ライフサイエンスコーパス: acetoacetate

1 oxide ring opening and carboxylation to form acetoacetate.

2 to epoxypropane followed by carboxylation to acetoacetate.

3 of the carbon nucleophilic lipid metabolite acetoacetate.

4 evels ( approximately 10% yield) relative to acetoacetate.

5 ates acetone and HCO3(-) to form the product acetoacetate.

6 secondary product formed by the reduction of acetoacetate.

7 and a ketone/enolate nucleophile to generate acetoacetate.

8 inhibition pattern, partially alleviated by acetoacetate.

9 hydrolysis via acetoacetamide-N-sulfonate to acetoacetate.

10 ardial oxidation of beta-hydroxybutyrate and acetoacetate.

11 d inhibiting protonation in the formation of acetoacetate.

12 tabolically preferred carboxylation product, acetoacetate.

13 were identified as beta-hydroxybutyrate and acetoacetate.

14 of the enamine or an imine tautomer produces acetoacetate.

15 ding an allene (2,3-butadienoate) to produce acetoacetate.

16 similarly to rat islets but formed much more acetoacetate.

17 uctive cleavage and carboxylation to produce acetoacetate.

18 results in the conversion of epoxypropane to acetoacetate.

19 leavage of HMG-CoA to produce acetyl-CoA and acetoacetate.

20 e is dependent on the presence of Mg(2+) and acetoacetate.

21 ading capacity in the presence or absence of acetoacetate.

22 t cleavage of HMG-CoA to form acetyl-CoA and acetoacetate.

23 he condensation of acetone and CO(2) to form acetoacetate.

24 om commercially available ethyl [(13) C(4) ]-acetoacetate ([(13) C(4) ]-15).

25 oxylation to form acetone and CO(2); and (4) acetoacetate/(14)CO(2) exchange to form (14)C(1)-acetoac

26 ated increased acetate, adenosine, xanthine, acetoacetate, 3-hydroxybutyrate and betaine in alcohol-f

27 to the 'acidic' nature of the ketone bodies (acetoacetate, 3-hydroxybutyrate, and acetone).

28 emonstrated that high glucose (25 mm) and/or acetoacetate (4 mm) increased reactive oxygen species, d

29 se plus insulin (40 microU/ml), glucose plus acetoacetate (5 mM), or glucose plus insulin and acetoac

30 tate 4a, N-tosyl carbamate 5a, TBDMS 6a, and acetoacetate 7a) undergo metathesis without competing si

31 cells, AMPK-deficient cells required instead acetoacetate, a product of fatty acid catabolism indicat

32 counter elevated levels of the ketone bodies acetoacetate (AA), beta-hydroxybutyrate (BHB), and aceto

33 he ketone bodies 3-hydroxybutyrate (3HB) and acetoacetate (AA).

34 U937 cells were cultured with ketone bodies (acetoacetate [AA] and beta-hydroxybutyrate [BHB]) in the

35 through the in situ polymerization of allyl acetoacetate (AAA) monomers.

36 Hydroxybutyrate and acetoacetate (AC), alone or in combination, either faile

37 vels were associated with elevated levels of acetoacetate (AcAc) and beta-hydroxybutyrate (BHB).

38 strip displays high selectivity for HB over acetoacetate (AcAc) and other interferences (i.e., aceta

39 ketone bodies beta-hydroxybutyrate (BHB) and acetoacetate (AcAc) support mammalian survival during st

40 Conversion of the ketone body acetoacetate (AcAc) to beta-hydroxybutyrate (beta-HB) by

41 ticular interest, as ketone bodies (acetone, acetoacetate (AcAc), and beta-hydroxybutyrate (BHB)) ser

42 including beta-hydroxybutyrate (betaOHB) and acetoacetate (AcAc)-as essential fuels supporting CD8(+)

43 Both 3-beta-hydroxybutyrate and acetoacetate+acetone individually associated with incide

44 A one-pot acetoacetate acylation/decarboxylation/cyclodehydration

45 biotinylated capture probe, the Friedlander-acetoacetate adduct can be trapped and purified directly

46 However, acetoacetate and 3-hydroxybutyrate are produced not as a

47 d the labeling of the ketone bodies [1-(13)C]acetoacetate and [1-(13)C]beta-hydroxybutyryate, without

48 erized and demonstrated to cleave HMG-CoA to acetoacetate and acetyl-CoA with catalytic and affinity

49 oduction from glycine and conversion between acetoacetate and B-OH-butyrate, were assigned higher wei

50 The time courses of acetoacetate and beta-hydroxybutyrate formaton indicate

51 T1D is associated with both hyperketonemia (acetoacetate and beta-hydroxybutyrate) and hyperglycemia

52 on of propylene oxide (epoxypropane) to form acetoacetate and beta-hydroxybutyrate.

