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Cell Type–Specific Localization of Transcripts Encoding Nine Consecutive Enzymes Involved in Protoberberine Alkaloid Biosynthesis

Department of Biological Sciences, University of Calgary, Calgary, Alberta, T2N 1N4, Canada

² To whom correspondence should be addressed. E-mail pfacchin{at}ucalgary.ca; fax 403-289-9311.

	ABSTRACT

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Molecular clones encoding nine consecutive biosynthetic enzymes that catalyze the conversion of L-dopa to the protoberberine alkaloid (S)-canadine were isolated from meadow rue (Thalictrum flavum ssp glaucum). The predicted proteins showed extensive sequence identity with corresponding enzymes involved in the biosynthesis of related benzylisoquinoline alkaloids in other species, such as opium poppy (Papaver somniferum). RNA gel blot hybridization analysis showed that gene transcripts for each enzyme were most abundant in rhizomes but were also detected at lower levels in roots and other organs. In situ RNA hybridization analysis revealed the cell type–specific expression of protoberberine alkaloid biosynthetic genes in roots and rhizomes. In roots, gene transcripts for all nine enzymes were localized to immature endodermis, pericycle, and, in some cases, adjacent cortical cells. In rhizomes, gene transcripts encoding all nine enzymes were restricted to the protoderm of leaf primordia. The localization of biosynthetic gene transcripts was in contrast with the tissue-specific accumulation of protoberberine alkaloids. In roots, protoberberine alkaloids were restricted to mature endodermal cells upon the initiation of secondary growth and were distributed throughout the pith and cortex in rhizomes. Thus, the cell type–specific localization of protoberberine alkaloid biosynthesis and accumulation are temporally and spatially separated in T. flavum roots and rhizomes, respectively. Despite the close phylogeny between corresponding biosynthetic enzymes, distinct and different cell types are involved in the biosynthesis and accumulation of benzylisoquinoline alkaloids in T. flavum and P. somniferum. Our results suggest that the evolution of alkaloid metabolism involves not only the recruitment of new biosynthetic enzymes, but also the migration of established pathways between cell types.

	INTRODUCTION

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Plants produce a vast array of secondary metabolites in response to biotic or abiotic interactions with their environment, which impart flavor, color, and fragrance, and confer protection through a variety of antimicrobial, pesticidal, and pharmacological properties. Because of their specific biological functions and inherent cytotoxicity, many secondary metabolites accumulate in distinct organs and tissues. For example, colorful flavonoids and aromatic terpenoids often accumulate in distinct floral and fruit tissues to attract animals involved in pollination and seed dispersal, respectively. The tissue-specific localization of secondary metabolites demonstrates the role of plant developmental processes in the biochemical specialization of cell types involved in the biosynthesis and/or accumulation of natural products. Enzymes and gene transcripts involved in the biosynthesis of phenylpropanoids (Reinold and Hahlbrock, 1997; Saslowsky and Winkel-Shirley, 2001), terpenoids (McCaskill et al., 1992), and alkaloids (St-Pierre et al., 1999; Suzuki et al., 1999; Moll et al., 2002; Bird et al., 2003) have been localized to a variety of cell types in plants. However, the cell type–specific localization of most secondary metabolic pathways has not been characterized.

Alkaloids are a large and diverse group of nitrogenous secondary metabolites found in 20% of plant species. Although plant alkaloids are most often derived from certain amino acids, metabolic pathways leading to different alkaloid types are generally unrelated in terms of both biosynthesis and phylogeny. A complex and diversified relationship between cellular differentiation and alkaloid metabolism has emerged. Gene transcripts and enzymes involved in the biosynthesis of monoterpenoid indole alkaloids show differential localization to the internal phloem (Burlat et al., 2004), epidermis, laticifers, and idioblasts (St-Pierre et al., 1999; Irmler et al., 2000) in leaves of Catharanthus roseus. In C. roseus roots, monoterpenoid indole alkaloid biosynthetic gene transcripts and enzymes were localized to the protoderm and cortical cells near the apical meristem. Tropane alkaloids are also produced near the root apex but accumulate in aerial organs (Facchini, 2001). Biosynthetic enzymes or gene transcripts involved in the initial and final steps of tropane alkaloid biosynthesis were colocalized to the pericycle (Hashimoto et al., 1991; Suzuki et al., 1999), whereas an intermediate enzyme was found in the adjacent endodermis and nearby cortical cells in Atropa belladonna and Hyoscyamus muticus (Nakajima and Hashimoto, 1999). Pyrrolizidine alkaloids also accumulate in aerial organs but are synthesized in endodermal and cortical cells immediately adjacent to the phloem in roots of Senecio vernalis (Moll et al., 2002) or throughout the cortex in roots of Eupatorium cannabinum (Anke et al., 2004). In Papaver somniferum, benzylisoquinoline alkaloids accumulate in specialized laticifers, but biosynthetic gene transcripts and enzymes are restricted to companion cells and sieve elements, respectively (Facchini and De Luca, 1995; Bird et al., 2003). Overall, a remarkable variety of cell types have been implicated in the biosynthesis and/or accumulation of alkaloids in plants.

