A platform for compartmentalized protein synthesis: protein translation and translocation in the ER

Recent advances in the study of protein translocation across the membrane of the endoplasmic reticulum include insights into the mechanism of signal-sequence function. Biochemical and genetic studies have provided further evidence that lumenal proteins perform direct roles in secretory protein translocation and in the regulation of protein-conducting-channel permeability during membrane protein integration. A hypothesis identifying the endoplasmic reticulum as a site of mRNA localization and compartmentalized protein synthesis has been suggested.     

ER translocation intermediates are adjacent to a nonglycosylated 34-kD integral membrane protein

We have used the homobifunctional cross-linking reagent disuccinimidyl suberate (DSS) to identify proteins that are adjacent to nascent polypeptides undergoing translocations across mammalian rough ER. Translocation intermediates were assembled by supplementing cell free translations of truncated mRNAs with the signal recognition particle (SRP) and microsomal membrane vesicles. Two prominent cross-linked products of 45 and 64 kD were detected. The 64-kD product was obtained when the cell free translation contained SRP, while formation of the 45-kD product required both SRP and translocation competent microsomal membrane vesicles. In agreement with previous investigators, we suggest that the 64-kD product arises by cross-linking of the nascent polypeptide to the 54-kD subunit of SRP. The 45-kD product resists alkaline extraction from the membrane, so we conclude that the 11-kD nascent polypeptide has been crosslinked to an integral membrane protein of approximately 34 kD (imp34). The cross-linked product does not bind to ConA Sepharose, nor is it sensitive to endoglycosidase H digestion; hence imp34 is not identical to the alpha or beta subunits of the signal sequence receptor (SSR). We propose that imp34 functions in concert with SSR to form a translocation site through which nascent polypeptides pass in traversing the membrane bilayer of the rough endoplasmic reticulum.     

Three sets of translocation intermediates are formed during the early stage of protein import into chloroplasts

During the early stage of protein import into chloroplasts, precursor proteins synthesized in the cytosol irreversibly bind to chloroplasts to form the early translocation intermediate under stringent energy conditions. Many efforts have been made to identify the components involved in protein import by analyzing the early intermediate. However, the state of the precursor within the intermediate has not been well investigated so far. In this study, an attempt was made to evaluate the extent of translocation of the precursor by determining the state of the precursor in the early intermediate under various conditions and analyzing the fragments generated by limited proteolysis of the precursors docked to chloroplasts. Our results indicate that three different sets of early intermediate are formed based on temperature and the hydrolysis of GTP/ATP. These have been identified based on the size of proteolytic fragments of the precursor as "energy-dependent association," "insertion," and "penetration" states. These findings suggest two individual ATP-hydrolyzing steps during the early stage of protein import, one of which is temperature-sensitive. Our results also demonstrate that translocation through the outer envelope membrane is mainly dependent on internal ATP.     

Inhibition of the elongation step of protein synthesis by vaccinia virus

Vaccinia cores inhibit translation in cell-free protein synthesis systems at two stages: initiation; and, as shown here, elongation. The former effect tends to obscure the latter. Elongation control could, however, be revealed as follows: when, in a reticulocyte of L-cell lysate, initiation was blocked by a drug (edein), the residual [35S]methionine incorporation was severely reduced by the subsequent addition of vaccinia cores. The elongation block could also be demonstrated by analysis of ribosome profiles: treatment with edein alone permitted ribosomal run-off; treatment with either the elongation inhibition anisomycin or with cores preserved the polyribosomes.     

Continuous cell-free protein synthesis using glycolytic intermediates as energy sources

In this work, we demonstrate that glycolytic intermediates can serve as efficient energy sources to regenerate ATP during continuous-exchange cell-free (CECF) protein synthesis reactions. Through the use of an optimal energy source, approximately 10 mg/ml of protein was generated from CECF protein synthesis reaction at greatly reduced reagent costs. Compared with the conventional reactions utilizing phosphoenol pyruvate as an energy source, the described method yields 10-fold higher productivity per unit reagent cost, making the techniques of CECF protein synthesis more realistic alternative for rapid protein production.     

