ライフサイエンスコーパス: Antirrhinum

1 opsis reflects greater genetic redundancy in Antirrhinum .

2 ene which controls dorsoventral asymmetry in Antirrhinum.

3 support for a model of parallel evolution in Antirrhinum.

4 ter the first described plant PEBP gene from Antirrhinum.

5 space separating two flower color morphs of Antirrhinum.

6 n a downstream target gene RADIALIS (RAD) in Antirrhinum.

7 in Arabidopsis, similar to the situation in Antirrhinum.

8 transformation in stamen number relative to Antirrhinum, aborting the lateral and adaxial stamens du

9 The fimbriata (fim) gene of Antirrhinum affects both the identity and arrangement of

10 cture is conserved in relation to AG and the Antirrhinum AG orthologue, PLENA (PLE), and low-stringen

11 TEM orthologs were isolated from antirrhinum (AmTEM) and olive (OeTEM) and were expressed

12 rent, reflecting the diverse morphologies of Antirrhinum and Arabidopsis flowers.

13 ion is associated with petal identity, as in Antirrhinum and Arabidopsis, but this is achieved throug

14 In Antirrhinum and Arabidopsis, mutations in the floral mer

15 antly from weak C-function mutant alleles in Antirrhinum and Arabidopsis.

16 t three duplications since the divergence of Antirrhinum and Arabidopsis.

17 rgence among Antirrhinum species and between Antirrhinum and Digitalis is also low.

18 stinct from the expression pattern of RAD in Antirrhinum and from the endogenous RAD-like genes of Ar

19 or establishing petal and stamen identity in Antirrhinum and is expressed in all three layers of the

20 mologous transcription factors FLORICAULA of Antirrhinum and LEAFY of Arabidopsis share conserved rol

21 ibution of Tkn2 KNOX transcripts compared to Antirrhinum and maize suggests either a different spatia

22 f plants sampled from natural populations of Antirrhinum and Misopates species.

23 plains the biosynthesis of 7-epi-iridoids in Antirrhinum and related genera.

24 n protein, closely related to PHANTASTICA in Antirrhinum and ROUGH SHEATH2 in maize, both of which ne

25 a langsdorffii X N. sanderae) homolog of the antirrhinum (Antirrhinum majus) MYB305.

26 e have tested whether the model proposed for Antirrhinum applies to Arabidopsis, by creating transgen

27 red for the ABC functions in Arabidopsis and Antirrhinum are members of the MADS-box gene family, and

28 ogs AG from Arabidopsis and PLENA (PLE) from Antirrhinum are shown to be representatives of separate

29 -evolved with overall leaf shape and size in Antirrhinum because these characters are constrained by

30 ntity is based on studies of Arabidopsis and Antirrhinum, both of which are highly derived eudicots.

31 We tested for parallel trait evolution in Antirrhinum by investigating phylogenetic relationships

32 This feature of the two Antirrhinum C-function-like genes is markedly different

33 We have determined the crystal structure of Antirrhinum CEN to 1.9 A resolution.

34 y a natural variant of the barley homolog of Antirrhinum CENTRORADIALIS (HvCEN) as a contributor to s

35 An allele of the DAG locus of Antirrhinum (dag::Tam3), which is required for chloropla

36 amiana using TRV-VIGS was similar to that of Antirrhinum def and Arabidopsis ap3 mutants and caused t

37 uggest that NbDEF is a functional homolog of Antirrhinum DEF.

38 Dorsoventral asymmetry in flowers of Antirrhinum depends on expression of the cycloidea gene

39 shape--petal asymmetry--in the petal lobe of Antirrhinum depends on the direction of growth rather th

40 The development of reproductive organs in Antirrhinum depends on the expression of an organ identi

41 cterize the phylogenetic orthologue of Ls in Antirrhinum, ERAMOSA (ERA).

42 identity in Arabidopsis; their orthologs in Antirrhinum exhibit similar functions.

43 r the presence of high-fitness ridges in the Antirrhinum floral-color adaptive landscape, their data

44 UPULIFORMIS (CUP) in formation of the ornate Antirrhinum flower shape.

45 lip, and characteristic folds of the closed Antirrhinum flower.

