ライフサイエンスコーパス: bioconversion

1 n of chemicals and biopolymers via microbial bioconversion.

2 y of these prodrugs is, in part, due to poor bioconversion.

3 ential to perform many industrially relevant bioconversions.

4 s of genome organization, numerous genes for bioconversion, a preliminary insight into regulation of

5 that a minor reaction of ALDH2-catalyzed GTN bioconversion, accounting for about 5% of the main clear

6 ys, Northern blotting, Western blotting, and bioconversion analysis of erythromycin intermediates.

7 tylU reduced tylosin yields by about 80% and bioconversion analysis with the resultant strain reveale

8 asingly adopted for swine manure value-added bioconversion and pollution control, but few studies hav

9 operations including microbial fermentation, bioconversion and product recovery techniques.

10 GT708A6 can also O-glycosylate flavanones in bioconversion assays in Escherichia coli as well as by i

11 ty was characterized by in vitro and in vivo bioconversion assays.

12 can be hydrolyzed into maltose for trehalose bioconversion by enzymatic methods.

13 We show here that bioconversion by mitochondria of clinically relevant con

14 vailable to cover the large diversity of BTP bioconversions by the gut microbiota.

15 There, they can undergo a wide range of bioconversions by the resident colonic microbiota but ca

16 ow phenotypic variation in gut microbial BTP bioconversion capacity relates to gut and cardiovascular

17 ritional phenotypes related to gut microbial bioconversion capacity.

18 The bioconversion efficiency of yellow maize beta-carotene t

19 The calculated bioconversion factor was 10.4 mug beta-carotene equivale

20 cessary tools for the evolution of microbial bioconversion into a key unit operation in future bioref

21 ting macroalgae (seaweeds) as feedstocks for bioconversion into biofuels and commodity chemical compo

22 toward the utilization of hemicellulose for bioconversion into cellulosic biofuels have resulted in

23 b) and their (R)-enantiomers to see if their bioconversion is affected by BChE inhibition in the same

24 anediol and related compounds from the crude bioconversion mixtures was developed.

25 is illustrated by reference to a particular bioconversion, namely the Baeyer-Villiger oxidation of b

26 een used for the investigation of the indene bioconversion network expressed in Rhodococcus sp. KY1.

27 We demonstrate this method in the indene bioconversion network of Rhodococcus modified for the ov

28 oxylase (i.e., CYP27B1), leading to enhanced bioconversion of 25-hydroxyvitamin D(3) (25D(3)) to its

29 t by itself to induce CYP27b1 and subsequent bioconversion of 25-hydroxyvitamin D3 (25D3) into bioact

30 ly affect erythropoiesis, heme biosynthesis, bioconversion of ALA to PPIX, and porphyrin-mediated pho

31 orans is an emerging model bacterium for the bioconversion of algal biomass.

32 ine oxidation, a catalytic mechanism for the bioconversion of amino pyrrolnitrin into pyrrolnitrin wa

33 estrogen throughout their lives through the bioconversion of androgens by the aromatase enzyme in go

34 in prostate-derived cell lines parallels the bioconversion of androstanediol to DHT.

35 ive selection method for mutations affecting bioconversion of aromatic compounds was applied to a mut

36 retinyl palmitate and beta-carotene and the bioconversion of beta-carotene to retinol in humans.

37 esses, making it an attractive candidate for bioconversion of biomass substrates to various bioproduc

38 nt against pathogenic fungi and insects, the bioconversion of chitinous bio waste associated with sea

39 ertheless, chitosan inhibited the intestinal bioconversion of cholesterol and primary bile acids to s

40 Our finding of bioconversion of cis-isomers of lycopene into apo-10'-ly

41 Here, we report the whole-cell bioconversion of citrate to itaconate with enhanced acon

42 ese results underscore the promise of direct bioconversion of CO(2) into fuels and chemicals, which b

43 pening the possibility of electricity-driven bioconversion of CO(2) to commercial chemicals.

44 reptomyces lividans TY24 resulted in in vivo bioconversion of daunomycin to doxorubicin.

45 Recent progress in the measurement of the bioconversion of dietary provitamin A carotenoids to vit

46 ormed by a de novo pathway that involves the bioconversion of GDP-mannose.

47 f UDP-glucose into kanosamine along with the bioconversion of kanosamine 6-phosphate into 4-amino-3,4

48 (e.g. phenolic) compounds can compromise the bioconversion of lignocellulosic biomass to fuels and ch

49 depolymerization serve a crucial step in the bioconversion of lignocellulosic biomass to fuels and ch

50 applicable to enzyme screening for improved bioconversion of lignocellulosic biomass.

51 of hemicellulosic sugars is critical for the bioconversion of lignocellulosics to ethanol.

52 Both transformants brought about the total bioconversion of monophenols at a high concentration (5

53 e, and its fermentation is important for the bioconversion of plant biomass to fuels and chemicals.

54 Economic bioconversion of plant cell wall hydrolysates into fuels

55 ysate (PH) was produced by deep controllable bioconversion of poultry processing leftovers (broiler n

56 Methods to assess the bioavailability and bioconversion of provitamin A carotenoids have advanced

57 The effects of the food matrix on the bioconversion of provitamin A carotenoids to vitamin A,

58 this is the first report to characterise the bioconversion of R-(+)- and S-(-)-limonene by cellular d

59 Pseudomonas, and paves the way for tailored bioconversion of renewable raw materials to MCAE-based b

60 d harvesting methods, and major steps in the bioconversion of seaweed biomass to biofuels.

61 Mouse liver microsome bioconversion of the methamidoxime prodrugs is significa

62 The bioconversion of the prodrug was investigated in vitro a

63 The bioconversion of the S-(-)-isomer was tested on cell per

64 t has only recently become apparent that the bioconversion of traditional dietary sources of beta-car

65 The bioconversion of UDP-glucose into kanosamine along with

66 ded microbial nutrition, strain improvement, bioconversions of statins and beta-lactams, sporulation

67 This study compared the bioconversion process of S-(-)-limonene into limonene-1,

68 and surface of the engulfed substrate in the bioconversion process.

69 e third part, the techno-economic aspects of bioconversion processes are critically reviewed.

70 ould be appropriate for improved, commercial bioconversion processes.

71 endothelial function for specific microbial bioconversion products.

72 on of saccharolytic enzymes before microbial bioconversion remain economic barriers to industrial dep

73 Here we introduce a new bioconversion scheme that effectively converts syngas, g

74 ent, albeit limited, flexibility as shown by bioconversion studies with unnatural substrates.

75 In addition, this bioconversion system does not require the use of buffers

76 Our bioconversion system suggests very high productivity for

77 Using this whole-cell bioconversion system, we were able to catalyze the conve

78 antify beta-carotene bioavailability and its bioconversion to retinol at physiologically relevant dos

79 lysates and metabolic engineering to develop bioconversions using LA as a feedstock.

80 /micropore size distributions decrease after bioconversion, while the accessible micropore size distr