ライフサイエンスコーパス: symmetric division

1 (iii) where both daughters change phenotype (symmetric division).

2 division, or an ISC becoming two EEs through symmetric division.

3 are kept firmly within this plane to give a symmetric division.

4 whose expression accumulates just before the symmetric division.

5 1, a MUTE-induced G1 cyclin, and permits the symmetric division.

6 normally exit the cell cycle through a final symmetric division.

7 top hierarchical HSCs preferentially undergo symmetric divisions.

8 ated concurrently by asymmetric and terminal symmetric divisions.

9 s were present and replaced through periodic symmetric divisions.

10 , glioblasts underwent a prolonged series of symmetric divisions.

11 press neurog1 inside the placode, and apical symmetric divisions amplify the specified pool.

12 e-assisted laser inactivation created a more symmetric division and allowed the survival and differen

13 stem/progenitor-like cell division to favor symmetric division and differentiated into higher levels

14 phorylate Numb in both progenies, leading to symmetric division and expansion of the cancer SC compar

15 he adult SVZ, and the transient increases in symmetric division and neuronal differentiation may resu

16 Intestinal stem cells (ISCs) undergo symmetric division and neutral drift dynamics to renew t

17 divisions where loss of TOE-2 led to a more symmetric division and to survival of the smaller Q.a da

18 tem cells in the inner limbus undergo mostly symmetric divisions and are required to sustain the popu

19 g epidermis, a balance between self-renewing symmetric divisions and differentiative asymmetric divis

20 An initial amplification occurs through symmetric divisions and is followed by a switch to asymm

21 In mes-1 embryos, P(2) and P(3) undergo symmetric divisions and partition germ granules to both

22 elopment, tissue stem cells first expand via symmetric divisions and then switch to asymmetric divisi

23 the capacity to propagate themselves through symmetric divisions and to divide asymmetrically to enge

24 limited tumor-propagating capacity, undergo symmetric division, and are sensitive to castration.

25 ular zone, differentiated astrocytes undergo symmetric division, and their progeny integrate function

26 ocal activation leads to faster, deeper, and symmetric division as equatorial forces dominate.

27 xpansion in number and have reduced rates of symmetric division as well as reduced insulin signaling.

28 These precursors undergo nonapical symmetric division at the laminar location where mature

29 precursor cell identity that leads to extra symmetric divisions at the end of the cell lineage.

30 matal patterning by permitting only a single symmetric division before stomata differentiate.

31 re that, contrarily to other eukaryotes with symmetric division, budding yeast keeps the nascent tran

32 showing TuJ1 immunoreactivity in cells with symmetric division but not cells with asymmetric divisio

33 olon stem cells (ISCs) predominantly undergo symmetric division but turn on asymmetric division to cu

34 A;1, with medium levels being sufficient for symmetric divisions but high levels being required for f

35 We demonstrate how symmetric divisions can work to stabilize paw epidermis

36 rsity and epithelial stratification, whereas symmetric divisions contribute to tissue growth, spreadi

37 quiring mutations that permit asymmetric and symmetric division, converting the host immune attack to

38 cell precursors (GCPs) undergo predominantly symmetric division during postnatal development; (2) clo

39 Thus, control of symmetric division, essential for neuroepithelial stem c

40 that superficial cells renew their number by symmetric division, express mesenchymal stem cell marker

41 celerated division rates and predominance of symmetric division fates.

42 rating zone of the Arabidopsis root, regular symmetric divisions give rise to patterns of parallel fi

43 These mirror-symmetric divisions have powerful morphogenetic influenc

44 Furthermore, these mirror-symmetric divisions have powerful morphogenetic influenc

45 testinal progenitor cells and promotes their symmetric division in response to nutrients, defining a

46 growth in the heart, decreased proliferative symmetric divisions in brain neural progenitors, and inc

47 epidermis, depletion of Bcam or Xiap induced symmetric divisions in neighboring wild-type cells.

48 e TONNEAU1a (TON1a) gene display misoriented symmetric divisions in the epidermis and have no divisio

49 ocytes frequently exit the cell cycle before symmetric division into daughter cells, leading to polyp

50 ped fission yeast Schizosaccharomyces pombe, symmetric division is achieved through anillin/Mid1-depe

51 itiated cell capable of clonal expansion via symmetric division is predicted to occur with a frequenc

52 We discover that the symmetric division is slower than the asymmetric divisio

53 oard pattern), yet only if the proportion of symmetric divisions is sufficiently low.

