Uterine-embryonic interaction in pig: activin, follistatin, and activin receptor II in uterus and embryo during early gestation

The mRNA expression patterns of activin beta(A) and follistatin in the uterus and embryo, the mRNA expression of the activin receptor II in the embryo, and the localization in the uterus of the immunoreactive activin beta(A) and the receptor II proteins in the uterus were examined at gestation days 7-12 after ovulation in pig. Activin was located predominantly at the mesometrial side of the uterus during all stages of pregnancy studied. Follistatin mRNA was absent in the uterus during these stages, suggesting that activin of uterine origin is not inhibited by intra-uterine follistatin. The receptor was localized throughout the glandular and luminal epithelium of the uterus. In the embryo, activin was expressed predominantly in the epiblast before unfolding, but after unfolding of the epiblast activin expression shifted to the trophoblast. The expression pattern of follistatin mRNA was contrarily to that of activin, i.e., before unfolding predominantly in the trophoblast (days 8-9), and shifted to the epiblast at day 10. During streak stages, follistatin was detected in the node and primitive streak. Activin receptor II mRNA was first detected at day 8 in the embryoblast. At day 11, it was expressed in trophoblast cells near the epiblast, and in the first ingressing mesoderm cells. During the streak stages, it was expressed predominantly in the trophoblast. The presence of activin and its receptor in uterine epithelium and early embryonic tissues indicate that both embryonic and uterine activin are involved in intra-uterine processes, such as attachment and early embryonic development. Mol. Reprod. Dev. 59: 390-399, 2001.     

Introduction of chemically labile substructures into Arabidopsis lignin through the use of LigD,the Cα‐dehydrogenase from Sphingobium sp. strain SYK‐6

Bacteria‐derived enzymes that can modify specific lignin substructures are potential targets to engineer plants for better biomass processability. The Gram‐negative bacterium Sphingobium sp. SYK‐6 possesses a Cα‐dehydrogenase (LigD) enzyme that has been shown to oxidize the α‐hydroxy functionalities in β–O–4‐linked dimers into α‐keto analogues that are more chemically labile. Here, we show that recombinant LigD can oxidize an even wider range of β–O–4‐linked dimers and oligomers, including the genuine dilignols, guaiacylglycerol‐β‐coniferyl alcohol ether and syringylglycerol‐β‐sinapyl alcohol ether. We explored the possibility of using LigD for biosynthetically engineering lignin by expressing the codon‐optimized ligD gene in Arabidopsis thaliana. The ligD cDNA, with or without a signal peptide for apoplast targeting, has been successfully expressed, and LigD activity could be detected in the extracts of the transgenic plants. UPLC‐MS/MS‐based metabolite profiling indicated that levels of oxidized guaiacyl (G) β–O–4‐coupled dilignols and analogues were significantly elevated in the LigD transgenic plants regardless of the signal peptide attachment to LigD. In parallel, 2D NMR analysis revealed a 2.1‐ to 2.8‐fold increased level of G‐type α‐keto‐β–O–4 linkages in cellulolytic enzyme lignins isolated from the stem cell walls of the LigD transgenic plants, indicating that the transformation was capable of altering lignin structure in the desired manner.     

Lignin: Genetic Engineering and Impact on Pulping

Lignin is a major component of wood, the most widely used raw material for the production of pulp and paper. Although the biochemistry and molecular biology underpinning lignin production are better understood than they are for the other wood components, recent work has prompted a number of re-evaluations of the lignin biosynthetic pathway. Some of the work on which these revisions have been based involved the investigation of transgenic plants with modified lignin biosynthesis. In addition to their value in elucidating the lignin biosynthetic pathway, such transgenic plants are also being produced with the aim of improving plant raw materials for pulp and paper production. This review describes how genetic engineering has yielded new insights into how the lignin biosynthetic pathway operates and demonstrates that lignin can be improved to facilitate pulping. The current technologies used to produce paper are presented in this review, followed by a discussion of the impact of lignin modification on pulp production. Fine-tuned modification of lignin content, composition, or both is now achievable and could have important economic and environmental benefits.     

Vessel- and ray-specific monolignol biosynthesis as an approach to engineer fiber-hypolignification and enhanced saccharification in poplar

