ライフサイエンスコーパス: anaerobic metabolism

1 olytic inhibitors due to their dependence on anaerobic metabolism.

2 indicating a complex regulatory circuitry of anaerobic metabolism.

3 Seals, for example, seldom rely on anaerobic metabolism.

4 ls is an increased uptake of glucose and its anaerobic metabolism.

5 rogenase activity, indicating a shift toward anaerobic metabolism.

6 cultures confirmed co-occurring aerobic and anaerobic metabolism.

7 hich in turn catalyze essential reactions in anaerobic metabolism.

8 s production, and the balance of the aerobic/anaerobic metabolism.

9 rapes and wine, likely due to differences in anaerobic metabolism.

10 s of strict delineations between aerobic and anaerobic metabolism.

11 hey cannot meet cellular energy demands with anaerobic metabolism.

12 y transition from an aerobic to an exclusive anaerobic metabolism.

13 ction of genes encoding enzymes required for anaerobic metabolism.

14 actate production, suggesting a shift toward anaerobic metabolism.

15 many of which encode enzymes associated with anaerobic metabolism.

16 etic shift from oxidative phosphorylation to anaerobic metabolism.

17 , including angiogenesis, proliferation, and anaerobic metabolism.

18 on was responsible for a further increase in anaerobic metabolism.

19 and archaea that carry out diverse types of anaerobic metabolism.

20 that control the switch between aerobic and anaerobic metabolism.

21 ily lead to increased acid concentration via anaerobic metabolism.

22 n their sustained growth must also depend on anaerobic metabolism.

23 relative to the parental strain during dark, anaerobic metabolism.

24 integrates upstream mRNA signals to activate anaerobic metabolism.

25 ed via the ArcB redox sensor and to activate anaerobic metabolism.

26 Psp system is induced via ArcB and activates anaerobic metabolism.

27 c factors and inducing enzymes necessary for anaerobic metabolism.

28 olved in virulence, DNA repair, and notably, anaerobic metabolism.

29 active, whereas others shut down or rely on anaerobic metabolism.

30 gical responses to modulators of aerobic and anaerobic metabolism.

31 pression was expected based on their role in anaerobic metabolism.

32 eletal muscle, cardiac muscle cannot sustain anaerobic metabolism.

33 elsewhere are characterized predominately by anaerobic metabolisms.

34 rowth conditions, including both aerobic and anaerobic metabolisms.

35 tained higher flesh firmness and reduced the anaerobic metabolism, although it decreased fruit qualit

36 rly HIF-1, which activates genes involved in anaerobic metabolism and angiogenesis.

37 ergy-regenerating mechanism, which activates anaerobic metabolism and autophagy-mediated macromolecul

38 apy should include a better understanding of anaerobic metabolism and biofilm development by P. aerug

39 pH, which could provide for feedback between anaerobic metabolism and hypoxia sensing.

40 e results highlight the interconnectivity of anaerobic metabolism and importance of community dynamic

41 wing exposure to cadmium revealed a shift to anaerobic metabolism and induction of several stress res

42 Anaerobic metabolism and its energy promoting effect on

43 HUPs coregulated with genes associated with anaerobic metabolism and other processes that significan

44 Proteins involved in anaerobic metabolism and oxidative-stress tolerance are

45 Consequently, they consume glucose in anaerobic metabolism and produce a high level of lactate

46 n and messenger RNA translation that promote anaerobic metabolism and thus sustain substrate-level AT

47 ected by chance, as are domains involved in (anaerobic) metabolism and DNA binding.

48 tic hormone levels, a change from aerobic to anaerobic metabolism, and increases in inflammatory cyto

49 plantation but is associated with ischaemia, anaerobic metabolism, and organ injuries, leading to pat

50 ate and fatty acid biosynthesis, for FDX2 in anaerobic metabolism, and possibly in state transition.

