Post on 18-Jan-2018
description
CZ.1.07/2.3.00/30.0009Employment of Newly Graduated Doctors of Science for Scientific Excellence
2nd Postdoc Presentation Day
14. 3. 2014
Name of the postdoc: Markéta Žďárská
Project title: The role of cytokinin-ethylene signaling crosstalk in
plant development
Mentor: doc. RNDr. Jan Hejátko, Ph.D.
Faculty/Department/Research group: CEITEC-MU, Research group
Functional Genomics and Proteomics of Plants
Start date of postdoc (in the project): May 1st, 20132
IntroductionCytokinin-ethylene crosstalk knowledge
ATCG00490 (RBCL)AT4G14880 (OASA1)AT4G28520 (CRU3)AT4G38630 (RPN10)AT4G38970 (FBA2)
AT1G62380 (ACO2)AT2G36880 (M AT3)
AT5G17920 ( ATMS1)
MVApathway ABA+CK
+CK ethylenebiosynthesis ethylene
ABA-relatedproteins
root response
(Zdarska et al, 2013)
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First connections: exogenous CK application inhibited the elongation and formation of lateral roots in etiolated seedlings (Bertell and Eliasson, 1992).
CK stimulates ethylene production (Cary et al., 1995).
CK stabilizes proteins of ACC synthase: ACS5 and ACS9 (Kakimoto et al, 1998; Hansen et al, 2009).
CK mediates ethylene biosynthesis in roots (Zdarska et al, 2013).
Research aims Analysis of molecular mechanisms involved in
the CK-mediated regulation of ethylene biosynthesis
Inspection of the potential crosstalk between CK- and ethylene-mediated MSP
Identification of the molecular nature of conditional switch leading to changes between CK and ethylene signaling
Cytokinin and ethylene signaling pathways
ETR1
(Schaller et al, 2012)
ETR1 reveals both STK and HK activity and embody high levels of similarity to HK acting in the MSP (Schaller et al, 2011).
ETR1 interacts with AHP1, AHP3 and ARR4 (Urao et al, 2000).
ETR1 interacts with AHP1-3 and AHP5-6 (Hrdinová, unpublished)
Ethylene receptors (STK
activity)
(Etheridge et al., 2006)
Cross-talk at signaling pathways
• ACC application regulates ARRs-A differentially in Col-0:• upregulation of ARR3, 5, 6 and 15 in shoots• downregulation of ARR5, 6, 8 and 15 in roots
• ACC treatment does not activate MSP in ahk2 ahk36
EXPRESSION ANALYSIS OF ARR-A (qRT-PCR)
1
10
100
1 000
shoot Col-0 root Col-0 shoot ahk2,3 root ahk2,3
30' ACC treatment
ARR3 ARR4 ARR5 ARR6 ARR7 ARR8 ARR9 ARR15 ARR16
rela
tive
gene
e
(D‘ Agostino, 2000)
Cytokinin response regulators ARR-A
1
10
100
1 000
shoot ahk2,4 root ahk2,4 shoot ahk3,4 root ahk3,4
rela
tive
gene
expr
essi
on
30' ACC treatment
ARR3 ARR4 ARR5 ARR6 ARR7 ARR8 ARR9 ARR15
Cross-talk at signaling pathways
• ahk2 ahk4 - upregulation of several ARRs-A in shoots and almost no effect in roots
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• ahk3 ahk4 – dowregulation of ARRs-A in shoots and generally no effect in roots
1. Overall, these data suggest that AHK2 and
AHK3 receptors modulate ethylene dependent activation of MSP output - AHK2 in roots and
AHK3 in both tissues.
almost all ARRs-A are induced by BAP (aromatic CK) treatment in shoots and roots of Col-0 and etr1-1 (unable to bind ethylene - constitutively active)
enhanced inducibity of ARR3, 5 and 16 in roots of etr1-1 than in Col-0 (denoted by red triangles above bars) 8
1
10
100
1 000
10 000
shoot Col-0 root Col-0 shoot etr1-1 root etr1-1
30' BAP treatment
ARR3 ARR4 ARR5 ARR6 ARR7 ARR8 ARR9 ARR15 ARR16
rela
tive
gene
expr
2. ETR1 interferes with CK in the regulation of MSP activity
CK and ethylene crosstalk model suggestion in the root
ARRs-A(MSP output)
AHK2, AHK3
cytokinin + ethyleneresponse
ETR1
MAPKcascade
AHP1-3,5
CK ethylenebiosynthesis ethylene
ethyleneresponse
EIN3
EIN2
ARRs-B
Multi-step phosphorelay (MSP) CK treatment upregulates several
proteins involved in the ethylene biosynthesis, resulting in prompt ethylene upregulation as an effect of root-specific ACC accumulation (Zdarska et al., 2013).
AHK2 and AHK3 receptors modulate ethylene dependent activation of MSP output.
Ethylene binds to ETR1 that interacts via ETR1 RD with AHP proteins (AHP1-3,5) and modulates MSP output at the level of expression ARRs-A.
Ethylene signaling plays a role in the CK-dependent regulation of RAM size.
9 Overall, these data show the integration of both CK and
ethylene signaling and its display as a mutual CK-ethylene response.
Future prospects Publication: The role of cytokinin-ethylene signaling crosstalk in plant development
e.g. Plant Physiology or Plant Journal (2014)
Internship at Caltech, CA – laboratory of prof. Meyerowitz September 2014 – February 2015 publication e.g. Plant Physiology or Plant Cell (2015)
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Thank you for attention!