An inexpensive gel electrophoresis-based polymerase chain reaction method for quantifying mRNA levels

In order to engage their students in a core methodology of the new genomics era, an ever-increasing number of faculty at primarily undergraduate institutions are gaining access to microarray technology. Their students are conducting successful microarray experiments designed to address a variety of interesting questions. A next step in these teaching and research laboratory projects is often validation of the microarray data for individual selected genes. In the research community, this usually involves the use of real-time polymerase chain reaction (PCR), a technology that requires instrumentation and reagents that are prohibitively expensive for most undergraduate institutions. The results of a survey of faculty teaching undergraduates in classroom and research settings indicate a clear need for an alternative approach. We sought to develop an inexpensive and student-friendly gel electrophoresis-based PCR method for quantifying messenger RNA (mRNA) levels using undergraduate researchers as models for students in teaching and research laboratories. We compared the results for three selected genes measured by microarray analysis, real-time PCR, and the gel electrophoresis-based method. The data support the use of the gel electrophoresis-based method as an inexpensive, convenient, yet reliable alternative for quantifying mRNA levels in undergraduate laboratories.     

Characterization of a structurally and functionally diverged acyl-acyl carrier protein desaturase from milkweed seed

A cDNA for a structurally variant acyl-acyl carrier protein (ACP) desaturase was isolated from milkweed (Asclepias syriaca) seed, a tissue enriched in palmitoleic (16:1⁹)* and cis-vaccenic (18:1¹¹) acids. Extracts of Escherichia coli that express the milkweed cDNA catalyzed ⁹ desaturation of acyl-ACP substrates, and the recombinant enzyme exhibited seven- to ten-fold greater specificity for palmitoyl (16:0)-ACP and 30-fold greater specificity for myristoyl (14:0)-ACP than did known ⁹-stearoyl (18:0)-ACP desaturases. Like other variant acyl-ACP desaturases reported to date, the milkweed enzyme contains fewer amino acids near its N-terminus compared to previously characterized ⁹-18:0-ACP desaturases. Based on the activity of an N-terminal deletion mutant of a⁹ -18:0-ACP desaturase, this structural feature likely does not account for differences in substrate specificities.     

Caribbean mangroves adjust to rising sea level through biotic controls on change in soil elevation

Aim The long‐term stability of coastal ecosystems such as mangroves and salt marshes depends upon the maintenance of soil elevations within the intertidal habitat as sea level changes. We examined the rates and processes of peat formation by mangroves of the Caribbean Region to better understand biological controls on habitat stability. Location Mangrove‐dominated islands on the Caribbean coasts of Belize, Honduras and Panama were selected as study sites. Methods Biological processes controlling mangrove peat formation were manipulated (in Belize) by the addition of nutrients (nitrogen or phosphorus) to Rhizophora mangle (red mangrove), and the effects on the dynamics of soil elevation were determined over a 3‐year period using rod surface elevation tables (RSET) and marker horizons. Peat composition and geological accretion rates were determined at all sites using radiocarbon‐dated cores. Results The addition of nutrients to mangroves caused significant changes in rates of mangrove root accumulation, which influenced both the rate and direction of change in elevation. Areas with low root input lost elevation and those with high rates gained elevation. These findings were consistent with peat analyses at multiple Caribbean sites showing that deposits (up to 10 m in depth) were composed primarily of mangrove root matter. Comparison of radiocarbon‐dated cores at the study sites with a sea‐level curve for the western Atlantic indicated a tight coupling between peat building in Caribbean mangroves and sea‐level rise over the Holocene. Main conclusions Mangroves common to the Caribbean region have adjusted to changing sea level mainly through subsurface accumulation of refractory mangrove roots. Without root and other organic inputs, submergence of these tidal forests is inevitable due to peat decomposition, physical compaction and eustatic sea‐level rise. These findings have relevance for predicting the effects of sea‐level rise and biophysical processes on tropical mangrove ecosystems.     

