ライフサイエンスコーパス: lawn

1 these amoebae and leave an intact bacterial lawn.

2 application to the phage-infected bacterial lawn.

3 ks inscribed as they move through an E. coli lawn.

4 s C. elegans to lay more eggs away from that lawn.

5 ans starts to vacate the pathogenic bacteria lawn.

6 indicated by plaque formation in a bacterial lawn.

7 abitats: low hummock (LH), high lawn and low lawn.

8 , also failed to produce plaques on a mutant lawn.

9 cula of 10(5)-10(6) cells per plate formed a lawn.

10 ofilm matrix as they move through a Yersinia lawn.

11 nd generated the largest plaques on the slyD lawn.

12 mutants of phi X174 were isolated on a slyD lawn.

13 lopment and display slow growth on bacterial lawns.

14 tic environments including thicker bacterial lawns.

15 by high MIC/MBC, and a no inhibition on agar lawns.

16 ncluding low worm density and thin bacterial lawns.

17 nifera) appeared to migrate more easily into lawns.

18 patient's residence, including on manicured lawns.

19 with best growth on membranes over "helper" lawns.

20 thodologies, with emission rates greatest in lawns.

21 igration, forming large plaques on bacterial lawns.

22 bacteria and form plaques in their bacterial lawns.

23 Our LaWN(3) synthesis should inspire growth of other predict

24 tride perovskite lanthanum tungsten nitride (LaWN(3)) in the form of oxygen-free sputtered thin films

25 ion confirm polar symmetry of the perovskite LaWN(3).

26 Solitary foragers move slowly on a bacterial lawn and disperse across it, while social foragers move

27 Lawn and garden pesticide use was associated with breast

28 extent of developed land use and cultivated lawn and gardens around a pond.

29 ferent microhabitats: low hummock (LH), high lawn and low lawn.

30 er, we create well-defined replicates of the lawn and quantitatively study the population expansion o

31 g branches, and having a dry barrier between lawn and woods, tended to increase risk.

32 utant, which does not aggregate on bacterial lawns and arrests as loose mounds on nitrocellulose filt

33 face flows (primarily from overirrigation of lawns and ornamental plants) harbor FIB at concentration

34 uburban neighborhoods (e.g., from forests to lawns and ornamental plants) increase the distribution o

35 Ticks were sampled from lawns and woodlands by dragging flannel over the vegetat

36 types (evergreen trees, deciduous trees and lawn) and (ii) different ages (constructed 10, approxima

37 cea) is a weed naturally found in driveways, lawns, and fields and edible in many regions of Europe,

38 had a specific swarm rate reduction on prey lawns, and thus reduced fitness, compared to an isogenic

39 the dominant lawn fluxes, and the fact that lawns are unlikely to dry out, climate warming may subst

40 All five strains that grew as confluent lawns around Hb discs possessed either 9 or 12 consecuti

41 location, assessed using the plasma membrane lawn assay.

42 y clear circular zones of lysis on bacterial lawns at the site of gamma phage inoculation after incub

43 of sensory neurons to inhibit P. aeruginosa lawn avoidance behaviour through inhibition of the neuro

44 have previously shown promotes P. aeruginosa lawn avoidance behaviour.

45 Higher initial lawn bacterial densities could also contribute to faster

46 ficacy of antibiotics against planktonic and lawn biofilm bacteria.

47 antibiotic-resistant variants that emerge in lawn biofilms after antibiotic treatment.

48 ilver electrodes were overlaid with agar and lawn biofilms grown for 24 h.

49 The ultrastructure changes in the lawn biofilms imaged using transmission electron microsc

50 one and in combination was evaluated against lawn biofilms of bioluminescent strains of Staphylococcu

51 ounds have been shown to eradicate bacterial lawn biofilms through electroceutical treatment.

52 elution and activity against planktonic and lawn biofilms.

53 atment with electroceutical treatment on the lawn biofilms.

