ライフサイエンスコーパス: reproductive fitness

1 (WwTWs) results in feminization and reduced reproductive fitness.

2 s, reflecting evolutionary pressures tied to reproductive fitness.

3 ue homeostasis, which are required to ensure reproductive fitness.

4 ng optimal mates is important for maximizing reproductive fitness.

5 cts on plant and pollinator interactions and reproductive fitness.

6 , this exposure may influence post-migratory reproductive fitness.

7 uctive fitness and a positive effect on male reproductive fitness.

8 itat use and calving success, a component of reproductive fitness.

9 l state, females maximize their survival and reproductive fitness.

10 r innovations enhancing their vegetative and reproductive fitness.

11 isions were in accordance with prospects for reproductive fitness.

12 and longevity, and, at least in animals, on reproductive fitness.

13 y regulated to ensure proper development and reproductive fitness.

14 on theory that relates floral morphology to reproductive fitness.

15 nations between compatible morphs, and hence reproductive fitness.

16 with reproductive maturity to maximize male reproductive fitness.

17 ar of life, an important component of female reproductive fitness.

18 evolutionary trade-off between immunity and reproductive fitness.

19 ns reduces both reproductive hyperphagia and reproductive fitness.

20 l transmission of non-genetic information in reproductive fitness.

21 ly modulate aggression with consequences for reproductive fitness.

22 n floral color, with repercussions for plant reproductive fitness.

23 nfer certain traits with positive effects on reproductive fitness.

24 Men and women with TOF have reduced reproductive fitness.

25 ariation burden was a predictor of decreased reproductive fitness.

26 r unrelated offspring at a cost to their own reproductive fitness.

27 ities can be properly coordinated to improve reproductive fitness.

28 d infants, agents with a potential impact on reproductive fitness.

29 phenotype that is critical for foraging, and reproductive fitness.

30 e cells that may lay at the basis of loss of reproductive fitness.

31 aggression, intensity of parental care, and reproductive fitness.

32 s individuals with the highest potential for reproductive fitness.

33 foraging behavior and direct measures of its reproductive fitness.

34 their flowering with the seasons to maximise reproductive fitness.

35 re optimal allocation of plant resources for reproductive fitness.

36 th female molecules in a manner that affects reproductive fitness.

37 duce dysfunctional gametes and thus have low reproductive fitness.

38 ed alleles are recessive in their effects on reproductive fitness.

39 c variation than traits directly influencing reproductive fitness.

40 s, so continued survival contributes less to reproductive fitness.

41 the strength of natural selection acting on reproductive fitness.

42 ssion, and were likely causing reductions in reproductive fitness.

43 ral deafness, reduced lifespan and decreased reproductive fitness.

44 their territories and thereby increase their reproductive fitness.

45 the relationship between this variation and reproductive fitness.

46 ranslocation heterozygotes and reduces their reproductive fitness.

47 ut only NCVs caused significant reduction in reproductive fitness.

48 Potentially to communicate reproductive fitness [2,3], mosquito males and females h

49 occurred when the dove would normally attain reproductive fitness (about 1 year old).

50 investment in motility in proportion to the reproductive fitness advantage provided by the ability t

51 pattern of biological processes and confer a reproductive fitness advantage to their hosts.

52 plementation had a negative effect on female reproductive fitness and a positive effect on male repro

53 of the female body correlate with health and reproductive fitness and are found attractive.

54 ted the influence of food deprivation on the reproductive fitness and behavior of the egg parasitoid

55 restriction, with associated improvement in reproductive fitness and extended lifespan.

56 Dominant human genetic diseases that impair reproductive fitness and have high locus heterogeneity c

57 the class C gene AGAMOUS (AG) causes reduced reproductive fitness and is prevented by polycomb repres

58 nes, suggesting that they are beneficial for reproductive fitness and may allow mammals to cope with

59 During aging, both reproductive fitness and mitochondrial homeostasis decli

60 The birth of a healthy child is central to reproductive fitness and must have been subject to stron

61 site Gyrodactylus turnbulli affects parental reproductive fitness and offspring parasite resistance.

62 However, a link between reproductive fitness and spatial memory ability has yet

63 e mate encounter rates and hence to optimize reproductive fitness and success.

64 Reproductive fitness and survival are enhanced by adapti

65 lement dietary deficiencies and modulate the reproductive fitness and the defense system of the fly.

66 any innate social behaviors are essential to reproductive fitness and therefore fundamentally differe

67 ansinfected hosts, especially in relation to reproductive fitness and vectorial competence and capaci

68 ms exhibit tube test dominance and increased reproductive fitness, and here we show that social isola

69 istory trade-offs between flowering time and reproductive fitness are impacted by telomere length var

70 ss the contribution of MYC TFs to growth and reproductive fitness at high levels of defence, we mutat

71 dels may help elucidate how h-APOE4 promotes reproductive fitness at the cost of AD in later life.

72 cation within intact animals that influences reproductive fitness at the cost of somatic resilience.

73 of millions of women confronted with reduced reproductive fitness because of ageing.

74 The difference in reproductive fitness between HV and LV fish was particul

75 , antitumor immunity, and cross-generational reproductive fitness, but its mode of action is unknown.

