木质素合成关键酶——肉桂醇脱氢酶的研究进展

肉桂醇脱氢酶(CAD)是木质素合成途径的关键酶之一,它作用于木质素单体生物合成的最后一步。重点综述了肉桂醇脱氢酶(CAD)的在基因家族方面,基因调控方面以及蛋白结晶方面的研究进展,讨论了存在的问题并提出了相关策略。     

Red Xylem and Higher Lignin Extractability by Down-Regulating a Cinnamyl Alcohol Dehydrogenase in Poplar

Cinnamyl alcohol dehydrogenase (CAD) catalyzes the last step in the biosynthesis of the lignin precursors, the monolignols. We have down-regulated CAD in transgenic poplar (Populus tremula X Populus alba) by both antisense and co-suppression strategies. Several antisense and sense CAD transgenic poplars had an approximately 70% reduced CAD activity that was associated with a red coloration of the xylem tissue. Neither the lignin amount nor the lignin monomeric composition (syringyl/guaiacyl) were significantly modified. However, phloroglucinol-HCl staining was different in the down-regulated CAD plants, suggesting changes in the number of aldehyde units in the lignin. Furthermore, the reactivity of the cell wall toward alkali treatment was altered: a lower amount of lignin was found in the insoluble, saponified residue and more lignin could be precipitated from the soluble alkali fraction. Moreover, large amounts of phenolic compounds, vanillin and especially syringaldehyde, were detected in the soluble alkali fraction of the CAD down-regulated poplars. Alkaline pulping experiments on 3-month-old trees showed a reduction of the kappa number without affecting the degree of cellulose degradation. These results indicate that reducing the CAD activity in trees might be a valuable strategy to optimize certain processes of the wood industry, especially those of the pulp and paper industry.     

Manipulation of Guaiacyl and Syringyl Monomer Biosynthesis in an Arabidopsis Cinnamyl Alcohol Dehydrogenase Mutant Results in Atypical Lignin Biosynthesis and Modified Cell Wall Structure

Modifying lignin composition and structure is a key strategy to increase plant cell wall digestibility for biofuel production. Disruption of the genes encoding both cinnamyl alcohol dehydrogenases (CADs), including CADC and CADD, in Arabidopsis thaliana results in the atypical incorporation of hydroxycinnamaldehydes into lignin. Another strategy to change lignin composition is downregulation or overexpression of ferulate 5-hydroxylase (F5H), which results in lignins enriched in guaiacyl or syringyl units, respectively. Here, we combined these approaches to generate plants enriched in coniferaldehyde-derived lignin units or lignins derived primarily from sinapaldehyde. The cadc cadd and ferulic acid hydroxylase1 (fah1) cadc cadd plants are similar in growth to wild-type plants even though their lignin compositions are drastically altered. In contrast, disruption of CAD in the F5H-overexpressing background results in dwarfism. The dwarfed phenotype observed in these plants does not appear to be related to collapsed xylem, a hallmark of many other lignin-deficient dwarf mutants. cadc cadd, fah1 cadc cadd, and cadd F5H-overexpressing plants have increased enzyme-catalyzed cell wall digestibility. Given that these CAD-deficient plants have similar total lignin contents and only differ in the amounts of hydroxycinnamaldehyde monomer incorporation, these results suggest that hydroxycinnamaldehyde content is a more important determinant of digestibility than lignin content.     

Elicitor-Induced Cinnamyl Alcohol Dehydrogenase Activity in Lignifying Wheat (Triticum aestivum L.) Leaves