Benzylisoquinoline alkaloids are a diverse group of more than 2500 products with potent pharmacological activity, including the analgesic morphine, the neuromuscular blocker (+)-tubocurarine, and the antimicrobials sanguinarine and berberine. Benzylisoquinoline alkaloid biosynthesis begins with the conversion of L-Tyr to dopamine and 4-hydroxyphenylacetaldehyde via a lattice of ortho-hydroxylations, deaminations, and decarboxylations (Figure 1). Dopamine is derived from L-dopa via an aromatic amino acid decarboxylase (tyrosine/dopa decarboxylase [TYDC]) and condenses with 4-hydroxyphenylacetaldehyde to yield (S)-norcoclaurine, the central precursor to all benzylisoquinoline alkaloids. (S)-Norcoclaurine is converted to (S)-reticuline by a (S)-norcoclaurine-6-O-methyltransferase (6OMT), an N-methyltransferase [(S)-coclaurine-N-methyltransferase; CNMT], a P450-dependent hydroxylase [(S)-N-methylcoclaurine-3'-hydroxylase; CYP80B], and a 4'-O-methyltransferase [(S)-3'-hydroxy-N-methylcoclaurine-4'-O-methyltransferase; 4'OMT] (Figure 1). (S)-Reticuline is a key branch-point intermediate in the biosynthesis of most benzylisoquinoline alkaloids, including those with a morphinan (e.g., morphine), benzophenanthridine (e.g., sanguinarine), or protoberberine (e.g., berberine) nucleus. The conversion of (S)-reticuline to (S)-scoulerine via the berberine bridge enzyme (BBE) represents the first committed step in benzophenanthridine and protoberberine alkaloid biosynthesis (Figure 1). In plants that produce protoberberine alkaloids, (S)-scoulerine-9-O-methyltransferase (SOMT) catalyzes the conversion of (S)-scoulerine to (S)-tetrahydrocolumbamine, which is converted by a P450-dependent enzyme [(S)-canadine synthase; CYP719A] to (S)-canadine via methylenedioxy bridge formation (Figure 1). Oxidation of (S)-canadine to berberine is catalyzed by an iron-dependent (S)-canadine oxidase in Coptis japonica and Thalictrum minus or a flavinylated (S)-tetrahydroprotoberberine oxidase in Berberis stolonifera.

View larger version (14K): [in this window] [in a new window]   Figure 1. The Corresponding cDNAs for Nine Consecutive Enzymes Involved in Protoberberine Alkaloid Biosynthesis Have Been Isolated. TYDC, tyrosine/dopa decarboxylase; 6OMT, (S)-norcoclaurine-6-O-methyltransferase; CNMT, (S)-coclaurine N-methyltransferase; CYP80B, (S)-N-methylcoclaurine-3'-hydroxylase; 4'OMT, (S)-3'-hydroxy-N-methylcoclaurine-4'-O-methyltransferase; BBE, berberine bridge enzyme; SOMT, (S)-scoulerine-9-O-methyltransferase; CYP719A, (S)-canadine synthase.

