Cell-free translation experiments of integral membrane proteins in single-compartment liposomes
Cell-free translation experiments of integral membrane proteins in single-compartment liposomes
Membrane proteins provide the appropriate molecular mechanisms that allow the controlled entry of useful molecules into the cell and permit the export of intracellular products to the extracellular compartment. Enzymes in the cell membrane synthesize the molecules that make up the cell membrane (e.g., saturated and unsaturated fatty acids, mercurial lipids, glycerides, sphingolipids, sterols, polyisoprene). Enzyme complexes in the cell membrane are responsible for electron transfer, generating electrochemical gradients, which are utilized by the delicate cytosolic ATPase motor to produce ATP. Membrane proteins can also harvest light, provide mutant receptors to transduce information about the binding of external molecules to the cell membrane into cellular responses via signaling cascades; provide surface contacts necessary for the differentiation and assembly of embryonic stem cells into more complex tissues; and help to stimulate an antigenic response to pathogenic infections.
Author: Burgess et al., Translated by Wei Chen, this experiment is from "Protein Purification Guide".
Operation method
Cell-free translation experiments of integral membrane proteins in single-compartment liposomes Move gene cloning This method requires two-step PCR (Blommel et al., 2006; Thao et al., 2004). Figure 37.2 provides a vector map of pEU-HSCB and an example of primer design for cloning His6-bacterial retinoids (Blommel andFox, 2007). Using this vector and primer design scheme, the T E V protease was able to cleave the MGHHHHHHHAIAENLYFQ sequence so that serine became the first amino acid of the mature protein. The tobacco mosaic virus omega sequence is a translational enhancer sequence (Sawasaki et al., 2000). The Flexi Vector cloning method (Blommel et al., 2006) can be used to transfer the cloned genes into any (or all) of the vectors mentioned in Table 37-1, as well as a number of other commercially available vectors (see http :// for other examples), by adding the Sg/ I and PmeI cleavage sites to the positions indicated in the corresponding primers. www.promega.com for other examples). The s a c & C A T cassettes shown in Fig. 37. 2 provide a toxicity screen when the corresponding transformants are grown on plates containing 5 % sucrose. In this way positive clones containing the target gene can be screened more efficiently, while sac& C A T also provides resistance against chloramphenicol. The p F I K homology region enhances the efficiency of transferring cloned genes between different Flexi vectors (Blommel et al., 2006). In the example given in Figure 37. 2 B, the 5' forward primer used in the first step of the P C R contains a gene-specific nucleotide sequence and incorporates an invariant sequence at the end of the 5' segment that encodes part of the T EV cleavage site. The 3' reverse complementary primers shown in Figure 37. 2 C contain gene-specific nucleotide and PmeI sites. Other genes can be cloned by substituting gene-specific sequences when designing primers. The second PCR step uses a universal forward primer (Fig. .37. 2B) containing sequences that complement the T E V digest site and the Sg/I site. Generic reverse PCR primers were used to replicate the PmeI site and spiked with additional nucleotides (Fig. 37.2 B) . In the second PCR step, a portion of the product from the first PCR step is added to a new PCR reaction system containing the universal forward and reverse primers to obtain a PCR product that is correct for Flexi Vector cloning. PCR products are purified before SG/I/PMeI digestion. Materials and Reagents PCR purification kit [Quickstep 2 PCR purification kit (EdgeBio, Gaithersburg, MD)] containing SOPE