Kinetically controlled enzymatic synthesis of dipeptide precursor of L-alanyl-L-glutamine

An important nutritional dipeptide precursor, benzoyloxycarbonyl protected L-alanyl-L-glutamine (Z-Ala-Gln), was successfully prepared through a kinetically controlled enzymatic peptide synthesis method. A commercially available and low-cost protease (papain) was used as biocatalyst with Z-Ala-OMe and Gln as acyl donor and nucleophile, respectively. The dipeptide yield was 35.5% under the optimized reaction conditions: 35°C, pH 9.5, and the ratio of acyl donor/nucleophile is 1:10. Based on the reaction mechanism and experimental data, the kinetic model was established, which was in accordance with the Michaelis-Menten equation, and the apparent Michaelis constant K(m)(app) and the apparent maximum reaction rate r(max)(app) were calculated as 1.71 mol/L and 6.09 mmol/(L Min), respectively.     

Kinetically controlled refolding of a heat-denatured hyperthermostable protein

The thermal denaturation of endo-beta-1,3-glucanase from the hyperthermophilic microorganism Pyrococcus furiosus was studied by calorimetry. The calorimetric profile revealed two transitions at 109 and 144 degrees C, corresponding to protein denaturation and complete unfolding, respectively, as shown by circular dichroism and fluorescence spectroscopy data. Calorimetric studies also showed that the denatured state did not refold to the native state unless the cooling temperature rate was very slow. Furthermore, previously denatured protein samples gave well-resolved denaturation transition peaks and showed enzymatic activity after 3 and 9 months of storage, indicating slow refolding to the native conformation over time.     

The transition of early translocation intermediates in chloroplasts is accompanied by the movement of the targeting signal on the precursor protein

During protein import into chloroplasts, precursor proteins are docked to these organelles under stringent energy conditions to form early translocation intermediates. Depending on the temperature and the requirement for ATP, different types of early-intermediates are present, for which the extent of precursor protein translocation differs [H. Inoue, M. Akita, J. Biol. Chem. 283 (2008) 7491–7502]. However, it has not been determined whether the environment surrounding the precursor differs for each intermediate. We therefore employed a site-specific photo-crosslinking strategy in our current study to capture any components in close proximity to the targeting signal of the precursors within the early-intermediates. Various crosslinked products, one of which contains Toc75, were identified. The appearance of these products was found to be dependent on the position of the precursor upon modification by the crosslinker and also the intermediate state. This indicated that the transition of early translocation intermediates is accompanied with the movement of the targeting signal within the early-intermediates.     

Regeneration of adenosine triphosphate from glycolytic intermediates for cell-free protein synthesis.

A new approach for adenosine triphosphate (ATP) regeneration in a cell-free protein synthesis system is described. We first show that pyruvate can be used as a secondary energy source to replace or supplement the conventional secondary energy source, phosphoenol pyruvate (PEP). We also report that glucose-6-phosphate, an earlier intermediate of the glycolytic pathway, can be used for ATP regeneration. These new methods provide more stable maintenance of ATP concentration during protein synthesis. Because pyruvate and glucose-6-phosphate are the first and last intermediates of the glycolytic pathway, respectively, the results also suggest the possibility of using any glycolytic intermediate, or even glucose, for ATP regeneration in a cell-free protein synthesis system. As a result, the methods described provide cell-free protein synthesis with greater flexibility and cost efficiency.     

DNA synthesis in competent Bacillus subtilis cells.

Competent cells of Bacillus subtilis incorporate degradation products from transfecting DNA into their chromosomal DNA. The sensitivity of this incorporation to inhibitors of bacterial DNA synthesis [phage infection or 6-(p-hydroxyphenylazo)-uracil] suggests that semiconservative DNA synthesis can occur in competent cells.     

Topological analysis of the MraY protein catalysing the first membrane step of peptidoglycan synthesis

The two-dimensional membrane topology of the Escherichia coli and Staphylococcus aureus MraY transferases, which catalyse the formation of the first lipid intermediate of peptidoglycan synthesis, was established using the beta-lactamase fusion system. All 28 constructed mraY-blaM fusions produced hybrid proteins. Analysis of the ampicillin resistance of the strains with hybrids led to a common topological model possessing 10 transmembrane segments, five cytoplasmic domains and six periplasmic domains including the N- and C-terminal ends. The agreement between the topologies of E. coli and S. aureus, their agreement to a fair extent with predicted models and a number of features arising from the comparative analysis of 25 orthologue sequences strongly suggested the validity of the model for all eubacterial MraYs. The primary structure of the 10 transmembrane segments diverged among orthologues, but they retained their hydrophobicity, number and size. The similarity of the sequences and distribution of the five cytoplasmic domains in both models, as well as their conservation among the MraY orthologues, clearly suggested their possible involvement in substrate recognition and in the catalytic process. Complementation tests showed that only fusions with untruncated mraY restored growth. It was noteworthy that S. aureus MraY was functional in E. coli. An increased MraY transferase activity was observed only with the untruncated hybrids from both organisms.     

