Characterization of electrogenic bromosulfophthalein transport in carnation petal microsomes and its inhibition by antibodies against bilitranslocase

Bilitranslocase is a rat liver plasma membrane carrier, displaying a high-affinity binding site for bilirubin. It is competitively inhibited by grape anthocyanins, including aglycones and their mono- and di-glycosylated derivatives. In plant cells, anthocyanins are synthesized in the cytoplasm and then translocated into the central vacuole, by mechanisms yet to be fully characterized. The aim of this work was to determine whether a homologue of rat liver bilitranslocase is expressed in carnation petals, where it might play a role in the membrane transport of anthocyanins. The bromosulfophthalein-based assay of rat liver bilitranslocase transport activity was implemented in subcellular membrane fractions, leading to the identification of a bromosulfophthalein carrier (K(M) = 5.3 microm), which is competitively inhibited by cyanidine 3-glucoside (Ki = 51.6 microm) and mainly noncompetitively by cyanidin (Ki = 88.3 microm). Two antisequence antibodies against bilitranslocase inhibited this carrier. In analogy to liver bilitranslocase, one antibody identified a bilirubin-binding site (Kd = 1.7 nm) in the carnation carrier. The other antibody identified a high-affinity binding site for cyanidine 3-glucoside (Kd = 1.7 microm) on the carnation carrier only, and a high-affinity bilirubin-binding site (Kd = 0.33 nm) on the liver carrier only. Immunoblots showed a putative homologue of rat liver bilitranslocase in both plasma membrane and tonoplast fractions, isolated from carnation petals. Furthermore, only epidermal cells were immunolabeled in petal sections examined by microscopy. In conclusion, carnation petals express a homologue of rat liver bilitranslocase, with a putative function in the membrane transport of secondary metabolites.     

Immunolocalisation of bilitranslocase in mucosecretory and parietal cells of the rat gastric mucosa

SummaryBilitranslocase is a plasma membrane carrier localised at the vascular pole of the rat liver cell, where it mediates uptake of organic anions from the blood into the liver. This carrier is also present in the epithelium of the rat gastric mucosa, with similar molecular mass and functional properties. An immunohistochemical study reveals that both the mucus-secreting cells of the gastric pit and the H⁺-secreting parietal cells express bilitranslocase. These data point to a possible role of bilitranslocase and of its food-borne substrates (anthocyanins and nicotinic acid) in regulating the function and the permeability of the gastric mucosa.     

Uptake of bilirubin into HepG2 cells assayed by thermal lens spectroscopy. Function of bilitranslocase

Bilitranslocase is a carrier protein localized at the basolateral domain of the hepatocyte plasma membrane. It transports various organic anions, including bromosulfophthalein and anthocyanins. Functional studies in subcellular fractions enriched in plasma membrane revealed a high-affinity binding site for bilirubin, associated with bilitranslocase. The aim of this work was to test whether the liver uptake of bilirubin depends on the activity of bilitranslocase. To this purpose, an assay of bilirubin uptake into HepG2 cell cultures was set up. The transport assay medium contained bilirubin at a concentration of approximately 50 nm in the absence of albumin. To analyse the relative changes in bilirubin concentration in the medium throughout the uptake experiment, a highly sensitive thermal lens spectrometry method was used. The mechanism of bilirubin uptake into HepG2 cells was investigated by using inhibitors such as anti-sequence bilitranslocase antibodies, the protein-modifying reagent phenylmethanesulfonyl fluoride and diverse organic anions, including nicotinic acid, taurocholate and digoxin. To validate the assay further, both bromosulfophthalein and indocyanine green uptake in HepG2 cells was also characterized. The results obtained show that bilitranslocase is a carrier with specificity for both bilirubin and bromosulfophthalein, but not for indocyanine green.     

Structural analysis of a peptide fragment of transmembrane transporter protein bilitranslocase

Using a combination of genomic and post-genomic approaches is rapidly altering the number of identified human influx carriers. A transmembrane protein bilitranslocase (TCDB 2.A.65) has long attracted attention because of its function as an organic anion carrier. It has also been identified as a potential membrane transporter for cellular uptake of several drugs and due to its implication in drug uptake, it is extremely important to advance the knowledge about its structure. However, at present, only the primary structure of bilitranslocase is known. In our work, transmembrane subunits of bilitranslocase were predicted by a previously developed chemometrics model and the stability of these polypeptide chains were studied by molecular dynamics (MD) simulation. Furthermore, sodium dodecyl sulfate (SDS) micelles were used as a model of cell membrane and herein we present a high-resolution 3D structure of an 18 amino acid residues long peptide corresponding to the third transmembrane part of bilitranslocase obtained by use of multidimensional NMR spectroscopy. It has been experimentally confirmed that one of the transmembrane segments of bilitranslocase has alpha helical structure with hydrophilic amino acid residues oriented towards one side, thus capable of forming a channel in the membrane.     