Chlorophyll Degradation: The Tocopherol Biosynthesis-Related Phytol Hydrolase in Arabidopsis Seeds Is Still Missing

Phytyl diphosphate (PDP) is the prenyl precursor for tocopherol biosynthesis. Based on recent genetic evidence, PDP is supplied to the tocopherol biosynthetic pathway primarily by chlorophyll degradation and sequential phytol phosphorylation. Three enzymes of Arabidopsis (Arabidopsis thaliana) are known to be capable of removing the phytol chain from chlorophyll in vitro: chlorophyllase1 (CLH1), CLH2, and pheophytin pheophorbide hydrolase (PPH), which specifically hydrolyzes pheophytin. While PPH, but not chlorophyllases, is required for in vivo chlorophyll breakdown during Arabidopsis leaf senescence, little is known about the involvement of these phytol-releasing enzymes in tocopherol biosynthesis. To explore the origin of PDP for tocopherol synthesis, seed tocopherol concentrations were determined in Arabidopsis lines engineered for seed-specific overexpression of PPH and in single and multiple mutants in the three genes encoding known dephytylating enzymes. Except for modestly increasing tocopherol content observed in the PPH overexpressor, none of the remaining lines exhibited significantly reduced tocopherol concentrations, suggesting that the known chlorophyll-derived phytol-releasing enzymes do not play major roles in tocopherol biosynthesis. Tocopherol content of seeds from double mutants in NONYELLOWING1 (NYE1) and NYE2, regulators of chlorophyll degradation, had modest reduction compared with wild-type seeds, although mature seeds of the double mutant retained significantly higher chlorophyll levels. These findings suggest that NYEs may play limited roles in regulating an unknown tocopherol biosynthesis-related phytol hydrolase. Meanwhile, seeds of wild-type over-expressing NYE1 had lower tocopherol levels, suggesting that phytol derived from NYE1-dependent chlorophyll degradation probably doesn’t enter tocopherol biosynthesis. Potential routes of chlorophyll degradation are discussed in relation to tocopherol biosynthesis.Vitamin E tocochromanols are lipidic antioxidants found in photosynthetic organisms that exist as two alternate classes, tocopherols and tocotrienols, which differ in the degree of saturation of the hydrophobic C20 prenyl side chain classes. Among these two classes, four forms occur that differ in methylation of the hydrophilic tocochromanol head group (Sattler et al., 2004). The initial step of tocopherol biosynthesis is the condensation of the aromatic head group precursor homogentisate and the prenyl tail precursor phytyl diphosphate (PDP). This reaction is catalyzed by a plastid-localized enzyme, homogentisate PDP transferase (HPT; Soll et al., 1980; Collakova and DellaPenna, 2001). PDP for tocopherol biosynthesis is either provided through direct reduction of geranylgeranyl diphosphate (Keller et al., 1998) or from chlorophyll-bound phytol through chlorophyll hydrolysis and subsequent conversion of free phytol into PDP by two consecutive kinase reactions (Fig. 1; Rise et al., 1989; Goffman et al., 1999; Matile et al., 1999; Kräutler, 2002; Hörtensteiner, 2006). The first of these phosphorylation steps was shown to be catalyzed by vitamin E pathway5 (VTE5; Valentin et al., 2006).Open in a separate windowFigure 1.The substrate PDP directing toward tocopherol biosynthesis is primarily derived from chlorophyll degradation. Two phytol-releasing activities are known, i.e. CLH catalyzing release from chlorophyll and PPH dephytylating pheophytin. Phytol is then converted to PDP by sequential kinase reactions catalyzed by VTE5 and a second, unknown kinase. Condensation of PDP and homogentisate by HPT marks the initial reaction of tocopherol biosynthesis. phy, Phytyl. [See online article for color version of this figure.]Seeds of the Arabidopsis (Arabidopsis thaliana) vte5 mutant have only about 20% of wild-type concentrations of vitamin E, while containing 3-fold more free phytol compared with seeds of wild-type plants (Valentin et al., 2006). In addition, it has been shown that tocopherol accumulation in Brassica napus seeds correlates with chlorophyll breakdown during seed