Project description:Verticillium dahliae Kleb., a soil-borne fungus that colonizes vascular tissues, induces wilting, chlorosis and early senescence in potato. Difference in senescence timing found in two diploid potato clones, 07506-01 and 12120-03, was studied and genetic variation in response to V. dahliae infection was identified as a causal factor. The clone, 07506-01, was infected with V. dahliae but did not develop symptoms, indicating tolerance to the pathogen. The other diploid clone, 12120-03 had low levels of pathogen with infection and moderate symptoms indicating partial resistance. 07506-01 was found to carry two susceptible alleles of the Ve2 gene and 12120-03 carried one Ve2 resistant and one susceptible allele. Infected leaves of the two clones were compared using gene expression profiling with the Potato Oligonucleotide Chip Initiative (POCI) microrarray. The results provide further evidence for differences in response of the two clones to infection with V. dahliae. Chlorophyll biosynthesis was higher in the tolerant 07506-01 compared to partially resistant 12120-03. On the other hand, expression of fungal defense genes, Ve resistance genes and defense phytohormone biosynthetic enzyme genes was decreased in 07506-01 compared to 12120-03 suggesting defense responses were suppressed in tolerance compared to resistance. Transcription factor gene expression differences pointed to the WRKY family as potential regulators of V. dahliae responses in potato. Two-color microarray comparison of two clones, three biological replicates of each clone, one dye swap technical replicate

Project description:Quantifying the Contribution of the Liver to Glucose Homeostasis: A Detailed Kinetic Model of Human Hepatic Glucose Metabolism Kinetic Model of Human Hepatic Glucose Metabolism Authors Matthias Koenig, Sascha Bulik and Hermann-Georg Holzhuetter Corresponding Author Matthias Koenig matthias.koenig@charite.de Charite Berlin, Computational Systems Biochemistry, Germany Keywords hepatic glucose metabolism; kinetic model; glucose homeostasis; liver Despite the crucial role of the liver in glucose homeostasis, a detailed mathematical model of human hepatic glucose metabolism is lacking so far. Here we present, a detailed kinetic model of glycolysis, gluconeogenesis and glycogen metabolism in human hepatocytes integrated with the hormonal control of these pathways by insulin, glucagon and epinephrine. Model simulations are in excellent agreement with experimental data on (i) the quantitative contributions of glycolysis, gluconeogenesis, and glycogen metabolism to hepatic glucose production and hepatic glucose utilization under varying physiological states. (ii) the time courses of postprandial glycogen storage as well as glycogen depletion in overnight fasting and short term fasting (iii) the switch from hepatic glucose production under hypoglycemia to hepatic glucose utilization under hyperglycemia essential for glucose homeostasis. Response analysis reveals an extra high capacity of the liver to counteract changes of plasma glucose level below 5 mM (hypoglycemia) and above 7.5 mM (hyperglycemia). Our model may serve as an important module of a