ライフサイエンスコーパス: higher animal

1 on is critical to goal-oriented behaviors in higher animals.

2 or slow recovery from acute seizures also in higher animals.

3 abundance are important for the survival of higher animals.

4 elopment, and restores the nervous system in higher animals.

5 rol brain development and neuronal wiring in higher animals.

6 releasable reservoir of thrombospondin-1 in higher animals.

7 ules play an analogous role to antibodies in higher animals.

8 has not been identified in Drosophila or in higher animals.

9 lmarks of zinc deficiency (ZD) in humans and higher animals.

10 tentions and expectations in the behavior of higher animals.

11 ial for eye development in invertebrates and higher animals.

12 ound in any integrin beta-subunit genes from higher animals.

13 ification and susceptibility to arthritis in higher animals.

14 are characteristically found in Sec tRNA of higher animals.

15 tenance of the female reproductive system of higher animals.

16 chromes c from fungi and plants but not from higher animals.

17 genetic approaches that are not possible in higher animals.

18 ntaining cholesterol homeostasis in cells of higher animals.

19 ntial for the adaptive behaviors observed in higher animals.

20 mark of living systems, from single cells to higher animals.

21 zymatic production of beta-apocarotenoids in higher animals; 2) the occurrence of beta-apocarotenoids

22 In higher animals, a centrally located system has evolved t

23 e-binding proteins (MBP) are both present in higher animals and both are composed of a carbohydrate-r

24 w methods for controlling gene expression in higher animals and in studying the interactions between

25 ts presence in nature from microorganisms to higher animals and plants is attributed to the many func

26 hosphorylation provides most of the ATP that higher animals and plants use to support life and is res

27 tionary connection between the leukocytes of higher animals and their unicellular, protozoan ancestor

28 Scarring is a long-lasting problem in higher animals, and reductionist approaches could aid in

29 onan is an essential polysaccharide found in higher animals as well as in a few pathogenic bacteria.

30 luding mammals, raising the possibility that higher animals can communicate gene-specific silencing i

31 g of lipid phosphate phosphatase 3, which in higher animals can dephosphorylate a range of phospholip

32 MTMR8 has a similar function in autophagy of higher animal cells.

33 Cytochromes c from plants and fungi, but not higher animals, contain methylated lysine residues at sp

34 Complexity in higher animals derives in part from various modalities o

35 homology in smell and taste pathways in all higher animals, experimental approaches in Drosophila wi

36 In mothers, higher animal exposure trends towards a higher number of

37 Higher animal fat and cholesterol intakes were significa

38 subjects may have an impaired adaptation to higher animal fat diets that could result in higher card

39 is more deviant from muscle actin than other higher animal forms, the generality of glycolytic enzyme

40 tor family transporter, homologs of which in higher animals have been shown to transport S1P) can als

41 Many higher animals have evolved the ability to use the Earth

42 few radical SAM-dependent enzymes present in higher animals; however, the enzyme appears broadly cons

43 Antibiotic peptides of higher animals include the defensins, first discovered i

44 accumulate in various organs and tissues of higher animals, including humans, mice, and flies.

45 roception coordinates ingestive processes in higher animals, including humans.

46 Adult body size in higher animals is dependent on the amount of growth that

47 redominant theme seen in the homologues from higher animals is extensive intron loss.

48 (vitamin A) serve two distinct functions in higher animals: light absorption for vision and gene reg

49 coordination of physiological sub-systems in higher animals may be through the direct entrainment of

50 se that this knowledge can inform studies in higher animal models and help to develop treatments to c

51 s and airway epithelial cells could serve as higher animal models to examine the relationships betwee

52 n increased phospholipid unsaturation, as in higher animal models.

53 slices led to faster dilative remodeling and higher animal mortality.

54 The higher rates are associated with higher animal protein and fat, and lower fibre consumpti

55 ry fat intakes and girls aged 6-8 years with higher animal protein intakes became adolescents with ea

56 nce, resemble those of both MAO A and B from higher animals, raising the possibility that it may be a

57 Propagation in higher animals requires the efficient and accurate displ

58 umber of introns found in only one phylum of higher animals result from frequent intron loss, as oppo

59 In addition, reduced insulin signaling in higher animals-rodents and humans-causes glucose intoler

60 iological basis of information processing in higher animals, spiking neural networks must be able to

61 In all higher animals studied, we have found many fewer genes t

62 In higher animals, the structural integrity and functional

63 In higher animals, these membrane proteins participate in a

64 Because FNTs do not occur in higher animals, they are attractive drug targets for man

65 Higher animal-to-plant protein ratio (extreme-quartile H

66 Higher animals typically rely on calcification to harden

67 onserved across all kingdoms of life, and in higher animals viperin is localized to the ER-membrane a

68 In higher animals, viperin expression also accelerates the

69 Moreover, in higher animals, viperin interacts with numerous other ho

70 a soluble cytoplasmic protein, analogous to higher animal visual pigments.

71 oundation for future preclinical research in higher animals, with potential implications on a procedu