Is cytochrome P-450 transported from the endoplasmic reticulum to the Golgi apparatus in rat hepatocytes?

The Influence of Lipid Microdomain Heterogeneity on Protein-Protein Interactions: Proteomic Analysis of Co-Immunoprecipitated Binding Partners of P450 1A2 and P450 3A in Rat Liver Microsomes

Liver cytochrome P450s (CYPs) of the endoplasmic reticulum (ER) are involved in the metabolism of exogenous and endogenous chemicals. The ER is not uniform, but possesses ordered lipid microdomains containing higher levels of saturated fatty acids, sphingomyelin, and cholesterol and disordered regions containing higher levels of polyunsaturated fatty acid chains. The various forms of drug-metabolizing P450s partition to either the ordered or disordered lipid microdomains with different degrees of specificity. P450s readily form complexes with ER-resident proteins, including other forms of P450. This study aims to ascertain whether lipid microdomain localization influences protein-P450 interactions in rat liver microsomes. Thus, liver microsomes were co-immunoprecipitated with CYP1A2-specific and CYP3A-specific antibodies, and the co-immunoprecipitating proteins were identified by liquid chromatography mass spectrometry proteomic analysis. These two P450s preferentially partition to ordered and disordered microdomains, respectively. More than 100 proteins were co-immunoprecipitated with each P450. Segregation of proteins into different microdomains did not preclude their interaction. However, CYP3A interacted broadly with proteins from ordered microdomains, whereas CYP1A2 reacted with a limited subset of these proteins. This is consistent with the concept of lipid raft heterogeneity and may indicate that CYP1A2 is targeted to a specific type of lipid raft. Although many of the interacting proteins for both P450s were other-drug metabolizing enzymes, other interactions were also evident. The consistent CYP3A binding partners were predominantly involved in phase I/II drug metabolism; however, CYP1A2 interacted not only with xenobiotic metabolizing enzymes, but also with enzymes involved in diverse cellular responses such as ER stress and protein folding. SIGNIFICANCE STATEMENT: This work describes the protein interactomes in rat liver microsomes of two important cytochromes P450s (CYP1A2 and CYP3A) in drug metabolism and describes the relationship of the interacting proteins to lipid microdomain distribution.

Hepatic cytochrome P450 degradation: mechanistic diversity of the cellular sanitation brigade

Hepatic cytochromes P450 (P450s) are monotopic endoplasmic reticulum (ER)-anchored hemoproteins that exhibit heterogenous physiological protein turnover. The molecular/cellular basis for such heterogeneity is not well understood. Although both autophagic-lysosomal and nonlysosomal pathways are available for their cellular degradation, native P450s such as CYP2B1 are preferentially degraded by the former route, whereas others such as CYPs 3A are degraded largely by the proteasomal pathway, and yet others such as CYP2E1 may be degraded by both. The molecular/structural determinants that dictate this differential proteolytic targeting of the native P450 proteins remain to be unraveled. In contrast, the bulk of the evidence indicates that inactivated and/or otherwise posttranslationally modified P450 proteins undergo adenosine triphosphate-dependent proteolytic degradation in the cytosol. Whether this process specifically involves the ubiquitin (Ub)-/26S proteasome-dependent, the Ub-independent 20S proteasome-dependent, or even a recently characterized Ub- and proteasome-independent pathway may depend on the particular P450 species targeted for degradation. Nevertheless, the collective evidence on P450 degradation attests to a remarkably versatile cellular sanitation brigade available for their disposal. Given that the P450s are integral ER proteins, this mechanistic diversity in their cellular disposal should further expand the repertoire of proteolytic processes available for ER proteins, thereby extending the currently held general notion of ER-associated degradation.