The substrate-specific induction of wheat (Triticum aestivum L. cv Fenman) leaf cinnamyl alcohol dehydrogenase (CAD, EC 1.1.1.195) was examined in relation to its role in regulating the composition of defensive lignin induced at wound margins. Treatment of wounds with a partially acetylated chitosan hydrolysate or spores of the nonpathogen Botrytis cinerea elicited lignification at wound margins and invoked significant increases in phenylalanine ammonia-lyase (EC 4.3.1.5), peroxidase (EC 1.11.1.7), and CAD activities. The substrate-specific induction of CAD with time was determined in elicitor-treated leaves and in excised lignifying wounds. In whole leaf extracts no significant increases in p-cou-maryl and coniferyl alcohol dehydrogenase activities were detectable, but a significant 5-fold increase in sinapyl alcohol dehydrogenase activity was evident 32 h after elicitor treatment. Similarly, fungal challenge resulted in elevated levels of only sinapyl alcohol dehydrogenase in whole-leaf extracts. In excised lignifying tissues p-coumaryl alcohol dehydrogenase levels were similar to those observed in healthy tissue. A small yet significant increase in coniferyl alcohol dehydrogenase was apparent, but the most dramatic increase occurred in sinapyl alcohol dehydrogenase activity, which increased to values approximately 10 times higher than the untreated controls. Our results show for the first time that CAD induction in lignifying tissues of wheat is predominantly attributable to highly localized increases in sinapyl alcohol dehydrogenase activity.     

A Nonsense Mutation in a Cinnamyl Alcohol Dehydrogenase Gene Is Responsible for the Sorghum brown midrib6 Phenotype

