《真核生物基因表达调控PPT》由会员分享,可在线阅读,更多相关《真核生物基因表达调控PPT(66页珍藏版)》请在金锄头文库上搜索。
1、Eukaryotic Gene Expression and Regulation第八章第八章真核基因表达调控真核基因表达调控本章主要内容本章主要内容1.基因表达与调控的基本概念与原理基因表达与调控的基本概念与原理2.转录水平的调控转录水平的调控(transcriptional regulation): uDNA level (Genetic)uChromatin level (Epigenetic)3.转录后水平的调控转录后水平的调控(post-transcriptional regulation):uRNA interference ( (RNAi) )uProtein degradati
2、on ( (Ubiquitin/proteasome) )第第 一一 节节基本概念与原理基本概念与原理Basic Concepts and PrinciplesGenome(cells repertoire of DNA)Transcriptome(cells repertoire of RNA transcripts)Proteome(cells repertoire of proteins)单个基因单个基因单个细胞单个细胞中心法则中心法则一、基因表达的概念一、基因表达的概念基因组基因组(genome)一个细胞或病毒所携带的全部遗传信息或整一个细胞或病毒所携带的全部遗传信息或整套基因。套基因
3、。基因表达基因表达(gene expression)基因经过转录、翻译,产生具有特异生物学功基因经过转录、翻译,产生具有特异生物学功能的能的蛋白质蛋白质分子或分子或RNA分子的过程。分子的过程。基因表达调控基因表达调控(gene regulation, or regulation of gene expression) 基因表达是受内源及外源信号调控的。基因表达是受内源及外源信号调控的。Regulation of Gene ExpressionChromatinepigenetic controlRNA silencingProteindegradation一般而言的基因表达调控范畴一般而言的
4、基因表达调控范畴二、基因表达的时间性及空间性二、基因表达的时间性及空间性(一)时间特异性(一)时间特异性按功能需要,某一特定基因的表达严格按按功能需要,某一特定基因的表达严格按特定的时间顺序发生,称之为基因表达的特定的时间顺序发生,称之为基因表达的时间时间特异性特异性(temporal specificity)。 多细胞生物基因表达的时间特异性又称多细胞生物基因表达的时间特异性又称阶阶段特异性段特异性(stage specificity)。人体发育过程中不同类型人体发育过程中不同类型-珠蛋白的含量变化珠蛋白的含量变化 (二)空间特异性(二)空间特异性基基因因表表达达伴伴随随时时间间顺顺序序所所
5、表表现现出出的的这这种种分分布布差差异异,实实际际上上是是由由细细胞胞在在器器官官的的分分布布决决定定的的,所所以以空空间间特特异异性性又又称称细细胞胞或或组组织织特特异异性性(cell or tissue specificity)。在在个个体体生生长长全全过过程程,某某种种基基因因产产物物在在个个体体按按不不同同组组织织空空间间顺顺序序出出现现,称称之之为为基基因因表表达达的的空间特异性空间特异性(spatial specificity)。BARD1 is expressed specifically in the apical domains of Arabidopsis inflores
6、cence (A), ovules (B), anthers (C), and embryos (D).In suit hybridizationA, B, C, D: antisense BARD1 probe;E: sense BARD1 probe as a negative control.(朱玉贤第五章课件)(朱玉贤第五章课件)四种母源影响基因的四种母源影响基因的mRNA和蛋白沿果蝇和蛋白沿果蝇胚胎前胚胎前-后轴分布的后轴分布的浓度变化图浓度变化图 proteinBICOIDNANOS第十章(基因和发育)第十章(基因和发育)mRNAFacts Identical genome: Vi
7、rtually every cell in an organism contains a complete set of genes Spatial specificity: But they are not all turned on in every cell or tissueTemporal specificity: Each cell of an organism expresses a distinctive subset of genes at different time or developmental stageTight regulation: During develo
8、pment different cells express different sets of genes in a precisely regulated fashion三、基因表达的方式三、基因表达的方式按对刺激的反应性,基因表达的方式分为:按对刺激的反应性,基因表达的方式分为:(一)组成性表达(一)组成性表达 (constitutive expression)某某些些基基因因在在一一个个个个体体的的几几乎乎所所有有细细胞胞中中持持续续表表达达,通通常常被被称称为为管管家家基基因因(housekeeping gene)。这这类类基基因因表表达达又又称称为为组组成成性性基基因因表表达达(co
