Reconstitution of the multiprotein complex of pp60src, hsp90, and p50 in a cell-free system.

A rabbit reticulocyte lysate system that has been used to reconstitute functional complexes between steroid receptors and the 90-kDa heat shock protein (hsp90) has been used here to form complexes between the pp60src tyrosine kinase and hsp90. Reticulocyte lysate forms complexes between hsp90 and a temperature-sensitive mutant of Rous sarcoma virus pp60v-src, which is normally present in cytosol virtually entirely in the multiprotein complex form. In addition, hsp90 in the lysate complexes with wild-type pp60v-src, of which only a small portion is normally recovered in cytosol in the native multiprotein complex, and with the cellular homolog, pp60c-src, which has never been recovered in cytosol in the form of a native multiprotein complex with hsp90. Moreover, the reticulocyte lysate-reconstituted complex also contains the 50-kDa phosphoprotein component of the native pp60v-src multiprotein complex. The native and reconstituted pp60src-hsp90 complexes have similar thermal stability and, like steroid receptor heterocomplexes, they are stabilized by molybdate. As previously shown with reticulocyte lysate-reconstituted steroid receptor heteroprotein complexes, the reconstituted pp60src multiprotein complex contains hsp70, which is a major candidate for providing the protein unfoldase activity required for hsp90 association.     

A novel cell-free protein synthesis system

An efficient cell-free protein synthesis system has been developed using a novel energy-regenerating source. Using the new energy source, 3-phosphoglycerate (3-PGA), protein synthesis continues beyond 2 h. In contrast, the reaction rate slowed down considerably within 30–45 min using a conventional energy source, phosphoenol pyruvate (PEP) under identical reaction conditions. This improvement results in the production of twice the amount of protein obtained with PEP as an energy source. We have also shown that Gam protein of phage lambda, an inhibitor of RecBCD (ExoV), protects linear PCR DNA templates from degradation in vitro. Furthermore, addition of purified Gam protein in extracts of Escherichia coli BL21 improves protein synthesis from PCR templates to a level comparable to plasmid DNA template. Therefore, combination of these improvements should be amenable to rapid expression of proteins in a high-throughput manner for proteomics and structural genomics applications.     

Effect of zeolites on protein synthesis in a cell-free system from Escherichia coli

Summary The effects of zeolites on protein synthesis in a cell-free system were investigated. The efficiency of protein synthesis was markedly enhanced upon the addition of zeolites to the reaction mixture. Pretreatment of reaction mixture with the zeolite prior to the start of reaction also stimulated the protein synthesis indicating that the effect is at least partially due to the removal of inhibitory substance(s) from the reaction mixture.     

Improvement of translation efficiency in an Escherichia coli cell-free protein system using cysteine

Cell-free protein synthesis systems are powerful tools for protein expression, and allow large amounts of specific proteins to be obtained even if these proteins are detrimental to cell survival. In this report we describe the effect of cysteine on cell-free protein synthesis. The addition of cysteine caused a 2.7-fold increase in the level of synthesized glutathione S-transferase (GST). Moreover, the levels of sulfhydryl group reductants, including reduced glutathione and dithiothreitol (DTT), were increased 1.9- and 1.7-fold, respectively, whereas levels of the disulfide dimers, cystine and oxidized glutathione, were suppressed 87% and 66%, respectively. These trends were also observed for green fluorescent protein (GFP) expression. The addition of cysteine competitively reversed the inhibitory effect of cystine on protein expression. These results suggest that the sulfhydryl group in cysteine plays a crucial role in enhancing protein synthesis, and that the addition of excess cysteine could be a convenient and useful method for improving protein expression.     

Protein synthesis inhibition stabilizes urokinase-type plasminogen activator mRNA. Studies in vivo and in cell-free decay reactions

Inhibition of protein synthesis stabilizes a number of mRNAs, but little is known about the mechanism. To understand the relationship between protein synthesis and mRNA stability, we studied the degradation of calcitonin-induced urokinase-type plasminogen activator (uPA) mRNA in LLC-PK cells. uPA mRNA became highly stable by pretreatment with either cycloheximide or pactamycin, and the stabilizing effect of cycloheximide treatment was time dependent with the full effect exerted by 60 min. Stabilization was also observed with histone H4 mRNA but only partially with c-myc mRNA. To further analyze, we developed a cell-free decay reaction system based on post-mitochondrial supernatant (PMS). In this system, uPA mRNA was completely stable when fractions were obtained from cells pretreated with cycloheximide, but very unstable in control fractions, paralleling uPA mRNA stability in intact cells. However, in contrast to uPA mRNA and the in vivo observation, histone H4 mRNA was unstable whether or not the cells were pretreated with cycloheximide. These results suggest that inhibition of protein synthesis stabilizes mRNAs in at least two different ways in LLC-PK1 cells. When PMS from cycloheximide/calcitonin-treated cells was mixed with PMS from untreated cells, uPA mRNA was not destabilized. This suggests that a putative labile factor responsible for uPA mRNA degradation is not a soluble protein.     

A cell-free system for the replication fo bacteriophage M-13 duplex DNA.

