- Email: [email protected]
Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
September 2012
ScienceDirect
Vol. 19 No. 3 1-13
Journal of Northeast Agricultural University (English Edition)
Available online at www.sciencedirect.com
Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops Chen Li-miao1, 2, Li Wen-bin2, and Zhou Xin-an1* 1
Key Laboratory of Oil Crop Biology, Ministry of Agriculture, Oil Crops Research Institute, CAAS, Wuhan 430062, China
2
Key Laboratory of Soybean Biology, Ministry of Education, Soybean Research Institute, Northeast Agricultural University, Harbin 150030, China
Abstract: Drought is one of the most important environmental constraints limiting plant growth, development and crop yield. Many drought-inducible genes have been identified by molecular and genomic analyses in Arabidopsis, rice and other crops. To better understand reaction mechanism of plant to drought tolerance, we mainly focused on introducing the research of transcription factors (TFs) in signal transduction and regulatory network of gene expression conferring drought. A TF could bind multiple target genes to increase one or more kinds of stress tolerance. Sometimes, several TFs might act together with a target gene. So drought-tolerance genes or TFs might respond to high-salinity, cold or other stresses. The crosstalk of multiple stresses signal pathways is a crucial aspect of understanding stress signaling. Key words: drought stress, stress tolerance, transcription factor, gene expression, signal pathway CLC number: S332.4; Q943.2
Document code: A
Article ID: 1006-8104(2012)-03-0001-13
involve in different signal pathways. But they are
Introduction
not totally isolated. The crosstalk of multiple stress
Transcription factors (TFs), which are known as
show differential transcript regulations in response to
trans-acting elements, can bind to cis-acting elements
different stresses (Table 2).
located in the promoter of stress-inducible genes,
Plants have adapted to respond to various environ-
and regulate their expressions. Stress-inducible gene
ment stresses, such as drought, high-salinity, ex-
expressions are regulated by some signal pathways,
treme temperature etc., through a series of stress
such as AREB/ABF, DREB, NAC, MYB/ MYC,
stimuli, signal perception, signal transduction, stress-
WRKY, NFYA, HD-ZIP etc (Table 1). AREB/ABF is
responsive gene expression, appropriate morpho-
ABA-dependent , DREB is ABA-independent, while
logical and physiological, molecular and cellular
NAC, MYB/MYC, WRKY, NFYA, and HD-ZIP
level changes occurred in plants, they protect them-
families include several subfamilies, in which some
self from the damage of biotic and abiotic stresses.
are ABA-dependent, the other are ABA- independent,
TFs play an important role in signal transduction.
even different members in the same subfamily
(Fig. 1).
signal pathways puts these TFs together. These TFs
Received 9 June 2011 Supported by Cultivation of New Varieties of Genetically Modified Major Projects (2011ZX08004-005); Soybean Industry Technology System (CARS-04-PS08) Chen Li-miao (1983-), female, assistant researcher, engaged in the research of soybean molecular cloning and genetic transformation. E-mail: [email protected] * Corresponding author. Zhou Xin-an, researcher, supervisor of Ph. D candidate, engaged in the research of soybean genetics and breeding. E-mail: [email protected] http: //publish.neau.edu.cn
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Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
Table 1 Sorts of transcription factors in different families Stress-responsive TFs
TFs families
Binding to cis-elements
Core sequence of cis-elements
DREB/CBF
AP2/EREBP
DRE/CRT
CCGAC
AREB/ABF
bZIP
ABRE
CACGTG (G box) CACGTC (C box) TACGTA (A box) MYB/MYC
MYB/MYC
MYBRS/MYCRS
TAACTG
NAC
NAC
NACRS
CATGTG
WRKY
WRKY
WRKYRS
TTGAC (W-BOX)
NF-YA/NF-YB
NF-Y
NF-YRS
CCAAT CAAT (A/T) AT
HD-ZIP
HB
HDERS
TG (HDE1) CAAT (G/C) AT TG (HDE2)
Table 2 Abiotic stress tolerance of transgenic plant over-expressing transcription factors in different species
Gene
Responsive to ABA
Increased tolerance to
Source species
Reference
AREB1
Yes
Drought
Arabidopsis
Furihata et al., 2006
AREB2
Yes
Drought
Arabidopsis
Furihata et al., 2006
ABF3
Yes
Drought
Arabidopsis
Furihata et al., 2006
ABP9
Yes
Drought, heat shock
Arabidopsis
Zhang et al., 2008
OsbZIP23
Yes
Drought, high-salinity
Rice
Xiang et al., 2008
OsbZIP72
Yes
Drought
Rice
Lu et al., 2009
SlAREB
Yes
Drought, salt
Tomato
Hsieh et al., 2010
DREB1A
No
Cold
Arabidopsis
Liu et al., 1998
DREB1B
No
Cold
Arabidopsis
Liu et al., 1998
DREB/
DREB1C
No
Cold
Arabidopsis
Liu et al., 1998
CBF
DREB1D/CBF4
No
Drought (low)
Arabidopsis
Haake et al., 2002
DREB2A
No
Drought, high-salinity
Arabidopsis
Nakashima et al., 2000
DREB2B
No
Drought, high-salinity
Arabidopsis
Nakashima et al., 2000
ANAC019
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC055
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC72
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC092
–
Salt
Arabidopsis
Balazadeh et al., 2010
ANAC102
–
Low-oxygen
Arabidopsis
Christianson et al., 2009
ATAF1
Yes
Drought
Arabidopsis
Lu et al., 2007
SNAC1
Yes
Drought
Rice
Hu et al., 2006
OsNAC52
Yes
Drought
Rice
Gao et al., 2010
OsNAC6
Yes
Drought, high-salinity, cold
Rice
Nakashima et al., 2007
ONAC045
Yes
Drought, high-salinity
Rice
Zheng et al., 2009
OsNAC10
Yes
Drought
Rice
Jeong et al., 2010
AtMYB2
Yes
Drought
Arabidopsis
Abe et al., 2003
MYB96
Yes
Drought
Arabidopsis
Seo et al., 2009
OsMYB3R-2
–
Drought, high-salinity, cold
Rice
Dai et al., 2007
StMYB1R-1
–
Drought
Potato
Shin et al., 2011
Family
bZIP
NAC
MYB
E-mail: [email protected]
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Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
Continued
Family
Gene
Responsive to ABA
Increased tolerance to
Source species
Reference
ABO3 OsWRKY45
Yes
Drought
Arabidopsis
Ren et al., 2010
Yes
Drought, high-salinity,
Rice
Qiu et al., 2009
0℃ and 42℃ WRKY
NF-Y
HD-ZIP
OsWRKY11
–
Drought, heat shock
Rice
Wu et al., 2009
GmWRKY21
–
Cold
Soybean
Zhou et al., 2008
GmWRKY54
–
Drought, salt
Soybean
Zhou et al., 2008
HvWRKY38
–
Drought
barley
AtNF-YB1
No
Drought
Arabidopsis
Xiong et al., 2010 Nelson et al., 2007
ZmNF-YB2
–
Drought
Maize
Nelson et al., 2007
NFYA5
Yes
Drought
Arabidopsis
Li et al., 2008
ATHB6
Yes
Drought
Arabidopsis
Söderman et al., 1999 Tran et al., 2006
ZFHD1
Yes
Drought, high-salinity
Arabidopsis
HDG11
–
Drought
Arabidopsis
Yu et al., 2008
CpHB-7
Yes
Drought
Craterostigma
Deng et al., 2006
Hahb-4
Yes
Drought
Brassica napus L
Dezar et al., 2005
NaHD20
Yes
Drought
Nicotiana attenuata
Re et al., 2011
plantagineum
Signal reception
Signal transduction pathway Transcription factors Auxin-dependent ABA-dependent
Biotic stress and wounding
Jasmonic aciddefense response
MYB96 (MYB) AtMYB2/AtMYC2 (MYB/MYC) NAC (RD26) AREB/ABF (bZIP) SIAREB (bZIP) AB3 (WRKY)
Drought stress High salinity stress
Regulatory gene expression GH3 RD22
Gly SnRK2 RD29A, COR47
WRKY18+ WRKY40– (WRKY) (WRKY) NFYA5 miR169 (NF-Y) ATHB6+ ATHB7– ATHB12– (HD-ZIPI) (HD-ZIPI) (HD-ZIPI) HDG11 NAC ZFHD1
WRKY60+ (WRKY)
ABI1, ABI2
NCED3, LOS5/ABA3, CIPK3, CAX3, ABI3 ERD1
AtNF-YB1 (NF-Y) ABA-independent Cold stress
DREB2 (AP2/EREBP) DREB1 (AP2/EREBP)
RD29A
Fig. 1 Transcriptional regulatory networks of TFs involved in abiotic stress-responsive gene expressions http: //publish.neau.edu.cn
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Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
drought and other stress in crop plants. Expression of
Study of Drought-inducible Genes in Arabidopsis
OsbZIP23 could be induced by most stresses, such as
Microarray analyses in Arabidopsis identify the pro-
yeast suggested that OsbZIP23 was a transcriptional
ducts of the drought-inducible genes, which are
activator. Transient expression in onion cells reveal-
divided into two types (Shinozaki et al., 2003). One
ed OsbZIP23 protein located in nucleus. Over-ex-
is functional protein, such as water channel, deto-
pressing OsbZIP23 in rice significantly improved to-
xification enzyme, late embryogenesis abundant
lerance to drought and high-salinity stresses and sen-
(LEA) protein, key enzyme for osmolyte biosynthesis
sitivity to ABA. On the contrary, a null mutant of this
(praline, sugar), and protease. Another is regulatory
gene showed significantly decreased sensitivity to a
protein, including transcription factor, protein kinase,
high concentration of ABA and decreased tolerance to
phospholipid metabolism, ABA biosynthesis and so
drought stress and high-salinity, and this phenotype
on. In which, transcription factors play an important
could be complemented by transforming the OsbZIP23
role in regulating drought-inducible gene expression.
