Localization of enzymes and alkaloidal metabolites in Papaver latex

In continuing studies on the metabolic activity of Papaver somniferum, latex has been examined for its enzyme and alkaloidal metabolite content. After an initial centrifugation of latex at 1000g, the pellet which contained a heterogeneous population of dense organelles was further resolved on sucrose gradients. Of the enzymes monitored, acid phosphatase and l-3,4-dihydroxyphenylalanine decarboxylase were found to be in the latex 1000g supernatant, whereas catecholase (polyphenolase) was localized in two distinct organelles within the 1000g sediment. The lighter organelles, sedimenting at 30% sucrose, contained a soluble enzyme which was readily released on organelle plasmolysis, whereas the catecholase found within the heavier organelles, sedimenting at 55–60% sucrose, was membrane bound and showed significant activity only in the presence of Triton X-100. These latter organelles also contained the alkaloids, including morphine and thebaine, and were observed to readily accumulate [¹⁴CH₃]morphine. The alkaloid precursor, dopamine, was localized in the same dense vesicle fraction as the alkaloids. The rate of uptake of [7-¹⁴C]dopamine into these fractions at room temperature, however, was markedly lower than that of morphine. Electron microscopic examination of the organelles of various densities revealed that they possessed different morphology. The results are consistent with the concept that both the 1000g and supernatant fractions of the latex are required for alkaloid biosynthesis and that a sub-population of dense organelles found in the 1000g sediment have at least a function as a storage compartment for both alkaloids and their catecholamine precursor.     

Calpain activity alters in rat myocardial subfractions after ischemia or reperfusion

To examine whether calpain is activated during ischemic or reperfusion injury, we measured calpain activity of the subfractions of rat myocardia after global ischemia for 60 min or the ischemia followed by 30 min reperfusion by the Langendorff procedure. The myocardial homogenate was fractionated into 600 × g, 10 000 × g and 100 000 × g pellet fractions as well as 10 000 × g supernatant fraction. The supernatant fraction was further subjected to DEAE cellulose and phenyl-Sepharose chromatographies to separate μ- and m-calpains. The m-calpain activity of the DEAE fractions after global ischemia for 60 min was higher but that after ischemia-reperfusion was lower than that of the control. On the other hand, the ischemia-reperfusion but not ischemia by itself raised the calpain activity of the phenyl-Sepharose fraction (μ-calpain) and the 10 000 × g pellet measured at 100 μM and 5 mM Ca²⁺. Treatment with verapamil but not with ryanodine during ischemia attenuated the increase in m-calpain activity. A dot-blotting analysis of calpain antigenicity showed a decrease in soluble but no change in the particulate fractions after ischemia-reperfusion. An immunoblotting technique did not detect proteolysis of the calpain 80-kDa subunit. These observations suggest that calpain is activated by Ca²⁺ influx during ischemia and reperfusion without gross changes in its amount. Some unknown processes other than translocation or autolysis are thought to be involved in the alterations.     

Morphine Biosynthesis in Opium Poppy Involves Two Cell Types: Sieve Elements and Laticifers

Immunofluorescence labeling and shotgun proteomics were used to establish the cell type–specific localization of morphine biosynthesis in opium poppy (Papaver somniferum). Polyclonal antibodies for each of six enzymes involved in converting (R)-reticuline to morphine detected corresponding antigens in sieve elements of the phloem, as described previously for all upstream enzymes transforming (S)-norcoclaurine to (S)-reticuline. Validated shotgun proteomics performed on whole-stem and latex total protein extracts generated 2031 and 830 distinct protein families, respectively. Proteins corresponding to nine morphine biosynthetic enzymes were represented in the whole stem, whereas only four of the final five pathway enzymes were detected in the latex. Salutaridine synthase was detected in the whole stem, but not in the latex subproteome. The final three enzymes converting thebaine to morphine were among the most abundant active latex proteins despite a limited occurrence in laticifers suggested by immunofluorescence labeling. Multiple charge isoforms of two key O-demethylases in the latex were revealed by two-dimensional immunoblot analysis. Salutaridine biosynthesis appears to occur only in sieve elements, whereas conversion of thebaine to morphine is predominant in adjacent laticifers, which contain morphine-rich latex. Complementary use of immunofluorescence labeling and shotgun proteomics has substantially resolved the cellular localization of morphine biosynthesis in opium poppy.     