Cell-free extracts from M-13 am5 infected Escherichia coli cells which are highly concentrated on cellophane membrane disks replicate efficiently endogenous M-13 duplex DNA. If the reaction is carried out in the presence of bromodeoxyuridine triphosphate, the majority of the label is found in two classes of hybrid DNA molecules in which either the viral or the complementary strand is newly synthesized. A minor portion of the label is incorporated into fully synthetic duplex DNA. DNA synthesis requires ATP and is inhibited by nalidixic acid, novobiocin, and arabinosylnucleoside triphosphates. Rifampicin blocks preferentially the synthesis of molecules with labeled complementary strands. A similar effect is observed upon addition of the helix-destabilising M-13 gene V protein. In contrast, addition of E. coli helix-destabilising protein (Eco HD-protein) stimulates the synthesis of both types of hybrid DNA molecules as well as the formation of fully synthetic duplex DNA.     

Stimulation of poliovirus synthesis in a HeLa cell-free in vitro translation-RNA replication system by viral protein 3CDpro

The plus-strand RNA genome of poliovirus serves three distinct functions in the life cycle of the virus. The RNA is translated and then replicated, and finally the progeny RNAs are encapsidated. These processes can be faithfully reproduced in a HeLa cell-free in vitro translation-RNA replication system that produces viable poliovirus. We have previously observed a stimulation of virus synthesis when an mRNA, encoding protein 3CD(pro), is added to the translation-RNA replication reactions of poliovirus RNA. Our aim in these experiments was to further define the factors that affect the stimulatory activity of 3CD(pro) in virus synthesis. We observed that purified 3CD(pro) protein also enhances virus synthesis by about 100-fold but has no effect on the translation of the polyprotein. Optimal stimulation is observed only when 3CD(pro) is present early in the incubation period. The stimulation, however, is abolished by a mutation either in the RNA binding domain of 3CD(pro), 3C(pro)R84S/I86A, or by each of two groups of complementary mutations R455A/R456A and D339A/S341A/D349A at interface I in the 3D(pol) domain of 3CD(pro). Surprisingly, virus synthesis is strongly inhibited by the addition of both 3C(pro) and 3CD(pro) at the beginning of incubation. We also examined the effect of other viral or cellular proteins on virus synthesis in the in vitro system. No enhancement of virus synthesis occurred with viral proteins 3BC, 3ABC, 3BCD, 3D(pol), and 3C(pro) or with cellular protein PCBP2. These results suggest that 3CD(pro) has to be present in the reaction at the time the replication complexes are assembled and that both the 3C(pro) and 3D(pol) domains of the protein are required for its activity that stimulates virus production.     

Folding of firefly luciferase during translation in a cell-free system.

In vitro synthesis of firefly luciferase and its folding into an enzymatically active conformation were studied in a wheat germ cell-free translation system. A novel method is described by which the enzymatic activity of newly synthesized luciferase can be monitored continuously in the cell-free system while this protein is being translated from its mRNA. It is shown that ribosome-bound polypeptide chains have no detectable enzymatic activity, but that this activity appears within a few seconds after luciferase has been released from the ribosome. In contrast, the renaturation of denatured luciferase under identical conditions occurs with a half-time of 14 min. These results support the cotranslational folding hypothesis which states that the nascent peptides start to attain their native tertiary structure during protein synthesis on the ribosome.     

Development of a rapid and productive cell-free protein synthesis system

Due to recent advances in genome sequencing, there has been a dramatic increase in the quantity of genetic information, which has lead to an even greater demand for a faster, more parallel expression system. Therefore, interest in cell-free protein synthesis, as an alternative method for high-throughput gene expression, has been revived. In contrast toin vivo gene expression methods, cell-free protein synthesis provides a completely open system for direct access to the reaction conditions. We have developed an efficient cell-free protein synthesis system by optimizing the energy source and S30 extract. Under the optimized conditions, approximately 650 μg/mL of protein was produced after 2 h of incubation, with the developed system further modified for the efficient expression of PCR-amplified DNA. When the concentrations of DNA, magnesium, and amino acids were optimized for the production of PCR-based cell-free protein synthesis, the protein yield was comparable to that from the plasmid template.     

Translation of collagen messenger RNA in a cell-free system derived from wheat germ.

A cell-free system for synthesizing protein from wheat germ was used to translate the messenger RNA extracted from 16-day embryonic chick calvaria. A part of the product had properties similar to collagenous peptides and served as a substrate for prolyl hydroxylase, an enzyme specific for collagen. The level of potassium was critical for the synthesis of high molecular weight products with properties similar to pro-alpha-chains. The potassium concentration for optimal protein synthesis, as judged by maximum incorporation of [3H]proline into acid precipitable material, was considerably lower than the concentration required for the synthesis of high molecular weight collagenous peptides.     

