Benzophenanthridine Alkaloids Sanguinarine Research Articles

Interaction and inhibition of lysozyme amyloid fibrillation by benzophenanthridine alkaloid sanguinarine: Photophysical, molecular docking and imaging studies

Protein misfolding lead to pathological amyloid aggregates causing neurodegenerative disorders. Interaction and effect of benzophenanthridine alkaloid, sanguinarine (SNR hereafter), on lysozyme fibrillation was studied in the quest for designing potent antiamyloidogenics. SNR quenched the intrinsic fluorescence of lysozyme and the quenching mechanism was static. There existed one type of binding site for SNR on lysozyme and TRP residues were mainly involved in binding. 3D-fluorescence studies indicated conformational changes in lysozyme upon complexation with SNR. The binding between lysozyme and SNR was also studied by molecular docking to understand the forces involved in the binding. Effect of SNR on lysozyme fibrillation was examined from Thioflavin T assay which revealed that SNR suppressed the fibrillation of lysozyme significantly. Nile red and ANS assay revealed that SNR arrested the fibrillation. FTIR and circular dichroism showed that β-sheet content of the fibrillar species was reduced by SNR implying fibrillogenesis was inhibited as amyloid fibrils have β-sheet rich structures. AFM also revealed that SNR induced a marked decrease in the fibrillar quantity. These results can be utilized for designing potential drugs for amyloidosis.

PH-sensitive liposomes with benzophenanthridine alkaloid sanguinarine and their cytotoxic activity

The plant alkaloid sanguinarine has antitumour, antiangiogenic, antimicrobial and antiviral activity. However, the maximum manifestation of the therapeutic potential of sanguinarine is hindered by ...

Preparation of Liposomal Sanguinarine and Study of Its Cytotoxic Effects against Prostate Cancer Cells

Benzophenanthridine alkaloid sanguinarine from Macleaya macrocarpa shows antitumor and anti-angiogenic activity, among others. Some side effects of sanguinarine, which significantly limit the possibilities of its therapeutic use, are described. To increase the effectiveness of its therapeutic effect, sanguinarine was introduced into the pH-sensitive liposomes by remote loading using ammonium dihydrogen phosphate. pH-sensitive liposomes, appearing in the acidic environment of the tumor or endosomal compartment, release sanguinarine, which causes the death of tumor cells. The average diameter of the liposome particles measured by the method of dynamic light scattering was 112.6 ± 1.8 nm; the zeta potential was –13.9 ± 1.7 mV. The effectiveness of the inclusion of sanguinarine in liposomes was 89.54 ± 2.13%. The dynamics of release of sanguinarine from the composition of a liposome preparation was studied, and the prolonged release pattern was demonstrated. The cytotoxic activity (CTA) of liposomal sanguinarine against prostate cancer cell lines LNCaP, DU 145, and PC-3 was studied. Liposomal sanguinarine exhibited dose-dependent CTA against cells of all the studied lines in the micromolar range of concentrations. The highest CTA of liposomal sanguinarine was seen against the hormone-sensitive LNCaP cells (IC50 2.86 μM). For the hormone-independent cells of the DU 145 and PC-3 lines, the cytotoxic activity of liposomal sanguinarine was somewhat lower and amounted to 3.37 μM and 3.63 μM, respectively. A dose-dependent induction of apoptosis of LNCaP, DU 145, and PC-3 cells was also demonstrated. The liposomal sanguinarine with high efficiency induced apoptosis of both hormone-sensitive and hormone-independent cells. The liposomal sanguinarine at a concentration of 8 μM induced apoptosis in 93.14% of LNCaP cells, 90.65% of DU 145 cells, and 98.12% of PC-3 cells. Thus, liposomal sanguinarine can be considered as a promising antitumor agent for the therapy of both hormone-sensitive and hormone-independent tumors.

