Functional expression and subcellular localization of the Nectria haematococca Mak1 phytoalexin detoxification enzyme in transgenic tobacco.

Medicarpin and maackiain are antifungal pterocarpan phytoalexins produced by many legumes, and are thought to be important components of the defense response of these legumes to certain fungal pathogens. The Mak1 gene from the fungal pathogen Nectria haematococca encodes an FAD-dependent mono-oxygenase, known to specifically hydroxylate the phytoalexins medicarpin and maackiain, converting them to less fungitoxic derivatives. Two binary vector constructs were made containing the coding regions from two fungal clones, a Mak1 cDNA (intronless) and a genomic (including three fungal introns) clone, regulated by an enhanced cauliflower mosaic virus 35S promoter. The constructs were introduced into tobacco to check for expression of active fungal enzyme in plant cells and for splicing of fungal introns. Leaves of tobacco plants transformed with the Mak1 cDNA construct readily metabolized infiltrated medicarpin to 1a-hydroxymedicarpin, indicating high levels of active enzyme. RT-PCR analysis of tobacco plants transformed with the Mak1 genomic construct indicated no processing of Mak1 introns, and no Mak1 activity was detected in these plants. When using plants containing the Mak1 cDNA construct, immunolocalization with a Mak1-specific antibody together with cellular fractionation indicated that Mak1 protein accumulated in the plant cytoplasm, associated with endoplasmic reticulum membranes; medicarpin biosynthetic enzymes have been localized to the same subcellular region. The Mak1 cDNA construct is therefore suitable for use in studies to selectively eliminate medicarpin accumulation to assess the relative importance of medicarpin in the antifungal defense mechanisms of alfalfa and other legumes.

The Medicago Genome Initiative: a model legume database.

The Medicago Genome Initiative (MGI) is a database of EST sequences of the model legume MEDICAGO: truncatula. The database is available to the public and has resulted from a collaborative research effort between the Samuel Roberts Noble Foundation and the National Center for Genome Resources to investigate the genome of M.truncatula. MGI is part of the greater integrated MEDICAGO: functional genomics program at the Noble Foundation (http://www.noble.org ), which is taking a global approach in studying the genetic and biochemical events associated with the growth, development and environmental interactions of this model legume. Our approach will include: large-scale EST sequencing, gene expression profiling, the generation of M.truncatula activation-tagged and promoter trap insertion mutants, high-throughput metabolic profiling, and proteome studies. These multidisciplinary information pools will be interfaced with one another to provide scientists with an integrated, holistic set of tools to address fundamental questions pertaining to legume biology. The public interface to the MGI database can be accessed at http://www.ncgr.org/research/mgi.

An enantiomeric assay for the flavonoids medicarpin and vestitone using capillary electrophoresis.

An enantiomeric assay for the flavonoids vestitone and medicarpin from transgenic plant extracts was developed using capillary electrophoresis. It was found that no single cyclodextrin proved capable of resolving the enantiomers of both medicarpin and vestitone. Instead, hydroxypropyl-beta-cyclodextrin provided the best selectivity for the vestitones while hydroxypropyl-gamma-cyclodextrin was best for the medicarpins. The addition of organic modifiers improved the resolution of both enantiomers. Acetonitrile proved best for the vestitones and only methanol improved the resolution of the medicarpins. An optimization study of mixed hydroxypropyl-beta-cyclodextrin and hydroxypropyl-gamma-cyclodextrin containing electrolytes revealed that the separation of the medicarpin enantiomers was intolerant to the presence of hydroxypropyl-beta-cyclodextrin. Our optimized running electrolyte was composed of 2 mM hydroxypropyl-beta-cyclodextrin, 20 mM hydroxypropyl-gamma-cyclodextrin, and 25 mM borate at pH 10.0 with 10% v/v methanol. This system provided a resolution of 1.47 and 1.80 for the medicarpin and vestitone enantiomers, respectively. This analysis was completed in 12 min. This separation provided a rapid screen to determine the enantiomeric purity of key flavonoids biosynthesized by transgenic legumes.

Constitutive accumulation of a resveratrol-glucoside in transgenic alfalfa increases resistance to Phoma medicaginis.