brown midrib6 (bmr6) affects phenylpropanoid metabolism, resulting in reduced lignin concentrations and altered lignin composition in sorghum (Sorghum bicolor). Recently, bmr6 plants were shown to have limited cinnamyl alcohol dehydrogenase activity (CAD; EC 1.1.1.195), the enzyme that catalyzes the conversion of hydroxycinnamoyl aldehydes (monolignals) to monolignols. A candidate gene approach was taken to identify Bmr6. Two CAD genes (Sb02g024190 and Sb04g005950) were identified in the sorghum genome based on similarity to known CAD genes and through DNA sequencing a nonsense mutation was discovered in Sb04g005950 that results in a truncated protein lacking the NADPH-binding and C-terminal catalytic domains. Immunoblotting confirmed that the Bmr6 protein was absent in protein extracts from bmr6 plants. Phylogenetic analysis indicated that Bmr6 is a member of an evolutionarily conserved group of CAD proteins, which function in lignin biosynthesis. In addition, Bmr6 is distinct from the other CAD-like proteins in sorghum, including SbCAD4 (Sb02g024190). Although both Bmr6 and SbCAD4 are expressed in sorghum internodes, an examination of enzymatic activity of recombinant Bmr6 and SbCAD4 showed that Bmr6 had 1 to 2 orders of magnitude greater activity for monolignol substrates. Modeling of Bmr6 and SbCAD4 protein structures showed differences in the amino acid composition of the active site that could explain the difference in enzyme activity. These differences include His-57, which is unique to Bmr6 and other grass CADs. In summary, Bmr6 encodes the major CAD protein involved in lignin synthesis in sorghum, and the bmr6 mutant is a null allele.Plant cell walls constitute a vast reserve of fixed carbon. Cellulose and lignin are the first and second most abundant polymers on the planet, respectively (Jung and Ni, 1998). The world community has started to look to biomass as substrates for plant-based biologically sustainable fuels, which would mitigate carbon dioxide emission and reduce petroleum dependence (Sarath et al., 2008; Schmer et al., 2008). In the current generation of biofuels, ethanol is being synthesized via the fermentation of grain starch or sugarcane juice. For the next generation of biofuels, research is being directed toward the conversion of lignocellulosic biomass into biofuels (Chang, 2007). As bioenergy technologies progress, the conversion of biomass to biofuels could involve a range of chemical, biochemical, and fermentation processes to produce biofuels; alternate biofuels, such as butanol or dimethylfuran, are also on the horizon (Ezeji et al., 2007; Roman-Leshkov et al., 2007). Most liquid biofuel production processes will likely rely on the conversion of the cell wall polysaccharides cellulose and hemicellulose into monomeric sugars.Plant cell walls consist of a complex polysaccharide moiety composed of cellulose microfibrils, composed of β-1,4-linked Glc polymers (Carpita and McCann, 2000). Connecting the cellulose microfibrils to each other is a hemicellulose network, whose structure and composition are species dependent, and which is mainly composed of glucuronoarabinoxylans in grasses (Carpita and McCann, 2000). Lignin, a nonlinear heterogeneous polymer derived from aromatic precursors, cross-links these polysaccharides, rigidifying and reinforcing the cell wall structure (Carpita and McCann, 2000). The addition of lignin polymers to the polysaccharide matrix creates a barrier that is chemically and microbially resistant.Lignin can block the liberation of sugars from the cell wall polysaccharide moieties, release compounds that can inhibit microbes used for fermenting sugars to fuels, and adhere to hydrolytic enzymes. Understanding lignin synthesis, structure, and function to increase cell wall digestibility has long been a goal for forage improvement and paper processing (Mackay et al., 1997; Jung and Ni, 1998). Recently, manipulating lignin has also become an important target for bioenergy feedstock improvement (Chen and Dixon, 2007; Li et al., 2008).Lignin is derived from the phenylpropanoid pathway and contains primarily three types of phenolic subunits: p-hydroxyphenyl, guaiacyl, and syringyl units (Dixon et al., 2001). The phenolic aldehyde precursors are reduced into their corresponding alcohols (monolignols) and subsequently transported to the cell wall (Fig. 1), where laccases and peroxidases catalyze lignin polymerization through the formation of monolignol radicals (Boerjan et al., 2003). Therefore, most research efforts to manipulate lignin have focused on biosynthesis of the monolignols. Most of the enzymes involved in monolignol synthesis have been cloned and characterized in Arabidopsis (Arabidopsis thaliana) and other dicot species, using both mutagenic and transgenic approaches to study the impact of these gene products on dicot cell walls (Anterola and Lewis, 2002). However, there are significant differences in the architecture, polysaccharide composition, and phenylpropanoid composition of grass cell walls compared with those of dicots (Carpita and McCann, 2000; Vogel and Jung, 2001). For example, grasses contain significant amounts of p-coumaric acid and ferulic acid that are cross-linked to cell wall polysaccharides through ester and ether linkages in addition to their presence in lignin (Grabber et al., 1991; Boerjan et al., 2003). Because many of the proposed dedicated bioenergy crops are grasses, there is a need to identify and understand the function of the gene products involved in lignin biosynthesis in these species (Vermerris et al., 2007; Li et al., 2008; Sarath et al., 2008).Open in a separate windowFigure 1.The CAD enzyme and its role in the monolignol biosynthetic pathway. A, CAD catalyzes the conversion of cinnamyl aldehydes to alcohols using NADPH as its cofactor. p-Coumaryl aldehyde and alcohol, R₁ and R₂ = H; caffeoyl aldehyde and alcohol, R₁ and R₂ = OH; coniferyl aldehyde and alcohol, R₁ = H and R₂ = OCH₃; sinapyl aldehyde and alcohol, R₁ and R₂ = OCH₃. B, A simplified model of the lignin biosynthetic pathway where CAD catalyzes the final step in monolignol biosynthesis.The brown midrib phenotype has been useful for identifying mutants affecting lignin synthesis in grasses because it is a visible phenotype. Spontaneous brown midrib mutants were first discovered in maize (Zea mays; Jorgenson, 1931) and were subsequently generated in sorghum (Sorghum bicolor) using diethyl sulfate mutagenesis (Porter et al., 1978). Brown midrib mutants in maize, sorghum, and pearl millet (Pennisetum glaucum) have increased forage digestibility for livestock (Cherney et al., 1990; Akin et al., 1993; Jung et al., 1998; Oliver et al., 2004). In maize and sorghum, there are at least four brown midrib loci in their respective genomes (Jorgenson, 1931; Porter et al., 1978; Gupta, 1995). The genes encoding bm3 in maize and bmr12 in sorghum are the only loci cloned to date, and both encode highly similar caffeic acid O-methyl transferases (Vignols et al., 1995; Bout and Vermerris, 2003). A second brown midrib locus associated with reduced cinnamyl alcohol dehydrogenase (CAD) activity has been identified both in maize (bm1; Halpin et al., 1998) and sorghum (bmr6; Bucholtz et al., 1980; Pillonel et al., 1991). CAD is a member of the alcohol dehydrogenase superfamily of proteins that catalyzes the conversion of the hydroxycinnamoyl aldehydes into alcohols prior to their incorporation into lignin polymers (Fig. 1). Reduced CAD activity results in increased digestibility on dry weight basis, altered cell wall architecture, reduced lignin level, and the incorporation of phenolic aldehydes into lignin in sorghum and maize (Pillonel et al., 1991; Provan et al., 1997; Halpin et al., 1998; Marita et al., 2003; Shi et al., 2006; Palmer et al., 2008). The reduced CAD activity in bm1 has been genetically mapped to a region of the maize genome that contained a CAD gene, ZmCAD2 (Halpin et al., 1998), but a mutation was not identified. However, it has recently been shown that bm1 down-regulated the expression of several lignin biosynthetic genes, suggesting its gene product may be a regulatory protein (Shi et al., 2006; Guillaumie et al., 2007).To identify the mutation responsible for the bmr6 phenotype and to characterize how bmr6 impacts the lignin biosynthetic pathway, a candidate gene approach was taken. Here, we describe the cloning and characterization of Bmr6 and a related protein, SbCAD4. The identification and characterization of Bmr6 has revealed the major monolignol CAD protein in the grasses, which is likely to aid the development of new strategies to increase conversion of sorghum and other grass feedstocks to biofuels.     

