Satoko Yoshizawa

Structural origins of gentamicin antibiotic action

Aminoglycoside antibiotics that bind to the ribosomal A site cause misreading of the genetic code and inhibit translocation. The clinically important aminoglycoside, gentamicin C, is a mixture of three components. Binding of each gentamicin component to the ribosome and to a model RNA oligonucleotide was studied biochemically and the structure of the RNA complexed to gentamicin C1a was solved using magnetic resonance nuclear spectroscopy. Gentamicin C1a binds in the major groove of the RNA. Rings I and II of gentamicin direct specific RNA‐drug interactions. Ring III of gentamicin, which distinguishes this subclass of aminoglycosides, also directs specific RNA interactions with conserved base pairs. The structure leads to a general model for specific ribosome recognition by aminoglycoside antibiotics and a possible mechanism for translational inhibition and miscoding. This study provides a structural rationale for chemical synthesis of novel aminoglycosides.

Rapid Detection of a Cocaine-Binding Aptamer Using Biological Nanopores on a Chip

This paper describes a methodology for the rapid and highly selective detection of cocaine using a membrane protein channel combined with a DNA aptamer. The DNA aptamer recognizes the cocaine molecule with high selectivity. We successfully detected a low concentration of cocaine (300 ng/mL, the drug test cutoff limit) within 60 s using a biological nanopore embedded in a microchip.

The many levels of control on bacterial selenoprotein synthesis

Selenium shares many chemical facets with sulphur but differs from it in the redox potential, especially of the Se(2-)/S(2-) oxidation state. The higher chemical reactivity of the deprotonated selenol has been used by Biology in the synthesis of the amino acid selenocysteine and its DNA-encoded incorporation into specific positions of proteins to enhance their structural role or their activity. Since selenocysteine is a steric isomer of cysteine, numerous control mechanisms have been developed which prevent cross-intrusion of the elements during biosynthesis and insertion. As described in this review, these fidelity steps occur at the genetic, biochemical and physiological level.

Structural basis for mRNA recognition by elongation factor SelB.

In bacteria, incorporation of selenocysteine, the 21st amino acid, into proteins requires elongation factor SelB, which has the unusual property of binding to both transfer RNA (tRNA) and mRNA. SelB binds to an mRNA hairpin formed by the selenocysteine insertion sequence (SECIS) with extremely high specificity, the molecular basis of which has been unknown. We have determined the crystal structure of the mRNA-binding domain of SelB in complex with SECIS RNA at a resolution of 2.3 Å. This is the first example of a complex between an RNA and a winged-helix (WH) domain, a motif found in many DNA-binding proteins and recently discovered in RNA-binding proteins. Notably, RNA binding does not induce a major conformational change in the WH motif. The structure reveals a new mode of RNA recognition with a geometry that allows the complex to wrap around the small ribosomal subunit.

Structure of Prokaryotic SECIS mRNA Hairpin and its Interaction with Elongation Factor SelB

In prokaryotes, the recoding of a UGA stop codon as a selenocysteine codon requires a special elongation factor (EF) SelB and a stem-loop structure within the mRNA called a selenocysteine insertion sequence (SECIS). Here, we used NMR spectroscopy to determine the solution structure of the SECIS mRNA hairpin and characterized its interaction with the mRNA-binding domain of SelB. Our structural and biochemical data identified the conserved structural features important for binding to EF SelB within different SECIS RNA sequences. In the free SECIS mRNA structure, conserved nucleotides are strongly exposed for recognition by SelB. Binding of the C-terminal domain of SelB stabilizes the RNA secondary structure. In the protein-RNA complex, a Watson-Crick loop base-pair leaves a GpU sequence accessible for SelB recognition. This GpU sequence at the tip of the capping tetraloop and a bulge uracil five Watson-Crick base-pairs apart from the GpU are essential for interaction with SelB.

Solution structure of conserved AGNN tetraloops: insights into Rnt1p RNA processing

Rnt1p, the yeast orthologue of RNase III, cleaves rRNAs, snRNAs and snoRNAs at a stem capped with conserved AGNN tetraloop. Here we show that 9 bp long stems ending with AGAA or AGUC tetraloops bind to Rnt1p and direct specific but sequence‐independent RNA cleavage when provided with stems longer than 13 bp. The solution structures of these two tetraloops reveal a common fold for the terminal loop stabilized by non‐canonical A–A or A–C pairs and extensive base stacking. The conserved nucleotides are stacked at the 5′ side of the loop, exposing their Watson–Crick and Hoogsteen faces for recognition by Rnt1p. These results indicate that yeast RNase III recognizes the fold of a conserved single‐stranded tetraloop to direct specific dsRNA cleavage.

