The role of foam in improving the workability of sand : insights from DEM

Foam as a soil conditioner can transform the mechanical properties of the excavated natural muck and lubricate the interface between the cutting tools and muck, thus reducing the tools’ wear and promoting the efficiency of earth pressure balance (EPB) shield tunneling. This paper aims to explore the meso-mechanism of foam in improving the workability of sand by combining discrete element modeling (DEM) with experimental investigations of slump tests. A “sand-foam” mixture DEM model was generated by simplifying the sand grains and foam as individual particles with different properties. The particle-scale simulated parameters were calibrated based on a series of experimental observations. The effects of foam on the inter-particle contact distribution and the evolution of contact forces during the slumping process were investigated in detail through numerical modeling. It was found that injecting foam into sand specimens could increase the coordination number and the contact number around sand grains. Although the force transmission pattern changes from “sand-sand” into the coexistence of “sand-foam”, “sand-sand” and “foam-foam” contacts, the magnitude of contact forces transferred by foam particles is significantly lower than that by sand particles. The presence of foam reduces contact-scale frictional strength and thus reduces the stability of the microstructures of sand. In addition, the normal direction of inter-particle contact force deflects from the vertical to the horizontal and the magnitude of contact force decreases significantly with the influence of foam

Optimization of the cry1Ah1 Sequence Enhances the Hyper-Resistance of Transgenic Poplars to Hyphantria cunea

Increased expression of the insect control protein genes of Bacillus thuringiensis in Populus has been critical to the development of genetically improved plants with agronomically acceptable levels of insect resistance. Bacillus thuringiensis (Cry1Ah1) proteins with highly specific toxicity against Hyphantria cunea were screened using an indoor bioactivity assay to obtain hyper-resistant transgenic poplars. Then, the Cry1Ah1 sequence was optimized and transformed according to the optimal codon in poplar using software of our own design (http://120.79.60.226:8080/u/chen/w/codonpoplar). A vector was constructed to transform poplar NL895. The Cry1Ah1 gene was transformed to poplar NL895 and six transgenic lines were obtained. The expression and insecticidal effect of the Cry1Ah1 gene in transgenic poplar were evaluated by PCR and ELISA, and the specific indoor activity and field insecticidal activity against H. cunea were compared with a control. We concluded that the insecticidal activity of the transgenic NL895 was significantly better against lower instar larvae of H. cunea than against higher instar larvae. The mortality and pupation rates clearly differed among the various instar larvae and between transgenic and non-transgenic poplar. We obtained poplar seedlings with hyper-resistance to H. cunea by screening Bt genes and optimizing their genetic sequence

Flexible polydimethylsiloxane/multi-walled carbon nanotubes membranous metacomposites with negative permittivity

Metacomposites with negative electromagnetic parameters can be promising substitute for periodic metamaterials. In this paper, we devoted to fabricating flexible metacomposite films, which have great potential applications in the field of wearable cloaks, sensing, perfect absorption and stretchable electronic devices. The conductivity and the complex permittivity were investigated in flexible polydimethylsiloxane (PDMS)/multi-walled carbon nanotubes (MWCNTs) membranous nanocomposites, which were fabricated via in-situ polymerization process. With the increase of conductive one-dimension carbon nanotubes concentration, there was a percolation transition observed in conduction due to the formation of continuous networks. The dielectric dispersion behavior was also analyzed in the spectra of complex permittivity. It is indicated that the conduction and polarization make a combined effect on the dielectric loss in flexible PDMS/MWCNTs composites. The negative permittivity with a dielectric resonance was obtained, and was attributed to the induced electric dipoles

Calibration of linear contact stiffnesses in discrete element models using a hybrid analytical-computational framework