Lignin is one of the main factors determining recalcitrance to processing of lignocellulosic biomass towards bio-based materials and fuels. Consequently, wood of plants engineered for low lignin content is typically more amenable to processing. However, lignin-modified plants often exhibit collapsed vessels and associated growth defects. Vessel-specific reintroduction of lignin biosynthesis in dwarfed low-lignin cinnamoyl-CoA reductase1 (ccr1) Arabidopsis mutants using the ProSNBE:AtCCR1 construct overcame the yield penalty while maintaining high saccharification yields, and showed that monolignols can be transported between the different xylem cells acting as ‘good neighbors’ in Arabidopsis. Here, we translated this research into the bio-energy crop poplar. By expressing ProSNBE:AtCCR1 into CRISPR/Cas9-generated ccr2 poplars, we aimed for vessel-specific lignin biosynthesis to: (i) achieve growth restoration while maintaining high saccharification yields; and (ii) study the existence of ‘good neighbors’ in poplar wood. Analyzing the resulting ccr2 ProSNBE:AtCCR1 poplars showed that vessels and rays act as good neighbors for lignification in poplar. If sufficient monolignols are produced by these cells, monolignols migrate over multiple cell layers, resulting in a restoration of the lignin amount to wild-type levels. If the supply of monolignols is limited, the monolignols are incorporated into the cell walls of the vessels and rays producing them and their adjoining cells resulting in fiber hypolignification. One such fiber-hypolignified line had 18% less lignin and, despite its small yield penalty, had an increase of up to 71% in sugar release on a plant base upon saccharification.     

Bud set in poplar--genetic dissection of a complex trait in natural and hybrid populations

? The seasonal timing of growth events is crucial to tree distribution and conservation. The seasonal growth cycle is strongly adapted to the local climate that is changing because of global warming. We studied bud set as one cornerstone of the seasonal growth cycle in an integrative approach. ? Bud set was dissected at the phenotypic level into several components, and phenotypic components with most genetic variation were identified. While phenotypic variation resided in the timing of growth cessation, and even so more in the duration from growth cessation to bud set, the timing of growth cessation had a stronger genetic component in both natural and hybrid populations. ? Quantitative trait loci (QTL) were identified for the most discriminative phenotypic bud-set components across four poplar pedigrees. The QTL from different pedigrees were recurrently detected in six regions of the poplar genome. ? These regions of 1.83-4.25 Mbp in size, containing between 202 and 394 genes, form the basis for further molecular-genetic dissection of bud set.     