53 esis of the northern half based on nerol and acetoacetate and chromium(II)-mediated Reformatsky react

54 oacetate/(14)CO(2) exchange to form (14)C(1)-acetoacetate and CO(2).

55 topropylthio)ethanesulfonate; 2-KPC] to form acetoacetate and coenzyme M (CoM) in the bacterial pathw

56 boxylation of the beta-ketothioether to form acetoacetate and coenzyme M.

57 nd carboxylation of 2-ketopropyl-CoM to form acetoacetate and CoM according to the reaction: 2-ketopr

58 The two ketone body redox partners, acetoacetate and D-B-hydroxybutyrate, serve distinct met

59 opyl cleavage product, yielding the products acetoacetate and free coenzyme M.

60 zation in vivo using hyperpolarized [3-(13)C]acetoacetate and investigated the alterations in myocard

61 oacetyl-CoA synthetase to synthesize and use acetoacetate and suggests human islets may use this path

62 least two redundant pathways, one involving acetoacetate and the other citrate, for the synthesis SC

63 er a longer fast and with severer ketonemia, acetoacetate and total ketone-body production and oxidat

64 Rates of plasma acetoacetate and total ketone-body production and oxidat

65 ld ketonemia and minimal ketonuria, rates of acetoacetate and total ketone-body production and oxidat

66 ed of three compounds (beta-hydroxybutyrate, acetoacetate, and acetone) that circulate during starvat

67 ma concentrations of KBs (B-hydroxybutyrate, acetoacetate, and acetone) were measured by nuclear magn

68 l coenzyme A (acetoacetyl-CoA), butyryl CoA, acetoacetate, and beta-hydroxybutyrate.

69 output of 13C-labeled beta-hydroxybutyrate, acetoacetate, and CO2, indicating stimulated fatty acid

70 gen content in hearts perfused with glucose, acetoacetate, and insulin suggests increased glycogen tu

71 for a series of ketones (2-butanone, methyl acetoacetate, and N,N-dimethylacetoacetamide) and alkyl

72 nthesis of 13C-labeled beta-hydroxybutyrate, acetoacetate, and N-acetylglutamate.

73 The ketone bodies beta-hydroxybutyrate and acetoacetate are hepatically produced metabolites catabo

74 Ketone bodies (d-beta-hydroxybutyrate, acetoacetate) are increasingly recognised as important c

75 P-dependent carboxylation of acetone to form acetoacetate as a stoichiometric product.

76 in fumarylacetoacetate to yield fumarate and acetoacetate as the final step of Phe and Tyr degradatio

77 proceeds by a carboxylation reaction forming acetoacetate as the first detectable product.

78 s as carbonyl substrates, and urea and alkyl acetoacetates as further components.

79 networks and signals through the Oct-1-HMGCL-acetoacetate axis to selectively promote BRAF V600E-depe

80 d between dietary intakes of whole grain and acetoacetate (B: -0.50, P < 0.001) and B-hydroxybutyrate

81 01), as well as intakes of saturated fat and acetoacetate (B: 0.47, P < 0.001) and B-hydroxybutyrate

82 sured using NMR, reveals intact oxidation to acetoacetate but no contribution of ketone bodies to the

83 DNL, PUFA elongation required activation of acetoacetate by cytosolic acetoacetyl-coenzyme A synthet

84 ding on the medium, and was not derived from acetoacetate by nonenzymatic decarboxylation in the medi

85 enesis (production of beta-hydroxybutyrate + acetoacetate), C(5) ketogenesis (production of beta-hydr

86 t metabolites (3-D-hydroxybutyrate, acetone, acetoacetate, citrate, lactate, creatine, creatinine, an

87 the physiological products of the reaction, acetoacetate, coenzyme M, and NADP, and reduction of the

88 tructure demonstrates reduced coenzyme A and acetoacetate covalently bound to the active site cystein

89 Acetoacetate decarboxylase (AADase) has long been cited

90 e include the upregulated adc gene, encoding acetoacetate decarboxylase (EC 4.1.1.4), and the downreg

91 of enzymes in the acetone-formation pathway (acetoacetate decarboxylase [AADC] and coenzyme A-transfe

92 Acetoacetate decarboxylase from Clostridium acetobutylic

93 a high degree of structural similarity with acetoacetate decarboxylase, though the respective quater

94 previously uncharacterized family within the acetoacetate decarboxylase-like superfamily (ADCSF) and

95 mologues, identify a novel family within the acetoacetate decarboxylase-like superfamily with diverge

96 significant, level of sequence identity with acetoacetate decarboxylase.