9、nstitutive gene expression)(constitutive gene expression)。genes for essential cellular structures and metabolic pathways (e.g. rRNA, actin, tubulin)usually expressed at high levelthe level of their gene expression may vary Housekeeping genesrRNA, actin, tubulin are commonly used as loading control i
10、n RT-PCR or Northern blot(二)诱导和阻遏表达(二)诱导和阻遏表达在在特特定定环环境境信信号号刺刺激激下下,相相应应的的基基因因被被激激活活,基基因因表表达达产产物物增增加加,这这种种基基因因称称为为可可诱诱导导基因基因 (inducible genes)。 如如果果基基因因对对环环境境信信号号应应答答是是被被抑抑制制,这这种种基因是基因是可阻遏基因可阻遏基因 (repressible genes)。基因表达调控大多数是对这些基因的转基因表达调控大多数是对这些基因的转录和翻译速率的调节录和翻译速率的调节,从而导致其编码产从而导致其编码产物的水平发生改变,影响其功能。物的
11、水平发生改变,影响其功能。四、基因表达调控的生物学意义四、基因表达调控的生物学意义(一)维持细胞增殖、分化(一)维持细胞增殖、分化(二)维持个体生长、发育(二)维持个体生长、发育 (三)适应环境变化(三)适应环境变化第九、十章(基因与疾病、基因与发育)将要讲到第九、十章(基因与疾病、基因与发育)将要讲到 1. Transcripts (转录本)begin and end beyond the coding region (5UTR and 3UTR)2. The primary transcript is processed by: 5 capping 3 formation / polyA
12、splicing3. Mature transcripts are transported to the cytoplasm for translation一般而言,基因表达调控主要是发生在基因转录一般而言,基因表达调控主要是发生在基因转录水平上的调节,即:水平上的调节,即:mRNAmRNA合成的多少。合成的多少。transcription五、基因转录调节基本要素五、基因转录调节基本要素(一)(一)RNA聚合酶聚合酶 (RNA Polymerase)(二)特异(二)特异DNA序列序列 (cis-acting elements)(三)调节蛋白(三)调节蛋白 (trans-acting facto
13、rs)Gene expression regulation at the level of DNA (transcriptional regulation)-highly sequence-dependent-varied regulation for different genescis-acting elements: promoters/regulatory sequences of genestrans-acting factors: proteins and RNAs that bind cis-elements and promote or repress gene express
14、ion (一一) RNA聚合酶聚合酶启动子、调节序列和调节蛋白通过启动子、调节序列和调节蛋白通过DNA-蛋白质相互作蛋白质相互作用、蛋白质用、蛋白质-蛋白质相互作用影响蛋白质相互作用影响RNA聚合酶活性。聚合酶活性。RNARNA PolPol I:I: rRNA,rRNA, 相对活性相对活性50-70%50-70%RNARNA PolPol IIII: : mRNAmRNA, ,相对活性相对活性20-40%20-40%RNA Pol III: tRNA,RNA Pol III: tRNA,相对活性相对活性10%10%RNA Pol IV: small ncRNA,RNA Pol IV: sma
15、ll ncRNA,相对活性相对活性?真核生物基因组中含有可以调控真核生物基因组中含有可以调控自身自身基因表达活性的特异基因表达活性的特异DNADNA序列,称为序列,称为顺式作用元件顺式作用元件 (cis-acting element)(cis-acting element)。 顺式作用元件顺式作用元件能够被转录调节蛋白特异识别和结合,从而影能够被转录调节蛋白特异识别和结合,从而影响基因表达活性。响基因表达活性。 启动子启动子 (promoter)(promoter) 顺式作用元件顺式作用元件又分又分 增强子增强子 (enhancer)(enhancer) 沉默子沉默子 (silencer)(s
16、ilencer)En/SiProDNA编码序列编码序列转录起始点转录起始点 (二)特异(二)特异DNA序列序列反式作用因子反式作用因子 (trans-acting factor) 能直接或间接与能直接或间接与顺式作用元件顺式作用元件相互作用,进而调控基相互作用,进而调控基因转录的一类调节蛋白,统称为因转录的一类调节蛋白,统称为反式作用因子反式作用因子。 按其功能不同,常有以下三类:按其功能不同,常有以下三类: 基本转录因子基本转录因子 :识别识别promoter元件元件 转录调节因子转录调节因子:识别识别enhancer或或silencer 共调节因子:不能进行共调节因子:不能进行DNA-蛋白