In vitro wound healing of tumor cells: inhibition of cell migration by selected cytotoxic alkaloids

BackgroundCell migration is involved in several pathological processes such as tumor invasion, neoangiogenesis and metastasis. Microtubules are needed in directional migration.MethodsTo investigate the effects of microtubule-binding agents (paclitaxel, vinblastine, colchicine, podophyllotoxin), benzophenanthridine alkaloids (sanguinarine, chelerythrine, chelidonine) and other anti-tumor drugs (homoharringtonine, doxorubicin) on cell migration, we performed the in vitro wound healing assay. The interactions between selected alkaloids and microtubules were studied via U2OS cells expressing microtubule-GFP markers.ResultsThe microtubule-binding natural products paclitaxel, vinblastine, colchicine and podophyllotoxin significantly altered microtubule dynamics in living cells and inhibited cell migration at concentrations below apparent cytotoxicity. The benzophenanthridine alkaloid sanguinarine, chelerythrine and chelidonine which affected microtubules in living cells, did not inhibit cell migration. Homoharringtonine (protein biosynthesis inhibitor) and doxorubicin significantly inhibited cell migration, however, they did not exert obvious effects on microtubules.ConclusionIn this study, we demonstrated that microtubule-binding agents are effective anti-migrating agents; moreover, homoharringtonine and doxorubicin can be referred as anti-migrating agents, but direct microtubule dynamics are not involved in their mode of action. Our study provides evidence that some alkaloids and other microtubule-binding natural products may be interesting candidates for the development of novel agents against metastasis.

Molecular Determinants of Sensitivity or Resistance of Cancer Cells Toward Sanguinarine.

For decades, natural products represented a significant source of diverse and unique bioactive lead compounds in drug discovery field. In Clinical oncology, complete tumors remission is hampered by the development of drug-resistance. Therefore, development of cytotoxic agents that may overcome drug resistance is urgently needed. Here, the natural benzophenanthridine alkaloid sanguinarine has been studied for its cytotoxic activity against multidrug resistance (MDR) cancer cells. We investigated the role of the ATP-binding cassette (ABC) transporters BCRP/ABCG2, P-glycoprotein/ABCB1 and its close relative ABCB5 in drug resistance. Further drug resistance mechanisms analyzed in this study were the tumor suppressor TP53 and the epidermal growth factor receptor (EGFR). Multidrug resistant cells overexpressing BCRP, ABCB5 and mutated ΔEGFR were not cross-resistant toward sanguinarine. Interestingly, P-gp overexpressing cells were hypersensitive to sanguinarine. Doxorubicin uptake assay carried by flow cytometry revealed that sanguinarine is a potent inhibitor of the P-gp transporter. Moreover, immunoblotting analysis proved that P-gp was downregulated in a dose dependent manner after treating P-gp overexpressing cells with sanguinarine. It was surmised that The inhibition of NFκB activity might explain the collateral sensitivity in CEM/ADR5000 cells. The COMPARE and hierarchical cluster analyses of transcriptome-wide expression profiles of tumor cell lines of the National Cancer Institute identified genes involved in various cellular processes (immune response, inflammation signaling, cell migration and microtubule formation) significantly correlated with log10IC50 values for sanguinarine. In conclusion, sanguinarine may have therapeutic potential for treating multidrug resistant tumors.

Preparation of liposomes containing benzophenanthridine alkaloid sanguinarine and evaluation of its cytotoxic activity

Sanguinarine is a plant alkaloid with relatively low toxicity and high antiangiogenic, antitumour and antiviral potential. In order to increase its bioavailability and effectiveness, sanguinarine liposomes were prepared by a reverse phase evaporation method and characterised. Dynamic light scattering showed mean liposome size of 65 ± 11 nm, zeta-potential equal to -54 ± 1.2 mV, and polydispersity index equal to 0.26. The encapsulation efficiency was 78.6 ± 5.1%. The study on experimental models showed a prolonged sanguinarine release from liposome preparations. Liposomal sanguinarine showed dose-dependent cytotoxic activity in vitro on B16 (murine melanoma) and HeLa (human cervical carcinoma) cell lines. The highest cytotoxicity was observed on B16 cell line (IC50 6.5 μM). HeLa cell line cytotoxicity was relatively lower, equal to 8.03 μМ. Compared with free sanguinarine, liposomal sanguinarine may have advantages for in vivo anticancer therapy, due to its lower toxicity and 'passive targeting' as a result of enhanced permeability of tumour vessels.

