ライフサイエンスコーパス: aquatic plant

1 s can assist "mate finding," particularly in aquatic plants.

2 edicting bioavailability of nanomaterials to aquatic plants.

3 a decrease of nanoparticle absorption by the aquatic plants.

4 and aquatic plants; or water, sediment, and aquatic plants.

5 ndance reducing light intensity reaching the aquatic plants.

6 s/d) and Mankai green shake (Wolffia globosa aquatic plant) (+800 mg/d polyphenols).

7 nse to interspecific competition between two aquatic plants allows for species coexistence where comp

8 Aquaculture, the cultivation of aquatic plants and animals, has grown rapidly since the

9 posit that the Maya used a diverse array of aquatic plants and other biota to keep water clean in th

10 Biomarkers reveal hominins had access to aquatic plants and protective woods in a patchwork lands

11 urnal cycles caused by the metabolism of the aquatic plants and shows stable and reproducible results

12 ittle is known about the evolution of CAM in aquatic plants and the lack of genomic data has hindered

13 e nonfecal FIB source, beach wrack (decaying aquatic plants), and its impacts on water quality along

14 osystem populated by groundwater-fed rivers, aquatic plants, angiosperm shrublands, and edible plants

15 Here, we explored detection of invasive aquatic plants, animals (vertebrate and invertebrate), a

16 in northern Europe based on macrofossils of aquatic plants are in many cases ca. 2 degrees C warmer

17 Over 15 families of aquatic plants are known to use a strategy of developmen

18 ical microenvironments in the rhizosphere of aquatic plants at high spatiotemporal resolution with a

19 uenced nanomaterial bioavailability to three aquatic plants: Azolla caroliniana Willd, Egeria densa P

20 d waterways and return nutrients captured in aquatic plants back to agriculture with promise of break

21 consequences of nanoplastic accumulation in aquatic plants, but there is no direct evidence for the

22 n and distribution of As was analyzed in the aquatic plant Ceratophyllum demersum to understand As me

23 To address this deficit we studied an aquatic plant community in an ecosystem subject to gradi

24 Vascular aquatic plant diversity may not necessarily enhance wetl

25 eciation and distribution was measured in an aquatic plant, duckweed (Landoltia punctata), exposed to

26 ment for studies of environmental impacts on aquatic plant ecophysiology.

27 d systematic processing of C3/C4 grasses and aquatic plants, gathered from the savannahs and lakes in

28 Duckweed, a sustainable, protein-rich aquatic plant, has recently emerged as a promising sourc

29 Aquatic plants (i.e., helophytes) used in these techniqu

30 abandoned river channel with open water and aquatic plants; (ii) inundated forest swamp; and (iii) r

31 The roots of aquatic plants, including rice, release oxygen into the

32 the potential public health implications of aquatic plant invasions.

33 -group-specific SSDs for algae/cyanobacteria/aquatic plants, invertebrates, and vertebrates for 180 c

34 st in part, the neotenous reduction of these aquatic plants is based on readjusted copy numbers of pr

35 l risk assessment of substances, toxicity to aquatic plants is evaluated using, among other methods,

36 tems, but its influence on interactions with aquatic plants is still unclear.

37 All three silver treatments were toxic to aquatic plants, leading to a significant release of diss

38 experimental evolution, that fitness of the aquatic plant Lemna minor is modified by interactions be

39 We expressed human mAbs in the small aquatic plant Lemna minor, which offers several advantag

40 norhabditis elegans (nematode worm), and the aquatic plant Lemna minuta (least duckweed)).

41 We demonstrate that aquatic plant macrofossil records can provide additional

42 ed the species richness of rooted, submerged aquatic plant (macrophyte) communities in experimental w

43 acred lotus (Nelumbo nucifera) is an ancient aquatic plant of medicinal value because of antiviral an

44 The Lemnaceae family comprises aquatic plants of angiosperms gaining attention due to t

45 surface water; water and sediment; water and aquatic plants; or water, sediment, and aquatic plants.

46 with freshwater sediments and two species of aquatic plants (Potamogeton diversifolius and Egeria den

47 sequenced the transcriptome of the submerged aquatic plant Ranunculus bungei, and two terrestrial rel

48 nlike in land plants, photosynthesis in many aquatic plants relies on bicarbonate in addition to carb

49 We used the decline in aquatic plant richness and cover as an index of ecologic

50 hydr)oxide rind, or Fe plaque, that forms on aquatic plant roots is an important sorbent of metal(loi

51 l questions regarding the biogeochemistry of aquatic plant roots.

52 ding to radiocarbon dating of seeds from the aquatic plant Ruppia cirrhosa.

53 nal traits of native and nonnative submersed aquatic plants (SAP) in an aquatic ecosystem.

54 CWs keep water clean via certain aquatic plants since all plants uptake nutrients (e.g.,

55 course of competitive population dynamics of aquatic plant species over 10-15 generations in the fiel

56 In all terrestrial and aquatic plant species the primary cell wall is a dynamic

57 o globally distributed, ecologically similar aquatic plant species.

58 iploids and synthetic autotetraploids of the aquatic plant Spirodela polyrhiza.

59 nanomaterials and nanomaterial attachment to aquatic plant surfaces.

60 e sampling approach can be adopted for other aquatic plant systems.

61 ecies that have been sequenced and comprises aquatic plants that grow rapidly on the water surface.

62 rassinosteroid-deficient dwarf mutant in the aquatic plant Utricularia gibba with twisted internal ti

63 nvestigate whether AFMK exists in plants, an aquatic plant, water hyacinth, was used.

64 us and Montsechia, open the possibility that aquatic plants were locally common at a very early stage

65 s from aquaculture (excluding the farming of aquatic plants), with a focus on using modern, commercia