resin, secure sterile sealing tape, forma Ultra 96-well plates and V-Bottom 9 6-well plates. Experimental protocols (1) Add 4 uL of well-suspended SOPE resin to 20 jlxL of the PCR product (from the F L E X I - T E V PCR protocol described above). (2) Seal the plate with a secure sterile sealing tape and vortex. The suspension is allowed to stand at room temperature. Simultaneously prepare; performaUltra 9 6-well plates. (3) Remove the adhesive seal from the top and bottom of the Performa Ultra 9 6-well plate and add the lid. (4) Stack the Performa Ultra 96-well plate on top of a 9 6-well flat-bottomed microculture plate. (5) Place the device in a lined plate carrier for centrifugation. (6) Centrifuge at 850 g for 5 min. (7) Centrifuge briefly to enrich the SOPE/PCR mixture to the bottom of the wells. Slowly transfer the S O P E / P C R reaction mixture directly to the Performs Ultra 96-well plate using a liquid pipette. Ensure that the liquid flows into the gel matrix. Add lid. (8) Stack the Performa Ultra 96-well plate on top of the 96-well V - b o t t o m microplate. (9) Place the device in a centrifuge plate tray and centrifuge at 850 g for 5 mIn. The eluate containing the purified PCR product is retained. The fraction can be stored at 20°C until ready for use. The following procedure involves digestion of pEU vector variants and purified PCR products with SG/I and PMEI prior to ligation. Additional descriptions of cloning using the FIexi Vector System can be found elsewhere in the literature (Blommer and Fox, 2007; Blommer and Fox, 2007; Blommer and Fox, 2007; Blommer and Fox, 2007). Reagents 5X Flexi Digestion Buffer (Promega); 10X Sgf1/PmeI Enzyme Mix (Promega); pEU Vector Variants (Table 37.1); purified PCR product [from step (9) of the PCR product purification protocol]. The digested and purified P C R product and p E U variant vector are ligated in this step. For the most efficient ligation reaction, it is important to use a high concentration of ligase. Reagents 10X T4 DNA Ligase Buffer (Promega); high concentration T4 DNA Ligase (Promega); pEU Variants Carrier (from Flexi Carrier Digestion Reaction Step (2)); Purified PCR digest [from PCR product digestion reaction step (6)]. Experimental Program (1) Set up a ligase master mix consisting of 225 ul of sterile deionized water, 100 ul of 10 X T4 ligase buffer, and 50 ul of highly concentrated T4 DNA ligase. (2) Add 5.0 ul of purified PCR digest, 2.0 ul of digested pEU carrier, and 3.5 pL of Ligation Master Mix to each well of the new PCR plate. This is the ligation plate. (3) Incubate the ligation plate at 25°C for 3 h in a thermocycler. (4) Transform immediately or store the connection plate overnight at 4°C. The following steps are for the transformation of receptor cells with the products of the linkage reaction. Receptor cells from both Invitrogen and P r o m e g a have been used successfully according to the manufacturer's experimental protocols. Materials and Reagents 10 G chemoreceptor cells for transformation (LUCig en, Middleton, W I ); 10 G cell recovery solution (Lucigen); Junction plate [from step (4) of the Junction reaction]; Fishherb nmd sterile disposable Petri dishes (60 m m X 15 m m ) (Fisher Scientific, Pittsburgh, P A ); Y T agar plates containing 0.5% (W/V) glucose, 50 ug/m L kanamycin, and 5% sucrose. ,P A ); Y T agar plates containing 0.5% (W /V) glucose, 50 ug/m L kanamycin, and 5% sucrose for screening of p E U -H S C B carriers (Fig. 37. 