic acid metabolites may act as mediators in the regulation of vascular tone and renal function. We studied arachidonic acid hydroxylase activities in renal microsomes from normotensive NMRI mice, desoxycorticosterone acetate (DOCA)-salt hypertensive mice, and DOCA-salt mice treated with either lovastatin or bezafibrate, both of which improve hemodynamics in this model. Control renal microsomes had arachidonic acid hydroxylase activities of 175+/-12 pmol. min(-1). mg(-1). The metabolites formed were 20- and 19-hydroxyarachidonic acid, representing approximately 80% and approximately 20% of the total hydroxylation. Treatment with DOCA-salt resulted in significantly decreased hydroxylase activities (to 84+/-4 pmol. min(-1). mg(-1)) of the total microsomal P450 content and a decrease in immunodetectable Cyp4a proteins. Lovastatin had no effect on these variables, whereas bezafibrate increased arachidonic acid hydroxylase activities to 163+/-12 pmol. min(-1). mg(-1). In situ hybridization with probes for Cyp4a-10, 12, and 14 revealed that Cyp4a-14 was the P450 isoform most strongly induced by bezafibrate. The expression was concentrated in the cortical medullary junction and was localized predominantly in the proximal tubules. In conclusion, these results suggest that the capacity to produce 20-hydroxyarachidonic acid is impaired in the kidneys of DOCA-salt hypertensive mice. Furthermore, bezafibrate may ameliorate hemodynamics in this model by restoring P450-dependent arachidonic acid hydroxylase activities. Lovastatin, on the other hand, exerts its effects via P450-independent mechanisms.

Inhibition of pressure natriuresis in mice lacking the AT2 receptor.

UNLABELLED: Inhibition of pressure natriuresis in mice lacking the AT2 receptor. BACKGROUND: Angiotensin II type 2 (AT2) receptor knockout mice have higher blood pressures than wild-type mice; however, the hypertension is imperfectly defined. We tested the hypothesis that renal mechanisms could be contributory. METHODS: We conducted pressure-natriuresis-diuresis experiments, measured renal cortical and medullary blood flow by laser Doppler methods, and explored cytochrome P450-dependent arachidonic acid metabolism by means of reverse transcription-polymerase chain reaction. RESULTS: Blood pressure was 15 mm Hg higher in AT2 receptor knockout mice than in controls, and pressure diuresis and natriuresis curves were shifted rightward. At similar renal perfusion pressures (113 to 118 mm Hg), wild-type mice excreted threefold more sodium and water than AT2 receptor knockout mice. Fractional sodium and water excretion curves were shifted rightward in parallel. Renal blood flow ranged between 6.72 and 7.88 mL/min/g kidney wet weight (kwt) in wild-type and between 5.84 and 6.15 mL/min/g kwt in AT2 receptor knockout mice. Renal vascular resistance was increased in AT2A receptor knockout mice. Cortical blood flow readings leveled at 2.5 V in wild-type and 1.5 V in AT2 receptor knockout mice. Medullary blood flow readings ranged between 0.8 and 1.0 V and increased 116% in wild-type mice as renal perfusion pressure was increased. This increase did not occur in AT2 receptor knockout mice. The glomerular filtration rate (GFR) was similar in both groups at approximately 1 mL/min/g kwt. Renal microsomes from AT2 receptor knockout mice had less activity in hydroxylating arachidonic acid to 20-hydroxyeicosatetraenoic acid (20-meter) than controls, whereas renal AT1 receptor gene expression was increased in AT2 receptor knockout mice. CONCLUSIONS: Hemodynamic and tubular factors modify renal sodium handling in AT2 receptor knockout mice and may cause hypertension. AT2 receptor disruption induces alterations of other regulatory systems, including altered arachidonic acid metabolism, that may contribute to the intrarenal differences observed between AT2 receptor knockout and wild-type mice.

Inducible membranes in yeast: relation to the unfolded-protein-response pathway.

Overproduction of an endoplasmic reticulum (ER)-resident membrane protein (cytochrome P450 52A3) and of a secretory protein (invertase) was used to study the regulation of the luminal ER protein Kar2p under conditions that lead to ER proliferation and secretory overload, respectively. In both cases we found (i) a significant increase of Kar2 protein and mRNA levels, (ii) a transcriptional regulation based on the the function of the 22 bp unfolded-protein-response element of the KAR2 promoter and (iii) an essential role of the transmembrane kinase Ire1p for upregulation of KAR2 gene expression. These results show that the same mechanism operates when KAR2 induction is triggered by overproduction of cytochrome P450 or invertase and that this mechanism shares the known features of the unfolded-protein-response pathway. Disruption of the IRE1 gene resulted in a marked decrease of the invertase protein levels produced. In contrast, a functional IRE1 gene was not required to reach high-level production of the integral membrane protein cytochrome P450 52A3, Moreover, IRE1 gene disruption did not prevent P450-induced ER proliferation. We suggest that Ire1p-mediated KAR2 induction is, in the case of cytochrome P450 52A3 overproduction, a process which follows on ER proliferation, thereby monitoring the increase of ER size and adjusting the level of Kar2p accordingly.

