Nonuniversal Transverse Electron Mean Free Path through Few-layer Graphene.

In contrast to the in-plane transport electron mean-free path in graphene, the transverse mean-free path has received little attention and is often assumed to follow the "universal" mean-free path (MFP) curve broadly adopted in surface and interface science. Here we directly measure transverse electron scattering through graphene from 0 to 25 eV above the vacuum level both in reflection using low energy electron microscopy and in transmission using electronvolt transmission electron microscopy. From these data, we obtain quantitative MFPs for both elastic and inelastic scattering. Even at the lowest energies, the total MFP is just a few graphene layers and the elastic MFP oscillates with graphene layer number, both refuting the universal curve. A full theoretical calculation taking the graphene band structure into consideration agrees well with experiment, while the key experimental results are reproduced even by a simple optical toy model.

Microbial Community Dynamics and Response to Plant Growth-Promoting Microorganisms in the Rhizosphere of Four Common Food Crops Cultivated in Hydroponics.

Plant growth promoting microorganisms (PGPMs) of the plant root zone microbiome have received limited attention in hydroponic cultivation systems. In the framework of a project aimed at the development of a biological life support system for manned missions in space, we investigated the effects of PGPMs on four common food crops (durum and bread wheat, potato and soybean) cultivated in recirculating hydroponic systems for a whole life cycle. Each crop was inoculated with a commercial PGPM mixture and the composition of the microbial communities associated with their root rhizosphere, rhizoplane/endosphere and with the recirculating nutrient solution was characterised through 16S- and ITS-targeted Illumina MiSeq sequencing. PGPM addition was shown to induce changes in the composition of these communities, though these changes varied both between crops and over time. Microbial communities of PGPM-treated plants were shown to be more stable over time. Though additional development is required, this study highlights the potential benefits that PGPMs may confer to plants grown in hydroponic systems, particularly when cultivated in extreme environments such as space.

Charge Catastrophe and Dielectric Breakdown During Exposure of Organic Thin Films to Low-Energy Electron Radiation.

The effects of exposure to ionizing radiation are central in many areas of science and technology, including medicine and biology. Absorption of UV and soft-x-ray photons releases photoelectrons, followed by a cascade of lower energy secondary electrons with energies down to 0 eV. While these low energy electrons give rise to most chemical and physical changes, their interactions with soft materials are not well studied or understood. Here, we use a low energy electron microscope to expose thin organic resist films to electrons in the range 0-50 eV, and to analyze the energy distribution of electrons returned to the vacuum. We observe surface charging that depends strongly and nonlinearly on electron energy and electron beam current, abruptly switching sign during exposure. Charging can even be sufficiently severe to induce dielectric breakdown across the film. We provide a simple but comprehensive theoretical description of these phenomena, identifying the presence of a cusp catastrophe to explain the sudden switching phenomena seen in the experiments. Surprisingly, the films undergo changes at all incident electron energies, starting at ∼0 eV.

Intravarietal polymorphisms reveal possible common ancestor of native Schinus terebinthifolius Raddi populations in Brazil.

Schinus terebinthifolius Raddi is a perennial native from Atlantic forest. It is of high ecological plasticity and is used in traditional medicine. Based on promising reports concerning its bioactivity, it was included as a species of great interest for distribution through the National Health System. A number of agronomic studies to guide its crop production are therefore underway. This study examined diversity and phylogenetic relationships among native S. terebinthifolius populations from different Brazilian ecosystems: Cerrado; sandbanks; dense rainforest; and deciduous forest. The intergenic regions rpl20-5'rps12, trnH-psbA, and trnS-trnG were sequenced from cpDNA and aligned using BLASTn. There were few fragments for comparison in GenBank and so only region trnS-trnG was informative. There were variations among and within populations with intravarietal polymorphisms and three distinct haplotypes (HpSM, HpDDO, HpNE), once populations from NE (sandbanks and rainforest) clustered together. Sequences from HpSM, HpNE, and HpDDO returned greater similarity to haplotypes A (AY928398.1), B (AY928399.1), and C (AY928400.1), respectively. A network, built by median-joining among native haplotypes and 10 available on GenBank, revealed HpSM as the origin of all other haplogroups. HpDDO showed the most mutations and was closely related to haplogroups from Argentina. While this could indicate hybridization, we believe that the polymorphisms resulted from adaptation to events such as deforestation, fire, rising temperature, and seasonal drought during the transition from Atlantic forest to Cerrado. While more detailed phylogeographical studies are needed, these results indicate eligible groups for distinct climates as an important step for pre-breeding programs before field propagation.

