Takanori Kigawa

Cell-free production and stable-isotope labeling of milligram quantities of proteins.

We have improved the productivity of an Escherichia coli cell‐free protein synthesis system. First, creatine phosphate and creatine kinase were used as the energy source regeneration system, and the other components of the reaction mixture were optimized. Second, the E. coli S30 cell extract was condensed by dialysis against a polyethylene glycol solution to increase the rate of synthesis. Third, during the protein synthesis, the reaction mixture was dialyzed against a low‐molecular‐weight substrate solution to prolong the reaction. Thus, the yield of chloramphenicol acetyltransferase was raised to 6 mg/ml of reaction mixture. Stable‐isotope labeling of a protein with 13C/15N‐labeled amino acids for NMR spectroscopy was achieved by this method.

Structural genomics projects in Japan.

Two major structural genomics projects exist in Japan. The oldest, the RIKEN Structural Genomics Initiative, has two major goals: to determine bacterial, mammalian, and plant protein structures by X-ray crystallography and NMR spectroscopy and to perform functional analyses with the target proteins. The newest, the structural genomics project at the Biological Information Research Center, focuses on human membrane proteins.

Preparation of Escherichia coli cell extract for highly productive cell-free protein expression

AbstractAs structural genomics and proteomics research has become popular, the importance of cell-free protein synthesis systems has been realized for high-throughput expression. Our group has established a high-throughput pipeline for protein sample preparation for structural genomics and proteomics by using cell-free protein synthesis. Among the many procedures for cell-free protein synthesis, the preparation of the cell extract is a crucial step to establish a highly efficient and reproducible workflow. In this article, we describe a detailed protocol for E. coli cell extract preparation for cell-free protein synthesis, which we have developed and routinely use. The cell extract prepared according to this protocol is used for many of our cell-free synthesis applications, including high-throughput protein expression using PCR-amplified templates and large-scale protein production for structure determinations. abbreviations 2-mEt — 2-mercaptoethanol; AcCoA — acetyl coenzyme A; BL21 CP — BL21 codon-plus RIL; CAT — chloramphenicol acetyl transferase; CK — creatine kinase; Cm — chloramphenicol; DEPC — diethylpyrocarbonate; CP — creatine phosphate; DTNB — 5,5′-dithiobis-2-nitrobenzoic acid; DTT — dithiothreitol; Folinic acid — L(−)-5-formyl-5,6,7,8-tetrahydrofolic acid; KGlu — polyethyleneglycol; PEG — potassium glutamate; PEP — phospho-enolpyruvate; PK — pyruvate kinase.

An unnatural base pair for incorporating amino acid analogs into proteins

An unnatural base pair of 2-amino-6-(2-thienyl)purine (denoted by s) and pyridin-2-one (denoted by y) was developed to expand the genetic code. The ribonucleoside triphosphate of y was site-specifically incorporated into RNA, opposite s in a template, by T7 RNA polymerase. This transcription was coupled with translation in an Escherichia coli cell-free system. The yAG codon in the transcribed ras mRNA was recognized by the CUs anticodon of a yeast tyrosine transfer RNA (tRNA) variant, which had been enzymatically aminoacylated with an unnatural amino acid, 3-chlorotyrosine. Site-specific incorporation of 3-chlorotyrosine into the Ras protein was demonstrated by liquid chromatography–mass spectrometry (LC-MS) analysis of the products. This coupled transcription–translation system will permit the efficient synthesis of proteins with a tyrosine analog at the desired position.

An engineered Escherichia coli tyrosyl–tRNA synthetase for site-specific incorporation of an unnatural amino acid into proteins in eukaryotic translation and its application in a wheat germ cell-free system

Tyrosyl–tRNA synthetase (TyrRS) from Escherichia coli was engineered to preferentially recognize 3-iodo-l-tyrosine rather than l-tyrosine for the site-specific incorporation of 3-iodo-l-tyrosine into proteins in eukaryotic translation systems. The wild-type TyrRS does not recognize 3-iodo-l-tyrosine, because of the bulky iodine substitution. On the basis of the reported crystal structure of Bacillus stearothermophilus TyrRS, three residues, Y37, Q179, and Q195, in the l-tyrosine-binding site were chosen for mutagenesis. Thirty-four single amino acid replacements and 16 of their combinations were screened by in vitro biochemical assays. A combination of the Y37V and Q195C mutations changed the amino acid specificity in such a way that the variant TyrRS activates 3-iodo-l-tyrosine 10-fold more efficiently than l-tyrosine. This engineered enzyme, TyrRS(V37C195), was tested for use in the wheat germ cell-free translation system, which has recently been significantly improved, and is now as productive as conventional recombinant systems. During the translation in the wheat germ system, an E. coli suppressor tRNATyr was not aminoacylated by the wheat germ enzymes, but was aminoacylated by the E. coli TyrRS(V37C195) variant with 3-iodo-l-tyrosine. After the use of the 3-iodotyrosyl–tRNA in translation, the resultant uncharged tRNA could be aminoacylated again in the system. A mass spectrometric analysis of the produced protein revealed that more than 95% of the amino acids incorporated for an amber codon were iodotyrosine, whose concentration was only twice that of l-tyrosine in the translation. Therefore, the variant enzyme, 3-iodo-l-tyrosine, and the suppressor tRNA can serve as an additional set orthogonal to the 20 endogenous sets in eukaryotic in vitro translation systems.