Calcium-requiring step in the uptake of deoxyribonucleic acid molecules through the surface of competent pneumococci.

The conversion of surface-adsorbed deoxyribonucleic acid (DNA) molecules to a state in which they are inaccessible to exogenous deoxyribonuclease requires specifically calcium ions; magnesium ions cannot replace calcium ions. Virtually maximal levels of nuclease-resistant DNA binding and genetic transformation can be obtained in media free from magnesium and containing only calcium ions. It is suggested that the calcium-requiring process is the transport of DNA molecules across the plasma membrane. Magnesium ions stimulate both the loss of surface-adsorbed DNA to the medium and the extracellular degradation of DNA.     

A multisubunit complex of outer and inner mitochondrial membrane protein translocases stabilized in vivo by translocation intermediates.

Translocation of nuclear encoded preproteins into the mitochondrial matrix requires the coordinated action of two translocases: one (Tom) located in the outer mitochondrial membrane and the other (Tim) located in the inner membrane. These translocases reversibly cooperate during protein import. We have previously constructed a chimeric precursor (pPGPrA) consisting of an authentic mitochondrial precursor at the N terminus (Delta(1)-pyrroline-5-carboxylate dehydrogenase, pPut) linked, through glutathione S-transferase, to protein A. When pPGPrA is expressed in yeast, it becomes irreversibly arrested during translocation across the outer and inner mitochondrial membranes. Consequently, the two membranes of mitochondria become progressively "zippered" together, forming long stretches in which they are in close contact (Schülke, N., Sepuri, N. B. V., and Pain, D. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 7314-7319). We now demonstrate that trapped PGPrA intermediates hold the import channels stably together and inhibit mitochondrial protein import and cell growth. Using IgG-Sepharose affinity chromatography of solubilized zippered membranes, we have isolated a multisubunit complex that contains all Tom and Tim components known to be essential for import of matrix-targeted proteins, namely Tom40, Tom22, Tim17, Tim23, Tim44, and matrix-localized Hsp70. Further characterization of this complex may shed light on structural features of the complete mitochondrial import machinery.     

Kinetically controlled synthesis of dipeptides using ficin as biocatalyst.

The application of the sulfhydryl protease ficin as biocatalyst is proposed as a novel method for enzyme-catalyzed synthesis of dipeptides. The negligible peptidase but considerable esterase activity at alkaline pH facilitated the kinetically controlled formation of peptide bonds by coupling the ester substrates Z-Ala-OMe and Z-Gly-OMe with L-alanine, D-alanine, L-glutamine, D-glutamine and L-Cys(acetamidomethyl) respectively. The reaction is accomplished without the occurrence of secondary peptide hydrolysis. Under optimum reaction conditions (pH 9.2, high ratio nucleophile/carboxyl component, 4.8% ethanol, 40 degrees C), the peptide yields ranged from 5 to 91%, depending on the structure of the amino and/or carboxyl component. No racemization was observed in the enzymatic reaction. Application of short-chain peptides has been advocated recently in clinical nutrition. Ficin-catalyzed peptide synthesis might be an attractive biotechnological approach for the synthesis of suitable dipeptides in this respect.     

Biocatalytic synthesis of atorvastatin intermediates

Atorvastatin is a 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitor, and this drug leads to decreased levels of low density lipoprotein (LDL) cholesterol. Lower LDL cholesterol has direct relationship in reducing mortality from coronary heart diseases. Lipitor® (atorvastatin calcium) was the first drug to reach the annual sales of 10 billion dollars in USA and currently is the top selling pharmaceutical product globally. Atorvastatin has a side chain containing two chiral centers as its pharmacophore and it can be synthesized either from chiral pool precursors, by using metal catalysts; or more preferably by the application of free or immobilized enzymes and whole cell biocatalysts for carrying out either asymmetric synthesis or racemic resolution. Biocatalytic synthesis methods for chiral atorvastatin intermediates employ a wide variety of biocatalysts such as alcohol dehydrogenase, 2-deoxy-d-ribose 5-phosphate aldolase, nitrilase, lipase, etc. and each of these biocatalytic processes is discussed in detail in this paper.