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1 fferentially expressed in root system during plant development.
2 adaptable organs that play critical roles in plant development.
3 s small molecules requiring AXR1 to modulate plant development.
4 tiple environmental cues are integrated into plant development.
5 t biostimulants have been shown to influence plant development.
6 are involved in abiotic stress responses and plant development.
7 ffecting mRNA export and splicing as well as plant development.
8 s of light to regulate genome expression and plant development.
9 cell wall, and are of critical importance in plant development.
10 f DypB in the cytosol and ER does not affect plant development.
11 tion between light- and cytokinin-controlled plant development.
12 s chloroplasts, which is essential for early plant development.
13 hereby regulating target gene expression and plant development.
14 on and its effects on gene expression during plant development.
15 ther understanding various MCTP functions in plant development.
16 rtant hormones that regulate many aspects of plant development.
17 NA helicase that is indispensable for proper plant development.
18 ght and temperature have dramatic effects on plant development.
19 sts a link between organelle functioning and plant development.
20 n of the phytohormone auxin is essential for plant development.
21 stance during stress responses and modulates plant development.
22 citrance without negative effects on overall plant development.
23 ctions between signaling pathways help guide plant development.
24 en these two redox systems and its impact on plant development.
25 n controlling formative divisions throughout plant development.
26 s shown to alter their expression and affect plant development.
27 and/or biotic factors (e.g., novel pests) on plant development.
28 group members in regulating PIN polarity and plant development.
29 e-plant transpiration, with minor effects on plant development.
30 itochondrial editing is necessary for normal plant development.
31 (8% to 9% by weight), without any impact on plant development.
32 cosides play an important role in regulating plant development.
33 r the establishment of cell polarity and for plant development.
34 inating multiple signaling activities during plant development.
35 in many important mechanisms and pathways of plant development.
36 tability contributes to its functions during plant development.
37 uvenile seedlings as well as long-term adult plant development.
38 nctionality of RNA Polymerase III and normal plant development.
39 r normal ER-cytoskeleton interaction and for plant development.
40 Hormonal interactions are crucial for plant development.
41 ffecting mRNA export and splicing as well as plant development.
42 owing 78.3% of seed germination and 56.6% of plant development.
43 equence of exposure to ionizing radiation on plant development.
44 hway to affect TOC159 stability during early plant development.
45 of gamma-aminobutyrate, which in turn affect plant development.
46 ductase (POR, EC 1.3.1.33) has a key role in plant development.
47 regions) to the sink organs is essential for plant development.
48 diversity of stomatal forms observed during plant development.
49 unknown signaling link between symbiosis and plant development.
50 expression does not have a strong impact on plant development.
51 highlight its role in hormonally controlled plant development.
52 ide signals that control distinct aspects of plant development.
53 ine tuning of HG methylesterification during plant development.
54 r the control of stem cell production during plant development.
55 acetic acid (IAA, or auxin) is essential for plant development.
56 he functions of cell wall polysaccharides in plant development.
57 tablishment in a manner essential for normal plant development.
58 ownstream of cytokinin signalling to control plant development.
59 ctive ligands critical to various aspects of plant development.
60 d cytokinin are key endogenous regulators of plant development.
61 onses to mechanical stimuli during secondary plant development.
62 d symbionts and are potentially important in plant development.
63 larization but instead play broader roles in plant development.
64 nt cotton cultivars and their implication on plant development.
65 le internal and external signals to optimize plant development.
66 ation, plant metabolism, protein import, and plant development.
67 their direct role in ribosome biogenesis and plant development.
68 esponse modules similar to those seen during plant development.
69 type, suggesting a critical role of m(6)A in plant development.
70 suboptimal concentrations, strongly limiting plant development.
71 s reveal new roles for polygalacturonases in plant development.
72 components of cell polarization processes in plant development.
73 gely subject to cotranslational decay during plant development.
74 are crucial for wall architecture and normal plant development.
75 tes and likely has widespread importance for plant development.
76 ors and display overlapping functions during plant development.
77 and they are involved in numerous aspects of plant development.
78 four CEK isoforms in Cho/Etn metabolism and plant development.
79 by altering different mechanisms influencing plant development.
80 osure to light marks a crucial transition in plant development.
81 pecies to play roles in heat acclimation and plant development.
82 le of the dynamics of DNA methylation during plant development.
83 cular tissue formation are shared throughout plant development.
84 jor focus of comparative genetic analyses in plant development.
85 ally distinct distribution of oxygen affects plant development.
86 n and how this activity might regulate early plant development.
87 a critical role in many diverse processes in plant development.
