ライフサイエンスコーパス: unicellular organism

1 NRKs), an extraordinarily large number for a unicellular organism.

2 genetic machinery similar to those of extant unicellular organisms.

3 nd nuclear processes in multicellular and/or unicellular organisms.

4 l how this protein affects the physiology of unicellular organisms.

5 ittle about the processes behind invasion by unicellular organisms.

6 organism for morphogenesis and patterning in unicellular organisms.

7 ich is among the highest values recorded for unicellular organisms.

8 een the growth rate and the biomass yield in unicellular organisms.

9 ifying potential drug targets, especially in unicellular organisms.

10 rgy buffer in insects, crustaceans, and some unicellular organisms.

11 is a ubiquitous feature of multicellular and unicellular organisms.

12 , is currently limited to cultured cells and unicellular organisms.

13 ound in all sequenced multicellular and many unicellular organisms.

14 c scales and is exhibited by many eukaryotic unicellular organisms.

15 means to manipulate swimming populations of unicellular organisms.

16 mammals containing more methylation than the unicellular organisms.

17 unction is crucial for pathogenesis in these unicellular organisms.

18 ive dynamic phenotypic mosaicism in isogenic unicellular organisms.

19 ther protein leads to hyper-recombination in unicellular organisms.

20 nguishable from the scaling relationship for unicellular organisms.

21 st also be synchronized during the growth of unicellular organisms.

22 there been any evidence for its presence in unicellular organisms.

23 ely little is known about snRNA synthesis in unicellular organisms.

24 As they negotiate their environs, unicellular organisms adjust their swimming in response

25 wth and cell division previously observed in unicellular organisms also exists in intact plant tissue

26 ammals, we investigated the possibility that unicellular organisms also respond to viral pathogens by

27 eless, it biases the orientation of swimming unicellular organisms, alters bone cell differentiation,

28 l. reveals the surprising complexity of this unicellular organism and, by inference, of the last comm

29 ty gradients to be reduced or absent in some unicellular organisms and attribute this to their high a

30 s to why programmes of cell suicide exist in unicellular organisms and how they may be benefit such o

31 until now, miRNAs have not been described in unicellular organisms and it has been suggested that the

32 f all organisms are similar: The lowest (for unicellular organisms and plants) is separated from the

33 te in a process similar to quorum sensing in unicellular organisms and suggest that disruption of thi

34 with the phosphorylation-based repression in unicellular organisms and syncytia.

35 Unicellular organisms are constantly subject to sudden c

36 Unicellular organisms are often used as model systems fo

37 Unicellular organisms are particularly susceptible to en

38 Symbioses between eukaryotes and unicellular organisms are quite common, with examples co

39 However, the situation is more complex in unicellular organisms bearing few flagella.

40 What would be the advantage of unicellular organisms becoming multicellular?

41 In contrast to unicellular organisms, biological and technical variatio

42 coideum are social amoebas that propagate as unicellular organisms but aggregate upon starvation and

43 ses are critical not only to the survival of unicellular organisms but also to the normal function of

44 This selection pressure is apparent in unicellular organisms, but is mitigated in higher eukary

45 impact of expression noise on the fitness of unicellular organisms by considering the influence of su

46 We extend this theory to the realm of unicellular organisms by developing mathematical models

47 Dictyostelium discoideum, a unicellular organism capable of developing into a multic

48 synthesis is dominated by a diverse group of unicellular organisms collectively called microalgae.

49 Cell cycle-dependent morphogenesis of unicellular organisms depends on the spatiotemporal cont

50 cterial pathogen, could replicate within the unicellular organism Dictyostelium discoideum.

51 s of pathogens have thus far been limited to unicellular organisms (e.g., protozoa and bacteria).

52 The sequenced genomes of unicellular organisms encode from approximately 25%, for

53 by duplicate genes), in multicellular versus unicellular organisms enhances genomic functional innova

54 previously described strictly in plants and unicellular organisms, entails post-translational excisi

55 o cilia, some cells, including those of many unicellular organisms, exhibit many cilia.

