SUMO蛋白酶Ulp1的高效表达纯化并通过His-SUMO标签制备scFv

SUMO蛋白酶(Ulp1)是切割小分子泛素修饰(SUMO)融合蛋白获得天然N端靶蛋白的一种工具酶,具有酶切效率高、特异性好等优点。但现有市售SUMO蛋白酶Ulp1价格昂贵、操作复杂,限制了SUMO融合体系的运用。利用基因工程技术,合成基因ulp1(Leu403-Lys621),并在N端和C端加入多聚组氨酸标签(His_6),构建重组表达载体psv T7-ulp1,将重组质粒转入大肠杆菌BL21(DE3)和BL21 trx B(DE3)中。经过高通量筛选技术快速确定最优的表达条件为采用BL21(DE3)作为表达宿主,转接后7h加入IPTG,IPTG的终浓度为0.1mmol/L,诱导时间为16h,最终蛋白质表达量占菌体总蛋白质量的34.5%,重组蛋白Ulp1的表达量为190mg/L,通过Ni-NTA一步纯化即可得到纯度95%以上的Ulp1。通过酶切反应,测定酶活为5.19U/μl,比酶活为5.23×10~4U/mg,是先前报道比酶活的1.87倍,通过酶活动力学分析,Ulp1的表观米氏常数K_m=0.359g/L,V_m=5.10μg/(ml·min)。将SUMO融合表达体系用于单链抗体(single-chain antibody fragment,scFv)的表达,得到可溶的SUMO-scFv融合蛋白,使用表达的Ulp1进行酶切并纯化,获得纯度高于90%且N端不含多余氨基酸的scFv,操作步骤简单,显著改善了scFv在大肠杆菌中难以高效可溶性表达纯化的现状。     

小泛蛋白样修饰物双荧光融合蛋白及其特异性蛋白酶的原核表达及鉴定

本实验克隆了人的4种SENP(Sentrin-specific protease)C端催化结构域、3种SUMO(Smallubiq uitin-like modifer)、ECFP(Enhanced cyan fluorescent protein)以及EYFP(Enhanced yellow fluorescent protein)的基因,通过RecJoin克隆技术分别成功构建SENP和ECFP-SUMO-EYFP表达载体B28和B13。将表达载体转化大肠杆菌BL21,经IPTG诱导表达,通过Ni-NTA离子交换柱层析纯化,进一步采用SDS-PAGE和Westernblotting分析鉴定,并以酶切实验初步分析了SENP相对于底物ECFP-SUMO-EYFP的酶切特异性。最终,SENP3C(SENP3 catalytic domain)截短表达,SENP5C以包涵体形式表达,其他蛋白均为可溶性表达,SDS-PAGE分析表明表达产物分子质量(Mr)与预期相符,Western blotting方法进一步证实其为目的蛋白。酶切实验初步鉴定了SENP1C和SENP2C的酶切特异性。以上蛋白的原核表达为荧光共振能量转...     

LSECtin-CRD-GST融合蛋白的原核表达、纯化及复性

目的:构建C型凝集素LSECtin主要功能结构域CRD的原核表达载体,在大肠杆菌中表达LSECtin-CRD-GST融合蛋白。方法:根据Gen Bank发布的LSECtin基因序列设计引物,利用基因重组技术将获得的LSECtin-CRDc DNA定向克隆至C端带GST蛋白标签序列的融合表达载体p GEX-6p-1中,转化大肠杆菌Origami(DE3)进行重组蛋白的诱导表达,用GST柱亲和纯化融合蛋白。结果:获得了原核表达载体p GEX-6p-1-LSECtin-CRD,诱导表达出大量相对分子质量约40×103的包涵体融合蛋白,经纯化、复性获得可溶蛋白,经Western印迹鉴定为目的蛋白。结论:获得足量的LSECtin-CRD-GST融合蛋白,为进一步研究CRD蛋白结构域的动态构象变化提供了实验材料。     

猪繁殖与呼吸综合征病毒Nsp2蛋白原核表达纯化及其蛋白酶活性分析

摘要：【目的】表达并纯化猪繁殖与呼吸综合征病毒非结构蛋白2（Nsp2）,分析Nsp2的蛋白酶活性。【方法】本研究通过PCR分别扩增nsp2基因的N端和C端,利用原核表达载体pET21a(+)表达Nsp2蛋白的N端和C端(即Nsp2-N 和 Nsp2-C),通过Ni-NTA琼脂糖亲和层析和凝胶过滤的方法纯化两个重组蛋白。预测Nsp2-N含有半胱氨酸蛋白酶结构域,本研究利用western blot检测其顺式酶切蛋白酶活性;并人工合成潜在的十肽底物,利用体外多肽酶切实验检测其反式酶切蛋白酶活性。成功获得Nsp2     

