Impact of Willow Short Rotation Coppice on Water Quality

Short rotation coppice (SRC) with willow has been grown in Sweden from the late 1980s to produce biomass for energy on agricultural land. This study evaluated the effects of SRC on water quality by determining differences in leaching of nitrogen and phosphorus to groundwater of a number of commercial “old” SRC willow stands in Sweden compared to adjacent arable fields grown with “ordinary” crops. The study was conducted in 16 locations under three vegetation seasons. NO₃–N leaching from willow SRC fields was significantly lower than that from reference fields with cereals. The opposite was observed for PO₄–P; concentrations in the groundwater of SRC were higher compared to reference fields. Sewage sludge applications were not responsible for the elevated PO₄–P leaching under SRC compared to reference crops.     

Assessing the rider's seat and horse's behavior: difficulties and perspectives

A correct seat and position are the basis for a good performance in horseback riding. This study aimed to measure deviations from the correct seat, test a seat improvement program (dismounted exercises), and investigate whether horse behavior was affected by the rider's seat. Five experienced trainers defined 16 seat deviations and scored the occurrence in 20 riders in a dressage test. Half the riders then carried out an individual training program; after 9 weeks, riders were again scored. The study took no video or heart-rate recordings of horses and riders. Panel members did not agree on the deviations in the rider's seat; the study detected no differences-with the exception of improvement of backward-tilted pelvis-between the groups. Horse behavior, classified as "evasive," increased; horse heart rate decreased in the experimental group. Heart rates of riders in both groups decreased. Seven of 9 riders in the experimental group had the impression that the exercises improved their riding performance. There is a clear need to develop a robust system that allows trainers to objectively evaluate the rider's seat.     

Gut flora, Toll-like receptors and nuclear receptors: a tripartite communication that tunes innate immunity in large intestine

Separating the large intestine from gut flora is a robust layer of epithelial cells. This barrier is armed with an array of recognizing receptors that collectively set the host innate response. Here, we use nuclear receptors (NRs) and Toll-like receptors (TLRs), suggested to act as second messengers in the communication between microorganisms and epithelial cells, as probes to assess the impact of gut flora on innate immunity in germ-free (GF) mice. Using quantitative real-time polymerase chain reaction analyses, we show that 37/49 NRs are expressed in colonic cells of GF mice. Of these, 5 can be modulated by resident flora: LXRα, RORγ and CAR show reduced expression and Nur77 and GCNF display elevated expression in conventionally raised mice compared with GF. Moreover, increased expression levels of TLR-2 and TLR-5 are observed in specific pathogen-free (SPF) mice compared with GF mice, and CAR expression is connected to the TLR-2 signalling pathway. Infections of GF or SPF mice with Yersinia pseudotuberculosis , show that GF intestinal epithelial cells fail to respond, except for CAR, which is downregulated. In contrast, SPF epithelial cells show a downregulation of all the NRs except CAR, which appears to be unaffected. Our findings indicate that gut flora contributes to the development of an intact barrier function.     

The galactolipid monogalactosyldiacylglycerol (MGDG) contributes to photosynthesis-related processes in Arabidopsis thaliana