2); ColiR oiler plate beads (N o v a g e n , Gibbstow n , N J ) . The experimental program (1) 10 G chemoreceptor cells were removed from an 80°C refrigerator and melted on ice. (2) Dispense 10 ul of cells into pre-cooled PCR plates or strip tubes. (3) Add I.0 ligand and mix well with the tip of the pipette gun. (4) Incubate on ice for at least 5 m i n . Lock the thermocycler setting to 34°C. (5) Heat shock at 34°C for 30 s (follow manufacturer's instructions for small reaction volumes). (6) Return the transformed reaction to ice and incubate for 2 m i n . (7) Remove from ice and add 80 fxL of recovery medium at room temperature. (8) Incubate at 37°C for I h. Do not shake. Do not shake. (9) While incubating the transformants, mark the bottom of % Y T plates containing the appropriate antibiotic and A1-H12, and add 5 to 10 sterile ColiRoller glass beads to each plate. (10) Add all of the transformation reagents to each corresponding labeled plate. Shake the plate in a circular motion to disperse the liquid. Carefully remove the ColiRoller beads by turning the plates into a suitable waste container or place 1 000 % ethanol in the plate for next use. (11) Incubate plates at 37°C overnight. All reagents used for in vitro transcription and translation must be free of RNAase. Therefore, all glassware used to prepare cell-free reactions must be baked at 1800 °C for 3 h to remove the RNA enzyme. In addition, wear gloves and avoid talking and sneezing while handling reagents to prevent RNAase contamination of hands and saliva. Unless otherwise noted, all buffers must be sterilized by filtration with a 0.2 um filter and stored at 20 °C. In addition, all reagents are prepared in 18 MΩ water (Milli-Q water, Millipore, Billerica, M A ) unless otherwise noted. Diethyl pyrocarbonate (DEPC)-treated water should not be used in this protocol because the degradation products of DEPC inhibit in vitro transcription and translation reactions. Reagents The 10X buffer for proteinase K contains 10 mmol/L Tris-HCl (pH 8.0), 50 mmol/L Protease K was purchased from S i g m a/Aldrich (St. Louis, M O ). An IO X protease K solution was prepared by adding 0.5 m g of protease K to I.0 m L of IO X protease K buffer. Dispense 10 ul of this protease K solution and store it at 80°C. In cell-free translation, m R N A is a necessary reactant for protein synthesis reactions. In order to achieve the highest transcriptional efficiency, a sufficient amount of m RNA must be added to saturate the ribosomes in the translation reaction. Reagents Contains Mg Transcription Buffer (5X ): 400 m m o l / L HEPE-KOH (p H 7.8), 100 m m o l / L magnesium acetate, 10 m m m o l / L spermidine hydrochloride, and 50 m m m o l / L DTT. Store at 20° C. NTP solution: Contain 25 m m o l /L of ATP, GTP, CTP and UTP, prepared by sterile filtration of 100 m m o l /L NTP (Milli-Q water soluble) through a 0.2 um filter. The NTP solution was stored at 180°C. The NTP solution was also preserved in the refrigerator. SP6 RNA polymerase and RNA enzyme inhibitor (RNI) were purchased from Promega. Single-compartment liposomes are added to a cell-free translation reaction to capture newly translated membrane proteins. This step provides an alternative approach to solubilizing membrane proteins with detergents. The presence of a decontaminating agent would result in an inability to directly measure the function of the membrane protein. Materials and Reagents Soybean complete extract (200 % lecithin) was purchased from Avanti Polar Lipids (Alabaster, A L ). Lipid rehydration buffer: 25 m m o l / L HEPES (p H 7.5), IOO m m o l / L NACL. 0.4 um and 0.I um track-etch polycarbonate membranes (Track-etch polycarbonate membrane) were purchased from Nucleopore (Pleasanton, CA). A mini-extruder for the preparation of single-chamber liposomes was purchased from Avanti Polar Lipids. Experimental Program (1) Dissolve I g of soybean complete extract (200 % lecithin) in 3 m L of chloroform. (2) Wash the lipid solution with a stream of N2 to remove most of the organic solvents. Dry the residual lipids in vacuum for 30 mIn. (3) Resuspend dried lipids with 67 mL of lipid rehydration buffer. Vortex the lipid solution until homogenization. 