C2株贾第虫醛糖还原酶的原核表达与生物信息学分析北大核心

[目的]克隆、原核表达、纯化C2株蓝氏贾第鞭毛虫(Giardia lamblia,简称贾第虫)醛糖还原酶(Aldose reductase,AR)基因,并进行生物信息学分析。[方法]从C2株贾第虫基因组DNA中克隆贾第虫AR编码区,双酶切连入原核表达载体pET-28a(+),酶切和测序进行验证,并进行生物信息学分析;将构建成功的重组质粒pET-28a(+)-AR转化大肠杆菌Rosetta(DE3)并进行诱导表达,SDS-PAGE及Western Blot验证表达效果;镍亲和层析纯化AR蛋白,SDS-PAGE观察纯化效果。[结果]成功克隆了C2株贾第虫AR蛋白编码区并构建了原核表达载体,SDS-PAGE及Western Blot显示,AR表达载体转化的大肠杆菌经诱导可表达出相对分子量约37.2k Da的目的蛋白,与预期一致;重组蛋白通过亲和层析获得了高效纯化;生物信息学分析显示贾第虫AR蛋白主要二级结构为无规则卷曲,整体为一个NADPH依赖的氧化还原酶结构域。AR蛋白在真核生物中相当保守,贾第虫AR蛋白在进化上相对独立。[结论]证实了贾第虫AR蛋白的存在并明确了其结构和进化上的特征,为贾第虫AR抗体的制备和功能的研究提供了基础。     

C2株贾第虫醛糖还原酶的原核表达与生物信息学分析

[目的]克隆、原核表达、纯化C2株蓝氏贾第鞭毛虫(Giardia lamblia,简称贾第虫)醛糖还原酶(Aldose reductase,AR)基因,并进行生物信息学分析。[方法]从C2株贾第虫基因组DNA中克隆贾第虫AR编码区,双酶切连入原核表达载体pET-28a(+),酶切和测序进行验证,并进行生物信息学分析;将构建成功的重组质粒pET-28a(+)-AR转化大肠杆菌Rosetta(DE3)并进行诱导表达,SDS-PAGE及Western Blot验证表达效果;镍亲和层析纯化AR蛋白,SDS-PAGE观察纯化效果。[结果]成功克隆了C2株贾第虫AR蛋白编码区并构建了原核表达载体,SDS-PAGE及Western Blot显示,AR表达载体转化的大肠杆菌经诱导可表达出相对分子量约37.2k Da的目的蛋白,与预期一致;重组蛋白通过亲和层析获得了高效纯化;生物信息学分析显示贾第虫AR蛋白主要二级结构为无规则卷曲,整体为一个NADPH依赖的氧化还原酶结构域。AR蛋白在真核生物中相当保守,贾第虫AR蛋白在进化上相对独立。[结论]证实了贾第虫AR蛋白的存在并明确了其结构和进化上的特征,为贾第虫AR抗体的制备和功能的研究提供了基础。     

枯草杆菌谷氨酰胺转胺酶的克隆及其在大肠杆菌中的融合表达

利用PCR技术 ,从枯草杆菌DB40 3染色体上扩增出谷氨酰胺转胺酶基因 ,将其克隆到大肠杆菌载体pET32a( + )中 ,成功构建谷氨酰胺转胺酶表达载体pET32-BTGase ,并转化大肠杆菌BL2 1 (DE3)。重组克隆在IPTG诱导下 ,表达出硫氧还蛋白 谷氨酰胺转胺酶 (Trx-BTGase)融合蛋白 ,表达量占细菌总蛋白量的 2 6%。利用金属螯合层析纯化菌体裂解上清中表达的融合蛋白 ,纯度超过 80 %,再通过分子筛层析进一步纯化得到融合蛋白纯品。酶活性分析表明表达的Trx-BTGase融合蛋白具有交联蛋白的活性 ,并发现Trx-BTGase融合蛋白和经凝血酶酶切后得到的BTGase单体都能催化牛血清白蛋白的聚合反应     

人MDM2基因真核表达载体的构建及其与p53的相互作用

目的:构建带Flag标签的MDM2真核表达载体,并检测MDM2与p53的相互作用。方法:从人乳腺文库中PCR扩增MDM2编码序列,将其插入pcDNA3.0-Flag载体,转染293T细胞后用Western印迹检测其在293T细胞中的表达,并通过免疫共沉淀实验检测MDM2与p53的相互作用。结果:双酶切和测序结果表明,Flag-MDM2真核表达载体构建成功,转染293T细胞后成功表达;免疫共沉淀实验证明Flag-MDM2与p53存在相互作用。结论:构建了带Flag标签的人MDM2真核表达载体,并检测了MDM2与p53之间的相互作用,为研究MDM2的功能奠定了基础。     