46 In Antirrhinum, flower asymmetry depends on activation of R

47 The Antirrhinum gene CENTRORADIALIS (CEN) and the Arabidopsi

48 revealed that Stp is the pea homolog of the Antirrhinum gene Fimbriata (Fim) and of UNUSUAL FLORAL O

49 that cyc and fil1 are among the least biased Antirrhinum genes, so that their low diversity is not du

50 gest either that these gene families (or the Antirrhinum genome) are unusually constrained or that th

51 e history of eudicots and that the ancestral Antirrhinum had an active H gene and restricted trichome

52 present in multiple groups, suggesting that Antirrhinum has repeatedly colonised alpine habitats.

53 Antirrhinum has two genes corresponding to AP2, termed L

54 e controlling floral asymmetry, cycloidea in Antirrhinum, has been isolated.

55 e used primers designed from three published Antirrhinum hispanicum S-allele sequences in PCR reactio

56 hese phenotypes resemble the Arabidopsis and Antirrhinum homeotic B-function mutants apetala3/deficie

57 ra (desert ghost flower), which differs from Antirrhinum in corolla (petal) symmetry and pollination

58 in Senecio versus dorsal petal elongation in Antirrhinum In S vulgaris, diversification of CYC genes

59 lower 1 in Arabidopsis and centroradialis in Antirrhinum, inflorescences that are normally indetermin

60 Introduction of a RAD genomic clone from Antirrhinum into Arabidopsis leads to a novel expression

61 ablishment and maintenance and, in maize and Antirrhinum, it has been proposed that PHAN acts as an e

62 Dorsoventral asymmetry of Antirrhinum leaves requires activity of the Phantastica

63 umulation of knox gene products in maize and Antirrhinum leaves, respectively.

64 Eluta locus by transposon-tagging, using an Antirrhinum line that spontaneously lost the nonsuppress

65 the coupling of RAD to CYC regulation in the Antirrhinum lineage and hence the co-option of RAD had a

66 of RAD may have occurred specifically in the Antirrhinum lineage.

67 in an early divergence of alpine and lowland Antirrhinum lineages, and the alleles underlying this sp

68 etic replicas of petal surfaces and isogenic Antirrhinum lines differing only in petal epidermal cell

69 Compared with Antirrhinum, little divergence is again observed.

70 We report the discovery of an Antirrhinum MADS-box gene, FARINELLI (FAR), and the isol

71 ble for model organisms such as Arabidopsis, Antirrhinum, maize, rice and wheat, a phylogenetic persp

72 lly symmetrical flowers of the model species Antirrhinum majus (Plantaginaceae) are highly specialize

73 unctional genomic approach, we identified an Antirrhinum majus (snapdragon) BALDH, which exhibits 40%

74 In the model developmental system Antirrhinum majus (snapdragon), the closely related gene

75 The model species Antirrhinum majus (the garden snapdragon) has over 20 cl

76 In the early 1900s, Erwin Baur established Antirrhinum majus as a model system, identifying and cha

77 Tam3 from Antirrhinum majus belongs to the Ac/Ds family of transpo

78 An Antirrhinum majus dihydroflavonol reductase (DFR) cDNA w

79 Here we report the isolation of a gene from Antirrhinum majus encoding a protein from an entirely no

80 ne responsible for conferring dorsal fate in Antirrhinum majus flowers.

81 Ectopic expression of the MIXTA gene from Antirrhinum majus in S. dulcamara results in the formati

82 w that the growth and asymmetry of leaves in Antirrhinum majus involves the related YABBY transcripti

83 MIXTA, which in Antirrhinum majus is reported to regulate certain aspect

84 n the distantly related core eudicot species Antirrhinum majus L., paralogous SBP-box proteins SBP1 a

85 The identification of Antirrhinum majus mutants with ectopic petal spurs sugge

86 he reporter system is based on expression of Antirrhinum majus MYB-related Rosea1 (Ros1) transcriptio

87 In four Antirrhinum majus populations with different mating syst

88 ve identified a mutation at the DAG locus of Antirrhinum majus which blocks the development of chloro

89 Here, snapdragon (Antirrhinum majus) GPPS-SSU was over-expressed in tomato

90 Here, we show that expression of snapdragon (Antirrhinum majus) GPPS.SSU in tobacco (Nicotiana tabacu

91 le) and Dicotyledonae (Nicotiana tabacum and Antirrhinum majus) indicating that LINEs are a universal

92 i X N. sanderae) homolog of the antirrhinum (Antirrhinum majus) MYB305.