back into the mutant. These demonstrated adequately
drought, salt, abscisic acid (ABA), and polyethylene glycol (PEG) treatments. Trans-activation assay in
that OsbZIP23 was an important regulator in ABAAREB/ABFs regulated pathway
dependent drought and high-salinity signal pathway
Some TFs, such as basic leucine zippers (bZIPs),
(Xiang et al., 2008). OsbZIP72 was another positive
regulate stress-responsive gene expressions through
transcription factor. It not only showed a hypersensiti-
ABA signal pathway. There are some cis-elements,
vity to ABA and a higher ability of drought tolerance,
termed Abscisic Acid-Responsive Element Binding
but also activated expression of ABA response genes,
Proteins (ABREs), binding to bZIP-type AREB/ABFs
such as LEAs (Lu et al., 2009). The rice bZIP TF OsABI5
in the promoter of ABA-regulated genes. AREB1,
was also isolated from rice panicles. Expression of
AREB2, and ABF3 in the AREB/ABFs subfamily need
OsABI5 was induced by ABA and high salinity, but
to be activated by ABA and can be induced under
was down-regulated by drought and cold (4℃) stress
drought. These three transcription factors could form
in seedlings. Over-expression of OsABI5 in rice con-
dimers in nucleus, and could interact with an SNF1-
ferred high sensitivity to salt stress. In contrast, down-
related protein kinase 2 (SnRK2) protein kinase de-
regulation of OsABI5 improved stress tolerance, but
signated SRK2D/SnRK2.2, which phosphorylated
decreased fertility of rice. These results demonstrated
the AREB1 polypeptide (Furihata et al., 2006).
that OsABI5 might regulate stress response and plant
To further study AREB1, AREB2, and ABF3
fertility (Zou et al., 2008). In addition, a tomato
function, an areb1 areb2 abf3 triple mutant was
bZIP transcription factor, SlAREB in Arabidopsis
constructed. The mutant was less sensitive to ABA
thaliana and tomato plants regulated stress-related
and had weaker drought tolerance. Therefore, AREB1,
genes including AtRD29A, AtCOR47, and SlCI7-like
AREB2, and ABF3 as transcription factors, collabora-
dehydrin under ABA and abiotic stress treatments.
tively regulated ABA-signaling gene expression under
Taken together, these results showed that SlAREB
drought (Yoshida et al., 2010). In Arabidopsis, a bZIP
might regulate some stress-responsive genes and that
transcription factor, ABP9 (ABA-responsive-element
its over-production improved plant tolerance to water
(ABRE) binding protein 9) constitutive expression
deficit and salt stress (Hsieh et al., 2010).
could improve the photo-synthetic capacity of plants under stress, including drought and heat shock (Zhang
DREBs regulated pathway
et al., 2008). There are some bZIP TFs responding to
Other TFs are in response to drought stress, but no
E-mail: [email protected]
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
·5·
respond to ABA, such as DREBs. The dehydration
NAC recognition sequence (NACRS), by analyzing
responsive element binding proteins (DREBs) are
the promoter of the drought inducible EARLY
important transcription factors that regulate the abiotic
RESPONSE TO DEHYDRATION1 (ERD1) gene.
stress-related genes and further improve stress tole-
The expression of ERD1 under drought depended on
rance to plants. DREBs were divided into DREB1/CBF
both the "CACTAAATTGTCAC" ZFHDRS and the
and DREB2 (Yamaguchi-Shinozaki and Shinozaki,
"ANNNNNTCNNNNNNNACACGCATGT" NACRS
2005) which responsed to different stress signals as
sequences (Simpson et al., 2003). They both acted as
cold and drought. They both belong to the EREBP
transcription activators in response to drought stress.
family of transcription factors, and bind to DRE (dehy-
In Arabidopsis, some NAC TFs could be induced
dration-responsive element)/CRT (C-RepeaT), both
by drought, high-salinity, low temperature or other
of which were cis-acting elements in the promoters of
stress. It was reported that ANAC019, ANAC055 or
stress-inducible genes (Yamaguchi-Shinozaki and
ANAC72 over-expression could improve some stress-
Shinozaki, 1994). Their conserved DNA-binding
inducible genes up-regulated and increase drought
motifs were CCGAC. The Arabidopsis genome con-
tolerance in transgenic plants (Fujita et al., 2004;
tained six DREB1/CBF genes and eight DREB2
Tran et al., 2004). They also regulated jasmonic acid-
genes (Sakuma et al., 2002). DREB1A, DREB1B, and
signaled defense response (Ooka et al., 2003; Bu et
DREB1C were strongly induced by cold, but not by
al., 2008). RD26 gene encoding a NAC transcription
drought and high-salinity stress (Liu et al., 1998).
factor was responsive not only to dehydration, but
However, DREB2A and DREB2B genes were on the
also to NaCl, ABA and jasmonic acid treatments. The
contrary (Nakashima et al., 2000). Other DREB1 and
transgenic plants over-expressing RD26 cDNA were
DREB2 genes were weakly induced (Sakuma et al.,
hypersensitive to ABA, and inversely, the transgenic
2002), and some DREB1/CBF genes as DREB1D/
plants with RD26 repressed were insensitive to ABA.
CBF4 also expressed low under drought stress, indicat-
The expressions of many ABA- and stress-induced
ing crosstalk between the DREB1/CBF and the DREB2
genes including RD20 and GLY genes were up-re-
pathways under drought stresses (Haake et al., 2002;
gulated in plants over-expressing RD26 and repressed
Magome et al., 2004). DREB1/CBF and DREB2-
in plants with RD26 repressed. In Arabidopsis proto-
homologous genes were identified in rice, named 10
plasts, RD26 activated a promoter of the GLY gene
OsDREB1s and four OsDREB2s, respectively. They
that was up-regulated in plants over-expressing RD26.
had a similar function with these in Arabidopsis to
Thus, GLY was the target gene of RD26. These results
abiotic stress.
demonstrated that RD26, as a transcription activator, involved in stress-responsive ABA-dependent signal
NAC regulated pathway
transduction pathway (Fujita et al., 2004). ANAC092/
NAC (NAM, ATAF and CUC) transcription factors
AtNAC2/ORE1 was found to act during senescence
(TFs), which are one kind of plant-specific TFs
and respond to salt stress (Balazadeh et al., 2010).
families, have been reported to enhance different
ANAC102 was reported to be induced by low-oxygen
stress tolerance such as drought, high salinity and
stress, and decreasing ANAC102 expression would
cold. Many NAC TFs have been identified in model
reduce seed germination efficiency under a 0.1%
Arabidopsis and crops. More than 105 putative NAC
oxygen treatment, but increasing expression had no
TFs existed in Arabidopsis, 140 in rice (Ooka et al.,
effect on seed germination. Indicating ANAC102
2003), 101 in soybean (Pinheiro et al., 2009) and
as an important regulator of seed germination under
152 in tobacco (Rushton et al., 2008), respectively.