Efficient selections of particle-scale contact parameters in discrete element modelling remain an open question. The aim of this study is to provide a hybrid calibration framework to estimate linear contact stiffnesses (normal and tangential) for both two-dimensional and three-dimensional simulations. Analytical formulas linking macroscopic parameters (Young's modulus, Poisson's ratio) to mesoscopic particle parameters for granular systems are derived based on statistically isotropic packings under small-strain isotropic stress conditions. By taking the derived analytical solutions as initial approximations, the gradient descent algorithm automatically obtains a reliable numerical estimation. The proposed framework is validated with several numerical cases including randomly distributed monodisperse and polydisperse packings. The results show that this hybrid method practically reduces the time for artificial trials and errors to obtain reasonable stiffness parameters. The proposed framework can be extended to other parameter calibration problems in DEM

Saturation of an Intra-Gene Pool Linkage Map: Towards a Unified Consensus Linkage Map for Fine Mapping and Synteny Analysis in Common Bean

Map-based cloning and fine mapping to find genes of interest and marker assisted selection (MAS) requires good genetic maps with reproducible markers. In this study, we saturated the linkage map of the intra-gene pool population of common bean DOR364×BAT477 (DB) by evaluating 2,706 molecular markers including SSR, SNP, and gene-based markers. On average the polymorphism rate was 7.7% due to the narrow genetic base between the parents. The DB linkage map consisted of 291 markers with a total map length of 1,788 cM. A consensus map was built using the core mapping populations derived from inter-gene pool crosses: DOR364×G19833 (DG) and BAT93×JALO EEP558 (BJ). The consensus map consisted of a total of 1,010 markers mapped, with a total map length of 2,041 cM across 11 linkage groups. On average, each linkage group on the consensus map contained 91 markers of which 83% were single copy markers. Finally, a synteny analysis was carried out using our highly saturated consensus maps compared with the soybean pseudo-chromosome assembly. A total of 772 marker sequences were compared with the soybean genome. A total of 44 syntenic blocks were identified. The linkage group Pv6 presented the most diverse pattern of synteny with seven syntenic blocks, and Pv9 showed the most consistent relations with soybean with just two syntenic blocks. Additionally, a co-linear analysis using common bean transcript map information against soybean coding sequences (CDS) revealed the relationship with 787 soybean genes. The common bean consensus map has allowed us to map a larger number of markers, to obtain a more complete coverage of the common bean genome. Our results, combined with synteny relationships provide tools to increase marker density in selected genomic regions to identify closely linked polymorphic markers for indirect selection, fine mapping or for positional cloning

Rôle de la perception des signaux symbiotiques fongiques chez des dicotylédones non nodulantes