54 Specifically, N2 exhibits lawn bordering and roaming behavior on mucoid nonpathoge

55 nts do not aggregate in plaques on bacterial lawns, but they do proceed further in development on nit

56 teria, form visible lesions within bacterial lawns (called plaques), which are employed ubiquitously

57 atives in environmental golf and sustainable lawn care are explored.

58 These results suggest that US lawn care behaviors are more differentiated in practice

59 r yard") to 0.24 (trans-nonachlor and "store lawn care products in garage").

60 ies the framework to the case of residential lawn care.

61 When developing on a bacterial lawn, cells of the mutant strain (dtfA- cells) aggregate

62 On Pseudomonas aeruginosa lawns, cleared plaques were observed with the bacterial

63 1 mutant formed smaller plaques on bacterial lawns compared with those of the WT.

64 onto cellulose-acetate membranes placed over lawn cultures of helper strains.

65 like bison and elephants to generate grazing lawns: dependable sources of sodium.

66 e human kinetochore behaves like a flexible "lawn" despite being nucleated by repeating biochemical s

67 This was based on up-scaled lawn emissions of 1.2-1.5 g CH4 m(-2) , vs. an up-scaled

68 marsh-to-upland transects in both wooded and lawn environments.

69 uipped with a three-way catalytic converter, lawn equipment, utility vehicles, urban buses, semitruck

70 ntinue to lay their eggs away from the dense lawn even after the predator is removed, indicating a fo

71 ubwatersheds of the Mississippi River in St. Lawn fertilizer and pet waste dominated N and P inputs,

72 Two behaviors are examined: lawn fertilizing and irrigating.

73 rong temperature sensitivity of the dominant lawn fluxes, and the fact that lawns are unlikely to dry

74 Why insect control on lawns, golf courses, and sport fields remains insecticid

75 construct pseudomolecules for allotetraploid lawn grass utilizing PacBio long reads in combination wi

76 soil that suppressed brown patch disease of lawn grass.

77 ificantly reduce egg laying behavior off the lawn in both predator-free and predator-inhabited lawns,

78 ental phosphorylation of an NDC80 molecular "lawn," in which the NDC80-MT bonds reorganize dynamicall

79 more, we find that biofilm-forming bacterial lawns including Bacillus subtilis and Pseudomonas aerugi

80 od lawn, the presence of a predator inside a lawn induces C. elegans to lay more eggs away from that

81 microtopographical subunits (sedge-dominated lawns, interhummocks and hummocks) within an aapa mire i

82 at do form when cells are grown on bacterial lawns lack the one- and two-dimensional symmetries so ap

83 on, tax-4-expressing sensory neurons promote lawn-leaving behaviors that are elicited by feeding inhi

84 Others produced lawn-like growth largely devoid of typical microcolonies

85 used extensively in residential settings for lawn maintenance and in homes to control household pests

86 iatric operations attains the magnitude of a lawn mower and peaks resemble a passing truck.

87 ere more likely than controls to have used a lawn mower or brush cutter in the two weeks before the i

88 ndicating an inability to hear a gas-powered lawn mower) received an intracochlear infusion of DB-OTO

89 ak of primary pneumonic tularemia implicates lawn mowing and brush cutting as risk factors for this i

90 Lawn mowing and brush cutting remained significant risk

91 ractive to growers because they often reduce lawn mowing frequencies.

92 entiation involving the formation of a dense lawn of aerial hyphae that grow away from the colony sur

93 often visualized as plaques, or holes, in a lawn of bacteria on an agar-filled Petri dish; however,

94 s of a synthetic sensor kinase that allows a lawn of bacteria to function as a biological film, such

95 short time (3-5 hours) before transfer to a lawn of E. coli.

96 th in batch culture and in patterns across a lawn of engineered cells.

97 myces coelicolor involves the formation of a lawn of hair-like aerial hyphae on the colony surface th

98 mination, and forms far smaller plaques on a lawn of Klebsiella aerogenes.

99 s a large prominent halo around plaques on a lawn of M. smegmatis.

100 Bacillus amyloliquefaciens contaminant in a lawn of N. gonorrhoeae.

101 ing spots of localized transfection within a lawn of non-transfected cells.

