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不同未知功能结构域蛋白家族(DUFs)基因在植物中的生物学功能 总被引:2,自引:0,他引:2
未知功能结构域蛋白家族(domains of unknown function protein families,DUFs)是一大群并未表征功能的蛋白家族,其蛋白结构中包含至少一个高度保守的DUF结构域。在众多的DUFs蛋白家族中存在一些植物特有的DUFs蛋白家族,其参与调控植物生长发育、植物对病虫害的防御反应和植物对非生物胁迫的应答反应等生物学过程。本文对近几年关于植物DUFs基因参与上述生物学功能方面的研究进行了综述,旨在为未知功能基因的挖掘及其调控机制的阐明提供基础资料。 相似文献
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植物同源结构域(plant homeodomain,PHD结构域),是真核生物中一种进化保守的锌指结构域.多种调控基因转录、细胞周期、凋亡的蛋白质含有PHD结构域.研究表明,PHD结构域涉及多种功能,包括蛋白质相互作用,特别是同核小体组蛋白的作用.目前认为,各种组蛋白修饰(包括甲基化、乙酰化、磷酸化、泛素化等)的模式和组合,调节染色质状态和基因转录活性,并提出了组蛋白密码理论.PHD指结构域能特异性识别组蛋白的甲基化(修饰)密码,可能是组蛋白密码的一种重要解读器. 相似文献
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植物同源盒基因的克隆与功能研究 总被引:3,自引:0,他引:3
同源盒基因在植物、动物、菌物的广泛存在说明这种结构在真核生物进化的早期就已出现,并暗示其具有重要功能。本文对植物同源盒基因的克隆与功能研究进行了综述,包括同源盒基因编码蛋白的结构特点、类型,并以玉米Knl、水稻OSH1及拟南芥STM为例,介绍了同源盒基因功能研究的现状。现有证据表明,同源盒基因与植物的发育过程有关。 相似文献
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PPR蛋白在陆生植物中属于最大的蛋白家族之一,其成员种类和数量均十分庞大。PPR蛋白主要的功能是通过在多种细胞器中进行定位从而参与细胞核和细胞器中特异单链RNA的转录后修饰和编辑,在植物生长发育的多个阶段均发挥着重要的作用。多数PPR蛋白编码基因的突变体呈现异常的发育表型,如胚胎致死、发育迟缓及绿化延迟等。对近年来植物PPR蛋白的分类、定位、RNA修饰的机制及其对植物生长发育影响进行了综述,并展望了植物PPR发挥功能区域和参与的调控网络研究。 相似文献
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溴结构域和超末端结构域(bromodomain and extraterminal domain, Bet)家族是表观基因组的调节因子,也是肿瘤细胞生存所依赖的肿瘤相关基因表达的关键驱动因子。溴结构域蛋白4 (bromodomain-containing protein 4, Brd4)是溴域和端外蛋白家族中的一员,通常识别乙酰化组蛋白,并定位于目的基因的启动子或增强子区域,启动并维持肿瘤相关基因的表达。Brd4与多种转录因子调控和染色质修饰密切相关,并参与DNA损伤修复、维持端粒功能,从而维持肿瘤细胞的存活。本文围绕Brd4蛋白的结构、功能及其抑制剂在肿瘤研究中的应用进行综述。 相似文献
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蛋白磷酸化修饰是植物细胞信号调控的普遍机制。植物-病原微生物互作过程中, 关键调控蛋白的磷酸化状态影响免疫信号的激活。多种病原微生物通过干扰宿主蛋白的磷酸化状态攻击免疫系统, 以提高致病性。该文对植物免疫调控过程中关键元件的磷酸化修饰及其在免疫信号中的调控作用进行了综述。研究植物-病原菌互作过程中关键蛋白的磷酸化修饰, 有助于深入探讨植物-病原微生物互作的分子机理。该文将为寻找广谱抗病的新途径提供理论依据。 相似文献
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热激蛋白(HSP)是一类在受到逆境刺激后大量表达的蛋白质, 能够帮助蛋白质正确折叠, 促使变性蛋白质降解, 缓解逆境胁迫对生物体的损伤。为揭示热激蛋白在耐旱的复苏植物中的保护作用, 该研究对复苏植物旋蒴苣苔(Boea hygrometrica)HSP40家族中J结构域蛋白BhDNAJC2的编码基因进行了克隆、表达与功能分析。Real-time PCR检测表明, 该基因受脱水、低温、热激等多种逆境条件和脱落酸(ABA)诱导表达。BhDNAJC2-YFP定位于细胞质、内质网和细胞核。过表达BhDNAJC2的拟南芥(Arabidopsis thaliana)株系在干旱、热激、盐胁迫和碱胁迫下均表现出明显的抗逆性。综上所述, BhDNAJC2可能在旋蒴苣苔抗旱、耐热及耐盐碱等胁迫反应中起关键作用。 相似文献
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Many over-wintering plants, through vernalization, overcome a block to flowering and thus acquire competence to flower in the following spring after experiencing prolonged cold exposure or winter cold. The vernalization pathways in different angiosperm lineages appear to have convergently evolved to adapt to temperate climates. Molecular and epigenetic mechanisms for vernalization regulation have been well studied in the crucifer model plant Arabidopsis thaliana.Here, we review recent progresses on the vernalization pathway in Arabidopsis. In addition, we summarize current molecular and genetic understandings of vernalization regulation in temperate grasses including wheat and Brachypodium, two monocots from Pooideae, followed by a brief discussion on divergence of the vernalization pathways between Brassicaceae and Pooideae. 相似文献
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Jean Choi Youbong Hyun Min-Jeong Kang Hye In Yun Jae-Young Yun Clare Lister Caroline Dean Richard M. Amasino Bosl Noh Yoo-Sun Noh Yeonhee Choi 《The Plant journal : for cell and molecular biology》2009,57(5):918-931
The epigenetic regulation of the floral repressor FLOWERING LOCUS C ( FLC ) is one of the critical factors that determine flowering time in Arabidopsis thaliana . Although many FLC regulators, and their effects on FLC chromatin, have been extensively studied, the epigenetic resetting of FLC has not yet been thoroughly characterized. Here, we investigate the FLC expression during gametogenesis and embryogenesis using FLC::GUS transgenic plants and RNA analysis. Regardless of the epigenetic state in adult plants, FLC expression disappeared in gametophytes. Subsequently, FLC expression was reactivated after fertilization in embryos, but not in the endosperm. Both parental alleles contributed equally to the expression of FLC in embryos. Surprisingly, the reactivation of FLC in early