Processes putatively dependent on the galactolipid monogalactosyldiacylglycerol (MGDG) were recently studied using the knockdown monogalactosyldiacylglycerol synthase 1 (mgd1-1) mutant (∼40% reduction in MGDG). Surprisingly, targeting of chloroplast proteins was not affected in mgd1-1 mutants, suggesting they retain sufficient MGDG to maintain efficient targeting. However, in dark-grown mgd1-1 plants the photoactive to photoinactive protochlorophyllide (Pchlide) ratio was increased, suggesting that photoprotective responses are induced in them. Nevertheless, mgd1-1 could not withstand high light intensities, apparently due to impairment of another photoprotective mechanism, the xanthophyll cycle (and hence thermal dissipation). This was mediated by increased conductivity of the thylakoid membrane leading to a higher pH in the thylakoid interior, which impaired the pH-dependent activation of violaxanthin de-epoxidase (VDE) and PsbS. These findings suggest that MGDG contribute directly to the regulation of photosynthesis-related processes.Key words: conductivity, galactolipid, light stress, photosynthesis, plastid, xanthophyllThe galactolipid monogalactosyldiacylglycerol (MGDG), the major lipid in plastids,¹ is mainly synthesised in inner plastid envelopes,² where monogalactosyldiacylglycerol synthase 1 (MGD1) catalyses the last step of its production.³ Two MGDG-deficient mutants are known: the knockdown mgd1-1 mutant, which accumulates ∼40% less MGDG than wild type,⁴ and the null mutant mgd1-2, which displays extremely severe defects in chloroplast and plant development.⁵ Thus, the mgd1-1 mutant is more suitable for assessing putative roles of MGDG in processes such as protein targeting and photoprotection.There are conflicting indications regarding the involvement of galactolipids in chloroplast protein targeting: some suggest they play an important role,^6–10 but not all.^11,12 The data recently collected for mgd1-1 do not support MGDG''s involvement in protein targeting, since (inter alia) the level of MGDG in mgd1-1 mutants is clearly sufficient for efficient targeting.¹³ Further, the galactolipid associated with the TOC complex¹² is digalactosyldiacylglycerol (DGDG) and the digalactosyldiacylglycerol synthase 1 (dgd1) mutant,¹⁴ which has ∼10% of wild-type levels of DGDG, has impaired import efficiency.^15,16 Hence, this may indicate that DGDG is relatively more important for chloroplast import than MGDG.The prolamellar bodies (PLBs) of etioplasts have high lipid-to-protein ratios compared to thylakoids. Their major lipid and protein are MGDG and NADPH:Pchlide oxidoreductase (POR), respectively,¹⁷ and MGDG putatively plays an important role, interactively with POR, in the formation of PLBs.^18–20 The transformation of PLBs into thylakoids involves phototransformation of photoactive Pchlide (F656), a precursor of chlorophyll. Non-photoactive Pchlide (F631) is susceptible to photooxidative damage, but POR is believed to suppress this.^21,22 After excitation at 440 nm, mgd1-1 mutants display distinctly higher fluorescence emission peaks corresponding to photoactive Pchlide than wild type counterparts and (hence) higher photoactive:non-photoactive Pchlide ratios.¹³ These changes may be photoprotective responses that favour formation of photoactive Pchlide and optimize the plants'' opportunities to use light for chlorophyll production, enabling the transformation of etioplasts into chloroplasts.Interestingly,the xanthophyll cycle, another photoprotective mechanism, is impaired in mgd1-1.¹³ Normally, the xanthophyll cycle pigment violaxanthin is de-epoxidized into antheraxanthin, and then into zeaxanthin, by the enzyme VDE (Fig. 1), which is dependent on MGDG.²³ MGDG is also an integral component of photosynthetic complexes.^24–26 Thus, since mgd1-1 mutants have reduced total amounts of xanthophyll and chlorophyll pigments, but increased chlorophyll a/b ratios, their photosynthesis capacity is unsurprisingly reduced, even though the organization of their electron transport chains is not strongly affected by the MGDG deficiency.¹³Open in a separate windowFigure 1Reactions of the xanthophyll cycle (adapted from ref. ²⁹). VDE, violaxanthin de-epoxidase; ZE, zeaxanthin epoxidase.During short-term high light stress, antheraxanthin and zeaxanthin are thought to facilitate dissipation of excess light energy in the PSII antenna bed by non-photochemical quenching.^27,28 Upon high light stress the pH decreases, triggering photoprotective mechanisms via changes in the PSII antenna system. The PsbS protein, which is involved in thermal dissipation, is protonated and initiates a conformational change in the PSII antenna bed. This change is further stabilized by the de-epoxidation of violaxanthin to zeaxanthin by the luminal VDE.²⁸ However, the thermal dissipation is impaired in mgd1-1 mutants at high light intensities (>1000 µmol m⁻² s⁻¹) making them more susceptible to light stress. Surprisingly, this is not mediated by direct effects on VDE and PsbS activities, but by changes in the proton conductivity of the thylakoid membrane.¹³The steady-state capacity of the xanthophyll cycle is reduced in mgd1-1 mutants, due to a ∼40% reduction in the proton motive force (pmf) across their thylakoid membranes, indicating that they have impaired capacities to energize these membranes. Nevertheless, the pmf is more or less equal to wild type under light-limited conditions (200 µmol m⁻² s⁻¹ light); it is only the increase in pmf in high light intensities that is impaired in the mutants.¹³ This leads to the thylakoid lumen being less acidic in mgd1-1 than in wild type, hampering full activation of VDE and PsbS. Thus, the thylakoid lumen pH is above the threshold level required for full activation of PsbS and VDE under steady-state conditions and so de-epoxidation rates are retarded and the equilibrium between zeaxanthin and violaxanthin starts to shift slightly towards violaxanthin (Fig. 2).¹³ Thus, increased conductivity of the thylakoid membranes is probably responsible for the diminished non-photochemical quenching in mgd1-1, and the findings strongly indicate that MGDG is required for efficient photosynthesis and photoprotection, in addition to being a physical membrane constituent.Open in a separate windowFigure 2Schematic diagram illustrating the normal mode of action of the xanthophyll cycle. In standard light conditions, V is bound to the photosynthetic complexes and harvests light. In strong light, V is released from the complexes and converted to Z by VDE, which is unable to access V when it is associated with the photosynthetic complexes. The newly formed Z then binds to the photosynthetic complexes (at the PsbS protein), where it dissipates excess energy through NPQ. V, violaxanthin; A, antheraxanthin; Z, zeaxanthin; VDE, violaxanthin de-epoxidase; ZE, zeaxanthin epoxidase. Arrows indicate the directions of reactions.     