Metabolite Profiling Reveals a Role for Atypical Cinnamyl Alcohol Dehydrogenase CAD1 in the Synthesis of Coniferyl Alcohol in Tobacco Xylem

In angiosperms, lignin is built from two main monomers, coniferyl and sinapyl alcohol, which are incorporated respectively as G and S units in the polymer. The last step of their synthesis has so far been considered to be performed by a family of dimeric cinnamyl alcohol dehydrogenases (CAD2). However, previous studies on Eucalyptus gunnii xylem showed the presence of an additional, structurally unrelated, monomeric CAD form named CAD1. This form reduces coniferaldehyde to coniferyl alcohol, but is inactive on sinapaldehyde. In this paper, we report the functional characterization of CAD1 in tobacco (Nicotiana tabacum L.). Transgenic tobacco plants with reduced CAD1 expression were obtained through an RNAi strategy. These plants displayed normal growth and development, and detailed biochemical studies were needed to reveal a role for CAD1. Lignin analyses showed that CAD1 down-regulation does not affect Klason lignin content, and has a moderate impact on G unit content of the non-condensed lignin fraction. However, comparative metabolic profiling of the methanol-soluble phenolic fraction from basal xylem revealed significant differences between CAD1 down-regulated and wild-type plants. Eight compounds were less abundant in CAD1 down-regulated lines, five of which were identified as dimers or trimers of monolignols, each containing at least one moiety derived from coniferyl alcohol. In addition, 3-trans-caffeoyl quinic acid accumulated in the transgenic plants. Together, our results support a significant contribution of CAD1 to the synthesis of coniferyl alcohol in planta, along with the previously characterized CAD2 enzymes. Sequences of NtCAD1-1 and NtCAD1-7 were deposited in GenBank under accession numbers AY911854 and AY911855, respectively.     

Purification, Characterization, and Cloning of Cinnamyl Alcohol Dehydrogenase in Loblolly Pine (Pinus taeda L.)

Cinnamyl alcohol dehydrogenase (CAD, EC 1.1.1. 195) has been purified to homogeneity from differentiating xylem tissue and developing seeds of loblolly pine (Pinus taeda L.). The enzyme is a dimer with a native molecular weight of 82,000 and a subunit molecular weight of 44,000, and is the only form of CAD involved in lignification in differentiating xylem. High levels of loblolly pine CAD enzyme were found in nonlignifying seed tissue. Characterization of the enzyme from both seeds and xylem demonstrated that the enzyme is the same in both tissues. The enzyme has a high affinity for coniferaldehyde (K_m = 1.7 micromolar) compared with sinapaldehyde (K_m in excess of 100 micromolar). Kinetic data strongly suggest that coniferin is a noncompetitive inhibitor of CAD enzyme activity. Protein sequences were obtained for the N-terminus (28 amino acids) and for two other peptides. Degenerate oligonucleotide primers based on the protein sequences were used to amplify by polymerase chain reaction a 1050 base pair DNA fragment from xylem cDNA. Nucleotide sequence from the cloned DNA fragment coded for the N-terminal protein sequence and an internal peptide of CAD. The N-terminal protein sequence has little similarity with the λCAD4 clone isolated from bean (MH Walter, J Grima-Pettenati, C Grand, AM Boudet, CJ Lamb [1988] Proc Natl Acad Sci USA 86:5546-5550), which has homology with malic enzyme.     

