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1 e sperm cell can produce viable progeny in a flowering plant.
2 zospheric and internal hormonal functions in flowering plants.
3 undant and best studied mRNA modification in flowering plants.
4 arge, highly successful Compositae family of flowering plants.
5 ns have been rampant during the evolution of flowering plants.
6 ral to reconstructing the early evolution of flowering plants.
7 that has been lost in several lineages like flowering plants.
8 ential requirement of sexual reproduction in flowering plants.
9 reproducing organisms, including mammals and flowering plants.
10 current expansions via serial duplication in flowering plants.
11 ependently many times in diverse lineages of flowering plants.
12 sion and contributes to cellular function in flowering plants.
13 SEPALLATA proteins just before the origin of flowering plants.
14 ster-of-PIN1 (SoPIN1), which is conserved in flowering plants.
15 tivity varies across developmental phases in flowering plants.
16 re essential for generating new offspring in flowering plants.
17 yed a crucial role in the diversification of flowering plants.
18 inal isoprenylation motif, are found only in flowering plants.
19 ar accumulation in these two major groups of flowering plants.
20 the endosperm, a nourishing tissue unique to flowering plants.
21 st severe habitat shift ever accomplished by flowering plants.
22 lopment of complex and diverse morphology in flowering plants.
23 cumulation and phloem loading selectively in flowering plants.
24 hesis is hypothesized as a key innovation in flowering plants.
25 for the load-bearing secondary cell wall of flowering plants.
26 However, dioecy is rare among flowering plants.
27 ting that AcMFT functions similarly to FT in flowering plants.
28 bacteria, except Deltaproteobacteria, and in flowering plants.
29 gene expression, is observed in mammals and flowering plants.
30 he reproductive alternatives that prevail in flowering plants.
31 d cell wall mechanics and cell elongation in flowering plants.
32 e moss, contrary to the inverse situation in flowering plants.
33 e content and gene order for vertebrates and flowering plants.
34 t occasions from hermaphroditic ancestors in flowering plants.
35 ns between sexual and clonal reproduction in flowering plants.
36 y in several species during the evolution of flowering plants.
37 ects, molluscs, polychaetes, vertebrates and flowering plants.
38 ul model system for studying the genetics of flowering plants.
39 and daisies) are the most diverse family of flowering plants.
40 bellows organs for active pollen transfer in flowering plants.
41 et the stage for the ecological expansion of flowering plants.
42 jor factor in driving the diversification of flowering plants.
43 ource for future studies on the evolution of flowering plants.
44 luding human, mouse, fruit fly, planaria and flowering plants.
45 ety of growth and developmental processes in flowering plants.
46 ly a handful of conserved intronic ncRNAs of flowering plants.
47 titive sequences in Marchantia compared with flowering plants.
48 f the epidermal layer in developing seeds of flowering plants.
49 t of 'speciation genes' ('barrier genes') in flowering plants.
50 patterning and shoot branching regulation in flowering plants.
51 rn along the placenta inside the gynoecia of flowering plants.
52 t not H3K9 or DNA methylation as reported in flowering plants.
53 expand current concepts on the evolution of flowering plants.
54 nally abundant in meiotic anthers of diverse flowering plants.
55 tional repression of protein-coding genes in flowering plants.
56 questration, a function conserved across the flowering plants.
57 lishing a unified evolutionary timescale for flowering plants.
58 llen tubes imposes hybridization barriers in flowering plants.
59 tal pigmentation patterning is widespread in flowering plants.
60 mistry and metabolism of nectar secretion in flowering plants.
61 mbionts colonize neighboring nonvascular and flowering plants.
62 ngle-copy highly syntenic genes are rare for flowering plants.
63 parental alleles, mainly in the endosperm of flowering plants.
64 t components of the plant immune response in flowering plants.
66 romatin was marked by H3K9 methylation as in flowering plants, a significant proportion of transposon
69 ity is thus important for the maintenance of flowering plant and pollinator diversity and predicted s
70 ation patterns of species that diverged from flowering plants and animals over a billion years ago.