76 he timing of genome replication, and reduces reproductive fitness by 45%.

77 infection caused by L. wallacei reduced host reproductive fitness by negatively impacting egg load, o

78 pulation growth and that negative effects on reproductive fitness can be short-lived.

79 Reproductive fitness costs associated with this reductio

80 males with rare colour patterns have higher reproductive fitness, demonstrating NFDS mediated by sex

81 K(a)/K(s) ratio of >1, indicating increased reproductive fitness) detected 19 of 23 known drug-resis

82 ce, and non-TG littermates) displayed normal reproductive fitness, development and lifespan (1) These

83 elling example of balancing body growth with reproductive fitness due to the combination of indetermi

84 tations suggest connections between maternal reproductive fitness, early zygotic development and geno

85 idual per generation, and because of the low reproductive fitness for de novo variants causing severe

86 -type littermates with regard to morphology, reproductive fitness, growth, longevity and a variety of

87 e limitation in small populations can reduce reproductive fitness, hinder population growth, and incr

88 its role in the sperm release that promotes reproductive fitness in D. melanogaster.

89 he consequences of loss of clock function on reproductive fitness in Drosophila melanogaster with mut

90 dysregulation of these interactions impairs reproductive fitness in mice.

91 ndicating a significant genetic component to reproductive fitness in the Hutterites.

92 ween vulnerability to capture and individual reproductive fitness in the wild.

93 es longevity in germline-less C. elegans and reproductive fitness in wild-type animals.

94 ssing NF1 had increased life spans, improved reproductive fitness, increased resistance to oxidative

95 cedented microbial evolutionary response, as reproductive fitness increases acquired in the selection

96 mplex interaction between current and future reproductive fitness, individual condition and external

97 Reproductive fitness is a complex phenotype that is a di

98 heritable psychiatric disorders that reduce reproductive fitness is an evolutionary paradox.

99 on, intestinal and brain metabolic profiles, reproductive fitness, locomotion, and brain gene express

100 ual centrality is positively associated with reproductive fitness (number of living offspring).

101 Reproductive fitness of adults with TOF and recurrence r

102 soil chemistries on flowering phenology and reproductive fitness of Boechera stricta, a wild relativ

103 berculosis (MDR-TB) epidemics depends on the reproductive fitness of circulating strains of MDR M. tu

104 nfections can have large effects on relative reproductive fitness of competing host populations.

105 ed transkingdom interactions that impact the reproductive fitness of distantly related nematodes.

106 ed future trend in resistance depends on the reproductive fitness of drug-resistant Mycobacterium tub

107 -species mating errors reducing lifespan and reproductive fitness of female C. nouraguensis only.

108 e sexual advantage of the male trait and the reproductive fitness of females and the individual fitne

109 m captive populations has not undermined the reproductive fitness of first generation individuals.

110 suggests habitat analogues may increase the reproductive fitness of range-shifting species allowing

111 The reproductive fitness of the Anopheles gambiae mosquito r

112 oduction; however, this diet did not improve reproductive fitness of the clk-1(qm30) animals.

113 ed L1 larvae that correlate with compromised reproductive fitness of the generation that experienced

114 unction to enhance sperm competitiveness and reproductive fitness of the male by finetuning gene expr

115 likely essential for maintaining the optimal reproductive fitness of virgin females and for species s

116 with the advent of modern surgical repairs, reproductive fitness of women began to exceed that of me

117 he host-adapted powdery mildew had a reduced reproductive fitness on rop6(DN) plants, which was retai

118 odulation of expression of genes influencing reproductive fitness or behavior.

119 to prioritize rapid food intake and greater reproductive fitness over the long-term benefits of prol

120 In terms of reproductive fitness, pairs in which fathers had been in

121 response, high-altitude hypoxic adaptation, reproductive fitness, pathogen defence, immunity, pigmen

122 knowledge no studies have demonstrated that reproductive fitness per se is improved by resonance bet

123 sporadically and are associated with reduced reproductive fitness, pointing to a causative role for d

124 Reproductive fitness rather than longevity has served as

125 Wild-type nematodes showed no change in reproductive fitness regardless of the Qn isoform fed.

126 ygotes and homozygotes have higher and lower reproductive fitness, respectively.

127 s receptor binding characteristics to clonal reproductive fitness, revealing physical determinants of

128 Many cases occur sporadically and impair reproductive fitness, suggesting a role for de novo muta

129 scale up to influence health, survival, and reproductive fitness, thereby affecting evolutionary cha

130 s is the first report of reduction of insect reproductive fitness through plant-mediated RNAi, demons

131 we investigated the genetic architecture of reproductive fitness traits in a fertile human populatio

132 We measured reproductive fitness via hermaphrodite self-brood size a

133 The important role of clock genes for reproductive fitness was confirmed by reversal of the lo

134 mplex CDH likely has a significant impact on reproductive fitness, we hypothesized that de novo varia

135 mal deletions are thought to severely impair reproductive fitness, which precludes their transmission

136 en residing at high altitudes in Nepal links reproductive fitness with trait combinations increasing

137 drug treatments and mutations with positive reproductive fitness, with high statistical significance

138 otype by environment (G x E) interaction for reproductive fitness, with the benefits and costs to per