TINY, a dehydration-responsive element (DRE)-binding protein-like transcription factor connecting the DRE- and ethylene-responsive element-mediated signaling pathways in Arabidopsis

Dehydration-responsive element-binding proteins (DREBs) and ethylene-responsive element (ERE) binding factors are two major subfamilies of the AP2/ethylene-responsive element-binding protein family and play crucial roles in the regulation of abiotic- and biotic-stress responses, respectively. In the present work, we have reported a previously identified DREB-like factor, TINY, that was involved in both abiotic- and biotic-stress signaling pathways. TINY was capable of binding to both DRE and ERE with similar affinity and could activate the expression of reporter genes driven by either of these two elements in tobacco cells. The 15th amino acid in the APETALA2 (AP2)/ethylene-responsive element-binding factor domain was demonstrated to be essential for its specific binding to ERE, whereas the 14th and 19th amino acids were responsible for the binding to DRE. The expression of TINY was greatly activated by drought, cold, ethylene, and slightly by methyl jasmonate. Additionally, overexpression of TINY in Arabidopsis resulted in elevated expressions of both the DRE- and the ERE-containing genes. Moreover, the expression of DRE-regulated genes, such as COR6.6 and ERD10, was up-regulated upon ethylene treatment, and the expression of ERE-regulated genes, such as HLS1, was also increased by cold stress, when the expression of TINY was being induced. These results strongly suggested that TINY might play a role in the cross-talk between abiotic- and biotic-stress-responsive gene expressions by connecting the DRE- and ERE-mediated signaling pathways. The results herein might promote the understanding of the mechanisms of specific DNA recognition and gene expression regulation by DREBs.     

Determination of floral organ identity by Arabidopsis MADS domain homeotic proteins AP1, AP3, PI, and AG is independent of their DNA-binding specificity.

The MADS domain homeotic proteins APETALA1 (AP1), APETALA3 (AP3), PISTILLATA (PI), and AGAMOUS (AG) combinatorially specify the identity of Arabidopsis floral organs. AP1/AP1, AG/AG, and AP3/PI dimers bind to similar CArG box sequences; thus, differences in DNA-binding specificity among these proteins do not seem to be the origin of their distinct organ identity properties. To assess the overall contribution that specific DNA binding could make to their biological specificity, we have generated chimeric genes in which the amino-terminal half of the MADS domain of AP1, AP3, PI, and AG was substituted by the corresponding sequences of human SRF and MEF2A proteins. In vitro DNA-binding assays reveal that the chimeric proteins acquired the respective, and distinct, DNA-binding specificity of SRF or MEF2A. However, ectopic expression of the chimeric genes reproduces the dominant gain-of-function phenotypes exhibited by plants ectopically expressing the corresponding Arabidopsis wild-type genes. In addition, both the SRF and MEF2 chimeric genes can complement the pertinent ap1-1, ap3-3, pi-1, or ag-3 mutations to a degree similar to that of AP1, AP3, PI, and AG when expressed under the control of the same promoter. These results indicate that determination of floral organ identity by the MADS domain homeotic proteins AP1, AP3, PI, and AG is independent of their DNA-binding specificity. In addition, the DNA-binding experiments show that either one of the two MADS domains of a dimer can be sufficient to confer a particular DNA-binding specificity to the complex and that sequences outside the amino-terminal basic region of the MADS domain can, in some cases, contribute to the DNA-binding specificity of the proteins.     

AP2功能基因在植物花发育中的重要作用

AP2基因作为调控植物花发育的功能基因,参与花分生特性建立、花器官的特性特化以及形成调控。所编码的AP2/EREBP转录因子的主要特征是都至少含有一个由60到70个左右的氨基酸组成高度保守的DNA结合区,称作AP2结合域。按其所含的AP2结构域的数目分为3个亚族,即AP2亚家族、EREBP亚家族和RAV亚家族,每个亚家族都有各自的作用。AP2基因不但自身调控着花、胚珠的发育,而且与其他因子相互协作,参与到复杂的花发育调控网络。将对AP2基因的特征和分类及其在花发育中的作用进行概述。     

DNA-binding properties of Arabidopsis MADS domain homeotic proteins APETALA1, APETALA3, PISTILLATA and AGAMOUS.

