Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C0282612 (
PIN
)
2,291
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Plants have evolved a unique plasticity of their root system architecture to flexibly exploit heterogeneously distributed mineral elements from soil. Local high concentrations of
nitrate
trigger lateral root initiation in adult shoot-borne roots of maize (Zea mays) by increasing the frequency of early divisions of phloem pole pericycle cells. Gene expression profiling revealed that, within 12 h of local high
nitrate
induction, cell cycle activators (cyclin-dependent kinases and cyclin B) were up-regulated, whereas repressors (Kip-related proteins) were down-regulated in the pericycle of shoot-borne roots. In parallel, a ubiquitin protein ligase S-Phase Kinase-Associated Protein1-cullin-F-box protein(S-Phase Kinase-Associated Protein 2B)-related proteasome pathway participated in cell cycle control. The division of pericycle cells was preceded by increased levels of free indole-3-acetic acid in the stele, resulting in DR5-red fluorescent protein-marked auxin response maxima at the phloem poles. Moreover, laser-capture microdissection-based gene expression analyses indicated that, at the same time, a significant local high
nitrate
induction of the monocot-specific
PIN
-FORMED9 gene in phloem pole cells modulated auxin efflux to pericycle cells. Time-dependent gene expression analysis further indicated that local high
nitrate
availability resulted in
PIN
-FORMED9-mediated auxin efflux and subsequent cell cycle activation, which culminated in the initiation of lateral root primordia. This study provides unique insights into how adult maize roots translate information on heterogeneous nutrient availability into targeted root developmental responses.
...
PMID:Cell Type-Specific Gene Expression Analyses by RNA Sequencing Reveal Local High Nitrate-Triggered Lateral Root Initiation in Shoot-Borne Roots of Maize by Modulating Auxin-Related Cell Cycle Regulation. 2619 56
Nitrogen (N) is a major essential nutrient for plant growth, and rice is an important food crop globally. Although ammonium (NH
4
+
) is the main N source for rice,
nitrate
(NO
3
-
) is also absorbed and utilized. Rice responds to NO
3
-
supply by changing root morphology. However, the mechanisms of rice root growth and formation under NO
3
-
supply are unclear. Nitric oxide (NO) and auxin are important regulators of root growth and development under NO
3
-
supply. How the interactions between NO and auxin in regulating root growth in response to NO
3
-
are unknown. In this study, the levels of indole-3-acetic acid (IAA) and NO in roots, and the responses of lateral roots (LRs) and seminal roots (SRs) to NH
4
+
and NO
3
-
, were investigated using wild-type (WT) rice, as well as
osnia2
and
ospin1b
mutants. NO
3
-
supply promoted LR formation and SR elongation. The effects of NO donor and NO inhibitor/scavenger supply on NO levels and the root morphology of WT and
nia2
mutants under NH
4
+
or NO
3
-
suggest that NO
3
-
-induced NO is generated by the nitrate reductase (NR) pathway rather than the NO synthase (NOS)-like pathway. IAA levels, [
3
H] IAA transport, and
PIN
gene expression in roots were enhanced under NO
3
-
relative to NH
4
+
supply. These results suggest that NO
3
-
regulates auxin transport in roots. Application of SNP under NH
4
+
supply, or of cPTIO under NO
3
-
supply, resulted in auxin levels in roots similar to those under NO
3
-
and NH
4
+
supply, respectively. Compared to WT, the roots of the
ospin1b
mutant had lower auxin levels, fewer LRs, and shorter SRs. Thus, NO affects root growth by regulating auxin transport in response to NO
3
-
. Overall, our findings suggest that NO
3
-
influences LR formation and SR elongation by regulating auxin transport via a mechanism involving NO.
...
PMID:Nitric Oxide Affects Rice Root Growth by Regulating Auxin Transport Under Nitrate Supply. 3157 20
Asymmetric root growth (ARG) on tilted plates, or root coiling on horizontally placed plates, is proposed to be a combination of gravitropism, mechanical sensing, and "circumnutation," a word designated by Charles Darwin to describe the helical movement that all plant organs make around the growth direction. ARG is developmentally controlled in which microtubule-regulating proteins and the phytohormone auxin participates. Nutrient deficiency influences ARG. However, it is unclear which nutrients play key roles in regulating ARG, what endogenous components are involved in responding to nutrient deficiency for ARG, and how nutrient deficiency is translated into endogenous responses. We report here that
nitrate
deficiency resulted in a strong ARG in Arabidopsis.
Nitrate
deficiency caused root coiling on horizontal plates, which is inhibited by an auxin transport inhibitor, and by mutations in
PIN
-FORMED2
(
PIN2
) and
AUXIN RESISTANT 1
(
AUX1
). We further show that suppression of ARG by
nitrate
is mediated by the
nitrate
transporter/sensor NRT1.1. In addition, PIN2- and AUX1-mediated auxin transports are epistatic to NRT1.1 in
nitrate
deficiency-induced ARG. This study reveals a signaling pathway in root growth by responding to exogenous
nitrate
and relaying it into altered auxin transport.
...
PMID:NRT1.1-Mediated Nitrate Suppression of Root Coiling Relies on PIN2- and AUX1-Mediated Auxin Transport. 3258 37