waterlogging (Christianson et al., 2009). ATAF1/
The core motif CACG was identified, which was
ATAF2 both negatively regulated stress-responsive http: //publish.neau.edu.cn
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Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
gene expressions, the difference was that ATAF1 was
and salinity, but had not different effects on low
strongly induced by dehydration and abscisic acid
temperature. The transient expression of GmNAC1,
(ABA) treatment, indicating it regulated drought-
GmNAC5 and GmNAC6 in tobacco leaves promoted
responsive pathway (Lu et al., 2007), ATAF2 re-
senescence and further resulted in cell death. The
pressed the expression of pathogenesis-related genes
function and participating in stress-responsive
in Arabidopsis (Delessert et al., 2005). In rice, there
pathways NAC TFs in soybean would be further
are also some NAC TFs involving in drought, high-
studied.
salinity, low temperature etc. stress. SNAC1 (STRESSRESPON- SIVE NAC 1) over-expression significantly
MYB regulated pathway
increased drought tolerance in transgenic rice, whose
The MYB family is a large family and exists in all
seed setting was 22%-34% higher than that of control
eukaryotes. MYB proteins are main regulators in
during drought stress. The transgenic rice was more
plant development, metabolism and response to biotic
sensitive to ABA treatment and losed water more
and abiotic stresses. AtMYB2 and AtMYC2 both
slowly than WT by closing more stomatal pores, yet
bound cis-elements in the RD22 promoter and co-
showed no significant difference in the rate of photo-
operatively activated the RD22. Microarray analysis
synthesis. Therefore, the yield had not been affected
suggested that target genes of MYC/MYB over-
(Hu et al., 2006). OsNAC52, a rice NAC transcription
expression in transgenic plants might be alcohol
factor, could respond to ABA. OsNAC52 over-expre-
dehydrogenase and ABA-or jasmonic acid (JA)-
ssion activated the expression of downstream genes
inducible genes (Abe et al., 2003). Over-expression
in transgenic Arabidopsis and enhanced tolerance to
of AtMYB2 and AtMYC2 showed hypersensitivity
drought stresses but not growth retardation (Gao et al.,
to ABA and improved drought tolerance of the
2010). Similarly, a rice NAC gene, ONAC045, was
transgenic plants. A R2R3-type MYB transcription
also induced by drought, high salt, and low tempera-
factor, MYB96, regulated drought stress response
ture stress and ABA treatment in leaves and roots.
by integrating ABA and auxin signals. The MYB96-
Over-expressing ONAC045 in rice enhanced tolerance
mediated ABA signals were integrated into an auxin
to drought and salt treatments (Zheng et al., 2009).
signaling pathway that involved a subset of GH3
OsNAC10 expressed in roots significantly, and be
genes encoding auxin-conjugating enzymes. MYB96
induced by drought, high salinity, and ABA. In
over-expression in Arabidopsis exhibited enhanced
transgenic rice, OsNAC10 over-expression increased
drought resistance with reduced lateral roots. On the
drought tolerance. Under the control of root-specific
other hand, a T-DNA insertional knockout mutant was
promoter RCc3, root diameter of OsNAC10 plants
more susceptible to drought. Taken together, MYB96
was thicker by 1.25-fold than that of the constitutive
was a molecular link that mediated ABA-auxin cross
promoter GOS2 and non-transgenic plants grain
talk in drought stress response and lateral root growth
yield added by 17% in drought stress condition, 9%
(Seo et al., 2009). By a cDNA microarray approach
in normal condition (Jeong et al., 2010). In soybean,
to monitor the expression profile of rice under cold
101 NAC domain-containing proteins were divided
stress, OsMYB3R-2 was identified. Unlike most plant
into 15 different subgroups, in which six previously
R2R3 MYB transcription factors, OsMYB3R-2 has
described GmNAC proteins (GmNAC1 to GmNAC6)
three imperfect repeats in the DNA-binding domain.
were located in the nucleus and responded to
Expression of OsMYB3R- 2 was induced by cold,
various stress. GmNAC 2-5 acted as transactivators.
drought, and salt stress. Over-expressing OsMYB3R-2
GmNAC2-4 were significantly induced by osmotic
in Arabidopsis showed increased tolerance to cold,
stress. GmNAC3-4 were also induced by ABA, JA
drought, and salt stress (Dai et al., 2007). A putative
E-mail: [email protected]
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
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R1-type MYB-like transcription factor, StMYB1R-1,
that regulated gene expression in both plant defense
was also isolated as a putative stress-response gene
and stress responses by acting as either transcription
using reverse northern-blot analysis under abiotic
activator or repressor (Chen et al., 2010). The ABO3, a
environmental stress conditions. StMYB1R-1 located
WRKY transcription factor, regulated plant responses
to the nucleus and bound to the DNA sequence
to abscisic acid and drought tolerance in Arabidopsis.
/AGATAA. StMYB1R-1 over-expression in potato
The ABA sensitive mutant, abo3, was hypersensitive
plants improved plant tolerance to drought stress while
to ABA in both seedling establishment and seedling
having no significant effects on other agricultural
growth. However, stomatal closure was less sensitive
traits. In addition, over-expression of StMYB1R-1
to ABA, and the abo3 mutant was less drought tolerant
enhanced the expression of drought-regulated genes
than the wild type. Northern blot analysis showed that
such as AtHB-7, RD28, ALDH22a1, and ERD1-like.
the expression of the ABA-responsive transcription
These results demonstrated that StMYB1R-1 functions
factor ABF2/AREB1 was markedly lower in the
as a transcription factor involved in the activation of
abo3 mutant than in the wild type. The abo3 mutation
drought-related genes (Shin et al., 2011).
also reduced the expression of stress-inducible genes RD29A and COR47, especially early during the ABA
WRKY regulated pathway
treatment. The ABO3 was able to bind the W-box in
Like MYB family, the WRKY gene family also
the promoter of ABF2 in vitro. These results indicated
encoded a large group of TFs. Proteins of this family
that ABO3 played an important role as a WRKY
contained one or two highly conserved WRKY
transcription factor in plant responses to ABA and
domains and a zinc finger motif in the C-terminal
drought stress (Ren et al., 2010). In addition, the
region (Eulgem et al., 2000). The WRKY domain
expression of OsWRKY45 found in rice markedly
bound to the W box or SURE (sugar-responsive cis-
induced by abscisic acid (ABA) and various stress
element) found in promoters of target genes and
factors in Arabidopsis, including NaCl, PEG, mannitol
regulated its transcription (Rushton et al., 1995;
or dehydration, treatment with 0℃ and 42℃ as well as
Sun et al., 2003). WRKY transcription factors were
infection by Pyricularia oryzae Cav. and Xanthomonas
involved in plant responses to both biotic and abiotic
oryzae pv. oryzae. Together, these results indicated
stresses such as WRKY18, WRKY40, and WRKY60.
that the OsWRKY45 may be involved in the signal
WRKY18 and WRKY60 had a positive effect on plant
pathways of both biotic and abiotic stress responses
ABA sensitivity for inhibition of seed germination
(Qiu and Yu, 2009). Besides, in other plants, including
and root growth. And the two WRKY genes also
soybean and barely, there were also some WRKY TFs
enhanced plant sensitivity to salt and drought stress.
responding to drought and other stresses. Soybean
In contrast, WRKY40 repressed WRKY18 and
WRKY-type transcription factor, GmWRKY13,
WRKY60 in the effect on plant sensitivity to ABA
GmWRKY21, and GmWRKY54, conferred differential
and abiotic stress in germination and growth. Both
tolerance to abiotic stresses in transgenic Arabidopsis
WRKY18 and WRKY40 were rapidly induced by
plants. GmWRKY21-transgenic Arabidopsis plants
ABA, while induction of WRKY60 by ABA was
were tolerant to cold stress, whereas GmWRKY54
delayed. ABA-inducible expression of was almost
conferred salt and drought tolerance, possibly through
completely abolished in the WRKY18 and WRKY40
the regulation of DREB2A and STZ/Zat10. Transgenic
mutants. Thus, WRKY60 might be a direct target gene
plants over-expressing GmWRKY13 showed
of WRKY18 and WRKY40 in ABA signaling. Taken
increased sensitivity to salt and mannitol stress, but
together, these three related WRKY transcription
decreased sensitivity to ABA, when compared with
factors formed a highly interacting regulatory network
wild-type plants. In addition, GmWRKY13-transgenic http: //publish.neau.edu.cn
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Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
plants showed an increase in lateral roots. These
vascular tissues and guard cells, and NFYA5 contained
results indicated that these three GmWRKY genes
a target site for miR169, which was down-regulated
played differential roles in abiotic stress tolerance
by drought stress also by an ABA-dependent pathway.