A microsatellite linkage map of Drosophila mojavensis

Background

Drosophila mojavensishas been a model system for genetic studies of ecological adaptation and speciation. However, despite its use for over half a century, no linkage map has been produced for this species or its close relatives.

Results

We have developed and mapped 90 microsatellites in D. mojavensis, and we present a detailed recombinational linkage map of 34 of these microsatellites. A slight excess of repetitive sequence was observed on the X-chromosome relative to the autosomes, and the linkage groups have a greater recombinational length than the homologous D. melanogaster chromosome arms. We also confirmed the conservation of Muller's elements in 23 sequences between D. melanogaster and D. mojavensis.

Conclusions

The microsatellite primer sequences and localizations are presented here and made available to the public. This map will facilitate future quantitative trait locus mapping studies of phenotypes involved in adaptation or reproductive isolation using this species.     

Involvement of the Electrophilic Isothiocyanate Sulforaphane in Arabidopsis Local Defense Responses

Plants defend themselves against microbial pathogens through a range of highly sophisticated and integrated molecular systems. Recognition of pathogen-secreted effector proteins often triggers the hypersensitive response (HR), a complex multicellular defense reaction where programmed cell death of cells surrounding the primary site of infection is a prominent feature. Even though the HR was described almost a century ago, cell-to-cell factors acting at the local level generating the full defense reaction have remained obscure. In this study, we sought to identify diffusible molecules produced during the HR that could induce cell death in naive tissue. We found that 4-methylsulfinylbutyl isothiocyanate (sulforaphane) is released by Arabidopsis (Arabidopsis thaliana) leaf tissue undergoing the HR and that this compound induces cell death as well as primes defense in naive tissue. Two different mutants impaired in the pathogen-induced accumulation of sulforaphane displayed attenuated programmed cell death upon bacterial and oomycete effector recognition as well as decreased resistance to several isolates of the plant pathogen Hyaloperonospora arabidopsidis. Treatment with sulforaphane provided protection against a virulent H. arabidopsidis isolate. Glucosinolate breakdown products are recognized as antifeeding compounds toward insects and recently also as intracellular signaling and bacteriostatic molecules in Arabidopsis. The data presented here indicate that these compounds also trigger local defense responses in Arabidopsis tissue.Plants are constantly challenged by pathogenic microorganisms and have developed several detection and defense systems to protect themselves against the invaders. Preformed defenses include the waxy cuticle, thick cell walls, and antimicrobial compounds. After recognition of microbe-associated patterns, defense responses are induced, which include the fortification of cell walls and the production of phytoalexins (Monaghan and Zipfel, 2012). Overcoming the preformed and induced defenses of the plant hosts requires adaptation by the pathogen. Pathogenic bacteria use type III secretion to inject proteins (so-called effectors) into the host cytosol in order to overcome plant defense responses (Bent and Mackey, 2007). In turn, plants have developed systems to recognize the pathogenic effectors and mount defense. Recognition of type III effectors by plant resistance (R) proteins induces robust defense responses that frequently include the hypersensitive response (HR).The HR is a complex defense reaction characterized by the induction of programmed cell death (PCD) in the local host tissue as well as the activation of other defense responses in both local and systemic tissue (Mur et al., 2008; Shah, 2009). Oomycetes and true fungi also secrete proteinaceous effectors that can be recognized by host R proteins (Coates and Beynon, 2010; Hückelhoven and Panstruga, 2011; Feng and Zhou, 2012). The lesions formed during the HR vary in size between different host-pathogen pairs; however, a lesion induced at one or a few cells can spread to surrounding cells (Mur et al., 2008). Since pathogens inducing HR typically fail to proliferate, the first infected cell likely releases a compound that promotes PCD in surrounding cells. This is especially clear in models with oomycete and fungal pathogens, where the localization of the pathogen and the spread of cell death around the infection site can be clearly visualized (Mur et al., 2008; Coates and Beynon, 2010). Trailing necrosis is an incomplete resistance phenotype characterized by cell death that trails, but fails to contain, the filamentous growth of the pathogen. One explanation for trailing necrosis is a failure of infected cells to produce a putative mobile defense signal required to enhance defense in neighboring cells. Farther from the site of PCD, other defense pathways are activated and systemic tissue is primed for defense.The hunt for systemically acting compounds has been intense, and several candidates for this signal have been presented (Dempsey and Klessig, 2012). In contrast, even though the phenomenon of HR as a defense reaction was described almost a century ago (Stakman, 1915; Mur et al., 2008), compounds acting on the local tissue scale of the HR have attracted little attention. We set out to find substances released from cells undergoing the HR that could induce cell death in naive tissue. We report that leaf tissue of the model plant Arabidopsis (Arabidopsis thaliana) releases the reactive electrophilic compound sulforaphane after bacterial effector recognition. Mutants affected in sulforaphane production as well as other glucosinolate breakdown products showed delayed or reduced cell death after the recognition of pathogenic effectors and decreased resistance to an oomycete pathogen. Moreover, pretreatment of plants with sulforaphane enhanced resistance against a virulent oomycete isolate. Thus, we interpret this as that sulforaphane and likely similar compounds might both possess direct antimicrobial properties and, through a cytotoxic mechanism, act directly on plant cells to trigger defense responses.     