L'endosymbiose racinaire entre les plantes et les champignons mycorhiziens à arbuscules (CMA) permet aux plantes d'avoir un meilleur accès aux nutriments du sol. Pour cette raison, cette endosymbiose joue un rôle majeur dans les écosystèmes et pour l'agriculture durable. Les étapes clés de la colonisation des racines par les CMA sont: 1) la pénétration des CMA dans le système racinaire à travers les cellules de l'épiderme et du cortex externe, et 2) la formation dans les cellules du cortex interne d'une structure ramifiée appelée arbuscule, qui permet des échanges entre les cellules végétales et les hyphes fongiques. L'établissement de cette symbiose implique une communication entre les deux partenaires. Les plantes produisent des hormones, les strigolactones qui induisent chez les CMA la production de signaux symbiotiques : des lipo-chitooligosaccharides (Myc-LCO) et des chitooligosaccharides courts (Myc-COs). Les Myc-LCO et les Myc-CO induisent des réponses moléculaires et physiologiques chez les plantes qui sont capables de former des mycorhizes à arbuscules. Cependant, leur rôle exact dans l'établissement des mycorhizes à arbuscules n'est pas connu. La difficulté à cultiver et transformer le partenaire fongique de cette symbiose rend la recherche compliquée du côté fongique. Du côté des plantes, on sait que des membres de la famille des récepteurs kinases à domaines lysin (LysM-RLK) perçoivent des LCO et des CO produits par divers microorganismes et sont donc de bons candidats pour percevoir des Myc-LCO et des Myc-CO. La plupart des recherches sur les mycorhizes à arbuscules sont réalisées chez des légumineuses, espèces chez lesquelles plusieurs duplications de gènes codant les LysM-RLK ont eu lieu. J'ai donc utilisé lors de mon doctorat des Solanaceae (Solanum lycopersicum, Petunia hybrida et Nicotiana benthamiana) pour étudier le rôle de deux récepteurs putatifs de Myc- LCO, codés par les gènes LYK10 et LYK4. Ces deux gènes, physiquement proches l'un de l'autre dans les génomes de la plupart des dicotylédones, proviennent probablement d'une ancienne duplication en tandem. En utilisant une approche biochimique, nous avons montré que SlLYK10 de S. lycopersicum est capable de lier des LCO avec une haute affinité. De plus, j'ai montré que le promoteur de SlLYK10 est exprimé dans l'épiderme et le cortex externe avant la colonisation par les CMA, puis dans des cellules contenant des arbuscules au cours de la colonisation par les CMA. Enfin, des approches de génétique inverse chez la tomate et le pétunia ont permis de démontrer que LYK10 contrôle la pénétration des CMA dans les racines et la formation des arbuscules. Ces résultats suggèrent que LYK10 perçoit les LCO et active chez les plantes la machinerie nécessaire à la pénétration de CMA dans les cellules végétales et à la formation des arbuscules.The root endosymbiosis between plants and arbuscular mycorrhizal fungi (AMF) allows the plants to have a better access to soil nutrients. For this reason this endosymbiosis plays a major role in ecosystems and in sustainable agriculture. The key steps for AMF colonization are: 1) the AMF penetration in the root system through crossing epidermal/outer cortical cells, and 2) the formation of a branched inner cortex structure called arbuscules that permits exchanges between plant cells and fungal hyphae. The establishment of this symbiosis involves communication between the two partners of the symbiosis. Plants produce strigolactones, hormones that induce in AMF the production of symbiotic signals : lipo-chitooligosaccharides (Myc-LCOs) and short chitooligosaccharides (Myc-COs). Both Myc-LCOs and Myc-COs induce plant molecular and physiological responses known to be associated with the formation of arbuscular mycorrhiza (AM). However, theit exact role in AM establishment is unknown. The difficulty to grow and transform the fungal partner of this symbiosis makes the research complicated on the fungal side. On the plant side, members of the lysin motif receptor-like kinase (LysM-RLK) family are known to perceive LCOs and COs produced by various microorganisms and are thus good candidates to perceive Myc-LCOs and Myc-COs. Most of the laboratory researches on AM conducted worldwide are performed on legumes where the LysM-RLK family has encountered several gene duplications. During my PhD I used Solanaceae species (Solanum lycopersicum, Petunia hybrida and Nicotiana benthamiana) to study the role of two candidate Myc-LCO receptors encoded by the genes LYK10 and LYK4. These two genes are physically close to each other in genomes of most of the dicotyledons and likely originate from of an ancient tandem duplication. By using a biochemical approach, we showed that S. lycopersicum SlLYK10 is able to bind LCOs with high affinity. Moreover, I showed that SlLYK10 promoter is expressed in epidermis/outer cortex before AMF colonization and also in arbuscule-containing cells during colonization. Finally, reverse genetic approaches in tomato and petunia allowed demonstrating that LYK10 controls AMF penetration into the roots and arbuscule formation. Taken together, these results suggest that LYK10 perceive LCOs and induce/activate the plant machinery required for AMF penetration into plant cells. Altogether this strongly suggests that LCOs play a role in AMF perception by plant during AM establishment. By using the same approaches, we found that N. benthamiana NbLYK4, as its orthologs in legumes and other dicotyledons, also binds LCOs with high affinity and is involved in AM establishment and plant defence. NbLYK4-silenced plants showed reduced responses to defence elicitors and increased colonization by pathogens and AMF. This led to the hypothesis that LYK4 perceives LCOs and locally inhibits plant defence during AMF colonization. This strongly suggests that Myc-LCOs are able to regulate plant defence. In conclusion, at least two proteins are involved non-redundantly in LCO perception in Solanaceae, LYK10 and LYK4 and regulates complementary plant machineries required for AMF colonization