51 However, the molecular targets of NO in anaerobic metabolism are less understood.

52 Both aerobic and anaerobic metabolisms are available, the former requirin

53 gene-inferred aerobic, microaerophilic, and anaerobic metabolisms are likely supported by shallower

54 Solutes indicative of a progression of anaerobic metabolisms are observed vertically and horizo

55 Anaerobic metabolisms are thought to dominate nitrogen c

56 from oxidative phosphorylation to glycolytic anaerobic metabolism as well as for angiogenesis and has

57 oxygen levels and switch between aerobic and anaerobic metabolisms, as exemplified by the fumarate, n

58 responding to oxidative stress exploits the anaerobic metabolism associated with dmsABC gene product

59 ith decreased OXHPOS and upregulation of the anaerobic metabolism-associated uncoupling protein 2 (UC

60 FNR regulon and increases the efficiency of anaerobic metabolism by repressing the synthesis of enzy

61 verse range of cellular activities including anaerobic metabolism, cell envelope biogenesis, metal ac

62 In volume-responders, unlike markers of anaerobic metabolism, central venous oxygen saturation d

63 hat the preference of a microorganism for an anaerobic metabolism correlates with the number of PHX e

64 f anaerobiosis is that optimal strategies of anaerobic metabolism depend upon radical chemistry and l

65 in 16 (84%) patients and increased cerebral anaerobic metabolism developed in 11 (58%) patients.

66 Lactic acid produced by anaerobic metabolism during cardiac ischemia is among se

67 ion of ATP and facilitates the transition to anaerobic metabolism during low-oxygen stress.

68 as an early defect in close association with anaerobic metabolism during progression of circulatory s

69 d indicating a significant contribution from anaerobic metabolism during severe asphyxia.

70 s that the severity of acidosis secondary to anaerobic metabolism during severe focal cerebral ischem

71 GF) and inducible nitric oxide synthase] and anaerobic metabolism (e.g., glycolytic enzymes).

72 esults suggest that during the transition to anaerobic metabolism, E3 remains unchanged, but it appea

73 tudy investigated the dynamic changes in the anaerobic metabolism end products (ethanol, acetaldehyde

74 g transcription factors, signaling proteins, anaerobic metabolism enzymes, and uncharacterized protei

75 are reduced, a finding inconsistent with the anaerobic metabolism expected to occur during hypoxia.

76 regulated by a global regulatory protein for anaerobic metabolism, FNR.

77 and thiamine biosynthesis (bioF and thiDFH), anaerobic metabolism (focB, hyfACDR, ttdA, and fumB), an

78 especially true for lactate, the product of anaerobic metabolism following glycolysis.

79 nd maximal biomass productivities of various anaerobic metabolisms for a range of pH, temperatures, a

80 uring anoxia, the naked mole-rat switches to anaerobic metabolism fueled by fructose, which is active

81 olved in metal transport (feoA, mntH, sirA), anaerobic metabolism genes (adhE, pflA, nrdDG) and a lar

82 owever, lactate (conventionally a product of anaerobic metabolism) has been proposed to act as an ene

83 vidence to support a shift from oxidative to anaerobic metabolism in AD.

84 the robust activation of genes required for anaerobic metabolism in B. subtilis.

85 )/ O(2) was able to depict the occurrence of anaerobic metabolism in both tissue hypoxia models.

86 the alcohol dehydrogenase (ADH) and greater anaerobic metabolism in comparison with DCA - CF (chloro

87 ctivates transcription of genes required for anaerobic metabolism in Escherichia coli through interac

88 tics and mechanism of H(2) production and of anaerobic metabolism in general.

89 cells provides evidence of extensive use of anaerobic metabolism in hypoxic COPD patients.

90 ating species-resolved, single-cell rates of anaerobic metabolism in low-biomass environments while s

91 e production, and 3) increased dependence on anaerobic metabolism in skeletal muscles.

92 e to the development of an informed model of anaerobic metabolism in this and potentially other algae

93 their abilities to reflect the occurrence of anaerobic metabolism in two experimental models of tissu

94 Bacteroidetes and a functional shift towards anaerobic metabolism, including degradation of complex b

95 nt for anaerobic growth and demonstrate that anaerobic metabolism influences virulence of P. aerugino

96 demonstrate that the switch from aerobic to anaerobic metabolism is brought about by changes in the

97 J- or U-shaped metabolism-speed curves; (ii) anaerobic metabolism is involved at all swimming speeds

98 erichia coli, the switch between aerobic and anaerobic metabolism is primarily controlled by the fuma

99 CO(2)/ O(2) did not only reflect the ongoing anaerobic metabolism; it was confounded by the effects o

100 Products of bacterial anaerobic metabolism, like butyrate and other short-chai

101 ional activation under hypoxia that leads to anaerobic metabolism may need to be fine-tuned.