97 Acetoacetate decarboxylation and (14)CO(2) exchange occu

98 sing 2-ketopropyl-CoM but did not inactivate acetoacetate decarboxylation or (14)CO(2) exchange react

99 siologically important forward reaction; (3) acetoacetate decarboxylation to form acetone and CO(2);

100 A redox-independent reaction of 2-KPCC (acetoacetate decarboxylation) was not decreased for any

101 on of acetone, CO2, inorganic phosphate, and acetoacetate did not perturb the EPR.

102 Treatment of benzaldehyde and an acetoacetate ester with potassium carbonate in an alcoho

103 m a diverse range of benzyl alcohols, methyl acetoacetate/ethyl benzoylacetate and hydroxylamine hydr

104 The use of low-cost iron(III) acetoacetate (Fe(acac)3) and tetramethylethylenediamine

105 phosphono allylic carbonates with tert-butyl acetoacetate followed by hydrolysis and decarboxylation,

106 for acetone carboxylation of 0.225 micromol acetoacetate formed min-1.mg-1 at 30 degrees C and pH 7.

107 ol AMP and 2 mol inorganic phosphate per mol acetoacetate formed.

108 phosphono allylic carbonate 10a with methyl acetoacetate gave the vinyl phosphonate 9a.

109 exosamine pathway including glucose, GlcNAc, acetoacetate, glutamine, ammonia, or uridine but not by

110 issues, starch was first functionalized with acetoacetate groups and subsequently blended with chitos

111 Dynamic cross-linking occurred between the acetoacetate groups and the primary amine groups of chit

112 xypropane + CO(2) + NADPH + NAD(+) + CoM --> acetoacetate + H(+) + NADP(+) + NADH + CoM.

113 action epoxypropane + CO2 + NADPH + NAD+ --> acetoacetate + H+ + NADP+ + NADH.

114 ation: epoxypropane + CO2 + NADPH + NAD+ --> acetoacetate + H+ + NADP+ + NADH.

115 After fumaryl acetoacetate hydrolase (Fah) gene transfer to hepatocyte

116 ient mice (specifically mice lacking fumaryl acetoacetate hydrolase [Fah], recombination activating g

117 ed the carboxylation of epoxypropane to form acetoacetate in a reaction that was dependent on the add

118 eductive cleavage, and carboxylation to form acetoacetate in a three-step metabolic pathway.

119 rsus direct hydration of the allene to yield acetoacetate in the case of Cg10062.

120 release indicating formation of SC-CoAs from acetoacetate in the cytosol is important for insulin sec

121 toacid-CoA transferase, an enzyme that forms acetoacetate in the mitochondria, and acetoacetyl-CoA sy

122 Nitric oxide adds to methyl acetoacetate in the presence of KOH in methanol at room

123 rsion of propylene to the central metabolite acetoacetate in Xanthobacter autotrophicus Py2.

124 uction in the absence of acetoacetate, while acetoacetate inhibited the uptake of glucose and the oxi

125 While an acetoacetate intermediate was not absolutely required fo

126 Hyperpolarized [3-(13)C]acetoacetate is a new probe with potential for non-invas

127 beta-hydroxybutyrate formaton indicate that acetoacetate is the primary product of propylene oxide c

128 ruvate) and mitochondrial (3-hydroxybutyrate/acetoacetate) NADH redox states were elevated by at leas

129 action: 2-ketopropyl-CoM + NADPH + CO(2) --> acetoacetate + NADP(+) + CoM.

130 media with serum and without serum; however, acetoacetate only induced proteolysis in cells maintaine

131 The addition of acetoacetate or insulin increased the incorporation of e

132 e longest linear sequence from either methyl acetoacetate or isobutyraldehyde.

133 ccessible 2-propargyloxypyridines and either acetoacetates or dimethyl malonate are reported.