embryos was independent of FRIGIDA (FRI) and SUPPRESSOR OF FRIGIDA 4 (SUF4) activities. Instead, FRI , SUF4 and autonomous-pathway genes determined the level of FLC expression only in late embryogenesis. Many FLC regulators exhibited expression patterns similar to that of FLC , indicating potential roles in FLC reprogramming. An FVE mutation caused ectopic expression of FLC in the endosperm. A mutation in PHOTOPERIOD-INDEPENDENT EARLY FLOWERING 1 caused defects in FLC reactivation in early embryogenesis, and maintenance of full FLC expression in late embryogenesis. We also show that the polycomb group complex components, Fertilization-Independent endosperm and MEDEA, which mediate epigenetic regulation in seeds, are not relevant for FLC reprogramming. Based on our results, we propose that FLC reprogramming is composed of three phases: (i) repression in gametogenesis, (ii) reactivation in early embryogenesis and (iii) maintenance in late embryogenesis. 相似文献
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Sheldon CC Finnegan EJ Dennis ES Peacock WJ 《The Plant journal : for cell and molecular biology》2006,45(6):871-883
Prolonged exposure to cold results in early flowering in Arabidopsis winter annual ecotypes, with longer exposures resulting in a greater promotion of flowering than shorter exposures. The promotion of flowering is mediated through an epigenetic down-regulation of the floral repressor FLOWERING LOCUS C (FLC). We present results that provide an insight into the quantitative regulation of FLC by vernalization. Analysis of the effect of seed or plant cold treatment on FLC expression indicates that the time-dependent nature of vernalization on FLC expression is mediated through the extent of the initial repression of FLC and not by affecting the ability to maintain the repressed state. In the over-expression mutant flc-11, the time-dependent repression of FLC correlates with the proportional deacetylation of histone H3. Our results indicate that sequences within intron 1 and the activities of both VERNALIZATION1 (VRN1) and VERNALIZATION2 (VRN2) are required for efficient establishment of FLC repression; however, VRN1 and VRN2 are not required for maintenance of the repressed state during growth after the cold exposure. SUPPRESSOR OF OVER-EXPRESSION OF CO 1 (SOC1), a downstream target of FLC, is quantitatively induced by vernalization in a reciprocal manner to FLC. In addition, we show that SOC1 undergoes an acute induction by both short and long cold exposures. 相似文献
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Jean Finnegan E Kovac KA Jaligot E Sheldon CC James Peacock W Dennis ES 《The Plant journal : for cell and molecular biology》2005,44(3):420-432
FLOWERING LOCUS C (FLC), a repressor of flowering, is a major determinant of flowering time in Arabidopsis. FLC expression is repressed by vernalization and in plants with low levels of DNA methylation, resulting in early flowering. This repression is not associated with changes of DNA methylation within the FLC locus in either vernalized plants or plants with low levels of DNA methylation. In both cases, there is a reduction of histone H3 trimethyl-lysine 4 (K4) and acetylation of both histones H3 and H4 around the promoter-translation start of FLC. The expression of the two genes flanking FLC is also repressed in both conditions and repression is associated with decreased histone H3 acetylation. The changes in histone modifications at the FLC gene cluster, which are similar in vernalized plants and in plants with reduced DNA methylation, must arise by different mechanisms. VERNALIZATION 1, VERNALIZATION 2 and VERNALIZATION INSENSITIVE 3 modulate FLC expression in vernalized plants; these proteins play no role in the downregulation of FLC in plants with low levels of DNA methylation. Chimeric FLC::GUS transgenes respond to vernalization but these same transgenes show a position-dependent response to low levels of DNA methylation. In plants with reduced DNA methylation, expression of the five MADS AFFECTING FLOWERING (MAF) genes is repressed, suggesting that DNA methylation alters the expression of a trans-acting regulator common to FLC and members of the related MAF gene family. Our observations suggest that DNA methylation is not part of the vernalization pathway. 相似文献