Small molecule–RNA recognition: Binding of the benzophenanthridine alkaloids sanguinarine and chelerythrine to single stranded polyribonucleotides

Single stranded RNAs are biologically potent as they participate in various key cellular processes. The binding efficacy of two potent anticancer alkaloids, sanguinarine (here after SANG) and chelerythrine (here after CHEL), with single-stranded ribonucleic acids poly(rI), poly(rG), and poly(rC) were studied using spectroscopic and thermodynamic tools. Results reveal that both SANG and CHEL binds well with single stranded RNAs with affinity in the order poly(rI)>poly(rG)>poly(rC). CHEL showed slightly higher affinity compared to SANG with all the single stranded RNAs. Both SANG and CHEL showed association affinity of the lower 106 order with poly(rI), higher 105 order binding with poly(rG) and lower 105 order with poly(rC). The binding mode was partial intercalation due to the staking interaction between the bases and the alkaloids. The complexation of both the SANG and CHEL to the RNAs were mainly enthalpy driven and also favoured by entropy changes. Perturbation was observed in the RNA conformation due to binding of the alkaloids. In this present study we have deciphered the fundamental structural and calorimetric aspects of the interaction of the natural benzophenanthridine alkaloids with single stranded RNAs and these results may help to develop new generation alkaloid based therapeutics targeting single stranded RNAs.

Antitumor effects of the benzophenanthridine alkaloid sanguinarine: Evidence and perspectives.

Historically, natural products have represented a significant source of anticancer agents, with plant-derived drugs becoming increasingly explored. In particular, sanguinarine is a benzophenanthridine alkaloid obtained from the root of Sanguinaria canadensis, and from other poppy Fumaria species, with recognized anti-microbial, anti-oxidant and anti-inflammatory properties. Recently, increasing evidence that sanguinarine exibits anticancer potential through its capability of inducing apoptosis and/or antiproliferative effects on tumor cells, has been proved. Moreover, its antitumor seems to be due not only to its pro-apoptotic and inhibitory effects on tumor growth, but also to its antiangiogenic and anti-invasive properties. Although the precise mechanisms underlying the antitumor activity of this compound remain not fully understood, in this review we will focus on the most recent findings about the cellular and molecular pathways affected by sanguinarine, together with the rationale of its potential application in clinic. The complex of data currently available suggest the potential application of sanguinarine as an adjuvant in the therapy of cancer, but further pre-clinical studies are needed before such an antitumor strategy can be effectively translated in the clinical practice.

Synergistic antibacterial activity of the combination of the alkaloid sanguinarine with EDTA and the antibiotic streptomycin against multidrug resistant bacteria.

Drug combinations consisting of the DNA intercalating benzophenanthridine alkaloid sanguinarine, the chelator EDTA with the antibiotic streptomycin were tested against several Gram-positive and Gram-negative bacteria, including multi-resistant clinical isolates. Microdilution, checkerboard and time kill curve methods were used to investigate the antibacterial activity of the individual drugs and the potential synergistic activity of combinations. Sanguinarine demonstrated a strong activity against Gram-positive and Gram-negative bacteria (minimum inhibitory concentrations, MIC = 0.5-128 μg/ml), while streptomycin was active against Gram-negative strains (MIC = 2-128 μg/ml). EDTA showed only bacteriostatic activity. Indifference to synergistic activity was seen in the two-drug combinations sanguinarine + EDTA and sanguinarine + streptomycin (fractional inhibitory concentration index = 0.1-1.5), while the three-drug combination of sanguinarine + EDTA + streptomycin showed synergistic activity against almost all the strains (except methicillin-resistant Staphylococcus aureus), as well as a strong reduction in the effective doses (dose reduction index = 2-16 times) of sanguinarine, EDTA and streptomycin. In time kill studies, a substantial synergistic interaction of the three-drug combination was detected against Escherichia coli and Klebsiella pneumoniae. The combination of drugs, which interfere with different molecular targets, can be an important strategy to combat multidrug resistant bacteria.

Synergism of three-drug combinations of sanguinarine and other plant secondary metabolites with digitonin and doxorubicin in multi-drug resistant cancer cells

We determined the ability of some phytochemicals, including alkaloids (glaucine, harmine, and sanguinarine), phenolics (EGCG and thymol), and terpenoids (menthol, aromadendrene, β-sitosterol-O-glucoside, and β-carotene), alone or in combination with the saponin digitonin to reverse the relative multi-drug resistance of Caco-2 and CEM/ADR5000 cells to the chemotherapeutical agent doxorubicin. The IC50 of doxorubicin in Caco-2 and CEM/ADR5000 was 4.22 and 44.08μM, respectively. Combination of non-toxic concentrations of individual secondary metabolite with doxorubicin synergistically sensitized Caco-2 and CEM/ADR5000 cells, and significantly enhanced the cytotoxicity of doxorubicin. Furthermore, three-drug combinations (secondary metabolite+digitonin+doxorubicin) were even more powerful. The best synergist was the benzophenanthridine alkaloid sanguinarine. It reduced the IC50 value of doxorubicin 17.58-fold in two-drug combinations (sanguinarine+doxorubicin) and even 35.17-fold in three-drug combinations (sanguinarine+digitonin+doxorubicin) in Caco-2 cells. Thus synergistic drug combinations offer the possibility to enhance doxorubicin efficacy in chemotherapy.