Some differences in intracellular distribution and properties of the chymotrypsin-like esterase activity of human and rabbit neutrophils

The intracellular localization and properties of the chymotrypsin-like esterase activity ($\text{N-}\text{acetyl}\text{-}\text{DL}\text{-}\text{phenlylalanine}\text{β-}\text{naphthyl}$ esterase acitivity) of the rabbit peritoneal neutrophil has been studied and shown to differ from that of the human neutrophil.The major portion of the esterase activity in the rabbit neutrophil is in the 100 000 × g supernatant fraction with distinctly less activity in the lysosomal fraction. The 100 000 × g supernatant contained the highest relative specific activity of any of the subcellular fractions. Rabbit peripheral blood neutrophils gave the same distribution.The 100 000 × g supernatant esterase is 95% esterase 1 and 5% esterase 3, whereas, the lysosomal esterase is 78% esterase 1, 10–16% esterase 2 and 9% esterase 3 as defined by their ability to be inhibited by p-nitrophenyllethyl-5-chloropentylphosphonate. The 100 000 × g supernatant The 100 000 × g supernatant and lysosomal esterase activities further differ in their susceptibility to other inhibitors, their pH optima, ease of elution from DEAE and isoelectric points. Two molecular weight species of 174 000 and 70 000 were found in the 100 000 × g supernatant fraction and extracts of the lysosomal fraction but usually in differing proportions.In confirmation of others, essentially all of the chymotrypsin-like esterase activity ($\text{N-}\text{acetyl}\text{-}\text{DL}\text{-}\text{phenlylalanine}\text{β-}\text{naphthyl}$ esterase activity) of the human neutrophil is in the lysosomal fraction, unlike the rabbit cell. The human neutrophil esterase was less susceptible to inhibition by p-nitrophenylethyl-5-chloropentylphosphonate and diisopropylphosphofluoridate but more susceptible to soybean trypsin inhibitor than rabbit esterase activity. The pH optimum of the human neutrophil esterase differed from either the rabbit lysosomal or 100 000 × g supernatant esterase, as did the isoelectric point and molecular weights.     

Catecholamine-induced phosphorylation of cardiac muscle proteins

The catecholamine-induced phosphorylation of cardiac muscle protein was investigated using a rat ventricular muscle slice preparation. Slices 0.5 mm thick and weighing 40–50 mg were incubated for 40 min in oxygenated bathing medium containing ³²P to partially label intracellular ATP. Subsequent addition of 10^?5 M isoproterenol for 10 min resulted in a 44–63% (based on protein) or a 63–70% (based on inorganic phosphate) increase in ³²P incorporation into 100 000 × g particulate and 100 000 × g supernatant (soluble) fractions without an increase into homogenates, 1000 and 29 000 × g particulate fractions prepared from the slices. The catecholamines also produced a 93% increase in ³²P incorporation ans a 27% increase in inorganic phosphate in trichloroacetic acid-insoluble protein that was obtained from ventricular slice homogenates. A significant increase in the incorporation of ³²P occurred in the 100 000 × g particulate and supernatant fractions and the acid-insoluble protein within 2 and 1 min, respectively. While the β-adrenergic blocking agent propanolol had no effect by itself on ³²P incorporation, it prevented the isoproterenol-induced incorporation of ³²P into the 100 000 × g particulate and supernatant fractions and the acid-insoluble protein. Removal of isoproterenol from the bathing medium eliminated the differences in ³²P incorporation, indicating that the effects of the catecholamine were reversible. Norepinephrine and ipinephrine at 10^?5 M caused phosphorylation effects similar to that of isoproterenol. When the slices were bathed under anoxic conditions isoproterenol failed to enhance the incorporation of ³²P into proteins of the 100 000 ×g particulate and supernatant fractions or acid-insoluble protein. SDS gel eloectrophoresis of ventricular slice homogenates revealed that isoproterenol enhanced the ³²P incorporation into several myocardial proteins having molecular weights of 155, 94 (glycogen phosphorylase), 79, 68–77, and 54–59 · 10³ and decreased the incorporation into a 30 · 10³ dalton protein(s). These results are consistent with the notion that catecholamines may increase the phosphorylation of myocardial proteins in the intact myocardium which in turn may play a role in catecholamine-induced glycogenolysis and augmentation of contractility.     