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Benlloch R Kim MC Sayou C Thévenon E Parcy F Nilsson O 《The Plant journal : for cell and molecular biology》2011,67(6):1094-1102
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An early flowering mutant of Arabidopsis, elf32-D was isolated from activation tagging screening. The mutant flowered earlier than wild type under both long day and short
day conditions. The mutant phenotype was caused by overexpression of a Kunitz-type trypsin inhibitor gene (AtKTI1). The expression of AtKTI1 was detected in leaves, flowers, siliques and roots. In the vegetative state, no change of flowering integrator gene expression
was observed for AtKTI1 overexpressing plants. In contrast, at the reproductive stage, its overexpression resulted in the
down-regulation of FLC, a strong floral repressor which integrates the autonomous and vernalization pathways and also the up-regulation of FT and AP1, which are downstream floral integrator genes. It is probable that the AtKTI1 overexpression inhibits components of the flowering
signaling pathway upstream of FLC, eventually regulating expression of FLC, or causing perturbations in plant metabolism and thus indirectly affecting flowering. 相似文献
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Proveniers M Rutjens B Brand M Smeekens S 《The Plant journal : for cell and molecular biology》2007,52(5):899-913
Floral induction is controlled by a plethora of genes acting in different pathways that either repress or promote floral transition at the shoot apical meristem (SAM). During vegetative development high levels of floral repressors maintain the Arabidopsis SAM as incompetent to respond to promoting factors. Among these repressors, FLOWERING LOCUS C (FLC) is the most prominent. The processes underlying downregulation of FLC in response to environmental and developmental signals have been elucidated in considerable detail. However, the basal induction of FLC and its upregulation by FRIGIDA (FRI) are still poorly understood. Here we report the functional characterization of the ARABIDOPSIS THALIANA HOMEOBOX 1 (ATH1) gene. A function of ATH1 in floral repression is suggested by a gradual downregulation of ATH1 in the SAM prior to floral transition. Further evidence for such a function of ATH1 is provided by the vernalization-sensitive late flowering of plants that constitutively express ATH1. Analysis of lines that differ in FRI and/or FLC allele strength show that this late flowering is caused by upregulation of FLC as a result of synergism between ATH1 overexpression and FRI. Lack of ATH1, however, results in attenuated FLC levels independently of FRI, suggesting that ATH1 acts as a general activator of FLC expression. This is further corroborated by a reduction of FLC-mediated late flowering in fca-1 and fve-1 autonomous pathway backgrounds when combined with ath1. Since other floral repressors of the FLC clade are not significantly affected by ATH1, we conclude that ATH1 controls floral competency as a specific activator of FLC expression. 相似文献
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The FLOWERING LOCUS C (FLC) gene controls the transition of arabidopsis plants to flowering following cold induction (vernalization). Time to flowering in annual and biennial species of Brassicaceae supposedly depends on the number of FLC copies. We analyzed DNA restriction fragment length polymorphism in six Brassica species with diploid (AA, BB, and CC) and allotetraploid (AABB, AACC, and BBCC) genomes using for a hybridization probe an FLC homolog previously cloned in our laboratory from B. juncea. The characteristic variations in the patterns of restriction fragments corresponded to the genomic composition of Brassica species and, in some cases, correlated with the timing of floral transition.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 3, 2005, pp. 399–405.Original Russian Text Copyright © 2005 by Martynov, Khavkin. 相似文献