	RESULTS

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Molecular Cloning of the Protoberberine Alkaloid Pathway from T. flavum
We recently isolated a cDNA encoding (S)-norcoclaurine synthase (NCS) from a T. flavum cell suspension culture library (Samanani and Facchini, 2001, 2002; Samanani et al., 2004). Benzylisoquinoline alkaloid biosynthetic genes from C. japonica and P. somniferum were used as heterologous probes to isolate cDNAs encoding eight additional protoberberine alkaloid biosynthetic enzymes from T. flavum. Full-length genomic clones encoding 6OMT (Morishige et al., 2000), CNMT (Choi et al., 2002), 4'OMT (Morishige et al., 2000), SOMT (Takeshita et al., 1995), CYP80B (Ikezawa et al., 2003), and CYP719A (Ikezawa et al., 2003) were amplified from C. japonica genomic DNA by PCR using gene-specific primers. Genetic sequences encoding TYDC (Facchini and De Luca, 1994) and BBE (Facchini et al., 1996) from P. somniferum were reported previously. Each heterologous probe was used to screen 2 x 10⁵ plaque-forming units from the T. flavum cDNA library under high stringency hybridization conditions. Several independent clones with identical nucleotide sequences were obtained for each protoberberine alkaloid biosynthetic enzyme, suggesting a single-copy gene for each enzyme in T. flavum. By contrast, a family of 15 genes encoding TYDC was identified in P. somniferum (Facchini and De Luca, 1994), and several genomic homologs of BBE were also detected (Facchini et al., 1996).

The isolated full-length cDNAs exhibited extensive nucleotide and predicted amino acid sequence identity with the C. japonica and P. somniferum clones encoding benzylisoquinoline alkaloid biosynthetic enzymes (Table 1). Alignment of the predicted amino acid sequences showed 84 to 89% identity and 90 to 95% homology between corresponding enzymes from T. flavum and C. japonica and 57 to 79% identity and 76 to 89% homology between equivalent enzymes from T. flavum and P. somniferum, Eschscholzia californica, or Berberis stolonifera. The only notable difference between corresponding enzymes from T. flavum and other benzylisoquinoline alkaloid-producing plants was the absence of a 30–amino acid extension found at the N terminus of SOMT from C. japonica (Takeshita et al., 1995). The function of this apparent N-terminal domain, which was suggested to include a putative signal peptide in C. japonica, is not known.

View larger version (33K): [in this window] [in a new window]   Figure 2. Protoberberine Biosynthetic Gene Transcripts Are Present in Various Organs of T. flavum. RNA gel blot hybridization analysis was performed using 15 µg of total RNA, which was fractionated, transferred to a nylon membrane, and hybridized at high stringency to 32P-labeled cDNAs. Gels were stained with ethidium bromide before blotting to ensure equal loading.

View larger version (140K): [in this window] [in a new window]   Figure 3. Protoberberine Alkaloid Biosynthetic Gene Transcripts Are Localized to the Immature Endodermis and Surrounding Tissues in T. flavum Roots. (A) to (R) In situ hybridization using DIG-labeled antisense probes for TYDC ([A] and [B]), NCS ([C] and [D]), 6OMT ([E] and [F]), CNMT ([G] and [H]), CYP80B ([I] and [J]), 4'OMT ([K] and [L]), BBE ([M] and [N]), SOMT ([O] and [P]), and CYP719A ([Q] and [R]) performed on cross ([A], [C], [E], [G], [I], [K], [M], [O], and [Q]) and longitudinal ([B], [D], [F], [H], [J], [L], [N], [P], and [R]) root sections. (S) and (T) In situ hybridization using a DIG-labeled sense probe for CYP719A performed on cross (S) and longitudinal (T) root sections. Bar = 50 µm for (A) to (T).

View larger version (170K): [in this window] [in a new window]   Figure 4. Protoberberine Alkaloid Biosynthetic Gene Transcripts Are Localized to the Protoderm of Leaf Primordia in T. flavum Rhizomes. (A) Rhizome longitudinal section stained with toluidine blue O. (B) to (K) In situ hybridization using DIG-labeled antisense probes for TYDC (B), NCS (C), 6OMT ([D] and [K]), CNMT (E), CYP80B (F), 4'OMT (G), BBE (H), SOMT (I), and CYP719A (J) performed on longitudinal ([B] to [J]) and cross (K) rhizome sections. (L) In situ hybridization using a DIG-labeled sense probe for CYP719A performed on a longitudinal rhizome section. Yellow and red asterisks in (A) show the location of leaf primordia and axillary buds, respectively. Bar = 250 µm in (A) and 50 µm in (L). Bar in (L) also applies to (B) to (K).

