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Transcript
Metabolomics, spring 06 Unfinished business from April 4! Hans Bohnert ERML 196 [email protected] 265-5475 333-5574 http://www.life.uiuc.edu/bohnert/ class April 6 Metabolite profiling = a static picture, a snapshot! Does it matter?* *Fernie AR et al. (2005) Flux an important, but neglected, component of functional genomics. Curr. Opin. Plant Biology 8, 174. *Fell DA (2005) Enzymes, metabolites and fluxes. J. Exptl Botany 56, 267. …. and two case studies. One could use the contraption for other experiments Maize Western Corn rootworm Nematode trap Rasmann et al. (2005) Nature 434, 731. Trimorphic interaction involving a entomopathogenic nematode Experiments similar to the wasp predation experiment • Identification of attractant • Why is US maize not protected • Does it work in the field • Isoprenoids in the soil? 2 – β-caryophyllene Attraction to / by authentic β-caryophyllene Olfactometer arms spiked with authentic β-caryophyllne Absence of β-Car. in some (mostly US) maize lines Reproductive success and β-caryophyllene Pactol – low amounts Graf – high amounts healthy fungal infections nematode presence All six containers received the same number of nematodes added β-caryophllene Emergence of adults is reduced when nematodes are attracted (pactol minus). in sand out of medium a - Detection in a column of wet sand 10 cm from release point b – detection in air space above a column of sand (note the scale differences) β-caryophylline diffuses readily (at least in and out of sand) Sesquiterpene hydrocarbons in maize A – leaf herbivore inducible; B – ubiquitous (maize self); C – root specific high - volatility - low Terpene synthases in maize • Heterologous expression • GC-MS with isotopic tracers • GC-MS of different lines • Mutational analysis of the “bottom” of the active site region Sesquiterpene spectrum as affected by mutational analysis of the TPS gene Tri-trophic interactions ecological studies phenotypic behavior experimental design metabolite profiling molecular analyses biochemical studies intraspecific variation - genetics transgenic approaches breeding objectives Systems biology multi-disciplinarity collaboration integration Experimental complexity in biology approaches what is common in astronomy and, especially, physics. Metabolite profiling = a static picture, a snapshot! Does it matter? Static (steady-state) “knowledge units” genome sequence, microarray profile, proteome composition How to understand cellular dynamics? Flux – where to measure, how and what is the most important “link”? Metabolites – intermediates in pathways to end-products (starch, cellulose, proteins, fats, lipids, second. products) Enzyme activity changes: steady-state of intermediates or flux? What is affected? yeast metabolomics (mutants) metabolites do change. Plants – metabolites +/- constant, flux altered photosynthesis – Calvin cycle – [NAD(P)H] – [ATP] – sucrose to starch [ADP-glucose pyrophosporylase] Steady state alone can be misleading pool size constant but coordinated increase in flux (activities altered) Monitoring flux Rate of depletion of an initial substrate Rate of accumulation of an end product Isotope labeling of (a) metabolite(s) (complete or in certain atoms) radioactive or stable isotopes (2H, 3H, 13C, 14C, 15N, 18O, 32P, 35S) Can we infer flux from changes in intermediates? think allosteric effects of metabolites measuring regulated steps in a pathway is intermediates [conc] (consider the Mark Stitt lecture) Pathways branch (label lost) Different pathway(s) provide(s) intermediate (label diluted by unknown) Tracer addition may change the equilibrium of the system Plants: where, and how, to introduce the tracer Pool size – dilution of label Is end-product transported – loss of label Do we know the pathway, or assume we know, and are we right Need certainty about pathway structures – (MapMan, TAIR, KEGG) – do we? More pitfalls and traps! Measuring (labeled) substrate consumption – insensitive, inaccurate Measuring end-product – stable, transported or metabolized (e.g., disappear in cell wall; does CO2 production and glycolysis) Branched pathways – do we know Linear relationship between product level and time (growth!) Experimental material – entire plant, organ (or part of organ), tissue slice, cells, organelles How “big” is the flux, the pathway – can we actually measure it? NMR (stable isot.), GC-MS, LC-MS - sensitivity and accuracy Positional information of