Institution
Syngenta
Company•Basel, Switzerland•
About: Syngenta is a company organization based out in Basel, Switzerland. It is known for research contribution in the topics: Population & Gene. The organization has 4724 authors who have published 6036 publications receiving 164311 citations. The organization is also known as: Syngenta & Syngenta AG.
Topics: Population, Gene, Cultivar, Germplasm, Alkyl
Papers published on a yearly basis
Papers
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TL;DR: This review focuses on recent findings regarding three levels of adenylyl cyclase organization--oligomerization, positioning to lipid rafts and participation in multiprotein signalling complexes.
142 citations
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TL;DR: The local lymph node assay, when conducted according to published guidelines, provides a robust method for skin sensitization testing that not only provides reliable hazard identification information but also data necessary for effective risk assessment and risk management.
140 citations
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14 Nov 2001TL;DR: An HPPD-inhibitor resistant HPPD enzyme comprising an amino acid sequence GIKECQ and a sequence F,(D/E), F, (M/L), W1, (P/A), P, W2, X, X X, Y, Y as mentioned in this paper, where X is any amino acid.
Abstract: An HPPD-inhibitor resistant HPPD enzyme comprising an amino acid sequence GIKECQ and a sequence F, (D/E), F, (M/L), W1, (P/A), P, W2, X, X, Y, Y wherein W1 is either A or P and where (i) if W1 is A then W2 is P, A, Q or L or, (ii) if W1 is P then W2 is P, A, Q or T, and wherein X is any amino acid. The invention also include methods of identifying HPPD inhibitor resistant HPPD enzymes and also of the enzymes thus identified.
140 citations
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TL;DR: These findings imply that AtGSNOR1 controls multiple genetic networks integral to plant growth and development, and may negatively regulate the autonomous and photoperiod flowering time pathways.
Abstract: Nitric oxide (NO) has been proposed to regulate a diverse array of activities during plant growth, development and immune function. S-nitrosylation, the addition of an NO moiety to a reactive cysteine thiol, to form an S-nitrosothiol (SNO), is emerging as a prototypic redox-based post-translational modification. An ARABIDOPSIS THALIANAS-NITROSOGLUTATHIONE (GSNO) REDUCTASE (AtGSNOR1) is thought to be the major regulator of total cellular SNO levels in this plant species. Here, we report on the impact of loss- and gain-of-function mutations in AtGSNOR1 upon plant growth and development. Loss of AtGSNOR1 function in atgsnor1-3 plants increased the number of initiated higher order axillary shoots that remain active, resulting in a loss of apical dominance relative to wild type. In addition atgsnor1-3 affected leaf shape, germination, 2,4-D sensitivity and reduced hypocotyl elongation in both light and dark grown seedlings. Silique size and seed production were also decreased in atgsnor1-3 plants and the latter was reduced in atgsnor1-1 plants, which overexpress AtGSNOR1. Overexpression of AtGSNOR1 slightly delayed flowering time in both long and short days, whereas atgsnor1-3 showed early flowering compared to wild type. In the atgsnor1-3 line, FLOWERING LOCUS C (FLC) expression was reduced, whereas transcription of CONSTANS (CO) was enhanced. Therefore, AtGSNOR1 may negatively regulate the autonomous and photoperiod flowering time pathways. Both overexpression and loss of AtGSNOR1 function also reduced primary root growth, while root hair development was increased in atgsnor1-1 and reduced in atgsnor1-3 plants. Collectively, our findings imply that AtGSNOR1 controls multiple genetic networks integral to plant growth and development.
140 citations
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TL;DR: Various structural and functional MSCs were not resistant to drying-rewetting stress and that resilience depended strongly on the parameter investigated, as well as specific groups in the microbial community were sensitive to the stress.
Abstract: Prior to registration of crop protection products (CPPs) their persistence in soil has to be determined under defined conditions. For this purpose, soils are collected in the field and stored for up to 3 months prior to the tests. During storage, stresses like drying may induce changes in microbiological soil characteristics (MSCs) and thus may influence CPP degradation rates. We investigated the influence of soil storage-related stress on the resistance and resilience of different MSCs by assessing the impact of a single severe drying-rewetting cycle and by monitoring recovery from this event for 34 days. The degradation and mineralization of the fungicide metalaxyl-M and the insecticide lufenuron were delayed by factors of 1.5 to 5.4 in the dried and rewetted soil compared to the degradation and mineralization in an undisturbed reference. The microbial biomass, as estimated by direct cell counting and from the soil DNA content, decreased on average by 51 and 24%, respectively. The bulk microbial activities, as determined by measuring substrate-induced respiration and fluorescein diacetate hydrolysis, increased after rewetting and recovered completely within 6 days after reequilibration. The effects on Bacteria, Archaea, and Pseudomonas were investigated by performing PCR amplification of 16S rRNA genes and reverse-transcribed 16S rRNA, followed by restriction fragment length polymorphism (RFLP) and terminal RFLP (T-RFLP) fingerprinting. Statistical analyses of RFLP and T-RFLP profiles indicated that specific groups in the microbial community were sensitive to the stress. In addition, evaluation of rRNA genes and rRNA as markers for monitoring the stress responses of microbial communities revealed overall similar sensitivities. We concluded that various structural and functional MSCs were not resistant to drying-rewetting stress and that resilience depended strongly on the parameter investigated.
140 citations
Authors
Showing all 4737 results
Name | H-index | Papers | Citations |
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John R. Yates | 177 | 1036 | 129029 |
Thomas Boller | 101 | 310 | 42294 |
Tamio Hayashi | 98 | 799 | 35281 |
Ian Kimber | 91 | 620 | 28629 |
Roberto Bassi | 89 | 320 | 21655 |
Michael P. Washburn | 81 | 296 | 32468 |
Robert Gurny | 81 | 396 | 28391 |
Ian Jones | 80 | 353 | 37673 |
Xinnian Dong | 66 | 108 | 27849 |
Willem F. Broekaert | 66 | 155 | 19690 |
Rebecca J. Dearman | 66 | 287 | 13197 |
Steven J. Rothstein | 66 | 164 | 13804 |
Tong Zhu | 64 | 124 | 17310 |
John Ryals | 63 | 115 | 23451 |
Nicholas A. Buckley | 62 | 419 | 14283 |