Antitumor effects of the benzophenanthridine alkaloid sanguinarine in a rat syngeneic model of colorectal cancer

To evaluate the in-vivo preclinical antitumor activity of sanguinarine in a rat syngeneic model of colorectal cancer. The effects of sanguinarine on DHD/K12/TRb colorectal adenocarcinoma cells were first evaluated in vitro by means of ³H-thymidine incorporation, 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium) (MTS) assay, and terminal transferase dUTP nick end labeling (TUNEL) microscopy. For the in-vivo studies, DHD/K12/TRb cells (1.5 × 10⁶ cells/0.3 ml of sterile saline/animal) were injected subcutaneously in syngeneic BDIX rats, which were chronically treated with sanguinarine (5 mg/kg/day per os) or control diluent. Tumor growth, body weight, hematologic, and clinical chemistry measurements were monitored in individual animals at defined time intervals. After killing, subcutaneous tumors were explanted from experimental animals for histopathological examination. In vitro, micromolar concentrations of sanguinarine inhibited dose-dependently DHD/K12/TRb cell proliferation and metabolism and induced cell death by apoptosis. In vivo, oral administration of sanguinarine induced a significant inhibition of tumor growth (P<0.01 vs. untreated controls), in the absence of any toxic or side effects. Marked apoptosis and reduced peritumoral vascularization were observed in tumors from sanguinarine-treated rats as compared with the controls. Additional basic studies are needed to fully characterize the mechanism/s underlying the inhibitory effects of sanguinarine on angiogenesis and tumor growth as well as the pharmacological and safety profile of this drug in experimental tumor models. Overall, findings from this study suggest that sanguinarine is a likely candidate for further evaluation in cancer therapy.

Differential effect of the benzophenanthridine alkaloids sanguinarine and chelerythrine on glycine transporters

Glycine transporter inhibitors modulate the transmission of pain signals. Since it is well known that extracts from medicinal plants such as Chelidonium majus exhibit analgesic properties, we investigated the effects of alkaloids typically present in this plant on glycine transporters. We found that chelerythrine and sanguinarine selectively inhibit the glycine transporter GlyT1 with comparable potency in the low micromolar range while berberine shows no inhibition at all. At this concentration both alkaloids only minimally affected transport of the closely related glycine transporter GlyT2, suggesting that the effect is not mediated by the inhibitory activity of these alkaloids on the Na +/K + ATPase. GlyT1 inhibition was time-dependent, noncompetitive and increased with glycine concentration. While chelerythrine inhibition was reversible, the effect of sanguinarine was resistant to wash out. These results suggest that benzophenanthridine alkaloids interact with glycine transporters and at low micromolar range selectively target glycine transporter GlyT1.

Sanguinarine causes DNA damage and p53-independent cell death in human colon cancer cell lines

The benzophenanthridine alkaloid sanguinarine has antimicrobial and possibly anticancer properties but it is not clear to what extent these activities involve DNA damage. Thus, we studied its ability to cause DNA single and double strand breaks, as well as increased levels of 8-oxodeoxyguanosine, in human colon cancer cells and found DNA damage consistent with oxidation. Since the tumor suppressor p53 is frequently involved in inducing apoptosis following DNA damage we investigated the effect of sanguinarine in wild type, p53-mutant and p53-null colon cancer cell lines. We found them to be equally sensitive to this plant compound, indicating that cell death is not mediated by p53 in this case. In addition, our observation that apoptosis induced by sanguinarine is initiated very rapidly raised the question whether there is enough time for cellular signaling in response to DNA damage. Moreover, the abundance of double strand breaks is not consistent with only oxidative damage to DNA. We conclude that the majority of DNA double strand breaks in sanguinarine-treated cells are likely the result, rather than the cause, of apoptotic cell death and that apoptosis induced by sanguinarine is independent of p53 and most likely independent of DNA damage.

