Necrobiome framework for bridging decomposition ecology of autotrophically and heterotrophically derived organic matter
- Benbow, M., Barton, Philip, Ulyshen, Michael, Beasley, James, DeVault, Travis
- Authors: Benbow, M. , Barton, Philip , Ulyshen, Michael , Beasley, James , DeVault, Travis
- Date: 2019
- Type: Text , Journal article
- Relation: Ecological Monographs Vol. 89, no. 1 (2019), p.
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- Description: Decomposition contributes to global ecosystem function by contributing to nutrient recycling, energy flow, and limiting biomass accumulation. The decomposer organisms influencing this process form diverse, complex, and highly dynamic communities that often specialize on different plant or animal resources. Despite performing the same net role, there is a need to conceptually synthesize information on the structure and function of decomposer communities across the spectrum of dead plant and animal resources. A lack of synthesis has limited cross-disciplinary learning and research in important areas of ecosystem and community ecology. Here we expound on the “necrobiome” concept and develop a framework describing the decomposer communities and their interactions associated with plant and animal resource types within multiple ecosystems. We outline the biotic structure and ecological functions of the necrobiome, along with how the necrobiome fits into a broader landscape and ecosystem context. The expanded necrobiome model provides a set of perspectives on decomposer communities across resource types, and conceptually unifies plant and animal decomposer communities into the same framework, while acknowledging key differences in processes and mechanisms. This framework is intended to raise awareness among researchers, and advance the construction of explicit, mechanistic hypotheses that further our understanding of decomposer community contributions to biodiversity, the structure and function of ecosystems, global nutrient recycling and energy flow. © 2018 by the Ecological Society of America
- Authors: Benbow, M. , Barton, Philip , Ulyshen, Michael , Beasley, James , DeVault, Travis
- Date: 2019
- Type: Text , Journal article
- Relation: Ecological Monographs Vol. 89, no. 1 (2019), p.
- Full Text:
- Reviewed:
- Description: Decomposition contributes to global ecosystem function by contributing to nutrient recycling, energy flow, and limiting biomass accumulation. The decomposer organisms influencing this process form diverse, complex, and highly dynamic communities that often specialize on different plant or animal resources. Despite performing the same net role, there is a need to conceptually synthesize information on the structure and function of decomposer communities across the spectrum of dead plant and animal resources. A lack of synthesis has limited cross-disciplinary learning and research in important areas of ecosystem and community ecology. Here we expound on the “necrobiome” concept and develop a framework describing the decomposer communities and their interactions associated with plant and animal resource types within multiple ecosystems. We outline the biotic structure and ecological functions of the necrobiome, along with how the necrobiome fits into a broader landscape and ecosystem context. The expanded necrobiome model provides a set of perspectives on decomposer communities across resource types, and conceptually unifies plant and animal decomposer communities into the same framework, while acknowledging key differences in processes and mechanisms. This framework is intended to raise awareness among researchers, and advance the construction of explicit, mechanistic hypotheses that further our understanding of decomposer community contributions to biodiversity, the structure and function of ecosystems, global nutrient recycling and energy flow. © 2018 by the Ecological Society of America
- McCourt, Richard, Karol, Kenneth, Hall, John, Casanova, Michelle, Grant, Michael
- Authors: McCourt, Richard , Karol, Kenneth , Hall, John , Casanova, Michelle , Grant, Michael
- Date: 2017
- Type: Text , Book chapter
- Relation: Handbook of the Protists p. 165-183
- Full Text: false
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- Description: The charophytes, or stoneworts, are a group of green algae with six extant genera in one family, distributed worldwide in freshwater ponds and lakes. They are among the green algal groups most closely related to land plants and exhibit a complex thallus, with multinucleate internodal cells joined at nodes comprising smaller, uninucleate cells giving rise to whorled branchlets. Two genera (Chara, Nitella) contain most of the described species, with a third (Tolypella) containing several dozen taxa. The remaining genera have one or a few species. Reproduction is oogamous, with sperm and eggs produced in separate multicellular structures. The thallus is haploid; the zygote is the only diploid cell in the life cycle, and meiosis is followed by the development of a resistant spore. Thalli and spores are often encrusted with calcium carbonate. Such spores are abundant in the fossil record of the Charales, which extends to the Upper Silurian, and many genera and families have become extinct. These algae provide important ecosystem services, for example, as colonizing species, as biological agents for producing water clarity, or as the base of the food web. Charophytes are important for the study of evolution of embryophyte development, growth meristems, and cell biophysics. As one of the green algal groups most closely related to land plants, the rich charophyte fossil record may reveal clues regarding the earliest algae that invaded the land.