17、质相互作用蛋白质相互作用(三)真核基因的调节调节蛋白(三)真核基因的调节调节蛋白RNA聚合酶聚合酶在转录因子帮助下,形成的转录起始复合物在转录因子帮助下,形成的转录起始复合物polTFHTAFTFFTAFTAFTFATFBTBPTATA DNATAF: TBP associated factorsholoenzyme1. 1. 基本转录因子基本转录因子 (general transcription factor, GTF) 是是指指能能够够直直接接或或间间接接与与启启动动子子核核心心序序列列TATATATA盒盒特特异异结结合合、并启动转录的一类调节蛋白。并启动转录的一类调节蛋白。TBP: TA
18、TA-box binding proteinTFII: pol II associated TF2. 2. 转录调节因子转录调节因子 (transcription factor, TF) 这类调节蛋白能识别并结合转录起始点的上游序列和远这类调节蛋白能识别并结合转录起始点的上游序列和远端的增强子元件,通过端的增强子元件,通过DNADNA蛋白质相互作用而调节转录活性。蛋白质相互作用而调节转录活性。决定不同基因的时间、空间特异性表达决定不同基因的时间、空间特异性表达. .转录激活因子转录激活因子(transcriptional activator)转录阻遏因子转录阻遏因子(transcription
19、al repressor)3. 3. 共调节因子共调节因子 (transcriptional regulator/ co-factor) 首先与转录因子发生蛋白蛋白相互作用,进而影响它们首先与转录因子发生蛋白蛋白相互作用,进而影响它们的分子构象,以调节转录活性的分子构象,以调节转录活性, ,本身无本身无DNADNA结合活性。结合活性。 如果与转录激活因子有协同作用如果与转录激活因子有协同作用共激活因子;共激活因子; 与转录阻遏因子有协同作用与转录阻遏因子有协同作用共阻遏因子。共阻遏因子。常见转录因子的结构域常见转录因子的结构域 (domain)DNA结合域结合域 (DNA binding do
20、main)Basic AA (K/R) rich, positively charged转录激活域转录激活域(trans-activation domain)TF蛋白质蛋白质-蛋白质结合域蛋白质结合域(dimerization, co-factors) 谷氨酰胺谷氨酰胺(Q)(Q)富含域富含域酸性激活域酸性激活域 (D/E-rich)脯氨酸脯氨酸(P)富含域富含域Zinc FingerbHLHbZIPHomeodomain1) TF最常见的最常见的DNA binding domain(1) 锌指锌指(zinc finger)常结合常结合GC boxCys-X2-4-Cys-X3-Phe-X5-
21、Leu-X2-His-X3-HisC-terminal: -helix binding DNA(2) 碱性亮氨酸拉链碱性亮氨酸拉链 bZIPbHLHbHLH蛋白蛋白(basic Helix-Loop-Helix)(basic Helix-Loop-Helix)(3) 碱性螺旋碱性螺旋-环环-螺旋螺旋bHLH2) TF常见的常见的trans-activation domain(Activation domain is interchangeable)Interaction AssaysDesign of Two-hybrid / Three-hybrid /etcseparable functi
22、onal domainsTwo-hybrid assay(protein-protein)Tri-hybrid assay(protein-RNA)1. RNA polymerase II2. promoter and enhancers3. transcription factorsEukaryotic gene expression is usually controlled at the level of initiation of transcription.真核基因转录起始的调控真核基因转录起始的调控 Holoenzyme - a supramolecular complex com
23、prising Pol II, most GTFs, and Mediator/Srb complex In yeast, a 2MDa holoenzyme + TBP suffices for transcriptionOrdered Assembly and Pol II HoloenzymeTFIIDTFIIDone-stepmultiple-stepTFIIB binds to DNA and contacts RNA polymerase near the RNA exit site and at the active center, and orients it on DNA.+
24、25bpQ: prok -10bp vs euk -25bp?Sequential AssemblyTBP: TATA binding proteinTAFs: TBP associated factorsBinding of TFIID (TBP + 11 TAFs, 800KD) to the TATA box is the first step in initiation.CTD:RNA Pol II C-terminal domainCTD is an unusual extension appended to the C terminus of the largest subunit
