Tatsuo Yanagisawa

Multistep Engineering of Pyrrolysyl-tRNA Synthetase to Genetically Encode Nɛ-(o-Azidobenzyloxycarbonyl) lysine for Site-Specific Protein Modification

Pyrrolysyl-tRNA synthetase (PylRS) esterifies pyrrolysine to tRNA(Pyl). In this study, N(epsilon)-(tert-butyloxycarbonyl)-L-lysine (BocLys) and N(epsilon)-allyloxycarbonyl-L-lysine (AlocLys) were esterified to tRNA(Pyl) by PylRS. Crystal structures of a PylRS catalytic fragment complexed with BocLys and an ATP analog and with AlocLys-AMP revealed that PylRS requires an N(epsilon)-carbonyl group bearing a substituent with a certain size. A PylRS(Y384F) mutant obtained by random screening exhibited higher in vitro aminoacylation and in vivo amber suppression activities with BocLys, AlocLys, and pyrrolysine than those of the wild-type PylRS. Furthermore, the structure-based Y306A mutation of PylRS drastically increased the in vitro aminoacylation activity for N(epsilon)-benzyloxycarbonyl-L-lysine (ZLys). A PylRS with both the Y306A and Y384F mutations enabled the large-scale preparation (>10 mg per liter medium) of proteins site-specifically containing N(epsilon)-(o-azidobenzyloxycarbonyl)-L-lysine (AzZLys). The AzZLys-containing protein was labeled with a fluorescent probe, by Staudinger ligation.

Adding l-lysine derivatives to the genetic code of mammalian cells with engineered pyrrolysyl-tRNA synthetases

We report a method for site-specifically incorporating l-lysine derivatives into proteins in mammalian cells, based on the expression of the pyrrolysyl-tRNA synthetase (PylRS)-tRNA(Pyl) pair from Methanosarcina mazei. Different types of external promoters were tested for the expression of tRNA(Pyl) in Chinese hamster ovary cells. When tRNA(Pyl) was expressed from a gene cluster under the control of the U6 promoter, the wild-type PylRS-tRNA(Pyl) pair facilitated the most efficient incorporation of a pyrrolysine analog, N(epsilon)-tert-butyloxycarbonyl-l-lysine (Boc-lysine), into proteins at the amber position. This PylRS-tRNA(Pyl) system yielded the Boc-lysine-containing protein in an amount accounting for 1% of the total protein in human embryonic kidney (HEK) 293 cells. We also created a PylRS variant specific to N(epsilon)-benzyloxycarbonyl-l-lysine, to incorporate this long, bulky, non-natural lysine derivative into proteins in HEK293. The recently reported variant specific to N(epsilon)-acetyllysine was also expressed, resulting in the genetic encoding of this naturally-occurring lysine modification in mammalian cells.

Recognition of Non-α-amino Substrates by Pyrrolysyl-tRNA Synthetase

Pyrrolysyl-tRNA synthetase (PylRS), an aminoacyl-tRNA synthetase (aaRS) recently found in some methanogenic archaea and bacteria, recognizes an unusually large lysine derivative, L-pyrrolysine, as the substrate, and attaches it to the cognate tRNA (tRNA(Pyl)). The PylRS-tRNA(Pyl) pair interacts with none of the endogenous aaRS-tRNA pairs in Escherichia coli, and thus can be used as a novel aaRS-tRNA pair for genetic code expansion. The crystal structures of the Methanosarcina mazei PylRS revealed that it has a unique, large pocket for amino acid binding, and the wild type M. mazei PylRS recognizes the natural lysine derivative as well as many lysine analogs, including N(epsilon)-(tert-butoxycarbonyl)-L-lysine (Boc-lysine), with diverse side chain sizes and structures. Moreover, the PylRS only loosely recognizes the alpha-amino group of the substrate, whereas most aaRSs, including the structurally and genetically related phenylalanyl-tRNA synthetase (PheRS), strictly recognize the main chain groups of the substrate. We report here that wild type PylRS can recognize substrates with a variety of main-chain alpha-groups: alpha-hydroxyacid, non-alpha-amino-carboxylic acid, N(alpha)-methyl-amino acid, and D-amino acid, each with the same side chain as that of Boc-lysine. In contrast, PheRS recognizes none of these amino acid analogs. By expressing the wild type PylRS and its cognate tRNA(Pyl) in E. coli in the presence of the alpha-hydroxyacid analog of Boc-lysine (Boc-LysOH), the amber codon (UAG) was recoded successfully as Boc-LysOH, and thus an ester bond was site-specifically incorporated into a protein molecule. This PylRS-tRNA(Pyl) pair is expected to expand the backbone diversity of protein molecules produced by both in vivo and in vitro ribosomal translation.

