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Fig. 1 Pathways for the biosynthesis of N-p-coumaroyloctopamine (p-CO) and chlorogenic acid (CGA) in potato tuber tissue. PAL, phenylalanine ammonia-lyase; C3′H, 5-O-(4-hydroxycinnamoyl) quinate 3′-hydroxylase; C4H, cinnamate 4-hydroxylase; 4CL, 4-hydroxycinnamic acid:CoA ligase; THT, tyramine hydroxycinnamoyl-CoA:tyramine N-(hydroxycinnamoyl)transferase; CQT, quinate hydroxycinnamoyl-CoA:quinate hydroxycinnamoyltransferase. From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
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Fig. 2 Time course for the accumulation of p-CO (closed circles) and CGA (open circles) in wound-healing potato tuber tissue. At time –24, potato tuber disks were prepared and incubated at 18°C under dark conditions. The results are expressed as the mean of triplicate experiments ±SD. L is the straight line that passes through the two points on the CGA concentration curve at –6 h and +6 h. The slope of line L was defined as a constant v for non-linear regression analysis of CGA. From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
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Fig. 3 Schematic models of linear metabolic pathways
Fig. 3 Schematic models of linear metabolic pathways. Symbols, X, Y and Z represent three metabolites in the pathway. J indicates the metabolic flux of each step. (A) A steady-state pathway. The flux from X to Y (defined as J) is equal to that from Y to Z. (B) A pathway in which the pool size of Y changes dynamically. The flux from X to Y (defined as J<sub>in</sub>) is not equal to that from Y to Z (J<sub>out</sub>). From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
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Fig. 4 Simplified pathways of p-CO and CGA biosynthesis for the analysis of metabolic flux using isotope-labeled phenylalanine. The four or five reaction steps in the pathway from phenylalanine to p-CO or CGA (Fig. 1) are simplified to one step by assuming that the levels of these intermediates are low enough. Based on the pathway, J<sub>in</sub> and J<sub>out</sub> of each metabolite were determined by metabolic flux analysis. The metabolic fate of CGA is not well understood. From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
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Fig. 5 Time course for the isotope abundance of l-phenyl-d<sub>5</sub>-alanine (Phe*) in potato tuber tissue. At time 0, a 10 µl aliquot of 10 mM Phe* solution was applied to the tissue (~0.2 g) and incubated for a set amount of time. Following the removal of excess Phe* by thorough washing with distilled water, Phe and Phe* in the tissues were extracted and analyzed by LC-MS. The results are expressed as the mean of triplicate experiments ±SD. From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
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Fig. 6 The procedure for the analysis of metabolic flux of p-CO and CGA in wound-healing potato tuber tissue. (A) A typical HPLC chromatogram of potato extracts using UV detection at 280 nm. The separation of major metabolites was accomplished in 5 min. (B) SIM chromatograms of same samples with LC-MS (APCI positive ion mode) analysis. The protonated molecule [M+H]<sup>+</sup> (m/z 355.1) and the ion formed by loss of water from the protonated molecule [M–H<sub>2</sub>O+H]<sup>+</sup> (m/z 282.1) were observed as the molecular-related ions in the case of CGA and p-CO, respectively. (C) SIM chromatograms of isotope-labeled and non-labeled p-CO in the potato extracts at 0, 0.5, 2 h after treatment with Phe* solution. Isotope-labeled p-CO (p-CO*) was