88 LORAD) is vital for organellar functions and plant development.
89 ryotic organisms and play major roles during plant development.
90 e and stress tolerance while ensuring normal plant development.
91 HDA9 and PWR to control gene expression and plant development.
92 nterpreting them, is a longstanding issue in plant development.
93 o reduce trichome density at later stages of plant development.
96 d in several biological processes, including plant development, ABA-mediated signalling pathway, ubiq
97 e acquisition of quantitative information on plant development across a range of temporal and spatial
99 f PRPs may be involved in MAPK regulation of plant development and / or pathogen resistance responses
102 pre-mRNA splicing is essential for adequate plant development and adaptation to freezing temperature
105 ligases (CRLs) regulate different aspects of plant development and are activated by modification of t
106 mones and volatile precursors that influence plant development and confer aesthetic and nutritional v
107 ngle protein playing a dual role, regulating plant development and conveying stress defence responses
110 lable on the multiple roles of jasmonates in plant development and defense, knowledge about the funct
120 red and far-red photoreceptors that control plant development and growth by promoting the proteolysi
124 patterning of stomata plays a vital role in plant development and has emerged as a paradigm for the
126 e expression of downstream genes involved in plant development and hormonal and stress responses.
127 etabolites are critically important both for plant development and human nutrition; however, the natu
130 ping bentgrass (Agrostis stolonifera) alters plant development and improves plant salt stress and nit
131 (2+))-binding proteins with crucial roles in plant development and in coordinating plant stress toler
132 ecise spatiotemporal coordination throughout plant development and in response to the environment.
134 gs reveal that SME1 plays a critical role in plant development and interaction with the environment b
136 is essential for embryonic and postembryonic plant development and it affects growth rate and stress
137 hat TK1a is expressed in most tissues during plant development and it was differentially induced by u
138 prevalence of cotranslational mRNA decay in plant development and its role in translational control.
140 ent suggests that complex I is essential for plant development and likely acts as a negative regulato
141 er content was adjusted at an early stage of plant development and maintained at a constant level unt
142 We determined how K(+) deprivation affects plant development and mineral acquisition and how these
143 years ago and was shown to be essential for plant development and morphogenesis, but its mode of act
144 nces with emphasis on the earliest stages of plant development and on the switch from pluripotency to
151 l transcriptomics holds promise for studying plant development and plant physiology with unprecedente
154 and intensity of ambient temperature impair plant development and reproduction, particularly male ga
155 lization of PSR1 but abolished its effect on plant development and resistance to viral and Phytophtho
156 ll death (PCD) is a crucial process both for plant development and responses to biotic and abiotic st
157 elements regulating abscisic acid-dependent plant development and responses to environmental stresse
158 Precise cell-cycle control is critical for plant development and responses to pathogen invasion.
160 tral node in coordinating auxin dynamics and plant development and reveals tight feedback regulation
162 Low phosphate (Pi) availability constrains plant development and seed production in both natural an
167 ough DGK activity is known to be involved in plant development and stress response, how specific DGK
169 etyltransferase, NAA50, in the regulation of plant development and stress responses in Arabidopsis (A
170 An important mechanism by which NO regulates plant development and stress responses is through S-nitr
175 osphoinositides function as lipid signals in plant development and stress tolerance by binding with p
176 TSN was found to be indispensable for normal plant development and stress tolerance, the molecular me
177 de the absence of telomere shortening during plant development and the corresponding activity of telo
178 the central function of the chloroplast for plant development and the modulation of stress tolerance
179 ties of pectin and, thereby, is critical for plant development and the plant defense response, althou
180 Alternative splicing (AS) plays key roles in plant development and the responses of plants to environ
181 This work establishes NAA50 as essential for plant development and the suppression of stress response
183 on factors that regulate multiple aspects of plant development and were recently shown to regulate ab
184 particularly important at the final stage of plant development and, unlike capital A, Cyrilliccapital
185 ng cross talks between auxin, a regulator of plant development, and Ca2+, a universal second messenge
186 on dioxide emissions associated with initial plant development, and have not considered the impact of
187 SH1 causes dramatic and heritable changes in plant development, and here we show that crossing these
190 reactions and growth at different stages of plant development, and the PP2A regulatory subunit PP2A-
191 ronmental adaptation, ecology, evolution and plant development, and will be instrumental for future b
192 af permeability during the juvenile phase of plant development are controlled by the maize (Zea mays)
196 crucial roles of ALA proteins in regulating plant development as well as PIN trafficking and polarit
198 because of both the complex role of auxin in plant development as well as technical limitations in in
199 also demonstrate the importance of m(5)C in plant development, as trm4b mutants have shorter primary