Role of fungal symbiotic signal perception in non-nodulating dicotyledons

L'endosymbiose racinaire entre les plantes et les champignons mycorhiziens à arbuscules (CMA) permet aux plantes d'avoir un meilleur accès aux nutriments du sol. Pour cette raison, cette endosymbiose joue un rôle majeur dans les écosystèmes et pour l'agriculture durable. Les étapes clés de la colonisation des racines par les CMA sont: 1) la pénétration des CMA dans le système racinaire à travers les cellules de l'épiderme et du cortex externe, et 2) la formation dans les cellules du cortex interne d'une structure ramifiée appelée arbuscule, qui permet des échanges entre les cellules végétales et les hyphes fongiques. L'établissement de cette symbiose implique une communication entre les deux partenaires. Les plantes produisent des hormones, les strigolactones qui induisent chez les CMA la production de signaux symbiotiques : des lipo-chitooligosaccharides (Myc-LCO) et des chitooligosaccharides courts (Myc-COs). Les Myc-LCO et les Myc-CO induisent des réponses moléculaires et physiologiques chez les plantes qui sont capables de former des mycorhizes à arbuscules. Cependant, leur rôle exact dans l'établissement des mycorhizes à arbuscules n'est pas connu. La difficulté à cultiver et transformer le partenaire fongique de cette symbiose rend la recherche compliquée du côté fongique. Du côté des plantes, on sait que des membres de la famille des récepteurs kinases à domaines lysin (LysM-RLK) perçoivent des LCO et des CO produits par divers microorganismes et sont donc de bons candidats pour percevoir des Myc-LCO et des Myc-CO. La plupart des recherches sur les mycorhizes à arbuscules sont réalisées chez des légumineuses, espèces chez lesquelles plusieurs duplications de gènes codant les LysM-RLK ont eu lieu. J'ai donc utilisé lors de mon doctorat des Solanaceae (Solanum lycopersicum, Petunia hybrida et Nicotiana benthamiana) pour étudier le rôle de deux récepteurs putatifs de Myc- LCO, codés par les gènes LYK10 et LYK4. Ces deux gènes, physiquement proches l'un de l'autre dans les génomes de la plupart des dicotylédones, proviennent probablement d'une ancienne duplication en tandem. En utilisant une approche biochimique, nous avons montré que SlLYK10 de S. lycopersicum est capable de lier des LCO avec une haute affinité. De plus, j'ai montré que le promoteur de SlLYK10 est exprimé dans l'épiderme et le cortex externe avant la colonisation par les CMA, puis dans des cellules contenant des arbuscules au cours de la colonisation par les CMA. Enfin, des approches de génétique inverse chez la tomate et le pétunia ont permis de démontrer que LYK10 contrôle la pénétration des CMA dans les racines et la formation des arbuscules. Ces résultats suggèrent que LYK10 perçoit les LCO et active chez les plantes la machinerie nécessaire à la pénétration de CMA dans les cellules végétales et à la formation des arbuscules. Ces résultats suggèrent aussi que les Myc-LCO jouent un rôle dans la perception des CMA par les plantes au cours de l'établissement des mycorhizes à arbuscules. En utilisant les mêmes approches, nous avons montré que NbLYK4 de N. benthamiana, comme ses orthologues chez les légumineuses et d'autres dicotylédones, est aussi capable de lier des LCO avec une haute affinité. De plus, le gène codant ce LysM-RLK participe à l'établissement des mycorhizes à arbuscules et aux mécanismes de défense des plantes contre des pathogènes. Des plantes chez lesquelles le niveau d'expression de NbLYK4 est réduit, montrent des réponses réduites à des éliciteurs de défense et une colonisation accrue par des pathogènes et des CMA. Cela a conduit à l'hypothèse que LYK4 perçoit les LCO et inhibe localement les défenses des plantes pour permettre la colonisation par des CMA. Cela suggère aussi que les Myc-LCO sont capables de réguler les défenses des plantes. En conclusion, au moins deux protéines sont impliquées de manière non redondante dans la perception des Myc-LCO chez les Solanaceae: LYK10 et LYK4, et régulent chez les plantes des mécanismes complémentaires requis pour la colonisation par des CMAThe root endosymbiosis between plants and arbuscular mycorrhizal fungi (AMF) allows the plants to have a better access to soil nutrients. For