development (Valentin et al., 2006). Therefore, it was concluded that in Arabidopsis, the 80% of PDP that is used for VTE5-dependent tocopherol biosynthesis in seeds arises from free phytol released during chlorophyll degradation. Chlorophyll degradation is an important catabolic process that is catalyzed by a multistep pathway and occurs during leaf senescence and fruit ripening. An early reaction of the chlorophyll degradation pathway is dephytylation. The true identity of the enzyme(s) associated with phytol release has only recently been revealed. It was long believed that chlorophyllase (CLH) is responsible for phytyl hydrolysis, yielding chlorophyllide and free phytol (Heaton and Marangoni, 1996; Takamiya et al., 2000; Hörtensteiner, 2006). However, analysis of the two CLHs in Arabidopsis, AtCLH1 and AtCLH2 (Tsuchiya et al., 1999; Takamiya et al., 2000), indicated that the AtCLH isoforms are neither chloroplast localized nor essential for senescence-related chlorophyll breakdown (Schenk et al., 2007). These findings are consistent with the observation that not all molecularly identified CLHs contain a predicted chloroplast transit peptide (Jacob-Wilk et al., 1999; Tsuchiya et al., 1999). As a consequence, subcellular compartments distinct from plastids were considered to be additional sites of chlorophyll degradation (Takamiya et al., 2000). By contrast, results obtained from Citrus spp. suggested that CLH functions as a rate-limiting enzyme in chlorophyll catabolism within the chloroplast and is controlled by posttranslational regulation (Harpaz-Saad et al., 2007; Azoulay Shemer et al., 2008). Additionally, work in Arabidopsis indicated that clh2 mutants showed a slight delay in chlorophyll degradation compared with clh1 and wild-type plants (Schenk et al., 2007).More recently, a novel plastid-localized enzyme, pheophytin pheophorbide hydrolase (PPH), was shown to be essential for chlorophyll breakdown during leaf senescence in Arabidopsis. PPH catalyzes the dephytylation of pheophytin rather than chlorophyll, resulting in pheophorbide and free phytol as the products (Schelbert et al., 2009). pph mutants are unable to degrade chlorophyll during senescence and therefore exhibit a stay-green phenotype in leaves. Altogether, these data reflect the complexity of the process of chlorophyll dephytylation and raise the question whether any of these activities may be related to tocopherol biosynthesis.Recently, Gregor Mendel’s green cotyledon gene stay-green (SGR), encoding a chloroplast-localized protein, was shown to be required for the initiation of chlorophyll breakdown (Armstead et al., 2007; Sato et al., 2007). Like in many plant species (Hörtensteiner, 2009), NON-YELLOWING1 (NYE1; also named SGR1), the Arabidopsis homolog of SGR, plays an important positive regulatory role in chlorophyll degradation during senescence, because NYE1 overexpression resulted in either pale-yellow leaves or even albino seedlings, while nye1 mutants retain chlorophyll during senescence (Ren et al., 2007). In addition, the second isoform of NYE in Arabidopsis, NYE2 (also named SGR2), is a negative regulator of chlorophyll degradation in senescent leaves (Sakuraba et al., 2014). By contrast, both enzymes positively contribute to chlorophyll breakdown during seed maturation (Delmas et al., 2013). NYE1 and NYE2 were shown to interact at light-harvesting complex II (LHCII) with other chlorophyll catabolic enzymes, including PPH. This suggests that SGRs might function as scaffold proteins in the formation of a catabolic multienzyme complex regulating chlorophyll degradation (Sakuraba et al., 2012, 2014). Whether NYE1 and NYE2 may also affect CLH function remains unclear, but their role as a key regulators for chlorophyll degradation raises the question whether NYEs may also play a role in tocopherol biosynthesis.Here, by employing Arabidopsis transferred DNA (T-DNA) insertion or nonsense mutants that are defective in known chlorophyll degradation-associated genes, and by PPH or NYE1 overexpression, we provide genetic and physiological evidence that neither CLHs nor PPH plays a major role in tocopherol biosynthesis in Arabidopsis seeds.     