3 to 5 freeze/towa cycles will assist in the hydration of the lipids. (4) Formation of single chamber liposomes by means of a miniature extruder. The liposome solution is passed 11 times through a 0.4 m Tracketch polycarbonate membrane and 11 times through a 0.im Track-etch polycarbonate membrane. (5) Dispensing and rapid freezing of liposomes. Liposomes prepared in this way can be stored at 1 80°C. Figure 37.3 compares the construction of a bilayer reaction with that of a dialysis reaction. The bilayer reaction utilizes the difference in density between the extract and the upper buffer to isolate the extract and mRNA from the other reactants. In this case, diffusion of substrate and product occurs throughout the buffer interface. Due to the simplicity of the setup, the double-layer cell-free translation reaction can be operated automatically (Sawasaki et al. 2002a; Tyler et al. 2005; Vinarov et al. 2004; 2006). According to our results, the bilayer reaction can produce about 0.2 m g / m L of different membrane proteins. However, the yield is limited due to the diffuse dilution of the reaction. The method can be scaled up from 50 uL to 10 mL or larger volumes without an overall change in volumetric productivity. This approach allows for simple screening of a small number of proteins in smaller volumes, while larger volumes can be scaled up for proteins that have been characterized by small-scale protocols and found to be amenable to further study. Experimental protocols for cell-free translation using bilayers and automated batching of analytical reactions have been published (E n d o andSawasaki, 2006; Sawasaki et al.) For the translation of intact membrane proteins, we have found that the addition of unilamellar liposomes effectively modifies the translation reaction (Gorene and Fox, 2008; Nozawaet al., 2007). (2) Add 5 porphyrin of the mRNA preparation to a single well of a %-well U-bottom plate. (3) Add an additional 20uL of the translation mixture to the mRNA sample in each well and mix well. (4) Carefully add 125 fxL I X Cover Buffer to form a bilayer. Be careful not to disrupt the bilayer structure as this will dilute the extract and reduce protein yield. (5) Incubate the reaction at 26°C for 20 h without disrupting the bilayer structure. (6) Protein translation levels can be determined by denaturing SDS-PAGE, with creatine kinase as an internal reference. Experimental protocol for dialysis reaction (1) Dissolve the purified mRNA starch with 50 uL of the translation mixture described in step (1) of the two-layer reaction protocol. (2) Place the translation mixture into a 12 k D a M W C ◦ dialysis cup. (3) Prepare a stock dialysis buffer by mixing 6.5 m L Milli-Q water, 2.0 m L 5 X reaction buffer, and 1.5 m L of 2 m m o l / L unlabeled amino acids. Ultrasonically mix the solution for 5 m i n and filter through a 0.2 um filter. Add 2.5 mL of Reserve Dialysis Buffer to each well of a 2 4-well plate. (4) Suspend the dialysis cup into the Reserve Dialysis Buffer. Be careful not to get bubbles under the dialysis cups, as this may interfere with the replenishment of the additives. (5) Cover the 24-well plate with Saran wrap to prevent evaporation of the Reserve Dialysis Buffer. Incubate the translation reaction for 16 h at 26°C. (6) Protein translation levels can be determined by denaturing SDS-PAGE with creatine kinase as an internal reference. Figure 37. 4 shows a schematic diagram of the purification of liposomes containing membrane proteins (produced by the cell-free translation technique in wheat germ). After the density gradient is assembled, one-step centrifugation separates the liposomes from the cell-free extracted proteins. In most cases, liposomes are greatly concentrated at the interface between the 3 0 % A c c u d e n z solution and the upper buffer. The partitioning surface of the mass rehydration buffer. For more product details, please visit Aladdin Scientific website.