Solution Structure of an Arabidopsis WRKY DNA Binding Domain

The WRKY proteins comprise a major family of transcription factors that are essential in pathogen and salicylic acid responses of higher plants as well as a variety of plant-specific reactions. They share a DNA binding domain, designated as the WRKY domain, which contains an invariant WRKYGQK sequence and a CX4–5CX22–23HXH zinc binding motif. Herein, we report the NMR solution structure of the C-terminal WRKY domain of the Arabidopsis thaliana WRKY4 protein. The structure consists of a four-stranded β-sheet, with a zinc binding pocket formed by the conserved Cys/His residues located at one end of the β-sheet, revealing a novel zinc and DNA binding structure. The WRKYGQK residues correspond to the most N-terminal β-strand, kinked in the middle of the sequence by the Gly residue, which enables extensive hydrophobic interactions involving the Trp residue and contributes to the structural stability of the β-sheet. Based on a profile of NMR chemical shift perturbations, we propose that the same strand enters the DNA groove and forms contacts with the DNA bases.

Cell-free synthesis and amino acid-selective stable isotope labeling of proteins for NMR analysis

SummaryFor the application of multidimensional NMR spectroscopy to larger proteins, it would be useful to perform selective labeling of one of the 20 amino acids. For some amino acids, however, amino acid metabolism drastically reduces the efficiency and selectivity of labeling in in vivo expression systems. In the present study, a cell-free protein synthesis system was optimized, so that highly efficient and selective stable isotope labeling of proteins can be achieved in the absence of amino acid metabolism. The productivity of the E. coli cell-free coupled transcription-translation system was first improved, by about fivefold, by using the T7 RNA polymerase for transcription and also by improving the translation conditions. Thus, about 0.1 mg protein per 1 ml reaction mixture was synthesized. Then, this improved cell-free system was used for Asp- or Ser-selective 15N-labeling of the human c-Ha-Ras protein. With a 15 ml cell-free reaction, using less than 1 mg of 15N-labeled amino acid, 1 mg of the Ras protein was obtained. 1H-15N HSQC experiments confirmed that the Ras protein was efficiently labeled with high selectivity. These results indicate that this cell-free protein synthesis system is useful for NMR studies.

Phosphatidylinositol monophosphate-binding interface in the oomycete RXLR effector AVR3a is required for its stability in host cells to modulate plant immunity.

The oomycete pathogen Phytophthora infestans causes potato late blight, one of the most economically damaging plant diseases worldwide. P. infestans produces AVR3a, an essential modular virulence effector with an N-terminal RXLR domain that is required for host-cell entry. In host cells, AVR3a stabilizes and inhibits the function of the E3 ubiquitin ligase CMPG1, a key factor in host immune responses including cell death triggered by the pathogen-derived elicitor protein INF1 elicitin. To elucidate the molecular basis of AVR3a effector function, we determined the structure of Phytophthora capsici AVR3a4, a close homolog of P. infestans AVR3a. Our structural and functional analyses reveal that the effector domain of AVR3a contains a conserved, positively charged patch and that this region, rather than the RXLR domain, is required for binding to phosphatidylinositol monophosphates (PIPs) in vitro. Mutations affecting PIP binding do not abolish AVR3a recognition by the resistance protein R3a but reduce its ability to suppress INF1-triggered cell death in planta. Similarly, stabilization of CMPG1 in planta is diminished by these mutations. The steady-state levels of non–PIP-binding mutant proteins in planta are reduced greatly, although these proteins are stable in vitro. Furthermore, overexpression of a phosphatidylinositol phosphate 5-kinase results in reduction of AVR3a levels in planta. Our results suggest that the PIP-binding ability of the AVR3a effector domain is essential for its accumulation inside host cells to suppress CMPG1-dependent immunity.

A B-Box 2 Surface Patch Important for TRIM5α Self-Association, Capsid Binding Avidity, and Retrovirus Restriction

ABSTRACT TRIM5α is a tripartite motif (TRIM) protein that consists of RING, B-box 2, coiled-coil, and B30.2(SPRY) domains. The TRIM5αrh protein from rhesus monkeys recognizes the human immunodeficiency virus type 1 (HIV-1) capsid as it enters the host cell and blocks virus infection prior to reverse transcription. HIV-1-restricting ability can be eliminated by disruption of the B-box 2 domain. Changes in the TRIM5αrh B-box 2 domain have been associated with alterations in TRIM5αrh turnover, the formation of cytoplasmic bodies and higher-order oligomerization. We present here the nuclear magnetic resonance structure of the TRIM5 B-box 2 domain and identify an unusual hydrophobic patch (cluster 1) on the domain surface. Alteration of cluster 1 or the flanking arginine 121 resulted in various degrees of inactivation of HIV-1 restriction, in some cases depending on compensatory changes in other nearby charged residues. For this panel of TRIM5αrh B-box 2 mutants, inhibition of HIV-1 infection was strongly correlated with higher-order self-association and binding affinity for capsid complexes but not with TRIM5αrh half-life or the formation of cytoplasmic bodies. Thus, promoting cooperative TRIM5αrh interactions with the HIV-1 capsid represents a major mechanism whereby the B-box 2 domain potentiates HIV-1 restriction.

DNA-binding domains of plant-specific transcription factors: structure, function, and evolution

The families of the plant-specific transcription factors (TFs) are defined by their characteristic DNA-binding domains (DBDs), such as AP2/ERF, B3, NAC, SBP, and WRKY. Recently, three-dimensional structures of the DBDs, including those in complexes with DNA, were determined by NMR spectroscopy and X-ray crystallography. In this review we summarize the functional and evolutionary implications arising from structure analyses. The unexpected structural similarity between B3 and the noncatalytic DBD of the restriction endonuclease EcoRII allowed us to build structural models of the B3/DNA complex. Most of the DBDs of plant-specific TFs are likely to have originated from endonucleases associated with transposable elements. After the DBDs have been established in unicellular eukaryotes, they experienced extensive plant-specific expansion, by acquiring new functions.