Characterization of poplar metabotypes via mass difference enrichment analysis.

Instrumentation technology for metabolomics has advanced drastically in recent years in terms of sensitivity and specificity. Despite these technical advances, data analytical strategies are still in their infancy in comparison with other 'omics'. Plants are known to possess an immense diversity of secondary metabolites. Typically, more than 70% of metabolomics data are not amenable to systems biological interpretation because of poor database coverage. Here, we propose a new general strategy for mass-spectrometry-based metabolomics that incorporates all exact mass features with known sum formulas into the evaluation and interpretation of metabolomics studies. We extend the use of mass differences, commonly used for feature annotation, by redefining them as variables that reflect the remaining 'omic' domains. The strategy uses exact mass difference network analyses exemplified for the metabolomic description of two grey poplar (Populus × canescens) genotypes that differ in their capability to emit isoprene. This strategy established a direct connection between the metabotype and the non-isoprene-emitting phenotype, as mass differences pertaining to prenylation reactions were over-represented in non-isoprene-emitting poplars. Not only was the analysis of mass differences able to grasp the known chemical biology of poplar, but it also improved the interpretability of yet unknown biochemical relationships.

[1]  J. K. Senior Partitions and Their Representative Graphs , 1951 .

[2]  A. Barabasi,et al.  Network biology: understanding the cell's functional organization , 2004, Nature Reviews Genetics.

[3]  D. R. Fulkerson,et al.  Incidence matrices and interval graphs , 1965 .

[4]  Eran Pichersky,et al.  Convergent evolution in plant specialized metabolism. , 2011, Annual review of plant biology.

[5]  Rainer Breitling,et al.  Ab initio prediction of metabolic networks using Fourier transform mass spectrometry data , 2006, Metabolomics.

[6]  P. Casey,et al.  Protein prenylation: molecular mechanisms and functional consequences. , 1996, Annual review of biochemistry.

[7]  F. Loreto,et al.  RNAi-mediated suppression of isoprene emission in poplar transiently impacts phenolic metabolism under high temperature and high light intensities: a transcriptomic and metabolomic analysis , 2010, Plant Molecular Biology.

[8]  S. Bernard,et al.  The importance of cytosolic glutamine synthetase in nitrogen assimilation and recycling. , 2009, The New phytologist.

[9]  R. Dixon,et al.  Characterization of an Isoflavonoid-Specific Prenyltransferase from Lupinus albus1[W][OA] , 2012, Plant Physiology.

[10]  M. Stitt Fructose-2,6-Bisphosphate as a Regulatory Molecule in Plants , 1990 .

[11]  M. Witting,et al.  Molecular and structural characterization of dissolved organic matter during and post cyanobacterial bloom in Taihu by combination of NMR spectroscopy and FTICR mass spectrometry. , 2014, Water research.

[12]  Mark R. Viant,et al.  MI-Pack: Increased confidence of metabolite identification in mass spectra by integrating accurate masses and metabolic pathways , 2010 .

[13]  Matej Oresic,et al.  MPEA - metabolite pathway enrichment analysis , 2011, Bioinform..

[14]  J. Gershenzon,et al.  Metabolic Flux Analysis of Plastidic Isoprenoid Biosynthesis in Poplar Leaves Emitting and Nonemitting Isoprene1[W] , 2014, Plant Physiology.

[15]  Franco Moritz,et al.  Molecular cartography in acute Chlamydia pneumoniae infections—a non-targeted metabolomics approach , 2013, Analytical and Bioanalytical Chemistry.

[16]  T. Nägele,et al.  Solving the Differential Biochemical Jacobian from Metabolomics Covariance Data , 2014, PloS one.

[17]  Y. Lou,et al.  Plant Terpenoids: Biosynthesis and Ecological Functions , 2007 .

[18]  K. Forchhammer,et al.  A Widespread Glutamine-Sensing Mechanism in the Plant Kingdom , 2014, Cell.

[19]  M. Angelis,et al.  Distinct signatures of host–microbial meta-metabolome and gut microbiome in two C57BL/6 strains under high-fat diet , 2014, The ISME Journal.

[20]  T. Ideker,et al.  A new approach to decoding life: systems biology. , 2001, Annual review of genomics and human genetics.