![物 完 全 无 损 。 ⑴ 建 立 PCR引物板( PCR primer plate),将每个目的基因的正向和反向引物各 10 prnol/L分 别 在 ISC PCR板上的一个孔中混合。 ⑵ 建 立 PCR Master Mix,含有 2.195 mL 水 、250 IOX _ P/w Ultra II Buffer、 25 pL dNTPs(每个 10 ymol/L)和 50 fxl. Pfu Ultra ]I 融合热启动 DNA 聚合酶。这一 Master Mix足 够 96个反应,也可适当的扩大。丢弃没有使用的混合物。 ( 3 ) 根 据 需 要 ,在 I S C P C R 板 上 每 孔 中 加 人 23. 0 F L P C R Master M i x 。此 为 P C R 反 应 板 (P C R reaction plate) 。 (4) 加 人 自 P C R 引物板的 I fxL引物混合物到P C R 反应板的对应孔中。 (5) 分别 加 人 I fzL(约 100 n g )含每个要克隆基因的载体D N A 到 P C R 反应板上对 应孔中。 (6) 用 A U e g r a 6R 离心机和6H 3. B 转子短暂的离心;P C R 反应 板 ,使孔中的液体到 底 部 ,然后用封口带覆盖板子。 ( 7 ) 将 P C R 反 应 板 放 于 热 循 环 仪 ,并 用 以 下 参 数 设 定 循 环 : ① 9 5 1 ,2. 00 m i n ; © 9 4 。€: ,2 0 3必 5 0 。( :,2 0 3必 7 2 。( :,1 5 5/汕 ;© 重 复 © 〜 @ 步 1 9 次 。 (8) 对于第二步P C R ,将第一步P C R 产 物 2 0 % 的体积加入新的P C R 反应中,并加人 0.2 fxmol/L 的通用正向和反向引物。第 二 步 P C R 循环参数:①95°C ,2.00 m i n ;② 94°C , 2〇 3必 50。( :,2〇 5必 72。(: ,15 3/1^);( 1 ) 重 复 © 〜 @ 步 4 次 ;© 9 4 。( : ,2〇 3;© 5 5 。(: ,2〇 3; ⑧ 72°C ,15 s/k b ;⑨重复⑥ 〜 ⑧ 步 2 4 次;⑩ 72°C ,3.00 m i n ;⑪ 4°C 保存。 (9) P C R 反应完成后,用琼脂糖凝胶电泳分析适当大小的产物。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/08/A147158841551554due38e48png_small.jpg)
et al., 2006). Successful Flexi V e c t o r cloning is important to avoid overdigestion of the P C R product and the Flexi vector. sgf1 has asterisk activity, and overdigestion removes the sticky ends and turns the digested vector into a flat end, which can result in the vector self-linking and producing a high background of clones without the inserted human fragment.
![6 . 1 试剂 5X Flexi 消化缓冲液(P r o m e g a );10X S g /1/ P m e I 酶混合剂(P r o m e g a );p E U 载体变 体 (表 37. 1);纯 化 P C R 产物[自 P C R 产物纯化实验方案第(9)步]。 6- 1- 1 实验方案 ⑴ 建 立 p E U 载 体 酶 切 Master Mix。含 有 158. 3 fiL无菌去离子水、44. 0 (uL 5 X Flexi消化缓 冲 液 、2. 2 (uL 10 X S g /1/ P W I 混 合 酶 和 13. 5 y L 目 的 p E U 载体变体(如 150 n g V L 的纯化p E U -His-F V )。 混合酶稠密容易沉降,因此将其加入成分前须充分混勻。 (2)将 PE U 载体酶切Master M i x 放于热循环仪,并用以下参数设定循环:① 37°C , 40. 00 m i n ;② 65°C ,20. 00 m i n ;③ 4°C 直至需要。 ⑶ 建 立 P C R 产物消化 Master Mix。含 有 638 juL无菌去离子水、220 juL 5 X Flexi 消化缓冲液、22 (LtL lOXSg/1/P W I混合酶。这一 Master M i x 可以满足9 6 个反应,也可 适当的扩大。丢弃没有使用的混合物。 ⑷ 将 8. 0 的 P C R 产 物 酶 切 Master M i x 加 人 I S C P C R 板的每个孔。此 为 P C R 消化板(P C R digest plate)。 (5) 在 PCR消化板的每个使用过的孔中,加 2. 0 纯化 的 P C R 产物。 (6) 将 P C R 消化板放于热循 环 仪 ,并 用 以 下 参 数 设 定 循 环 : ① 37° C ,40. 00 m i n ; ② 65°C ,20. 00 m i n ;③ 需要前保存在4°C 。 如果转化没有产生克隆,或者克隆仅含目的插 人片段的载体,则 降 低 37°C 孵育的时间以减小星号活性。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/08/A147158848067922juysgsa7png_small.jpg)