结核分枝杆菌Rv1009结构域基因的克隆、表达及亲和层析纯化

目的:克隆结核分枝杆菌Rv1009结构域基因,经序列测定正确后进行融合表达和纯化。方法:采用PCR从结核分枝杆菌H37Rv基因组中扩增出Rv1009结构域基因,用限制性内切酶消化后插入pUC-19克隆载体中,经测序正确后亚克隆到融合表达载体pPro-EXHT中,转化大肠杆菌DH5α,目的基因经IPTG诱导,由T7启动子调控表达了N端带6个连续组氨酸残基的Rv1009结构域多肽,在变性条件下对目的蛋白进行纯化。结果:获得了结核分枝杆菌Rv1009结构域基因,得到融合6个组氨酸残基的Rv1009结构域多肽,纯化获得的蛋白纯度大于87%。结论:构建了结核分枝杆菌Rv1009结构域基因的重组表达载体,并获得了高纯度的融合表达蛋白,为后续深入研究奠定了基础。     

重组人基质金属蛋白酶12的原核表达与纯化

目的:利用原核系统表达重组对人基质金属蛋白酶12(MMP-12)并纯化,获得高纯度的人MMP-12蛋白。方法:在MMP-12氨基酸序列的N端加入His标签和肠激酶位点序列,构建MMP-12融合蛋白的原核表达载体,通过表达和亲和纯化获得MMP-12融合蛋白,以肠激酶对融合蛋白进行酶切和二次纯化,获得高纯度的人MMP-12。结果:构建了pET-MMP-12表达载体,并在大肠杆菌中实现了稳定高效表达。重组融合蛋白MMP-12经亲和层析纯化后,相对分子质量为42×10~3,纯度约95%。利用肠激酶对融合蛋白MMP-12进行酶切,酶切效率接近100%,通过二次纯化获得了MMP-12,相对分子质量为40.8×10~3,纯度大于95%。结论:利用原核表达系统高效表达了MMP-12融合蛋白,通过亲和纯化和肠激酶酶切的方法可以获得高纯度的MMP-12,为后续抗体制备和配基筛选奠定了基础。     

Regulation of MDM2 E3 ligase activity by phosphorylation after DNA damage

MDM2 is a major regulator of p53 by acting as a ubiquitin E3 ligase. The central acidic domain and C-terminal RING domain of MDM2 are both indispensable for ubiquitination of p53. Our previous study suggested that ATM phosphorylation of MDM2 near the C terminus inhibits RING domain oligomerization, resulting in p53 stabilization after DNA damage. We present here evidence that these modifications allosterically regulate the functions of both acidic domain and RING domain of MDM2. Using chemical cross-linking, we show that the MDM2 RING domain forms oligomers including dimer and higher-order complexes in vivo. RING domain dimerization efficiency is negatively regulated by upstream sequence. ATM-mediated phosphorylation of the upstream sequence further inhibits RING dimerization. Forced oligomerization of MDM2 partially overcomes the inhibitory effect of phosphorylation and stimulates p53 ubiquitination. Furthermore, the ability of MDM2 acidic domain to bind p53 core domain and induce p53 misfolding are also suppressed by the same C-terminal ATM sites after DNA damage. These results suggest that the acidic domain and RING domain of MDM2 are both allosterically coupled to the intervening ATM sites, which enables the same modification to regulate multiple MDM2 functions critical for p53 ubiquitination.     

MDM2 regulates vascular endothelial growth factor mRNA stabilization in hypoxia

Expression of vascular endothelial growth factor (VEGF) increases in cancer cells during hypoxia. Herein, we report that the MDM2 oncoprotein plays a role in hypoxia-mediated VEGF upregulation. In studying the characteristics of MDM2 and VEGF expression in neuroblastoma cells, we found that hypoxia induced significantly higher upregulation of both VEGF mRNA and protein in MDM2-positive cells than in the MDM2-negative cells, even in cells without wild-type (wt) p53. We found that hypoxia induced translocation of MDM2 from the nucleus to the cytoplasm, which was associated with increased VEGF expression. Enforcing overexpression of cytoplasmic MDM2 by transfection of the mutant MDM2/166A enhanced expression of VEGF mRNA and protein production, even without hypoxia. The results of mechanistic studies demonstrated that the C-terminal RING domain of the MDM2 protein bound to the AU-rich sequence within the 3' untranslated region (3'UTR) of VEGF mRNA; this binding increased VEGF mRNA stability and translation. In addition, knockdown of MDM2 by small interfering RNA (siRNA) in MDM2-overexpressing cancer cells resulted in inhibition of VEGF protein production, cancer cell survival, and angiogenesis. Our results suggest that MDM2 plays a p53-independent role in the regulation of VEGF, which may promote tumor growth and metastasis.     