Sequence dependence of substrate recognition and cleavage by yeast RNase III.

Yeast Rnt1p is a member of the double-stranded RNA (dsRNA) specific RNase III family of endoribonucleases involved in RNA processing and RNA interference (RNAi). Unlike other RNase III enzymes, which recognize a variety of RNA duplexes, Rnt1p cleaves specifically RNA stems capped with the conserved AGNN tetraloop. This unusual substrate specificity challenges the established dogma for substrate selection by RNase III and questions the dsRNA contribution to recognition by Rnt1p. Here we show that the dsRNA sequence adjacent to the tetraloop regulates Rnt1p cleavage by interfering with RNA binding. In context, sequences surrounding the cleavage site directly influence the cleavage efficiency. Introduction of sequences that stabilize the RNA helix enhanced binding while reducing the turnover rate indicating that, unlike the tetraloop, Rnt1p binding to the dsRNA helix may become rate-limiting. These results suggest that Rnt1p activity is strictly regulated by a combination of primary and tertiary structural elements allowing a substrate-specific binding and cleavage efficiency.

Structure of 23S rRNA hairpin 35 and its interaction with the tylosin-resistance methyltransferase RlmAII

The bacterial rRNA methyltransferase RlmAII (formerly TlrB) contributes to resistance against tylosin‐like 16‐membered ring macrolide antibiotics. RlmAII was originally discovered in the tylosin‐producer Streptomyces fradiae, and members of this subclass of methyltransferases have subsequently been found in other Gram‐positive bacteria, including Streptococcus pneumoniae. In all cases, RlmAII methylates 23S rRNA at nucleotide G748, which is situated in a stem–loop (hairpin 35) at the macrolide binding site of the ribosome. The conformation of hairpin 35 recognized by RlmAII is shown here by NMR spectroscopy to resemble the anticodon loop of tRNA. The loop folds independently of the rest of the 23S rRNA, and is stabilized by a non‐canonical G–A pair and a U‐turn motif, rendering G748 accessible. Binding of S.pneumoniae RlmAII induces changes in NMR signals at specific nucleotides that are involved in the methyltransferase–RNA interaction. The conformation of hairpin 35 that interacts with RlmAII is radically different from the structure this hairpin adopts within the 50S subunit. This indicates that the hairpin undergoes major structural rearrangement upon interaction with ribosomal proteins during 50S assembly.

Interaction of the HIV-1 frameshift signal with the ribosome

Ribosomal frameshifting on viral RNAs relies on the mechanical properties of structural elements, often pseudoknots and more rarely stem-loops, that are unfolded by the ribosome during translation. In human immunodeficiency virus (HIV)-1 type B a long hairpin containing a three-nucleotide bulge is responsible for efficient frameshifting. This three-nucleotide bulge separates the hairpin in two domains: an unstable lower stem followed by a GC-rich upper stem. Toeprinting and chemical probing assays suggest that a hairpin-like structure is retained when ribosomes, initially bound at the slippery sequence, were allowed multiple EF-G catalyzed translocation cycles. However, while the upper stem remains intact the lower stem readily melts. After the first, and single step of translocation of deacylated tRNA to the 30 S P site, movement of the mRNA stem-loop in the 5′ direction is halted, which is consistent with the notion that the downstream secondary structure resists unfolding. Mechanical stretching of the hairpin using optical tweezers only allows clear identification of unfolding of the upper stem at a force of 12.8 ± 1.0 pN. This suggests that the lower stem is unstable and may indeed readily unfold in the presence of a translocating ribosome.

Lipid-coated microdroplet array for in vitro protein synthesis.

Monitoring complex biological assays such as in vitro protein synthesis over long periods in micrometer-sized cavities of poly(dimethyl siloxane) (PDMS) microfluidic devices requires a strategy that solves the adsorption and absorption problems on PDMS surfaces. In this study, we developed a technique that instantaneously arrays aqueous microdroplets coated with a phospholipid membrane within a single microfluidic device. The simple lipid bilayer coating effectively inhibits the adsorption of proteins and DNA, whereas the encapsulation of the droplet reduces the area in contact with the PDMS surface, resulting in decreased absorption in part. Although the size becomes smaller during the first few hours, a lipid-coated microdroplet array demonstrated a temporal stability of more than 20 h and a size uniformity of CV 3% in the device. Furthermore, we succeeded in expressing a green fluorescent protein by confining an in vitro translation system in the microdroplets, which was confirmed by scanning the fluorescence spectrum of the droplets, demonstrating that the lipid coat secured the synthetic reaction from the adsorption problem.