25、 of RNA polymerase II. It comprises from 25 to 52 tandem copies of the consensus repeat heptad Y1S2P3T4S5P6S7.S2 and S5 are major phosphorylation sites.CTD phosphorylation cause the conversion of proline isomerization states.Phosphorylation patterns on the CTD repeats determine different sets of ass
26、ociated factors, so that provide a dynamic platform to recruit different regulators of the transcription apparatus.In eukaryotic cells, the transcription of genes is accurately orchestrated both spatially and temporally by the C-terminal domain of RNA polymerase II (CTD). PIC: PhosphoS5 is required
27、for assembly of the PIC and facilitates mRNA capping via recruitment of capping enzymes. Elongation: S5 gradually becomes dephosphorylated, whereas S2 is phosphorylated. Terminating: PhosphoS2 ensures efficient 3-RNA processing by triggering recruitment of 3-RNA processing machinery. Ending: CTDs ar
28、e free of phosphate groups; non-phosphorylated CTDs are required for RNA polymerase II to recycle and bind a promoter for the next cycle of transcription.S2 & S5, the trigger for transcriptional process modulationFactors involved in gene expression include RNA polymerase and the basal apparatus, act
29、ivators that bind directly to, co-activators that bind to both activators and the basal apparatus, and regulators that act on chromatin structure (chromatin remodeling complex).Many Transcriptional Activatorsi.e. CAATGC-boxNear the initiation siteA little far awaySP1 stimulates transcription in pres
30、ence of TAFII110 GC boxes bound by DNA binding protein SP1 SP1 recruits TFIID by binding TAFII110 Partially reconstituted complex (TBP and 3 TAFs) in addition to other GTFs, Pol II leads to high levels of transcription SV40 early promoterNearMediator complex is targeted by an activator Mediator is a
31、 stable complex containing several proteins (20-50) Mediator binds to the RNA pol II and transcription factors (activators or repressors) and mediates the regulatory signals to pol II (中介复合体)中介复合体)FarWhat is the mechanism of activation?Two models: 1.Tethering holoenzyme (recruitment)2.Activating hol
32、oenzyme (allosteric)(interaction activation)?In favor of recruitment model(勾引模型勾引模型)tat protein of HIV can stimulate transcription initiation without binding DNA at all The activating domain of the tat protein can stimulate transcription if it is tethered in the vicinity of promoter by binding to th
33、e RNA product (tar sequence) of a previous round of transcription.tartatDNA-binding domain is to bring the activation domain into the vicinity of the startpoint. And activation is independent of the means of tethering. we can think of DNA-binding (or RNA-binding in the case of tat) domain as providi