Cell Type–Specific Localization of Protoberberine Alkaloids in Roots and Rhizomes
Protoberberine alkaloids can be readily visualized in fresh plant tissues because of the bright yellow color of berberine and related compounds. Protoberberine alkaloids were apparent along the length of T. flavum roots but were absent from segments extending 4 mm basipetal to the apical meristem (Figure 5A). The yellow color gradually became visible in root segments displaying maximum root hair extension. Quaternary protoberberine alkaloids, such as berberine, also exhibit strong yellow fluorescence under UV illumination at certain wavelengths. The fluorescence characteristics of T. flavum roots at various stages of development were examined (Figures 5D to 5F). In root sections near the apical meristem, an epidermis surrounded about five cortical cell layers, which enclosed a central stele (Figure 5B). The autofluorescence of the cell walls indicated the presence of an exodermis and an endodermis within the cortex (Figure 5B). The lignified secondary wall of the xylem elements also fluoresced strongly. In young roots lacking secondary growth, a yellow fluorescence corresponding to protoberberine alkaloids was absent (Figure 5B). When the root reached 4 mm in diameter, secondary growth was identified by the periclinal division of pericycle cells internal to the endodermis (Figure 5C). By contrast, the endodermis showed anticlinal division and expansion at the onset of secondary growth, and an abundance of protoberberine alkaloids appeared in the endodermal cells (Figure 5C). The endodermis continued to undergo extensive anticlinal cell division and expansion and ultimately displaced all external tissues in mature roots (Figure 5D), which expanded to 6 mm in diameter at the base of the stem. Protoberberine alkaloid accumulation was confined to the outermost region of mature roots, including the endodermis (Figure 5D) and three to four layers of adjacent pericycle cells (data not shown).

View larger version (34K): [in this window] [in a new window]   Figure 5. Protoberberine Alkaloids Accumulate in the Mature Endodermis of Roots, and in the Pith and Cortex of Rhizomes, in T. flavum. (A) to (D) Accumulation of protoberberine alkaloids in a fresh whole root (A) shown by light microscopy and in 0.5-mm cross sections of fresh roots at various stages of development ([B] to [D]) revealed by epifluorescence microscopy. (E) and (F) Accumulation of protoberberine alkaloids in fresh longitudinal sections (E) and cross sections (F) of a rhizome shown by light microscopy. ap, apical meristem; co, cortex; en, endodermis; ep, epidermis; ex, exodermis; pe, petiole; pi, pith; ro, root; va, vascular tissue. Bars = 500 µm in (A), 40 µm in (B) to (D), and 500 µm in (E) and (F).

	DISCUSSION

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We have shown that the cell type–specific localization of protoberberine alkaloid biosynthetic gene transcripts and product accumulation are temporally and spatially separated in T. flavum roots and rhizomes, respectively. A model depicting these relationships is shown in Figure 6. In roots, gene transcripts for nine consecutive biosynthetic enzymes (essentially the entire pathway) were localized to immature endodermis, pericycle, and, in some cases, adjacent cortical cells proximal to the apical meristem (Figure 3). In rhizomes, all gene transcripts were restricted to the protoderm of leaf primordia (Figure 4). By contrast, protoberberine alkaloid accumulation was restricted to the pith and cortex in rhizomes and to mature endodermis after the initiation of secondary growth in roots (Figure 5) but was also found in the pericycle once the endodermis was sloughed off (Samanani et al., 2002). Protoberberine alkaloid biosynthetic enzymes are almost certainly localized to the same cell types as their corresponding gene transcripts. However, immunolocalization studies would provide insight into the stability of these enzymes in the endodermis and pericycle of roots and in the protoderm of leaf primordia. In particular, the temporal distinction between the localization of gene transcripts and alkaloid product accumulation in the root endodermis implies that all biosynthetic enzymes remain active well after mRNA levels are no longer detectable. Nevertheless, our results clearly show that the biosynthesis and accumulation of protoberberine alkaloids in T. flavum are unique with respect to the cell type–specific localization of alkaloid metabolism in other plants (Facchini, 2001), including the evolutionarily related benzylisoquinoline alkaloid pathways in P. somniferum (Bird et al., 2003).