Crystallization and preliminary X-ray crystallographic analysis of the catalytic domain of pyrrolysyl-tRNA synthetase from the methanogenic archaeon Methanosarcina mazei.

Pyrrolysyl-tRNA synthetase (PylRS) from Methanosarcina mazei was overexpressed in an N-terminally truncated form PylRS(c270) in Escherichia coli, purified to homogeneity and crystallized by the hanging-drop vapour-diffusion method using polyethylene glycol as a precipitant. The native PylRS(c270) crystals in complex with an ATP analogue belonged to space group P6(4), with unit-cell parameters a = b = 104.88, c = 70.43 A, alpha = beta = 90, gamma = 120 degrees , and diffracted to 1.9 A resolution. The asymmetric unit contains one molecule of PylRS(c270). Selenomethionine-substituted protein crystals were prepared in order to solve the structure by the MAD phasing method.

Reassignment of a rare sense codon to a non-canonical amino acid in Escherichia coli

The immutability of the genetic code has been challenged with the successful reassignment of the UAG stop codon to non-natural amino acids in Escherichia coli. In the present study, we demonstrated the in vivo reassignment of the AGG sense codon from arginine to l-homoarginine. As the first step, we engineered a novel variant of the archaeal pyrrolysyl-tRNA synthetase (PylRS) able to recognize l-homoarginine and l-N6-(1-iminoethyl)lysine (l-NIL). When this PylRS variant or HarRS was expressed in E. coli, together with the AGG-reading tRNAPylCCU molecule, these arginine analogs were efficiently incorporated into proteins in response to AGG. Next, some or all of the AGG codons in the essential genes were eliminated by their synonymous replacements with other arginine codons, whereas the majority of the AGG codons remained in the genome. The bacterial hosts ability to translate AGG into arginine was then restricted in a temperature-dependent manner. The temperature sensitivity caused by this restriction was rescued by the translation of AGG to l-homoarginine or l-NIL. The assignment of AGG to l-homoarginine in the cells was confirmed by mass spectrometric analyses. The results showed the feasibility of breaking the degeneracy of sense codons to enhance the amino-acid diversity in the genetic code.

Molecular cloning and crystal structural analysis of a novel beta-N-acetylhexosaminidase from Paenibacillus sp. TS12 capable of degrading glycosphingolipids

We report the molecular cloning and characterization of two novel beta-N-acetylhexosaminidases (beta-HEX, EC 3.2.1.52) from Paenibacillus sp. strain TS12. The two beta-HEXs (Hex1 and Hex2) were 70% identical in primary structure, and the N-terminal region of both enzymes showed significant similarity with beta-HEXs belonging to glycoside hydrolase family 20 (GH20). Interestingly, however, the C-terminal region of Hex1 and Hex2 shared no sequence similarity with the GH20 beta-HEXs or other known proteins. Both recombinant enzymes, expressed in Escherichia coli BL21(DE3), hydrolyzed the beta-N-acetylhexosamine linkage of chitooligosaccharides and glycosphingolipids such as asialo GM2 and Gb4Cer in the absence of detergent. However, the enzyme was not able to hydrolyze GM2 ganglioside in the presence or in the absence of detergent. We determined three crystal structures of Hex1; the Hex1 deletion mutant Hex1-DeltaC at a resolution of 1.8 A; Hex1-DeltaC in complex with beta-N-acetylglucosamine at 1.6 A; and Hex1-DeltaC in complex with beta-N-acetylgalactosamine at 1.9 A. We made a docking model of Hex1-DeltaC with GM2 oligosaccharide, revealing that the sialic acid residue of GM2 could hinder access of the substrate to the active site cavity. This is the first report describing the molecular cloning, characterization and X-ray structure of a procaryotic beta-HEX capable of hydrolyzing glycosphingolipids.