tracer substrate modification may be important Long-term feeding expt, or pulse labeling, or pulse/chase expts Figure 1a Schwender et al. (2004) Rubisco without the Calvin cycle improves the carbon efficiency of developing green seeds. Nature 432, 779. (on web as: Shachar-Hill-Nature-2004) Figure 1b Figure 1 Metabolic transformation of sugars into fatty acids. a, Conversion of hexose phosphate to pentose phosphate through the non-oxidative steps of the pentose phosphate pathway and the subsequent formation of PGA by Rubisco bypasses the glycolytic enzymes glyceraldehyde-3-phosphate dehydrogenase and phosphoglycerate kinase while recycling half of the CO2 released by PDH. PGA is then further processed to pyruvate, acetyl-CoA and fatty acids. b, Part of a expanded to indicate carbon skeletons and to define relationships between V PDH (flux through PDH complex); V X (additional CO2 production by the OPPP, the TCA, and so on); V Rub (refixation by Rubisco). Metabolites: Ac-CoA, acetyl coenzymeA; DHAP, dihydroxyacetone-3-phosphate; E4P, erythrose-4-phosphate; Fru-6P, fructose-6-phosphate; GAP, glyceraldehydes-3-phosphate; Glc-6P, glucose-6phosphate; PGA, 3-phosphoglyceric acid; Pyr, pyruvate; R-5P, ribose-5-phosphate; Ru1,5-P2, ribulose-1,5-bisphosphate; Ru-5P, ribulose-5-phosphate; S-7P, sedoheptulose7-phosphate; Xu-5P, xylulose-5-phosphate. Enzymes: Aldo, fructose bisphosphate aldolase; Eno, 2-phosphoglycerate enolase; Xepi, xylulose-5-phosphate epimerase; FAS, fatty-acid synthase, PGM, phosphoglyceromutase; GAPDH, glyceraldehyde-3phosphate dehydrogenase; GPI, phosphoglucose isomerase; Riso, ribose-5-phosphate isomerase; PDH, pyruvate dehydrogenase; PFK, phosphofructokinase; PK, pyruvate kinase, PGK, phosphoglycerate kinase; PRK, phosphoribulokinase; TA, transaldolase; TK, transketolase; TPI, triose phosphate isomerase. Conclusions Rubisco operates as part of a previously undescribed metabolic route between carbohydrate and oil (Fig. 1a). Three stages: (1) conversion of hexose phosphates to ribulose-1,5-bisphosphate by the non-oxidative reactions of the OPPP together with phosphoribulokinase. (2) conversion of ribulose-1,5-bisphosphate and CO2 (most produced by PDH3) to PGA by Rubisco (3) metabolism of PGA to pyruvate and then to fatty acids (Fig. 1a). The net carbon stoichiometry of this conversion: 5 hexose phosphate > 6 pentose phosphate > 12 acetyl-CoA + 6 CO2 The conversion of the same amount of hexose phosphates by glycolysis: 5 hexose phosphate >10 Acetyl-CoA + 10 CO2 Where does the label go? • Primary metabolism • potato tubers • wild type and transgenics • EI GC-MS • U-13C/14C glucose feeding • pathway verification Roessner-Tunali et al. (2004) Kinetics of labeling of organic and amino acids in potato tubers by gas chromatography-mass spectrometry following incubation in (13)C labelled isotopes. Plant J. 39, 668. Possible reaction rates to measure Wt INV-2-30 SP-29 What is U-13C or U-14C glucose? Amounts over time (up to 12h) bold - transgenic difference to wild type (P < 0.05) important – watch differences in rates of synthesis (Δf = >100) A different experiment Arabidopsis ecotypes in high CO2 in FACE rings Attempts at correlating gene expression and metabolite concentrations Transcripts -0.6 0 2.4.1.123 Galactose 0.6 Galactinol Raffinose 2.4.1.82 Starch (log2 - fold change) Sucrose 3.2.1.1 Metabolites Neutral Invertase Cvi 27 Cvi 21 Col 27 Col 21 3.2.1.2 2.4.1.25 MEX1 Cysteine Maltose 3.2.1.26 Invertase, cell wall Invertase, vacuole Fructose Glucose DEP2 4.2.99.8 Melibiose 5.3.1.9 Tryptophan isoforms 2.7.1.1 At4g02610 At4g27070 4.1.1.48 2.3.1.30 1.2.1.12 5.3.1.24 2.7.2.3 2.1.2.1 3.1.3.3 Serine Glycine 2.6.1.52 1.1.1.95 2.4.2.18 3-Phosphoglycerate 5.4.2.1 Leucine 2.6.1.42 1.1.1.85 4.2.1.33 4.1.3.12 4.1.3.27 4.2.1.11 Phenylalanine 4.1.1.49 PEP 4.2.3.4 2.7.1.40 4.1.1.31 2.6.1.42 Valine 4.2.1.10 1.1.1.86 2.2.1.6 2.6.1.5 Pyruvate 2.7.1.71 Oxaloacetate Asparagine 4.2.1.51 2.5.1.19 4.2.3.5 Acetyl-CoA 6.3.5.4 Chorismate 2.6.1.1 Aspartate Oxaloacetate 1.3.1.12 Citrate Tyrosine 1.1.99.16 1.2.1.11 4.2.1.3 Aspartate-4-semialdehyde Malate Isocitrate 1.1.1.3 Proline 4.2.1.52 2.7.1.39 1.3.1.26 Homoserine-4-phosphate 1.1.1.42 4.2.1.2 At5g14800 At5g62530 2.6.1.17 4.2.99 3.5.1.18 alpha-Ketoglutarate Fumarate 4.4.1.8 1.4.7.1 Glutamate AT5G65750 5.1.1.7 6.3.1.2 Threonine 1.3.5.1 2.2.1.6 1.1.1.86 2.6.1.42 Isoleucine 2.1.1.14 2.1.1.10 Methionine Prephenate 2.3.3.1 2.7.2.4 4.2.3.1 5.4.99.5 4. 1.3.8 Lysine 6.2.1.4 Succinate Glutamine Figure 7.