Ribonucleic acids from barley leaves

1. The total RNA and the RNA present in 27000g pellet (probably composed of chloroplasts, nuclei and mitochondria) and in 27000g supernatant (probably composed of microsomes and soluble proteins) fractions (separated by centrifugation at 27000g of a leaf homogenate prepared in 0·5m-sucrose–0·02m-tris–HCl, pH7·6) of barley leaves were extracted by phenol–sodium lauryl sulphate and their elution profiles on Sephadex G-200 and on ECTEOLA-cellulose anion-exchanger were examined and their nucleotide compositions and the melting curves were determined. 2. The pellet and the supernatant fractions contained respectively about 55% and 20% of the total RNA, whereas 25% of the total RNA was lost during homogenization of the leaf tissue with sucrose–buffer. 3. The total RNA or the RNA from pellet or supernatant fractions, which by its behaviour on Sephadex G-200 columns was found to be predominantly of high molecular weight (i.e. of ribosomal origin), produced about 13 peaks on ECTEOLA-cellulose columns. The RNA species in the pellet and supernatant fractions probably resembled each other in molecular size or secondary structure or both. However, they were present in relatively different amounts in these fractions. 4. The T_m (i.e. the temperature at which 50% of the maximal increase in extinction had occurred) of total RNA and of RNA from pellet fraction was 64·5° whereas T_m of RNA from the supernatant fraction was 73°. The total RNA and the RNA from pellet fraction also resembled each other in nucleotide composition, and the RNA from the supernatant fraction in accordance with its high T_m had a high GMP+CMP content.     

Insulin and glucagon degradation by the kidney I. Subcellular distribution under different assay conditions

Insulin and glucagon degradation by rat kidney homogenates and subcellular fractions was examined under a variety of conditions including high and low substrate concentrations, at pH 4 and pH 7, with and without glutathione. At high insulin concentration (4.1 · 10^?5 M) insulin degradation by the homogenate was greatest at pH 4 but at low insulin concentration (1 · 10^?10 M) insulin degradation was greatest at pH 7. At either high or low glucagon concentration glucagon degradation by the homogenate was greatest at pH 7. Glutathione at pH 7 stimulated insulin degradation at high insulin concentrations and inhibited insulin degradation at low concentrations. Glucagon degradation at pH 7 was inhibited at both high and low concentrations of glucagon by glutathione.Separation of kidney into cortex and medulla prior to homogenation produced a pattern of insulin and glucagon degradation identical to the whole homogenate but glucagon degradation by the medulla was greater than by the cortex.Examination of degradation by subcellular fractions revealed that at high concentration at neutral pH most insulin was degraded by the 100 000 × g pellet but at low insulin concentrations over 90% of the activity was in the 100 000 × g supernatant. At pH 7, at both high and low concentrations, most glucagon-degrading activity was in the 100 000 × g pellet, although the cytosol also had activity. At pH 4 most degradation occurred in the lysosomal fractions.Separation into cortex and medulla again showed similar distribution of activity as the whole gland with the medulla having more glucagon-degrading activity than the cortex. With low insulin concentrations the cortex 100 000 × g supernatant had higher relative specific activities than the medulla supernatant.Examination of recoveries of enzyme activity revealed that the subcellular fractions consistently had markedly less insulin-degrading activity than the original homogenate. This loss of activity was only discernible when insulin degradation was performed at pH 7 at low substrate concentrations. Comparable losses of glucagon-degrading activity were not seen.     

The relationship between l-dopa decarboxylase in the latex of Papaver somniferum and alkaloid formation

The presence of l-dopa decarboxylase has been demonstrated in poppy latex utilising l-dopa-1-[¹⁴C] and l-dopa-3-[¹⁴Cl] as substrates. The enzyme appeared to have maximum activity at pH 7.2 and showed both substrate and pyridoxal phosphate inhibition. The substrates l-tyrosine, l-phenylalanine and l-histidine were also decarboxylated. l-dopa decarboxylase was found to occur solely in the latex supernatant fraction. The possible involvement of this enzyme in alkaloid biosynthesis in the latex is discussed.     

Benzylisoquinoline alkaloid biosynthesis in opium poppy

Opium poppy (Papaver somniferum) is one of the world’s oldest medicinal plants and remains the only commercial source for the narcotic analgesics morphine, codeine and semi-synthetic derivatives such as oxycodone and naltrexone. The plant also produces several other benzylisoquinoline alkaloids with potent pharmacological properties including the vasodilator papaverine, the cough suppressant and potential anticancer drug noscapine and the antimicrobial agent sanguinarine. Opium poppy has served as a model system to investigate the biosynthesis of benzylisoquinoline alkaloids in plants. The application of biochemical and functional genomics has resulted in a recent surge in the discovery of biosynthetic genes involved in the formation of major benzylisoquinoline alkaloids in opium poppy. The availability of extensive biochemical genetic tools and information pertaining to benzylisoquinoline alkaloid metabolism is facilitating the study of a wide range of phenomena including the structural biology of novel catalysts, the genomic organization of biosynthetic genes, the cellular and sub-cellular localization of biosynthetic enzymes and a variety of biotechnological applications. In this review, we highlight recent developments and summarize the frontiers of knowledge regarding the biochemistry, cellular biology and biotechnology of benzylisoquinoline alkaloid biosynthesis in opium poppy.     