93 proteins, initially described in snapdragon (Antirrhinum majus) petals, are known regulators of epide

94 unds detected in the majority of snapdragon (Antirrhinum majus) varieties.

95 ms such as Arabidopsis thaliana, snapdragon (Antirrhinum majus), and petunia (Petunia hybrida).

96 transcription factor genes from snapdragon (Antirrhinum majus), paying particular attention to chang

97 rved in Arabidopsis thaliana and snapdragon (Antirrhinum majus).

98 i.e. AmRosea1 and AmDelila from snapdragon (Antirrhinum majus).

99 This observation extends previous reports in Antirrhinum majus, Epilobium hirsutum, Nicotiana tabacum

100 In Antirrhinum majus, floral zygomorphy is established by t

101 Investigation of two classic mutants in Antirrhinum majus, mutabilis and incolorata I, showed th

102 In Antirrhinum majus, one proposed role of the gene fimbria

103 ridoids in the ornamental flower snapdragon (Antirrhinum majus, Plantaginaceae family) are derived fr

104 ng bZIP proteins are expressed in flowers of Antirrhinum majus, predominantly in vascular tissues, ca

105 ing mechanisms used by four such proteins in Antirrhinum majus, SQUA, PLE, DEF and GLO.

106 In Antirrhinum majus, the MIXTA protein directs the formati

107 variation in 3000 leaves from 400 plants of Antirrhinum majus.

108 ment of conical epidermal cells in petals of Antirrhinum majus.

109 to the development of dorsal petal lobes of Antirrhinum majus.

110 ptide-encoding sequence from the oli gene of Antirrhinum majus.

111 class in Arabidopsis (TCP1) and snapdragon (Antirrhinum majus; CYCLOIDEA) have been shown to be asym

112 e show that the previous inability to obtain Antirrhinum mutants corresponding to the A class gene AP

113 Snapdragon (Antirrhinum) mutants lacking conical cells have been sho

114 Unlike the situation in Antirrhinum, none of the Arabidopsis RAD-like genes are

115 c tobacco lines, biolistic transformation of Antirrhinum petals and promoter activation/repression as

116 is expressed only in the inner epidermis of Antirrhinum petals.

117 gene sequence was found to be similar to the Antirrhinum PHANTASTICA (PHAN) gene sequence, which enco

118 ily conserved sequences in the intron of the Antirrhinum PLENA (PLE) gene to establish whether they r

119 ences, and one to a very similar unpublished Antirrhinum S-like RNase sequence.

120 red in Arabidopsis are therefore separate in Antirrhinum, showing that the genetic basis of some aspe

121 fied visually, to observe the development of Antirrhinum (snapdragon) petals.

122 antify differences in leaf allometry between Antirrhinum (snapdragon) species, including variation in

123 In the genus Antirrhinum (snapdragons), as in other plants, a suite o

124 rns using natural variation within the genus Antirrhinum (snapdragons), which has evolved hairy alpin

125 Divergence among Antirrhinum species and between Antirrhinum and Digitali

126 mined the evolutionary relationships between Antirrhinum species and how these relate to geography an

127 s variation in trichome patterns between all Antirrhinum species except one.

128 Hybrids between Antirrhinum species have been used successfully to ident

129 Antirrhinum species with diverse floral phenotypes forme

130 s, euAP1 (including Arabidopsis APETALA1 and Antirrhinum SQUAMOSA) and euFUL (including Arabidopsis F

131 It has previously been proposed for Antirrhinum that another gene, FIMBRIATA (FIM), mediates

132 A transcription factor couple from Antirrhinum that is known to control anthocyanin biosynt

133 In Antirrhinum, the inflorescence can be distinguished by i

134 ved role in petal growth in both Senecio and Antirrhinum, the regulatory relationships and expression

135 the normally indeterminate inflorescence of Antirrhinum to terminate in a flower.

136 ed an Impatiens homologue of the FIM gene of Antirrhinum (UFO in Arabidopsis), Imp-FIM, and analysed

137 zfl2, the maize homolog of FLORICAULA of Antirrhinum, was associated with plant height.

138 and FT were observed in both Arabidopsis and antirrhinum, which correlated with the length of the JVP

139 rsity studies revealed that the fil1 gene of Antirrhinum, which has been reported to be single copy,

140 We have studied the cin mutant of Antirrhinum, which has crinkly rather than flat leaves.