AtMYB77促进NO合成参与调控干旱胁迫下拟南芥侧根发育

转录因子MYB77与信号分子一氧化碳(NO)是侧根发育的重要调节因子,但MYB77和NO在干旱胁迫下侧根发生中的作用及机制尚不明确。该文以拟南芥(Arabidopsis thaliana)野生型、AtMYB77缺失突变体Atmyb77-1及过表达株系AtOE77-1和AtOE77-3为材料,研究了MYB77和NO在干旱...     

Folding and misfolding mechanisms of the p53 DNA binding domain at physiological temperature

p53 modulates a large number of cellular response pathways and is critical for the prevention of cancer. Wild-type p53, as well as tumorigenic mutants, exhibits the singular property of spontaneously losing DNA binding activity at 37 degrees C. To understand the molecular basis for this effect, we examine the folding mechanism of the p53 DNA binding domain (DBD) at elevated temperatures. Folding kinetics do not change appreciably from 5 degrees C to 35 degrees C. DBD therefore folds by the same two-channel mechanism at physiological temperature as it does at 10 degrees C. Unfolding rates, however, accelerate by 10,000-fold. Elevated temperatures thus dramatically increase the frequency of cycling between folded and unfolded states. The results suggest that function is lost because a fraction of molecules become trapped in misfolded conformations with each folding-unfolding cycle. In addition, at 37 degrees C, the equilibrium stabilities of the off-pathway species are predicted to rival that of the native state, particularly in the case of destabilized mutants. We propose that it is the presence of these misfolded species, which can aggregate in vitro and may be degraded in the cell, that leads to p53 inactivation.     

p53 mutants without a functional tetramerisation domain are not oncogenic

p53 is altered in about 50 % of cancers. Most of the p53 mutants have lost the wild-type tumour suppressor activity but show oncogenic properties. The majority of the p53 alterations are missense mutations of residues located in its DNA binding domain (DBD). Only a few mutations concern residues in its tetramerisation domain (TD). However, the study of mutant proteins identified in tumors that do not form tetramers has shown that they have lost the wild-type activity like most of the p53 DBD mutants. Here, we show that two of such mutant proteins, Arg342Pro and Leu344Pro are not dominant negative and do not stimulate the expression of a reporter gene under the control of the multi-drug resistance gene-1 (MDR-1). This suggests that to be oncogenic, p53 mutants need to form tetramers. Accordingly, the dominant negative effect and the ability of a tetrameric mutant protein, Asp281Gly, to stimulate the MDR-1 promoter are abolished when its TD is rendered non-functional by the mutation of leucine 344 to a proline residue. These results suggest that mutations in the TD, are less selected in tumors than mutations in the DBD because they do not lead to oncogenic proteins.     

Functional Mapping of the DNA Binding Domain of Bovine Papillomavirus E1 Protein

Bovine papillomavirus type 1 (BPV-1) requires viral proteins E1 and E2 for efficient DNA replication in host cells. E1 functions at the BPV origin as an ATP-dependent helicase during replication initiation. Previously, we used alanine mutagenesis to identify two hydrophilic regions of the E1 DNA binding domain (E1DBD), HR1 (E1(179-191)) and HR3 (E1(241-252)), which are critical for sequence-specific recognition of the papillomavirus origin. Based on sequence and structure, these regions are similar in spacing and location to DNA binding regions A and B2 of T antigen, the DNA replication initiator of simian virus 40 (SV40). HR1 and A are both part of extended loops which are supported by residues from the HR3 and B2 alpha-helices. Both elements contain basic residues which may contact DNA, although lack of cocrystal structures for both E1 and T antigen make this uncertain. To better understand how E1 interacts with origin DNA, we used random mutagenesis and a yeast one-hybrid screen to select mutations of the E1DBD which disrupt sequence-specific DNA interactions. From the screen we selected seven single point mutants and one double point mutant (F175S, N184Y/K288R, D185G, V193M, F237L, K241E, R243K, and V246D) for in vitro analysis. All mutants tested in electrophoretic mobility shift assays displayed reduced sequence-specific DNA binding compared to the wild-type E1DBD. Mutants D185G, F237L, and R243K were rescued in vitro for DNA binding by the replication enhancer protein E2. We also tested the eight mutations in full-length E1 for the ability to support DNA replication in Chinese hamster ovary cells. Only mutants D185G, F237L, and R243K supported significant DNA replication in vivo which highlights the importance of E1DBD-E2 interactions for papillomavirus DNA replication. Based on the specific point mutations examined, we also assigned putative roles to individual residues in DNA binding. Finally, we discuss sequence and spacing similarities between E1 HR1 and HR3 and short regions of two other DNA tumor virus origin-binding proteins, SV40 T antigen and Epstein-Barr virus nuclear antigen 1 (EBNA1). We propose that all three proteins use a similar DNA recognition mechanism consisting of a loop structure which makes base-specific contacts (HR1) and a helix which primarily contacts the DNA backbone (HR3).     

巴西橡胶树HbMYB62转录因子基因的克隆和表达分析

R2R3-MYB类转录因子参与包括逆境胁迫反应等多种生物反应。为鉴定橡胶树中MYB转录因子的结构与功能,从橡胶树叶片中克隆HbMYB62全长的cDNA序列。该基因片段大小为1 013 bp,包含945 bp的ORF,编码314个氨基酸残基。其推导的氨基酸序列具有植物HTH_MYB的特异性结构域,并与拟南芥AtMYB62具有高度相似性。qRT-PCR发现HbMYB62主要在橡胶树花中表达,而在树皮、叶和乳胶中表达量较少。其叶片表达量在过氧化氢（H₂O₂）、脱落酸（ABA）、水杨酸（SA）等处理下显著上调。表明HbMYB62与橡胶树的抗逆反应和激素信号传导过程有关,为进一步研究其结构和功能打下基础。     

Structure,function, and aggregation of the zinc-free form of the p53 DNA binding domain

The p53 DNA binding domain (DBD) contains a single bound zinc ion that is essential for activity. Zinc remains bound to wild-type DBD at temperatures below 30 degrees C; however, it rapidly dissociates at physiological temperature. The resulting zinc-free protein (apoDBD) is folded and stable. NMR spectra reveal that the DNA binding surface is altered in the absence of Zn(2+). Fluorescence anisotropy studies show that Zn(2+) removal abolishes site-specific DNA binding activity, although full nonspecific DNA binding affinity is retained. Surprisingly, the majority of tumorigenic mutations that destabilize DBD do not appreciably destabilize apoDBD. The R175H mutation instead substantially accelerates the rate of Zn(2+) loss. A considerable fraction of cellular p53 may therefore exist in the folded zinc-free form, especially when tumorigenic mutations are present. ApoDBD appears to promote aggregation of zinc-bound DBD via a nucleation-growth process. These data provide an explanation for the dominant negative phenotype exhibited by many mutations. Through a combination of induced p53 aggregation and diminished site-specific DNA binding activity, Zn(2+) loss may represent a significant inactivation pathway for p53 in the cell.