On the mechanism of bilitranslocase transport inactivation by phenylmethylsulphonyl fluoride.

Bilitranslocase is a plasma membrane carrier involved in the uptake of bilirubin and other organic anions from the blood into the liver cell. In the membrane, the carrier occurs as two interchangeable metastable forms, with high and low affinity for the substrates, respectively. The latter form can be specifically produced by either cysteine- or arginine modification. In liver plasma membrane vesicles, the serine-specific reagent phenylmethylsulphonyl fluoride is a partial inhibitor of bilitranslocase-mediated BSP transport rate. In this work, phenylmethyl-sulphonyl fluoride is shown to reduce the carrier maximal transport rate, without affecting its affinity for that substrate. In addition, it is found that the chemical modification caused by this reagent neither influences the equilibrium between the high- and the low-affinity forms nor prevents their free interconversion. From the effects of combined derivatizations of cysteine(s), arginine(s) and serine(s), it is concluded that the functionally relevant aminoacid residues lie in a close spatial arrangement. Also, in this study, the PMSF-modified serine(s) is shown to be involved in bilirubin binding by bilitranslocase.     

On the mechanism of bilitranslocase transport inactivation by phenylmethylsulphonyl fluoride

Bilitranslocase is a plasma membrane carrier involved in the uptake of bilirubin and other organic anions from the blood into the liver cell. In the membrane, the carrier occurs as two interchangeable metastable forms, with high and low affinity for the substrates, respectively. The latter form can be specifically produced by either cysteine- or arginine modification. In liver plasma membrane vesicles, the serine-specific reagent phenylmethylsulphonyl fluoride is a partial inhibitor of bilitranslocase-mediated BSP transport rate. In this work, phenylmethylsulphonyl fluoride is shown to reduce the carrier maximal transport rate, without affecting its affinity for that substrate. In addition, it is found that the chemical modification caused by this reagent neither influences the equilibrium between the high- and the low-affinity forms nor prevents their free interconversion. From the effects of combined derivatizations of cysteine(s), arginine(s) and serine(s), it is concluded that the functionally relevant aminoacid residues lie in a close spatial arrangement. Also, in this study, the PMSF-modified serine(s) is shown to be involved in bilirubin binding by bilitranslocase.     

Evidence for a putative flavonoid translocator similar to mammalian bilitranslocase in grape berries (<Emphasis Type="Italic">Vitis vinifera</Emphasis> L.) during ripening

During maturation, Vitis vinifera berries accumulate a large amount of several anthocyanins in the epidermal tissue, whereas their precursors and intermediates are ubiquitously synthesized within the fruit. Up to date, several mechanisms of flavonoid transport at subcellular level have been hypothesized, but it is not possible to identify a general model applicable in every plant tissue and organ. Recently, a putative anthocyanin carrier, homologue to mammalian bilitranslocase (BTL) (TC 2.A.65.1.1), was found in Dianthus caryophyllus petal microsomes. In the present paper, an immunohistochemical and immunochemical analysis, using an antibody raised against a BTL epitope, evidences the expression and function of such a transporter in V. vinifera berries (cv. Merlot). Specific localisations of the putative carrier within berry tissues together with expression changes during different developmental stages are shown. Water stress induces an increase in protein expression in both skin and pulp samples. A bromosulfalein (BSP) uptake activity, inhibitable by the BTL antibody, is detected in berry mesocarp microsomes, with K (m) = 2.39 microM BSP and V (max) = 0.29 micromol BSP min(-1) mg(-1) protein. This BSP uptake is also competitively inhibited by quercetin (K (i) = 4 microM). A putative role for this carrier is discussed in relation to the membrane transport of secondary metabolites.     

Naringin Glycosides α-Glucosylated on Ring B Found in the Natural Food Additive,Enzymatically Modified Naringin

The constituents of the natural food additive, enzymatically modified naringin, were structurally analyzed. Four constituents were isolated from the glucoamylase-treated sample. An NMR analysis revealed that two of them were novel compounds having 4′-O-α-glucosyl moieties on ring B of the naringenin aglycone. Both the aglycone and the glucose moiety in naringin are shown to be simultaneously glucosylated.     