whole-body model of human glucose metabolism and as a valuable tool for understanding the role of the liver in glucose homeostasis under normal conditions and in diseases like diabetes or glycogen storage diseases. Compartments Id Name Dimension Constant SBO GO cyto cytosol 3 Y SBO:0000290 physical compartment GO:0005829 cytosol blood blood 3 Y SBO:0000290 physical compartment GO:0005615 extracellular space mito mitochondrion 3 Y SBO:0000290 physical compartment GO:0005739 mitochondrion mm mitochondrial membrane 2 Y SBO:0000290 physical compartment GO:0031966 mitochondrial membrane pm plasma membrane 2 Y SBO:0000290 physical compartment GO:0005886 plasma membrane Species Id Name Compartment Constant Init [mM] KEGG CHEBI UNIPROT SBO atp ATP cyto Y 2.8 KEGG:C00002 CHEBI:15422 SBO:0000299 metabolite adp ADP cyto Y 0.8 KEGG:C00008 CHEBI:16761 SBO:0000299 metabolite amp AMP cyto Y 0.16 KEGG:C00020 CHEBI:16027 SBO:0000299 metabolite utp UTP cyto N 0.27 KEGG:C00075 CHEBI:15713 SBO:0000299 metabolite udp UDP cyto N 0.09 KEGG:C00015 CHEBI:17659 SBO:0000299 metabolite gtp GTP cyto N 0.29 KEGG:C00044 CHEBI:15996 SBO:0000299 metabolite gdp GDP cyto N 0.10 KEGG:C00035 CHEBI:17552 SBO:0000299 metabolite nad NAD+ cyto Y 1.22 KEGG:C00003 CHEBI:15846 SBO:0000299 metabolite nadh NADH cyto Y 5.60E-004 KEGG:C00004 CHEBI:16908 SBO:0000299 metabolite p phosphate cyto Y 5 KEGG:C00009 SBO:0000299 metabolite pp pyrophosphate cyto N 0.008 KEGG:C00013 SBO:0000299 metabolite h2o H2O cyto Y 55000 KEGG:C00001 CHEBI:15377 SBO:0000299 metabolite co2 CO2 cyto Y 5 KEGG:C00011 CHEBI:16526 SBO:0000299 metabolite h H+ cyto Y 5.00E-008 KEGG:C00080 CHEBI:24636 SBO:0000299 metabolite glc1p glucose-1-phosphate cyto N 0.012 KEGG:C00103 CHEBI:16077 SBO:0000299 metabolite udpglc UDP-glucose cyto N 0.38 KEGG:C00029 CHEBI:18066 SBO:0000299 metabolite glc glucose cyto N 5 KEGG:C00031 CHEBI:4167 SBO:0000299 metabolite glyglc glycogen cyto N 250 KEGG:C00182 CHEBI:28087 SBO:0000299 metabolite fru6p fructose-6-phosphate cyto N 0.05 KEGG:C00085 CHEBI:15946 SBO:0000299 metabolite glc6p glucose-6-phosphate cyto N 0.12 KEGG:C00092 CHEBI:4170 SBO:0000299 metabolite fru26bp fructose-2,6-bisphospate cyto N 0.004 KEGG:C00665 CHEBI:28602 SBO:0000299 metabolite fru16bp fructose-1,6-bisphospate cyto N 0.02 KEGG:C00354 CHEBI:16905 SBO:0000299 metabolite dhap dihydroxyacetone phosphate cyto N 0.03 KEGG:C00111 CHEBI:16108 SBO:0000299 metabolite grap glyceraldehyde 3-phosphate cyto N 0.1 KEGG:C00118 CHEBI:29052 SBO:0000299 metabolite pg3 3-phosphoglycerate cyto N 0.27 KEGG:C00197 CHEBI:17794 SBO:0000299 metabolite bpg13 1,3-bisphospho-glycerate cyto N 0.3 KEGG:C00236 CHEBI:16001 SBO:0000299 metabolite pep phosphoenolpyruvate cyto N 0.15 KEGG:C00074 CHEBI:44897 SBO:0000299 metabolite pg2 2-phosphoglycerate cyto N 0.03 KEGG:C00631 CHEBI:17835 SBO:0000299 metabolite oaa oxaloacetate cyto N 0.01 KEGG:C00036 CHEBI:30744 SBO:0000299 metabolite pyr pyruvate cyto N 0.1 KEGG:C00022 CHEBI:32816 SBO:0000299 metabolite glc_blood glucose blood Y 5 KEGG:C00031 CHEBI:4167 SBO:0000299 metabolite lac lactate cyto N 0.5 KEGG:C00186 CHEBI:422 SBO:0000299 metabolite p_mito phosphate mito Y 5 KEGG:C00009 SBO:0000299 metabolite oaa_mito