Investigation of genome structure of a cinnamyl alcohol dehydrogenase locus in a basal angiosperm hardwood species, Liriodendron tulipifera L., reveals low synteny

Basal angiosperms contain a wide diversity of floral and growth forms and gave rise to the largest recent angiosperm lineages.As none of the basal angiosperm genomes has been sequenced,examining large bacterial artificial chromosome (BAC) inserts remains the main approach to providing a first glimpse of the structure and organization of their genomes.In this study,we sequenced a 126.9-kbp BAC contig harboring a cinnamyl alcohol dehydrogenase gene (LtuCAD1) in a basal angiosperm species,Liriodendron tulipifera L.,an important timber tree species with significant ecological and economic values.A key enzyme in lignin biosynthesis,CAD catalyzes the final step in the synthesis of monolignols.We carried out phylogenetic analyses of seven full-length CAD family genes (LtuCAD1-7) obtained from a comprehensive Liriodendron expressed sequence tag dataset.The phylogenetic tree suggests that LtuCAD1 is the primary CAD gene involved in lignifications as it is the only Liriodendron CAD grouped with the bona fide CADs class.As well as the LtuCAD1,the BAC contig contained fragmented sequences for one integrase,eight hypothetical proteins,two gag-pol polyproteins,one RNase H family protein,and one chromatin binding protein.Comparative analysis with other angiosperm species suggests that the genomic segment in this BAC has undergone frequent arrangement.This study is our initial step in identifying and understanding lignin biosynthesis genes from basal angiosperm species.Such knowledge can help bridge the information gap between hardwood (angiosperm) and softwood (gymnosperm) species and benefit potential breeding and biotechnology application for enhanced production ofbiomass and digestibility in L.tulipifera.     

Generation of a large-scale genomic resource for functional and comparative genomics in Liriodendron tulipifera L.

Liriodendron tulipifera L., a member of Magnoliaceae in the order Magnoliales, has been used extensively as a reference species in studies on plant evolution. However, genomic resources for this tree species are limited. We constructed cDNA libraries from ten different types of tissues: premeiotic flower buds, postmeiotic flower buds, open flowers, developing fruit, terminal buds, leaves, cambium, xylem, roots, and seedlings. EST sequences were generated either by 454 GS FLX or Sanger methods. Assembly of almost 2.4 million sequencing reads from all libraries resulted in 137,923 unigenes (132,905 contigs and 4,599 singletons). About 50% of the unigenes had significant matches to publically available plant protein sequences, representing a wide variety of putative functions. Approximately 30,000 simple sequence repeats were identified. More than 97% of the cell wall formation genes in the Cell Wall Navigator and the MAIZEWALL databases are represented. The cinnamyl alcohol dehydrogenase (CAD) homologs identified in the L. tulipifera EST dataset showed different expression levels in the ten tissue types included in this study. In particular, the LtuCAD1 was found to partially recover the stiffness of the floral stems in the Arabidopsis thaliana CAD4 and CAD5 double mutant plants, of the LtuCAD1 in lignin biosynthesis. L. tulipifera genes have greater sequence similarity to homologs from other woody angiosperm species than to non-woody model plants. This large-scale genomic resour"HistryDatesce will be instrumental for gene discovery, cDNA microarray production, and marker-assisted breeding in L. tulipifera, and strengthen this species' role in comparative studies.     

