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Acta Agronomica Sinica ›› 2022, Vol. 48 ›› Issue (4): 781-790.doi: 10.3724/SP.J.1006.2022.12026

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Research progress regarding the function and mechanism of rice AP2/ERF transcription factor in stress response

CHEN Yue(), SUN Ming-Zhe, JIA Bo-Wei, LENG Yue, SUN Xiao-Li*()   

  1. Crop Stress Molecular Biology Laboratory, Heilongjiang Bayi Agricultural University, Daqing 163319, Heilongjiang, China
  • Received:2021-04-14 Accepted:2021-08-20 Online:2022-04-12 Published:2021-08-30
  • Contact: SUN Xiao-Li E-mail:18104516702@163.com;csmbl2016@126.com
  • Supported by:
    Innovative Research Program for Graduates of Heilongjiang Bayi Agricultural University(YJSCX2021-Y41);National Natural Science Foundation of China(31971826);Central Support Fund for Reform and Development of Local Universities and Talent Cultivation, and the Fund Program for the Scientific Activities of Selected Returned Overseas Professionals in Heilongjiang Province

Abstract:

AP2/ERF (APETALA2/ethylene responsive factor) is a family of plant specific transcription factors that are widely involved in various biological processes including plant growth and development and stress responses. Rice is an important food crop in China, but it is severely affected by multiple adverse environmental factors during growth period. It has been found that AP2/ERF transcription factors play important roles in stress response in rice. In this paper, we reviewed the classification and structure architecture of rice AP2/ERF transcription factors and summarized the function and molecular mechanism of different AP2/ERF subfamilies in rice response to disease, drought, saline, and low temperature stresses. This study provides a reference for further interpretation of the molecular network of rice AP2/ERFs-mediated regulatory network in stress responses and their application potential for stress resistance improvement of rice cultivars.

Key words: rice, transcription factors, AP2/ERF, stress response

Table 1

Classification of AP2/ERF family transcription factors in Arabidopsis [7,8]"

Sakuma等[8] Sakuma et al. [8] Nakano等[7] Nakano et al. [7]
分类
Classification
亚组
Subgroup
数量
No.
分类
Classification

Group
数量
No.
AP2亚家族
AP2 subfamily
17 AP2家族
AP2 family
18
2个AP2结构域
Two AP2 domains
14 2个AP2结构域
Two AP2 domains
14
1个AP2结构域
One AP2 domain
3 1个AP2结构域
One AP2 domain
4
DREB, ERF亚家族
DREB, ERF subfamily
121 ERF家族
ERF family
122
DREB亚家族
DREB subfamily
A (1-6) 56 I-IV 57
ERF亚家族
ERF subfamily
B (1-6) 65 V-X 58
VI-L and Xb-L 7
AL079349 1 At4g13040 1
RAV亚家族
RAV subfamily
6 RAV家族
RAV family
6
合计Total 145 合计Total 147

Fig. 1

Conserved domains of AP2/ERF transcription factors in plants[9]"

Table 2

Classification of the AP2/ERF transcription factor family in rice[10]"

亚家族
Subfamily
结构域组成
Domain architecture
结合元件
Binding cis-element
亚组
Subgroup
数量
No.
AP2 2个AP2结构域
Two AP2 domains
GCAC(A/G) N (A/T)
TCCC(A/G)ANG(C/T)
Ia 10
Ib 11
Ic 6
RAV 1个AP2结构域 One AP2 domain
1个B3结构域 One B3 domain
CAACA
CACCTG
II 5
ERF 1个AP2结构域
One AP2 domain
GCC-box(AGCCGCC) IIIa 32
IIIb 32
IIIc 16
CBF/DREB 1个AP2结构域
One AP2 domain
DRE/CRT(A/GCCGAC) IVa 10
IVb 6
IVc 16
IVd 24
Soloist 1个AP2/ERF结构域
One AP2/ERF domain
Soloist 2
合计Total 170

Table 3

Rice AP2/ERF transcription factors involved in stress responses"

亚家族
Subfamily
基因
Gene
结合元件
Binding cis-element
参与胁迫类型
Stresses involved in
参考文献
References
ERF OsEREBP1 GCC-box 正调控水稻抗病性和耐旱性
Positive regulation of disease resistance and drought tolerance in rice
[30]
OsERF83 GCC-box 正调控水稻抗病性
Positive regulation of disease resistance in rice
[31]
OsAP2/ERF152 正调控水稻抗病性
Positive regulation of disease resistance in rice
[32]
OsERF922 负调控水稻抗病性和耐盐性
Negative regulation of disease resistance and salt tolerance in rice
[33]
OsEBP89 GCC-box 负调控水稻耐旱性
Negative regulation of drought tolerance in rice
[34]
OsERF3/OsAP37 GCC-box 负调控水稻耐旱性
Negative regulation of drought tolerance in rice
[37]
OsDERF1 GCC-box 负调控水稻耐旱性
Negative regulation of drought tolerance in rice
[40]
OsERF109 GCC-box/DRE/CRT 负调控水稻耐旱性
Negative regulation of drought tolerance in rice
[41]
OsERF48 正调控水稻耐旱性
Positive regulation of drought tolerance in rice
[42]
OsERF71 正调控水稻耐旱性
Positive regulation of drought tolerance in rice
[43-45]
OsERF101 正调控水稻耐旱性
Positive regulation of drought tolerance in rice
[45]
OsSERF1 正调控水稻耐盐性
Positive regulation of salt tolerance in rice
[46]
OsAP23 GCC-box 负调控水稻耐盐性
Negative regulation of salt tolerance in rice
[49]
DREB OsDREB1A DRE/CRT 正调控水稻耐冷性
Positive regulation of cold tolerance in rice
[53]
OsDREB1B DRE/CRT 正调控水稻耐冷性
Positive regulation of cold tolerance in rice
[53]
OsDREB1D DRE/CRT/LTRE 正调控拟南芥耐冷和耐盐性
Positive regulation of cold and salt tolerance in Arabidopsis
[54]
OsDREB1E DRE/CRT 受冷胁迫和干旱诱导
Induced by cold and drought stress
[55]
OsDREB1F DRE/CRT 正调控水稻耐盐、耐旱和耐冷性
Positive regulation of salt, drought and cold tolerance in rice
[56]
OsDREB1G DRE/CRT 正调控水稻耐冷性
Positive regulation of cold tolerance in rice
[19]
OsDREB2A DRE/CRT 正调控水稻耐盐和耐旱性
Positive regulation of salt and drought tolerance in rice
[66,70]
亚家族
Subfamily
基因
Gene
结合元件
Binding cis-element
参与胁迫类型
Stresses involved in
参考文献
References
DREB OsDREB2B DRE/CRT 受干旱、盐和冷胁迫诱导
Induced by drought, salt and cold stress
[59]
OsDREB2C 受干旱和盐胁迫诱导
Induced by drought and salt stress
[59]
OsDREB6 DRE/CRT 正调控水稻耐冷性
Positive regulation of cold tolerance in rice
[65]
ARAG1 DRE/CRT 正调控水稻耐旱性
Positive regulation of drought tolerance in rice
[67]
OsAP21 正调控拟南芥耐旱和耐盐性
Positive regulation of drought and salt tolerance in Arabidopsis
[71]
RAV OsRAV2 GT-1 正调控水稻耐盐性
Positive regulation of salt tolerance in rice
[72]
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