oxaloacetate mito N 0.01 KEGG:C00036 CHEBI:30744 SBO:0000299 metabolite lac_blood lactate blood Y 1.2 KEGG:C00186 CHEBI:422 SBO:0000299 metabolite co2_mito CO2 mito Y 5 KEGG:C00011 CHEBI:16526 SBO:0000299 metabolite pyr_mito pyruvate mito N 0.1 KEGG:C00022 CHEBI:32816 SBO:0000299 metabolite cit_mito citrate mito Y 0.32 KEGG:C00158 CHEBI:30769 SBO:0000299 metabolite pep_mito pep mito N 0.15 KEGG:C00074 CHEBI:44897 SBO:0000299 metabolite acoa_mito acetyl-coenzyme A mito Y 0.04 KEGG:C00024 CHEBI:15351 SBO:0000299 metabolite gtp_mito GTP mito N 0.29 KEGG:C00044 CHEBI:15996 SBO:0000299 metabolite gdp_mito GDP mito N 0.10 KEGG:C00035 CHEBI:17552 SBO:0000299 metabolite atp_mito ATP mito Y 2.8 KEGG:C00002 CHEBI:15422 SBO:0000299 metabolite adp_mito ADP mito Y 0.8 KEGG:C00008 CHEBI:16761 SBO:0000299 metabolite nad_mito NAD+ mito Y 0.98 KEGG:C00003 CHEBI:15846 SBO:0000299 metabolite h_mito H+ mito Y 1.00E-008 KEGG:C00011 CHEBI:24636 SBO:0000299 metabolite coa_mito coenzymeA mito Y 0.055 KEGG:C00010 CHEBI:15346 SBO:0000299 metabolite nadh_mito NADH mito Y 0.24 KEGG:C00004 CHEBI:16908 SBO:0000299 metabolite epinephrine_blood epinephrine blood N 206.11 KEGG:C00547 CHEBI:18357 SBO:0000299 metabolite glucagon_blood glucagon blood N 4.36E-008 KEGG:C01501 UNIPROT:P01275 SBO:0000299 metabolite insulin_blood insulin blood N 7.61E-008 KEGG:C00723 UNIPROT:P01308 SBO:0000299 metabolite h20_mito H2O mito Y 55000 KEGG:C00080 CHEBI:15377 SBO:0000299 metabolite Reactions Id Name Compartment Irreversible Vmax [µmol/kg/min] EC KEGG UNIPROT SBO GLUT2 GLUT2 glucose transporter (facilitated diffusion) pm N 420 UNIPROT:P11168 SBO:0000284 transporter GK Glucokinase, hexokinase IV cyto Y 25.2 EC:2.7.1.2 KEGG:R00299 UNIPROT:P35557 SBO:0000014 enzyme G6PASE Glucose-6-phosphatase cyto Y 18.9 EC:3.1.3.9 KEGG:R00303 UNIPROT:P35575 SBO:0000014 enzyme GPI Glucose-6-phosphate isomerase cyto N 420 EC:5.3.1.9 KEGG:R00771 UNIPROT:P06744 SBO:0000014 enzyme G16PI glucose-1-phosphate 1,6-phosphomutase cyto N 100 EC:5.4.2.2 KEGG:R00959 UNIPROT:P36871, UNIPROT:Q96G03 SBO:0000014 enzyme UPGASE UTP:Glucose-1-phosphate uridylyltransferase cyto N 80 EC:2.7.7.9 KEGG:R00289 UNIPROT:Q16851 SBO:0000014 enzyme PPASE Pyrophosphate phosphohydrolase cyto Y 2.4 EC:3.6.1.1 KEGG:R00004 UNIPROT:Q15181 SBO:0000014 enzyme GS Glycogen synthase cyto Y 13.2 UNIPROT:P54840 SBO:0000014 enzyme GP Glycogen phosphorylase cyto N 6.8 UNIPROT:P06737 SBO:0000014 enzyme NTKGTP Nucleosid diphosphate kinase (GTP) cyto N 0 EC:2.7.4.6 KEGG:R00330 SBO:0000014 enzyme NTKUTP Nucleosid diphosphate kinase (UTP) cyto N 2940 EC:2.7.4.6 KEGG:R00156 SBO:0000014 enzyme AK Adenylat kinase cyto N 0 EC:2.7.4.3 KEGG:R00127 SBO:0000014 enzyme PFK2 Phosphofructo kinase 2 cyto Y 0.0042 EC:2.7.1.105 KEGG:R02732 UNIPROT:P16118 SBO:0000014 enzyme FBP2 Fructose-2,6-bisphosphatase cyto Y 0.126 EC:3.1.3.46 KEGG:R02731 UNIPROT:P16118 SBO:0000014 enzyme PFK1 Phosphofructo kinase 1 cyto Y 7.182 EC:2.7.1.11 KEGG:R00756 UNIPROT:P17858 SBO:0000014 enzyme FBP1 Fructose-1,6-bisphosphatase cyto Y 4.326 EC:3.1.3.11 KEGG:R00762 UNIPROT:O00757, UNIPROT:P09467 SBO:0000014 enzyme TPI Triosephosphate isomerase cyto N 420 EC:5.3.1.1 KEGG:R01015 UNIPROT:P60174 SBO:0000014 