The sulfhydryl groups responsible for bilitranslocase transport activity respond to the interaction of the carrier with bilirubin and functional analogues

Both inactivation of sulfobromophthalein transport in rat liver plasma membrane vesicles by sulfhydryl group reagents and subsequent reactivation by 2-mercaptoethanol are shown to be modulated by ligands to bilitranslocase. In particular, bilirubin, sulfobromophthalein and Thymol blue behave as negative effectors in the inactivation reaction and as positive effectors in the reactivation reaction. Kinetic data provide further evidence of the existence of two classes of sulfhydryl groups involved in transport activity. The effect brought about by remarkably low concentrations of bilirubin is in line with the physiological function of bilitranslocase as a bilirubin carrier.     

Arginine residues are involved in the transport function of bilitranslocase

Specific guanido group reagents inhibit bilitranslocase transport activity in rat liver plasma membrane vesicles. Their reaction is shown to be affected by sulfobromophthalein, Thymol blue and bilirubin, which are translocated by bilitranslocase across the plasma membrane. It is concluded that the transport function of bilitranslocase depends on arginine residues, which are involved in the interaction with the molecules to be translocated.     

The role of sulfhydryl groups in sulfobromophthalein transport in rat liver plasma membrane vesicles

Sulfobromophthalein (BSP) electrogenic transport activity in a plasma membrane vesicle preparation from rat liver is shown to depend on free sulfhydryl groups. These are organized in two classes, one of which does not react with the sulfhydryl group reagent 5,5'-dithiobis(2-nitrobenzoate). The two classes appear to be involved in BSP transport independently. However, reactivity of one class can be shown to be affected by alkylation of the other. Hence, it is concluded that both classes are located on the same carrier system, which previous research has established to be the integral sinusoidal membrane protein bilitranslocase.     

Common active site architecture and binding strategy of four phenylpropanoid P450s from Arabidopsis thaliana as revealed by molecular modeling

Despite extensive primary sequence diversity, crystal structures of several bacterial cytochrome P450 monooxygenases (P450s) and a single eukaryotic P450 indicate that these enzymes share a structural core of alpha-helices and beta-sheets and vary in the loop regions contacting individual substrates. To determine the extent to which individual structural features are conserved among divergent P450s existing in a single biosynthetic pathway, we have modeled the structures of four highly divergent P450s (CYP73A5, CYP84A1, CYP75B1, CYP98A3) in the Arabidopsis phenylpropanoid pathway synthesizing lignins, flavonoids and anthocyanins. Analysis of these models has indicated that, despite primary sequence identities as low as 13%, the structural cores and several loop regions of these P450s are highly conserved. Substrate docking indicated that all four enzymes employ a common strategy to identify their substrates in that their cinnamate-derived substrates align along helix I with their aromatic ring positioned towards the C-terminus of this helix and their aliphatic tails positioned towards the N-terminus. Further similarity was observed in the way the substrates contact the consensus P450 substrate recognition sites (SRS). Residues predicted to contact the aromatic ring region exist in SRS5, SRS6 and the C-terminal portion of SRS4 and residues contacting the distal end of each substrate exist in SRS1, SRS2 and the N-terminal portion of SRS4. Alignments of the regions contacting the aromatic ring region indicate that SRS4, SRS5 and SRS6 share higher degrees of sequence conservation than found in SRS1, SRS2 or the full-length protein.     

Camptotheca acuminata 10‐hydroxycamptothecin O‐methyltransferase: an alkaloid biosynthetic enzyme co‐opted from flavonoid metabolism

The medicinal plant Camptotheca acuminata accumulates camptothecin, 10‐hydroxycamptothecin, and 10‐methoxycamptothecin as its major bioactive monoterpene indole alkaloids. Here, we describe identification and functional characterization of 10‐hydroxycamptothecin O‐methyltransferase (Ca10OMT), a member of the Diverse subclade of class II OMTs. Ca10OMT is highly active toward both its alkaloid substrate and a wide range of flavonoids in vitro and in this way contrasts with other alkaloid OMTs in the subclade that only utilize alkaloid substrates. Ca10OMT shows a strong preference for the A‐ring 7‐OH of flavonoids, which is structurally equivalent to the 10‐OH of 10‐hydroxycamptothecin. The substrates of other alkaloid OMTs in the subclade bear little similarity to flavonoids, but the 3‐D positioning of the 7‐OH, A‐ and C‐rings of flavonoids is nearly identical to the 10‐OH, A‐ and B‐rings of 10‐hydroxycamptothecin. This structural similarity likely explains the retention of flavonoid OMT activity by Ca10OMT and also why kaempferol and quercetin aglycones are potent inhibitors of its 10‐hydroxycamptothecin activity. The catalytic promiscuity and strong inhibition of Ca10OMT by flavonoid aglycones in vitro prompted us to investigate the potential physiological roles of the enzyme in vivo. Based on its regioselectivity, kinetic parameters and absence of 7‐OMT flavonoids in vivo, we conclude that the major and likely only substrate of Ca10OMTin vivo is 10‐hydroxycamptothecin. This is likely accomplished by Ca10OMT being kept spatially separated at the tissue levels from potentially inhibitory flavonoid aglycones, and flavonoid aglycones being rapidly glycosylated to non‐inhibitory flavonoid glycosides.     