71 ansion of PP2A subunit gene families in both flowering plants and animals was driven by whole-genome
72 Flowers are vehicles of Darwinian fitness in flowering plants and are attacked by herbivores and path
73 y rewards are exceedingly rare among eudicot flowering plants and are only known to occur on sterile
74 roteins constitute a large protein family in flowering plants and are thought to be mostly involved i
75 anism that has been altered is common to all flowering plants and crops, the findings provide proof o
78 Heteroplasmy is suspected to be common in flowering plants and investigations of additional taxa m
79 he most frequent evolutionary transitions in flowering plants and is often associated with an organ-s
80 s emitted by C. sandersonii is unusual among flowering plants and lures kleptoparasitic flies into th
81 ave expanded into multigene families in both flowering plants and mammals, and the extent to which di
82 ts into epigenetic homeostasis mechanisms in flowering plants and mammals, highlighting analogous mec
83 re drawn between fertilization mechanisms in flowering plants and other eukaryotes, including mammals
84 duplications have shaped the history of all flowering plants and present challenges to elucidating t
86 e AtMYB93 homologues are detected throughout flowering plants and represent promising targets for man
87 y is a pervasive evolutionary feature of all flowering plants and some animals, leading to genetic an
88 nated the list of highest risk species, with flowering plants and terrestrial invertebrates also repr
89 concomitantly with the land colonization by flowering plants and, by inference, could have been a ma
90 subfamily within the third largest family in flowering plants), and evaluate the results relative to
91 y and ongoing Y-chromosome degeneration in a flowering plant, and indicate that Y degeneration can oc
92 d wild-type male gamete containing pollen of flowering plants, and analogous reproductive structure i
93 interesting example of a convergent trait in flowering plants, and are associated with the diversific
94 gametophyte generation in the life cycle of flowering plants, and creates genetic variations through
96 tion of embryogenesis after fertilization in flowering plants, and prevent its occurrence without fer
97 ersification, including the radiation of the flowering plants, and suggest that dental innovation rat
98 tween the two are not well known outside the flowering plants, and the paradigm for PIN-regulated bra
99 mpacts of wildflower gardens on urban native flowering plants, and we reveal substantial gaps in our
100 rtilizers; (b) loss of nectar resources from flowering plants; and (c) degraded overwintering forest
104 n clades, for which there are at least 16 in flowering plants (angiosperms); however, there is eviden
107 d molecular evolution in seed tissues of the flowering plant Arabidopsis As predicted, there is more
109 al regulators of stomatal development in the flowering plant Arabidopsis thaliana and essential for s
111 cellular structures in M. polymorpha and the flowering plant Arabidopsis thaliana suggests that these
114 ces 692 SUMMARY: Unlike in animals, sperm in flowering plants are immotile and they are embraced as p
120 close paralogs of SSP that are conserved in flowering plants, are involved in several YDA-dependent
121 is present sporadically in multiple taxa of flowering plants as well as some hornworts and ferns, pr
122 Our results provide robust evidence across flowering plants at the global scale that high selfing a
123 by PIN proteins is a primary determinant of flowering plant branching patterns regulating both branc
124 ird pollination has evolved repeatedly among flowering plants but is almost exclusively characterized
125 be detected throughout the eudicot clade of flowering plants, but also that a subset of 37 CNSs can
127 utionary innovation for many animals and all flowering plants, but its impact on selection and domest
128 de variety of crops and the majority of wild flowering plants, but until now research on pesticide ef
132 mbine a deeply sampled phylogeny for a major flowering plant clade-Saxifragales-with phenotype and ni
133 asterids are one of the largest lineages of flowering plants, containing groups such as the sunflowe
134 st and most phenotypically diverse genera of flowering plants, containing species ranging from woody
135 Our results revealed that AcMFT from a non-flowering plant could interact with FD to regulate the f
137 large part responsible for the diversity of flowering plants dates back more than 150 years to Darwi
139 al variation in C. hirsuta, such that spring flowering plants developed more petals than those flower
141 susceptible to temporal mismatch if bees and flowering plants differ in their phenological responses
143 that a subset of 37 CNSs can be found in all flowering plants (diverging approximately 170 million ye
144 erennial and older flower strips with higher flowering plant diversity enhanced pollination more effe
146 the paradigm for PIN-regulated branching in flowering plants does not fit bryophyte gametophytes.
147 emum Webb (Asteraceae), the largest genus of flowering plants endemic to the Macaronesian archipelago
148 (WGD) events have occurred repeatedly during flowering plant evolution, and there is growing evidence
155 > 1500 species from three widely distributed flowering plant families (Asteraceae, Brassicaceae and S
159 lus guttatus, collecting the early- and late-flowering plants from each of three neighboring populati
160 e that accompany reproductive development in flowering plants, from germline specification to seed ma
161 7,554 LRR-RLK genes from 31 fully sequenced flowering plant genomes, the complex evolutionary dynami
163 genomes, in particular rendering angiosperm (flowering plant) genomes much less stable than those of
169 ass of iridoids, found in various species of flowering plants, harbors astonishing chemical complexit
171 e-transcriptome analysis of early embryos in flowering plants has been hampered by their size and ina
172 ow the paternal epigenome is reprogrammed in flowering plants has remained unclear since DNA is not d
173 success of Asteraceae, the largest family of flowering plants, has been attributed to the unique infl
174 volutionarily conserved single copy genes in flowering plants have been shown to be enriched in essen
176 he ancestral C3 photosynthetic pathway, many flowering plants have evolved a derived pathway named C4
179 rgence of these genes in different groups of flowering plants have resulted in differences in gene fu
181 n phenology, with groups such as insects and flowering plants having higher seasonality than mammals.
182 id precursors, has evolved multiple times in flowering plant history for various roles in plant defen
183 llular diploid sporophyte in both mosses and flowering plants; however, the morphological context in
188 product present in Amaryllidaceae family of flowering plants including daffodils, belongs to a class
189 to affect the growth and development of both flowering plants, including crops, and marine algae.