54 ell is reduced coincident with the number of symmetric divisions it must perform.

55 rd cells of a stoma are produced by a single symmetric division just before terminal differentiation.

56 orientation is orthogonal to cell polarity, symmetric division occurs.

57 fferentiating stem cells are replaced by the symmetric division of adjacent stem cells.

58 C5aR1 inhibition reducing proliferation and symmetric division of apical neural progenitors in human

59 We show limited, life-long, symmetric division of cardiomyocytes as a rare event tha

60 achinery, other prerequisites for successful symmetric division of cardiomyocytes, such as the contro

61 toreceptors of the same type are produced by symmetric division of dedicated precursors.

62 2A family protein phosphatases, promotes the symmetric division of fission yeast cells through spatia

63 , we found that loss of Neur activity causes symmetric division of GMC-1 into two RP2s.

64 te GMC-1 causes mis-localization of Insc and symmetric division of GMC-1 to generate two RP2s.

65 central position of the spindle and ensures symmetric division of mouse zygotes.

66 ic division at both poles of the cell and by symmetric division of the endospores at an early stage o

67 raction with the SCMC and their roles in the symmetric division of the zygote in early mouse developm

68 h-frequency stimulation of the ATN increases symmetric divisions of a defined class of neural progeni

69 ike cells in the dentate gyrus but increases symmetric divisions of an early progenitor cell class.

70 cell cycle duration in the cortex and during symmetric divisions of epidermal cells was constant and

71 its adult body plan through the bilaterally symmetric divisions of mesodermal proteloblast DM'' and

72 and NUMB(+) cells, indicating an increase in symmetric divisions of putative cancer stem cells.

73 In contrast, in symmetric divisions, old and young centrosomes are thoug

74 radioresistance, a shift from asymmetric to symmetric division or a fast cycle of GSCs following fra

75 n how they respond to the signals that guide symmetric division orientation during patterning might p

76 , defining the abembryonic pole, forms where symmetric divisions predominate.

77 ve neurogenesis during favorable conditions, symmetric divisions prevent premature neurogenesis while

78 regulates this asymmetry, as when inhibited, symmetric divisions producing two neurogenic progenitors

79 nd notable regional differences, in terms of symmetric division ratio, have been noted-higher in thic

80 cleavage orientations produce asymmetric and symmetric divisions, respectively.

81 JZ stem cells tend to self-renew by planar symmetric divisions, respond to masticatory stresses, an

82 ed that less than 10% of radial glia undergo symmetric divisions resulting in two radial glia, wherea

83 NE cells undergoing proliferative, symmetric divisions retract their basal processes, and b

84 In addition to multiple, synchronous, and symmetric divisions, single-sorted CD34(+)/CD38(-) cells

85 ible explanation is that daughter cells of a symmetric division subsequently adopt differing cell fat

86 tem-cell-like precursor followed by a single symmetric division that creates paired guard cells surro

87 ng divisions but were more likely to undergo symmetric divisions that expanded the oRG population, as

88 nt canonical Wnt/beta-catenin signaling, and symmetric divisions that increase the seam cell number.

89 Before symmetric division, the transcriptional regulator RNT-1(

90 x2 levels in individual blastomeres promotes symmetric divisions, thereby allocating more cells to th

91 maize leaf epidermis, without affecting the symmetric divisions through which most epidermal cells a

92 Stem cells switch between asymmetric and symmetric division to expand in number as tissues grow d

93 upted epithelial cell polarity, and enhanced symmetric division to expand the stem cell population.

94 is, guard mother cells undergo a stereotyped symmetric division to form the guard cells of stomata.

95 of surrounding support cells, which undergo symmetric division to produce two hair cell daughters.

96 , while persisting HSCs expanded, undergoing symmetric divisions to create identical siblings and for

97 Neural progenitors can undergo symmetric divisions to expand cell population or asymmet

98 her show that human OPCs undergo consecutive symmetric divisions to exponentially increase the progen

99 division, as well as seam cell gains through symmetric divisions towards the seam cell fate were obse

100 sis via a combination of apoptosis, terminal symmetric division via Prospero, and a switch to gliogen

101 However, stem cells are also capable of symmetric division where both daughters remain stem cell

102 After an initial phase of symmetric divisions which causes an increase in their ow

103 ropose that this dynamic mechanism maintains symmetric divisions while allowing the quick adjustment

104 visions of MGE progenitor cells, followed by symmetric divisions within the subventricular zone.