Neisseria meningitidis Translation Elongation Factor P and Its Active-Site Arginine Residue Are Essential for Cell Viability.

Translation elongation factor P (EF-P), a ubiquitous protein over the entire range of bacterial species, rescues ribosomal stalling at consecutive prolines in proteins. In Escherichia coli and Salmonella enterica, the post-translational β-lysyl modification of Lys34 of EF-P is important for the EF-P activity. The β-lysyl EF-P modification pathway is conserved among only 26–28% of bacteria. Recently, it was found that the Shewanella oneidensis and Pseudomonas aeruginosa EF-P proteins, containing an Arg residue at position 32, are modified with rhamnose, which is a novel post-translational modification. In these bacteria, EF-P and its Arg modification are both dispensable for cell viability, similar to the E. coli and S. enterica EF-P proteins and their Lys34 modification. However, in the present study, we found that EF-P and Arg32 are essential for the viability of the human pathogen, Neisseria meningitidis. We therefore analyzed the modification of Arg32 in the N. meningitidis EF-P protein, and identified the same rhamnosyl modification as in the S. oneidensis and P. aeruginosa EF-P proteins. N. meningitidis also has the orthologue of the rhamnosyl modification enzyme (EarP) from S. oneidensis and P. aeruginosa. Therefore, EarP should be a promising target for antibacterial drug development specifically against N. meningitidis. The pair of genes encoding N. meningitidis EF-P and EarP suppressed the slow-growth phenotype of the EF-P-deficient mutant of E. coli, indicating that the activity of N. meningitidis rhamnosyl–EF-P for rescuing the stalled ribosomes at proline stretches is similar to that of E. coli β-lysyl–EF-P. The possible reasons for the unique requirement of rhamnosyl–EF-P for N. meningitidis cells are that more proline stretch-containing proteins are essential and/or the basal ribosomal activity to synthesize proline stretch-containing proteins in the absence of EF-P is lower in this bacterium than in others.

Modeling of tRNA‐assisted mechanism of Arg activation based on a structure of Arg‐tRNA synthetase, tRNA, and an ATP analog (ANP)

The ATP–pyrophosphate exchange reaction catalyzed by Arg‐tRNA, Gln‐tRNA and Glu‐tRNA synthetases requires the assistance of the cognate tRNA. tRNA also assists Arg‐tRNA synthetase in catalyzing the pyrophosphorolysis of synthetic Arg‐AMP at low pH. The mechanism by which the 3′‐end A76, and in particular its hydroxyl group, of the cognate tRNA is involved with the exchange reaction catalyzed by those enzymes has yet to be established. We determined a crystal structure of a complex of Arg‐tRNA synthetase from Pyrococcus horikoshii, tRNAArgCCU and an ATP analog with Rfactor = 0.213 (Rfree = 0.253) at 2.0 Å resolution. On the basis of newly obtained structural information about the position of ATP bound on the enzyme, we constructed a structural model for a mechanism in which the formation of a hydrogen bond between the 2′‐OH group of A76 of tRNA and the carboxyl group of Arg induces both formation of Arg‐AMP (Arg + ATP → Arg‐AMP + pyrophosphate) and pyrophosphorolysis of Arg‐AMP (Arg‐AMP + pyrophosphate → Arg + ATP) at low pH. Furthermore, we obtained a structural model of the molecular mechanism for the Arg‐tRNA synthetase‐catalyzed deacylation of Arg‐tRNA (Arg‐tRNA + AMP → Arg‐AMP + tRNA at high pH), in which the deacylation of aminoacyl‐tRNA bound on Arg‐tRNA synthetase and Glu‐tRNA synthetase is catalyzed by a quite similar mechanism, whereby the proton‐donating group (–NH–C+(NH2)2 or –COOH) of Arg and Glu assists the aminoacyl transfer from the 2′‐OH group of tRNA to the phosphate group of AMP at high pH.