Norrish-Prins reaction as a key step in the synthesis of 14β-hydroxy-5α (or 5β or Δ(5,6))-pregnane derivatives

Numerous bioactive glycosteroids are characterized by aglycones bearing a 14β-hydroxy pregnane skeleton like boucerin and isoramanone. In general, the syntheses of the latter are achieved by acidic hydrolysis of the corresponding glycosteroids. These aglycones were also obtained by a combined Norrish type I-Prins reaction starting from the corresponding 12-keto-pregnane derivatives. However, for the Norrish-Prins reaction, no reports describe the influence of the A/B ring junction (cis or trans or Δ(5,6) double bond) or the influence of the substitution pattern at position 20. Herein, we describe the use of Norrish type I-Prins reactions to synthesize isoramanone and boucerin derivatives and their A/B cis and trans analogs. The influence of the parameters mentioned above is also presented. These studies showed that the A/B ring junction has little influence on the Norrish type I-Prins reaction but that the substitution pattern at position 20 is important. The presence of a dioxolane group induced not only the formation of the desired 14β-hydroxy pregnane derivatives in the highest yields but also the formation of new spiro derivatives.     

The distribution of functional bacteriophage T4 mRNA on polysomes.

Functional bacteriophage T4 deoxynucleotide kinase and α-glucosyl transferase mRNAs can be isolated from polysomes extracted from cells 8 min after infection. At least 55% of the 8-min deoxynucleotide kinase mRNA is associated with polysomes and is released from the cell membrane by deoxyribonuclease (DNase) treatment (soluble mRNA). Approximately 20% of the kinase mRNA remains tightly bound to membrane after DNase treatment (membrane mRNA) and 25% of the kinase mRNA is routinely lost during fractionation. The membrane-bound kinase mRNA is about three times as stable in vitro as the soluble kinase mRNA. Soluble kinase mRNA (14.5S) is found associated with as few as one ribosome and as many as 22 ribosomes; however, 14.5S α-glucosyl transferase mRNA is found predominantly in six ribosome polysomes. The size of the α-glucosyl transferase mRNA is heterogenous, ranging between 14.5 and 20S. The larger α-glucosyl transferase mRNAs are never found on small polysomes but appear only in polysomes containing at least nine ribosomes (18S α-glucosyl transferase mRNA). Maximum-size α-glucosyl transferase mRNA (approximately 20S) appears on polysomes containing at least 14 ribosomes. The relationships between decay of T4 mRNA and polysome size and the location of ribosome loading sites on the 20S α-glucosyl transferase message are also discussed.     

Bilitranslocase is the protein responsible for the electrogenic movement of sulfobromophthalein in plasma membrane vesicles from rat liver: immunochemical evidence using mono- and poly-clonal antibodies

Monoclonal antibodies raised against bilitranslocase, may display either inhibitory or enhancing activity on the electrogenic transport of sulfobromophthalein, evoked in rat liver plasma-membrane vesicles by the addition of valinomycin in the presence of K+. In both cases, the target protein is identified with a 37 kDa band in SDS-mercaptoethanol gel electrophoresis of solubilized membranes. The electrophoretically homogeneous protein isolated by ion-exchange chromatography, corresponds in all respects to the 37 kDa protein band of bilitranslocase, obtained in the past by different techniques. Using this protein as antigen, a polyclonal monospecific antibody preparation has been obtained. As expected, the antibody preparation inhibits the electrogenic movement of sulfobromophthalein in plasma membrane vesicles from rat liver. It is concluded that the 37 kDa protein of bilitranslocase is at least a necessary component of the transport system involved in the sulfobromophthalein movement in plasma membrane.     

New sweet diterpene glucosides from Stevia rebaudiana

From the leaves of Stevia rebaudiana, two new sweet glucosides, rebaudiosides A and B, were isolated besides the known glucosides, stevioside and steviolbioside. On the basis of IR, MS, ¹H and ¹³C NMR as well as chemical evidences, the structure of rebaudioside B was assigned as 13-O-[β-glucosyl(1-2)-β-glucosyl(1-3)]-β-glucosyl-steviol and rebaudioside A was formulated as its β-glucosyl ester.