enzyme ALD Aldolase cyto N 420 EC:4.1.2.13 KEGG:R01068 UNIPROT:P05062 SBO:0000014 enzyme PGK Phosphoglycerate kinase cyto N 420 EC:2.7.2.3 KEGG:R01512 UNIPROT:P00558 SBO:0000014 enzyme GAPDH Glyceraldehydephosphate dehydrogenase cyto N 420 EC:1.2.1.12 KEGG:R01061 UNIPROT:P04406 SBO:0000014 enzyme EN Enolase cyto N 35.994 EC:4.2.1.11 KEGG:R00658 UNIPROT:P06733, UNIPROT:P09104, UNIPROT:P13929 SBO:0000014 enzyme PGAM 3-Phosphoglycerate mutase cyto N 420 EC:5.4.2.1 KEGG:R01518 UNIPROT:P18669 SBO:0000014 enzyme PEPCK Phosphoenolpyruvate carboxykinase cyto N 0 EC:4.1.1.32 KEGG:R00431 UNIPROT:P35558 SBO:0000014 enzyme PK Pyruvate kinase cyto Y 46.2 EC:2.7.1.40 KEGG:R00200 UNIPROT:P30613 SBO:0000014 enzyme PC Pyruvate Carboxylase mito Y 168 EC:6.4.1.1 KEGG:R00344 UNIPROT:P11498 SBO:0000014 enzyme PEPCK_mito Phosphoenolpyruvate carboxykinase mito N 546 EC:4.1.1.32 KEGG:R00431 UNIPROT:Q16822 SBO:0000014 enzyme LACT Lactate transporter pm N 5.418 SBO:0000284 transporter LDH Lactate dehydrogenase cyto N 12.6 EC:1.1.1.27 -KEGG:R00703 UNIPROT:P00338, UNIPROT:P07195, UNIPROT:P07864 SBO:0000014 enzyme PEPT PEP transporter mm N 33.6 SBO:0000284 transporter PYRT Pyruvate transporter mm N 42 SBO:0000284 transporter CS Citrate synthase mito N 4.2 EC:2.3.3.1 -KEGG:R00351 UNIPROT:O75390 SBO:0000014 enzyme PDH Pyruvate dehydrogenase mito Y 13.44 EC:1.2.4.1 KEGG:R00209 UNIPROT:P08559, UNIPROT:P11177, UNIPROT:P10515, UNIPROT:P09622, O00330 SBO:0000014 enzyme ACOAFLX Acetyl-CoA flux mito N 0 SBO:0000014 enzyme VCITFLX Citrate flux mito N 0 SBO:0000014 enzyme NDK_mito Nucleosid diphosphate kinase (GTP) mito N 420 EC:2.7.4.6 KEGG:R00330 SBO:0000014 enzyme OAAFLX Oxalacetate flux mito N 0 SBO:0000014 enzyme

Project description:Verticillium dahliae Kleb., a soil-borne fungus that colonizes vascular tissues, induces wilting, chlorosis and early senescence in potato. Difference in senescence timing found in two diploid potato clones, 07506-01 and 12120-03, was studied and genetic variation in response to V. dahliae infection was identified as a causal factor. The clone, 07506-01, was infected with V. dahliae but did not develop symptoms, indicating tolerance to the pathogen. The other diploid clone, 12120-03 had low levels of pathogen with infection and moderate symptoms indicating partial resistance. 07506-01 was found to carry two susceptible alleles of the Ve2 gene and 12120-03 carried one Ve2 resistant and one susceptible allele. Infected leaves of the two clones were compared using gene expression profiling with the Potato Oligonucleotide Chip Initiative (POCI) microrarray. The results provide further evidence for differences in response of the two clones to infection with V. dahliae. Chlorophyll biosynthesis was higher in the tolerant 07506-01 compared to partially resistant 12120-03. On the other hand, expression of fungal defense genes, Ve resistance genes and defense phytohormone biosynthetic enzyme genes was decreased in 07506-01 compared to 12120-03 suggesting defense responses were suppressed in tolerance compared to resistance. Transcription factor gene expression differences pointed to the WRKY family as potential regulators of V. dahliae responses in potato.