View larger version (26K): [in this window] [in a new window]   Figure 6. The Cell Type–Specific Localization of Protoberberine Alkaloid Gene Transcripts and Product Accumulation Are Temporally and Spatially Distinct in T. flavum Roots and Rhizomes, Respectively. (A) Model showing the relationship between the sites of protoberberine alkaloid biosynthetic gene expression (blue) and alkaloid accumulation (yellow) in a root. (B) Model showing the relationship between the sites of protoberberine alkaloid biosynthetic gene expression (blue) and alkaloid accumulation (yellow) in a rhizome. ap, apical meristem; co, cortex; en, endodermis; pi, pith; va, vascular tissue.

The rhizome and older petioles of T. flavum are conspicuously yellow due to the abundance of protoberberine alkaloids throughout the pith, cortex, and rib parenchyma (Figures 5E and 5F). By contrast, protoberberine alkaloids were confined to endodermal cells in T. flavum roots (Figures 5A to 5D), except in the oldest parts of the root where three to four pericycle cell layers also accumulate alkaloids (Samanani et al., 2002). The initial pale blue autofluorescence of endodermal cells in the young root was due to the presence of phenolics in the cell wall (Figure 5B). Upon the initiation of secondary growth, protoberberine alkaloids were detected in the endodermis (Figures 5C and 5D). In T. flavum, the endodermis remained intact despite a rapid expansion of the stele (Figure 5C) and emerged as the outer cell layer of the mature root (Figure 5D). The accumulation of berberine in the endodermis and, subsequently, in the pericycle ensures the presence of a protective layer of peripheral cells containing potent antimicrobial alkaloids (Samanani et al., 2002).

The tissue-specific biosynthesis and accumulation of protoberberine alkaloids and the unusual development of the endodermis might have evolved as a mechanism to protect roots from soil-borne pathogens and perhaps other harmful organisms. Other antimicrobial secondary metabolites exhibit an abundant accumulation in peripheral root tissues. Saponins have been localized to the epidermal cells of oat (Avena sativa) roots as an initial barrier to fungal infection (Osbourn et al., 1994; Osbourn, 1996). Flavonoids and flavonoid biosynthetic enzymes also accumulate in the epidermis and adjacent cortical cells of Arabidopsis thaliana roots (Saslowsky and Winkel-Shirley, 2001). The tissue-specific association of protoberberine alkaloids with the unusual endodermis and pericycle of T. flavum roots suggests that these cells also act as an initial barrier to potential pathogens.

Endodermal and pericycle root tissues have been implicated in the biosynthesis and accumulation of several types of alkaloids. Putrescine N-methyltransferase and hyoscyamine 6ß-hydroxylase catalyze the first and last steps in the biosynthesis of the tropane alkaloid scopolamine and are exclusively localized to the pericycle (Hashimoto et al., 1991; Suzuki et al., 1999). Putrescine N-methyltransferase also catalyzes the first step in nicotine biosynthesis and has been localized to endodermis, outer cortex, and xylem tissues in Nicotiana sylvestris (Shoji et al., 2000, 2002). However, tropinone reductase I, an intermediate enzyme in tropane alkaloid metabolism, resides in the endodermis and nearby cortical cells (Nakajima and Hashimoto, 1999); thus, tropane alkaloid pathway intermediates must be transported between cell types. Intercellular translocation of monoterpenoid indole alkaloid pathway intermediates has also been suggested to occur between internal phloem, epidermis, laticifers, and idioblasts in the leaves of C. roseus (St-Pierre et al., 1999; Irmler et al., 2000; Burlat et al., 2004). Moreover, tropane alkaloids and nicotine are transported from roots to shoots for storage (Facchini, 2001). By contrast, protoberberine alkaloid biosynthesis and accumulation in T. flavum roots appear to occur in the same cell, although we cannot rule out the possibility that products are translocated between endodermis and pericycle or transported to other organs. The formation and storage of acridone alkaloids were also associated with endodermis in Ruta graveolens (Junghanns et al., 1998). Localization of alkaloid biosynthetic enzymes to endodermis and pericycle provides efficient access to amino acid precursors from the phloem and to vascular conduits for the systemic transport of metabolic products.