Topogenesis of a microsomal cytochrome P450 and induction of endoplasmic reticulum membrane proliferation in Saccharomyces cerevisiae.

Cytochrome P450 52A3 (P450Cm1) is one of the membrane proteins known to trigger by its high-level expression a marked proliferation of the endoplasmic reticulum, (ER). To gain insight into the relationship between the expression of a membrane protein and the induction of ER proliferation we have characterized the membrane topology of P450Cm1 and identified the structural determinants required for ER targeting, formation of correct membrane orientation, and ER retention. We show that all these features are interrelated and determined by sequence elements within the NH2-terminal region of P450Cm1. Using several approaches--a protease protection assay followed by probing with peptide-specific antibodies, immunolabeling of the intact membrane-bound P450 protein, and expression of fusion proteins in Saccharomyces cerevisiae--membrane topology was defined as follows: residues 2-16 are located in the ER lumen, only the first hydrophobic segment (residues 17-34) spans the membrane, a second hydrophobic segment (48-66) is exposed at the cytoplasmic side, and the remaining part (67-523) forms a large cytosolic domain. Fused to a cytosolic reporter protein, the first 44-amino-acid sequence of P450Cm1 was sufficient to mediate ER targeting, wild-type membrane orientation, and retention in the ER. Similar to wild-type P450Cm1, various fusion proteins were able to induce distinctly organized structures of proliferated ER provided that they were either permanently retained in the ER or accumulated in this compartment due to a delay in further transportation. Thus, we conclude that membrane insertion of the first hydrophobic segment is sufficient to deliver a signal for increased membrane formation.

Characterization of the n-alkane and fatty acid hydroxylating cytochrome P450 forms 52A3 and 52A4.

Two enzymes, P450 52A3 (P450Cm1) and 52A4 (P450Cm2), the genes of which belong to the CYP52 multigene family occurring in the alkane-assimilating yeast Candida maltosa, have been characterized biochemically and compared in terms of their substrate specificities. For this purpose, both the p450 proteins and the corresponding C. maltosa NADPH-cytochrome P450 reductase were separately produced by expressing their cDNAs in Saccharomyces cerevisiae, purified, and reconstituted to active monooxygenase systems. Starting from microsomal fractions with a specific content of 0.75 nmol P450Cm1, 0.34 nmol P450Cm2, and 10.5 units reductase per milligram of protein, respectively, each individual recombinant protein was purified to homogeneity. P450 substrate difference spectra indicated strong type I spectral changes and high-affinity binding of n-hexadecane (Ks= 26 micron) and n-octadecane (Ks = 27 microM) to P450Cm1, whereas preferential binding to P450Cm2 was observed using lauric acid (Ks = 127 microM) and myristic acid (Ks = 134 microM) as substrates. These substrate selectivities were further substantiated by kinetic parameters, determined for n-alkane and fatty acid hydroxylation in a reconstituted system, which was composed of the purified components and phospholipid, as well as in microsomes obtained after coexpressing each of the P450 proteins with the reductase. The highest catalytic activities within the reconstituted system were measured for n-hexadecane hydroxylation to 1-hexadecanol by P450Cm1 (Vmax = 27 microM x min-1, Km = 54 microM) and oxidation of lauric acid to 16-hydroxylauric acid by P450Cm2 (Vmax = 30 microM x min-1, Km = 61 microM). We conclude that P450Cm1 and P450Cm2 exhibit overlapping but distinct substrate specificities due to different chain-length dependencies and preferences for either n-alkanes or fatty acids.

Candida maltosa NADPH-cytochrome P450 reductase: cloning of a full-length cDNA, heterologous expression in Saccharomyces cerevisiae and function of the N-terminal region for membrane anchoring and proliferation of the endoplasmic reticulum.