The MADS domain proteins APETALA1 (AP1), APETALA3 (AP3), PISTILLATA (PI), and AGAMOUS (AG) specify the identity of Arabidopsis floral organs. AP1 and AG homocomplexes and AP3-PI heterocomplexes bind to CArG-box sequences. The DNA-binding properties of these complexes were investigated. We find that AP1, AG and AP3-PI are all capable of recognizing the same DNA-binding sites, although with somewhat different affinities. In addition, the three complexes induce similar conformational changes on a CArG-box sequence. Phasing analysis reveals that the induced distortion is DNA bending, oriented toward the minor groove. The molecular dissection of AP1, AP3, PI and AG indicates that the boundaries of the dimerization domains of these proteins vary. The regions required to form a DNA-binding complex include, in addition to the MADS box, the entire L region (which follows the MADS box) and the first putative amphipathic helix of the K box in the case of AP3-PI, while for AP1 and AG only a part of the L region is needed. The similarity of the DNA-binding properties of AP1, AP3-PI and AG is discussed with regard to the biological specificity that these proteins exhibit.     

Solution structure of the DNA-binding domain of interleukin enhancer binding factor 1 (FOXK1a)

Interleukin enhancer binding factor (ILF) binds to the interleukin-2 (IL-2) promoter and regulates IL-2 gene expression. In this study, the 3D structure of the DNA-binding domain of ILF was determined by multidimensional NMR spectroscopy. NMR structure analysis revealed that the DNA-binding domain of ILF is a new member of the winged helix/forkhead family, and that its wing 2 contains an extra alpha-helix. This is the first study to report the presence of a C-terminal alpha-helix in place of a typical wing 2 in a member of this family. This structural difference may be responsible for the different DNA-binding specificity of ILF compared to other winged helix/forkhead proteins. Our deletion studies of the fragments of ILF also suggest that the C-terminal region plays a regulatory role in DNA binding.     

茶树CsDREB-A1转录因子基因的克隆及其特性分析

基于茶树品种‘迎霜’（Camellia sinensis‘Yingshuang’）的转录组数据,采用PCR方法从其基因组DNA中克隆获得编码DREB转录因子的CsDREB-A1基因。结果显示：该基因的开放阅读框（ORF）长度为585 bp,编码194个氨基酸,该氨基酸序列即为CsDREB-A1转录因子。CsDREB-A1转录因子的N端含有AP2/ERF家族转录因子典型的AP2 DNA保守结合结构域,其中包含保守的YRG元件和WLG基序,且其第14位和第19位分别为缬氨酸和谷氨酸,该结构域的上、下游分别有PKK/RPAGRx KFx ETRHP和DSAW特征序列。通过进化分析可知CsDREB-A1转录因子属于AP2/ERF家族中DREB亚族的A1组,其与茶树CBF转录因子的相似性较高,与拟南芥〔Arabidopsis thaliana（Linn.）Heynh.〕等植物的DREB类转录因子也有较高的相似性。CsDREB-A1转录因子为亲水性蛋白,理论相对分子质量为21 165.4,理论等电点为p I 9.56,碱性、酸性、芳香族和脂肪族氨基酸比例分别为18%、10%、6%和18%;该转录因子只有1个包含53个氨基酸的无序化区域,且大部分无序化氨基酸位于AP2DNA保守结合结构域内,无序化氨基酸的比例为27.32%;在CsDREB-A1转录因子的三级结构中,N端有1个α螺旋、C端有3个β折叠。研究结果显示：CsDREB-A1转录因子可能与茶树的抗寒性相关。