The Last Step of Syringyl Monolignol Biosynthesis in Angiosperms Is Regulated by a Novel Gene Encoding Sinapyl Alcohol Dehydrogenase

Cinnamyl alcohol dehydrogenase (CAD; EC 1.1.1.195) has been thought to mediate the reduction of both coniferaldehyde and sinapaldehyde into guaiacyl and syringyl monolignols in angiosperms. Here, we report the isolation of a novel aspen gene (PtSAD) encoding sinapyl alcohol dehydrogenase (SAD), which is phylogenetically distinct from aspen CAD (PtCAD). Liquid chromatography-mass spectrometry-based enzyme functional analysis and substrate level-controlled enzyme kinetics consistently demonstrated that PtSAD is sinapaldehyde specific and that PtCAD is coniferaldehyde specific. The enzymatic efficiency of PtSAD for sinapaldehyde was approximately 60 times greater than that of PtCAD. These data suggest that in addition to CAD, discrete SAD function is essential to the biosynthesis of syringyl monolignol in angiosperms. In aspen stem primary tissues, PtCAD was immunolocalized exclusively to xylem elements in which only guaiacyl lignin was deposited, whereas PtSAD was abundant in syringyl lignin-enriched phloem fiber cells. In the developing secondary stem xylem, PtCAD was most conspicuous in guaiacyl lignin-enriched vessels, but PtSAD was nearly absent from these elements and was conspicuous in fiber cells. In the context of additional protein immunolocalization and lignin histochemistry, these results suggest that the distinct CAD and SAD functions are linked spatiotemporally to the differential biosynthesis of guaiacyl and syringyl lignins in different cell types. SAD is required for the biosynthesis of syringyl lignin in angiosperms.     

The Affinity Purification and Characterization of a Dehydrogenase from Aspergillus parasiticus Involved in Aflatoxin B1, Biosynthesis

Abstract

A two step scheme has been developed for the purification of a dehydrogenase from mycelia of 84 hours old Aspergillus parasiticus (1-11-105 Wh 1), which catalyzes the conversion of norsolorinic acid (NA) to averantin (AVN). The dehydrogenase was purified from cell-free extracts using reactive green 19-agarose and norsolorinic acid-agarose affinity chromatography. The latter affinity matrix was synthesised by attaching norsolorinic acid to ω-aminohexylagarose. The purified protein was shown to be homogenous on non-denaturing polyacrylamide gel electrophoresis. A final purification of 215-fold was achieved. Results of gel filtration chromatography indicated the approximate molecular mass of the native protein to be 140 000 daltons. The isoelectric point of the protein was about 5.5 as determined by chromatofocusing. The reaction catalyzed by the dehydrogenase was optimum at pH 8.5 and between 25[ddot] to 35[ddot]C. The Km of the enzyme for NA and NADPH was determined to be 3.45 μM and 103 μM respectively.     

Functional Characterization of the Chlamydomonas reinhardtii ERG3 Ortholog,a Gene Involved in the Biosynthesis of Ergosterol

Background

The predominant sterol in the membranes of the alga Chlamydomonas reinhardtii is ergosterol, which is commonly found in the membranes of fungi, but is rarely found in higher plants. Higher plants and fungi synthesize sterols by different pathways, with plants producing cycloartenol as a precursor to end-product sterols, while non-photosynthesizing organisms like yeast and humans produce lanosterol as a precursor. Analysis of the C. reinhardtii genome sequence reveals that this algae is also likely to synthesize sterols using a pathway resembling the higher plant pathway, indicating that its sterols are synthesized somewhat differently than in fungi. The work presented here seeks to establish experimental evidence to support the annotated molecular function of one of the sterol biosynthetic genes in the Chlamydomonas genome.

Methodology/Principal Findings

A gene with homology to the yeast sterol C-5 desaturase, ERG3, is present in the Chlamydomonas genome. To test whether the ERG3 ortholog of C. reinhardtii encodes a sterol C-5 desaturase, Saccharomyces cerevisiae ERG3 knockout strains were created and complemented with a plasmid expressing the Chlamydomonas ERG3. Expression of C. reinhardtii ERG3 cDNA in erg3 null yeast was able to restore ergosterol biosynthesis and reverse phenotypes associated with lack of ERG3 function.

Conclusions/Significance

Complementation of the yeast erg3 null phenotypes strongly suggests that the gene annotated as ERG3 in C. reinhardtii functions as a sterol C-5 desaturase.     