Nitrogen fixation and nifH diversity in human gut microbiota
- Igai, Katsura, Itakura, Manabu, Nishijima, Suguru, Tsurumaru, Hirohito, Suda, Wataru, Tsutaya, Takumi, Tomitsuka, Eriko, Tadokoro, Kiyoshi, Baba, Jun, Odani, Shingo, Natsuhara, Kazumi, Morita, Ayako, Yoneda, Minoru, Greenhill, Andrew, Horwood, Paul, Inoue, Jun-ichi, Ohkuma, Moriya, Hongoh, Yuichi, Yamamoto, Taro, Siba, Peter, Hattori, Masahira, Minamisawa, Kiwamu, Umezaki, Masahiro
- Authors: Igai, Katsura , Itakura, Manabu , Nishijima, Suguru , Tsurumaru, Hirohito , Suda, Wataru , Tsutaya, Takumi , Tomitsuka, Eriko , Tadokoro, Kiyoshi , Baba, Jun , Odani, Shingo , Natsuhara, Kazumi , Morita, Ayako , Yoneda, Minoru , Greenhill, Andrew , Horwood, Paul , Inoue, Jun-ichi , Ohkuma, Moriya , Hongoh, Yuichi , Yamamoto, Taro , Siba, Peter , Hattori, Masahira , Minamisawa, Kiwamu , Umezaki, Masahiro
- Date: 2016
- Type: Text , Journal article
- Relation: Scientific Reports Vol. 6, no. (2016), p. 1-11
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- Description: It has been hypothesized that nitrogen fixation occurs in the human gut. However, whether the gut microbiota truly has this potential remains unclear. We investigated the nitrogen-fixing activity and diversity of the nitrogenase reductase (NifH) genes in the faecal microbiota of humans, focusing on Papua New Guinean and Japanese individuals with low to high habitual nitrogen intake. A 15 N 2 incorporation assay showed significant enrichment of 15 N in all faecal samples, irrespective of the host nitrogen intake, which was also supported by an acetylene reduction assay. The fixed nitrogen corresponded to 0.01% of the standard nitrogen requirement for humans, although our data implied that the contribution in the gut in vivo might be higher than this value. The nifH genes recovered in cloning and metagenomic analyses were classified in two clusters: one comprising sequences almost identical to Klebsiella sequences and the other related to sequences of Clostridiales members. These results are consistent with an analysis of databases of faecal metagenomes from other human populations. Collectively, the human gut microbiota has a potential for nitrogen fixation, which may be attributable to Klebsiella and Clostridiales strains, although no evidence was found that the nitrogen-fixing activity substantially contributes to the host nitrogen balance. © The Author(s) 2016.
- Authors: Igai, Katsura , Itakura, Manabu , Nishijima, Suguru , Tsurumaru, Hirohito , Suda, Wataru , Tsutaya, Takumi , Tomitsuka, Eriko , Tadokoro, Kiyoshi , Baba, Jun , Odani, Shingo , Natsuhara, Kazumi , Morita, Ayako , Yoneda, Minoru , Greenhill, Andrew , Horwood, Paul , Inoue, Jun-ichi , Ohkuma, Moriya , Hongoh, Yuichi , Yamamoto, Taro , Siba, Peter , Hattori, Masahira , Minamisawa, Kiwamu , Umezaki, Masahiro
- Date: 2016
- Type: Text , Journal article
- Relation: Scientific Reports Vol. 6, no. (2016), p. 1-11
- Full Text:
- Reviewed:
- Description: It has been hypothesized that nitrogen fixation occurs in the human gut. However, whether the gut microbiota truly has this potential remains unclear. We investigated the nitrogen-fixing activity and diversity of the nitrogenase reductase (NifH) genes in the faecal microbiota of humans, focusing on Papua New Guinean and Japanese individuals with low to high habitual nitrogen intake. A 15 N 2 incorporation assay showed significant enrichment of 15 N in all faecal samples, irrespective of the host nitrogen intake, which was also supported by an acetylene reduction assay. The fixed nitrogen corresponded to 0.01% of the standard nitrogen requirement for humans, although our data implied that the contribution in the gut in vivo might be higher than this value. The nifH genes recovered in cloning and metagenomic analyses were classified in two clusters: one comprising sequences almost identical to Klebsiella sequences and the other related to sequences of Clostridiales members. These results are consistent with an analysis of databases of faecal metagenomes from other human populations. Collectively, the human gut microbiota has a potential for nitrogen fixation, which may be attributable to Klebsiella and Clostridiales strains, although no evidence was found that the nitrogen-fixing activity substantially contributes to the host nitrogen balance. © The Author(s) 2016.
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