Phosphonamide pyrabactin analogues as abscisic acid agonists.

A four step synthesis towards novel phosphonic pyrabactin analogues is presented. Via a stomatal closure and germination assay, the ability of the analogues to selectively induce the ABA-signaling pathway was demonstrated.

Walsh modes and radial quantum correlations of spatially entangled photons.

Orthogonal sets of 2D transverse modes are key to controlling the spatial degree of freedom of light in a classical or quantum context. In contrast to the azimuthal part, which is easily accessible using orbital angular momentum modes, control of the radial part is more difficult. We show here that simple sets of orthogonal binary sequences, the Walsh functions, provide a workable solution for exploration of the radial space with phase-only spatial light modulation. We demonstrate this by measuring "sequency" quantum correlations between different radial Walsh modes of spatially entangled photon pairs and for numerically optimized versions thereof.

SGO1 but not SGO2 is required for maintenance of centromere cohesion in Arabidopsis thaliana meiosis.

Shugoshin is a protein conserved in eukaryotes and protects sister chromatid cohesion at centromeres in meiosis. In our study, we identified the homologs of SGO1 and SGO2 in Arabidopsis thaliana. We show that AtSGO1 is necessary for the maintenance of centromere cohesion in meiosis I since atsgo1 mutants display premature separation of sister chromatids starting from anaphase I. Furthermore, we show that the localization of the specific centromeric cohesin AtSYN1 is not affected in atsgo1, suggesting that SGO1 centromere cohesion maintenance is not mediated by protection of SYN1 from cleavage. Finally, we show that AtSGO2 is dispensable for both meiotic and mitotic cell progression in Arabidopsis.

Localization and control of expression of Nt-Syr1, a tobacco SNARE protein.

Syntaxins and other SNARE proteins are crucial for intracellular vesicle trafficking, fusion and secretion. Previously, we isolated the syntaxin-related protein Nt-Syr1 from Nicotiana in a screen for ABA-related signalling elements, and demonstrated its role in determining the ABA sensitivity of stomatal guard cells. Because the location and expression of SNAREs are often important clues to their functioning, we have examined the distribution and stimulus-dependent expression of Nt-Syr1 between tissues, as well as its location within the cell, using antisera raised against purified recombinant peptides corresponding to overlapping cytosolic domains of Nt-Syr1. The Nt-Syr1 epitope was strongly represented in roots and to lesser extents in stems, leaves and flowers of well-watered plants. Biochemical analysis and examination of immunogold labelling under the electron microscope indicated Nt-Syr1 to be located primarily at the plasma membrane. Expression of the protein in leaves and to a lesser extent in flowers and stems was transiently enhanced by ABA, but not by auxin, kinetin or gibberellic acid. Expression in leaves was promoted by salt stress and wounding, but not by cold. By contrast, Nt-Syr1 levels in the root were unaffected by ABA. In the leaves, enhanced expression of Nt-Syr1 by salt stress was not observed in aba1 mutant Nicotiana, which is deficient in ABA synthesis, and in plants carrying the Arabidopsis abi1 transgene that suppresses a number of ABA-evoked responses in these plants. However, an enhanced expression in response to wounding was observed, even in the mutant backgrounds. We conclude that Nt-Syr1 expression at the plasma membrane is important for its function and is subject to control by parallel, stress-related signalling pathways, both dependent on and independent of ABA. Nt-Syr1 may be associated with additional functions, especially in the roots, that are unrelated to ABA or stress responses in the plant.

Disruption of putative anion channel gene AtCLC-a in Arabidopsis suggests a role in the regulation of nitrate content.