observed at m/z that was increased four mass units from the non-labeled p-CO (m/z 282.1). (D) Time course for the isotope abundance of p-CO (closed circles) and CGA (open circles) in wound-healing potato tuber tissue. Following the determination of the peak area of isotope-labeled (A*) and non-labeled (A) metabolite from the SIM chromatogram of LC-MS analysis, isotope abundance (A*/(A + A*)) was calculated. The results are expressed as the mean of triplicate experiments ±SD. The fitting curves of equation (7) are also shown. From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063 Plant Cell Physiol |
![Fig. 6 The procedure for the analysis of metabolic flux of p-CO and CGA in wound-healing potato tuber tissue. (A) A typical HPLC chromatogram of potato extracts using UV detection at 280 nm. The separation of major metabolites was accomplished in 5 min. (B) SIM chromatograms of same samples with LC-MS (APCI positive ion mode) analysis. The protonated molecule [M+H]<sup>+</sup> (m/z 355.1) and the ion formed by loss of water from the protonated molecule [M–H<sub>2</sub>O+H]<sup>+</sup> (m/z 282.1) were observed as the molecular-related ions in the case of CGA and p-CO, respectively. (C) SIM chromatograms of isotope-labeled and non-labeled p-CO in the potato extracts at 0, 0.5, 2 h after treatment with Phe* solution. Isotope-labeled p-CO (p-CO*) was observed at m/z that was increased four mass units from the non-labeled p-CO (m/z 282.1). (D) Time course for the isotope abundance of p-CO (closed circles) and CGA (open circles) in wound-healing potato tuber tissue. Following the determination of the peak area of isotope-labeled (A*) and non-labeled (A) metabolite from the SIM chromatogram of LC-MS analysis, isotope abundance (A*/(A + A*)) was calculated. The results are expressed as the mean of triplicate experiments ±SD. The fitting curves of equation (7) are also shown.](http://slideplayer.com./slide/13219779/79/images/6/Fig.+6+The+procedure+for+the+analysis+of+metabolic+flux+of+p-CO+and+CGA+in+wound-healing+potato+tuber+tissue.+%28A%29+A+typical+HPLC+chromatogram+of+potato+extracts+using+UV+detection+at+280+nm.+The+separation+of+major+metabolites+was+accomplished+in+5+min.+%28B%29+SIM+chromatograms+of+same+samples+with+LC-MS+%28APCI+positive+ion+mode%29+analysis.+The+protonated+molecule+%5BM%2BH%5D%3Csup%3E%2B%3C%2Fsup%3E+%28m%2Fz+355.1%29+and+the+ion+formed+by+loss+of+water+from+the+protonated+molecule+%5BM%E2%80%93H%3Csub%3E2%3C%2Fsub%3EO%2BH%5D%3Csup%3E%2B%3C%2Fsup%3E+%28m%2Fz+282.1%29+were+observed+as+the+molecular-related+ions+in+the+case+of+CGA+and+p-CO%2C+respectively.+%28C%29+SIM+chromatograms+of+isotope-labeled+and+non-labeled+p-CO+in+the+potato+extracts+at+0%2C+0.5%2C+2+h+after+treatment+with+Phe%2A+solution.+Isotope-labeled+p-CO+%28p-CO%2A%29+was+observed+at+m%2Fz+that+was+increased+four+mass+units+from+the+non-labeled+p-CO+%28m%2Fz+282.1%29.+%28D%29+Time+course+for+the+isotope+abundance+of+p-CO+%28closed+circles%29+and+CGA+%28open+circles%29+in+wound-healing+potato+tuber+tissue.+Following+the+determination+of+the+peak+area+of+isotope-labeled+%28A%2A%29+and+non-labeled+%28A%29+metabolite+from+the+SIM+chromatogram+of+LC-MS+analysis%2C+isotope+abundance+%28A%2A%2F%28A+%2B+A%2A%29%29+was+calculated.+The+results+are+expressed+as+the+mean+of+triplicate+experiments+%C2%B1SD.+The+fitting+curves+of+equation+%287%29+are+also+shown..jpg "From: Metabolic Flux Analysis of the Phenylpropanoid Pathway in Wound-Healing Potato Tuber Tissue using Stable Isotope-Labeled Tracer and LC-MS Spectroscopy. Plant Cell Physiol. 2003;44(5): doi: /pcp/pcg063. Plant Cell Physiol |")
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