34、ng a tethering function, whose main purpose is to ensure that the activation domain is in the vicinity of the initiation complex.The notion of tethering is a more general idea that initiation requires a high concentration of transcription factors in the vicinity of the promoter.This may be achieved
35、when activators bind to enhancers, upstream promoter elements, or in an extreme case by tethering to a newly-made RNA product.总结总结 l 所有激活因子的共性:识别靶位点(启动子、增强子)的特异性由DNA结合域决定。l DNA结合域将转录激活域带到基础转录区域附近。l 直接作用的激活因子具有DNA结合域和转录激活域。 l 没有转录激活域的激活因子可能与具有转录激活域的共激活因子一起行使功能。l 基础转录区域中许多元件是(共)激活因子的靶位点l RNA聚合酶可以和多种不同
36、的转录因子相互作用,形成全酶复合物行使功能。Synergy High levels of transcription induced by multiple factors Transcription factors can enhance transcription in a non-linear manner Synergisitic activation occurs due to multiple contacts with the machinery Multiple copies of the same activator also induce synergistic activ
37、ationInterferon enhancer Enhancers often have binding sites for several transcription factors Transcription factors can bind cooperatively at adjacent sites Architectural factors (with no regulatory domains, i.e. HMG1) can assist assembly Remarkably increase binding affinity for both DNA and machine
38、ryHMG1肩并肩、手挽手,根基稳、魅力足肩并肩、手挽手,根基稳、魅力足香肩并立、玉指紧扣,脚如磐石、面若桃花香肩并立、玉指紧扣,脚如磐石、面若桃花One possible strategy: -Looping-Cohesins help to stabilize enhancer-promoter interactionsHow do enhancers act independent of distance and orientation?An enhancer may function by bringing proteins into the vicinity of the promo
39、ter. An enhancer does not act on a promoter at the opposite end of a long linear DNA, but becomes effective when the DNA is joined into a circle by a protein bridge. An enhancer and promoter on separate circular DNAs do not interact, but can interact when the two molecules are catenated.Two experime
40、nts support the looping model-The essential role of the enhancer is to increase the concentration of activator in the vicinity of the promoter-Receptors for many steroid and thyroid hormones have a similar organization, with an individual N-terminal region, conserved DNA-binding region, and a C-term
41、inal hormone-binding regionSteroid receptors are transcription factorsZinc finger TFGlucocorticoids regulate gene transcription bycausing their receptor to transport into the nucleus and bind to an enhancer whose action is needed for promoter function.Activation of Glucocorticoid Receptor (GR)Nuclea