The prokaryotic cytoskeleton: a putative target for inhibitors and antibiotics?

In the recent decade, our view on the organization of the bacterial cell has been revolutionized by the identification of cytoskeletal elements. Most bacterial species have structural homologs of actin and tubulin that assemble into dynamic, filamentous structures at precisely defined sub-cellular locations. The essential cell division protein FtsZ forms a dynamic ring at mid-cell and is similar in its structure to tubulin. Proteins of the MreB family, which are structural homologs of actin, assemble into helical or straight filaments in the bacterial cytoplasm. As in eukaryotic cells, the bacterial cytoskeleton drives essential cellular processes such as cell division, cell wall growth, DNA movement, protein targeting, and alignment of organelles. Different high-throughput assays have been developed to search for inhibitors of components of the bacterial cytoskeleton. Cell-based assays for the detection of cell division inhibitors as well as FtsZ GTPase assays led to the identification of several compounds that inhibit the polymerization of FtsZ, by this blocking bacterial cell division. Such inhibitors might not only be valuable tools for basic research, but might also lead to novel therapeutic agents against pathogenic bacteria. For example, the polyphenol dichamanetin, the 2-alkoxycarbonylaminopyridine SRI-3072, and the benzophenanthridine alkaloid sanguinarine inhibit the GTPase activity of FtsZ and exhibit antimicrobial activity.

DNA-binding affinities and sequence selectivity of quaternary benzophenanthridine alkaloids sanguinarine, chelerythrine, and nitidine

A comparative study on the intercalating binding of sanguinarine, chelerythrine, and nitidine with CT DNA, poly(dG–dC)·poly(dG–dC), poly(dA–dT)·poly(dA–dT), and seven sequence-designed double-stranded oligodeoxynucleotides has been performed using fluorometric and spectrophotometric techniques, aiming at providing insights into their sequence selectivity for DNA-binding. The results show that both sanguinarine and nitidine bind preferentially to DNA containing alternating GC base pairs [d(TGCGCA) 2], while chelerythrine exhibits quite distinct sequence selectivity from sanguinarine, which shows a high specificity for DNA containing contiguous GC base pairs [5′-TGGGGA-3′/3′-ACCCCT-5′].

The benzophenanthridine alkaloid sanguinarine perturbs microtubule assembly dynamics through tubulin binding

Sanguinarine has been shown to inhibit proliferation of several types of human cancer cell including multidrug-resistant cells, whereas it has minimal cytotoxicity against normal cells such as neutrophils and keratinocytes. By analyzing the antiproliferative activity of sanguinarine in relation to its effects on mitosis and microtubule assembly, we found that it inhibits cancer cell proliferation by a novel mechanism. It inhibited HeLa cell proliferation with a half-maximal inhibitory concentration of 1.6 +/- 0.1 microM. In its lower effective inhibitory concentration range, sanguinarine depolymerized microtubules of both interphase and mitotic cells and perturbed chromosome organization in mitotic HeLa cells. At concentrations of 2 microM, it induced bundling of interphase microtubules and formation of granular tubulin aggregates. A brief exposure of HeLa cells to sanguinarine caused irreversible depolymerization of the microtubules, inhibited cell proliferation, and induced cell death. However, in contrast with several other microtubule-depolymerizing agents, sanguinarine did not arrest cell cycle progression at mitosis. In vitro, low concentrations of sanguinarine inhibited microtubule assembly. At higher concentrations (> 40 microM), it altered polymer morphology. Further, it induced aggregation of tubulin in the presence of microtubule-associated proteins. The binding of sanguinarine to tubulin induces conformational changes in tubulin. Together, the results suggest that sanguinarine inhibits cell proliferation at least in part by perturbing microtubule assembly dynamics.

Apoptotic response of uveal melanoma cells upon treatment with chelidonine, sanguinarine and chelerythrine

The benzophenanthridine alkaloids sanguinarine, chelerythrine and chelidonine were reported previously to provoke cell death in a variety of tumor cells suggesting their potential application as anticancer agents. Here we tested their effects on a primary human uveal melanoma cell line, OCM-1. Flow cytometric analysis of annexin V binding/PI exclusion and DNA fragmentation disclosed that all these alkaloids could induce apoptosis in OCM-1 cells. Moreover, necrotic cell death was also observed upon alkaloid treatment. As it was also evidenced by light microscopic inspection of cellular morphology, chelidonine primarily caused apoptosis, while sanguinarine and chelerythrine were effective via a so-termed bimodal cell death (apoptosis and primary necrosis). The relative efficiencies of the two modes depended on the applied dose. This study is the first implication for the possible use of these alkaloids in the therapy of uveal melanomas, for which no really efficient therapeutic regimen is available so far.