Multiple site-specific installations of Nε-monomethyl-L-lysine into histone proteins by cell-based and cell-free protein synthesis.

Lysine methylation is one of the important post‐translational modifications of histones, and produces an Nε‐mono‐, di‐, or trimethyllysine residues. Multiple and site‐specific lysine methylations of histones are essential to define epigenetic statuses and control heterochromatin formation, DNA repair, and transcription regulation. A method was previously developed to build an analogue of Nε‐monomethyllysine, with cysteine substituting for lysine. Here, we have developed a new method of preparing histones bearing multiple Nε‐monomethyllysine residues at specified positions. Release factor 1‐knockout (RFzero) Escherichia coli cells or a cell‐free system based on the RFzero cell lysate was used for protein synthesis, as in RFzero cells UAG is redefined as a sense codon for non‐canonical amino acids. During protein synthesis, a tert‐butyloxycarbonyl‐protected Nε‐monomethyllysine analogue is ligated to Methanosarcina mazei pyrrolysine tRNA (tRNAPyl) by M. mazei pyrrolysyl‐tRNA synthetase mutants, and is translationally incorporated into one or more positions specified by the UAG codon. Protecting groups on the protein are then removed with trifluoroacetic acid to generate Nε‐monomethyllysine residues. We installed Nε‐monomethyllysine residues at positions 4, 9, 27, 36, and/or 79 of human histone H3. Each of the Nε‐monomethyllysine residues within the produced histone H3 was recognized by its specific antibody. Furthermore, the antibody recognized the authentic Nε‐monomethyllysine residue at position 27 better than the Nε‐monomethyllysine analogue built with cysteine. Mass spectrometry analyses also confirmed the lysine modifications on the produced histone H3. Thus, our method enables the installation of authentic Nε‐monomethyllysines at multiple positions within a protein for large‐scale production.

Meningococcal PilV Potentiates Neisseria meningitidis Type IV Pilus-Mediated Internalization into Human Endothelial and Epithelial Cells

ABSTRACT The type IV pilus of Neisseria meningitidis is the major factor for meningococcal adhesion to host cells. In this study, we showed that a mutant of N. meningitidis pilV, a minor pilin protein, internalized less efficiently to human endothelial and epithelial cells than the wild-type strain. Matrix-assisted laser desorption ionization–time of flight mass spectrometry and electrospray ionization tandem mass spectrometry analyses showed that PilE, the major subunit of pili, was less glycosylated at its serine 62 residue (Ser62) in the ΔpilV mutant than in the pilV + strain, whereas phosphoglycerol at PilE Ser93 and phosphocholine at PilE Ser67 were not changed. Introduction of the pglL mutation, which results in complete loss of O-linked glycosylation from Ser62, slightly reduced N. meningitidis internalization into human brain microvascular endothelial cells, whereas the addition of the ΔpilV mutation greatly reduced N. meningitidis internalization. The accumulation of ezrin, which is part of the cytoskeleton ERM family, was observed with pilV +, ΔpglL, and pilE(S62A) strains but not with the ΔpilV mutant. These results suggested that whereas N. meningitidis pilin originally had an adhesive activity that was less affected by minor pilin proteins, the invasive function evolved with incorporation of the PilV protein into the pili to promote the N. meningitidis internalization into human cells.