In animals and yeast, voltage-dependent chloride channels of the CLC family play a role in basic cellular functions such as epithelial transport, plasma membrane excitability, and control of pH and membrane potential in intracellular compartments. To assess the function of CLCs in plants, we searched for CLC insertion mutants in a library of Arabidopsis lines transformed by Agrobacterium tumefaciens transferred DNA (T-DNA). Using a polymerase chain reaction-based screening procedure, an Arabidopsis line that carries a T-DNA insertion within the C-terminus of the AtCLC-a coding sequence was identified. Progeny from this plant line, clca-1, showed dramatically altered transcription of the AtCLC-a gene. Plants homozygous for the clca-1 mutation exhibited normal development and a morphology indistinguishable from the wild-type. However, their capacity to accumulate nitrate under conditions of nitrate excess was reduced in roots and shoots, by approximately 50%, while chloride, sulphate and phosphate levels were similar to the wild-type. In addition, the herbicide chlorate, an analogue of nitrate, induced a faster and more pronounced chlorosis in mutant plants. Hypersensitivity to chlorate as well as decreased nitrate levels co-segregated with the T-DNA insertion. They were found at various time points of the clca-1 life cycle, supporting the idea that AtCLC-a has a general role in the control of the nitrate status in Arabidopsis. Concordant with such a function, AtCLC-a mRNA was found in roots and shoots, and its levels rapidly increased in both tissues upon addition of nitrate but not ammonium to the culture medium. The specificity of AtCLC-a function with respect to nitrate is further supported by a similar free amino acid content in wild-type and clca-1 plants. Although the cellular localization of AtCLC-a remains unclear, our results suggest that AtCLC-a plays a role in controlling the intracellular nitrate status.

A tobacco syntaxin with a role in hormonal control of guard cell ion channels.

The plant hormone abscisic acid (ABA) regulates potassium and chloride ion channels at the plasma membrane of guard cells, leading to stomatal closure that reduces transpirational water loss from the leaf. The tobacco Nt-SYR1 gene encodes a syntaxin that is associated with the plasma membrane. Syntaxins and related SNARE proteins aid intracellular vesicle trafficking, fusion, and secretion. Disrupting Nt-Syr1 function by cleavage with Clostridium botulinum type C toxin or competition with a soluble fragment of Nt-Syr1 prevents potassium and chloride ion channel response to ABA in guard cells and implicates Nt-Syr1 in an ABA-signaling cascade.

Function and regulation of seed aquaporins.

The discovery of water channel proteins named aquaporins has shed new light on the molecular mechanisms of transmembrane water transport in higher plants. As with their animal counterparts, plant aquaporins belong to the large MIP family of transmembrane channels. An increasing number of aquaporins is now being identified on both the vacuolar and plasma membranes of plant cells, but their integrated function remains unclear. Aquaporin α-TIP is specifically expressed in the membrane of protein storage vacuoles in seeds of many plant species. α-TIP was previously shown to undergo phosphorylation in bean seeds. The functional significance of this process was further investigated after heterologous expression of the protein in Xenopus oocytes. Using site-directed mutagenesis of α-TIP and in vitro and in vivo phosphorylation by animal cAMP-dependent protein kinase, it is shown that, in oocytes, direct phosphorylation of α-TIP occurs at three distinct sites and stimulates its water channel activity. In addition to aquaporin phosphorylation, other mechanisms that target aquaporin function are used by living cells to regulate their membrane water permeability. These are the fine control of aquaporin gene expression and, in animal cells only, the regulated trafficking of water channel-containing vesicles. The present work and studies by others on the phosphorylation of nodulin-26, an ion channel protein homologous to α-TIP, provide novel insights into the mechanisms of plant membrane protein regulation. These studies might help identifying and characterizing novel membrane-bound protein kinases and phosphatases. Finally, an integrated function for seed vacuolar aquaporins is discussed. During germination, the rehydration of seed cells, the drastic changes in vacuole morphology, the breakdown and the mobilization of storage products from the vacuole may create osmotic perturbations in the cytoplasm. The fine tuning of TIP aquaporin activity may help control the kinetics and amplitude of osmotic water flows across the tonoplast to achieve proper cytoplasm osmoregulation and control of vacuolar volume.