Cell biology of cytochrome P-450 in the liver

Cytochromes P-450 (P-450) are members of a multigene superfamily of hemoproteins consisting the microsomal monooxygenase system with NADPH P-450 reductase (reductase) and/or reducing equivalents. Expression of many P-450 isoforms in hepatocytes is shown to be regulated at the level of transcription through interaction between cis-acting elements in the genes and DNA-binding (transacting) factors. Some isoforms of the CYP1A, 2B, 2E, and 3A subfamilies are regulated at the posttranscriptional level. For the topology of P-450 and reductase molecules in ER membrane of hepatocytes, models from stopped flow analysis and electron spin resonance are proposed. The densities of total P-450 and reductase molecules are revealed to be high enough to support the cluster model, suggesting that about ten P-450 molecules form an aggregate and surround one reductase molecule, and therefore the two enzymes form large micelles. ER proliferation after PB administration, which had been correlated with increase in P-450 level, is shown to be probably independent of the increase in P-450 level. There are considerable discrepancies among results reported on sublobular expression of various P-450 isoforms. Causes of the discrepancies are likely to be differences in experimental conditions of histochemical detection carried out and/or in species, strain, and/or sex.

Membrane topology and retention of microsomal aldehyde dehydrogenase in the endoplasmic reticulum

Microsomal aldehyde dehydrogenase (msALDH) is anchored to the endoplasmic reticulum (ER) membrane by the hydrophobic domain at its carboxyl terminus, and most of the molecule is exposed to the cytoplasm (Masaki, R., Yamamoto, A., and Tashiro, Y.(1994) J. Cell Biol. 126, 1407-1420). To determine the membrane topology and the intracellular localization of msALDH, the amino-terminal region of bovine opsin containing N-glycosylation sites was fused to the carboxyl terminus of msALDH, and three chimeric proteins with extensions of different sizes were expressed in COS cells. Indirect immunofluorescence microscopy showed the ER localization of all of the chimeric proteins similar to wild-type msALDH. Immunoblotting revealed that the two chimeric proteins containing longer extensions, those with the N-glycosylation site at distances of 13 and 21 amino acids from the membrane anchor, respectively, were glycosylated. These results indicate that the membrane binding domain of msALDH spans the bilayer of the ER. The carbohydrate chain of the chimeras was sensitive to endoglycosidase H but resistant to endoglycosidase D. Upon treatment of transfected COS cells with brefeldin A, the carbohydrate chain was processed to an endoglycosidase H-resistant form, presumably by cis/medial Golgi-specific enzymes redistributed in the ER. These biochemical results in addition to immunofluorescence microscopic observations suggest that msALDH is retained in the ER by blockading of the exit from the ER.

Stacking of Golgi cisternae in Schizosaccharomyces pombe requires intact microtubules

Fission yeast was treated with the anti-microtubule agent, thiabendazole. Cytoplasmic microtubules broke down with a half-time of less than 10 minutes followed closely by the unstacking of Golgi cisternae. The final product appeared to be single Golgi cisternae. No other organelle seemed to be affected by this treatment, which was completely reversible. The nda3 mutant strain has an altered beta-tubulin and its cytoplasmic microtubules are resistant to thiabendazole. The Golgi in this cold-sensitive mutant was unaffected by treatment at the permissive temperature but unstacked at the non-permissive temperature even in the absence of thiabendazole. Taken together these data show that disruption of the microtubular network can cause dissociation of Golgi cisternae. Newly synthesised acid phosphatase was transported and secreted to the same extent and with the same kinetics whether or not the Golgi was unstacked. The possible role of microtubules in Golgi stacking and the lack of effect on secretion are discussed.

O-glycosylation of intact and truncated ribophorins in brefeldin A-treated cells: newly synthesized intact ribophorins are only transiently accessible to the relocated glycosyltransferases