Project description:Kinetic Modeling of Human Hepatic Glucose Metabolism in Type 2 Diabetes Mellitus Predicts Higher Risk of Hypoglycemic Events in Rigorous Insulin Therapy* Kinetic Model of Human Hepatic Glucose Metabolism in T2DM Authors Matthias Koenig and Hermann-Georg Holzhuetter Corresponding Author Matthias Koenig matthias.koenig@charite.de Charite Berlin, Computational Systems Biochemistry, Germany Keywords hepatic glucose metabolism; kinetic model; glucose homeostasis; liver, T2DM A major problem in the insulin therapy of patients with diabetes type 2 (T2DM) is the increased occurrence of hypoglycemic events which, if left untreated, may cause confusion or fainting and in severe cases seizures, coma, and even death. To elucidate the potential contribution of the liver to hypoglycemia in T2DM we applied a detailed kinetic model of human hepatic glucose metabolism to simulate changes in glycolysis, gluconeogenesis, and glycogen metabolism induced by deviations of the hormones insulin, glucagon, and epinephrine from their normal plasma profiles. Our simulations reveal in line with experimental and clinical data from a multitude of studies in T2DM, (i) significant changes in the relative contribution of glycolysis, gluconeogenesis, and glycogen metabolism to hepatic glucose production and hepatic glucose utilization; (ii) decreased postprandial glycogen storage as well as increased glycogen depletion in overnight fasting and short term fasting; and (iii) a shift of the set point defining the switch between hepatic glucose production and hepatic glucose utilization to elevated plasma glucose levels, respectively, in T2DM relative to normal, healthy subjects. Intriguingly, our model simulations predict a restricted gluconeogenic response of the liver under impaired hormonal signals observed in T2DM, resulting in an increased risk of hypoglycemia. The inability of hepatic glucose metabolism to effectively counterbalance a decline of the blood glucose level becomes even more pronounced in case of tightly controlled insulin treatment. Given this Janus face mode of action of insulin, our model simulations underline the great potential that normalization of the plasma glucagon profile may have for the treatment of T2DM. Compartments Id Name Dimension Constant SBO GO cyto cytosol 3 Y SBO:0000290 physical compartment GO:0005829 cytosol blood blood 3 Y SBO:0000290 physical compartment GO:0005615 extracellular space mito mitochondrion 3 Y SBO:0000290 physical compartment GO:0005739 mitochondrion mm mitochondrial membrane 2 Y SBO:0000290 physical compartment GO:0031966 mitochondrial membrane pm plasma membrane 2 Y SBO:0000290 physical compartment GO:0005886 plasma membrane Species Id Name Compartment Constant Init [mM] KEGG CHEBI UNIPROT SBO atp ATP cyto Y 2.8 KEGG:C00002 CHEBI:15422 SBO:0000299 metabolite adp ADP cyto Y 0.8 KEGG:C00008 CHEBI:16761 SBO:0000299 metabolite amp AMP cyto Y 0.16 KEGG:C00020 CHEBI:16027 SBO:0000299 metabolite utp UTP cyto N 0.27 KEGG:C00075 CHEBI:15713 SBO:0000299 metabolite udp UDP cyto N 0.09 KEGG:C00015 CHEBI:17659 SBO:0000299 metabolite gtp GTP cyto N 0.29 KEGG:C00044 CHEBI:15996 SBO:0000299 metabolite gdp GDP cyto N 0.10 KEGG:C00035 CHEBI:17552 SBO:0000299 metabolite nad NAD+ cyto Y 1.22 KEGG:C00003 CHEBI:15846 SBO:0000299 metabolite nadh NADH cyto Y 5.60E-004 KEGG:C00004 CHEBI:16908 SBO:0000299 metabolite p phosphate cyto Y 5 KEGG:C00009 SBO:0000299 metabolite pp pyrophosphate cyto N 0.008 KEGG:C00013 SBO:0000299 metabolite h2o H2O cyto Y 55000 KEGG:C00001 CHEBI:15377 SBO:0000299 metabolite co2 CO2 cyto Y 5 KEGG:C00011 CHEBI:16526 SBO:0000299 metabolite h H+ cyto Y 5.00E-008 KEGG:C00080 CHEBI:24636 SBO:0000299 metabolite glc1p glucose-1-phosphate cyto N 0.012 