Structural Basis for Evolution of Product Diversity in Soybean Glutathione Biosynthesis

The redox active peptide glutathione is ubiquitous in nature, but some plants also synthesize glutathione analogs in response to environmental stresses. To understand the evolution of chemical diversity in the closely related enzymes homoglutathione synthetase (hGS) and glutathione synthetase (GS), we determined the structures of soybean (Glycine max) hGS in three states: apoenzyme, bound to γ-glutamylcysteine (γEC), and with hGSH, ADP, and a sulfate ion bound in the active site. Domain movements and rearrangement of active site loops change the structure from an open active site form (apoenzyme and γEC complex) to a closed active site form (hGSH•ADP•SO₄²⁻ complex). The structure of hGS shows that two amino acid differences in an active site loop provide extra space to accommodate the longer β-Ala moiety of hGSH in comparison to the glycinyl group of glutathione. Mutation of either Leu-487 or Pro-488 to an Ala improves catalytic efficiency using Gly, but a double mutation (L487A/P488A) is required to convert the substrate preference of hGS from β-Ala to Gly. These structures, combined with site-directed mutagenesis, reveal the molecular changes that define the substrate preference of hGS, explain the product diversity within evolutionarily related GS-like enzymes, and reinforce the critical role of active site loops in the adaptation and diversification of enzyme function.     

Sphingolipid C-9 Methyltransferases Are Important for Growth and Virulence but Not for Sensitivity to Antifungal Plant Defensins in Fusarium graminearum

The C-9-methylated glucosylceramides (GlcCers) are sphingolipids unique to fungi. They play important roles in fungal growth and pathogenesis, and they act as receptors for some antifungal plant defensins. We have identified two genes, FgMT1 and FgMT2, that each encode a putative sphingolipid C-9 methyltransferase (C-9-MT) in the fungal pathogen Fusarium graminearum and complement a Pichia pastoris C-9-MT-null mutant. The ΔFgmt1 mutant produced C-9-methylated GlcCer like the wild-type strain, PH-1, whereas the ΔFgmt2 mutant produced 65 to 75% nonmethylated and 25 to 35% methylated GlcCer. No ΔFgmt1ΔFgmt2 double-knockout mutant producing only nonmethylated GlcCer could be recovered, suggesting that perhaps C-9-MTs are essential in this pathogen. This is in contrast to the nonessential nature of this enzyme in the unicellular fungus P. pastoris. The ΔFgmt2 mutant exhibited severe growth defects and produced abnormal conidia, while the ΔFgmt1 mutant grew like the wild-type strain, PH-1, under the conditions tested. The ΔFgmt2 mutant also exhibited drastically reduced disease symptoms in wheat and much-delayed disease symptoms in Arabidopsis thaliana. Surprisingly, the ΔFgmt2 mutant was less virulent on different host plants tested than the previously characterized ΔFggcs1 mutant, which lacks GlcCer synthase activity and produces no GlcCer at all. Moreover, the ΔFgmt1 and ΔFgmt2 mutants, as well as the P. pastoris strain in which the C-9-MT gene was deleted, retained sensitivity to the antifungal plant defensins MsDef1 and RsAFP2, indicating that the C-9 methyl group is not a critical structural feature of the GlcCer receptor required for the antifungal action of plant defensins.     

Mining the bitter melon (<Emphasis Type="Italic">momordica charantia</Emphasis>l.) seed transcriptome by 454 analysis of non-normalized and normalized cDNA populations for conjugated fatty acid metabolism-related genes

Background  

Seeds of Momordica charantia (bitter melon) produce high levels of eleostearic acid, an unusual conjugated fatty acid with industrial value. Deep sequencing of non-normalized and normalized cDNAs from developing bitter melon seeds was conducted to uncover key genes required for biotechnological transfer of conjugated fatty acid production to existing oilseed crops. It is expected that these studies will also provide basic information regarding the metabolism of other high-value novel fatty acids.