190 undred genes that are highly conserved among flowering plants, including genes involved in root devel
191 e recently been found in multiple species of flowering plants, including Silene noctiflora, which har
192 24-nt phasiRNA pathway is widely present in flowering plants, indicating that 24-nt reproductive pha
194 ting indeterminacy are well characterized in flowering plants, involving a feedback loop between clas
195 axonomic capacity to describe new species of flowering plant is stagnant at a time of unprecedented c
196 r divergent selection of these two groups of flowering plants is also observed in sugar transporter g
197 The enormous variation in architecture of flowering plants is based to a large extent on their abi
201 ulosic component of the primary cell wall of flowering plants, is composed of a beta-(1,4)-glucan bac
208 There are two main types of root systems in flowering plants, namely taproot systems of dicots and f
210 te change may constrain the success of early-flowering plants not through plant-pollinator mismatch b
211 selection that maintain such polymorphism in flowering plants, notably heterozygote advantage, negati
212 e study of B class gene functions in diverse flowering plants, novel insights can be gained from care
214 D. wrightii In a wind-tunnel setting with a flowering plant, Orco KO hawkmoths showed disrupted flig
217 own about species-level genetic diversity in flowering plants outside the eudicots and monocots, and
218 ts and vertebrates to the diversification of flowering plants over the past 100 million years and the
219 d sPPases, Pr-p26.1a and Pr-p26.1b, from the flowering plant Papaver rhoeas were inhibited by phospho
220 he three major phytochrome families found in flowering plants, phytochrome C (PHYC) is the least unde
224 This discovery expands our knowledge of flowering plant pollination systems and provides the fir
228 xpanded early in vertebrate evolution, while flowering plant PP2A subunit lineages evolved much more
229 tures in the previous year, and that of late-flowering plants primarily by temperatures 2 years earli
231 e fertilization, it has been recognized that flowering plants produce two highly dimorphic female gam
232 e environmental component in diverse taxa of flowering plants, promoting maintenance of skotomorphoge
233 ci for the control of nectary development in flowering plants, providing a critical data point in und
234 ramming during the sporophytic life cycle of flowering plants regulates genes is presently unknown.
239 RNA editing in plastids and mitochondria of flowering plants requires pentatricopeptide repeat prote
245 trol pollen tube growth and fertilization in flowering plants, serving as a model for dissecting the
248 odium quinoa willd.) is an annual herbaceous flowering plant showing appropriate nutritional and func
249 homologous to core ABA transduction genes in flowering plants [SNF1-related kinase2s (SnRK2s)] is pri
250 olonized the genomes of a large diversity of flowering plants, sometimes at very high copy numbers (>
251 wer family, Asteraceae, comprises 10% of all flowering plant species and displays an incredible diver
252 gain of approximately one pollinator and one flowering plant species and nearly two interactions.
255 cted experiments on 23 native and cultivated flowering plant species in Australia, South America, Nor
257 chanisms that establish gbM are unclear, yet flowering plant species naturally without gbM lack the D
260 molecules that are widely distributed across flowering plant species, many of which have been identif
262 ion for 9178 gene families shared between 37 flowering plant species, referred to as angiosperm core
263 and analogous reproductive structure in non-flowering plant species, tRFs accumulate to high levels.
264 genomic patterning of DNA methylation across flowering plant species, we compared single base resolut
270 rstanding of branching is largely limited to flowering plants such as Arabidopsis, which have a recen
272 argest family of plant CCDs, only present in flowering plants, suggesting a functional diversificatio
273 igenetic phenomenon occurring in mammals and flowering plants that causes genes to adopt a parent-of-
274 The SYP132A sequence is broadly found in flowering plants that form arbuscular mycorrhizal symbio
275 focused on monocotyledons, a major group of flowering plants that includes taxa of important economi
276 ly occurring mode of asexual reproduction in flowering plants that results in seed formation without
278 gulators of sporophytic shoot development in flowering plants, the extent of conservation in PIN func
280 yclic electron transport, suggesting that in flowering plants, the FLV's role was taken by other alte
282 form and function - the colour of petals in flowering plants, the shape of the fronds in ferns, and
285 in transport regulates branching patterns in flowering plants, this is not so in Physcomitrella, wher
286 Given the extensive conservation of gbM in flowering plants, this suggests that gbM could be an imp
287 tage is the critical developmental switch in flowering plants to ensure optimal fitness and/or yield.
291 ayed a key role in the adaptive radiation of flowering plants via their specialized interactions with
293 -binding protein (PEBP) gene families in non-flowering plants, we performed a functional analysis of
294 mage symptoms were found in treatments where flowering plants were grown on bunds than in plots where
296 -function of FRS7 and FRS12 results in early flowering plants with overly elongated hypocotyls mainly
297 in Arabidopsis is relatively uncommon among flowering plants, with most species having between three
298 bees provided with a very high diversity of flowering plants within the National Botanic Garden of W