42、r shuttling利用利用GR的特性构建可诱导表达融合蛋白系统的特性构建可诱导表达融合蛋白系统DexamethasoneGRGRGRXXXDexamethasone(DEX): 地塞米松,氟美松(抗炎药),合成的一种糖皮质激素;通过分子克隆的方法将GR和要研究的核蛋白X构建成融合蛋白,转基因到酵母、动物细胞或者植物中;不施加外源DEX时,融合蛋白与HSP90形成复合物,由于构象和空间位阻等原因,融合蛋白存在于胞质中,不能定位到细胞核;添加DEX时,DEX扩散入胞与GR相结合,融合蛋白改变构象后核定位信号暴露,即可入核行使功能;用以研究核蛋白的功能(包括转录因子)。Activation Ta
43、gging approach in plantsPlant transformation1.mutants screening2.locate T-DNA insertion site in Arabidopsis genome (how?)3.identify the right gene conferring mutant phenotype (how?) 构建T-DNA序列,其中包括4倍重复的CaMV的35S增强字序列,435S元件可以大大增强相邻基因的转录;通过转基因的方法将T-DNA片段整合到植物基因组中;植物基因组上与T-DNA插入位点相近的基因表达量增高,即得到这个基因gain-
44、of-function的转基因植物;XVELexA 的DNA结合域(X)VP16转录激活域(V)human estrogen receptor调控域(E)NPTII;转基因筛选标记OLexA-46:LexA操纵子CaMV 35S基本启动子(而非增强子) A chemical-inducible activation tagging vector pER16 in plants RB-LB: T-DNA fragment (可以插入到基因组中)其工作原理为:在G10-90启动子控制下,XVE 融合转录因子组成型表达;当加入雌激素,雌激素和受体调控域(E)结合,导致XVE融合蛋白构象发生变化,并由
45、细胞质转移进入核内;在细胞核内,XVE中的LexA DNA结合域(X)特异识别LexA操纵子区(OLexA),VP16的转录激活域(V)激活LB旁边的基因高水平表达。Enhancer TrapEnhancer trap的质粒包含一个报告基因(lacZ)和基本启动子,这段启动子不足以启动报告基因的表达,但是对增强子非常敏感。将这样的质粒整合到基因组中,如果插入位点附近有增强子报告基因就会表达。因此只要通过观测报告基因的表达情况(比如时空上的特异性)就可以知道这个增强子的作用,进而研究由这个增强子调控的内源基因的表达特性。ZFN 技术原理技术原理锌指核酸酶(Zinc-finger nuclease
46、s, ZFN)是人工改造的限制性核酸内切酶,利用不同的锌指结构识别特异DNA序列,利用核酸酶切断靶DNA。锌指结构中每一个螺旋可以特异识别3-4个碱基;人工设计识别特异DNA序列的螺旋采用如上的通用序列,通过改变其中7个X来实现识别不同的三联体碱基,TGEK是多个螺旋间的连接序列;构建成对人工锌指结构域和FokI融合蛋白(ZFN)可以在指定区域切断DNA双链。ZFN 技术锌指核酸酶介导的定向染色体删除研究人员可以利用ZFN技术进行各种基因编辑,比如基因敲除。已建立有ZFN库,识别多种DNA序列,但还不能达到识别任意靶DNA的目的,其应用受到一定的限制。TALEN=Transcription A
47、ctivator-Like Effector+FokI Nuclease fusion proteinTALEN 技术长度为34aa的重复肽段中的第12、13个氨基酸可以特异识别DNA单个碱基,形成2aa-1bp的特殊coden。利用这个特性可以人工设计识别任意碱基序列的TALE蛋白。TALE: transcription activator-like effector from Xanthomonas, TALE can specifically bind and regulate plant genes during pathogenesis.codon设计TALE结合位点接上报告基因(m
48、Cherry),同时构建一个特异识别这种TALE结合序列的的TALE蛋白,将两种质粒共同转入细胞,那么这个人工TALE蛋白可以启动报告基因mCherry的表达特异TALE蛋白与核酸内切酶FokI的融合蛋白可以切割特异识别序列下游9-13bp。基于这个原理,可以设计转基因融合蛋白敲除指定内源基因。设计一对识别果蝇tnikb基因的TALEN蛋白(left and right),内源tnikb将被FokI切开,转基因果蝇子代将有tnikb基因突变的个体。真核基因转录调节是真核基因转录调节是复杂的、多样的复杂的、多样的*不不同同的的DNA元元件件组组合合可可产产生生多多种种类类型型的的转转录录调节方式。调节方式。*多多种种转转录录因因子子又又可可结结合合相相同同或或不不同同的的DNA元元件。件。*转转录录因因子子与与DNA元元件件结结合合后后,对对转转录录激激活活过过程程所所产产生生的的效效果果各各异异,有有正正性性调调节节或或负负性性调调节之分。节之分。思考题:1、如何通过实验的方法分析CTD上S2和S5不同磷酸化pattern的功能?2、如何鉴定activation tagging的转基因植物中是哪个基因的表达上调而导致所观测的表型? 刚才的发言,如刚才的发言,如有不当之处请多指有不当之处请多指正。谢谢大家!正。谢谢大家!66