56 The accessible genetics of this unicellular organism facilitate structure-function analy

57 organisms and in the extracellular fluid of unicellular organisms, has been shown to function as a s

58 Genes of malaria parasites and other unicellular organisms have larger exons with fewer and s

59 Could the transient aggregation of unicellular organisms have paved the way for the evoluti

60 ome healing, has been extensively studied in unicellular organisms; however, its role in the mammalia

61 Unicellular organisms, human cells and mice have provide

62 propriately distinguishing multicellular and unicellular organisms; (ii) eukaryotic sex is extremely

63 In unicellular organisms, initiation is the rate-limiting s

64 her we consider the division of the simplest unicellular organisms into two daughter cells or the gen

65 The discovery of a lamin-like protein in a unicellular organism is not only intriguing in light of

66 The transport of water into and out of unicellular organisms is a seemingly simple process in w

67 Here we show that one mode of IL toxicity on unicellular organisms is driven by swelling of the cell

68 rnative splicing is active and functional in unicellular organisms is less understood.

69 Although it was already active in unicellular organisms, its role became universally impor

70 Many unicellular organisms live in multicellular communities

71 the smallest insects, comparable in size to unicellular organisms, modifications arise not only at t

72 thogens and is the major means by which many unicellular organisms obtain nutrients.

73 Motility of unicellular organisms occurred early in evolution with t

74 of the family Volvocaceae (Chlorophyta) and unicellular organisms of the Volvocales, including Chlam

75 ncluding chemotaxis toward and engulfment of unicellular organisms or cell debris.

76 We define the cellular architecture of a unicellular organism, or of a cell type from a multicell

77 is universal in the sense that it applies to unicellular organisms, plants and animals.

78 Whereas many unicellular organisms possess a small number of DRPs, ex

79 Its discovery, therefore, in unicellular organisms presents compelling questions.

80 tence of two extremes of motor response in a unicellular organism prompts unique investigations of fa

81 We find that unicellular organisms require a smaller degree of contro

82 Unicellular organisms respond to the presence of DNA les

83 Trypanosomatids, unicellular organisms responsible for several global dis

84 osaccharomyces pombe [1-3], but unlike other unicellular organisms, S. pombe has two structurally dis

85 ructures were previously available only from unicellular organisms, speculations regarding the molecu

86 However, in unicellular organisms such as budding yeast, they are no

87 Motile unicellular organisms such as E. coli exhibit rudimentar

88 Motile cilia are found on unicellular organisms such as the green alga Chlamydomon

89 However, in unicellular organisms such as yeast, this process has ra

90 Populations of certain unicellular organisms, such as suspensions of yeast in n

91 In unicellular organisms, such as the budding yeast Sacchar

92 from a single cell, can evolve rapidly in a unicellular organism that has never had a multicellular

93 e locus remains a practice mostly limited to unicellular organisms that afford simple targeting metho

94 Choanoflagellates, unicellular organisms that are closely related to metazo

95 gae constitute a diverse group of eukaryotic unicellular organisms that are of interest for pure and

96 of sexual reproduction cannot be realized in unicellular organisms that reproduce both sexually and a

97 In unicellular organisms the most used codons are optimally

98 roduced living hybrid materials by giving to unicellular organisms the nutrient to grow.

99 al and local synonymous codon biases in many unicellular organisms, this explanation cannot adequatel

100 end, receive, and process information allows unicellular organisms to act as multicellular entities a

101 nctionally and evolutionarily conserved from unicellular organisms to human.

102 We identify that ADF/cofilins from unicellular organisms to humans share a conserved activi

103 iated disorders in short-lived species, from unicellular organisms to laboratory mice and rats.

104 Evolution from unicellular organisms to larger multicellular ones requi

105 ompany the transition from motile totipotent unicellular organisms to multicellular organisms having

106 Unicellular organisms use a variety of mechanisms to co-

107 Unicellular organisms use gradient sensing to move (chem

108 Genes conserved with unicellular organisms were strongly up-regulated, wherea

109 D. discoideum grows as a unicellular organism when food is abundant and switches

110 The existence of TOR homologs in unicellular organisms whose growth is affected by enviro

111 f observations: (i) the rarity of introns in unicellular organisms with large population sizes, and t

112 appeared very early in evolution to provide unicellular organisms with motility in water.

113 In contrast, many unicellular organisms with small nuclear genomes seem to

114 tensive regulated exocytic systems among all unicellular organisms, yet the basis of protein traffick