this reason this endosymbiosis plays a major role in ecosystems and in sustainable agriculture. The key steps for AMF colonization are: 1) the AMF penetration in the root system through crossing epidermal/outer cortical cells, and 2) the formation of a branched inner cortex structure called arbuscules that permits exchanges between plant cells and fungal hyphae. The establishment of this symbiosis involves communication between the two partners of the symbiosis. Plants produce strigolactones, hormones that induce in AMF the production of symbiotic signals : lipo-chitooligosaccharides (Myc-LCOs) and short chitooligosaccharides (Myc-COs). Both Myc-LCOs and Myc-COs induce plant molecular and physiological responses known to be associated with the formation of arbuscular mycorrhiza (AM). However, theit exact role in AM establishment is unknown. The difficulty to grow and transform the fungal partner of this symbiosis makes the research complicated on the fungal side. On the plant side, members of the lysin motif receptor-like kinase (LysM-RLK) family are known to perceive LCOs and COs produced by various microorganisms and are thus good candidates to perceive Myc-LCOs and Myc-COs. Most of the laboratory researches on AM conducted worldwide are performed on legumes where the LysM-RLK family has encountered several gene duplications. During my PhD I used Solanaceae species (Solanum lycopersicum, Petunia hybrida and Nicotiana benthamiana) to study the role of two candidate Myc-LCO receptors encoded by the genes LYK10 and LYK4. These two genes are physically close to each other in genomes of most of the dicotyledons and likely originate from of an ancient tandem duplication. By using a biochemical approach, we showed that S. lycopersicum SlLYK10 is able to bind LCOs with high affinity. Moreover, I showed that SlLYK10 promoter is expressed in epidermis/outer cortex before AMF colonization and also in arbuscule-containing cells during colonization. Finally, reverse genetic approaches in tomato and petunia allowed demonstrating that LYK10 controls AMF penetration into the roots and arbuscule formation. Taken together, these results suggest that LYK10 perceive LCOs and induce/activate the plant machinery required for AMF penetration into plant cells. Altogether this strongly suggests that LCOs play a role in AMF perception by plant during AM establishment. By using the same approaches, we found that N. benthamiana NbLYK4, as its orthologs in legumes and other dicotyledons, also binds LCOs with high affinity and is involved in AM establishment and plant defence. NbLYK4-silenced plants showed reduced responses to defence elicitors and increased colonization by pathogens and AMF. This led to the hypothesis that LYK4 perceives LCOs and locally inhibits plant defence during AMF colonization. This strongly suggests that Myc-LCOs are able to regulate plant defence. In conclusion, at least two proteins are involved non-redundantly in LCO perception in Solanaceae, LYK10 and LYK4 and regulates complementary plant machineries required for AMF colonization

Visible and Infrared Image Fusion Using the Lifting Wavelet

In recent years image fusion plays a vital role in the image processing area. Fused images would help in doing many applications in image processing like segmentation, image enhancement and many.In order to improve the effect of fusion visible and infrared image images of the same scene, this paper presents an image fusion method based on lifting wavelet domain. Firstly, the source images are decomposed using lifting wavelet domain transform (LWT). Secondly, a weighted average approach based on normalized Shannon entropy is used to fuse low frequency lifting wavelet coefficients of the visible and infrared images. The fusion rule of local energy maximum is used to combine corresponding high frequency coefficients. After fusing low and high frequency coefficients of the source images, the final fused image is obtained using the inverse LWT. The experiments show that the proposed method provides improved subjective and objectives results as compared to previous image fusion methods such as Laplacian transform and traditional Wavelet transform. DOI: http://dx.doi.org/10.11591/telkomnika.v11i11.289