ライフサイエンスコーパス: temperate zone

1 of Pooideae out of the tropics and into the temperate zone.

2 common in tropical avifaunas but rare in the temperate zone.

3 compared with a similar area cleared in the temperate zone.

4 e elevationally restricted than those in the temperate zone.

5 nd acute effects on stillbirth risk, even in temperate zones.

6 ion of taxa within the northern and southern temperate zones.

7 lutionary selection in populations living in temperate zones.

8 and in accordance with previous studies from temperate zones.

9 f temperature change on species that inhabit temperate zones.

10 underlying soil is lacking, particularly in temperate zones.

11 into the annual rings formed in trees of the temperate zones.

12 in the tropics rather than heightened in the temperate zones.

13 In the temperate zone, AC has strong potential for climate chan

14 cays with geographic distance fastest in the temperate zone, again consistent with environmental filt

15 ival and recruitment) using 31 datasets from temperate zone amphibian populations (North America and

16 n models based on EF(a) or EF(b) for global, temperate zone and subtropical zone datasets, a power fu

17 (3 FDPs in tropics, 5 in subtropics and 5 in temperate zone) and compared the rates of species discri

18 ytochrome b was particularly variable in the temperate zone, and cytochrome oxidase I was notably mor

19 (Avena sativa), predominate in the northern temperate zone, and it is hypothesized that their radiat

20 Temperate zone animals time the onset of reproductive ev

21 Animals living in temperate zones anticipate seasonal environmental change

22 nal assemblages in the northern and southern temperate zones are less phylogenetically diverse than e

23 hat life history patterns of many species of temperate-zone bats, coupled with sufficiently long incu

24 Tropical and temperate zones both show impacts of glacial cycles, the

25 In the temperate zones, both photoperiod and temperature fluctu

26 iology differs substantially in tropical and temperate zones, but estimates of seasonal influenza mor

27 s can reduce the uncertainty of tropical and temperate zone carbon flux estimates.

28 rn distributions; and colonization routes in temperate zones during postglacial climatic amelioration

29 s of billions of nonhardy insects to exploit temperate zones during summer represent a sink from whic

30 ore subject to invasion; the latest Cenozoic temperate zones evidently received more invaders than th

31 er genus (surrogates of clades) peaks in the temperate zone for both families contrasting with data f

32 r N demands, limits the productivity of many temperate zone forests and in part determines ecosystem

33 or the utilization of this tropical grass in temperate zone grain and bioenergy production.

34 richness is much higher in tropical than in temperate zone habitats.

35 The reason why many immigrant children in temperate zones have vitamin D deficiency is unclear.

36 vation has expanded greatly from tropical to temperate zones; however, its sensitivity to chilling of

37 bad, India, and Sri Lanka) and two from more temperate zones in the north (Nepal and Burma).

38 dity in tropical regions; however, unlike in temperate zones, influenza in the tropics is not strongl

39 increases significantly more closely than in temperate-zone montane species.

40 ll tropical hypervolume, indicating that the temperate zone permits a wider range of trait combinatio

41 are largely based on studies of short-lived, temperate-zone plants.

42 rus are globally distributed in tropical and temperate zones, providing the opportunity for CHIKV to

43 quivalent in magnitude to those in the north temperate-zone regions, and are in fact far greater than

44 assic case of maladaptation by an inflexible temperate zone society extending into the arctic and col

45 Temperate-zone species have responded to warming tempera

46 operiod is an environmental cue used by many temperate-zone species to regulate their reproductive ti

47 warming temperatures even more strongly than temperate-zone species, but this prediction has yet to b

48 responses of tropical species with those of temperate-zone species, finding that average upslope shi

49 of tropical clades and their entry into the temperate zone suggest that OTT events are rare on a per

50 hically restricted species to persist in the temperate zone, suggesting that past differences in geog

51 certain regions, especially islands and the temperate zone, suggesting that species-rich mainland an

52 fungal diversity is significantly higher in temperate zones than in the tropics, with distance from

53 On the basis of studies conducted in the temperate zone, the intake of vitamin D3 needed to maint

54 In temperate zones, the primary environmental cue driving s

55 Located in aggrading stands in the temperate zone, they have provided a strong foundation f

56 ll-sampled faunas that dominated tropical-to-temperate zones to the north and south.

57 imate in shaping demography, particularly in temperate zone tree species with large latitudinal range

58 The data mainly cover top soil and temperate zones, whereas only few data from tropical reg

59 ge (RT) for a long time (>10 years), in warm temperate zones with fine-textured soils, and in soils w

60 should influence the leaf-out strategies of temperate zone woody species, with high winter chilling

61 led sorghum's utilization as a grain crop in temperate zones worldwide.