102 R and involving a switch between aerobic and anaerobic metabolism, may be key for survival.

103 Consequently, anaerobic metabolism must substitute oxygenase-catalyzed

104 Anaerobic metabolism of alphaKG/ASP also mitigated the l

105 Anaerobic metabolism of amino acids, carbohydrates and l

106 l mammalian cells with increased reliance on anaerobic metabolism of glucose to lactic acid even in t

107 ggest that energy is derived via aerobic and anaerobic metabolism of imported sugar in im white tissu

108 athway provides the critical missing link in anaerobic metabolism of l-carnitine to TMA, enabling inv

109 Furthermore, MGF inhibited anaerobic metabolism of pyruvate to lactate but enhanced

110 ate formate lyase (PFL), which catalyzes the anaerobic metabolism of pyruvate, is irreversibly inhibi

111 During these times, the anaerobic metabolism of the glycogen, by the epithelial

112 The first step in the anaerobic metabolism of toluene is a highly unusual reac

113 medium led to an upregulation of a number of anaerobic metabolism pathways.

114 al exercise, based on lack of achievement of anaerobic metabolism (peak respiratory quotient </=1.05)

115 RQ) and chlorophyll fluorescence (DCA-CF) on anaerobic metabolism, physiological storage disorders an

116 um responses at suboxic concentrations where anaerobic metabolisms predominate.

117 very to myocytes is minimal with ineffective anaerobic metabolism predominating.

118 not identify arcB, or any genes involved in anaerobic metabolism/regulation.

119 Therefore, proteins involved in anaerobic metabolism represent potentially important tar

120 oretical maximum rate of biomass production, anaerobic metabolism requires import of additional compo

121 and hypoxic, with an increased dependence on anaerobic metabolism, requiring increased energy substra

122 Greater anaerobic metabolism resulted in lower ethylene producti

123 sate with inadequate oxygen delivery induced anaerobic metabolism, resulting in suboptimal DCD heart

124 of volume-responsiveness, the indicators of anaerobic metabolism should be considered instead of cen

125 While all fuels were susceptible to anaerobic metabolism, special attention should be given

126 arate and nitrate reduction), a regulator of anaerobic metabolism that represses transcription of spa

127 t under neutral pH conditions resting muscle anaerobic metabolism, the rate of the creatine kinase re

128 s and radical-based mechanisms that optimize anaerobic metabolism; therefore, committed anaerobes hav

129 share a common core of genes related to the anaerobic metabolism, they differ in terms of ROS-relate

130 of their hosts, these parasites use unusual anaerobic metabolism - this requires rhodoquinone (RQ),

131 n activity was closely tied to S. oneidensis anaerobic metabolism through specific extracellular elec

132 hat an oxygen-sensitive RBP cluster controls anaerobic metabolism to confer hypoxia tolerance.

133 Birds, on the other hand, frequently rely on anaerobic metabolism to exploit prey-rich depths otherwi

134 tral venous oxygen saturation and markers of anaerobic metabolism to predict whether a fluid-induced

135 lting from the tumor's excessive reliance on anaerobic metabolism) to and from the microvessels, and

136 le hypoxia also generate neuronal ATP via an anaerobic metabolism, we studied the changes in cerebral

137 revealed that genes likely to be involved in anaerobic metabolism were upregulated during aerobic gro

138 d lactate production (J(Lac); i.e., index of anaerobic metabolism) were measured by using physiologic

139 Lactic acid levels, which are a measure of anaerobic metabolism, were found to be > 3 times higher

140 pH and Pco2, indicators of anaerobic metabolism, were plotted against tissue Po2.

141 sociated with stress-responsive proteins and anaerobic metabolism, whereas gene families related to b

142 tion, and is paralleled by the activation of anaerobic metabolism, which collectively impair contract

143 a result of a coordinated shift to enhanced anaerobic metabolism, which provides an energy source ou

144 a capacity for both aerobic respiration and anaerobic metabolism with concomitant hydrogen productio