ライフサイエンスコーパス: fungal spore

1 e infected flies by dusting the cuticle with fungal spores.

2 dust contamination and possible dispersal of fungal spores.

3 rder to establish a baseline measurement for fungal spores.

4 hogenic implications of infections caused by fungal spores.

5 (Hck), p72(Syk), and p77(Btk) in response to fungal spores.

6 ious disease caused by inhaling Coccidioides fungal spores.

7 uption in the morphological structure of the fungal spores.

8 as house dust mite feces, pollen grains, and fungal spores.

9 ch is comparable to that of volcanic ash and fungal spores.

10 1) expanding local measurement of pollen and fungal spores, (2) increasing the intensity of allergen

11 distributed standardized aerial sampling of fungal spores(3).

12 ecific areas on the nematode's surface where fungal spores adhere preferentially.

13 drophobins have been suggested to facilitate fungal spore adhesion and to direct the action of the en

14 insights into the host factors that mediate fungal spore adhesion.

15 m complex samples, including cell lysates of fungal spores, AFB1-spiked peanut, and wheat samples, by

16 ngal taxa, and biomass allocation between AM fungal spore and hyphal structures; yet a systematic und

17 Pollen, algal, fungal spore and micro-charcoal data from sediments demo

18 acterium tracking and subcellular imaging of fungal spores and hyphae in the rhizosphere.

19 dusts, biological species (pollen, bacteria, fungal spores and plankton), carbonaceous combustion pro

20 permicron particles such as bacterial cells, fungal spores and pollen grains.

21 Airborne biological particles, such as fungal spores and pollen, are ubiquitous in the Earth's

22 and other molds leading to aerosolization of fungal spores and potential exposure for patients.

23 e (ESEM), we observed rupturing of Amazonian fungal spores and subsequent release of submicrometer si

24 ypha and its content, hyphal networks and AM fungal spores - and explore key cellular dynamics.

25 Large bioaerosols can be formed by pollen, fungal spores, and cell debris.

26 ing mite and insect cuticles, pollen grains, fungal spores, and insect eggs.

27 ecially the biological one, i.e., pollen and fungal spores, and what their impact is, or could be, on

28 Finally, to negate discharge of fungal spores, and/or archaeal and/or bacterial cells, c

29 s striking implications for the evolution of fungal-spore- and plant-pollen-profilins as allergens.

30 Fungal spores are abundant in the environment and a majo

31 Furthermore, rupturing of fungal spores at high humidity may explain the bursting

32 'windscapes'-to model potential dispersal of fungal spores at the continental scale and linked them w

33 phages, and endosymbiont removal renders the fungal spores avirulent in vivo.

34 geographic structure in pine-associated ECM fungal spore banks across the North American continent.

35 Similar to plant seed banks, ECM fungal spore banks are, in general, depauperate, and rep

36 owth, the structure of ectomycorrhizal (ECM) fungal spore banks remains poorly understood.

37 th light) sharply reduced the infectivity of fungal spores but did not affect host susceptibility to

38 d is the primary dispersal mechanism of most fungal spores but is rarely considered in studies of fun

39 irst line of host defense upon inhalation of fungal spores by aiding in clearance but can also potent

40 The minimal concentration of fungal spores by air sampling for acquisition of fungal

41 Long-distance dispersal of fungal spores by the wind can spread plant diseases acro

42 ncreases in ambient temperature that amplify fungal spore concentration and pollen season duration, a

43 Fungal spores (conidia) are rapidly ingested by ECs deri

44 al for host survival following inhalation of fungal spores (conidia).

45 The average fungal spore counts per cubic metre of air in the bedroo

46 Nitrogen fertilisation decreased AM fungal spore density (SD), extraradical hyphal density (

47 sists in the plant until head emergence when fungal spores develop and are released from sori formed

48 The role of mammals in fungal spore dispersal is well documented, but the relev

49 nes to contribute to better understanding of fungal spore dispersal, plant disease epidemiology, and

50 unique Raman spectral signatures from intact fungal spores dispersed on commercially available alumin

51 nogaster flies with a standardized amount of fungal spores from clinical Zygomycetes isolates to stud

52 Strategies to efficiently remove fungal spores from hospital surfaces and, ideally, patie

53 ly, we show that this activity also protects fungal spores from phagocytosis and clearance by human m

54 uclear migration, and death of the conidium (fungal spore) from which the infection originated.

55 During fungal spore germination, a resting spore returns to a c

56 rmination medium reduced M. sexta growth and fungal spore germination, respectively.

57 ted forms of phenols, which highly inhibited fungal spore germination.

58 l particles such as pollen, plant parts, and fungal spores, has great utility in forensic geolocation

59 of the trail may be more likely to encounter fungal spores implying a trade-off between resource disc

60 method can be used to trap trace amounts of fungal spores in a peanut extract and complement Fe(3+)-

61 ans to accurately enumerate and localize the fungal spores in the pulmonary tissues.

62 Early epithelial internalization of fungal spores in vivo cannot explain the bronchial/bronc

63 While immunization with live fungal spores induced antibody responses, we found a mar

64 udes a quiescent stage, such as bacterial or fungal spores, insect larvae, or plant seeds.

65 LDD of small particles like fungal spores is often a result of turbulent wind disper

66 Neurospora, meiotic drive can be observed in fungal spore killing.

67 sone treatment does not significantly affect fungal spore killing.

68 dox based on wind-gust aerodynamic models of fungal-spore liberation.

69 stead revealed that the sum of bacterial and fungal spores mass represented only a minor OMCOARSE fra

70 ls consisting of: i) soil samples containing fungal spores of B. bassiana and B. brongniartii in know

71 rom palaeoecological records of coprophilous fungal spores of the formerly more extensive geographica

72 Despite the serious impact of fungal spores on human health, little is known about the

73 Germinated fungal spores on potato dextrose agar were also reduced

74 acing billions of stochastic trajectories of fungal spores over dynamically changing host and environ

75 sion models controlling for weekend days and fungal spores, personal O3 was associated with asthma se

76 nd daily counts of ambient concentrations of fungal spores, pollen, and air pollutants.

77 es between metabolically active and inactive fungal spores remains an important question.

78 Live but not heat-inactivated fungal spores resulted in recruitment of gamma interfero

79 Exposures to several outdoor fungal spore taxa, including some not reported in previo

80 from vegetated areas contained 149% more AM fungal spores than unvegetated areas.

81 osis has shaped the ecology and evolution of fungal spores that are involved in dispersal and coloniz

82 l responses are restricted to challenge with fungal spores that have the potential to germinate and c

83 dynamics of experimental murine exposure to fungal spores, thereby highlighting the potential of mat

84 le dew cycle can disperse copious numbers of fungal spores to other wheat plants, even in the absence

85 , some insects can detect and actively avoid fungal spores to reduce infection risk.

86 ves to create robust protein coats that help fungal spores to resist wetting and thus facilitate thei

87 Key to pathogenesis is the ability of fungal spores to swell, germinate, and penetrate surroun

88 risk to global wheat production, because the fungal spores transmitting the disease can be wind-dispe

89 Control root tips or fungal spores treated with nuclease alone exhibited norm

90 orld environmental measurement data of total fungal spores using Air-o-Cell cassettes in 16 different

91 The limit of detection of the method against fungal spores was as low as ~10(4) spores mL(-1).

92 Large numbers of AM fungal spores were present in the air over the course of

93 Fungal spores were significantly associated with symptom

94 ass spectrometry (SALDI-MS) method to detect fungal spores, which is a critical concern in food safet