Optimization and clinical validation of a pathogen detection microarray

DNA microarrays used as 'genomic sensors' have great potential in clinical diagnostics. Biases inherent in random PCR-amplification, cross-hybridization effects, and inadequate microarray analysis, however, limit detection sensitivity and specificity. Here, we have studied the relationships between viral amplification efficiency, hybridization signal, and target-probe annealing specificity using a customized microarray platform. Novel features of this platform include the development of a robust algorithm that accurately predicts PCR bias during DNA amplification and can be used to improve PCR primer design, as well as a powerful statistical concept for inferring pathogen identity from probe recognition signatures. Compared to real-time PCR, the microarray platform identified pathogens with 94% accuracy (76% sensitivity and 100% specificity) in a panel of 36 patient specimens. Our findings show that microarrays can be used for the robust and accurate diagnosis of pathogens, and further substantiate the use of microarray technology in clinical diagnostics.     

Glycosylation sites and site-specific glycosylation in human Tamm- Horsfall glycoprotein

The N-glycosylation sites of human Tamm-Horsfall glycoprotein from one healthy male donor have been characterized, based on an approach using endoproteinase Glu-C (V-8 protease, Staphylococcus aureus ) digestion and a combination of chromatographic techniques, automated Edman sequencing, and fast atom bombardment mass spectrometry. Seven out of the eight potential N-glycosylation sites, namely, Asn52, Asn56, Asn208, Asn251, Asn298, Asn372, and Asn489, turned out to be glycosylated, and the potential glycosylation site at Asn14, being close to the N-terminus, is not used. The carbohydrate microheterogeneity on three of the glycosylation sites was studied in more detail by high-pH anion-exchange chromatographic profiling and 500 MHz1H-NMR spectroscopy. Glycosylation site Asn489 contains mainly di- and tri-charged oligosaccharides which comprise, among others, the GalNAc4 S (beta1-4)GlcNAc terminal sequence. Only glycosylation site Asn251 bears oligomannose-type carbohydrate chains ranging from Man5GlcNAc2to Man8GlcNAc2, in addition to a small amount of complex- type structures. Profiling of the carbohydrate moieties of Asn208 indicates a large heterogeneity, similar to that established for native human Tamm-Horsfall glycoprotein, namely, multiply charged complex-type carbohydrate structures, terminated by sulfate groups, sialic acid residues, and/or the Sda-determinant.