(Zhou et al., 2008). Constitutive expression of the
Analysis of the expression of miR169 precursors
barley HvWRKY38 transcription factor also enhanced
showed that miR169a and miR169c were substantially
drought tolerance in turf and forage grass (Paspalum
down-regulated by drought stress. Co-expression of
notatum Flugge). Transgenic plants retained water
miR169 and NFYA5 suggested that miR169a was
better during dehydration, recovered faster and
more efficient than miR169c at repressing the NFYA5
produced more biomass following rehydration and
mRNA level. nfya5 knockout plants and plants over-
survived severe dehydration stress under controlled
expressing miR169a showed enhanced leaf water
environment conditions in contrast to non-transgenic
loss and were more sensitive to drought stress than
plants. They indicated that HvWRKY38 played the
wild-type plants. By contrast, transgenic Arabidopsis
regulatory role in dehydration tolerance (Xiong et al.,
plants over-expressing NFYA5 displayed reduced
2010).
leaf water loss and were more resistant to drought stress than the wild type. Microarray analysis indicated
NF-Y regulated pathway
that NFYA5 was an important regulator for the
NF-Y transcription factors existd ubiquitous in all
expression of a number of drought stress-responsive
eukaryotes and have roles in the regulation of various
genes. Therefore, NFYA5 was crucial for drought
genes (McNabb et al., 1995; Edwards et al., 1998;
tolerance, and its induction by drought stress occurred
Maity and Crombrugghe, 1998; Mantovani, 1999).
at both the transcriptional and posttranscriptional
The NF-Y transcription factor complex was composed
levels.
of three unique subunits: NF-YA, NF-YB, and NFYC. The subunits NF-YB and NF-YC formed a
HD-Zip regulated pathway
heterodimer in the cytoplasm, and then translocated
The HD-Zip (Homeodomain-Leucine Zipper)
to the nucleus, where they combined with the third
family of transcription factors is unique to the plant
subunit, NF-YA, heterotrimeric NF-Y transcription
kingdom. They are made up of four subfamilies in
factor (Frontini et al., 2004; Kahle et al., 2005). NF-Y
Arabidopsis, including HD-ZipⅠ, Ⅱ, Ⅲ, and Ⅳ.
transcription factor combined to CCAAT box, the
Some HD-Zip proteins participate in plant growth
core sequence in the promoter of regulative genes.
and development, while, others involve the action
Plant NF-Y TFs function appears to be important
of hormones or are apt to respond to environmental
for responses to drought stress. Although a specific
stress. Here, we mainly reviewed recent studies for
mechanism remains unknown. Over-expression of
transcription factors of this family playing crucial
AtNF-YB1 and its ortholog in maize (Zea mays),
role in environment stress, especially in drought.
ZmNF-YB2 improved drought tolerance (Nelson and
In 1999, ATHB6 (HD-ZipⅠ) was reported to be
Repetti, 2007). However, no loss-of-function data were
induced by water deficit, osmotic stress or exogenous
provided to study and indicated the function of drought
treatment with abscisic acid (ABA), and the ATHB6
in Arabidopsis. On the other hand, a publication
induction was impaired in the two ABA-insensitive
provided both over-expression and loss-of-function
mutants, abi1 and abi2. It demonstrated that ATHB6
data for NFYA5 (Li et al., 2008). The Arabidopsis
might act downstream to both ABI1 and ABI2 in
thaliana NFYA5 transcript was strongly induced by
a signal transduction pathway mediating a drought
drought stress in an abscisic acid (ABA)-dependent
stress response (Söderman et al., 1999). In contrast,
signal pathway. NFYA5 was highly expressed in
the Arabidopsis thaliana homeodomain leucine-
E-mail: [email protected]
·9·
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
zipper gene ATHB7 and ATHB12 (HD-ZipⅠ) acted
dehydration responsive dehydrin gene. CpHB-7
to mediate a response to water deficit as a negative
over-expression in transgenic desiccation-tolerant
regulator of growth (Söderman et al., 1996; Hjellstrom
plant Craterostigma plantagineum reduced sensitivity
et al., 2003; Olsson et al., 2004). The dehydration-
towards ABA during seed germination and stomatal
inducible expression of the Arabidopsis thaliana
closure. CpHB-7 regulated ABA-responsive gene
EARLY RESP O N S I V E T O D E H Y D R A T I O N
expression as a negative regulator, which was func-
STRESS 1 (ERD1) gene depended on the action
tionally similar to the Arabidopsis transcription factor,
together of zinc finger homeodomain ZFHD1 and
ATHB-6 (Deng et al., 2006). Brassica napus L. Hom-
NAC transcription factors. Using the yeast one-hybrid
eodomain Leucine-Zipper Gene BnHB6 was reported
system, ZFHD1 transcriptional activator was isolated.
to be induced by several stress and phytohormones
The expression of ZFHD1 was induced by drought,
including mannitol, NaCl, cold treatment, anaerobic
high salinity and abscisic acid. The DNA-binding
culture, wounding, H2O2, abscisic acid (ABA), and
and activation domains of ZFHD1 were localized on
salicylic acid (SA) treatments, but not by ultraviolet
the C-terminal homeodomain and N-terminal zinc
treatment (Yu et al., 2005). Hahb-4, a sunflower
finger domain, respectively. Microarray analysis of
homeobox-leucine zipper gene, can be induced by
transgenic plants over-expressing ZFHD1 revealed
drought and ABA. Its over-expression also increased
that several stress-inducible genes were up-regulated
drought tolerance. It showed that it might participate
in the transgenic plants. Using the yeast two-hybrid
in the regulation of the expression of genes involved
system, both ZFHD1 and NAC proteins were detected.
in developmental responses of plants to desiccation
Moreover, co-overexpression of the ZFHD1 and NAC
(Dezar et al., 2005). Besides, the TF was a new
genes restored the morphological phenotype of the
component of ethylene signaling pathways, and that
transgenic plants to a near wild-type state and increase
it induced a marked delay in senescence. Plants over-
expression of ERD1 in transgenic Arabidopsis
expressing Hahb-4 were less sensitive to external
plants (Tran et al., 2006). Activated expression of
ethylene, entered the senescence pathway later.
an Arabidopsis HD-START Protein, HDG11(HD-
Expression of this TF had a major repressive effect
Zip Ⅳ) enhanced drought tolerance with improved
on genes related to ethylene synthesis, such as the
root system and reduced stomatal density (Yu et al.,
ACO and the SAM, and on genes related to ethylene
2008). And HDG11 over-expression in transgenic
signaling, such as ERF2 and ERF5. Taken together,
Arabidopsis, tobacco and tall fescue all increased
we proposed that Hahb-4 was involved in a novel
drought tolerance (Yu et al., 2008; Cao et al., 2009).
conserved mechanism related to ethylene-mediated
HIPP26 from Arabidopsis thaliana belonged to the
senescence that improved desiccation tolerance
HIPP family of plant proteins, characterized by a
(Manavella et al., 2006). Nicotiana attenuata NaHD20
heavy metal associated domain and an additional
enhanced leaf ABA accumulation during water stress,
isoprenylation motif. It was induced during cold, salt
and NaHD20 played a positive role in the expression
and drought stress. By a yeast-two-hybrid approach,
of some dehydration-responsive genes including ABA
a strong interaction of HIPP26 with the zinc finger
biosynthetic genes (Re et al., 2011).
