ライフサイエンスコーパス: fertilized egg

1 nates sperm-derived mitochondrial DNA from a fertilized egg.

2 ertilized egg, but not to the surface of the fertilized egg.

3 the calcium wave reaches the antipode in the fertilized egg.

4 o separate pronuclei near the surface of the fertilized egg.

5 specifies the germline of descendants in the fertilized egg.

6 organisms that allow mRNA delivery into the fertilized egg.

7 all fraction of the total amount of PLC in a fertilized egg.

8 such as the notochord and neural tube to the fertilized egg.

9 ed specifically to the vegetal cortex of the fertilized egg.

10 that are restricted to the vegetal cortex of fertilized eggs.

11 on of F-actin and are defective in producing fertilized eggs.

12 In addition, they do not bind to fertilized eggs.

13 indicating their origin from heteroplasmy in fertilized eggs.

14 showed that CrANT is expressed in sperm and fertilized eggs.

15 mRNA, eGFP mRNA, and single guide RNAs into fertilized eggs.

16 ing to deformation and rapid ejection of the fertilized eggs.

17 jection of zinc-finger nucleases (ZFNs) into fertilized eggs.

18 s in 168 day old larvae as compared to newly fertilized eggs.

19 pollen tube growth, and decreased numbers of fertilized eggs.

20 bly line of oocyte production that generates fertilized eggs.

21 mRNA, encoding GFP-tagged beta-catenin, into fertilized eggs.

22 ytosis, and preventing sperm from binding to fertilized eggs.

23 ites, and is subsequently microinjected into fertilized eggs.

24 ed eggs and females develop as diploids from fertilized eggs.

25 unfertilized oocytes, but not to the zona of fertilized eggs.

26 re inherited differently in unfertilized and fertilized eggs.

27 However, in fertilized eggs, activation of the Mos/MEK/p42 MAPK path

28 symbiont reverses sperm modification in the fertilized egg, allowing offspring of infected females t

29 In addition to the impact of fertilized eggs, ALMR exopher production can be enhanced

30 uctures called P granules are present in the fertilized egg and are segregated into each of the germl

31 is present in both the unfertilized and the fertilized egg and contributes to the initial phase of P

32 r, such as increased clutch size, numbers of fertilized egg and fledglings).

33 GLUT1) is a major glucose transporter of the fertilized egg and preimplantation embryo.

34 ing through the cellular lineage between the fertilized egg and the cancer cell, each composed of spe

35 and are haploid, while females develop from fertilized eggs and are diploid.

36 become localized to the vegetal cytoplasm of fertilized eggs and are incorporated into muscle lineage

37 e MHC-heterozygous males contributed to more fertilized eggs and fledglings.

38 nesis, in which diploid females develop from fertilized eggs and haploid males develop from unfertili

39 s, in which females develop as diploids from fertilized eggs and males develop parthenogenetically as

40 ing wild and semi-natural pairs yielded more fertilized eggs and more fledglings, with a higher fledg

41 ed cytomegalovirus (CMV)-CTCF construct into fertilized eggs and mouse oocytes, respectively.

42 In addition, offspring arising from both fertilized eggs and parthenogenetic development were obs

43 chromosomes while diploid females arise from fertilized eggs and receive both maternal and paternal c

44 f microtubules in the cortex of activated or fertilized eggs and resulted in defects in the dorsovent

45 s uniformly distributed in oocytes and newly fertilized eggs, and becomes localized asymmetrically in

46 on genes were separately electroporated into fertilized eggs, and their regulatory activities were mo

47 Embryogenesis, from the time fertilized eggs are deposited in an eggcase (called a co

48 erference, the anterior cortical membrane of fertilized eggs became very fluid during meiosis and sub

49 inase activity was specifically inhibited in fertilized eggs by a truncated form of the Xenopus Cdk i

50 ine shows that the cellular machinery of the fertilized egg cannot demethylate the second maternal ge

51 onstrate that injection of HrPax-37 RNA into fertilized eggs causes ectopic expression of the dorsal

52 duce sexually by developing an embryo from a fertilized egg cell.

53 on consequences, rather than the presence of fertilized eggs, constitute the exopher-inducing stimulu

54 Here we show that whereas oocytes and fertilized eggs could utilize Sp1-dependent promoters, t

55 fficient in mutating Dot1L when expressed in fertilized eggs, creating essentially Dot1L knockout emb

56 transient, whereas BAPTA/AM-treated ICSI or fertilized eggs cultured in Ca(2+)-free medium remained

57 How does a fertilized egg decode its own genome to eventually devel

58 rtilized eggs develop as haploid males while fertilized eggs develop as diploid females, so the entir

59 use unfertilized eggs develop as males while fertilized eggs develop as females.

60 rtilized eggs give rise to haploid males and fertilized eggs develop into diploid females.

61 Fertilized eggs develop poorly into blastocysts, which r

62 However, most of the fertilized eggs develop without using the sperm DNA and

63 In addition, all successfully fertilized eggs die before the 2-cell stage due to persi

64 egg from the affected woman to an enucleated fertilized egg donated by an unaffected woman.

65 curred, in the absence of Ca(2+) influx, the fertilized eggs failed to emit the second polar body, re

66 urate and cost-effective selection of normal fertilized eggs for embryo transfer.

67 ves transplantation of nuclear genome from a fertilized egg from the affected woman to an enucleated

68 sayed nests, and multiple sneakers sometimes fertilized eggs from a single female.

