Quantifying environmental adaptation of metabolic pathways in metagenomics

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Quantifying environmental adaptation of metabolic pathways in metagenomics. / Gianoulis, Tara A; Raes, Jeroen; Patel, Prianka V; Bjornson, Robert; Korbel, Jan O; Letunic, Ivica; Yamada, Takuji; Paccanaro, Alberto; Snyder, Michael; Bork, Peer; Gerstein, Mark B; Jensen, Lars Juhl.

In: Proceedings of the National Academy of Science of the United States of America, Vol. 106, No. 5, 2009, p. 1374-9.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Gianoulis, TA, Raes, J, Patel, PV, Bjornson, R, Korbel, JO, Letunic, I, Yamada, T, Paccanaro, A, Snyder, M, Bork, P, Gerstein, MB & Jensen, LJ 2009, 'Quantifying environmental adaptation of metabolic pathways in metagenomics', Proceedings of the National Academy of Science of the United States of America, vol. 106, no. 5, pp. 1374-9. https://doi.org/10.1073/pnas.0808022106

APA

Gianoulis, T. A., Raes, J., Patel, P. V., Bjornson, R., Korbel, J. O., Letunic, I., Yamada, T., Paccanaro, A., Snyder, M., Bork, P., Gerstein, M. B., & Jensen, L. J. (2009). Quantifying environmental adaptation of metabolic pathways in metagenomics. Proceedings of the National Academy of Science of the United States of America, 106(5), 1374-9. https://doi.org/10.1073/pnas.0808022106

Vancouver

Gianoulis TA, Raes J, Patel PV, Bjornson R, Korbel JO, Letunic I et al. Quantifying environmental adaptation of metabolic pathways in metagenomics. Proceedings of the National Academy of Science of the United States of America. 2009;106(5):1374-9. https://doi.org/10.1073/pnas.0808022106

Author

Gianoulis, Tara A ; Raes, Jeroen ; Patel, Prianka V ; Bjornson, Robert ; Korbel, Jan O ; Letunic, Ivica ; Yamada, Takuji ; Paccanaro, Alberto ; Snyder, Michael ; Bork, Peer ; Gerstein, Mark B ; Jensen, Lars Juhl. / Quantifying environmental adaptation of metabolic pathways in metagenomics. In: Proceedings of the National Academy of Science of the United States of America. 2009 ; Vol. 106, No. 5. pp. 1374-9.

Bibtex

@article{5d7bd2b07ddb11df928f000ea68e967b,
title = "Quantifying environmental adaptation of metabolic pathways in metagenomics",
abstract = "Recently, approaches have been developed to sample the genetic content of heterogeneous environments (metagenomics). However, by what means these sequences link distinct environmental conditions with specific biological processes is not well understood. Thus, a major challenge is how the usage of particular pathways and subnetworks reflects the adaptation of microbial communities across environments and habitats-i.e., how network dynamics relates to environmental features. Previous research has treated environments as discrete, somewhat simplified classes (e.g., terrestrial vs. marine), and searched for obvious metabolic differences among them (i.e., treating the analysis as a typical classification problem). However, environmental differences result from combinations of many factors, which often vary only slightly. Therefore, we introduce an approach that employs correlation and regression to relate multiple, continuously varying factors defining an environment to the extent of particular microbial pathways present in a geographic site. Moreover, rather than looking only at individual correlations (one-to-one), we adapted canonical correlation analysis and related techniques to define an ensemble of weighted pathways that maximally covaries with a combination of environmental variables (many-to-many), which we term a metabolic footprint. Applied to available aquatic datasets, we identified footprints predictive of their environment that can potentially be used as biosensors. For example, we show a strong multivariate correlation between the energy-conversion strategies of a community and multiple environmental gradients (e.g., temperature). Moreover, we identified covariation in amino acid transport and cofactor synthesis, suggesting that limiting amounts of cofactor can (partially) explain increased import of amino acids in nutrient-limited conditions.",
author = "Gianoulis, {Tara A} and Jeroen Raes and Patel, {Prianka V} and Robert Bjornson and Korbel, {Jan O} and Ivica Letunic and Takuji Yamada and Alberto Paccanaro and Michael Snyder and Peer Bork and Gerstein, {Mark B} and Jensen, {Lars Juhl}",
note = "Keywords: Amino Acids; Biosensing Techniques; Genomics; Lipid Metabolism; Microbiology; Polysaccharides",
year = "2009",
doi = "10.1073/pnas.0808022106",
language = "English",
volume = "106",
pages = "1374--9",
journal = "Proceedings of the National Academy of Sciences of the United States of America",
issn = "0027-8424",
publisher = "The National Academy of Sciences of the United States of America",
number = "5",