Alfalfa (Medicago sativa) was transformed with a peanut (Arachis hypogaea) cDNA encoding resveratrol synthase (RS) transcriptionally regulated by an enhanced Cauliflower mosaic virus (CaMV) 35S promoter. Transgenic plants accumulated a new compound, not present in wild-type or vector-transformed alfalfa, that was identified as trans-resveratrol-3-O-beta-D-glucopyranoside (RGluc) by high-pressure liquid chromatography (HPLC), UV, 1H- and 13C-nuclear magnetic resonance (NMR) analyses. RGluc concentration was highest in the youngest leaves (>15 microg per g fresh weight) and oldest stem internode segments (>10 microg per g fresh weight) while roots contained only trace amounts (<0.2 microg per g fresh weight). RS transcript levels were highest in leaves and stems, with comparatively little transcript accumulation in the roots, while an inverse pattern was observed for chalcone synthase (CHS) transcript levels. CHS directly competes with RS for the metabolic precursors p-coumaroyl CoA and malonyl CoA, and may also contribute to the developmental variations in RGluc levels by limiting the availability of substrates. Agar-plate bioassays indicated that both RGluc and resveratrol greatly inhibit hyphal growth of the alfalfa fungal pathogen Phoma medicaginis. Subsequently, RGluc-containing leaves were wound inoculated and showed a significant reduction (relative to control leaves) in the size of necrotic lesions, intensity of adjacent chlorosis, and number of fungal reproductive structures (pycnidia). Decreasing sporulation of this pathogen may greatly reduce disease spread and severity throughout the field.

Overexpression of L-Phenylalanine Ammonia-Lyase in Transgenic Tobacco Plants Reveals Control Points for Flux into Phenylpropanoid Biosynthesis.

Transgenic tobacco (Nicotiana tabacum L.) plants overexpressing the enzyme L-phenylalanine ammonia-lyase (PAL; EC 4.3.1.5) were grown from seeds of a primary transformant containing the bean PAL2 gene, which had shown homology-dependent silencing of the endogenous tobacco PAL genes. Analysis of endogenous and transgene-encoded PAL transcripts and protein in the primary transformant (T0) and first-generation (T1) overexpressor plants indicated that the transgene-encoded PAL is the cause of the greater than wild-type levels of PAL activity (up to 5- and 2-fold greater in leaf and stem tissue, respectively) in the T1 plants. Leaves of PAL-overexpressing plants contained increased levels of the hydroxycinnamic acid ester chlorogenic acid but not of the flavonoid rutin, indicating that PAL is the key control point for flux into chlorogenic acid. In addition, levels of the glucoside of 4-coumaric acid increased in the overexpressing plants, suggesting that the 4-coumarate:coenzyme A ligase or coumarate hydroxylase reactions might have become limiting. These results help to define the regulatory architecture of the phenylpropanoid pathway and indicate the possibility of engineering-selective changes in this complex metabolic pathway by overexpression of a single early pathway gene.

Metabolic engineering: prospects for crop improvement through the genetic manipulation of phenylpropanoid biosynthesis and defense responses--a review.

In leguminous plants such as the forage legume alfalfa, products of the phenylpropanoid pathway of secondary metabolism are involved in interactions with beneficial microorganisms (flavonoid inducers of the Rhizobium symbiosis), and in defense against pathogens (isoflavonoid phytoalexins). In addition, the phenylpropane polymer lignin is a major structural component of secondary vascular tissue and fibers in higher plants. the recent isolation of genes encoding key enzymes of the various phenylpropanoid branch pathways opens up the possibility of engineering important crop plants such as alfalfa for: (a) improved forage digestibility, by modification of lignin composition and/or content; (b) increased or broader-spectrum disease resistance, by introducing novel phytoalexins or structural variants of the naturally occurring phytoalexins, or by modifying expression of transcriptional regulators of phytoalexin pathways; and (c) enhanced nodulation efficiency, by engineering over-production of flavonoid nod gene inducers. The basic biochemistry and molecular biology underlying these strategies is briefly reviewed, and recent progress with transgenic plants summarized. The potential importance of metabolic compartmentation for attempts to engineer phenylpropanoid biosynthetic pathways is also discussed. Over-expression of an alfalfa glucanase-encoding gene confers significant protection against Phytophthora in alfalfa, possibly via indirect effects on phenylpropanoid metabolism.

High-performance liquid chromatography/continuous-flow liquid secondary ion mass spectrometry of flavonoid glycosides in leguminous plant extracts.