Ribophorins I and II are type I transmembrane glycoproteins of the ER that are segregated to the rough domains of this organelle. Both ribophorins appear to be part of the translocation apparatus for nascent polypeptides that is associated with membrane-bound ribosomes and participate in the formation of a proteinaceous network within the ER membrane that also includes other components of the translocation apparatus. The ribophorins are both highly stable proteins that lack O-linked sugars but each contains one high mannose N-linked oligosaccharide that remains endo H sensitive throughout their lifetimes. We have previously shown (Tsao, Y. S., N. E. Ivessa, M. Adesnik, D. D. Sabatini, and G. Kreibich. 1992. J. Cell Biol. 116:57-67) that a COOH-terminally truncated variant of ribophorin I that contains only the first 332 amino acids of the luminal domain (RI332), when synthesized in permanent transformants of HeLa cells, undergoes a rapid degradation with biphasic kinetics in the ER itself and in a second, as yet unidentified nonlysosomal pre-Golgi compartment. We now show that in cells treated with brefeldin A (BFA) RI332 molecules undergo rapid O-glycosylation in a multistep process that involves the sequential addition of N-acetylgalactosamine, galactose, and terminal sialic acid residues. Addition of O-linked sugars affected all newly synthesized RI332 molecules and was completed soon after synthesis with a half time of about 10 min. In the same cells, intact ribophorins I and II also underwent O-linked glycosylation in the presence of BFA, but these molecules were modified only during a short time period immediately after their synthesis was completed, and the modification affected only a fraction of the newly synthesized polypeptides. More important, these molecules synthesized before the addition of BFA were not modified by O-glycosylation. The same is true for ribophorin I when overexpressed in HeLa cells although it is significantly less stable than the native polypeptide in control cells. We, therefore, conclude that soon after their synthesis, ribophorins lose their susceptibility to the relocated Golgi enzymes that effect the O-glycosylation, most likely as a consequence of a conformational change in the ribophorins that occurs during their maturation, although it cannot be excluded that rapid integration of these molecules into a supramolecular complex in the ER membrane leads to their inaccessibility to these enzymes.

Differentiation of a calsequestrin-containing endoplasmic reticulum during sea urchin oogenesis

We have used light and electron microscopic immunolocalization to study the distribution of a sea urchin calsequestrin-like protein (SCS) during sea urchin oogenesis. SCS was localized exclusively in the lumen of the endoplasmic reticulum (ER) and in the nuclear envelope of oocytes of all maturation stages. Immunoelectron microscopy also revealed that SCS is not present in golgi complexes of oocytes. Double label immunofluorescent staining of frozen sections of ovary with the SCS antiserum and an antibody to the cortical granule protein hyalin indicated a dramatic morphogenesis of the SCS-containing ER (SCS-ER) coincident with oocyte maturation. This differentiation included an apparent increase in the amount and complexity of the cytoplasmic SCS-ER network, the transient appearance of stacks of SCS-ER cisternae in synthetically active vitellogenic oocytes, and the restructuring of the SCS-ER in the cortex. Immunofluorescence of isolated oocyte cortices showed a plasma membrane-associated SCS-ER which was much less dense and regular than that found surrounding the cortical granules in the mature unfertilized egg cortex. Cytoplasmic and cortical microtubule arrays are present in oocytes and may provide the basis for the SCS-ER distributional dynamics. The results of this study underscore the dynamic nature of ER and how it's organization reflects cellular functions. We suggest that the establishment during oogenesis of the dense SCS-ER tubuloreticulum provides the egg with the calcium sequestration and release apparatus that regulates calcium fluxes during egg activation and early development.

Cell type-specific post-Golgi apparatus localization of a "resident" endoplasmic reticulum glycoprotein, glucosidase II

Glucosidase II, an asparagine-linked oligosaccharide processing enzyme, is a resident glycoprotein of the endoplasmic reticulum. In kidney tubular cells, in contrast to previous findings on hepatocytes, we found by light and electron microscopy immunoreactivity for glucosidase II predominantly in post-Golgi apparatus structures. The majority of immunolabel was in endocytotic structures beneath the plasma membrane. Immunoprecipitation confirmed presence of the glucosidase II subunit in purified brush border preparations. Kidney glucosidase II contained species carrying endo H-sensitive, high mannose as well as endo H-resistant oligosaccharide chains. Some species of glucosidase II contained sialic acid. The sialylated species were enzymatically active. This study demonstrates than an enzyme presumed to be a resident of the endoplasmic reticulum may show alternative localizations in some cell types.