201 ay perturbation that were perceived early in plant development but were not predicted by lignin conte
203 Brassinosteroids (BRs) play crucial roles in plant development, but little is known of mechanisms tha
204 endomembrane system plays essential roles in plant development, but the proteome responsible for its
205 -specialists alike know that auxin regulates plant development, but the role of auxin transport mecha
208 can be suppressed during the late stages of plant development by gigantea (gi2), which defines the g
209 ly and circadian rhythm in the inhibition of plant development by glyphosate, due to interaction betw
210 rolling the regulation of photosynthesis and plant development by light (PIF3, HY5) and cold stress r
211 ch dorsoventral genes coordinate to regulate plant development by localizing auxin response between t
213 IP17 mutant, we found that to support normal plant development bZIP17 must be capable of mobilization
214 mtDNA configuration, compatible with normal plant development, can be generated by stoichiometric sh
215 ponent of polyadenylation machinery, affects plant development, cell division and elongation, and res
216 espite the crucial roles of phytohormones in plant development, comparison of the exact distribution
217 iations arise is necessary to understand how plant development contributes to local adaption in an ec
220 However, molecular events which regulate plant development downstream of SMAX1 removal have not b
223 spite well established roles of microRNAs in plant development, few aspects have been addressed to un
226 ted processes control almost every aspect of plant development from seed and bud dormancy, liberation
227 ly occurring signaling molecules that affect plant development, fungi-plant interactions, and parasit
228 rafficking plays pivotal roles in regulating plant development, gene silencing, and adaptation to env
229 for grapevine and winemaking, which affects plant development, grape juice fermentation and has a po
230 and is biosynthesized by plants to regulate plant development, growth, and stress responses via a we
231 timuli, such as wind, rain, and touch affect plant development, growth, pest resistance, and ultimate
235 TOR (MED) complex plays diverse functions in plant development, hormone signaling and biotic and abio
236 ric oxide (NO) exerts pleiotropic effects on plant development; however, its involvement in cell wall
238 ed the possibility that the UPR functions in plant development in the same manner as it does in respo
239 attention, but also considers other areas of plant development in which NAE metabolism has been impli
241 of pectin affects multiple processes during plant development, including cell expansion, organ initi
242 3 (GSK3)-like kinases play various roles in plant development, including chloroplast development, bu
243 thaliana) could cause detrimental effects on plant development, including growth arrest, leaf necrosi
244 ycomb-mediated gene silencing that regulates plant development, including organ boundary formation.
247 study indicates that the adequate timing of plant development is crucial to maximize yield formation
249 The remarkable plasticity of post-embryonic plant development is due to groups of stem-cell-containi
256 is a complex process that is integrated with plant development, leading to fully differentiated and f
258 Consistent with its essential roles during plant development, mutations of the basic SUMOylation ma
260 track a successively delayed spring flush of plant development on the way to their breeding sites.
261 od, a major environmental factor controlling plant development, on two Arabidopsis (Arabidopsis thali
263 m is a major but poorly understood aspect of plant development, partly because the stem initiates in
265 For the past several decades, advances in plant development, physiology, cell biology, and genetic
267 light the association of OcXII with not only plant development processes, but also with stress respon
268 xhibit antagonistic interactions during many plant development processes, but little is known about t
272 miRNAs, which were predominately involved in plant development, signal transduction and transcription
275 s have a plethora of functions in control of plant development, stress response, and primary metaboli
276 RC1 components perform discrete roles during plant development, suggesting the existence of PRC1 vari
278 diurnal, light, and temperature controls on plant development, their influence on chromatin-based tr
279 Auxin phytohormones control most aspects of plant development through a complex and interconnected s
283 nasin content significantly increases during plant development, thus justifying the belief that after
284 pecies have acquired the ability to redirect plant development to form unique organs called galls, wh
285 inducing and leaf-mining insects, manipulate plant development to form unique organs that provide the
286 erscore a need for a better understanding of plant development under conditions of Pi deprivation.
287 of signal transduction pathway(s) that limit plant development under the Pi starvation condition.
288 organelle glutathione redox homeostasis and plant development using a combination of genetic complem
290 omb group (PcG) proteins play vital roles in plant development via epigenetically repressing the tran
292 To determine the role of these proteins in plant development we performed an extensive genetic anal
293 w complex I function impacts respiration and plant development, we isolated Arabidopsis (Arabidopsis
295 nd its implications for stress tolerance and plant development were investigated in a set of rice kno
296 yrrole synthesis to become limiting in early plant development when active photosystem biogenesis pro
297 liphatic and total GLSs increased throughout plant development, whereas kaempferol and total flavonoi