A method for the identification of flavonoid glycosides utilizing continuous-flow liquid secondary ion mass spectrometry (CF-LSIMS) is presented. Minimum detectable quantities (MDQs) were determined for three model flavonoid glycosides (rutin, naringin and esculin) by both positive ion direct insertion probe (DIP)-LSIMS (1.6 nmol, 1.7 nmol and 730 pmol, respectively) and positive ion CF-LSIMS (330 pmol, 340 pmol and 290 pmol, respectively). Optimization of CF-LSIMS instrumental parameters was performed using the model compound rutin. Parameters optimized included mobile phase composition, glycerol concentration, mobile phase flow rate, ion source temperature, acceleration lens potential (amplitude and polarity) and Cs+ primary ion energy. Final instrumental optimization yielded an MDQ of 1.0 ng (1.6 pmol) for rutin by flow-injection CF-LSIMS. The optimization parameters were utilized in the identification of flavonoid glucosides in alfalfa (Medicago sativa L) and chickpea (Cicer arietinum) extracts by high-performance liquid chromatogrphy/CF-LSIMS. The results support the controversial identification of a major extract component as formononetin-7-O-glucoside-6"-malonate as opposed to afrormosin-7-O-glucoside-6"-malonate.

Molecular cloning and expression of alfalfa (Medicago sativa L.) vestitone reductase, the penultimate enzyme in medicarpin biosynthesis.

Medicarpin, the major phytoalexin in alfalfa, is synthesized by way of the isoflavonoid branch of phenylpropanoid metabolism. One of the final steps of medicarpin biosynthesis, from vestitone to 7,2'-dihydroxy-4'-methoxyisoflavanol, is catalyzed by vestitone reductase. A 1245-bp cDNA clone which encodes vestitone reductase was identified utilizing internal amino acid sequence of purified vestitone reductase. When expressed in Escherichia coli, the cloned enzyme exhibits strict substrate stereospecificity for (3R)-vestitone, as was observed for vestitone reductase purified from alfalfa. The calculated molecular weight of the protein (35,918) is similar to that of purified vestitone reductase from alfalfa (38 kDa by SDS-PAGE). The levels of vestitone reductase transcript (1.35 kb) greatly increase within 2 h of elicitor addition to alfalfa cell suspension cultures, preceding the rapid increases in vestitione reductase enzyme activity and medicarpin biosynthesis. In healthy alfalfa plants, the highest levels of transcripts were detected in roots and root nodules, consistent with the synthesis of medicarpin and its conjugate in these tissues. The cloning of the vestitone reductase gene provides a specific tool for the study and manipulation of pterocarpan biosynthesis in legumes.

Features of the hmg 1 subfamily of genes encoding HMG-CoA reductase in potato.

3-Hydroxy-3-methylglutaryl coenzyme A reductase (HMGR) catalyzes a key step in isoprenoid metabolism leading to a range of compounds that are important for the growth, development and health of the plant. We have isolated 7 classes of genomic clones encoding HMGR from a potato genomic library. Comparison of nucleic acid sequences reveals a high degree of identity between all seven classes of clones and the potato hmg 1 gene described by Choi et al. (Plant Cell 4: 1333, 1992), indicating that all are members of the same subfamily in potato. A representative member (hmg 1.2) of the most abundant class of genomic clones was selected for further characterization. Transgenic tobacco and potato containing the beta-glucuronidase (GUS) reporter gene under the control of the hmg 1.2 promoter expressed GUS activity constitutively at a low level in many plant tissues. High levels of GUS activity were observed only in the pollen. GUS assays of isolated pollen, correlations of GUS activity with the HMGR activity of anthers, hmg 1.2 promoter deletion studies, and segregation analysis of the expression of hmg 1.2::GUS among the R2 pollen of R1 progeny plants demonstrated that the hmg 1.2 promoter controls pollen expression.

The 'pterocarpan synthase' of alfalfa: association and co-induction of vestitone reductase and 7,2'-dihydroxy-4'-methoxy-isoflavanol (DMI) dehydratase, the two final enzymes in medicarpin biosynthesis.