Immunocytochemistry of calciosomes in liver and pancreas

Calciosomes are small cytoplasmic vacuoles identified in various nonmuscle cell types by their content of protein(s) similar to calsequestrin (CS), the Ca2+ storage protein of the muscle sarcoplasmic reticulum (SR). These entities have been interpreted as the "primitive" counterpart of the SR, and suggested to be the organelle target of inositol-1,4,5-triphosphate action (Volpe, P., K. H. Krause, S. Hashimoto, F. Zorzato, T. Pozzan, J. Meldolesi, and D. P. Lew. Proc. Natl. Acad. Sci. USA. 85:1091-1095). Immunoperoxidase and immunogold experiments carried out in both thick and ultrathin cryosections of rat hepatocytes and pancreatic acinar cells by using antimuscle CS antibodies revealed a specific labeling widely distributed in the entire cytoplasm, while nuclei were negative. Individual calciosomes appeared as small (105 nm) membrane-bound vacuoles intermingled with, and often apposed to ER cisternae and mitochondria. Other calciosomes were scattered in the Golgi area, in between zymogen granules and beneath the plasma membrane. The cumulative volume of the CS-positive organelles was measured to account for the 0.8 and 0.45% of the cytoplasm in liver and pancreas cells, respectively. The real total volume of the calciosome compartment is expected to be approximately twice as large. In hepatocytes, structures similar to CS-positive calciosomes were decorated by antibodies against the Ca2+ ATPase of muscle SR, while ER cisternae were not. By dual labeling, colocalization was revealed in 53.6% of the organelles, with 37.6% positive for the ATPase only. CS appeared preferentially confined to the content, and the Ca2+ ATPase to the contour of the organelle. The results suggested a partial segregation of the two antigens, reminiscent of their well-known segregation in muscle SR. Additional dual-label experiments demonstrated that hepatic calciosomes express neither two ER markers (cytochrome-P450 and NADH-cytochrome b5 reductase) nor the endolysosome marker, luminal acidity (revealed by 3-[2,4-dinitroanilino]-3'-amino-N-methyl dipropylamine). Calciosomes appear as unique cytological entities, ideally equipped to play a role in the rapid-scale control of the cytosolic-free Ca2+ in nonmuscle cells.

Site of addition of N-acetyl-galactosamine to the E1 glycoprotein of mouse hepatitis virus-A59

By pulse-chase labeling with [35S]methionine and long-term labeling with 3H-sugars, the E1 glycoprotein of coronavirus MHV-A59 has been shown to acquire O-linked oligosaccharides in a two-step process. About 10 min after synthesis of the E1 protein, N-acetyl-galactosamine was added. This was followed approximately 10 min later by the addition of both galactose and sialic acid to give the mature oligosaccharides. This sequence of additions was confirmed by analyzing the 3H-labeled oligosaccharides bound to each of the E1 forms using gel filtration on P4 columns. The intracellular location of the first step was determined by exploiting the temperature sensitivity of virus release. The virus normally buds first into a smooth membrane compartment lying between the rough endoplasmic reticulum and the cis side of the Golgi stack (Tooze et al., 1984). At 31 degrees C the virus is assembled but does not appear to enter the Golgi stacks. The addition of N-acetyl-galactosamine is unaffected although the addition of galactose and sialic acid is inhibited. These results strongly suggest that addition of N-acetyl-galactosamine occurs in this budding compartment, the morphology of which is similar to that of transitional elements and vesicles.

Information transfer in biological systems: targeting of proteins to specific organelles or to the extracellular environment (secretion)

Orderliness is the salient characteristic of living systems. Cells are intolerant of disorder. They express this by rapidly eliminating or degrading out-of-place molecules. When cells are broken apart and their constituent organelles separated and analysed, the same types of macromolecules are always associated with the same subcellular structures. One finds, for example, the same proteins in mitochondria time after time, and these differ from the sets of proteins found in nuclei, secretory granules, or plasma membranes. The information necessary to target each protein to its appropriate intracellular destination is determined primarily by the gene for that protein. Encoded within the DNA structure of genes are signals that specify where each protein molecule belongs. Thus, it is the transfer of information from one macromolecule to another that maintains the integrity and orderliness of living cells.