Developmental regulation of benzylisoquinoline alkaloid biosynthesis in opium poppy plants and tissue cultures

Summary Opium poppy (Papaver somniferum L.) contains a number of pharmaceutically important alkaloids of the benzylisoquinoline type including morphine, codeine, papaverine, and sanguinarine. Although these alkaloids accumulate to high concentrations in various organs of the intact plant, only the phytoalexin sanguinarine has been found at significant levels in opium poppy cell cultures. Moreover, even sanguinarine biosynthesis is not constitutive in poppy cell suspension cultures, but is typically induced only after treatment with a funga-derived elicitor. The absence of appreciable quantities of alkaloids in dedifferentiated opium poppy cell cultures suggests that benzylisoquinoline alkaloid biosynthesis is developmentally regulated and requires the differentiation of specific tissues. In the 40 yr since opium poppy tissues were first culturedin vitro, a number of reports on the redifferentiation of roots and buds from callus have appeared. A requirement for the presence of specialized laticifer cells has been suggested before certain alkaloids, such as morphine and codeine, can accumulate. Laticifers represent a complex internal secretory system in about 15 plant families and appear to have multiple evolutionary origins. Opium poppy laticifers differentiate from procambial cells and undergo articulation and anastomosis to form a continuous network of elements associated with the phloem throughout much of the intact plant. Latex is the combined cytoplasm of fused laticifer vessels, and contains numerous large alkaloid vesicles in which latex-associated poppy alkaloids are sequestered. The formation of alkaloid vesicles, the subcellular compartmentation of alkaloid biosynthesis, and the tissue-specific localization and control of these processes are important unresolved problems in plant cell biology. Alkaloid biosynthesis in opium poppy is an excellent model system to investigate the developmental regulation and cell biology of complex metabolic pathways, and the relationship between metabolic regulation and cell-type specific differentiation. In this review, we summarize the literature on the roles of cellular differentiation and plant development in alkaloid biosynthesis in opium poppy plants and tissue cultures.     

Cellular localization of tyrosine decarboxylase expression in transgenic opium poppy and tobacco

Opium poppy, Papaver somniferum, is cultivated for its alkaloid-rich latex. Tyrosine decarboxylase (TyDC) is the first enzyme in poppy alkaloid biosynthesis and is encoded by a small gene family. A 2,060-bp promoter fragment of TyDC5 was translationally fused to the #-glucuronidase (GUS) reporter gene and introduced into poppy and tobacco (Nicotiana tabacum). Transgenic seedlings were stained for GUS activity which localized to the xylem parenchyma in the shoots of poppy and tobacco. Roots of both species had similar expression patterns with staining in the vascular cylinder surrounding the xylem. No staining was observed in poppy laticifers suggesting that other TyDC genes may be expressed in latex or that alkaloid precursors are supplied to laticifers by adjacent cells.     

Heterologous expression of alkaloid biosynthetic genes — a review

Tetrahydrobenzylisoquinoline alkaloids comprise a diverse class of secondary metabolites with many pharmacologically active members. The biosynthesis at the enzyme level of at least two tetrahydrobenzylisoquinoline alkaloids, the benzophenanthridine alkaloid sanguinarine in the California poppy, Eschscholtzia californica, and the bisbenzylisoquinoline alkaloid berbamunine in barberry, Berberis stolonifera, has been elucidated in detail starting from the aromatic amino acid (aa) l-tyrosine. In an initial attempt to develop alternate systems for the production of medicinally important alkaloids, one enzyme from each pathway (BBE, a covalently flavinylated enzyme of benzophenanthridine alkaloid biosynthesis and CYP80, a phenol coupling cytochrome P-450-dependent oxidase of bisbenzylisoquinoline alkaloid biosynthesis) has been purified to homogeneity, a partial aa sequence determined, and the corresponding cDNAs isolated with aid of synthetic oligos based on the aa sequences. The recombinant enzymes were actively expressed in Spodoptera frugiperda Sf9 cells using a baculovirus vector, purified and then characterized. Insect cell culture has proven to be a powerful system for the overexpression of alkaloid biosynthetic genes.     