Tricin,a Flavonoid Monomer in Monocot Lignification

Tricin was recently discovered in lignin preparations from wheat (Triticum aestivum) straw and subsequently in all monocot samples examined. To provide proof that tricin is involved in lignification and establish the mechanism by which it incorporates into the lignin polymer, the 4′-O-β-coupling products of tricin with the monolignols (p-coumaryl, coniferyl, and sinapyl alcohols) were synthesized along with the trimer that would result from its 4′-O-β-coupling with sinapyl alcohol and then coniferyl alcohol. Tricin was also found to cross couple with monolignols to form tricin-(4′-O-β)-linked dimers in biomimetic oxidations using peroxidase/hydrogen peroxide or silver (I) oxide. Nuclear magnetic resonance characterization of gel permeation chromatography-fractionated acetylated maize (Zea mays) lignin revealed that the tricin moieties are found in even the highest molecular weight fractions, ether linked to lignin units, demonstrating that tricin is indeed incorporated into the lignin polymer. These findings suggest that tricin is fully compatible with lignification reactions, is an authentic lignin monomer, and, because it can only start a lignin chain, functions as a nucleation site for lignification in monocots. This initiation role helps resolve a long-standing dilemma that monocot lignin chains do not appear to be initiated by monolignol homodehydrodimerization as they are in dicots that have similar syringyl-guaiacyl compositions. The term flavonolignin is recommended for the racemic oligomers and polymers of monolignols that start from tricin (or incorporate other flavonoids) in the cell wall, in analogy with the existing term flavonolignan that is used for the low-molecular mass compounds composed of flavonoid and lignan moieties.Lignin, a complex phenylpropanoid polymer in the plant cell wall, is predominantly deposited in the cell walls of secondary-thickened cells (Vanholme et al., 2010). It is synthesized via oxidative radical coupling reactions from three prototypical monolignols, p-coumaryl, coniferyl, and sinapyl alcohols, differentiated by their degree of methoxylation ortho to the phenolic hydroxyl group. Considered within the context of the entire polymer, the main structural features of lignin can be defined in terms of its p-hydroxyphenyl (H), guaiacyl (G), and syringyl (S) units, derived respectively from these three monolignols (Ralph, 2010). Several novel monomers, all deriving from the monolignol biosynthetic pathway, have been found to incorporate into lignin in wild-type and transgenic plants. For example, monolignol acetate, p-hydroxybenzoate, and p-coumarate ester conjugates have all been shown to incorporate into lignin polymers and are the source of naturally acylated lignins (Ralph et al., 2004; Lu and Ralph, 2008); lignins derived solely from caffeyl alcohol were found in the seed coats of both monocot and dicot plants (Chen et al., 2012a, 2012b); lignins derived solely from 5-hydroxyconiferyl alcohol were found in a cactus (for example, in a member of the genera Astrophytum) seed coat (Chen et al., 2012a); a Medicago truncatula transgenic deficient in cinnamyl alcohol dehydrogenase exhibited a lignin that was overwhelmingly derived from hydroxycinnamaldehydes (instead of their usual hydroxycinnamyl alcohol analogs; Zhao et al., 2013); and iso-sinapyl alcohol was implicated as a monomer in caffeic acid O-methyltransferase down-regulated switchgrass (Panicum virgatum; Tschaplinski et al., 2012). These findings imply that plants are quite flexible in being able to use a variety of monomers during lignification to form the heterogenous lignin polymer. Most recently, and as addressed more fully here, the flavonoid tricin has been implicated as a monomer in monocot lignins (del Río et al., 2012). To our knowledge, tricin is the first monomer from outside the monolignol biosynthetic pathway to be implicated in lignification.Tricin [5,7-dihydroxy-2-(4-hydroxy-3,5-dimethoxyphenyl)-4H-chromen-4-one], a member of the flavonoid family, is recognized as a valuable human health compound due to its antioxidant, antiaging, anticancer, and cardioprotective potentials (Ogo et al., 2013). Tricin and its derivatives can be solvent extracted from monocot samples such as wheat (Triticum aestivum), oat bran (Avena sativa), bamboo (Leleba oldhami), sugarcane (Saccharum officinarum), and maize (Zea mays). Extracted compounds can take the form of tricin itself, 7-O-glycosylated tricin, or the flavonolignan in which tricin is 4′-O-etherified by putative coupling with coniferyl alcohol (Ju et al., 1998; Bouaziz et al., 2002; Wenzig et al., 2005; Duarte-Almeida et al., 2007; Van Hoyweghen et al., 2010; Nakano et al., 2011; Bottcher et al., 2013; Moheb et al., 2013).In 2012, we reported, to our knowledge, the first evidence that tricin was incorporated into lignin, as implicated by two previously unassigned correlation peaks at δ_C/δ_H 94.1/6.56 and 98.8/6.20 in a heteronuclear single-quantum coherence (HSQC) NMR spectrum from the whole cell wall and an isolated milled wood lignin of (unacetylated) wheat straw (del Río et al., 2012). The same evidence has now been found in the HSQC spectrum of wheat straw lignin isolated via different methods (Yelle et al., 2013; Zeng et al., 2013). Additional studies have verified the presence of tricin in lignin fractions from a variety of monocots, including bamboo (You et al., 2013), coconut coir (Cocos nucifera; Rencoret et al., 2013), maize, and others examined in our laboratories. The implication that tricin is the first phenolic from outside the monolignol biosynthetic pathway found to be integrated into the polymer has prompted further study with the aim of identifying and mechanistically delineating the role of tricin in lignin and its biosynthetic incorporation pathway.Tricin, unlike the monolignols that derive from the shikimate biosynthetic pathway (Sarkanen and Ludwig, 1971), is derived from a combination of the shikimate and acetate/malonate-derived polyketide pathways (Winkel-Shirley, 2001), as shown in Supplemental Figure S1. After p-coumaroyl-CoA is synthesized from p-coumaric acid by 4-coumarate:CoA ligase, it branches from the monolignol biosynthetic route to be transformed via chalcone synthase and chalcone isomerase into naringenin, the central precursor of most flavonoids. Naringenin is subsequently converted into apigenin by flavone synthase. Further hydroxylation at C-3′ and C-5′ followed by O-methylation furnishes tricin (Koes et al., 1994; Winkel-Shirley, 2001). The incorporation of tricin into lignin, therefore, suggests that an additional biosynthetic pathway, namely the polyketide pathway, may be associated with cell wall lignification in monocots.The revelation that tricin is incorporated into the lignin polymer was precipitated by closer study of signals found within the NMR spectra of various monocot samples. Before this discovery, tricin had not been noted in any lignin fractions, and although it is reasonable to anticipate compatibility based on its chemical structure, there is no direct and reliable evidence to date showing that tricin is able to react with monolignols through radical coupling; therefore, the efficiency and selectivity of the coupling reactions between tricin and various monolignols were also unknown. Synthetic model compounds that would facilitate the elucidation of the role of tricin within plant cell walls are desirable as aids to be used in a mechanistic study of flavonolignin generation. (We coin the term flavonolignin to describe the racemic oligomers and polymers of monolignols that start from tricin [or other flavonoids] in the cell wall, in analogy with the existing term flavonolignan that is used for the low-molecular mass compounds composed of flavonoid and lignan moieties that are presumably made in the cytoplasm [Begum et al., 2010; Niculaes et al., 2014; Dima et al., 2015]).The overall objective of this study is to demonstrate that tricin incorporates into the lignin polymer of monocots, with maize/corn stover as the representative experimental material. To this end, we have synthesized tricin and various model compounds in which tricin is conjugated to monolignols in the manner expected for the lignification process. Next, we verified whether these synthetic compounds could be made from their assumed precursors under the biomimetic radical conditions anticipated for lignification. Subsequently, NMR data generated from these synthetic and biomimetic coupling products were compared with NMR data from native maize stover lignin, including high-M_r fractions. We conclude that tricin is a monomer in monocot lignification and that, because little syringaresinol is found in maize lignin, tricin is functioning as a nucleation site that initiates lignin polymer chains.