homeodomain transcription factor ATHB29 existed, which was known to play a role in dehydration stress response could be detected (Barth et al., 2009). A dehydration responsive nuclear-targeted HD-ZIP
Crosstalk of Stress-responsive Gene Regulatory Network
transcriptional regulator, CpHB-7 could combine
The crosstalk exists not only in different regulatory
with its target gene CDeT6-19, a known ABA and
systems, such as ABA-dependent or not, but also in http: //publish.neau.edu.cn
·10·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
different stresses-responsive gene expressions. Most drought-inducible genes are also induced by high-
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ScienceDirect
Vol. 19 No. 3 1-13
Journal of Northeast Agricultural University (English Edition)
Available online at www.sciencedirect.com
Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops Chen Li-miao1, 2, Li Wen-bin2, and Zhou Xin-an1* 1
Key Laboratory of Oil Crop Biology, Ministry of Agriculture, Oil Crops Research Institute, CAAS, Wuhan 430062, China
2
Key Laboratory of Soybean Biology, Ministry of Education, Soybean Research Institute, Northeast Agricultural University, Harbin 150030, China
Abstract: Drought is one of the most important environmental constraints limiting plant growth, development and crop yield. Many drought-inducible genes have been identified by molecular and genomic analyses in Arabidopsis, rice and other crops. To better understand reaction mechanism of plant to drought tolerance, we mainly focused on introducing the research of transcription factors (TFs) in signal transduction and regulatory network of gene expression conferring drought. A TF could bind multiple target genes to increase one or more kinds of stress tolerance. Sometimes, several TFs might act together with a target gene. So drought-tolerance genes or TFs might respond to high-salinity, cold or other stresses. The crosstalk of multiple stresses signal pathways is a crucial aspect of understanding stress signaling. Key words: drought stress, stress tolerance, transcription factor, gene expression, signal pathway CLC number: S332.4; Q943.2
Document code: A
Article ID: 1006-8104(2012)-03-0001-13
involve in different signal pathways. But they are
Introduction
not totally isolated. The crosstalk of multiple stress
Transcription factors (TFs), which are known as
show differential transcript regulations in response to
trans-acting elements, can bind to cis-acting elements
different stresses (Table 2).
located in the promoter of stress-inducible genes,
Plants have adapted to respond to various environ-
and regulate their expressions. Stress-inducible gene
ment stresses, such as drought, high-salinity, ex-
expressions are regulated by some signal pathways,
treme temperature etc., through a series of stress
such as AREB/ABF, DREB, NAC, MYB/ MYC,
stimuli, signal perception, signal transduction, stress-
WRKY, NFYA, HD-ZIP etc (Table 1). AREB/ABF is
responsive gene expression, appropriate morpho-
ABA-dependent , DREB is ABA-independent, while
logical and physiological, molecular and cellular
NAC, MYB/MYC, WRKY, NFYA, and HD-ZIP
level changes occurred in plants, they protect them-
families include several subfamilies, in which some
self from the damage of biotic and abiotic stresses.
are ABA-dependent, the other are ABA- independent,
TFs play an important role in signal transduction.
even different members in the same subfamily
(Fig. 1).
signal pathways puts these TFs together. These TFs
Received 9 June 2011 Supported by Cultivation of New Varieties of Genetically Modified Major Projects (2011ZX08004-005); Soybean Industry Technology System (CARS-04-PS08) Chen Li-miao (1983-), female, assistant researcher, engaged in the research of soybean molecular cloning and genetic transformation. E-mail: [email protected] * Corresponding author. Zhou Xin-an, researcher, supervisor of Ph. D candidate, engaged in the research of soybean genetics and breeding. E-mail: [email protected] http: //publish.neau.edu.cn
·2·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
Table 1 Sorts of transcription factors in different families Stress-responsive TFs
TFs families
Binding to cis-elements
Core sequence of cis-elements
DREB/CBF
AP2/EREBP
DRE/CRT
CCGAC
AREB/ABF
bZIP
ABRE
CACGTG (G box) CACGTC (C box) TACGTA (A box) MYB/MYC
MYB/MYC
MYBRS/MYCRS
TAACTG
NAC
NAC
NACRS
CATGTG
WRKY
WRKY
WRKYRS
TTGAC (W-BOX)
NF-YA/NF-YB
NF-Y
NF-YRS
CCAAT CAAT (A/T) AT
HD-ZIP
HB
HDERS
TG (HDE1) CAAT (G/C) AT TG (HDE2)
Table 2 Abiotic stress tolerance of transgenic plant over-expressing transcription factors in different species
Gene
Responsive to ABA
Increased tolerance to
Source species
Reference
AREB1
Yes
Drought
Arabidopsis
Furihata et al., 2006
AREB2
Yes
Drought
Arabidopsis
Furihata et al., 2006
ABF3
Yes
Drought
Arabidopsis
Furihata et al., 2006
ABP9
Yes
Drought, heat shock
Arabidopsis
Zhang et al., 2008
OsbZIP23
Yes
Drought, high-salinity
Rice
Xiang et al., 2008
OsbZIP72
Yes
Drought
Rice
Lu et al., 2009
SlAREB
Yes
Drought, salt
Tomato
Hsieh et al., 2010
DREB1A
No
Cold
Arabidopsis
Liu et al., 1998
DREB1B
No
Cold
Arabidopsis
Liu et al., 1998
DREB/
DREB1C
No
Cold
Arabidopsis
Liu et al., 1998
CBF
DREB1D/CBF4
No
Drought (low)
Arabidopsis
Haake et al., 2002
DREB2A
No
Drought, high-salinity
Arabidopsis
Nakashima et al., 2000
DREB2B
No
Drought, high-salinity
Arabidopsis
Nakashima et al., 2000
ANAC019
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC055
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC72
Yes
Drought, high-salinity
Arabidopsis
Tran et al., 2004
ANAC092
–
Salt
Arabidopsis
Balazadeh et al., 2010
ANAC102
–
Low-oxygen
Arabidopsis
Christianson et al., 2009
ATAF1
Yes
Drought
Arabidopsis
Lu et al., 2007
SNAC1
Yes
Drought
Rice
Hu et al., 2006
OsNAC52
Yes
Drought
Rice
Gao et al., 2010
OsNAC6
Yes
Drought, high-salinity, cold
Rice
Nakashima et al., 2007
ONAC045
Yes
Drought, high-salinity
Rice
Zheng et al., 2009
OsNAC10
Yes
Drought
Rice
Jeong et al., 2010
AtMYB2
Yes
Drought
Arabidopsis
Abe et al., 2003
MYB96
Yes
Drought
Arabidopsis
Seo et al., 2009
OsMYB3R-2
–
Drought, high-salinity, cold
Rice
Dai et al., 2007
StMYB1R-1
–
Drought
Potato
Shin et al., 2011
Family
bZIP
NAC
MYB
E-mail: [email protected]
·3·
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
Continued
Family
Gene
Responsive to ABA
Increased tolerance to
Source species
Reference
ABO3 OsWRKY45
Yes
Drought
Arabidopsis
Ren et al., 2010
Yes
Drought, high-salinity,
Rice
Qiu et al., 2009
0℃ and 42℃ WRKY
NF-Y
HD-ZIP
OsWRKY11
–
Drought, heat shock
Rice
Wu et al., 2009
GmWRKY21
–
Cold
Soybean
Zhou et al., 2008
GmWRKY54
–
Drought, salt
Soybean
Zhou et al., 2008
HvWRKY38
–
Drought
barley
AtNF-YB1
No
Drought
Arabidopsis
Xiong et al., 2010 Nelson et al., 2007
ZmNF-YB2
–
Drought
Maize
Nelson et al., 2007
NFYA5
Yes
Drought
Arabidopsis
Li et al., 2008
ATHB6
Yes
Drought
Arabidopsis
Söderman et al., 1999 Tran et al., 2006
ZFHD1
Yes
Drought, high-salinity
Arabidopsis
HDG11
–
Drought
Arabidopsis
Yu et al., 2008
CpHB-7
Yes
Drought
Craterostigma
Deng et al., 2006
Hahb-4
Yes
Drought
Brassica napus L
Dezar et al., 2005
NaHD20
Yes
Drought
Nicotiana attenuata
Re et al., 2011
plantagineum
Signal reception
Signal transduction pathway Transcription factors Auxin-dependent ABA-dependent
Biotic stress and wounding
Jasmonic aciddefense response
MYB96 (MYB) AtMYB2/AtMYC2 (MYB/MYC) NAC (RD26) AREB/ABF (bZIP) SIAREB (bZIP) AB3 (WRKY)
Drought stress High salinity stress
Regulatory gene expression GH3 RD22
Gly SnRK2 RD29A, COR47
WRKY18+ WRKY40– (WRKY) (WRKY) NFYA5 miR169 (NF-Y) ATHB6+ ATHB7– ATHB12– (HD-ZIPI) (HD-ZIPI) (HD-ZIPI) HDG11 NAC ZFHD1
WRKY60+ (WRKY)
ABI1, ABI2
NCED3, LOS5/ABA3, CIPK3, CAX3, ABI3 ERD1
AtNF-YB1 (NF-Y) ABA-independent Cold stress
DREB2 (AP2/EREBP) DREB1 (AP2/EREBP)
RD29A
Fig. 1 Transcriptional regulatory networks of TFs involved in abiotic stress-responsive gene expressions http: //publish.neau.edu.cn
·4·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
drought and other stress in crop plants. Expression of
Study of Drought-inducible Genes in Arabidopsis
OsbZIP23 could be induced by most stresses, such as
Microarray analyses in Arabidopsis identify the pro-
yeast suggested that OsbZIP23 was a transcriptional
ducts of the drought-inducible genes, which are
activator. Transient expression in onion cells reveal-
divided into two types (Shinozaki et al., 2003). One
ed OsbZIP23 protein located in nucleus. Over-ex-
is functional protein, such as water channel, deto-
pressing OsbZIP23 in rice significantly improved to-
xification enzyme, late embryogenesis abundant
lerance to drought and high-salinity stresses and sen-
(LEA) protein, key enzyme for osmolyte biosynthesis
sitivity to ABA. On the contrary, a null mutant of this
(praline, sugar), and protease. Another is regulatory
gene showed significantly decreased sensitivity to a
protein, including transcription factor, protein kinase,
high concentration of ABA and decreased tolerance to
phospholipid metabolism, ABA biosynthesis and so
drought stress and high-salinity, and this phenotype
on. In which, transcription factors play an important
could be complemented by transforming the OsbZIP23
role in regulating drought-inducible gene expression.