A full-length cDNA for NADPH-cytochrome P450 reductase from Candida maltosa was cloned and sequenced. The derived amino acid sequence showed a high similarity to the reductases from other eukaryotes. Expression in Saccharomyces cerevisiae under control of the GAL10 promoter resulted in an approximately 70-fold increase in NADPH-cytochrome c reductase activity in the microsomal fraction. The functional integrity of the heterologously expressed reductase as an electron transfer component for alkane hydroxylating cytochrome P450 from C. maltosa was shown in a reconstituted system containing both enzymes in a highly purified state. The signal-anchor sequence of the reductase was identified within the N-terminal region of the protein by means of constructing and expressing fusion proteins with the cytosolic form of yeast invertase. The first 33 amino acids turned out to be sufficient for stable membrane insertion, wild-type membrane orientation and retention in the endoplasmic reticulum. As shown by immunoelectron microscopy, the heterologously expressed reductase was integrated into the endoplasmic reticulum of the host organism. It triggered a strong proliferation of the membrane system. This membrane-inducing property of the reductase was transferable to the cytosolic reporter protein with the same N-terminal sequences that confer membrane insertion.

Immunocytochemical localization of alkane-inducible cytochrome P-450 and its NADPH-dependent reductase in the yeast Candida maltosa.

Antibodies directed against cytochrome P-450Cm1 and the NADPH-cytochrome P-450 reductase were used to study the induction and intracellular localization of these components of the alkane monooxygenase system in the yeast Candida maltosa. Transition from glucose to n-hexadecane utilization resulted in an about 100-fold increase of the immunodetectable P-450 form whereas the reductase was only moderately induced by a factor of about 5. P-450 but not the reductase was further increased by oxygen limitation during cultivation on n-hexadecane. Using an immunogold technique on ultrathin cryosections, P-450 was found to be concentrated in the nuclear envelope during the early phase of the induction process. However, after maximal induction, the highest labeling was observed in membranes of the endoplasmic reticulum closely associated with the peroxisomes and the plasma membrane. Double-labeling experiments revealed that P-450 and its reductase were distributed in the same regions of the endoplasmic reticulum.

Comparison of two cytochromes P-450 from Candida maltosa: primary structures, substrate specificities and effects of their expression in Saccharomyces cerevisiae on the proliferation of the endoplasmic reticulum.

cDNAs were cloned, sequenced and expressed which encode two different cytochrome P-450 forms of the alkane-assimilating yeast Candida maltosa, designated as P-450Cm1 and P-450Cm2. The amino acid sequences deduced were about 55% identical. Expression in Saccharomyces cerevisiae resulted in the formation of intact microsomal P-450 systems catalyzing the hydroxylation of n-hexadecane and lauric acid with significantly different substrate preferences. A massive proliferation of the endoplasmic reticulum was observed in the S. cerevisiae cells which produced P-450. Depending on the P-450 form expressed, distinctly organized stacks of paired membranes appeared and occupied considerable areas of the cytoplasm. As shown by immunoelectron microscopy for P-450Cm1, the protein expressed was highly concentrated within these newly formed membrane structures.

Molecular cloning and characterization of the primary structure of the alkane hydroxylating cytochrome P-450 from the yeast Candida maltosa.

A cDNA library was established starting from poly(A) RNA of n-alkane-grown Candida maltosa cells and cDNA clones were isolated containing the entire coding sequence for the alkane hydroxylating cytochrome P-450. The deduced protein consists of 521 amino acids, contains two putative transmembrane segments in the N-terminal region and has a characteristic heme-binding sequence in the C-terminal part. Sequence alignments with members of 11 reported cytochrome P-450 families revealed a strong homology to an alkane-inducible cytochrome P-450 from Candida tropicalis.

N-alkanes induce the synthesis of cytochrome P-450 mRNA in Candida maltosa.

In the yeast Candida maltosa the level of cytochrome P-450 was 100-300-fold higher in alkane-grown cells than in glucose-grown ones (detected by a radioimmunoassay). It was shown immunochemically (1) that this was not the result of an assembly of preexisting apoenzyme with the prosthetic heme group. By cell-free translation of total poly(A)RNA in a wheat germ system and subsequent immunoprecipitation it was shown that the amount of mRNA coding for cytochrome P-450 paralleled its concentration in the cell.

A comparative immunological investigation of the alkane hydroxylating cytochrome P-450 from the yeast Candida maltosa.

The immunological relations of the cytochrome P-450 from the n-alkane utilizing yeast Candida maltosa to cytochrome P-450 forms of other organisms - yeasts, bacteria and mammalia - were investigated using a solid-phase double-antibody radioimmunoassay. Only the microsomal fraction of other n-alkane utilizing yeasts shows a distinct cross-reaction with an antiserum against cytochrome P-450 from Candida maltosa. Neither the tested bacterial nor the mammalian cytochromes P-450 cross-react with the antiserum.