ライフサイエンスコーパス: thallus

1 ia which live in symbiosis within the lichen thallus.

2 dulates gemmae and rhizoid production in the thallus.

3 ems define the overall shape and form of the thallus.

4 photosynthetic cells that make up the lichen thallus? 2) Are the multiple group I introns in the lich

5 the production in both vegetative structure (thallus) and fruiting body (apothecia) of anthraquinones

6 from two adjacent meristems that develop at thallus apices.

7 iform with respect to the developing rhizoid-thallus axis during the formation of the axis, and no in

8 nidirectional blue light directs the rhizoid-thallus axis in the apolar zygotes of Fucus and Pelvetia

9 inic irradiance perpendicular to one side of thallus cross sections of the aquatic macrophyte Fucus v

10 around the thallus edge, highlighted during thallus development.

11 oducing insoluble compounds with a melanised thallus dominate.

12 cation of a margin tissue running around the thallus edge, highlighted during thallus development.

13 Fucoid zygotes establish a rhizoid-thallus growth axis in response to environmental signals

14 g that this model is insufficient to explain thallus growth.

15 gh common knowledge dictates that the lichen thallus is formed solely by a fungus (mycobiont) that de

16 Marchantia polymorpha and suggests that the thallus is likely to have zones with specialized functio

17 rmally develop a rhizoid from one pole and a thallus meristem from the other, addition of exogenous a

18 to various marine habitats, evolving diverse thallus morphologies and gamete types.

19 Our evidence indicates that thallus oil body cells, similar to the terpenoid-contain

20 ht (DW), but concentrations differed amongst thallus parts.

21 in vivo with 3-mercaptopicolinic acid (MPA), thallus photosynthesis decreased by 70% and became sensi

22 ment of fungal fruiting bodies from a hyphal thallus represents a transition from simple to complex m

23 the growth rate distributions that generate thallus shape given growth suppression at the apex.

24 deling to determine what regulates liverwort thallus shape in Marchantia polymorpha.

25 The mt(+/-) thallus strain released diploid biflagellate zoids, with

26 carrying the mt(-) and mt(+) genome (mt(+/-) thallus strains).

27 On the thallus surface and in the apoplast, iodide detoxifies b

28 orus (P) and nitrogen (N) deposited onto the thallus surface.

29 lved a "yeast" life cycle with a unicellular thallus that reproduces by budding, and many of the gene

30 The thallus tips of charophytes exhibit saturable IAA influx

31 nsformation efficiency was achieved by using thallus tissue grown under low light conditions.

32 We find that the thallus undergoes a stereotypical sequence of shape tran

33 d phytase activity was readily released into thallus washings.

34 phenotypic innovation (anthraquinones in the thallus) were all significant when testing for state-dep

35 s comprises two cell types, i.e. rhizoid and thallus which are morphogically and cytologically distin

36 age and have a flattened, creeping body (the thallus), which grows from apical cells in an invaginate