102 (OS-Seq), in which we modify the immobilized lawn of oligonucleotide primers of a next-generation DNA

103 affect C. elegans behavioural avoidance of a lawn of Pseudomonas aeruginosa.

104 The spread of viruses on a homogeneous lawn of receptive hosts provides an opportunity to detec

105 ant, we placed SeLECT-Defense sealant over a lawn of S. mutans.

106 s die with similar kinetics when placed on a lawn of S. typhimurium for a relatively short time (3-5

107 When C. elegans is placed on a lawn of S. typhimurium, the bacteria accumulate in the l

108 ngless or armadillo mutant embryos secrete a lawn of ventral denticles; armadillo mutants also exhibi

109 We found that a uniform lawn of wild type neuroligins displayed on the cell surf

110 ragments should be able to form plaques on a lawn of wild-type Escherichia coli (i.e., lacking supF).

111 pends on continuous C. elegans exposure to a lawn of Yersinia bacteria.

112 -containing cells on solid medium containing lawns of bacteria of the same (plasmid-containing) strai

113 We found that for N2 worms grown on mixed lawns of bacteria, Salmonella enterica serovar Typhimuri

114 c behavior: the aggregation of C. elegans on lawns of bacterial food.

115 D29 forms clear plaques on lawns of Mycobacterium smegmatis and Mycobacterium bovis

116 multiple life cycles of amoebae grown on the lawns of other bacteria, thus demonstrating a stable rel

117 we allowed Caenorhabditis elegans to feed on lawns of P. aeruginosa PAO1 grown on high and low phosph

118 Lawns of transformants were grown at the permissive temp

119 rnema jollieti nematodes cultivated on mixed lawns of X. bovienii expressing green or DsRed fluoresce

120 ill able to predate when directly applied to lawns of YFP-labelled prey bacteria, showing that flagel

121 imensional propagation of viruses through a "lawn" of receptive hosts, commonly called plaque growth,

122 ork variants, an initially undifferentiated 'lawn' of receivers is engineered to form a bullseye patt

123 ent P. aeruginosa strains, the bacteria form lawns on these plates with amoebae embedded in them.

124 l [CI], 1.1-6.7) and the use of professional lawn or landscape services (OR, 2.8; CI, 1.0-8.2).

125 cted by whether the upland being invaded was lawn or wooded, but the marsh-edge plant communities tha

126 The carbohydrate is present in bacterial lawns prior to addition of nematodes, indicating that bi

127 the adjacent upland is likely to be a mowed lawn rather than a wooded natural area.

128 n a spatially heterogeneous Escherichia coli lawn serves as an experimental model system to study pop

129 The addition of SA to P. aeruginosa lawns significantly diminished the bacterium's ability t

130 ly Chloridoideae, is widely used in domestic lawns, sports fields and as forage.

131 of this source by studying decomposition in lawns, street gutters, and catch basins during two winte

132 (-) is more aberrant in plaques on bacterial lawns than on nitrocellulose filters.

133 onal areas, golf courses, sports fields, and lawns that confer many ecosystem services.

134 In contrast, lawns that were exposed to a 48 h microaerobic shock gen

135 s prefers to lay its eggs on a bacteria food lawn, the presence of a predator inside a lawn induces C

136 nclude typical ecosystems in suburban yards: lawn, trees, water reservoirs, and a vegetable garden; t

137 tap water that was used to supply water to a lawn water slide on which the child had played extensive

138 urable spring through fall, especially where lawns were dense.

139 In the assay, bacterial lawns were grown on agar plates, harvested with phosphat

140 CH4 fluxes from lawns were strongly related to seasonal fluctuations in

141 on showed improved robustness when bacterial lawns were tested with high- and low-density inoculum us

142 in both predator-free and predator-inhabited lawns, which we can rescue by transgenic complementation

143 retained the ability to grow as a confluent lawn, while seven grew only as single colonies around Hb

144 persal was measured using agar settle plates lawned with the O6-bacteriophage host, Pseudomonas syrin