Vestitone reductase and 7,2'-dihydroxy-4'-methoxy-isoflavanol (DMI) dehydratase are the two final enzymes in medicarpin biosynthesis in alfalfa (Medicago sativa). Although two independent enzymes, vestitone reductase and DMI dehydratase can be loosely associated in low ionic strength buffers, presumably by a weak protein-protein interaction. The activities of vestitone reductase and DMI dehydratase increased approximately 3-fold 6 hours after elicitor treatment in alfalfa suspension cell culture. The activities remained at maximal levels for 40 hours, correlating with a steady increase in the medicarpin content of the cells. Medicarpin produced in vitro from vestitone by the action of vestitone reductase and DMI dehydratase was found to be (-)-medicarpin (6aR,11aR-medicarpin), possessing the same stereochemistry as medicarpin produced in vivo.

The elicitor-inducible alfalfa isoflavone reductase promoter confers different patterns of developmental expression in homologous and heterologous transgenic plants.

In legumes, the synthesis of infection- and elicitor-inducible antimicrobial phytoalexins occurs via the isoflavonoid branch of the phenylpropanoid pathway. To study transcriptional regulation of isoflavonoid pathway-specific genes, we have isolated the gene encoding isoflavone reductase (IFR), which is the enzyme that catalyzes the penultimate step in the synthesis of the phytoalexin medicarpin in alfalfa. Chimeric gene fusions were constructed between 765- and 436-bp promoter fragments of the IFR gene and the beta-glucuronidase reporter gene and transferred to alfalfa and tobacco by Agrobacterium-mediated transformation. Both promoter fragments conferred elicitor-mediated expression in cell suspension cultures derived from transgenic plants of both species and fungal infection-mediated expression in leaves of transgenic alfalfa. Developmental expression directed by both promoter fragments in transgenic alfalfa was observed only in the root meristem, cortex, and nodules, which is consistent with the accumulation of endogenous IFR transcripts. However, in transgenic tobacco, expression from the 765-bp promoter was observed in vegetative tissues (root meristem and cortex, inner vascular tissue of stems and petioles, leaf tips, and stem peripheries adjacent to petioles) and in reproductive tissues (stigma, placenta, base of the ovary, receptacle, seed, tapetal layer, and pollen grains), whereas the 436-bp promoter was expressed only in fruits, seed, and pollen. These data indicate that infection/elicitor inducibility of the IFR promoter in both species and developmental expression in alfalfa are determined by sequences downstream of position -436, whereas sequences between -436 and -765 confer a complex pattern of strong ectopic developmental expression in the heterologous species that lacks the isoflavonoid pathway.

Conversion of vestitone to medicarpin in alfalfa (Medicago sativa L.) is catalyzed by two independent enzymes. Identification, purification, and characterization of vestitone reductase and 7,2'-dihydroxy-4'-methoxyisoflavanol dehydratase.

Pterocarpan phytoalexins are antimicrobial compounds in leguminous plants. The final step of pterocarpan biosynthesis, conversion of vestitone to medicarpin, was thought to be catalyzed by a single enzyme "pterocarpan synthase." We have shown that the pterocarpan synthase activity observed in crude extracts of alfalfa suspension cell cultures is the sum of two independent enzymatic activities: vestitone reductase, which catalyzes the NADPH-dependent reduction of vestitone to 7,2'-dihydroxy-4'-methoxyisoflavanol (DMI), and DMI dehydratase, which catalyzes loss of water and closure of an ether ring to form medicarpin. The first enzyme, vestitone reductase, was purified 1,840-fold to homogeneity by a 5-step procedure. Purified vestitone reductase showed a single band on SDS-polyacrylamide gel electrophoresis with an estimated molecular mass of 38 kDa. The native molecular mass measured by gel filtration was shown to be 34 kDa, indicating that vestitone reductase is a monomer. Vestitone reductase has strict substrate stereo specificity for (3R)-vestitone with a Km value of 45 microM. The second enzyme, DMI dehydratase, was partially purified 962-fold. DMI dehydratase had a native molecular mass of 38 kDa as estimated by gel filtration and a Km value of 5 microM for DMI. Both enzymes have a temperature optimum of 30 degrees C and a pH optimum of 6.0. The discovery of vestitone reductase and DMI dehydratase will facilitate future genetic manipulation of pterocarpan biosynthesis.

Molecular cloning of isoflavone reductase from pea (Pisum sativum L.): evidence for a 3R-isoflavanone intermediate in (+)-pisatin biosynthesis.

