Publikasjoner
NIBIOs ansatte publiserer flere hundre vitenskapelige artikler og forskningsrapporter hvert år. Her finner du referanser og lenker til publikasjoner og andre forsknings- og formidlingsaktiviteter. Samlingen oppdateres løpende med både nytt og historisk materiale. For mer informasjon om NIBIOs publikasjoner, besøk NIBIOs bibliotek.
2024
Sammendrag
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Forfattere
Markus A. K. Sydenham Yoko Dupont Anders Nielsen Jens Olesen Henning Bang Madsen Astrid Brekke Skrindo Claus Rasmussen Megan Sara Nowell Zander Venter Stein Joar Hegland Anders Gunnar Helle Daniel Ingvar Jeuderan Skoog Marianne Strand Torvanger Kaj-Andreas Hanevik Sven Emil Hinderaker Thorstein Paulsen Katrine Eldegard Trond Reitan Graciela Monica RuschSammendrag
Climate change, landscape homogenization and the decline of beneficial insects threaten pollination services to wild plants and crops. Understanding how pollination potential (i.e. the capacity of ecosystems to support pollination of plants) is affected by climate change and landscape homogenization is fundamental for our ability to predict how such anthropogenic stressors affect plant biodiversity. Models of pollinator potential are improved when based on pairwise plant-pollinator interactions and pollinator´s plant preferences. However, whether the sum of predicted pairwise interactions with a plant within a habitat (a proxy for pollination potential) relates to pollen deposition on flowering plants has not yet been investigated. We sampled plant-bee interactions in 68 Scandinavian plant communities in landscapes of varying land-cover heterogeneity along a latitudinal temperature gradient of 4–8 C°, and estimated pollen deposition as the number of pollen grains on flowers of the bee-pollinated plants Lotus corniculatus, and Vicia cracca. We show that plant-bee interactions, and the pollination potential for these bee-pollinated plants increase with landscape diversity, annual mean temperature, plant abundance, and decrease with distances to sand-dominated soils. Furthermore, the pollen deposition in flowers increased with the predicted pollination potential, which was driven by landscape diversity and plant abundance. Our study illustrates that the pollination potential, and thus pollen deposition, for wild plants can be mapped based on spatial models of plant-bee interactions that incorporate pollinator-specific plant preferences. Maps of pollination potential can be used to guide conservation and restoration planning.
Sammendrag
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Forfattere
Luiz Claudio Garcia Guilherme H. Carraro Sandro Felema Allison J. Fornari Leandro J. V. Sformi Thiago InagakiSammendrag
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Forfattere
Mélanie Spedener Jenny Larsen Valaker Juliette Helbert Franziska Veronika Schubert Karen Marie Mathisen Marie Vestergaard Henriksen Anders Nielsen Gunnar Austrheim Barbara ZimmermannSammendrag
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Sammendrag
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Forfattere
Xiaoyu Yuan Keya Xu Fang Yan Zhiyuan Liu Carl Jonas Jorge Spetz Huanbin Zhou Xiaojie Wang Huaibing Jin Xifeng Wang Yan LiuSammendrag
Wheat dwarf virus (WDV, genus Mastrevirus, family Geminiviridae) is one of the causal agents of wheat viral disease, which severely impacts wheat production in most wheat-growing regions in the world. Currently, there is little information about natural resistance against WDV in common wheat germplasms. CRISPR/Cas9 technology is being utilized to manufacture transgenic plants resistant to different diseases. In the present study, we used the CRISPR/Cas9 system targeting overlapping regions of coat protein (CP) and movement protein (MP) (referred to as CP/MP) or large intergenic region (LIR) in the wheat variety ‘Fielder’ to develop resistance against WDV. WDV-inoculated T1 progenies expressing Cas9 and sgRNA for CP/MP and LIR showed complete resistance against WDV and no accumulation of viral DNA compared with control plants. Mutation analysis revealed that the CP/MP and LIR targeting sites have small indels in the corresponding Cas9-positive plants. Additionally, virus inhibition and indel mutations occurred in T2 homozygous lines. Together, our work gives efficient results of the engineering of CRISPR/Cas9-mediated WDV resistance in common wheat plants, and the specific sgRNAs identified in this study can be extended to utilize the CRISPR/Cas9 system to confer resistance to WDV in other cereal crops such as barley, oats, and rye.
Forfattere
Monica Sanden Johanna Eva Bodin Nur Duale Kristian Prydz Volha Shapaval Tage Thorstensen Anne-Marthe Ganes Jevnaker Ville Erling SipinenSammendrag
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Forfattere
Ville Erling Sipinen Monica Sanden Johanna Eva Bodin Nur Duale Anne-Marthe Ganes Jevnaker Kristian Prydz Volha Shapaval Tage ThorstensenSammendrag
The Norwegian Committee for Food and Environment (VKM) has performed a preliminary assessment of an application for authorization for the genetically modified maize event DP202216 in the EAA. The scope of the application includes all uses of maize DP202216 and sub-combinations independently of their origin equivalent to the uses of any other maize grain and forage. The assessment was performed in connection with EFSAs (European Food Safety Authorities) public hearing of application EFSA-GMO-NL-2019-159, on request from the Norwegian Food Safety Authority and the Norwegian Environment Agency. The assessment of maize DP202216 is based on information provided by the applicant in the application EFSA-GMO-NL-2019-159, and relevant peer-reviewed scientific literature. Maize DP202216 has the potential to enhanced grain yield, and provides tolerance to glufosinate-ammonium herbicides. Authorisation process for genetically modified organisms Through the EEA Agreement, the EU Directive 2001/18/EC on deliberate release into the environment of genetically modified organisms is implemented in Norwegian law. Norway is therefore affiliated with the GMO authorisation process in the EU. In the EU, both GMOs and derived products are regulated by the Directive and Regulation 1829/2003/EC. The Regulation concerns genetically modified food and feed and is currently not a part of the EEA Agreement. In preparation for a legal implementation of the Regulation in Norwegian law, Norway follows the EU proceedings for GMO applications. When a company seeks approval of a genetically modified organism, the application is submitted to the national competent authority of an EU Member State, which forwards the application to EFSA. EFSA then submits the application for a public hearing across all EEA countries. VKM conducts its own review of the application and sends its comments to EFSA. EFSA then completes their scientific opinion based on information from the applicant, comments from EEA member countries and independent literature. The scientific opinion is then issued to the European Commission. VKM submitted their comments on application EFSA-GMO-NL-2019-159 to EFSA before the deadline January 3, 2020.
Forfattere
Palingamoorthy Gnanamoorthy Junbin Zhao Abhishek Chakraborty Pramit Kumar Deb Burman Yaoliang Chen Linjie Jiao Jing Zhang Yaqi Liu Sigamani Sivaraj Yiping Zhang Qinghai SongSammendrag
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