ライフサイエンスコーパス: radicle

1 l polarity, and endogenous initiation of the radicle.

2 nd in the micropylar tissues surrounding the radicle.

3 tion after germination, the emergence of the radicle and lateral roots, and the transition to floweri

4 mpleted following enhanced growth within the radicle and lower axis.

5 pounds 1 and 3 showed inhibition against the radicle and plumule elongation of rice and lettuce seeds

6 a(+)/K(+) transporter, was restricted to the radicles and was not enhanced by NaCl or ABA.

7 get PXMT1 are predominantly expressed in the radicle, and the expression patterns of the two genes ar

8 sA and fengycin stimulate the development of radicles, and fengycin alone stimulate the growth of adu

9 he endosperm cap and radicle tip, and in the radicle appears as a distinct band possibly associated w

10 nsplanted cells were observed in portal vein radicles, as well as in liver sinusoids, albeit integrat

11 ferently within cotyledons and the hypocotyl/radicle axis in embryos of the oilseed crop Camelina sat

12 In optimal conditions, radicle cell divisions occur only after the completion o

13 eudicot seeds the endosperm surrounding the radicle confers coat dormancy and controls germination r

14 re seeds but accumulated specifically in the radicle cortex during and after germination.

15 control growth, such as the embryonic root (radicle) during seed germination, is a fundamental quest

16 ecause of impediment of the mutant testae to radicle egress.

17 completion of germination is blocked by ABA, radicle elongation and cell divisions occurred in these

18 e balance between the two opposing forces of radicle elongation and mechanical resistance of the endo

19 level of SHAM + CN but inhibited subsequent radicle elongation, thereby decreasing germination when

20 ations of osmoticum and measuring subsequent radicle elongation.

21 l components that reflect the future site of radicle emergence and abundant heteromannan.

22 oM abscisic acid, which delayed or prevented radicle emergence but not endosperm cap weakening.

23 ty contributes to the temporal regulation of radicle emergence in endospermic seeds by altering the m

24 (Lycopersicon esculentum) seeds just before radicle emergence through this tissue to complete germin

25 pression of LeEXP4 was not reduced, although radicle emergence was inhibited.

26 Completion of germination (radicle emergence) by gibberellin (GA)-deficient (gib-1)

27 ssed in tomato endosperm cap tissue prior to radicle emergence, we found no evidence that they were d

28 ciated with endosperm cap weakening prior to radicle emergence, whereas LeMAN1 mobilizes galactomanna

29 ndosperm cap tissue of tomato seeds prior to radicle emergence, whereas LeMAN1 was expressed only in

30 SeedGerm could match specialists' scoring of radicle emergence.

31 m cap', and is specifically activated before radicle emergence.

32 ycopersicon esculentum Mill.) seeds prior to radicle emergence.

33 ute to tissue weakening that is required for radicle emergence.

34 ight dependent and limited to the process of radicle emergence.

35 xpressed only in the lateral endosperm after radicle emergence.

36 y abundant in the micropylar region prior to radicle emergence.

37 ntrol embryo growth, endosperm breakdown and radicle emergence.

38 that a critical embryo size was required for radicle emergence.

39 germinated under controlled conditions up to radicle emergence.

40 nation, coincident with the emergence of the radicle from the seed coat.

41 icted that the outer cotyledon and hypocotyl/radicle generate the bulk of plastidic reductant/ATP via

42 vealed their enrichment within the embryonic radicle, identifying the presence of a decision-making c

43 hiza, a sheath-like organ that surrounds the radicle in grass embryos, performs the same role in the

44 fference between hepatocytes and portal vein radicles, intrasplenically transplanted cells were distr

45 cell wall extensibility changes in both the radicle itself and in the micropylar tissues surrounding

46 Radicle meristem activation and extension can therefore

47 tants complete germination in the absence of radicle meristem activation and growth.

48 soids, along with attenuation of portal vein radicles on angiography.

49 ed for the outer cotyledon and the hypocotyl/radicle only.

50 tribution patterns, e.g., in the cotyledons, radicle, or testa.

51 artments CAP (micropylar endosperm) and RAD (radicle plus lower hypocotyl).

52 Radicle protrusion from tomato (Lycopersicon esculentum

53 all loosening of the endosperm necessary for radicle protrusion from tomato seeds and in subsequent e

54 ring seed development and remained high when radicle protrusion was blocked by abscisic acid (ABA), w

55 nd weakening in the endosperm cap leading to radicle protrusion, and jasmonate is involved in the sig

56 by enabling embryo cell expansion leading to radicle protrusion, as well as endosperm weakening prior

57 is resistant to external ABA at the stage of radicle protrusion.

58 associated with endosperm cap weakening and radicle protrusion.

59 Upward orientation of the micropyle/radicle reduced the number of graviresponding roots to a

60 tly highlight the fates of the endosperm and radicle: senescence and growth, respectively.

61 glycerols was observed within the embryo and radicle, showing correlation with the heterogeneous dist

62 on was attained by day 5, but with a shorter radicle size.

63 s C/60 % RH from day 3, yielding the longest radicle size.

64 of several module (cotyledon, hypocotyl, and radicle)-specific factor-DNA interactions has been explo

65 , and -237 to -231 were found to orchestrate radicle-specific repression.

66 arated from other hepatocytes in portal vein radicles that failed to exhibit bile canalicular reconst

67 in the micropylar endosperm cap covering the radicle tip and subsequently in the remaining lateral en

68 it is not responsible for expression in the radicle tip during embryo development.

69 m growth factors is first induced within the radicle tip of the embryo.

70 kening of the endosperm tissue enclosing the radicle tip requires GA.

71 hitinase localized to both endosperm cap and radicle tip tissues.

72 nation predominates in the endosperm cap and radicle tip, and in the radicle appears as a distinct ba

73 ermal lipid gap, which channels water to the radicle tip, from whence it is distributed via embryonic

74 ndosperm in a seed, which is adjacent to the radicle tip, is called the 'endosperm cap', and is speci

75 ses, LeGOLS-1 mRNA was most prevalent in the radicle tip.

76 ly in the endosperm cap tissue enclosing the radicle tip.

77 akening of the endosperm tissue opposite the radicle tip.

78 tems, and distributed computation within the radicle underlies this signal integration mechanism.