KEGG:C00103 CHEBI:16077 SBO:0000299 metabolite udpglc UDP-glucose cyto N 0.38 KEGG:C00029 CHEBI:18066 SBO:0000299 metabolite glc glucose cyto N 5 KEGG:C00031 CHEBI:4167 SBO:0000299 metabolite glyglc glycogen cyto N 250 KEGG:C00182 CHEBI:28087 SBO:0000299 metabolite fru6p fructose-6-phosphate cyto N 0.05 KEGG:C00085 CHEBI:15946 SBO:0000299 metabolite glc6p glucose-6-phosphate cyto N 0.12 KEGG:C00092 CHEBI:4170 SBO:0000299 metabolite fru26bp fructose-2,6-bisphospate cyto N 0.004 KEGG:C00665 CHEBI:28602 SBO:0000299 metabolite fru16bp fructose-1,6-bisphospate cyto N 0.02 KEGG:C00354 CHEBI:16905 SBO:0000299 metabolite dhap dihydroxyacetone phosphate cyto N 0.03 KEGG:C00111 CHEBI:16108 SBO:0000299 metabolite grap glyceraldehyde 3-phosphate cyto N 0.1 KEGG:C00118 CHEBI:29052 SBO:0000299 metabolite pg3 3-phosphoglycerate cyto N 0.27 KEGG:C00197 CHEBI:17794 SBO:0000299 metabolite bpg13 1,3-bisphospho-glycerate cyto N 0.3 KEGG:C00236 CHEBI:16001 SBO:0000299 metabolite pep phosphoenolpyruvate cyto N 0.15 KEGG:C00074 CHEBI:44897 SBO:0000299 metabolite pg2 2-phosphoglycerate cyto N 0.03 KEGG:C00631 CHEBI:17835 SBO:0000299 metabolite oaa oxaloacetate cyto N 0.01 KEGG:C00036 CHEBI:30744 SBO:0000299 metabolite pyr pyruvate cyto N 0.1 KEGG:C00022 CHEBI:32816 SBO:0000299 metabolite glc_blood glucose blood Y 5 KEGG:C00031 CHEBI:4167 SBO:0000299 metabolite lac lactate cyto N 0.5 KEGG:C00186 CHEBI:422 SBO:0000299 metabolite p_mito phosphate mito Y 5 KEGG:C00009 SBO:0000299 metabolite oaa_mito oxaloacetate mito N 0.01 KEGG:C00036 CHEBI:30744 SBO:0000299 metabolite lac_blood lactate blood Y 1.2 KEGG:C00186 CHEBI:422 SBO:0000299 metabolite co2_mito CO2 mito Y 5 KEGG:C00011 CHEBI:16526 SBO:0000299 metabolite pyr_mito pyruvate mito N 0.1 KEGG:C00022 CHEBI:32816 SBO:0000299 metabolite cit_mito citrate mito Y 0.32 KEGG:C00158 CHEBI:30769 SBO:0000299 metabolite pep_mito pep mito N 0.15 KEGG:C00074 CHEBI:44897 SBO:0000299 metabolite acoa_mito acetyl-coenzyme A mito Y 0.04 KEGG:C00024 CHEBI:15351 SBO:0000299 metabolite gtp_mito GTP mito N 0.29 KEGG:C00044 CHEBI:15996 SBO:0000299 metabolite gdp_mito GDP mito N 0.10 KEGG:C00035 CHEBI:17552 SBO:0000299 metabolite atp_mito ATP mito Y 2.8 KEGG:C00002 CHEBI:15422 SBO:0000299 metabolite adp_mito ADP mito Y 0.8 KEGG:C00008 CHEBI:16761 SBO:0000299 metabolite nad_mito NAD+ mito Y 0.98 KEGG:C00003 CHEBI:15846 SBO:0000299 metabolite h_mito H+ mito Y 1.00E-008 KEGG:C00011 CHEBI:24636 SBO:0000299 metabolite coa_mito coenzymeA mito Y 0.055 KEGG:C00010 CHEBI:15346 SBO:0000299 metabolite nadh_mito NADH mito Y 0.24 KEGG:C00004 CHEBI:16908 SBO:0000299 metabolite epinephrine_blood epinephrine blood N 206.11 KEGG:C00547 CHEBI:18357 SBO:0000299 metabolite glucagon_blood glucagon blood N 4.36E-008 KEGG:C01501 UNIPROT:P01275 SBO:0000299 metabolite insulin_blood insulin blood N 7.61E-008 KEGG:C00723 UNIPROT:P01308 SBO:0000299 metabolite h20_mito H2O mito Y 55000 KEGG:C00080 CHEBI:15377 SBO:0000299 metabolite Reactions Id Name Compartment Irreversible Vmax [µmol/kg/min] EC KEGG UNIPROT SBO GLUT2 GLUT2 glucose transporter (facilitated diffusion) pm N 420 UNIPROT:P11168 SBO:0000284 transporter GK Glucokinase, hexokinase IV cyto Y 25.2 EC:2.7.1.2 KEGG:R00299 UNIPROT:P35557 SBO:0000014 enzyme G6PASE Glucose-6-phosphatase cyto Y 18.9 EC:3.1.3.9 KEGG:R00303 UNIPROT:P35575 SBO:0000014 enzyme GPI Glucose-6-phosphate isomerase cyto N 420 EC:5.3.1.9 KEGG:R00771 UNIPROT:P06744 SBO:0000014 enzyme G16PI glucose-1-phosphate 1,6-phosphomutase cyto N 100 EC:5.4.2.2 KEGG:R00959 UNIPROT:P36871, UNIPROT:Q96G03 SBO:0000014 enzyme UPGASE UTP:Glucose-1-phosphate uridylyltransferase cyto N 80 EC:2.7.7.9 KEGG:R00289 UNIPROT:Q16851 SBO:0000014 enzyme PPASE Pyrophosphate phosphohydrolase cyto Y 2.4 EC:3.6.1.1 KEGG:R00004 UNIPROT:Q15181 