Opportunities of Finding Novel Anti-Infective Agents from Plant Cell Cultures

Higher plants have evolved into efficient biochemical defense mechanisms, which comprised of a wide variety of secondary compounds including alkaloids, flavonoids, terpenoids and saponins. Induction of secondary plant metabolism in cells, tissues and organ cultures do provide a potential alternative to the use of the whole plant or total synthesis of the active components. In vitro manipulation of plant secondary products offers biotechnological techniques to exploit cultured plant cell metabolism. In spite of the fact that very few plant cell processes are operating commercially, the most successful commercial pharmaceuticals produced from undifferentiated cell cultures are antibiotic compounds. The naphthoquinone shikonin from Lithospermum erythrorhizon is an anti-inflammatory, the isoquinoline alkaloid berberine from Coptis japonica is an intestinal antiseptic and the oral antimicrobial benzo-phenanthridine alkaloid sanguinarine from Papaver bracteatum are well known examples. Moreover, intensive research studies is currently devoted to produce the anti-leukaemic alkaloids vinblastine and vincristine from Catharanthus roseus, the antimalaria artemisinin from Artemisia annua and the anti-ovarian cancer taxol from Taxus brevifolis. The scope of this review is to analyze the successful in vitro production examples of antimicrobial agents, to give examples of novel chemical structures produced by plant cell cultures and not reported from the corresponding parent plants and to highlight the poten tial of biotransformation, elicitation and transformation techniques for the production of antiinfective agents from plant cell, tissue and organ cultures. Keywords: antimicrobials, biotransformation, elicitation, hairy roots, plant cell culture

Sanguinarine-induced apoptosis is associated with an early and severe cellular glutathione depletion.

The quaternary benzophenanthridine alkaloid sanguinarine exhibits a broad range of activity, including cytotoxicity against various human tumour and normal cell lines. Here, we examined its potency as an anticancer drug. The differential cytotoxicity against cancer versus normal cells was assessed in vitro by two fluorimetric assays (RRT and Hoechst 33342 dye DNA assays, respectively) in a panel of human solid cancer cell lines and a human fibroblast primary culture. The ability to induce apoptosis was demonstrated in PC3 human prostatic adenocarcinoma cells by analysis of morphological changes, internucleosomal DNA fragmentation, cellular poly(ADP-ribose) polymerase cleavage and caspase 3/7 activation. Production of reactive oxygen species was evaluated by the 2',7'-dichlorofluorescin diacetate assay. Depletion of cellular glutathione content was assessed with the monochlorobimane assay. Sanguinarine markedly inhibited the growth of all tested cells (IC(50) 0.9-3.3 microM) without differential cytotoxicity against normal versus cancer cells. In PC3 cells, continuous treatment with 5 microM sanguinarine induced an early (within 10 min) cellular reduced glutathione depletion insensitive to dithiothreitol or N-acetylcysteine treatment, followed by a caspase 3/7-dependent apoptotic response within 2 h. Complementary assays suggested that the glutathione depletion was initiated by direct reactivity of sanguinarine with reduced glutathione. Taken together, these results show that (1) sanguinarine exhibits no specificity for cancer cells, and (2) its strong cytotoxicity is probably due to a rapid apoptotic response induced by an early and severe glutathione-depleting effect. They also suggest that the clinical usefulness of this alkaloid as an anticancer drug is limited.

Effects of alginate and immobilization by entrapment in alginate on benzophenanthridine alkaloid production in cell suspension cultures of Eschscholtzia californica

The production of benzophenanthridine alkaloids (sanguinarine, chelerythrine and macarpine) in cells of Eschscholtzia californica is enhanced by sodium alginate and by entrapment in Ca2+-alginate. Tyrosine decarboxylase, a key enzyme of alkaloid biosynthesis, is induced by the treatments. Alginate- entrapped cells are elicited over an extended period of time which leads to increased alkaloid biosynthesis (up to 800-fold enhancement). A major portion of alkaloids produced are released into the growth medium.