FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3025819186> ?p ?o ?g. }

• W3025819186 endingPage "718" @default.
• W3025819186 startingPage "709" @default.
• W3025819186 abstract "Viruses influence host fitness through direct or indirect interactions. The latter occur mostly through bacteriophages that regulate host-associated bacterial communities. Bacteriophages play an important role in the ecology and evolution of the host-associated microbiome and are directly linked to host fitness. The composition and diversity of viruses associated with the soil rhizosphere are largely unexplored. The rhizosphere virome might alleviate plant responses to abiotic stress, thereby influencing plant resistance and resilience to climate change scenarios. Microbiomes and their hosts influence each other; for instance, the microbiome improves host fitness, whereas the host supports microbiome nutrition. Most studies on this topic have focused on the role of bacteria and fungi, although research on viruses that infect bacteria, known as ‘bacteriophages’ (phages), has gained importance due to the potential role bacteriophages play in the resilience and functionality of the gut microbiome. Like the gut microbiome, the rhizosphere harbors a complex microbiome, but little is known about the role of phages in this ecosystem. In this opinion, we extend the knowledge gained in human gut virus metagenomics (viromics) to disentangle the potential role of phages in driving the resilience and functionality of the rhizosphere microbiome. We propose that future comparative studies across environments are necessary to unravel the underlying mechanisms through which phages drive the composition and functionality of the rhizosphere microbiome and its interaction with the plant host. Importantly, such understanding might generate strategies to improve plant resistance and resilience in the context of climate change. Microbiomes and their hosts influence each other; for instance, the microbiome improves host fitness, whereas the host supports microbiome nutrition. Most studies on this topic have focused on the role of bacteria and fungi, although research on viruses that infect bacteria, known as ‘bacteriophages’ (phages), has gained importance due to the potential role bacteriophages play in the resilience and functionality of the gut microbiome. Like the gut microbiome, the rhizosphere harbors a complex microbiome, but little is known about the role of phages in this ecosystem. In this opinion, we extend the knowledge gained in human gut virus metagenomics (viromics) to disentangle the potential role of phages in driving the resilience and functionality of the rhizosphere microbiome. We propose that future comparative studies across environments are necessary to unravel the underlying mechanisms through which phages drive the composition and functionality of the rhizosphere microbiome and its interaction with the plant host. Importantly, such understanding might generate strategies to improve plant resistance and resilience in the context of climate change. phage genes that affect host metabolism. They are not essential for phage replication and reproduction. bacteriophages are viral particles that infect bacterial cells, which are used as machinery to replicate viral particles. convergent set of microbial species that have been named as a concept useful to define the prevailing microbial genotypes in a given microbiome and unusually adapted to define which species must be found in an equilibrated or optimal microbiome. condition in which high diversity is observed in low-input nutrient environment. changes posed by temperate phage integration into the host’s phenotype. a virus of bacteria that can integrate into a bacterial genome and, upon receiving a cue, can excise and propagate. release of photosynthetically assimilated carbon by the roots. layer of soil tightly attached to the roots, where the diversity and abundance of molecules released through rhizodeposits are involved in the structure and activity of microbial communities by selectively recruiting populations of the soil microbiome. plant effort in building a beneficial environment whereby plant-beneficial microorganisms contribute to both nutrient availability and phytosanitary status. viral shunting is a process in which viral lysis releases readily available nutrients (i.e., dissolved organic matter and inorganic nutrients) to other neighboring microorganisms. viral microbiomes. viral metagenomics. structures resembling viruses; not necessarily infectious, as they might contain no viral genetic material." @default.
• W3025819186 created "2020-05-21" @default.
• W3025819186 creator A5031022926 @default.
• W3025819186 creator A5066413815 @default.
• W3025819186 creator A5076173056 @default.
• W3025819186 creator A5082037384 @default.
• W3025819186 date "2020-09-01" @default.
• W3025819186 modified "2023-10-18" @default.
• W3025819186 title "The Role of Rhizosphere Bacteriophages in Plant Health" @default.
• W3025819186 cites W1694538241 @default.
• W3025819186 cites W1933593286 @default.
• W3025819186 cites W1966912927 @default.
• W3025819186 cites W1985411040 @default.
• W3025819186 cites W2006742779 @default.