69 he transgene cassette was microinjected into fertilized eggs from B6C3 (C3H x C57BL/6) females mated

70 Transcriptomic analysis of fertilized eggs from both morphotypes and reciprocal F(1

71 Fertilized eggs from FVB mice were injected with a const

72 strongly co-expressed with Xeed mRNA in the fertilized egg, further suggesting that their encoded pr

73 fractions from MTX-treated males into normal fertilized eggs generated cranial cartilage defects in t

74 f parthenotes in the same clutch as sexually fertilized eggs highlights the prevalence of parthenogen

75 box RNA was found in maturing oocytes and in fertilized eggs; however, the abundance of Sebox RNA is

76 ales sequentially to two males and collected fertilized eggs in a temporal series.

77 Sneaker males had fertilized eggs in approximately 50% of the assayed nest

78 ximately 12 microm) while it develops from a fertilized egg into a tadpole [2].

79 Every animal grows from a single fertilized egg into an intricate network of cell types a

80 to run at maximum velocity, subdividing the fertilized egg into smaller and smaller cells.

81 y develop into uniparental haploid males and fertilized eggs into biparental diploid females.

82 C. elegans hermaphrodites release fertilized eggs into food-rich environments but retain t

83 n into wild-type ova and implantation of the fertilized eggs into foster mothers.

84 ne of two ways: as a "conversion" of diploid fertilized eggs into haploid males or as embryonic morta

85 Optimal development of fertilized eggs into preimplantation embryos is essentia

86 ould produce sperm and eggs and could cleave fertilized eggs into smaller cells that self-organize in

87 A fertilized egg is initially transcriptionally silent and

88 Surprisingly, the fertilized egg is provided with at most one-third of the

89 physiological function of activated cPKCs in fertilized eggs is to sustain long-lasting Ca2+ oscillat

90 D choreography of reductive divisions of the fertilized egg, known as cleavage patterns.

91 Incubation at high altitude of fertilized eggs laid by high altitude hens also restrict

92 By contrast, incubation at sea level of fertilized eggs laid by high altitude hens not only rest

93 ata show that incubation at high altitude of fertilized eggs laid by sea level hens markedly restrict

94 Single fertilized eggs monitored for Ca(2+) had a mean increase

95 Since groups of fertilized eggs normally oscillate asynchronously, synch

96 n the sMic lineage: microinjection into a Sp fertilized egg of an RNA that contains the GFP open read

97 olutionary changes in developmental mode, we fertilized eggs of a direct-developing sea urchin, Helio

98 the rejection of BMC grafts, we transfected fertilized eggs of FVB mice with a vector containing DNA

99 de RNA/Cas9 ribonucleoprotein complexes into fertilized eggs of the coral Acropora millepora can prod

100 I cDNA, and the fusion gene microinjected to fertilized eggs of the FVB-N mouse strain.

101 lobase human SP-C promoter and injected into fertilized eggs of the FVB/N mouse strain.

102 , and scalable method to deliver shRNAs into fertilized eggs of the hydrozoan cnidarian Hydractinia s

103 iable in generating hundreds or thousands of fertilized eggs on a roughly weekly schedule.

104 p42 MAPK are critical for the progression of fertilized eggs out of meiosis and through the first mit

105 In fertilized eggs rapamycin treatment increased the transl

106 aevis egg (approximately 1.2 mm diameter), a fertilized egg rapidly proceeds through mitosis in a spa

107 ivity in mouse oocytes and one-cell embryos (fertilized eggs) renders them incapable of utilizing Gal

108 found in different egg masses: (1) recently fertilized eggs (stage ~ 3), (2) organogenesis (stages ~

109 function appears to be unique to oocytes and fertilized eggs, suggesting that it provides a safeguard

110 To demonstrate this, we fertilized eggs that had been depleted of both XTcf3 and

111 In fertilized eggs, the Nasonia sperm brought in paternally

112 The development of a single-celled fertilized egg, through the blastocyst stage of a ball o

113 The development of a fertilized egg to an embryo requires the proper temporal

114 The zygotic transition, from a fertilized egg to an embryo, is central to animal and pl

115 nteract with the extracellular matrix of the fertilized egg to form the block to polyspermy.

116 roteins of Xenopus laevis was generated from fertilized egg to neurula embryo.

117 chemical explanation of development from the fertilized egg to the adult requires an understanding of

118 transcriptional processes occurring from the fertilized egg to the adult stage.

119 Amoeboid sperm crawl around fertilized eggs to the spermatheca--a convoluted tube wh

120 In insects, the fertilized egg undergoes a series of rapid nuclear divis

121 to the sea urchin embryo by RNA injection of fertilized eggs was examined.

122 on by injection of zebrafish Hmox1 mRNA into fertilized eggs was found to be sufficient for a dystrop

123 Fertilized eggs were compressed to change the orientatio

124 Fertilized eggs were treated with Dex (0.1 mg kg(-1) ),

125 ormally transient structure derived from the fertilized egg, were often associated with the arrested

126 Upon injection into newly fertilized eggs, wild-type Cdc25A shortened the cell cyc

127 hibition of gelsolin expression by injecting fertilized eggs with a specific morpholino oligonucleoti

128 g-term cell cycle inhibition was observed in fertilized eggs with the CaMKII antagonist myrAIP (50 mi

129 The transition from oocyte to fertilized egg (zygote) involves many changes, including

130 we show that a significant number of normal fertilized eggs (zygotes) can be obtained for reprogramm

131 control of the transcriptomic homeostasis in fertilized eggs, zygotes and two-cell embryos.