SBO:0000014 enzyme GS Glycogen synthase cyto Y 13.2 UNIPROT:P54840 SBO:0000014 enzyme GP Glycogen phosphorylase cyto N 6.8 UNIPROT:P06737 SBO:0000014 enzyme NTKGTP Nucleosid diphosphate kinase (GTP) cyto N 0 EC:2.7.4.6 KEGG:R00330 SBO:0000014 enzyme NTKUTP Nucleosid diphosphate kinase (UTP) cyto N 2940 EC:2.7.4.6 KEGG:R00156 SBO:0000014 enzyme AK Adenylat kinase cyto N 0 EC:2.7.4.3 KEGG:R00127 SBO:0000014 enzyme PFK2 Phosphofructo kinase 2 cyto Y 0.0042 EC:2.7.1.105 KEGG:R02732 UNIPROT:P16118 SBO:0000014 enzyme FBP2 Fructose-2,6-bisphosphatase cyto Y 0.126 EC:3.1.3.46 KEGG:R02731 UNIPROT:P16118 SBO:0000014 enzyme PFK1 Phosphofructo kinase 1 cyto Y 7.182 EC:2.7.1.11 KEGG:R00756 UNIPROT:P17858 SBO:0000014 enzyme FBP1 Fructose-1,6-bisphosphatase cyto Y 4.326 EC:3.1.3.11 KEGG:R00762 UNIPROT:O00757, UNIPROT:P09467 SBO:0000014 enzyme TPI Triosephosphate isomerase cyto N 420 EC:5.3.1.1 KEGG:R01015 UNIPROT:P60174 SBO:0000014 enzyme ALD Aldolase cyto N 420 EC:4.1.2.13 KEGG:R01068 UNIPROT:P05062 SBO:0000014 enzyme PGK Phosphoglycerate kinase cyto N 420 EC:2.7.2.3 KEGG:R01512 UNIPROT:P00558 SBO:0000014 enzyme GAPDH Glyceraldehydephosphate dehydrogenase cyto N 420 EC:1.2.1.12 KEGG:R01061 UNIPROT:P04406 SBO:0000014 enzyme EN Enolase cyto N 35.994 EC:4.2.1.11 KEGG:R00658 UNIPROT:P06733, UNIPROT:P09104, UNIPROT:P13929 SBO:0000014 enzyme PGAM 3-Phosphoglycerate mutase cyto N 420 EC:5.4.2.1 KEGG:R01518 UNIPROT:P18669 SBO:0000014 enzyme PEPCK Phosphoenolpyruvate carboxykinase cyto N 0 EC:4.1.1.32 KEGG:R00431 UNIPROT:P35558 SBO:0000014 enzyme PK Pyruvate kinase cyto Y 46.2 EC:2.7.1.40 KEGG:R00200 UNIPROT:P30613 SBO:0000014 enzyme PC Pyruvate Carboxylase mito Y 168 EC:6.4.1.1 KEGG:R00344 UNIPROT:P11498 SBO:0000014 enzyme PEPCK_mito Phosphoenolpyruvate carboxykinase mito N 546 EC:4.1.1.32 KEGG:R00431 UNIPROT:Q16822 SBO:0000014 enzyme LACT Lactate transporter pm N 5.418 SBO:0000284 transporter LDH Lactate dehydrogenase cyto N 12.6 EC:1.1.1.27 -KEGG:R00703 UNIPROT:P00338, UNIPROT:P07195, UNIPROT:P07864 SBO:0000014 enzyme PEPT PEP transporter mm N 33.6 SBO:0000284 transporter PYRT Pyruvate transporter mm N 42 SBO:0000284 transporter CS Citrate synthase mito N 4.2 EC:2.3.3.1 -KEGG:R00351 UNIPROT:O75390 SBO:0000014 enzyme PDH Pyruvate dehydrogenase mito Y 13.44 EC:1.2.4.1 KEGG:R00209 UNIPROT:P08559, UNIPROT:P11177, UNIPROT:P10515, UNIPROT:P09622, O00330 SBO:0000014 enzyme ACOAFLX Acetyl-CoA flux mito N 0 SBO:0000014 enzyme VCITFLX Citrate flux mito N 0 SBO:0000014 enzyme NDK_mito Nucleosid diphosphate kinase (GTP) mito N 420 EC:2.7.4.6 KEGG:R00330 SBO:0000014 enzyme OAAFLX Oxalacetate flux mito N 0 SBO:0000014 enzyme

Project description:Oligoarray expression profiling was carried out in poplar leaves upon infection with rust in order to identify genes expressed during tree defense response. For this purpose, we inoculated detached leaves of the interamerican hybrid poplar Populus trichocarpa x Populus deltoides 'Beaupré' grown in greenhouse either with spores of avirulent strain 93ID6 (incompatible interaction I48) or spores of virulent strain 98AG31 (compatible interaction C48) of the pathogenic rust fungus Melampsora larici-populina. Besides, we mock-inoculated 'Beaupré' leaves with water (control condition, T48). Detached leaves were maintained in vitro in controled conditions to allow fungal infection and colonization of plant tissue. Leaves were sampled 48 hours post-inoculation after that the fungus attempt to penetrate plant cells in mesophyll. Keywords: Plant tissue infection, Plant defense response, Oligonucleotide array