[21]  P. Kachlicki,et al.  Evaluation of glycosylation and malonylation patterns in flavonoid glycosides during LC/MS/MS metabolite profiling. , 2008, Journal of mass spectrometry : JMS.

[22]  Nuno Bandeira,et al.  Mass spectral molecular networking of living microbial colonies , 2012, Proceedings of the National Academy of Sciences.

[23]  Nathaniel D Hawkins,et al.  Metabolomic analysis of Arabidopsis reveals hemiterpenoid glycosides as products of a nitrate ion-regulated, carbon flux overflow , 2011, Proceedings of the National Academy of Sciences.

[24]  Simon Rogers,et al.  Probabilistic assignment of formulas to mass peaks in metabolomics experiments , 2009, Bioinform..

[25]  J. Gershenzon,et al.  Phenolic glycosides of the Salicaceae and their role as anti-herbivore defenses. , 2011, Phytochemistry.

[26]  Susan C. Connor,et al.  Assignment of MS-based metabolomic datasets via compound interaction pair mapping , 2008, Metabolomics.

[27]  John A. Morgan,et al.  BMC Systems Biology BioMed Central Research article , 2009 .

[28]  N. Stefan,et al.  Solutions for low and high accuracy mass spectrometric data matching: a data-driven annotation strategy in nontargeted metabolomics. , 2015, Analytical chemistry.

[29]  J. Gershenzon,et al.  The diversion of 2-C-methyl-D-erythritol-2,4-cyclodiphosphate from the 2-C-methyl-D-erythritol 4-phosphate pathway to hemiterpene glycosides mediates stress responses in Arabidopsis thaliana. , 2015, The Plant journal : for cell and molecular biology.

[30]  Jürgen Kurths,et al.  Observing and Interpreting Correlations in Metabolic Networks , 2003, Bioinform..

[31]  Martin J. Mueller,et al.  Lipid Profiling of the Arabidopsis Hypersensitive Response Reveals Specific Lipid Peroxidation and Fragmentation Processes: Biogenesis of Pimelic and Azelaic Acid1[C][W] , 2012, Plant Physiology.

[32]  Fabian J. Theis,et al.  Gaussian graphical modeling reconstructs pathway reactions from high-throughput metabolomics data , 2011, BMC Systems Biology.

[33]  S. K. Masakapalli,et al.  Subcellular Flux Analysis of Central Metabolism in a Heterotrophic Arabidopsis Cell Suspension Using Steady-State Stable Isotope Labeling1[W][OA] , 2009, Plant Physiology.

[34]  Measuring dimethylallyl diphosphate available for isoprene synthesis. , 2013, Analytical biochemistry.

[35]  L. Roberts,et al.  Measurement of lipid peroxidation. , 1998, Free radical research.

[36]  Chung-Jui Tsai,et al.  Biosynthesis of Phenolic Glycosides from Phenylpropanoid and Benzenoid Precursors in Populus , 2010, Journal of Chemical Ecology.

[37]  G. Kelly,et al.  Chloroplast Phosphofructokinase: II. Partial Purification, Kinetic and Regulatory Properties. , 1977, Plant physiology.

[38]  N. Brüggemann,et al.  Isoprene emission-free poplars--a chance to reduce the impact from poplar plantations on the atmosphere. , 2012, The New phytologist.

[39]  R. Breitling,et al.  Precision mapping of the metabolome. , 2006, Trends in biotechnology.

[40]  I. Arends,et al.  Are Natural Deep Eutectic Solvents the Missing Link in Understanding Cellular Metabolism and Physiology?[W] , 2011, Plant Physiology.

[41]  R. B. Jackson,et al.  Increasing atmospheric CO2 reduces metabolic and physiological differences between isoprene- and non-isoprene-emitting poplars. , 2013, The New phytologist.

[42]  J. Namieśnik,et al.  The compositional space of exhaled breath condensate and its link to the human breath volatilome , 2015, Journal of breath research.

[43]  Pablo Tamayo,et al.  Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[44]  F. Harary The Determinant of the Adjacency Matrix of a Graph , 1962 .