back into the mutant. These demonstrated adequately
drought, salt, abscisic acid (ABA), and polyethylene glycol (PEG) treatments. Trans-activation assay in
that OsbZIP23 was an important regulator in ABAAREB/ABFs regulated pathway
dependent drought and high-salinity signal pathway
Some TFs, such as basic leucine zippers (bZIPs),
(Xiang et al., 2008). OsbZIP72 was another positive
regulate stress-responsive gene expressions through
transcription factor. It not only showed a hypersensiti-
ABA signal pathway. There are some cis-elements,
vity to ABA and a higher ability of drought tolerance,
termed Abscisic Acid-Responsive Element Binding
but also activated expression of ABA response genes,
Proteins (ABREs), binding to bZIP-type AREB/ABFs
such as LEAs (Lu et al., 2009). The rice bZIP TF OsABI5
in the promoter of ABA-regulated genes. AREB1,
was also isolated from rice panicles. Expression of
AREB2, and ABF3 in the AREB/ABFs subfamily need
OsABI5 was induced by ABA and high salinity, but
to be activated by ABA and can be induced under
was down-regulated by drought and cold (4℃) stress
drought. These three transcription factors could form
in seedlings. Over-expression of OsABI5 in rice con-
dimers in nucleus, and could interact with an SNF1-
ferred high sensitivity to salt stress. In contrast, down-
related protein kinase 2 (SnRK2) protein kinase de-
regulation of OsABI5 improved stress tolerance, but
signated SRK2D/SnRK2.2, which phosphorylated
decreased fertility of rice. These results demonstrated
the AREB1 polypeptide (Furihata et al., 2006).
that OsABI5 might regulate stress response and plant
To further study AREB1, AREB2, and ABF3
fertility (Zou et al., 2008). In addition, a tomato
function, an areb1 areb2 abf3 triple mutant was
bZIP transcription factor, SlAREB in Arabidopsis
constructed. The mutant was less sensitive to ABA
thaliana and tomato plants regulated stress-related
and had weaker drought tolerance. Therefore, AREB1,
genes including AtRD29A, AtCOR47, and SlCI7-like
AREB2, and ABF3 as transcription factors, collabora-
dehydrin under ABA and abiotic stress treatments.
tively regulated ABA-signaling gene expression under
Taken together, these results showed that SlAREB
drought (Yoshida et al., 2010). In Arabidopsis, a bZIP
might regulate some stress-responsive genes and that
transcription factor, ABP9 (ABA-responsive-element
its over-production improved plant tolerance to water
(ABRE) binding protein 9) constitutive expression
deficit and salt stress (Hsieh et al., 2010).
could improve the photo-synthetic capacity of plants under stress, including drought and heat shock (Zhang
DREBs regulated pathway
et al., 2008). There are some bZIP TFs responding to
Other TFs are in response to drought stress, but no
E-mail: [email protected]
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
·5·
respond to ABA, such as DREBs. The dehydration
NAC recognition sequence (NACRS), by analyzing
responsive element binding proteins (DREBs) are
the promoter of the drought inducible EARLY
important transcription factors that regulate the abiotic
RESPONSE TO DEHYDRATION1 (ERD1) gene.
stress-related genes and further improve stress tole-
The expression of ERD1 under drought depended on
rance to plants. DREBs were divided into DREB1/CBF
both the "CACTAAATTGTCAC" ZFHDRS and the
and DREB2 (Yamaguchi-Shinozaki and Shinozaki,
"ANNNNNTCNNNNNNNACACGCATGT" NACRS
2005) which responsed to different stress signals as
sequences (Simpson et al., 2003). They both acted as
cold and drought. They both belong to the EREBP
transcription activators in response to drought stress.
family of transcription factors, and bind to DRE (dehy-
In Arabidopsis, some NAC TFs could be induced
dration-responsive element)/CRT (C-RepeaT), both
by drought, high-salinity, low temperature or other
of which were cis-acting elements in the promoters of
stress. It was reported that ANAC019, ANAC055 or
stress-inducible genes (Yamaguchi-Shinozaki and
ANAC72 over-expression could improve some stress-
Shinozaki, 1994). Their conserved DNA-binding
inducible genes up-regulated and increase drought
motifs were CCGAC. The Arabidopsis genome con-
tolerance in transgenic plants (Fujita et al., 2004;
tained six DREB1/CBF genes and eight DREB2
Tran et al., 2004). They also regulated jasmonic acid-
genes (Sakuma et al., 2002). DREB1A, DREB1B, and
signaled defense response (Ooka et al., 2003; Bu et
DREB1C were strongly induced by cold, but not by
al., 2008). RD26 gene encoding a NAC transcription
drought and high-salinity stress (Liu et al., 1998).
factor was responsive not only to dehydration, but
However, DREB2A and DREB2B genes were on the
also to NaCl, ABA and jasmonic acid treatments. The
contrary (Nakashima et al., 2000). Other DREB1 and
transgenic plants over-expressing RD26 cDNA were
DREB2 genes were weakly induced (Sakuma et al.,
hypersensitive to ABA, and inversely, the transgenic
2002), and some DREB1/CBF genes as DREB1D/
plants with RD26 repressed were insensitive to ABA.
CBF4 also expressed low under drought stress, indicat-
The expressions of many ABA- and stress-induced
ing crosstalk between the DREB1/CBF and the DREB2
genes including RD20 and GLY genes were up-re-
pathways under drought stresses (Haake et al., 2002;
gulated in plants over-expressing RD26 and repressed
Magome et al., 2004). DREB1/CBF and DREB2-
in plants with RD26 repressed. In Arabidopsis proto-
homologous genes were identified in rice, named 10
plasts, RD26 activated a promoter of the GLY gene
OsDREB1s and four OsDREB2s, respectively. They
that was up-regulated in plants over-expressing RD26.
had a similar function with these in Arabidopsis to
Thus, GLY was the target gene of RD26. These results
abiotic stress.
demonstrated that RD26, as a transcription activator, involved in stress-responsive ABA-dependent signal
NAC regulated pathway
transduction pathway (Fujita et al., 2004). ANAC092/
NAC (NAM, ATAF and CUC) transcription factors
AtNAC2/ORE1 was found to act during senescence
(TFs), which are one kind of plant-specific TFs
and respond to salt stress (Balazadeh et al., 2010).
families, have been reported to enhance different
ANAC102 was reported to be induced by low-oxygen
stress tolerance such as drought, high salinity and
stress, and decreasing ANAC102 expression would
cold. Many NAC TFs have been identified in model
reduce seed germination efficiency under a 0.1%
Arabidopsis and crops. More than 105 putative NAC
oxygen treatment, but increasing expression had no
TFs existed in Arabidopsis, 140 in rice (Ooka et al.,
effect on seed germination. Indicating ANAC102
2003), 101 in soybean (Pinheiro et al., 2009) and
as an important regulator of seed germination under
152 in tobacco (Rushton et al., 2008), respectively.
