ライフサイエンスコーパス: cuprous

1 sults indicate that at least with respect to cuprous and ferrous ions, Fet3p can be considered a meta

2 ory, and it is electronically described as a cuprous bis(benzoquinonediimine) species.

3 e chemical nuclease bis(1,10-phenanthroline) cuprous chelate [(OP)(2)Cu(+)] to the ORN and demonstrat

4 A cuprous chelate bearing a secondary sphere hydrogen bond

5 The neocuproine cuprous chelates are novel transcription inhibitors beca

6 ally cleaved by the redox active tetrahedral cuprous chelates of 1,10-phenanthroline and its derivati

7 Redox-inert, tetrahedral cuprous chelates of neocuproine (2,9-dimethyl-1,10- phen

8 Although these cuprous chelates of neocuproine bind at multiple sites w

9 for SNOHb that uses carbon monoxide (CO) and cuprous chloride (CuCl)-saturated Cys.

10 in the presence of a 6-fold molar excess of cuprous chloride under reduced conditions.

11 of 5 microM for the 2:1 5-phenylneocuproine cuprous complex ((5 phi NC)2Cu+) in runoff transcription

12 Cuprous copper [Cu(I)] is an essential cofactor for enzy

13 Cu(2+)) ion binding and its reduction to the cuprous (Cu(1+)) form.

14 A source of damage to Fe-S clusters is cuprous (Cu(1+)) ions.

15 Characterizations revealed the presence of cuprous, cupric, ferrous, and ferric ions in the CP mine

16 The active cuprous FGE complex was interrogated directly by X-ray a

17 Copper first needs to be reduced to the cuprous form, most likely by Steap proteins on the apica

18 Cuprous halides, characterized by a direct wide band-gap

19 n growing a single-crystal epitaxial film of cuprous halides.

20 Cuprous hydride (CuH) and cuprous hydroxide (CuOH) are p

21 trahedral complexes including a boron-capped cuprous hydride.

22 Cuprous hydride (CuH) and cuprous hydroxide (CuOH) are proved to exist in solid fo

23 e the single crystal epitaxy of high quality cuprous iodide (CuI) film grown on Si and sapphire subst

24 A degenerate p-type conduction of cuprous iodide (CuI) thin films is achieved at the iodin

25 Cuprous iodide and potassium iodide may be added to tabl

26 Afterward, the redox reaction generated cuprous ion (Cu(+)) works as a CDT agent for *OH generat

27 dentical tridentate core structure where the cuprous ion binds to the bispicolylamine (L) fragment.

28 urface of the small intestinal microvilli as cuprous ion by Ctr1.

29 gree to which the D-group interacts with the cuprous ion center.

30 nuclear complexes 11b and 11c, rendering the cuprous ion in a trigonal planar ligand environment of t

31 ygen turnover, and with the suggestions that cuprous ion is the valence state of intracellular copper

32 This result indicated that the apparent cuprous ion toxicity was not due to excess intracellular

33 tal-bound CusB is required for activation of cuprous ion transfer from CusF directly to a site in the

34 es specifically to Fet3p reactivity with the cuprous ion.

35 sights into not only the binding of multiple cuprous ions by metallochaperones but also protein-assoc

36 pplied toward the wound dressing electrodes, cuprous ions intercalated more into the hybrid PVA gel/P

37 pectroscopy, indicates the presence of bound cuprous ions, trigonally coordinated by thiolate ligands

38 is electrochemical production of micromolar cuprous ions, which mediated reduction of oxygen to hydr

39 of the electrochemical method to investigate cuprous oxidase activity and to understand the physiolog

40 ributes to copper resistance not only by its cuprous oxidase activity but also by chelation of copper

41 bility allows us to attribute this wave to a cuprous oxidase activity displayed by the laccase and in

42 CueO from Escherichia coli to have a robust cuprous oxidase activity, severalfold higher than any ho

43 As a defense strategy, the cuprous oxidase CueO is secreted into the periplasm to o

44 t3p that define it as both a ferroxidase and cuprous oxidase.

45 th two coppers that cycle through cupric and cuprous oxidation states.

46 ate the Met-rich domain is not essential for cuprous oxidation, but it facilitates Cu+ recruitment fr

47 y and sole substrate-binding active site for cuprous oxidation.

48 Cuprous oxide ([Formula: see text]) has recently emerged

49 Improving the stability of cuprous oxide (Cu(2) O) is imperative to its practical a

50 of oxidation states, from metallic copper to cuprous oxide (Cu(2)O) and cupric oxide (CuO), in additi

51 trategy is demonstrated using small (3-6 nm) cuprous oxide (Cu(2)O) colloidal nanocrystals (NC), solu

52 Cuprous oxide (Cu(2)O) is a promising material for solar

53 Among the various metal oxides, cuprous oxide (Cu(2)O) is regarded as a promising materi

54 Cuprous oxide (Cu(2)O)-based catalysts present a promisi

55 gation on the conduction mechanism in p-type cuprous oxide (Cu2O) thin films is performed based on an

56 lize charged impurities in the semiconductor Cuprous Oxide - an effect we call purification.

57 e report earth-abundant embedded aluminum in cuprous oxide antenna-reactor heterostructures that oper

58 Cuprous oxide as an inorganic semiconductor that was epi

59 opper(I) compounds with oxygen and hydrogen, cuprous oxide Cu(2)O is the only one stable and the best

60 carriers and increases optical absorption in cuprous oxide for selective carbon dioxide conversion to

61 Cuprous oxide in DMF was found to be the optimal catalys

62 that Cu vacancies in the growing islands of cuprous oxide inhibit water adsorption in the centers of

63 A stoichiometric, less stable cuprous oxide likely exists at island edges (the growth

64 hemistry is used to prepare small, colloidal cuprous oxide nanocrystals and to control their surface

65 vertically oriented zinc oxide nanowires and cuprous oxide nanoparticles.

66 surrounded by a film constructed from p-type cuprous oxide nanoparticles.

67 to a micrometer have indeed been observed in cuprous oxide semiconductors.

68 xidation of a metal in a reduced form (e.g., cuprous oxide) to a higher oxidation state.

69 loyed as an electrocatalyst and as part of a cuprous oxide-based photocathode.

70 lementary-tagged receptors were treated with cuprous phenanthroline to establish disulfide bonds betw

71 ction of O(2) to a precooled solution of the cuprous precursor [1]B(C(6)F(5))(4) (-135 C, 2-methyltet

72 es; Mes: mesityl) or by transmetalation with cuprous precursors from the corresponding deprotonated l

73 cture tests, we discover that the low-valent Cuprous-S(1)N(3) moiety acts as an active center during

74 These attributes of cuprous selenide are now integrated with a one-dimension

75 Cuprous selenide nanocrystals have hallmark attributes,

76 op elongation experiments always favored the cuprous site.

77 le oxygen consumption was also observed when cuprous SOD but not cupric SOD was added to a H(2)O(2) s

78 le in the bulk only above ca. 100 degrees C, cuprous sulfide nanocrystals of ca. 7 nm diameter and a

79 Here, we show the tunable preparation of cuprous sulfide nanocrystals ranging in internal structu

80 f the Cu(II) superoxo species are metastable cuprous superoxo [LCu(I)(O(2)(*-))](+) complexes.

81 an further induce metal-ligand coordination (cuprous-thioether).

82 The cuprous-thiolate cluster in Cox17 is substantially more

83 ervation that it binds copper as a binuclear cuprous-thiolate cluster.