An essential function of the extreme C-terminus of MDM2 can be provided by MDMX

MDM2 (HDM2) is a ubiquitin ligase that can target the p53 tumor suppressor protein for degradation. The RING domain is essential for the E3 activity of MDM2, and we show here that the extreme C-terminal tail of MDM2 is also critical for efficient E3 activity. Loss of E3 function in MDM2 mutants deleted of the C-terminal tail correlated with a failure of these mutants to oligomerize with MDM2, or with the related protein MDMX (HDMX). However, MDM2 containing point mutations within the C-terminus that inactivated E3 function retained the ability to oligomerize with the wild-type MDM2 RING domain and MDMX, and our results indicate that oligomers containing both wild-type MDM2 and a C-terminal mutant protein retain E3 function both in auto-degradation and degradation of p53. Interestingly, the E3 activity of C-terminal point mutants of MDM2 can also be supported by interaction with wild-type MDMX, suggesting that MDMX can directly contribute to E3 function.     

The MDM2 RING Domain and Central Acidic Domain Play Distinct Roles in MDM2 Protein Homodimerization and MDM2-MDMX Protein Heterodimerization

The oncoprotein murine double minute 2 (MDM2) is an E3 ligase that plays a prominent role in p53 suppression by promoting its polyubiquitination and proteasomal degradation. In its active form, MDM2 forms homodimers as well as heterodimers with the homologous protein murine double minute 4 (MDMX), both of which are thought to occur through their respective C-terminal RING (really interesting new gene) domains. In this study, using multiple MDM2 mutants, we show evidence suggesting that MDM2 homo- and heterodimerization occur through distinct mechanisms because MDM2 RING domain mutations that inhibit MDM2 interaction with MDMX do not affect MDM2 interaction with WT MDM2. Intriguingly, deletion of a portion of the MDM2 central acidic domain selectively inhibits interaction with MDM2 while leaving intact the ability of MDM2 to interact with MDMX and to ubiquitinate p53. Further analysis of an MDM2 C-terminal deletion mutant reveals that the C-terminal residues of MDM2 are required for both MDM2 and MDMX interaction. Collectively, our results suggest a model in which MDM2-MDMX heterodimerization requires the extreme C terminus and proper RING domain structure of MDM2, whereas MDM2 homodimerization requires the extreme C terminus and the central acidic domain of MDM2, suggesting that MDM2 homo- and heterodimers utilize distinct MDM2 domains. Our study is the first to report mutations capable of separating MDM2 homo- and heterodimerization.     

Structure of the MDM2/MDMX RING domain heterodimer reveals dimerization is required for their ubiquitylation in trans

MDM2, a ubiquitin E3-ligase of the RING family, has a key role in regulating p53 abundance. During normal non-stress conditions p53 is targeted for degradation by MDM2. MDM2 can also target itself and MDMX for degradation. MDMX is closely related to MDM2 but the RING domain of MDMX does not possess intrinsic E3-ligase activity. Instead, MDMX regulates p53 abundance by modulating the levels and activity of MDM2. Dimerization, mediated by the conserved C-terminal RING domains of both MDM2 and MDMX, is critical to this activity. Here we report the crystal structure of the MDM2/MDMX RING domain heterodimer and map residues required for functional interaction with the E2 (UbcH5b). In both MDM2 and MDMX residues C-terminal to the RING domain have a key role in dimer formation. In addition we show that these residues are part of an extended surface that is essential for ubiquitylation in trans. This study provides a molecular basis for understanding how heterodimer formation leads to stabilization of MDM2, yet degradation of p53, and suggests novel targets for therapeutic intervention.     