waterlogging (Christianson et al., 2009). ATAF1/
The core motif CACG was identified, which was
ATAF2 both negatively regulated stress-responsive http: //publish.neau.edu.cn
·6·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
gene expressions, the difference was that ATAF1 was
and salinity, but had not different effects on low
strongly induced by dehydration and abscisic acid
temperature. The transient expression of GmNAC1,
(ABA) treatment, indicating it regulated drought-
GmNAC5 and GmNAC6 in tobacco leaves promoted
responsive pathway (Lu et al., 2007), ATAF2 re-
senescence and further resulted in cell death. The
pressed the expression of pathogenesis-related genes
function and participating in stress-responsive
in Arabidopsis (Delessert et al., 2005). In rice, there
pathways NAC TFs in soybean would be further
are also some NAC TFs involving in drought, high-
studied.
salinity, low temperature etc. stress. SNAC1 (STRESSRESPON- SIVE NAC 1) over-expression significantly
MYB regulated pathway
increased drought tolerance in transgenic rice, whose
The MYB family is a large family and exists in all
seed setting was 22%-34% higher than that of control
eukaryotes. MYB proteins are main regulators in
during drought stress. The transgenic rice was more
plant development, metabolism and response to biotic
sensitive to ABA treatment and losed water more
and abiotic stresses. AtMYB2 and AtMYC2 both
slowly than WT by closing more stomatal pores, yet
bound cis-elements in the RD22 promoter and co-
showed no significant difference in the rate of photo-
operatively activated the RD22. Microarray analysis
synthesis. Therefore, the yield had not been affected
suggested that target genes of MYC/MYB over-
(Hu et al., 2006). OsNAC52, a rice NAC transcription
expression in transgenic plants might be alcohol
factor, could respond to ABA. OsNAC52 over-expre-
dehydrogenase and ABA-or jasmonic acid (JA)-
ssion activated the expression of downstream genes
inducible genes (Abe et al., 2003). Over-expression
in transgenic Arabidopsis and enhanced tolerance to
of AtMYB2 and AtMYC2 showed hypersensitivity
drought stresses but not growth retardation (Gao et al.,
to ABA and improved drought tolerance of the
2010). Similarly, a rice NAC gene, ONAC045, was
transgenic plants. A R2R3-type MYB transcription
also induced by drought, high salt, and low tempera-
factor, MYB96, regulated drought stress response
ture stress and ABA treatment in leaves and roots.
by integrating ABA and auxin signals. The MYB96-
Over-expressing ONAC045 in rice enhanced tolerance
mediated ABA signals were integrated into an auxin
to drought and salt treatments (Zheng et al., 2009).
signaling pathway that involved a subset of GH3
OsNAC10 expressed in roots significantly, and be
genes encoding auxin-conjugating enzymes. MYB96
induced by drought, high salinity, and ABA. In
over-expression in Arabidopsis exhibited enhanced
transgenic rice, OsNAC10 over-expression increased
drought resistance with reduced lateral roots. On the
drought tolerance. Under the control of root-specific
other hand, a T-DNA insertional knockout mutant was
promoter RCc3, root diameter of OsNAC10 plants
more susceptible to drought. Taken together, MYB96
was thicker by 1.25-fold than that of the constitutive
was a molecular link that mediated ABA-auxin cross
promoter GOS2 and non-transgenic plants grain
talk in drought stress response and lateral root growth
yield added by 17% in drought stress condition, 9%
(Seo et al., 2009). By a cDNA microarray approach
in normal condition (Jeong et al., 2010). In soybean,
to monitor the expression profile of rice under cold
101 NAC domain-containing proteins were divided
stress, OsMYB3R-2 was identified. Unlike most plant
into 15 different subgroups, in which six previously
R2R3 MYB transcription factors, OsMYB3R-2 has
described GmNAC proteins (GmNAC1 to GmNAC6)
three imperfect repeats in the DNA-binding domain.
were located in the nucleus and responded to
Expression of OsMYB3R- 2 was induced by cold,
various stress. GmNAC 2-5 acted as transactivators.
drought, and salt stress. Over-expressing OsMYB3R-2
GmNAC2-4 were significantly induced by osmotic
in Arabidopsis showed increased tolerance to cold,
stress. GmNAC3-4 were also induced by ABA, JA
drought, and salt stress (Dai et al., 2007). A putative
E-mail: [email protected]
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
·7·
R1-type MYB-like transcription factor, StMYB1R-1,
that regulated gene expression in both plant defense
was also isolated as a putative stress-response gene
and stress responses by acting as either transcription
using reverse northern-blot analysis under abiotic
activator or repressor (Chen et al., 2010). The ABO3, a
environmental stress conditions. StMYB1R-1 located
WRKY transcription factor, regulated plant responses
to the nucleus and bound to the DNA sequence
to abscisic acid and drought tolerance in Arabidopsis.
/AGATAA. StMYB1R-1 over-expression in potato
The ABA sensitive mutant, abo3, was hypersensitive
plants improved plant tolerance to drought stress while
to ABA in both seedling establishment and seedling
having no significant effects on other agricultural
growth. However, stomatal closure was less sensitive
traits. In addition, over-expression of StMYB1R-1
to ABA, and the abo3 mutant was less drought tolerant
enhanced the expression of drought-regulated genes
than the wild type. Northern blot analysis showed that
such as AtHB-7, RD28, ALDH22a1, and ERD1-like.
the expression of the ABA-responsive transcription
These results demonstrated that StMYB1R-1 functions
factor ABF2/AREB1 was markedly lower in the
as a transcription factor involved in the activation of
abo3 mutant than in the wild type. The abo3 mutation
drought-related genes (Shin et al., 2011).
also reduced the expression of stress-inducible genes RD29A and COR47, especially early during the ABA
WRKY regulated pathway
treatment. The ABO3 was able to bind the W-box in
Like MYB family, the WRKY gene family also
the promoter of ABF2 in vitro. These results indicated
encoded a large group of TFs. Proteins of this family
that ABO3 played an important role as a WRKY
contained one or two highly conserved WRKY
transcription factor in plant responses to ABA and
domains and a zinc finger motif in the C-terminal
drought stress (Ren et al., 2010). In addition, the
region (Eulgem et al., 2000). The WRKY domain
expression of OsWRKY45 found in rice markedly
bound to the W box or SURE (sugar-responsive cis-
induced by abscisic acid (ABA) and various stress
element) found in promoters of target genes and
factors in Arabidopsis, including NaCl, PEG, mannitol
regulated its transcription (Rushton et al., 1995;
or dehydration, treatment with 0℃ and 42℃ as well as
Sun et al., 2003). WRKY transcription factors were
infection by Pyricularia oryzae Cav. and Xanthomonas
involved in plant responses to both biotic and abiotic
oryzae pv. oryzae. Together, these results indicated
stresses such as WRKY18, WRKY40, and WRKY60.
that the OsWRKY45 may be involved in the signal
WRKY18 and WRKY60 had a positive effect on plant
pathways of both biotic and abiotic stress responses
ABA sensitivity for inhibition of seed germination
(Qiu and Yu, 2009). Besides, in other plants, including
and root growth. And the two WRKY genes also
soybean and barely, there were also some WRKY TFs
enhanced plant sensitivity to salt and drought stress.
responding to drought and other stresses. Soybean
In contrast, WRKY40 repressed WRKY18 and
WRKY-type transcription factor, GmWRKY13,
WRKY60 in the effect on plant sensitivity to ABA
GmWRKY21, and GmWRKY54, conferred differential
and abiotic stress in germination and growth. Both
tolerance to abiotic stresses in transgenic Arabidopsis
WRKY18 and WRKY40 were rapidly induced by
plants. GmWRKY21-transgenic Arabidopsis plants
ABA, while induction of WRKY60 by ABA was
were tolerant to cold stress, whereas GmWRKY54
delayed. ABA-inducible expression of was almost
conferred salt and drought tolerance, possibly through
completely abolished in the WRKY18 and WRKY40
the regulation of DREB2A and STZ/Zat10. Transgenic
mutants. Thus, WRKY60 might be a direct target gene
plants over-expressing GmWRKY13 showed
of WRKY18 and WRKY40 in ABA signaling. Taken
increased sensitivity to salt and mannitol stress, but
together, these three related WRKY transcription
decreased sensitivity to ABA, when compared with
factors formed a highly interacting regulatory network
wild-type plants. In addition, GmWRKY13-transgenic http: //publish.neau.edu.cn
·8·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
plants showed an increase in lateral roots. These
vascular tissues and guard cells, and NFYA5 contained
results indicated that these three GmWRKY genes
a target site for miR169, which was down-regulated
played differential roles in abiotic stress tolerance
by drought stress also by an ABA-dependent pathway.