Fucosylation and arabinosylation of Nod factors in Azorhizobium caulinodans: involvement of nolK, nodZ as well as noeC and/or downstream genes.

The DNA region downstream of the nodABCSUIJ operon of Azorhizobium caulinodans was further characterized and two new genes, nodZ and noeC were identified in the same operon. The A. caulinodans wild-type strain produces a population of Nod factors that, at the reducing end, are either unmodified or carry a D-arabinosyl and/or an L-fucosyl branch. Nod factors produced by Tn5-insertion mutants in nodZ, noeC, and the separate nolK locus, were analysed by thin-layer chromatography and mass spectrometry. Fucosylation of Nod factors depended on both nodZ and nolK. Arabinosylation depended on noeC and/or downstream genes. Protein extracts of A. caulinodans contained an enzymatic activity for fucose transfer from GDP-fucose to chitooligosaccharides and to Nod factors. By mutant analysis and expression of nodZ in Escherichia coli, the fucosyltransferase activity was ascribed to the protein encoded by nodZ. In addition, a Nod factor fucosyltransferase activity, independent of nodZ or other known nod genes, was detected in A. caulinodans. Finally, on the basis of sequence similarity of the nolK gene product, and mass spectrometric analysis of Nod factors produced by a nolK mutant, we propose that this gene is involved in the synthesis of GDP-fucose.

Cloning and functional expression of a plant voltage-dependent chloride channel.

Plant cell membrane anion channels participate in basic physiological functions, such as cell volume regulation and signal transduction. However, nothing is known about their molecular structure. Using a polymerase chain reaction strategy, we have cloned a tobacco cDNA (CIC-Nt1) encoding a 780-amino acid protein with several putative transmembrane domains. CIC-Nt1 displays 24 to 32% amino acid identity with members of the animal voltage-dependent chloride channel (CIC) family, whose archetype is CIC-0 from the Torpedo marmorata electric organ. Injection of CIC-Nt1 complementary RNA into Xenopus oocytes elicited slowly activating inward currents upon membrane hyperpolarization more negative than -120 mV. These currents were carried mainly by anions, modulated by extracellular anions, and totally blocked by 10 mM extracellular calcium. The identification of CIC-Nt1 extends the CIC family to higher plants and provides a molecular probe for the study of voltage-dependent anion channels in plants.

Biosynthesis of Azorhizobium caulinodans Nod factors. Study of the activity of the NodABCS proteins by expression of the genes in Escherichia coli.

By in vitro and in vivo studies with Escherichia coli expressing different combinations of the nodABCS genes of Azorhizobium caulinodans, Nod factor intermediates were identified and their structures determined using mass spectrometry. Substrate-product relationships were studied by time course experiments, and the Nod factor biosynthetic pathway was partially resolved. E. coli strains, harboring nodA and/or nodB, did not produce Nod metabolites, whereas the strain expressing nodC produced chitooligosaccharides. Thus, the first committed step was the production of the carbohydrate backbone. Bacitracin and tunicamycin did not affect this step, suggesting that undecaprenyl pyrophosphate-linked intermediates were not involved. The second step was the deacetylation of chitooligosaccharides by NodB since the E. coli strain expressing nodBC produced chitooligosaccharides, deacetylated at the non-reducing end and since the NodC products were precursors of the NodBC products. A strain expressing nodBCS produced N-methylated oligosaccharides, whereas a strain expressing nodCS produced unmethylated oligosaccharides. Time course experiments showed that methylation occurred after deacetylation. Thus, NodS acted after NodB. The NodBCS metabolites were partially converted to lipo-chitooligosaccharides when the nodABCS genes were expressed, showing that NodA was involved in the acylation and acted after NodS.

The nodD locus from Azorhizobium caulinodans is flanked by two repetitive elements.