Cotranslational assembly of membrane protein/nanoparticles in cell-free systems

Nanoparticles composed of amphiphilic scaffold proteins and small lipid bilayers are valuable tools for reconstitution and subsequent functional and structural characterization of membrane proteins. In combination with cell-free protein production systems, nanoparticles can be used to cotranslationally and translocon independently insert membrane proteins into tailored lipid environments. This strategy enables rapid generation of protein/nanoparticle complexes by avoiding detergent contact of nascent membrane proteins. Frequently in use are nanoparticles assembled with engineered derivatives of either the membrane scaffold protein (MSP) or the Saposin A (SapA) scaffold. Furthermore, several strategies for the formation of membrane protein/nanoparticle complexes in cell-free reactions exist. However, it is unknown how these strategies affect functional folding, oligomeric assembly and membrane insertion efficiency of cell-free synthesized membrane proteins.We systematically studied membrane protein insertion efficiency and sample quality of cell-free synthesized proteorhodopsin (PR) which was cotranslationally inserted in MSP and SapA based nanoparticles. Three possible PR/nanoparticle formation strategies were analyzed: (i) PR integration into supplied preassembled nanoparticles, (ii) coassembly of nanoparticles from supplied scaffold proteins and lipids upon PR expression, and (iii) coexpression of scaffold proteins together with PR in presence of supplied lipids. Yield, homogeneity as well as the formation of higher PR oligomeric complexes from samples generated by the three strategies were analyzed. Conditions found optimal for PR were applied for the synthesis of a G-protein coupled receptor. The study gives a comprehensive guideline for the rapid synthesis of membrane protein/nanoparticle samples by different processes and identifies key parameters to modulate sample yield and quality.     

Translation and processing of mouse hepatitis virus virion RNA in a cell-free system.

The first event after infection with mouse hepatitis virus strain A59 (MHV-A59) is presumed to be the synthesis of an RNA-dependent RNA polymerase from the input genomic RNA. The synthesis and processing of this putative polymerase protein was studied in a cell-free translation system utilizing 60S RNA from MHV-A59 virions. The polypeptide products of this reaction included two major species of 220 and 28 kilodaltons. Kinetics experiments indicated that both p220 and p28 appeared after 60 min of incubation and that protein p28 was synthesized initially as the N-terminal portion of a larger precursor protein. When the cell-free translation products were labeled with N-formyl[35S]methionyl-tRNAi, p28 was the predominant radioactive product, confirming its N-terminal location within a precursor protein. Translation in the presence of the protease inhibitors leupeptin and ZnCl2 resulted in the disappearance of p28 and p220 and the appearance of a new protein, p250. This product, which approached the maximal size predicted for a protein synthesized from genomic RNA, was not routinely detected in the absence of inhibitors even under conditions which optimized the translation reaction for elongation of proteins. Subsequent chelation of ZnCl2 resulted in the partial cleavage of the precursor protein and the reappearance of p28. One-dimensional peptide mapping with Staphylococcus aureus V-8 protease confirmed the precursor-product relationship of p250 and p28. The results show that MHV virion RNA, like many other viral RNAs, is translated into a large polyprotein, which is cleaved soon after synthesis into smaller, presumably functional proteins. This is in marked contrast to the synthesis of other MHV proteins, in which minimal proteolytic processing occurs.     

Effect of polaymines on yeast cell-free protein synthesizing system. I. Influence of spermine and spermidine on aminoacyl-tRNA transfer reaction.

Spermine and spermidine added to a Saccharomyces cerevisiae cell-free protein synthesizing system increased phenylalanine polymerization reaction several-fold at suboptimal concentration of Mg2+ and approximately two-fold at optimal amounts of Mg2+. The addition of polyamines greatly stimulated the enzymatic and nonenzymatic binding of phenylalanyl-tRNA and N-acetylphenylalanyl-tRNA to ribosomes. The binding of the acetylated derivative was higher than phenylalanyl-tRNA, however, as it was shown the former was bound exclusively to the A site of the ribosome. Contrary to the binding process, the puromycin reaction was not stimulated by spermine added at a concentration which enhanced the polyphenylalanine synthesis. These results indicate that polyamines have not only a sparing effect on the Mg2+ requirement for yeast protein synthesis in vitro and suggest that one of the possible sites of polyamines action might be the binding of aminoacyl-tRNA to ribosomes.     

Differential effect of Ca+2 on the translation of yeast mitochondrial and some viral RNA'S in an E.coli cell-free system.

Addition of 6mM CaCl₂ to an $\text{E. coli}$ cell-free system resulted in a several-fold enhancement of yeast mt RNA translation and in a severe inhibition of protein synthesis directed by MS2, Qβ and T₅ RNA's. CaCl₂ did not alter the Mg⁺² optimum or the time-course of protein synthesis and had no apparent effect on RNA degradation. Formaldehyde treatment of MS2 RNA markedly diminished the CaCl₂-mediated inhibition of its translation. Addition of equimolar amounts of EGTA, together with CaCl₂, abolished the effect of the latter on cell-free protein synthesis. FMet tRNA binding to ribosomes was enhanced by CaCl₂ in the presence of mt RNA, inhibited in the presence of MS2 RNA, and unaffected in the presence of formaldehyde-treated MS2 RNA. Maximal effect on initiation complex formation was observed with 0.1 mM CaCl₂.