(Zhou et al., 2008). Constitutive expression of the
Analysis of the expression of miR169 precursors
barley HvWRKY38 transcription factor also enhanced
showed that miR169a and miR169c were substantially
drought tolerance in turf and forage grass (Paspalum
down-regulated by drought stress. Co-expression of
notatum Flugge). Transgenic plants retained water
miR169 and NFYA5 suggested that miR169a was
better during dehydration, recovered faster and
more efficient than miR169c at repressing the NFYA5
produced more biomass following rehydration and
mRNA level. nfya5 knockout plants and plants over-
survived severe dehydration stress under controlled
expressing miR169a showed enhanced leaf water
environment conditions in contrast to non-transgenic
loss and were more sensitive to drought stress than
plants. They indicated that HvWRKY38 played the
wild-type plants. By contrast, transgenic Arabidopsis
regulatory role in dehydration tolerance (Xiong et al.,
plants over-expressing NFYA5 displayed reduced
2010).
leaf water loss and were more resistant to drought stress than the wild type. Microarray analysis indicated
NF-Y regulated pathway
that NFYA5 was an important regulator for the
NF-Y transcription factors existd ubiquitous in all
expression of a number of drought stress-responsive
eukaryotes and have roles in the regulation of various
genes. Therefore, NFYA5 was crucial for drought
genes (McNabb et al., 1995; Edwards et al., 1998;
tolerance, and its induction by drought stress occurred
Maity and Crombrugghe, 1998; Mantovani, 1999).
at both the transcriptional and posttranscriptional
The NF-Y transcription factor complex was composed
levels.
of three unique subunits: NF-YA, NF-YB, and NFYC. The subunits NF-YB and NF-YC formed a
HD-Zip regulated pathway
heterodimer in the cytoplasm, and then translocated
The HD-Zip (Homeodomain-Leucine Zipper)
to the nucleus, where they combined with the third
family of transcription factors is unique to the plant
subunit, NF-YA, heterotrimeric NF-Y transcription
kingdom. They are made up of four subfamilies in
factor (Frontini et al., 2004; Kahle et al., 2005). NF-Y
Arabidopsis, including HD-ZipⅠ, Ⅱ, Ⅲ, and Ⅳ.
transcription factor combined to CCAAT box, the
Some HD-Zip proteins participate in plant growth
core sequence in the promoter of regulative genes.
and development, while, others involve the action
Plant NF-Y TFs function appears to be important
of hormones or are apt to respond to environmental
for responses to drought stress. Although a specific
stress. Here, we mainly reviewed recent studies for
mechanism remains unknown. Over-expression of
transcription factors of this family playing crucial
AtNF-YB1 and its ortholog in maize (Zea mays),
role in environment stress, especially in drought.
ZmNF-YB2 improved drought tolerance (Nelson and
In 1999, ATHB6 (HD-ZipⅠ) was reported to be
Repetti, 2007). However, no loss-of-function data were
induced by water deficit, osmotic stress or exogenous
provided to study and indicated the function of drought
treatment with abscisic acid (ABA), and the ATHB6
in Arabidopsis. On the other hand, a publication
induction was impaired in the two ABA-insensitive
provided both over-expression and loss-of-function
mutants, abi1 and abi2. It demonstrated that ATHB6
data for NFYA5 (Li et al., 2008). The Arabidopsis
might act downstream to both ABI1 and ABI2 in
thaliana NFYA5 transcript was strongly induced by
a signal transduction pathway mediating a drought
drought stress in an abscisic acid (ABA)-dependent
stress response (Söderman et al., 1999). In contrast,
signal pathway. NFYA5 was highly expressed in
the Arabidopsis thaliana homeodomain leucine-
E-mail: [email protected]
·9·
Chen Li-miao et al. Regulatory Network of Transcription Factors in Response to Drought in Arabidopsis and Crops
zipper gene ATHB7 and ATHB12 (HD-ZipⅠ) acted
dehydration responsive dehydrin gene. CpHB-7
to mediate a response to water deficit as a negative
over-expression in transgenic desiccation-tolerant
regulator of growth (Söderman et al., 1996; Hjellstrom
plant Craterostigma plantagineum reduced sensitivity
et al., 2003; Olsson et al., 2004). The dehydration-
towards ABA during seed germination and stomatal
inducible expression of the Arabidopsis thaliana
closure. CpHB-7 regulated ABA-responsive gene
EARLY RESP O N S I V E T O D E H Y D R A T I O N
expression as a negative regulator, which was func-
STRESS 1 (ERD1) gene depended on the action
tionally similar to the Arabidopsis transcription factor,
together of zinc finger homeodomain ZFHD1 and
ATHB-6 (Deng et al., 2006). Brassica napus L. Hom-
NAC transcription factors. Using the yeast one-hybrid
eodomain Leucine-Zipper Gene BnHB6 was reported
system, ZFHD1 transcriptional activator was isolated.
to be induced by several stress and phytohormones
The expression of ZFHD1 was induced by drought,
including mannitol, NaCl, cold treatment, anaerobic
high salinity and abscisic acid. The DNA-binding
culture, wounding, H2O2, abscisic acid (ABA), and
and activation domains of ZFHD1 were localized on
salicylic acid (SA) treatments, but not by ultraviolet
the C-terminal homeodomain and N-terminal zinc
treatment (Yu et al., 2005). Hahb-4, a sunflower
finger domain, respectively. Microarray analysis of
homeobox-leucine zipper gene, can be induced by
transgenic plants over-expressing ZFHD1 revealed
drought and ABA. Its over-expression also increased
that several stress-inducible genes were up-regulated
drought tolerance. It showed that it might participate
in the transgenic plants. Using the yeast two-hybrid
in the regulation of the expression of genes involved
system, both ZFHD1 and NAC proteins were detected.
in developmental responses of plants to desiccation
Moreover, co-overexpression of the ZFHD1 and NAC
(Dezar et al., 2005). Besides, the TF was a new
genes restored the morphological phenotype of the
component of ethylene signaling pathways, and that
transgenic plants to a near wild-type state and increase
it induced a marked delay in senescence. Plants over-
expression of ERD1 in transgenic Arabidopsis
expressing Hahb-4 were less sensitive to external
plants (Tran et al., 2006). Activated expression of
ethylene, entered the senescence pathway later.
an Arabidopsis HD-START Protein, HDG11(HD-
Expression of this TF had a major repressive effect
Zip Ⅳ) enhanced drought tolerance with improved
on genes related to ethylene synthesis, such as the
root system and reduced stomatal density (Yu et al.,
ACO and the SAM, and on genes related to ethylene
2008). And HDG11 over-expression in transgenic
signaling, such as ERF2 and ERF5. Taken together,
Arabidopsis, tobacco and tall fescue all increased
we proposed that Hahb-4 was involved in a novel
drought tolerance (Yu et al., 2008; Cao et al., 2009).
conserved mechanism related to ethylene-mediated
HIPP26 from Arabidopsis thaliana belonged to the
senescence that improved desiccation tolerance
HIPP family of plant proteins, characterized by a
(Manavella et al., 2006). Nicotiana attenuata NaHD20
heavy metal associated domain and an additional
enhanced leaf ABA accumulation during water stress,
isoprenylation motif. It was induced during cold, salt
and NaHD20 played a positive role in the expression
and drought stress. By a yeast-two-hybrid approach,
of some dehydration-responsive genes including ABA
a strong interaction of HIPP26 with the zinc finger
biosynthetic genes (Re et al., 2011).
homeodomain transcription factor ATHB29 existed, which was known to play a role in dehydration stress response could be detected (Barth et al., 2009). A dehydration responsive nuclear-targeted HD-ZIP
Crosstalk of Stress-responsive Gene Regulatory Network
transcriptional regulator, CpHB-7 could combine
The crosstalk exists not only in different regulatory
with its target gene CDeT6-19, a known ABA and
systems, such as ABA-dependent or not, but also in http: //publish.neau.edu.cn
·10·
Journal of Northeast Agricultural University (English Edition)
Vol. 19 No. 3 2012
different stresses-responsive gene expressions. Most drought-inducible genes are also induced by high-
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