134 tion with the metabolic substrates pyruvate, acetoacetate, or hydroxybutyrate also prevented mitochon

135 earrangement of nonracemic phosphono allylic acetoacetates, or the intermolecular allylic substitutio

136 the C=O equivalence site with the poly(allyl acetoacetate) (PAAA) matrix.

137 HMG-CoA reductase reaction and/or cleaved to acetoacetate plus acetyl-CoA by HMG cleavage enzyme.

138 elds a markedly reduced beta-hydroxybutyrate:acetoacetate ratio of 1:3, compared with 3:1 in Oxct1(+)

139 ns of ketone bodies (beta-hydroxybutyrate or acetoacetate) reduced the spontaneous firing rate of neu

140 We conclude that insulin and acetoacetate regulate the incorporation of glucose into

141 C(3) unit that is ultimately carboxylated to acetoacetate, releasing CoM.

142 aled its ability to utilize both acetate and acetoacetate substrates.

143 the active enzyme catalyzing acetyl-CoA and acetoacetate synthesis when incubated with (S)-HMG-CoA.

144 Within a minute upon injection of [3-(13)C]acetoacetate, the production of [5-(13)C]glutamate and [

145 t synthesis of 2-ketopropyl-CoM from CoM and acetoacetate, the reverse of the physiologically importa

146 observed in condensations of 16 with benzyl acetoacetate to afford Biginelli adduct 29 supports the

147 , and acetoacetyl-CoA synthetase, which uses acetoacetate to form acyl-CoAs in the cytosol.

148 which is subjected to nucleophilic attack by acetoacetate to form the new C(gamma)-C(delta) bond in 3

149 generated succinyl-CoA initially reacts with acetoacetate to yield acetoacetyl-CoA plus succinate in

150 nary complex with NAD(+) and 3-ketobutyrate (acetoacetate) to 1.4 A resolution, and as a ternary comp

151 uccinate esters or generated by succinyl-CoA-acetoacetate transferase is metabolized to malate follow

152 cetyl-CoA plus succinate in the succinyl-CoA-acetoacetate transferase reaction.

153 oacetate (5 mM), or glucose plus insulin and acetoacetate, using a three tracer (3H, 14C, and 13C) te

154 licum (AAD) catalyzes the decarboxylation of acetoacetate via a Schiff base intermediate.

155 Acetoacetate was determined to be the stoichiometric pro

156 A clean arylation protocol of ethyl acetoacetate was developed using hypervalent diaryliodon

157 HP [1-(13)C]acetoacetate was increased in fasting (250%) but decreas

158 Acetoacetate was significantly increased in the 10 mg/kg

159 reated with high glucose alone or along with acetoacetate, was prevented by vitamin D supplementation

160 the product of reductive decarboxylation of acetoacetate, was revealed in this structure in addition

161 ertase subtilisin/kexin type 9, acetate, and acetoacetate were increased by the intervention.

162 P, Krebs cycle intermediates, glutamate, and acetoacetate were investigated as candidate stimulus-cou

163 Ketone bodies, 3-hydroxybutyrate, and acetoacetate, were nonstatistically elevated, when compa

164 not alter the stereochemistry at C-2 of [2-D]acetoacetate when the reaction is conducted in D2O.

165 s-CaaD and the T34 mutant generate (2R)-[2-D]acetoacetate, whereas Cg10062 generates mostly the 2S is

166 he developing charge during the formation of acetoacetate, which acts as a product inhibitor in the W

167 n release caused large relative increases in acetoacetate, which is a precursor of pathways to short

168 the conversion of 2-ketopropyl-coenzyme M to acetoacetate, which is used as a carbon source, in a con

169 eased intracellular levels of HMGCL product, acetoacetate, which selectively enhances binding of BRAF

170 nd promotes the formation of the ketone body acetoacetate, which subsequently enhances BRAF(V600E)/ME

171 ake and lactate production in the absence of acetoacetate, while acetoacetate inhibited the uptake of

172 ghest yields are observed upon reaction with acetoacetates, while neutral and electron-rich substrate

173 ensation of 2-hydroxybenzaldehydes and ethyl acetoacetate with 1:1 acetylenecarboxylate-isocyanides i

174 se catalyzes the carboxylation of acetone to acetoacetate with concomitant hydrolysis of ATP to AMP a

175 he ATP-dependent carboxylation of acetone to acetoacetate with the concomitant production of AMP and

176 Accumulation of acetoacetate yields a markedly reduced beta-hydroxybutyr