The sequence surrounding the Azorhizobium caulinodans (Ac) regulatory nodD gene was analyzed. Upstream from nodD and in the opposite orientation, two small open reading frames were identified (ORF1 and ORF2). The DNA sequence corresponding to ORF1, termed epsilon 1, is similar to a part of the insertion element IS51 from Pseudomonas savastanoi. Immediately downstream from nodD, a repeated element, delta 1, has been described [Goethals et al., Mol. Plant-Microbe Interact. 5 (1992) 405-411]. The elements epsilon 1 and delta 1 form the borders of a shift in GC content between nodD and its surrounding sequences. delta 1 and the ORF1+ORF2 sequence both occur as two copies in the Ac genome. Based on these observations, we postulate that the repeated elements played a role in the horizontal transfer of nodD during evolution. Insertion mutations in epsilon 1 and delta 1 did not influence the induction of the nodulation operon, nodABCSUIJ, and had no effect on the nodulation behavior on Sesbania rostrata. lacZ fusion studies suggested that nodD is constitutively transcribed and that the promoter driving nodD expression overlaps with the ORF1 sequence. In contrast, promoter activity in the direction of ORF1 and ORF2 was not observed. In the nodD-ORF1-intervening sequence, a nod box-related motif was recognized that deviates from active nod boxes by the absence of an ATC-9-bp-GAT palindrome, i.e., a sequence involved in NodD-mediated transcription stimulation [Goethals et al., Proc. Natl. Acad. Sci. USA 89 (1992) 1646-1650].

Cloning of an Azorhizobium caulinodans endoglucanase gene and analysis of its role in symbiosis.

Azorhizobium caulinodans ORS571, a symbiont of the tropical leguminous plant Sesbania rostrata, showed low, constitutive levels of endoglucanase (Egl) activity. A clone carrying the gene responsible for this phenotype was isolated via introduction of a genomic library into the wild-type strain and screening for transconjugants with enhanced Egl activity. By subcloning and expression in Escherichia coli, the Egl phenotype was allocated to a 3-kb EcoRI-BamHI fragment. However, sequence analysis showed the egl gene to be much larger, consisting of an open reading frame of 1,836 amino acids. Within the deduced polypeptide, three kinds of putative domains were identified: a catalytic domain, two cellulose-binding domains, and an eightfold reiterated motif. The catalytic domain belongs to the family A of cellulases. A C-terminal stretch of 100 amino acids was similar to family II cellulose-binding domains. A second copy of this domain occurred near the middle of the polypeptide, flanked by reiterated motifs. ORS571 mutants carrying a Tn5 insertion in the egl gene had lost the Egl activity. These mutants as well as Egl-overproducing strains showed a normal nodulation behavior, indistinguishable from wild-type nodulation on Sesbania rostrata under laboratory conditions.

NodS is an S-adenosyl-L-methionine-dependent methyltransferase that methylates chitooligosaccharides deacetylated at the non-reducing end.

In response to phenolic compounds exuded by the host plant, symbiotic Rhizobium bacteria produce signal molecules (Nod factors), consisting of lipochitooligosaccharides with strain-specific substitutions. In Azorhizobium caulinodans strain ORS571 these modifications are an O-arabinosyl group, an O-carbamoyl group, and an N-methyl group. Several lines of evidence indicate that the nodS gene located in the nodABCSUIJ operon is implicated in the methylation of Nod factors. Previously we have shown that NodS is an S-adenosyl-L-methionine (SAM)-binding protein, essential for the L-[3H-methyl]-methionine labelling of ORS571 Nod factors in vivo. Here, we present an in vitro assay showing that NodS from either A. caulinodans or Rhizobium species NGR234 methylates end-deacetylated chitooligosaccharides, using [3H-methyl]-SAM as a methyl donor. The enzymatic and SAM-binding activity were correlated with the nodS gene and localized within the soluble protein fraction. The A. caulinodans nodS gene was expressed in Escherichia coli and a glutathione-S-transferase-NodS fusion protein purified. This protein bound SAM and could methylate end-deacetylated chitooligosaccharides, but could not fully methylate acetylated chitooligosaccharides or unmethylated lipo-chitooligosaccharides. These data implicate that the methylation step in the biosynthesis pathway of ORS571 Nod factors occurs after deacetylation and prior to acylation of the chitooligosaccharides.