}

RIS

TY - JOUR

T1 - Quantifying environmental adaptation of metabolic pathways in metagenomics

AU - Gianoulis, Tara A

AU - Raes, Jeroen

AU - Patel, Prianka V

AU - Bjornson, Robert

AU - Korbel, Jan O

AU - Letunic, Ivica

AU - Yamada, Takuji

AU - Paccanaro, Alberto

AU - Snyder, Michael

AU - Bork, Peer

AU - Gerstein, Mark B

AU - Jensen, Lars Juhl

N1 - Keywords: Amino Acids; Biosensing Techniques; Genomics; Lipid Metabolism; Microbiology; Polysaccharides

PY - 2009

Y1 - 2009

N2 - Recently, approaches have been developed to sample the genetic content of heterogeneous environments (metagenomics). However, by what means these sequences link distinct environmental conditions with specific biological processes is not well understood. Thus, a major challenge is how the usage of particular pathways and subnetworks reflects the adaptation of microbial communities across environments and habitats-i.e., how network dynamics relates to environmental features. Previous research has treated environments as discrete, somewhat simplified classes (e.g., terrestrial vs. marine), and searched for obvious metabolic differences among them (i.e., treating the analysis as a typical classification problem). However, environmental differences result from combinations of many factors, which often vary only slightly. Therefore, we introduce an approach that employs correlation and regression to relate multiple, continuously varying factors defining an environment to the extent of particular microbial pathways present in a geographic site. Moreover, rather than looking only at individual correlations (one-to-one), we adapted canonical correlation analysis and related techniques to define an ensemble of weighted pathways that maximally covaries with a combination of environmental variables (many-to-many), which we term a metabolic footprint. Applied to available aquatic datasets, we identified footprints predictive of their environment that can potentially be used as biosensors. For example, we show a strong multivariate correlation between the energy-conversion strategies of a community and multiple environmental gradients (e.g., temperature). Moreover, we identified covariation in amino acid transport and cofactor synthesis, suggesting that limiting amounts of cofactor can (partially) explain increased import of amino acids in nutrient-limited conditions.

AB - Recently, approaches have been developed to sample the genetic content of heterogeneous environments (metagenomics). However, by what means these sequences link distinct environmental conditions with specific biological processes is not well understood. Thus, a major challenge is how the usage of particular pathways and subnetworks reflects the adaptation of microbial communities across environments and habitats-i.e., how network dynamics relates to environmental features. Previous research has treated environments as discrete, somewhat simplified classes (e.g., terrestrial vs. marine), and searched for obvious metabolic differences among them (i.e., treating the analysis as a typical classification problem). However, environmental differences result from combinations of many factors, which often vary only slightly. Therefore, we introduce an approach that employs correlation and regression to relate multiple, continuously varying factors defining an environment to the extent of particular microbial pathways present in a geographic site. Moreover, rather than looking only at individual correlations (one-to-one), we adapted canonical correlation analysis and related techniques to define an ensemble of weighted pathways that maximally covaries with a combination of environmental variables (many-to-many), which we term a metabolic footprint. Applied to available aquatic datasets, we identified footprints predictive of their environment that can potentially be used as biosensors. For example, we show a strong multivariate correlation between the energy-conversion strategies of a community and multiple environmental gradients (e.g., temperature). Moreover, we identified covariation in amino acid transport and cofactor synthesis, suggesting that limiting amounts of cofactor can (partially) explain increased import of amino acids in nutrient-limited conditions.

U2 - 10.1073/pnas.0808022106

DO - 10.1073/pnas.0808022106

M3 - Journal article

C2 - 19164758

VL - 106

SP - 1374

EP - 1379

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

SN - 0027-8424

IS - 5

ER -

ID: 20417512