Project description:Microarray analysis was performed on the aerial parts of 5 plants collected 24 hours after water treatment or inoculation by the Ralstonia solanacearum hrpB strain (avirulent strain) and 5 days (25% of wilted leaves) after challenge inoculation with the GMI1000 virulent R. solanacearum strain. We compared trancriptome expression level of protected plants (hrpB prinoculation) versus non protected plants (water treatment), 24H after treatment and 5 days (25% of wilted leaves) after challenge inoculation with the GMI1000 virulent R. solanacearum strain

Project description:cDNA macroarray expression profiling was carried out in poplar leaves upon infection with rust in order to identify genes expressed during tree defense response. For this purpose, we inoculated detached leaves of the interamerican hybrid poplar Populus trichocarpa x Populus deltoides 'Beaupré' grown in greenhouse either with spores of avirulent strain 93ID6 (incompatible interaction, I) or spores of virulent strain 98AG31 (compatible interaction, C) of the pathogenic rust fungus Melampsora larici-populina. Besides, we mock-inoculated 'Beaupré' leaves with water (control condition, T). Detached leaves were maintained in vitro in controled conditions to allow fungal infection and colonization of plant tissue. Leaves were sampled at 12, 24 and 48 hours post-inoculation (hpi) in a time-course experiment before (12 hpi) and after (24 and 48 hpi) that the fungus attempt to penetrate plant cells in mesophyll. Keywords: Plant tissue infection, Plant defense response, cDNA macroarray

Project description:Verticillium dahliae is a soil-borne fungus with a broad host range, including the model plants Nicotiana benthamiana and Arabidopsis thaliana. The plant immunity can be activated by Vd-derived patterns while V. dahliae secreted effectors. We report here the RNAseq analyses of samples from N. benthamiana infected by V. dahliae strains 592 and 171 at different time points. The data showed dynamic expression patterns of genes not only from plant defense signaling but also plant developmental signaling.

Project description:Geographical distinct virulent Babesia bovis strains have similar gene expression changes as they go through attenuation. Pair end RNA-sequencing reads on three biological replicate sample pairs of virulent parent and attenuated derivative Babesia bovis strain isolated in Argentina.

Project description:L. monocytogenes consisting of 13 serotypes, is an opportunistic food-borne pathogen that causes different host reactions to depend on its serotypes. In this study, highly toxic L. monocytogenes 10403s resulted in more severe infections and lower survival rates. Additionally, to investigate the remodeling of host proteome by strains exhibiting differential toxicity, the cellular protein re-sponses of intestinal organoids were analyzed using tandem mass tags (TMT) labeling and high-performance liquid chromatography-mass spectrometry. The virulent strain 10403s caused 102 upregulated and 52 downregulated proteins, while the low virulent strain M7 caused 188 upregulated and 25 downregulated proteins. Based on the analysis of Gene Ontology (GO) and KEGG databases, the expression of differential proteins in organoids infected by L. monocytogenes 10403s (virulent strain) or M7 (low virulent strain), was involved in regulating essential processes such as biological metabolism, energy metabolism, and immune system process. The results showed that the immune system process, as primary host defense response caused by L. mono-cytogenes, had five pathways including ECM-receptor interaction, complement and coagulation cascade, HIF-1, Ferroptosis, and NOD-like receptor signaling pathways. These results revealed that L. monocytogenes strains with different toxicity induced similar biological functions and immune responses while having different regulations on differential proteins in the pathway.