Isoflavone reductase (IFR) reduces achiral isoflavones to chiral isoflavanones during the biosynthesis of chiral pterocarpan phytoalexins. A cDNA clone for IFR from pea (Pisum sativum) was isolated using the polymerase chain reaction and expressed in Escherichia coli. Analysis of circular dichroism (CD) spectra of the reduction product sophorol obtained using the recombinant enzyme indicated that the isoflavanone possessed the 3R stereochemistry, in contrast to previous reports indicating a 3S-isoflavanone as the product of the pea IFR. Analysis of CD spectra of sophorol produced using enzyme extracts of CuCl2-treated pea seedlings confirmed the 3R stereochemistry. Thus, the stereochemistry of the isoflavanone intermediate in (+)-pisatin biosynthesis in pea is the same as that in (-)-medicarpin biosynthesis in alfalfa, although the final pterocarpans have the opposite stereochemistry. At the amino acid level the pea IFR cDNA was 91.8 and 85.2% identical to the IFRs from alfalfa and chickpea, respectively. IFR appears to be encoded by a single gene in pea. Its transcripts are highly induced in CuCl2-treated seedlings, consistent with the appearance of IFR enzyme activity and pisatin accumulation.

Stress responses in alfalfa (Medicago sativa L.) 11. Molecular cloning and expression of alfalfa isoflavone reductase, a key enzyme of isoflavonoid phytoalexin biosynthesis.

The major phytoalexin in alfalfa is the isoflavonoid (-)-medicarpin (or 6aR, 11aR)-medicarpin. Isoflavone reductase (IFR), the penultimate enzyme in medicarpin biosynthesis, is responsible for introducing one of two chiral centers in (-)-medicarpin. We have isolated a 1.18 kb alfalfa cDNA (pIFRalf1) which, when expressed in Escherichia coli, converts 2'-hydroxyformononetin stereospecifically to (3R)-vestitone, as would be predicted for IFR from alfalfa. The calculated molecular weight of the polypeptide (35,400) derived from the 954 bp open reading frame compares favorably to estimated Mrs determined for IFR proteins purified from other legumes. The transcript (1.4 kb) is highly induced in elicited alfalfa cell cultures. The kinetics of induction are consistent with the appearance of IFR activity, the accumulation of medicarpin, and the observed induction of other enzymes in the pathway. Low levels of IFR transcripts were found in healthy plant parts (roots and nodules) which accumulate low levels of a medicarpin glucoside. IFR appears to be encoded by a single gene in alfalfa. The cloning of IFR opens up the possibility of genetic manipulation of phytoalexin biosynthesis in alfalfa by altering isoflavonoid stereochemistry.

Stress responses in alfalfa (Medicago sativa L.) 12. Sequence analysis of phenylalanine ammonia-lyase (PAL) cDNA clones and appearance of PAL transcripts in elicitor-treated cell cultures and developing plants.

An expression library containing cDNAs derived from transcripts from fungal elicitor-treated alfalfa cell suspension cultures was screened with an antiserum raised against phenylalanine ammonia-lyase (PAL) from alfalfa. A single immunoreactive clone was isolated which encoded a full-length PAL cDNA (APAL1) consisting of a 2175 bp open reading frame, 96 bp 5'-untranslated leader and 128 bp 3'-non-coding region. The deduced amino acid sequence was 86.5% similar to that of the PAL2 gene of bean, and encoded a polypeptide of Mr 78,865. A second PAL cDNA species was isolated, whose 3'-untranslated region was 86% identical to that of APAL1. Southern blot analysis indicated that PAL is encoded by a small multigene family in alfalfa. PAL transcript levels were rapidly and massively induced, and preceded increased PAL extractable activity, on exposure of alfalfa suspension cells to elicitor from baker's yeast. PAL transcripts were most abundant in roots, stems and petioles during growth and development of alfalfa seedlings. These studies provide the basis for an examination of the developmental and environmental control of a key enzyme of phenylpropanoid synthesis in a plant species which is readily amenable to stable genetic transformation.

Incorporation of acetate, propionate, and methionine into rapamycin by Streptomyces hygroscopicus.

Labelling experiments with 13C-labelled precursors demonstrated that the majority of the macrolide ring of rapamycin is formed from six acetate and seven propionate units. A two-carbon unit in the ring was not labelled by acetate, propionate, glycine, or methionine. Methionine and glycine did, however, label the three methoxy groups of rapamycin to a high degree. Results from the incorporation experiments demonstrated that there were errors in the published 13C-nmr spectral assignments for rapamycin; these have now been corrected.