The occurrence of benzylisoquinoline alkaloids in basal angiosperm families suggests an ancient evolutionary origin for this group of secondary metabolites (Facchini et al., 2004). A common phylogeny is supported by the extensive sequence homology among enzymes from different plant families operating at corresponding points in the benzylisoquinoline alkaloid pathway (Table 1). For example, molecular clones encoding BBE, which is involved in the formation of protoberberine and benzophenanthridine alkaloids, have been isolated from members of Papaveraceae, Berberidaceae, and Ranunculaceae and exhibit extensive sequence similarity. Despite the extensive similarity between biosynthetic enzymes, benzylisoquinoline alkaloid metabolism involves vascular cell types in P. somniferum (Bird et al., 2003) and does not involve endodermis, pericycle, protoderm, cortex, or pith tissues as in T. flavum. The emergence of a complex benzylisoquinoline alkaloid pathway in an ancestor common to the basal angiosperms is in contrast with the proposed independent recruitment of pyrrolizidine alkaloid biosynthetic enzymes in at least four different angiosperm lineages (Reimann et al., 2004). Two scenarios have emerged concerning the relationship between the cell type–specific localization and evolutionary origin of plant alkaloids. In the case of pyrrolizidine alkaloids, the differential localization of a key pathway enzyme has been interpreted to support the independent origin of the biosynthetic pathway in various lineages (Anke et al., 2004). By contrast, the differential cell type–specific localization of benzylisoquinoline alkaloid gene transcripts in T. flavum and P. somniferum implicates the migration of established pathways between cell types as a key feature of phytochemical evolution. Thus, it is possible that benzylisoquinoline alkaloid pathways have become established in cell types other than those identified in T. flavum and P. somniferum.

In T. flavum rhizomes, biosynthetic gene transcripts were specifically localized to the protoderm of leaf primordia (Figure 4), which was in sharp contrast with the widespread accumulation of protoberberine alkaloids throughout the cortex and pith (Figures 5E and 5F). The spatial separation of product formation and storage implicates the intercellular transport of protoberberine alkaloids from the protoderm to cortical and pith cells. A molecular clone for a multidrug-resistance protein (MDR)–type ATP binding cassette (ABC) transporter (Cjmdr1), identified as a putative berberine transporter, has been isolated (Yazaki et al., 2001) and characterized (Shitan et al., 2003) from C. japonica. RNA gel blot and in situ hybridization analyses showed the abundant and preferential expression of Cjmdr1 in the rhizome (Yazaki et al., 2001) and suggested the localization of gene transcripts to xylem tissues (Shitan et al., 2003). In C. japonica, berberine accumulates mainly in the rhizome, whereas alkaloid biosynthetic enzymes have been associated with roots (Fujiwara et al., 1993). CjMDR1 was localized to the plasma membrane and suggested to function as an influx pump in the transport of berberine from roots to rhizomes by unloading protoberberine alkaloids from the xylem (Shitan et al., 2003).

The involvement of an ABC transporter in the secretion of berberine into the medium by cultured C. japonica and T. minus cells has also been demonstrated (Sakai et al., 2002; Terasaka et al., 2003). However, cultured T. flavum cells do not secrete berberine into the culture medium, but instead sequester protoberberine alkaloids to the vacuole (N. Samanani and P. Facchini, unpublished results). Vacuolar accumulation of protoberberine alkaloids was also observed in endodermal, pericycle, pith, and cortical cells of T. flavum plants (Samanani et al., 2002). Screening the same T. flavum cell culture cDNA library that contained a multitude of molecular clones encoding protoberberine alkaloid biosynthetic enzymes with Cjmdr1 yielded a low abundance (i.e., one Cjmdr1 cDNA among 300,000 plaque-forming units) partial clone encoding a protein with 94% amino acid identity over the final 143 C-terminal residues (N. Samanani and P. Facchini, unpublished results). Thus, the inability of T. flavum cells to secrete berberine into the culture medium might be due to the low level of a plasma membrane–associated ABC transporter. The sequestration of protoberberine alkaloids to the vacuole suggests a different mechanism of intracellular transport in T. flavum cells. The accumulation of protoberberine alkaloids in the endodermis and pericycle (Samanani et al., 2002) of T. flavum roots also implicates a different transport mechanism compared with C. japonica. It is not known whether berberine biosynthesis in C. japonica roots is associated with endodermis and pericycle, but the products mostly accumulate in the rhizome (Fujiwara et al., 1993). Modulations in the expression and substrate specificity of transporters, such as CjMDR1, might be a major force in the evolution of secondary metabolism in addition to the recruitment of new catalytic functions after gene duplication events (Pichersky and Gang, 2000).