Residues 240–250 in the C-Terminus of the Pirh2 Protein Complement the Function of the RING Domain in Self-Ubiquitination of the Pirh2 Protein

Pirh2 is a p53 inducible gene that encodes a RING-H2 domain and is proposed to be a main regulator of p53 protein, thus fine tuning the DNA damage response. Pirh2 interacts physically with p53 and promotes its MDM2-independent ubiquitination and subsequent degradation as well as participates in an auto-regulatory feedback loop that controls p53 function. Pirh2 also self-ubiquitinates. Interestingly, Pirh2 is overexpressed in a wide range of human tumors. In this study, we investigated the domains and residues essential for Pirh2 self-ubiquitination. Deletions were made in each of the three major domains of Pirh2: the N-terminal domain (NTD), Ring domain (RING), and C-terminal domain (CTD). The effects of these deletions on Pirh2 self-ubiquitination were then assessed using in vitro ubiquitination assays. Our results demonstrate that the RING domain is essential, but not sufficient, for Pirh2 self-ubiquitination and that residues 240–250 of the C-terminal domain are also essential. Our results demonstrate that Pirh2 mediated p53 polyubiquitination occurs mainly through the K48 residue of ubiquitin in vitro. Our data further our understanding of the mechanism of Pirh2 self-ubiquitination and may help identify valuable therapeutic targets that play roles in reducing the effects of the overexpression of Pirh2, thus maximizing p53''s response to DNA damage.     

Autoactivation of the MDM2 E3 Ligase by Intramolecular Interaction

The RING domain ubiquitin E3 ligase MDM2 is a key regulator of p53 degradation and a mediator of signals that stabilize p53. The current understanding of the mechanisms by which MDM2 posttranslational modifications and protein binding cause p53 stabilization remains incomplete. Here we present evidence that the MDM2 central acidic region is critical for activating RING domain E3 ligase activity. A 30-amino-acid minimal region of the acidic domain binds to the RING domain through intramolecular interactions and stimulates the catalytic function of the RING domain in promoting ubiquitin release from charged E2. The minimal activation sequence is also the binding site for the ARF tumor suppressor, which inhibits ubiquitination of p53. The acidic domain-RING domain intramolecular interaction is modulated by ATM-mediated phosphorylation near the RING domain or by binding of ARF. These results suggest that MDM2 phosphorylation and association with protein regulators share a mechanism in inhibiting the E3 ligase function and stabilizing p53 and suggest that targeting the MDM2 autoactivation mechanism may be useful for therapeutic modulation of p53 levels.     

Identification of a Catalytic Active but Non-Aggregating MDM2 RING Domain Variant

As a key regulator of the tumour suppressor protein p53, MDM2 is involved in various types of cancer and has thus been an attractive drug target. So far, small molecule design has primarily focussed on the N-terminal p53-binding domain although on-target toxicity effects have been reported. Targeting the catalytic RING domain of MDM2 resembles an alternative approach to drug MDM2 with the idea to prevent MDM2-mediated ubiquitination of p53 while retaining MDM2′s ability to bind p53. The design of RING inhibitors has been limited by the extensive aggregation tendency of the RING domain, making it challenging to undertake co-crystallization attempts with potential inhibitors. Here we compare the purification profiles of the MDM2 RING domain from several species and show that the MDM2 RING domain of other species than human is much less prone to aggregate although the overall structure of the RING domain is conserved. Through sequence comparison and mutagenesis analyses, we identify a single point mutation, G443T, which greatly enhances the dimeric fraction of human MDM2 RING domain during purification. Neither does the mutation alter the structure of the RING domain, nor does it affect E2(UbcH5B)–Ub binding and activity. Hence, MDM2-G443T facilitates studies involving binding partners that would be hampered by the low solubility of the wild-type RING domain. Furthermore, it will be valuable for the development of MDM2 RING inhibitors.     

MDM2 promotes ubiquitination and degradation of MDMX

The p53 tumor suppressor is regulated by MDM2-mediated ubiquitination and degradation. Mitogenic signals activate p53 by induction of ARF expression, which inhibits p53 ubiquitination by MDM2. Recent studies showed that the MDM2 homolog MDMX is also an important regulator of p53. We present evidence that MDM2 promotes MDMX ubiquitination and degradation by the proteasomes. This effect is stimulated by ARF and correlates with the ability of ARF to bind MDM2. Promotion of MDM2-mediated MDMX ubiquitination requires the N-terminal domain of ARF, which normally inhibits MDM2 ubiquitination of p53. An intact RING domain of MDM2 is also required, both to interact with MDMX and to provide E3 ligase function. Increase of MDM2 and ARF levels by DNA damage, recombinant ARF adenovirus infection, or inducible MDM2 expression leads to proteasome-mediated down-regulation of MDMX levels. Therefore, MDMX and MDM2 are coordinately regulated by stress signals. The ARF tumor suppressor differentially regulates the ability of MDM2 to promote p53 and MDMX ubiquitination and activates p53 by targeting both members of the MDM2 family.