Purification and Gene Cloning of a Dehydrogenase from Lactobacillus brevis That Catalyzes a Reaction Involved in Aflatoxin Biosynthesis

When 10 strains of lactic acid bacteria were incubated with 5′-hydroxyaverantin (HAVN), a precursor of aflatoxins, seven of them converted HAVN to averufin; the same reaction is found in aflatoxin biosynthesis of aflatoxigenic fungi. These bacteria had a dehydrogenase that catalyzed the reaction from HAVN to 5′-oxoaverantin (OAVN), which was so unstable that it was easily converted to averufin. The enzyme was purified from Lactobacillus brevis IFO 12005. The molecular mass of the enzyme was 100 kDa on gel filtration chromatography and 33 kDa on SDS polyacrylamide gel electrophoresis (SDS–PAGE). The gene encoding the enzyme was cloned and sequenced. The deduced protein consisted of 249 amino acids, and its estimated molecular mass was 25,873, in agreement with that by time of flight mass spectrometry (TOF MS) analysis. Although the deduced amino acid sequence showed about 50% identity to those reported for alcohol dehydrogenases from L. brevis or L. kefir, the commercially available alcohol dehydrogenase from L. kefir did not convert HAVN to OAVN. Aspergillus parasiticus HAVN dehydrogenase showed about 25% identity in amino acid sequence with the dehydrogenase and also with these two alcohol dehydrogenases.     

MocA Is a Specific Cytidylyltransferase Involved in Molybdopterin Cytosine Dinucleotide Biosynthesis in Escherichia coli

We have purified and characterized a specific CTP:molybdopterin cytidylyltransferase for the biosynthesis of the molybdopterin (MPT) cytosine dinucleotide (MCD) cofactor in Escherichia coli. The protein, named MocA, shows 22% amino acid sequence identity to E. coli MobA, the specific GTP:molybdopterin guanylyltransferase for molybdopterin guanine dinucleotide biosynthesis. MocA is essential for the activity of the MCD-containing enzymes aldehyde oxidoreductase YagTSR and the xanthine dehydrogenases XdhABC and XdhD. Using a fully defined in vitro assay, we showed that MocA, Mo-MPT, CTP, and MgCl₂ are required and sufficient for MCD biosynthesis in vitro. The activity of MocA is specific for CTP; other nucleotides such as ATP and GTP were not utilized. In the defined in vitro system a turnover number of 0.37 ± 0.01 min⁻¹ was obtained. A 1:1 binding ratio of MocA to Mo-MPT and CTP was determined to monomeric MocA with dissociation constants of 0.23 ± 0.02 μm for CTP and 1.17 ± 0.18 μm for Mo-MPT. We showed that MocA was also able to convert MPT to MCD in the absence of molybdate, however, with only one catalytic turnover. The addition of molybdate after one turnover gave rise to a higher MCD production, revealing that MCD remains bound to MocA in the absence of molybdate. This work presents the first characterization of a specific enzyme involved in MCD biosynthesis in bacteria.The biosynthesis of the molybdenum cofactor (Moco)² is an ancient, ubiquitous, and highly conserved pathway leading to the biochemical activation of molybdenum. In Moco the molybdenum atom is coordinated to the dithiolene group of the 6-alkyl side chain of a pterin called molybdopterin (MPT). Moco biosynthesis has been extensively studied in Escherichia coli by using a combination of biochemical, genetic, and structural approaches (1, 2). The biosynthesis of Moco has been divided into four major steps in Escherichia coli: (i) formation of precursor Z (3, 4), (ii) formation of MPT from precursor Z (5, 6), (iii) insertion of molybdenum to form Moco via an adenylylated MPT intermediate (7–9), and (iv) additional modification by covalent addition of GMP to the C4′ phosphate of MPT via a pyrophosphate bond, forming the molybdopterin guanine dinucleotide (MGD) cofactor (10, 11). In E. coli, GMP attachment to Moco is catalyzed by the MobA and MobB proteins (12). Although MobA was shown to be essential for this reaction and acts as a GTP:molybdopterin guanylyltransferase (11), the role of MobB still remains uncertain. From the crystal structure, it was postulated that MobB is an adapter protein acting in concert with MobA to achieve the efficient biosynthesis and utilization of MGD (13). Although MobA was shown to bind MPT, Mo-MPT, and MGD (14), investigations of in vitro studies using purified MobA, MgCl₂, GTP, and either MPT or Mo-MPT showed that MGD was only formed by MobA when the molybdenum atom was already ligated to MPT (15). The formation of bis-MGD is one of the most enigmatic steps in Moco biosynthesis in E. coli. It is still not known whether the two MGD molecules assemble on MobA or instead after the insertion into the respective target proteins like DMSO reductase or nitrate reductase A. In other bacteria like Arthrobacter nicotinovorans, Veillonella atypica, or Oligotropha carboxidovorans, Moco can be further modified by the attachment of CMP to the C4′ phosphate of MPT forming the molybdopterin cytosine dinucleotide (MCD) cofactor (16–18). A specific enzyme catalyzing the CTP:molybdopterin cytidylyltransferase reaction has not been identified so far. For A. nicotinovorans nicotine dehydrogenase and ketone dehydrogenase the involvement of a MobA homologous protein for MCD formation was reported (16); however, it was not shown whether the MobA protein was specifically required for MCD biosynthesis or whether it was also involved in the biosynthesis of MGD in this bacterium. Furthermore, enzymes binding MCD in bacteria usually contain an additional modification at the molybdenum site of Moco, where a terminal oxo-ligand is exchanged by a sulfido ligand, forming sulfurated or mono-oxo Moco (19). Recently, the MCD-containing protein YagTSR was identified and characterized in E. coli as a periplasmic aldehyde oxidoreductase which oxidizes a broad spectrum of aldehydes using ferredoxin as electron acceptor (20). It was shown that for the production of an active form of YagTSR, the YagQ protein was required, which is believed to be a MCD binding chaperone involved in the sulfuration of the Mo site and the insertion of sulfurated MCD into apoYagTSR (20). The majority of the other molybdoenzymes in E. coli were shown to bind the bis-MGD form of Moco, in which molybdenum is coordinated to two MGD moieties. The other exception is the YedY protein, being so far the only E. coli protein binding the Mo-MPT form of Moco (21). However, the physiological role of this protein still remains unclear.Investigations on YagTSR showed that MCD was inserted into YagR independent of the function of MobA, indicating that a so-far unidentified protein is involved in MCD biosynthesis in E. coli (20). Here, we report the identification of the specific CTP:molybdopterin cytidylyltransferase, which we named MocA (formerly named YgfJ by the E. coli nomenclature of genes with unknown function). Purified MocA was shown to catalyze the formation of MCD from Mo-MPT and CTP in vitro. Additionally, we report that a disruption in the mocA gene impaired MCD biosynthesis in E. coli, resulting in an inactive YagTSR protein devoid of Moco.     