	METHODS

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Plant Cultivation
Thalictrum flavum ssp glaucum seeds were surface sterilized with 20% (v v^–1) sodium hypochlorite for 15 min, rinsed with sterile water, and incubated on phytoagar at 4°C for 14 d. The seeds were transferred to phytagar containing B5 salts and vitamins (Gamborg et al., 1968) supplemented with 100 mg L^–1 myo-inositol, 1 g L^–1 hydrolyzed casein, 20 g L^–1 sucrose, and 5 mg/L of GA₃ and incubated at 23°C. After germination, T. flavum plants were maintained in vitro on phytagar-containing B5 salts and vitamins under a photoperiod of 16 h light/8 h dark at 23°C.

RNA Isolation and Analysis
Total RNA was isolated using the method of Logemann et al. (1987), and poly(A)⁺ RNA was selected by oligo(dT) cellulose chromatography. For gel blot analysis, 15 µg of RNA was fractionated on a 1.0% (w v^–1) agarose gel, containing 7.5% (w v^–1) formaldehyde, before transfer to a nylon membrane. Blots were hybridized with a random primer ³²P-labeled, full-length NCS probe. Hybridizations were performed at 65°C in 0.25 mM sodium phosphate buffer, pH 8.0, 7% (w v^–1) SDS, 1% (w v^–1) BSA, and 1 mM EDTA. Blots were washed at 65°C, twice with 2x SSC and 0.1% (w/v) SDS and twice with 0.2x SSC and 0.1% (w v^–1) SDS (1x SSC is 0.15 M NaCl and 0.015 M sodium citrate, pH 7.0), and autoradiographed with an intensifier at –80°C.

Molecular Cloning of cDNAs Encoding Berberine Biosynthetic Enzymes
A unidirectional oligo(dT)-primed cDNA library constructed in Uni-ZAPII XR (Stratagene, La Jolla, CA) using poly(A)⁺ RNA isolated from T. flavum cell suspension cultures (Samanani et al., 2004) was screened with probes for eight genes encoding enzymes involved in the biosynthesis of berberine, or other benzylisoquinoline alkaloids, from related plant species. The T. flavum NCS cDNA was isolated as described previously (Samanani et al., 2004).

Tissue Fixation and Embedding
Plant materials were immersed in FAA [50% (v v^–1) ethanol, 5% (v v^–1) acetic acid, and 3.7% (v v^–1) formaldehyde] and fixed overnight at 4°C. The tissues were dehydrated using an ethanol/tertiary butanol (t-butanol) series (4:1:5, 5:2:3, 5:3.5:1.5, 4.5:5.5:0, 2.5:7.5:0, and 0:1:0 ethanol:t-butanol:water) with a 2-h incubation in each solution except for the final step, which was overnight. Paraplast Plus (Oxford Labware, St. Louis, MO) was added to a paraffin infiltration series (1:1, 6.7:3.3, and 1:0 wax:t-butanol) with overnight incubations for each step. Embedded tissues were cut into 10-µm sections using an American Optical 620 microtome. Sections were placed onto aminopropyltriethoxysilane-coated slides and incubated overnight at 37°C to firmly adhere sections to the slides.