Cytochrome P-450 and NADPH-cytochrome P-450 reductase are degraded in the autolysosomes in rat liver

We have investigated the degradation in rat liver of two typical endoplasmic reticulum (ER) membrane proteins, phenobarbital (PB)-inducible cytochrome P-450 (P-450[PB]) and NADPH-cytochrome P-450 reductase (FP2). Autolysosomes, almost completely free from contamination by the other organelles such as ER, were prepared from leupeptin-treated rat livers according to the method of Furuno et al. (Furuno, K., T. Ishikawa, and K. Kato, 1982, J. Biochem., 91:1943-1950). Quantitative immunoblot analysis showed that these two proteins were found in large amounts in the autolysosomes regardless of PB treatment. The specific content of P-450 (PB) in the autolysosomes changed along with that in the microsomes during and after PB treatment, whereas hardly any P-450(PB) was detected in the cytosol fraction throughout the experiment. We also found a marked increase in the autolysosomal proteins 3 d after cessation of PB treatment when microsomal proteins are degraded most rapidly. Ferritin immunoelectron microscopy revealed directly that when the limiting membranes of the premature autolysosomes were partially broken the smooth vesicles segregated within the autolysosomes were heavily stained with ferritin anti-P-450(PB) conjugates. Thus, for the first time, we could present convincing evidence that P-450(PB) and FP2 are segregated to be degraded in the autolysosomes.

Transferrin receptor polarity and recycling accuracy in "tight" and "leaky" strains of Madin-Darby canine kidney cells

We have characterized the polarity of the transferrin receptor in the epithelial Madin-Darby canine kidney (MDCK) cell line. The receptor is present in approximately 165,000 copies per cell, migrates as a diffuse band upon SDS gel electrophoresis with Mr 90,000, displays a dissociation constant for diferritransferrin at neutral pH of approximately 2 nM, and is active in essentially all of the cells of the population. Transferrin-mediated 55Fe uptake was used to measure the polarity of active transferrin receptors in filter-grown MDCK cells. The ratio of basolateral to apical receptors was approximately 800:1 for the high resistance strain I MDCK cells (typically greater than 2,000 ohm X cm2) and approximately 300:1 for the lower resistance strain II cells (less than 350 ohm X cm2). In combination with morphometric data this shows that a difference in resistance between these two strains is not reflected in a significant difference in cell surface polarity. We used the recycling of transferrin receptor in filter-grown MDCK cells to evaluate the accuracy of the sorting of a basolateral protein during endocytosis. Monitoring the amount of apically released 125I-labeled transferrin after application of 55Fe- and 125I-labeled transferrin to the basolateral surface provided a sensitive assay of the accuracy of sorting during recycling of the receptor from endosomes to the plasma membrane. The accuracy of transferrin receptor sorting (greater than 99.88%) during a single cycle of transit between the endosome and the plasma membrane is sufficient to maintain the high level of polarity of the cell.

The trans Golgi network: sorting at the exit site of the Golgi complex

The Golgi complex is a series of membrane compartments through which proteins destined for the plasma membrane, secretory vesicles, and lysosomes move sequentially. A model is proposed whereby these three different classes of proteins are sorted into different vesicles in the last Golgi compartment, the trans Golgi network. This compartment corresponds to a tubular reticulum on the trans side of the Golgi stack, previously called Golgi endoplasmic reticulum lysosomes (GERL).

Temperature and energy dependence of secretory protein transport in the exocrine pancreas

Pancreatic lobules pulse-labeled with [3H]leucine have been incubated at temperatures between 0 and 37 degrees C in the presence or absence of ongoing oxidative phosphorylation. Subcellular fractionation methods and electron microscopic autoradiography have been used to monitor the progress of intracellular transport of newly synthesized secretory proteins. Over the period studied, exit from the rough endoplasmic reticulum (RER) occurs only at greater than 10 degrees C while traversal of the Golgi complex and entry into condensing vacuoles requires greater than 22 degrees C. Both steps of transport require ongoing ATP production. Incubation at 10 or 20 degrees C does not diminish ATP levels, relative to 37 degrees C controls. Remarkable and unprecedented alterations of the ultrastructure of transitional elements of the RER accompany the arrest of exit from the RER: at 10 degrees C transitional elements are much more numerous and longer than in controls; in the absence of ATP production they are essentially absent. These observations are interpreted in terms of a cyclic model of RER-to-Golgi vesicular traffic. Inhibition of ATP production also causes an increase in the rigid cisternae and coated elements in the distal Golgi area.