The nonmicrosomal production of N-(4-chlorophenyl)-glycolhydroxamic acid from 4-chloronitrosobenzene by rat liver homogenates

The incubation of 4-chloronitrosobenzene (4-CNB) with subcellular fractions of rat liver resulted in the formation of a previously unknown type of hydroxamic acid metabolite for mammals. This new metabolite, N-(4-chlorophenyl)glycolhydroxamic acid (Gl-CHA), is most likely formed through the action of liver transketolase on the substrate 4-CNB. Gl-CHA was produced only by the 10 000g and 105 000g supernatant fractions, and required glucose-6-phosphate as an energy source. No hydroxamic acid metabolites were produced in detectable quantities by the microsomal fraction of the rat liver homogenate. Gl-CHA was positively identified by isolation and comparison to an authentic sample of Gl-CHA. Authentic Gl-CHA was prepared by the condensation of 4-chlorophenylhydroxylamine with glycolic acid in the presence of dicylohexylcarbodiimide. The highest observed conversion of 4-CNB to Gl-CHA was 18%, which occurred at the lowest concentration of 4-CNB incubated with the 105 000g supernatant. Gl-CHA was not produced by C-hydroxylation of the corresponding acetyl-derived hydroxamic acid, since none of the subcellular fractions of rat liver would effect this conversion. The incubation of 4-chloroaniline under identical conditions failed to result in the production of Gl-CHA; however, such an observation is probably not important to the possibility that Gl-CHA might be a significant metabolite in vivo.     

Intracellular distribution of the steroidal glycoalkaloid α-tomatine in Lycopersicon esculentum fruit

Pericarp tissue from green tomato fruits was homogenized and separated into organelle fractions by differential centrifugation. Tomatine was found mainly in the final (105 000g) supernatant, with small amounts in the microsomes. Expressed sap from intact tissue was also rich in the alkaloid. It is suggested that tomatine accumulates in the vacuoles and/or soluble phase of the cytoplasm and is possibly synthesized in microsomal organelles.     

Some enzymes of general metabolism in the latex of Papaver somniferum

Enzymes of general metabolism have been determined in the latex of Papaver somniferum in an attempt to elucidate further the nature of the 1000 g130 min organelles and their role in alkaloid biogenesis. A number of enzymes involved in the glyoxylic acid and tricarboxylic acid cycles have been found, namely, aconitase, isocitrate dehydrogenase, succinate dehydrogenase, fumarase, malate dehydrogenase and isocitrate lyase. Two enzymes of glycolysis, namely, pyruvate kinase and lactate dehydrogenase, as well as enzymes associated with peroxisomes (glyoxylate reductase, catalase) and lysosomes (arylesterase, acid phosphatase) have been studied. Finally, some enzymes previously reported as occurring in poppy seedlings have been investigated, namely peroxidase, glutamate—oxaloacetate and glutamate-pyruvate transaminases, together with phenylalanine, tyrosine, DOPA and glutamic acid decarboxylases.     

Characterization of arginase activity from mouse epidermis and its relation to ornithine decarboxylase induction by the tumor-promoting agent, 12-O-tetradecanoylphorbol-13-acetate

Arginase, which catalyzes the cleavage of l-arginine to urea and ornithine, was detected in both soluble and particulate fractions of mouse epidermis. In a typical experiment, about 75 and 25% of the total arginase activity was associated with the soluble (100 000 × g supernatant) and the washed particulate fraction, respectively. Both soluble and particulate enzymes required the presence of divalent Mn²⁺ for activity. Arginase activity was increased by about 50% in the particulate fraction, but not in the soluble fraction, by preheating the fractions at either 50 or 55°C in the presence of 15 mM MnCl₂. Enzyme activity in both fractions, in the absence of 15 mM MnCl₂, dropped precipitously during heating. A comparison of the nature of arginases in the soluble and particulate fractions revealed similar K_m values (13 mM) and pH optima (9.5) and identical heat denaturation curves. Application of 10 nmol of 12-O-tetradecanoylphorbol-13-acetate to mouse skin did not increase arginase activity in either fraction over a period of 24 h. In contrast, there was a large increase in ornithine decarboxylase activity in the soluble fraction 4.5 h after treatment. Mouse epidermal ornithine decarboxylase activity was much less than arginase activity and was predominantly localized in the soluble fraction. These results indicate that the normal level of arginase activity is not a limiting factor for the stimulation of polyamine biosynthesis by TPA. High arginase activity in mouse epidermis may play a role in providing ornithine for polyamine biosynthesis and in the production of glutamate and proline as well as in the production of keratinous proteins.