[45]  H. Rennenberg,et al.  Isoprene emission protects photosynthesis in sunfleck exposed Grey poplar , 2010, Photosynthesis Research.

[46]  Yvan Saeys,et al.  Systematic Structural Characterization of Metabolites in Arabidopsis via Candidate Substrate-Product Pair Networks[C][W] , 2014, Plant Cell.

[47]  F. Daniel-Vedele,et al.  REVIEW: PART OF A SPECIAL ISSUE ON PLANT NUTRITION Nitrogen uptake, assimilation and remobilization in plants: challenges for sustainable and productive agriculture , 2010 .

[48]  A. Walch,et al.  Knocking Down of Isoprene Emission Modifies the Lipid Matrix of Thylakoid Membranes and Influences the Chloroplast Ultrastructure in Poplar1 , 2015, Plant Physiology.

[49]  S. Hauck,et al.  Genetic manipulation of isoprene emissions in poplar plants remodels the chloroplast proteome. , 2014, Journal of proteome research.

[50]  R. Merris Laplacian matrices of graphs: a survey , 1994 .

[51]  Theodoros N. Arvanitis,et al.  Dynamic range and mass accuracy of wide-scan direct infusion nanoelectrospray fourier transform ion cyclotron resonance mass spectrometry-based metabolomics increased by the spectral stitching method. , 2007, Analytical chemistry.

[52]  Ying Zhang,et al.  HMDB: the Human Metabolome Database , 2007, Nucleic Acids Res..

[53]  Cornelia Göbel,et al.  Rapid Induction of Distinct Stress Responses after the Release of Singlet Oxygen in Arabidopsis Online version contains Web-only data. Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.014662. , 2003, The Plant Cell Online.

[54]  W. Pryor,et al.  Autoxidation of polyunsaturated fatty acids: II. A suggested mechanism for the formation of TBA-reactive materials from prostaglandin-like endoperoxides , 1976, Lipids.

[55]  F. Loreto,et al.  UV-B mediated metabolic rearrangements in poplar revealed by non-targeted metabolomics. , 2015, Plant, cell & environment.

[56]  Ruth C. Martin,et al.  Cytokinins: Biosynthesis metabolism and perception , 2000, In Vitro Cellular & Developmental Biology - Plant.

[57]  W. Streit,et al.  Biotin in microbes, the genes involved in its biosynthesis, its biochemical role and perspectives for biotechnological production , 2003, Applied Microbiology and Biotechnology.

[58]  N. Hertkorn,et al.  Kendrick-Analogous Network Visualisation of Ion Cyclotron Resonance Fourier Transform Mass Spectra: Improved Options for the Assignment of Elemental Compositions and the Classification of Organic Molecular Complexity , 2011, European journal of mass spectrometry.

[59]  Andreas Hansson,et al.  Oxidative modifications to cellular components in plants. , 2007, Annual review of plant biology.

[60]  K. Suhre,et al.  DI-ICR-FT-MS-based high-throughput deep metabotyping: a case study of the Caenorhabditis elegans–Pseudomonas aeruginosa infection model , 2015, Analytical and Bioanalytical Chemistry.

[61]  A. Makris,et al.  Rational Conversion of Substrate and Product Specificity in a Salvia Monoterpene Synthase: Structural Insights into the Evolution of Terpene Synthase Function[W] , 2007, The Plant Cell Online.

[62]  Jason A. Corwin,et al.  Cytoplasmic genetic variation and extensive cytonuclear interactions influence natural variation in the metabolome , 2013, eLife.

[63]  W. Schwab,et al.  Metabolome diversity: too few genes, too many metabolites? , 2003, Phytochemistry.

[64]  J. Bohlmann,et al.  Transgenic, non-isoprene emitting poplars don't like it hot. , 2007, The Plant journal : for cell and molecular biology.

[65]  Anton Hartmann,et al.  Importance of sulfur-containing metabolites in discriminating fecal extracts between normal and type-2 diabetic mice. , 2014, Journal of proteome research.

[66]  T. Moritz,et al.  UHPLC-ESI/TOFMS Determination of Salicylate-like Phenolic Gycosides in Populus tremula Leaves , 2011, Journal of Chemical Ecology.