ライフサイエンスコーパス: lotus

1 nical properties of droplets, we fabricate a lotus leaf-inspired ZnO-Polydimethylsiloxane (PDMS) supe

2 -Co-C) catalyst mimicking the structure of a lotus pod that addresses these challenges.

3 On US, it has a 'lotus root-like' appearance.

4 i) the superhydrophobic mode, modeled after lotus leaves, and ii) the slippery mode, modeled after t

5 Nelumbo lutea (American lotus), which differs from Nelumbo nucifera (Asian lotus

6 a high-quality reference genome of American lotus for exploring the genetic divergence and variation

7 , we assembled the 843-Mb genome of American lotus into eight pseudochromosomes containing 31 382 pro

8 Furthermore, Hypoxyprobe-1 and lotus lectin co-localization studies showed that develop

9 mpared with maize (3.9), medicago (3.6), and lotus (2.5), suggesting that this silencing is less comp

10 illustrated through the so-called petal and lotus effects.

11 nes, inspired by pitcher plant trichomes and lotus leaves to enable efficient low volume sweat collec

12 rse-chestnut (HRP), water-chestnut (WRP) and lotus-stem starch particles (LRP) and added to the wheat

13 rse chestnut (HSC), water chestnut (WSC) and lotus stem (LSC) were prepared for nano-encapsulation of

14 shows how some hierarchical textures such as lotus leaves lead to reduced pinning, and counter-intuit

15 ts between the genomes of American and Asian lotus and identified 29 533 structural variants (SVs).

16 d deep divergence between American and Asian lotus, and independent domestication affecting seed, rhi

17 w and red petal colors of American and Asian lotus, respectively.

18 , which differs from Nelumbo nucifera (Asian lotus) morphologically, is one of the two remaining spec

19 ough this peptide reacted strongly with both lotus and concanavalin A (ConA) lectins, it bound to lot

20 Combining lotus root-like multichannel carbon nanofibers 'filling'

21 ke different types of persimmon (D. kaki, D. lotus, and D. virginiana) and ebony (e.g., D. ebenum).

22 equences (WGS) from D. kaki, D. oleifera, D. lotus, and D. virginiana were investigated for cT-DNAs.

23 As a result of the designed lotus-pod structure which features an efficient photothe

24 cT-DNA) sequences, for example, in Diospyros lotus.

25 inants in the Caucasian persimmon, Diospyros lotus, a dioecious plant with heterogametic males (XY).

26 tals and gecko foot-inspired adhesive films, lotus and mosquito eye inspired superhydrophobic materia

27 ntigen peptide format, and their avidity for lotus and ConA lectins was tested by surface plasmon res

28 Furthermore, lotus tetragonolobus lectin-negative/p-Creb-positive cys

29 Cdh6(high), lotus tetragonolobus lectin-low (LTL(low)) cells serve a

30 e NnMYB5 induced anthocyanin accumulation in lotus petals.

31 r, carpel thermogenesis and domestication in lotus.

32 egments that lost the differentiation marker lotus tetragonolobus lectin.

33 A novel lotus plumule polysaccharide (LPPS) was purified, charac

34 oute using a water-based extract of Nymphaea lotus leaves as a reducing agent.

35 dered suitable to delay post-cut browning of lotus root slices.

36 ajor constraints for shelf-life extension of lotus root slices.

37 therefore promise to overcome limitations of lotus-inspired surfaces (low durability, insufficient re

38 o genes that are essential for this process: lotus, required for maintaining a connection between the

39 Sacred lotus (Nelumbo nucifera Gaertn.) is a basal eudicot plan

40 Sacred lotus (Nelumbo nucifera) is an ancient aquatic plant of

41 OMTs) involved in BIA biosynthesis in sacred lotus.

42 marily in young leaves and embryos of sacred lotus.

43 ogrammed to evolve into bio-inspired shapes (lotus flowers and shark skins).

44 rvesting affects two congeners known as snow lotus.

45 In the present study, lotus roots slices were treated with 0, 5 and 10 mmol L(

46 al wetting as observed on a superhydrophobic lotus leaf.

47 We find that lotus encodes N-ethylmaleimide sensitive factor 2 (NSF2)

48 ophobic jute inspired by nature, such as the lotus leaf.

49 er plants-is conceptually different from the lotus effect, because we use nano/microstructured substr

50 About 18% of the lotus genome is comprised of Copia LTR retrotransposons,

51 Inspired by the unique structure of the lotus leaf, this study aimed to develop a strategy to co

52 g structures, particularly the leaves of the lotus, have led to the development of liquid-repellent m

53 d concanavalin A (ConA) lectins, it bound to lotus stronger than ConA.

54 fractal dimensions than those on traditional lotus leaf-inspired air-filled porous structures.

55 wealth of phenomena not seen on traditional lotus-leaf-inspired non-wetting surfaces.

56 howed that 10 mmol L(-1) oxalic acid treated lotus slices exhibited reduced browning, superoxide anio

57 nd antioxidant property from edible Zizyphus lotus fruit.

58 itions from a ripe edible fruits of Zizyphus lotus (L.) with an ultrasound-assisted system was achiev