• W3025819186 cites W2015486366 @default.
• W3025819186 cites W2050209831 @default.
• W3025819186 cites W2070190014 @default.
• W3025819186 cites W2081319466 @default.
• W3025819186 cites W2082376470 @default.
• W3025819186 cites W2082860967 @default.
• W3025819186 cites W2096430209 @default.
• W3025819186 cites W2102471114 @default.
• W3025819186 cites W2102635703 @default.
• W3025819186 cites W2120688439 @default.
• W3025819186 cites W2131781913 @default.
• W3025819186 cites W2151720897 @default.
• W3025819186 cites W2154760096 @default.
• W3025819186 cites W2159434736 @default.
• W3025819186 cites W2161251845 @default.
• W3025819186 cites W2166855726 @default.
• W3025819186 cites W2176161172 @default.
• W3025819186 cites W2270456711 @default.
• W3025819186 cites W2301892496 @default.
• W3025819186 cites W2321452352 @default.
• W3025819186 cites W2340022657 @default.
• W3025819186 cites W2342540743 @default.
• W3025819186 cites W2511649068 @default.
• W3025819186 cites W2562468253 @default.
• W3025819186 cites W2571652165 @default.
• W3025819186 cites W2576948248 @default.
• W3025819186 cites W2595182717 @default.
• W3025819186 cites W2610162525 @default.
• W3025819186 cites W2610214149 @default.
• W3025819186 cites W2613232244 @default.
• W3025819186 cites W2623963207 @default.
• W3025819186 cites W2735006823 @default.
• W3025819186 cites W2740255517 @default.
• W3025819186 cites W2748607273 @default.
• W3025819186 cites W2762750327 @default.
• W3025819186 cites W2763831277 @default.
• W3025819186 cites W2766659033 @default.
• W3025819186 cites W2767759966 @default.
• W3025819186 cites W2769152635 @default.
• W3025819186 cites W2781754262 @default.
• W3025819186 cites W2791612935 @default.
• W3025819186 cites W2796913172 @default.
• W3025819186 cites W2801691667 @default.
• W3025819186 cites W2806336739 @default.
• W3025819186 cites W2806680899 @default.
• W3025819186 cites W2809780492 @default.
• W3025819186 cites W2883002901 @default.
• W3025819186 cites W2895325477 @default.
• W3025819186 cites W2897072301 @default.
• W3025819186 cites W2901490786 @default.
• W3025819186 cites W2909257509 @default.
• W3025819186 cites W2912015780 @default.
• W3025819186 cites W2912656789 @default.
• W3025819186 cites W2913714888 @default.
• W3025819186 cites W2938799305 @default.
• W3025819186 cites W2943223175 @default.
• W3025819186 cites W2944799304 @default.
• W3025819186 cites W2950060642 @default.
• W3025819186 cites W2971060767 @default.
• W3025819186 cites W2979358136 @default.
• W3025819186 cites W2979501991 @default.
• W3025819186 cites W2989052596 @default.
• W3025819186 cites W2989706094 @default.
• W3025819186 cites W2989983670 @default.
• W3025819186 cites W2990533513 @default.
• W3025819186 cites W2990936965 @default.
• W3025819186 doi "https://doi.org/10.1016/j.tim.2020.04.005" @default.
• W3025819186 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/32417229" @default.
• W3025819186 hasPublicationYear "2020" @default.
• W3025819186 type Work @default.
• W3025819186 sameAs 3025819186 @default.
• W3025819186 citedByCount "36" @default.
• W3025819186 countsByYear W30258191862020 @default.
• W3025819186 countsByYear W30258191862021 @default.
• W3025819186 countsByYear W30258191862022 @default.
• W3025819186 countsByYear W30258191862023 @default.
• W3025819186 crossrefType "journal-article" @default.
• W3025819186 hasAuthorship W3025819186A5031022926 @default.
• W3025819186 hasAuthorship W3025819186A5066413815 @default.
• W3025819186 hasAuthorship W3025819186A5076173056 @default.
• W3025819186 hasAuthorship W3025819186A5082037384 @default.
• W3025819186 hasBestOaLocation W30258191862 @default.
• W3025819186 hasConcept C104317684 @default.
• W3025819186 hasConcept C110872660 @default.

• next