Cotton GalT1 Encoding a Putative Glycosyltransferase Is Involved in Regulation of Cell Wall Pectin Biosynthesis during Plant Development

Arabinogalactan proteins (AGPs), are a group of highly glycosylated proteins that are found throughout the plant kingdom. To date, glycosyltransferases that glycosylate AGP backbone have remained largely unknown. In this study, a gene (GhGalT1) encoding a putative β-1,3-galactosyltransferase (GalT) was identified in cotton. GhGalT1, belonging to CAZy GT31 family, is the type II membrane protein that contains an N-terminal transmembrane domain and a C-terminal galactosyltransferase functional domain. A subcellular localization assay demonstrated that GhGalT1 was localized in the Golgi apparatus. RT-PCR analysis revealed that GhGalT1 was expressed at relatively high levels in hypocotyls, roots, fibers and ovules. Overexpression of GhGalT1 in Arabidopsis promoted plant growth and metabolism. The transgenic seedlings had much longer primary roots, higher chlorophyll content, higher photosynthetic efficiency, the increased biomass, and the enhanced tolerance to exogenous D-arabinose and D-galactose. In addition, gas chromatography (GC) analysis of monosaccharide composition of cell wall fractions showed that pectin was changed in the transgenic plants, compared with that of wild type. Three genes (GAUT8, GAUT9 and xgd1) involved in pectin biosynthesis were dramatically up-regulated in the transgenic lines. These data suggested that GhGalT1 may be involved in regulation of pectin biosynthesis required for plant development.