EDTA and l % ( m/ V ) S D S
![9. 1 试剂 用于蛋白酶1^的10\缓冲液包含10〇 11111(1〇 1/11']: 丨5-1^〇 1(口1^8.0)、5〇 111111〇 1/乙 E D T A S l l % ( m/ V ) S D S 0 蛋白 酶 K 购 自 S i g m a/Aldrich(St.Louis,M O )。在 I.0 m L I O X 蛋 白 酶 K 的缓冲液 中加入0.5 m g 蛋 白 酶 K 以制备 I O X 蛋 白 酶 K 溶液。将 此 蛋 白 酶 K 溶液分装为1〇 ^ 并保存在一 80°C 。 9. 1. 1 实验方案 (1) 从 p E U -His-F V 转化子中挑单克隆转接I5O m L 的 2 X Y T 培养 液 ,在摇床中 37°C过夜培养。离心收集细胞。 (2) 用 M a r I i g e n公司高纯度质粒大提试剂盒[1\431%6111^11-口虹办口13311^]\/^- iprep kit(Marligen 1^〇 3士1^3,1]&:113¥1116,]\0)],依照制造商的说明书纯化质粒。用5〇〇 f^L M i U i - Q 水重悬每个分离的D N A 沉淀并测量260 n m 的吸光度以确定质粒D N A 的浓 度 。质 粒 D N A 的通常产量为600〜900 y g 。 (3) 商品化试剂盒制备的载体D N A 通常含有痕量的 R N A 酶污染。为了成功转录 和翻译,这一污染物必须去除。在 I X 蛋 白 酶 K 缓冲液中,用 50 n g ./ M L 的蛋白酶 K 37。(: 孵育 至 少 60 m i n 处理纯化的质粒,以除去痕量的R N A 酶污染。 (4) 残余蛋白质可加人同体积I : 1 的苯酿/氯仿溶液到制备的质粒中,剧烈涡旋,用 F 2402H 转子 和 Allegra 21R 离心机或相当的仪器14 000 r/m in (18 000 g )、4°C 离心以去 除 。将上层水相转移到新的管中并重复抽提步骤,转移水相到新管中。 ' ( 5 ) 向步骤(4)中获得的液相加入〇_1 倍 体 积 的 3 m o l /L 乙酸钠( p H 5_ 2)和 2. 5 倍 体积的乙醇,混匀 。 一 20°C冰 冻 10 m i n 以沉淀质粒D N A 。 ( 6 ) 用 F 2 4 0 2 H 转子和 Allegra 2 1 R 离心机 14 000 r/m in(18 000 尽) 、4。 (: 离 心 。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/08/A14715885259602hz7gtah9upng_small.jpg)

![1 0 . 1 . 1 实验方案 (1) 在使用前即时制备转录混合物,包含2 X 含 M g 的转录缓冲液、8 m m o l / L N T P 、 3. 2 unit/fJL S P 6 R N A 聚合酶和 I.6 u n i t / ^ L R N A 酶抑制剂。 (2)将质 粒 D N A [自质粒 D N A 纯化第(8)步]分别加入P C R 板 中 ,每 孔 2.5 。在 P C R 板中 ,每孔再加人2. 5 f x L 的转录混合物并混匀。此为转录板(transcripti〇n p late)。 (3) 密封转录板以避免蒸发导致的浓缩。 37°C 孵育转 录 板 4 h 。如果转录反应进行 无误,会形成焦磷酸镁的白色沉淀,使转录溶液浑浊。 ⑷ 用 C 0650 转子和 A U e g r a X - 2 2 R 离心机 6 2 3 0 r /m in ( 4 0 0 0 、2 6 t : 、5 m in 离心转 录反应物,除去白色沉淀。为了避免共沉淀 m R N A ,反应物不能冷冻。转移上清液到一 个新管中。澄清的溶液将作为m R N A 溶液用于 翻 译 反应。](http://img.dxycdn.com/trademd/upload/userfiles/image/2016/08/B1471588565860faym5tci3upng_small.jpg)




(6) Analyze the protein content of each fraction by denaturing SDS-PAGE.