In Situ RNA Hybridization
The NCS cDNA in pBluescript SK+ was used to synthesize sense and antisense DIG-labeled RNA probes using T3 and T7 RNA polymerases, respectively. DIG-labeled probes were hydrolyzed at 60°C in 40 mM sodium carbonate buffer, pH 10, to produce 200 to 400 nucleotide fragments. The pH was neutralized using 10% (v v^–1) acetic acid and the precipitated RNA resuspended in 50 µL of deionized water. Sections were deparaffinized with xylene and rehydrated using an ethanol series (1:0, 1:0, 9.5:0.5, 7:3, and 1:1 ethanol:water), incubated for 30 min in prehybridization buffer (100 mM Tris-HCl, pH 8.0, and 50 mM EDTA) containing 2 to 10 µg mL^–1 proteinase K (Roche Diagnostics, Indianapolis, IN), and blocked in TBS (10 mM Tris-HCl, pH 7.5, and 150 mM NaCl) containing 2 mg mL^–1 Gly. Sections were postfixed in 3.7% (v v^–1) formaldehyde in PBS (100 mM sodium phosphate buffer, pH 7.2, and 140 mM NaCl), incubated in 100 mM triethanolamine buffer, pH 8.0, containing 0.5% (v v^–1) acetic anhydride, and rinsed in TBS. Slides were inverted onto 100 µL of hybridization buffer (10 mM Tris-HCl, pH 6.8, 10 mM sodium phosphate buffer, pH 6.8, 40% [v v^–1] deionized formamide, 10% [w v^–1] dextran sulfate, 300 mM NaCl, 5 mM EDTA, 1 mg mL^–1 yeast tRNA, 0.8 units mL^–1 RNase inhibitor [Invitrogen, Carlsbad, CA], and 200 to 1000 ng mL^–1 of DIG-RNA) spread over a cover slip. Slides were sealed in a Petri dish lined with filter paper soaked in 50% (v v^–1) formamide, incubated overnight at 50°C, then immersed in 2x SSC at 37°C. Sections were incubated in 50 µg mL^–1 RNase A (Roche Diagnostics) in 500 mM NaCl, 10 mM Tris-HCl, pH 7.5, and 1 mM EDTA for 30 min at 37°C, and washed in 2 liters of the following solutions for 1 h: 2x SSC and 1x SSC at room temperature and 0.1x SSC at 65°C. Slides were rinsed in TBST (10 mM Tris-HCl, pH 7.5, 150 mM NaCl, and 0.3% [v v^–1] Triton X-100), blocked for 1 h in TBST containing 2% (w v^–1) BSA, inverted onto cover slips carrying 100 µL of goat anti-DIG alkaline phosphatase (AP) conjugate (Roche Diagnostics) diluted 1:200 in TBST containing 1% (w v^–1) BSA, incubated for 2 h in sealed Petri dishes lined with TBST-soaked filter paper, and rinsed in TBST buffer. Color development was performed in AP buffer containing 400 µM 5-bromo-4-chloro-3-indolyl phosphate and 428 µM nitroblue tetrazolium for 24 h.

Localization of Berberine in Fresh Tissues
Fresh hand sections of T. flavum roots, rizomes, and petioles were prepared as described previously (Samanani et al., 2002) and examined for the presence of protoberberine alkaloids. A Leica Aristoplan fluorescence microscope (Leica Microsystems, Wetzlar, Germany) was used to detect the autofluorescence of protoberberine alkaloids in root sections using a Leica A-UV filter combination (excitation, 340 to 380 nm; emission, 425 nm). Protoberberine alkaloids were visualized in root and rhizome sections under visible light using a Leica MZ125 stereomicroscope.

Light Microscopy
Results of in situ hybridization were viewed and recorded using a Leica DM RXA2 microscope and a Retiga EX digital camera mounted with a RGB color liquid crystal filter (QImaging, Burnaby, BC, Canada). Images were digitally captured and color corrected using Open Lab version 2.09 (Improvision, Coventry, UK).

Sequence data for T. flavum have been deposited with the EMBL/GenBank data libraries under the following accession numbers: TYDC, AF314150; NCS, AY376412; 6OMT, AY610507; CNMT, AY610508; CYP80B, AY610509; 4'OMT, AY610510; BBE, AY610511; SOMT, AY610512; CYP719A, AY610513; MDR1, AY780675.

	Acknowledgments

 
P.J.F. holds the Canada Research Chair in Plant Biotechnology. S.-U.P. was the recipient of a postdoctoral fellowship from the Alberta Ingenuity Fund. This work was funded by a grant from the Natural Sciences and Engineering Research Council of Canada to P.J.F.

	Footnotes

 
¹ Current address: Biotechnology Industrialization Center, Dongshin University, 880-4, Ansan-Ri, Noan-Myun, Naju, Jeonnam, 520-811, Korea.

The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors (www.plantcell.org) is: Peter J. Facchini (pfacchin{at}ucalgary.ca).

Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.104.028654.

Received October 22, 2004; accepted December 5, 2004.

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